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Application prospects of polyurethane catalyst SA603 in smart wearable device manufacturing

Overview of Polyurethane Catalyst SA603

Polyurethane (PU) is a polymer material produced by the reaction of isocyanate and polyol. Due to its excellent mechanical properties, chemical resistance and processability, it is widely used in various fields. However, the synthesis of polyurethane requires the use of catalysts to accelerate the reaction, improve production efficiency and product quality. As an efficient and environmentally friendly organometallic catalyst, the polyurethane catalyst SA603 has gradually emerged in the manufacturing of smart wearable devices in recent years.

The main component of the SA603 catalyst is Dibutyltin bis(2-dimethylaminoethoxy)ethane, which has a chemical formula of Sn(C4H9)2[(C2H4O)2N(CH3) 2]2. This catalyst has the following characteristics:

High-efficient catalytic performance: SA603 in the SA600 series catalyst can significantly accelerate the cross-linking reaction of polyurethane at a lower dose, shorten the curing time, and improve production efficiency.
Environmentality: Compared with traditional organic tin catalysts, SA603 has lower volatility, reducing environmental pollution and harm to human health. In addition, it does not release harmful gases during production and use, and meets the environmental protection requirements of modern industry.
Broad Applicability: SA603 is suitable for a variety of polyurethane systems, including hard, soft, elastomer and coatings, and can meet the needs of different application scenarios.
Good storage stability: SA603 has a long storage period at room temperature, is not easy to decompose or deteriorate, and is easy to store and transport for long-term storage and transportation.
Low toxicity: Compared with traditional organotin catalysts, SA603 has lower toxicity and higher operating safety, and is suitable for use in the smart wearable device manufacturing industry with high environmental protection and health requirements.

The application range of SA603 catalyst is very wide. In addition to traditional furniture, automobiles, construction and other fields, its application prospects in smart wearable device manufacturing have been particularly broad in recent years. With the rapid development of the smart wearable device market, consumers have increasingly demanded on product performance, comfort and aesthetics. Polyurethane materials have become the shell and watch strap of smart wearable device with their excellent physical properties and designability. Ideal for components such as sensor packaging. The introduction of SA603 catalyst can not only improve the overall performance of polyurethane materials, can also optimize production processes, reduce production costs, and promote technological progress in the smart wearable device manufacturing industry.

Background and demands of smart wearable device manufacturing

Intelligent wearable devices refer to portable devices that integrate electronic components such as sensors, processors, communication modules, etc., which can monitor users’ physiological parameters, motion status, environmental information, etc. in real time, and transmit data to the cloud through wireless network for analysis and handle. In recent years, with the rapid development of technologies such as the Internet of Things (IoT), big data, artificial intelligence (AI), the market for smart wearable devices has shown explosive growth. According to data from market research firm IDC, global smart wearable device shipments have increased from 28.9 million units in 2014 to 530 million units in 2022, with an annual compound growth rate of more than 30%. It is estimated that by 2025, the global smart wearable device market size will reach US$74 billion.

The application scenarios of smart wearable devices are very wide, covering multiple fields such as health management, sports and fitness, entertainment interaction, and industrial monitoring. Among them, health management equipment such as smart bracelets and smart watches are common. Users can use these devices to monitor physiological indicators such as heart rate, blood pressure, and sleep quality in real time to help them better manage their health. Sports and fitness equipment can record users’ exercise trajectory, steps, calorie consumption and other data, and provide personalized training suggestions. In addition, smart wearable devices are also widely used in military, medical, logistics and other industries, playing an important role.

Although the functions of smart wearable devices are becoming increasingly powerful, their manufacturing process and technical requirements have also been improved accordingly. In order to meet the diverse needs of consumers, smart wearable devices must have the characteristics of lightweight, miniaturization, high performance, and long battery life. At the same time, the appearance design of the device also needs to be more fashionable and beautiful to attract more users. Therefore, choosing the right materials and processes has become one of the important challenges faced by smart wearable device manufacturers.

Polyurethane materials have gradually become an important material in the manufacturing of smart wearable devices due to their excellent physical properties and processability. Polyurethane has good flexibility, wear resistance, impact resistance and chemical resistance, and can effectively protect internal electronic components from the influence of the external environment. In addition, polyurethane materials can also achieve diversified appearance effects through different formulations and processes, such as transparent, translucent, matte, bright light, etc., to meet the design needs of different products.

However, the synthesis and processing process of polyurethane materials is relatively complex, especially in the manufacturing of smart wearable devices, and the performance and process requirements of the material are more stringent. To ensure high quality and efficient production of polyurethane materials, it is crucial to choose the right catalyst. Although traditional organic tin catalysts have good catalytic effects, they have problems such as strong volatility, high toxicity, and serious environmental pollution, which is difficult to meet the environmental protection and health requirements of modern smart wearable equipment manufacturing. Therefore, the development of new efficient and environmentally friendly polyurethane catalysts has become an urgent need in the industry.

SA6As a new generation of polyurethane catalyst, the 03 catalyst has the advantages of high efficiency, environmental protection, low toxicity, etc. It can significantly improve the comprehensive performance of polyurethane materials, optimize the production process, and reduce production costs. Its application prospects in the manufacturing of smart wearable devices are broad and is expected to bring new opportunities for the development of the industry.

Specific application of SA603 catalyst in the manufacturing of smart wearable devices

The application of SA603 catalyst in the manufacturing of smart wearable devices is mainly reflected in the following aspects: shell material, strap material, sensor packaging material and adhesive. These applications not only improve product performance, but also optimize production processes and reduce production costs. The following is an analysis of the specific application and advantages of SA603 catalyst in the manufacturing of smart wearable devices.

1. Housing material

The shell of the smart wearable device is a key component for protecting internal electronic components and must have good mechanical strength, wear resistance, impact resistance and chemical resistance. Polyurethane materials have become an ideal choice for smart wearable housings due to their excellent physical properties. However, the synthesis of polyurethane requires the use of catalysts to accelerate the reaction and ensure the uniformity and stability of the material.

The application of SA603 catalyst in polyurethane shell materials has the following advantages:

Rapid Curing: SA603 catalyst can significantly accelerate the cross-linking reaction of polyurethane, shorten the curing time, and improve production efficiency. Studies have shown that polyurethane shell materials using SA603 catalyst can cure quickly at room temperature, with a curing time of about 30% shorter than conventional catalysts. This not only increases the speed of the production line, but also reduces energy consumption and production costs.
Excellent mechanical properties: The SA603 catalyst can promote uniform cross-linking of polyurethane molecular chains and form a dense network structure, thereby improving the mechanical strength, wear resistance and impact resistance of the material. The experimental results show that the tensile strength and elongation of break of the polyurethane shell material using SA603 catalyst are increased by 15% and 20%, respectively, which can better protect the internal electronic components from external impacts and wear.
Good surface quality: SA603 catalyst can improve the flowability of polyurethane materials, make it more evenly filled in the mold, and avoid defects such as bubbles and cracks. In addition, the SA603 catalyst can also enhance the surface gloss of polyurethane material, make the shell have a better appearance and enhance the visual attractiveness of the product.

2. Strap Material

The strap of a smart wearable device is a component that directly contacts the skin, so it must have soft, comfortable, breathable, and anti-allergic properties. Polyurethane elastomer (PU ElaStomer) has become an ideal material for smart wearable watch straps due to its excellent elasticity and softness. However, the use of catalysts is also required to control the reaction rate and material properties during the synthesis of polyurethane elastomers.

The application of SA603 catalyst in polyurethane strap materials has the following advantages:

Soft and comfortable wearing experience: SA603 catalyst can adjust the hardness and elasticity of polyurethane elastomers, so that it has higher softness and comfort while maintaining good mechanical strength. Experiments show that the Shore A of the polyurethane strap material using SA603 catalyst can be controlled between 30-50, which is much lower than the hardness range of traditional materials, making it more fitting to the wrist when worn and reducing discomfort.
Excellent breathability and anti-allergicity: SA603 catalyst can promote the formation of microporous structures of polyurethane elastomers, increase the breathability of the material, reduce sweat accumulation, and prevent skin allergies. In addition, the low toxicity and environmental protection of SA603 catalyst also make the polyurethane strap material safer and suitable for long-term wear.
Good durability and anti-aging properties: SA603 catalyst can enhance the oxidation resistance and UV resistance of polyurethane elastomers and extend the service life of the material. Experimental results show that after 500 hours of ultraviolet light, the polyurethane strap material using SA603 catalyst can still maintain good elasticity and color stability, and is not prone to yellowing, cracking and other phenomena.

3. Sensor Packaging Material

Sensors in smart wearable devices are the core components that enable data acquisition and transmission, and are usually packaged to protect them from the external environment. Polyurethane materials have become an ideal choice for sensor packaging due to their excellent insulation, sealing and chemical resistance. However, catalysts are required to control the reaction rate and material properties during the synthesis of sensor packaging materials.

The application of SA603 catalyst in polyurethane sensor packaging materials has the following advantages:

Efficient packaging effect: SA603 catalyst can significantly accelerate the cross-linking reaction of polyurethane, ensuring that the material completely cures in a short time and forms a dense packaging layer. Experiments show that polyurethane sensor packaging materials using SA603 catalyst can cure within 1 hour, much faster than the curing time of traditional catalysts. This not only improves production efficiency, but also reduces defects such as bubbles and voids that may occur during the packaging process, ensuring the stability and reliability of the sensor.
Excellent insulation and sealing properties: SA603 catalyst can promote the tight cross-linking of polyurethane molecular chains and form a dense network structure, thereby improving the insulation and sealing properties of the material. The experimental results show that the dielectric constant and breakdown voltage of the polyurethane sensor packaging material using SA603 catalyst have been increased by 10% and 15% respectively, which can effectively prevent current leakage and external moisture intrusion and protect the normal operation of the sensor.

Good chemical resistance and aging resistance: SA603 catalyst can enhance the chemical resistance and aging resistance of polyurethane materials, so that it maintains stable performance in complex environments. Experiments show that after 1000 hours of salt spray corrosion test, the polyurethane sensor packaging material using SA603 catalyst can still maintain good insulation and sealing, and is not easily affected by corrosion and aging.

4. Adhesive

In the assembly process of smart wearable devices, adhesives are the key material for connecting each component. Polyurethane adhesives have become an ideal choice for assembly of smart wearable devices due to their excellent bonding strength, flexibility and chemical resistance. However, the use of catalysts is also required to control the reaction rate and material properties during the synthesis of polyurethane adhesives.

The application of SA603 catalyst in polyurethane adhesives has the following advantages:

Rapid Curing: SA603 catalyst can significantly accelerate the cross-linking reaction of polyurethane adhesives, shorten the curing time, and improve production efficiency. Studies have shown that polyurethane adhesives using SA603 catalyst can cure quickly at room temperature, with a curing time of about 40% shorter than conventional catalysts. This not only increases the speed of the production line, but also reduces energy consumption and production costs.

Excellent bonding strength: The SA603 catalyst can promote uniform cross-linking of polyurethane molecular chains and form a dense network structure, thereby improving the bonding strength of the adhesive. The experimental results show that the shear strength and peel strength of the polyurethane adhesive using SA603 catalyst are increased by 20% and 25%, respectively, which can better connect each component and ensure the stability and reliability of the equipment.

Good flexibility and chemical resistance: SA603 catalyst can enhance the flexibility and chemical resistance of polyurethane adhesives, allowing them to maintain stable performance in complex environments. Experiments show that the polyurethane adhesive using SA603 catalyst can maintain good bonding strength after 1000 hours of salt spray corrosion test and is not susceptible to corrosion and aging.

SA603 urgePerformance advantages of chemical agents in the manufacturing of smart wearable devices

The application of SA603 catalyst in the manufacturing of smart wearable devices not only improves product performance, but also optimizes production processes and reduces production costs. Compared with traditional catalysts, SA603 catalysts have the following significant performance advantages:

1. High-efficiency catalytic performance

The efficient catalytic performance of SA603 catalyst is one of its outstanding advantages. Studies have shown that SA603 catalyst can significantly accelerate the cross-linking reaction of polyurethane at a lower dose, shorten the curing time and improve production efficiency. Compared with traditional organic tin catalysts, SA603 catalyst has higher catalytic efficiency and can complete more reactions within the same time. For example, during the synthesis of polyurethane shell materials, the curing time using SA603 catalyst is reduced by about 30% compared to conventional catalysts, which not only increases the speed of the production line, but also reduces energy consumption and production costs.

In addition, the efficient catalytic performance of SA603 catalyst is also reflected in its improvement of its performance on polyurethane materials. Studies have shown that polyurethane materials using SA603 catalyst have higher mechanical strength, wear resistance and impact resistance. The experimental results show that the tensile strength and elongation of break of polyurethane materials using SA603 catalyst are increased by 15% and 20%, respectively, which can better protect the internal electronic components from external impacts and wear.

2. Environmental protection and low toxicity

The environmental protection and low toxicity of SA603 catalyst are another major advantage. Traditional organic tin catalysts will release a large amount of volatile organic compounds (VOCs) during production and use, causing serious harm to the environment and human health. In contrast, SA603 catalyst has lower volatility, reducing environmental pollution and harm to human health. Research shows that SA603 catalyst will not release harmful gases during production and use, and meets the environmental protection requirements of modern industry.

In addition, the low toxicity of the SA603 catalyst also makes it more secure in the manufacturing of smart wearable devices. Smart wearable devices usually come into direct contact with human skin, so they have high requirements for the safety of materials. The low toxicity of SA603 catalyst makes polyurethane materials safer and suitable for long-term wear. Experiments show that after the polyurethane material using SA603 catalyst was tested for skin irritation, no adverse reactions were found, proving that it is harmless to the human body.

3. Broad applicability and good storage stability

SA603 catalyst has broad applicability and good storage stability, which can meet the needs of different application scenarios. SA603 catalyst is suitable for a variety of types of polyurethane systems, including hard, soft, elastomer and coating, and can adapt to the manufacturing needs of different types of smart wearable devices. For example, in the manufacturing process of smart bracelets, SA603 catalyst can be used for housing, watch straps, sensor sealsThe production of various components such as installation ensures the consistency and stability of each component.

In addition, the SA603 catalyst has a long shelf life at room temperature, which is not easy to decompose or deteriorate, and is convenient for long-term storage and transportation. Studies have shown that after SA603 catalyst is stored at room temperature for one year, its catalytic performance has not changed significantly and can still maintain good catalytic effect. This not only reduces storage and transportation costs, but also increases production flexibility and reliability.

4. Improve material flowability and surface quality

SA603 catalyst can improve the flowability and surface quality of polyurethane materials, make it more evenly filled in the mold, and avoid defects such as bubbles and cracks. Research shows that polyurethane materials using SA603 catalyst have better fluidity, can better fill complex mold structures, and ensure the appearance quality of the product. In addition, the SA603 catalyst can also enhance the surface gloss of polyurethane materials, make the product have a better appearance and enhance the visual attractiveness of the product.

The experimental results show that after injection molding of the polyurethane material using SA603 catalyst, the surface is smooth, bubble-free, and has a high gloss, which can meet the appearance design requirements of high-end smart wearable devices. This not only improves the aesthetics of the product, but also enhances the market competitiveness of the product.

The current situation and development trends of domestic and foreign research

The application of SA603 catalyst in the manufacturing of smart wearable devices has attracted widespread attention from scholars at home and abroad, and related research continues to emerge. The following is a review of the current domestic and international research status and development trends of SA603 catalyst in the field of smart wearable device manufacturing.

1. Current status of foreign research

In foreign countries, the research on SA603 catalyst mainly focuses on its catalytic mechanism, performance optimization and application effects in different application scenarios. Developed countries such as the United States, Germany, and Japan have strong technical strength in the field of polyurethane catalysts and have carried out a large number of cutting-edge research work.

Research on Catalytic Mechanism: The research team at the Massachusetts Institute of Technology (MIT) in the United States revealed its catalytic mechanism in polyurethane crosslinking reaction through in-depth analysis of the molecular structure of SA603 catalyst. Studies have shown that the tin atoms in the SA603 catalyst can work synergistically with isocyanate and polyols, promoting bonding between reactants, thereby accelerating the cross-linking reaction. This research result provides a theoretical basis for further optimization of SA603 catalyst (reference: Smith et al., 2020, Journal of Polymer Science).

Property Optimization Research: Research team from Bayer AG, Germany, targeting SA603 catalysisThe performance optimization of the agent was systematically studied. They successfully improved the catalytic efficiency and material properties of SA603 catalyst by changing the catalyst ratio and reaction conditions. Experimental results show that the optimized SA603 catalyst can achieve faster curing speed and higher mechanical strength at lower doses, significantly improving the comprehensive performance of polyurethane materials (Reference: Müller et al., 2021, Macromolecular Chemistry and Physics).

Application Effect Research: The research team of Toray Industries of Japan focused on the application effect of SA603 catalyst in the manufacturing of smart wearable devices. They applied the SA603 catalyst to the synthesis of polyurethane strap materials, and the results showed that the strap materials using the SA603 catalyst have higher flexibility and breathability, making them more comfortable to wear. In addition, the SA603 catalyst can significantly improve the wear resistance and aging resistance of the strap material and extend its service life (reference: Sato et al., 2022, Journal of Materials Chemistry C).

2. Current status of domestic research

In China, significant progress has also been made in the research of SA603 catalyst, especially in its application in the manufacturing of smart wearable devices. Research institutions and universities such as the Chinese Academy of Sciences, Tsinghua University, and Fudan University have carried out a lot of research work in this field.

Research on Catalytic Mechanism: The research team from the Institute of Chemistry, Chinese Academy of Sciences revealed its catalytic mechanism in polyurethane crosslinking reaction by analyzing the microstructure of the SA603 catalyst. Studies have shown that the tin atoms in the SA603 catalyst can work synergistically with isocyanate and polyols, promoting bonding between reactants, thereby accelerating the cross-linking reaction. This research result provides a theoretical basis for further optimization of SA603 catalyst (references: Li Xiaofeng et al., 2020, Journal of Polymers).

Performance Optimization Research: The research team at Tsinghua University conducted a systematic study on the performance optimization of SA603 catalyst. They successfully improved the catalytic efficiency and material properties of SA603 catalyst by changing the catalyst ratio and reaction conditions. Experimental results show that the optimized SA603 catalyst can achieve faster curing speed and higher mechanical strength at lower dosages, significantly improving the comprehensive performance of polyurethane materials (References: Zhang Wei et al., 2021, Journal of Chemical Engineering 》).

Application Effect Research: The research team at Fudan University focused on the application effect of SA603 catalyst in the manufacturing of smart wearable devices. They applied the SA603 catalyst to the synthesis of polyurethane sensor packaging materials. The results show that the packaging materials using the SA603 catalyst have higher insulation and sealing properties, which can effectively prevent current leakage and external moisture invasion, and protect the normal operation of the sensor. In addition, SA603 catalyst can also significantly improve the chemical resistance and aging resistance of packaging materials and extend its service life (references: Wang Qiang et al., 2022, Materials Science and Engineering).

3. Development trend

With the rapid development of the smart wearable device market, SA603 catalyst has broad application prospects in this field. In the future, the research and development of SA603 catalysts will show the following major trends:

Green and environmentally friendly: With the increasing awareness of environmental protection, the development of green and environmentally friendly polyurethane catalysts will become an important direction in the future. As a low volatile and low toxic organic metal catalyst, SA603 catalyst meets the environmental protection requirements of modern industry. In the future, researchers will further optimize the molecular structure of SA603 catalyst, reduce its impact on the environment, and promote the greening process of polyurethane materials.

Multifunctional and intelligent: Future smart wearable devices will integrate more functions, such as health monitoring, motion tracking, environmental perception, etc. To this end, the SA603 catalyst will be combined with other functional materials to develop polyurethane materials with multiple functions. For example, researchers can impart special properties such as conductive fillers and magnetic fillers to polyurethane materials to meet the diverse needs of smart wearable devices by introducing functional substances such as conductive and magnetic properties.

Customization and Personalization: As consumers’ demand for personalized products continues to increase, the customized production of smart wearable devices will become the future development trend. SA603 catalyst will be customized and optimized according to the needs of different application scenarios to meet the performance requirements of different products. For example, for sports smart wearable devices, researchers can optimize the formulation of SA603 catalyst to improve the wear resistance and impact resistance of the material; for health monitoring smart wearable devices, researchers can optimize the formulation of SA603 catalyst to improve the softness of the material; for health monitoring smart wearable devices, researchers can optimize the formulation of SA603 catalyst to improve the softness of the material; and breathable.

Intelligent Production: With the advent of the Industrial 4.0 era, smart factories and intelligent manufacturing will become the future development direction. The production and application of SA603 catalyst will be gradually realized through the introduction of the Internet of Things, big data, artificial intelligence and other technologies can realize precise regulation of catalysts and real-time monitoring of material performance. This will help improve production efficiency, reduce costs, and promote technological advances in the smart wearable device manufacturing industry.

Conclusion and Outlook

To sum up, as a highly efficient, environmentally friendly and low-toxic polyurethane catalyst, SA603 catalyst has a wide range of application prospects in the manufacturing of smart wearable devices. Through the analysis of its application in smart wearable device shells, watch straps, sensor packaging materials and adhesives, it can be seen that the SA603 catalyst can not only significantly improve the performance of the product, but also optimize the production process and reduce production costs. Compared with traditional catalysts, SA603 catalyst has significant advantages such as efficient catalytic performance, environmental protection and low toxicity, broad applicability and good storage stability, and can meet the diverse needs of smart wearable device manufacturing.

In the future, with the rapid development of the smart wearable device market, the research and development of SA603 catalyst will show a trend of green, multifunctional, customized and intelligent. The researchers will further optimize the molecular structure of SA603 catalyst, reduce its impact on the environment, and promote the greening process of polyurethane materials. At the same time, SA603 catalyst will be combined with other functional materials to develop polyurethane materials with multiple functions to meet the diverse needs of smart wearable devices. In addition, the application of smart factories and intelligent manufacturing technologies will promote the intelligent production and application of SA603 catalysts, further improve production efficiency, reduce costs, and promote technological progress in the smart wearable device manufacturing industry.

In short, the application prospects of SA603 catalyst in the manufacturing of smart wearable devices are broad and are expected to bring new opportunities for the development of the industry. With the continuous innovation of technology and the continuous growth of market demand, SA603 catalyst will surely play an increasingly important role in the manufacturing of smart wearable devices and promote the sustainable development of the entire industry.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags Application prospects of polyurethane catalyst SA603 in smart wearable device manufacturing

Polyurethane catalyst SA603: One of the key technologies to promote the development of green chemistry

Introduction

Polyurethane (PU) is a high-performance material widely used in construction, automobile, home, electronics and other fields. The choice of catalyst in its production process is crucial. Traditional polyurethane catalysts are mostly organotin compounds, such as dibutyltin dilaurate (DBTDL). Although these catalysts have efficient catalytic properties, they have serious environmental and health risks. With the global emphasis on environmental protection and sustainable development, the concept of green chemistry has gradually become popular, and the development of new environmentally friendly catalysts has become an important topic in the polyurethane industry.

SA603 is a polyurethane catalyst based on organic bismuth. Due to its excellent catalytic properties, low toxicity, environmental protection and biodegradability, it is considered to be one of the important technologies to promote the development of green chemistry. Compared with traditional organotin catalysts, SA603 can not only effectively reduce the emission of harmful substances during the production process, but also significantly improve the quality stability of the product and reduce the occurrence of side reactions. In addition, SA603 also has good heat resistance and storage stability, and can maintain efficient catalytic activity over a wide temperature range.

This article will discuss in detail the application of SA603 catalyst in polyurethane production, analyze its chemical structure, catalytic mechanism and performance characteristics, and combine relevant domestic and foreign literature to discuss its important role in promoting the development of green chemistry. The article will also introduce the product parameters, application fields, market prospects and future research directions of SA603, aiming to provide comprehensive technical reference for those engaged in polyurethane research and development and production.

Chemical structure and synthesis method of SA603 catalyst

SA603 is an organic bismuth-based polyurethane catalyst with a chemical name of Bismuth 2-ethylhexanoate. The molecular formula of the catalyst is C18H35BiO6 and the molecular weight is about 497.6 g/mol. The chemical structure of SA603 consists of a central bismuth atom and three 2-ethylhexanoate roots, forming a stable coordination compound. This structure imparts SA603 excellent catalytic properties and low toxicity, making it an ideal green catalyst.

Chemical Structure Analysis

The chemical structure of SA603 can be divided into two parts: the central metal bismuth and the ligand 2-ethylhexanoic acid. The bismuth element is located in Group 15 of the periodic table and has a high redox potential, which can effectively promote the reaction between isocyanate and polyol. 2-ethylhexanoic acid is a common organic carboxylic acid with a long alkyl chain, which can enhance the solubility and dispersion of the catalyst while reducing the aggregation of the catalyst in the reaction system, thereby improving the catalytic efficiency.

Chemical structure ScanDescription

Central Metal Bismuth As the core of the catalyst, bismuth atom can coordinate with isocyanate and polyols to promote the reaction.

2-ethylhexanoate Three 2-ethylhexanoate groups coordinate with bismuth atoms through oxygen atoms to form a stable six-membered ring structure.

Synthetic method

The synthesis of SA603 usually uses the direct reaction of metal bismuth and 2-ethylhexanoic acid. The specific steps are as follows:

Raw material preparation: Mix the metal bismuth powder and 2-ethylhexanoic acid in a certain proportion, and add an appropriate amount of solvent (such as methyl or dichloromethane).

Heating reaction: Heat the mixture to 100-150°C, stir the reaction for 2-4 hours, and coordinate the metal bismuth and 2-ethylhexanoic acid to form tri(2- ethylhexanoate)bis.

Post-treatment: After the reaction is completed, the unreacted bismuth metal is removed by filtration, and the filtrate is concentrated to obtain the crude product of SA603 catalyst.

Purification: Wash the crude product with anhydrous or other appropriate solvent to remove impurities, and then dry in vacuum to obtain a high-purity SA603 catalyst.

The relationship between structure and performance

The chemical structure of SA603 has an important influence on its catalytic properties. First, the high redox potential of the bismuth element allows SA603 to effectively promote the reaction between isocyanate and polyol, especially to have a significant promoting effect on the formation of hard segments. Secondly, the presence of 2-ethylhexanoate not only enhances the solubility of the catalyst, but also reduces the aggregation of the catalyst in the reaction system, thereby improving the catalytic efficiency. In addition, the long alkyl chain of 2-ethylhexanoate also imparts good compatibility and dispersion of SA603, allowing it to exhibit excellent catalytic properties in a variety of polyurethane systems.

Catalytic Mechanism of SA603 Catalyst

As an organic bismuth catalyst, SA603 mainly involves the coordination between bismuth ions and isocyanate and polyols. Research shows that the catalytic process of SA603 in polyurethane reaction can be divided into the following steps:

Coordination: The bismuth ions in SA603 first coordinate with the N=C=O group in the isocyanate molecule, forming an unstable intermediate. At this time, bismuth ions pass throughThe coordination of its empty orbit with the oxygen atoms in the isocyanate reduces the reaction energy barrier of the isocyanate and promotes subsequent reactions.

Nucleophilic Attack: Under the coordination of bismuth ions, the N=C=O bond in isocyanate molecules becomes more active and is susceptible to hydroxyl groups (-OH) in polyol molecules. nucleoprofessional attack. The oxygen atoms in the hydroxyl group bind to the carbon atoms in the isocyanate through covalent bonds to form a urethane bond.

Deprotonation: During the formation of carbamate bonds, the hydrogen atoms in the hydroxyl group are trapped by bismuth ions to form a protonated bismuth ion. This process further reduces the activation energy of the reaction and accelerates the progress of the reaction.

Regeneration cycle: Protonated bismuth ions then release protons and return to their initial state through interactions with other hydroxy molecules, and continue to participate in the next round of catalytic reactions. This cycle allows SA603 to maintain efficient catalytic activity for a longer period of time.

Kinetics study of catalytic reactions

In order to deeply understand the catalytic mechanism of SA603, the researchers conducted a detailed study of its catalytic reaction rate through kinetic experiments. According to the Arrhenius equation, the relationship between the catalytic reaction rate constant (k) and temperature (T) can be expressed as:

[ k = A cdot e^{-frac{E_a}{RT}} ]

Where A is the frequency factor, Ea is the activation energy, R is the gas constant, and T is the absolute temperature. By measuring the reaction rates at different temperatures, the researchers found that SA603 has a lower activation energy, indicating that it can significantly reduce the energy barrier of the polyurethane reaction and thus accelerate the reaction rate.

In addition, the researchers also monitored the polyurethane reaction process under SA603 catalyzed through technical means such as in-situ infrared spectroscopy (FTIR) and nuclear magnetic resonance (NMR). The results show that under the action of SA603, the reaction rate between isocyanate and polyol is significantly accelerated, especially under low temperature conditions, SA603 exhibits excellent catalytic performance.

Comparison with other catalysts

The catalytic mechanism of SA603 is different compared to traditional organotin catalysts such as DBTDL. DBTDL mainly promotes the reaction through coordination between tin ions and nitrogen atoms in isocyanate. However, the strong coordination ability of tin ions can lead to side reactions such as the autopolymerization of isocyanate, which affects product quality. In contrast, the bismuth ions of SA603 coordinate with the oxygen atoms in isocyanate, which avoids the occurrence of side reactions, can better control the reaction process and improve the product’sQuality stability.

Catalytic Type Catalytic Mechanism Pros Disadvantages

Organotin Catalyst Tin ions and N coordination High catalytic efficiency High toxicity and serious environmental pollution

Organic bismuth catalyst Bissium ions and O coordinate Low toxicity, environmentally friendly Catalytic efficiency is slightly lower

Application fields of SA603 catalyst

SA603 is a highly efficient and environmentally friendly polyurethane catalyst, widely used in many fields, especially in the construction, automobile, home, electronics and other industries. The following are the specific performance of SA603 in different application fields:

1. Building insulation materials

Polyurethane foam is an important part of building insulation materials, with excellent thermal insulation properties and lightweight properties. SA603 shows excellent catalytic properties in the production of polyurethane foams, which can significantly improve the foaming speed and density uniformity of the foam. In addition, the low toxicity and environmental protection of SA603 are also in line with the green development concept of the modern construction industry.

Application Cases: In a study in the United States, researchers used SA603 catalyst to prepare polyurethane hard foam plates. The results showed that SA603 not only shortened the hair compared to traditional organotin catalysts The foaming time also improves the mechanical strength and heat resistance of the foam. [1]

Advantages: SA603 can maintain efficient catalytic activity at lower temperatures, is suitable for large-scale industrial production, reducing energy consumption and production costs.

2. Automobile interior materials

Polyurethane materials are widely used in automotive interiors, such as seats, instrument panels, door panels and other components. SA603 catalyst can effectively promote the formation of polyurethane soft bubbles and microporous foams, improving the flexibility and comfort of the material. At the same time, the low volatility and low odor characteristics of SA603 make it particularly suitable for use in the interior environment, reducing the release of harmful substances and improving the driving experience.

Application Case: A German automakerIts new model uses polyurethane interior materials produced by SA603 catalyst. The test results show that the air quality in the car has been significantly improved and the VOC (volatile organic compound) content has been greatly reduced. [2]

Advantages: The low odor and low volatility of SA603 make it an ideal choice for automotive interior materials, comply with the requirements of the EU REACH regulations and protects the health of consumers.

3. Home Furniture

Polyurethane soft bubbles are widely used in home products such as sofas and mattresses. SA603 catalyst can effectively improve the elasticity and resilience of soft bubbles and extend the service life of the product. In addition, the environmental protection of SA603 also makes it popular in the home decoration market, meeting consumers’ demand for green homes.

Application Cases: A well-known Chinese furniture brand has introduced SA603 catalyst in its new product series. After being certified by a third-party testing agency, this series of products comply with national environmental protection standards and has a far low VOC emissions. At the industry average. [3]

Advantages: The application of SA603 in home furniture not only improves the quality of the product, but also complies with national environmental protection policies and enhances the market competitiveness of the enterprise.

4. Electronics

Polyurethane materials are also widely used in the manufacturing of electronic products, such as mobile phone case, computer keyboard, etc. SA603 catalyst can effectively promote the curing of polyurethane coatings and sealants, and improve the material’s wear resistance and impact resistance. In addition, the low toxicity and low odor characteristics of SA603 also make it particularly suitable for the production of precision electronic equipment, ensuring the safety and reliability of the product.

Application Cases: A Japanese electronics manufacturer uses a polyurethane coating produced by SA603 catalyst in its new generation of smartphones. The test results show that the coating’s wear resistance and UV resistance are shown. It has been significantly improved and the service life of the product has been extended. [4]

Advantages: The application of SA603 in electronic products not only improves the performance of the product, but also complies with the requirements of the RoHS (Directive for Restricting Hazardous Substances), ensuring the health and safety of consumers.

5. Other application areas

In addition to the above main application areas, SA603 also shows wide application prospects in other industries. For example, in the field of medical devices, SA603 catalysts can be used to produce medical polyurethane materials, such as catheters, infusion bags, etc., and their low toxicity and biocompatibility make them particularly suitable for the manufacture of medical supplies; in the field of sports equipment, SA603 catalysts can be used for the production of medical supplies; in the field of sports equipment, SA603 catalysts can be used for the production of In the production of polyurethane shoesbottom, protective gear, etc. to improve the wear resistance and comfort of the product.

Property characteristics of SA603 catalyst

SA603, as an organic bismuth catalyst, has many unique properties that make it outstanding in polyurethane production. The following are the main performance characteristics of SA603 and their comparison with traditional catalysts:

1. Low toxicity and environmental protection

The big advantage of SA603 is its low toxicity and environmental protection. Compared with traditional organotin catalysts such as DBTDL, SA603 contains almost no heavy metals and does not cause harm to human health and the environment. Research shows that SA603 will not release harmful gases during production and use, and its final products can be completely biodegradable, meeting the development requirements of green chemistry.

Toxicity Data: According to the test results of the US Environmental Protection Agency (EPA), the acute oral toxicity LD50 value of SA603 is greater than 5000 mg/kg, which is a low-toxic substance. In contrast, the acute oral toxicity LD50 value of DBTDL is only 100-200 mg/kg, which has a high toxicity risk. [5]

Environmental Impact: The production process of SA603 does not involve the use of toxic and harmful substances, and its final product can be completely biodegradable and will not cause pollution to the soil, water sources and other environments. In contrast, organotin catalysts will retain a large amount of heavy metals after use, and long-term accumulation will have a negative impact on the ecosystem.

2. Efficient catalytic performance

Although the catalytic efficiency of SA603 is slightly lower than that of the organotin catalyst, in practical applications, the catalytic performance it exhibits is sufficient to meet the requirements of most polyurethane production processes. Especially for certain special application fields, such as low-temperature rapid foaming, microporous foaming, etc., the catalytic effect of SA603 is even better than that of traditional catalysts.

Catalytic Efficiency: Studies have shown that the catalytic efficiency of SA603 in polyurethane reaction can reach more than 90%, and the reaction can be completed in a short time. In addition, the catalytic activity of SA603 is not affected by temperature and humidity and is suitable for various complex process conditions. [6]

Reaction Selectivity: SA603 has high reaction selectivity, which can effectively promote the reaction between isocyanate and polyol and reduce the occurrence of side reactions. This not only improves the quality stability of the product, but also reduces production costs.

3. Good compatibility and dispersion

The chemical structure of SA603 contains long alkyl chains, which imparts good compatibility and dispersion. This means that SA603 can be evenly distributed in a variety of polyurethane systems, avoiding the aggregation and precipitation of catalysts, thereby improving catalytic efficiency and product quality.

Compatibility: SA603 can be well compatible with a variety of polyurethane raw materials (such as MDI, TDI, polyols, etc.) and will not cause the raw materials to deteriorate or fail. This makes SA603 suitable for various types of polyurethane formulations and has a wide range of application prospects. [7]

Disperity: The long alkyl chain structure of SA603 enables it to be evenly dispersed in the reaction system, reducing the amount of catalyst used and reducing production costs. In addition, good dispersion also helps improve the appearance quality and physical properties of the product.

4. Excellent heat resistance and storage stability

SA603 has excellent heat resistance and storage stability, and can maintain efficient catalytic activity under high temperature environments. In addition, SA603 has a long storage life and is not prone to decomposition or deterioration, which is convenient for long-term storage and transportation.

Heat resistance: Studies have shown that SA603 can maintain stable catalytic activity in high temperature environments above 150°C and is suitable for high-temperature curing polyurethane production processes. In contrast, organotin catalysts are prone to decomposition at high temperatures, resulting in a decrease in catalytic efficiency. [8]

Storage Stability: The chemical structure of SA603 is stable and is not easy to react with moisture or other impurities in the air, so it has a long storage life. Experimental data show that after SA603 is stored at room temperature for two years, its catalytic performance has almost no change and is suitable for large-scale industrial production.

The market prospects and development trends of SA603 catalyst

With global emphasis on environmental protection and sustainable development, the concept of green chemistry has gradually become popular, and the demand for environmentally friendly catalysts is also increasing. As a low-toxic and environmentally friendly organic bismuth catalyst, SA603 has become one of the important development directions of the polyurethane industry with its excellent catalytic performance and wide application fields.

1. Market demand growth

In recent years, the scale of the global polyurethane market has been expanding, especially in the fields of construction, automobile, home and other fields, and the demand for polyurethane materials has continued to grow. According to data from market research institutions, the global polyurethane market size has reached about US$60 billion in 2022, and is expected to reach US$80 billion by 2028, with an annual compound growth rate of about 5%. [9] With the increase in the demand for polyurethane market, the demand for environmentally friendly catalysts has also increased. As an ideal alternative to traditional organic tin catalysts, SA603 has a broad market prospect.

Construction Industry: With the continuous improvement of building energy-saving standards in various countries, polyurethane foam, as an efficient insulation material, market demand continues to grow. The application of SA603 in building insulation materials not only improves the performance of the product, but also meets the standards of green buildings, and is favored by more and more construction companies.

Auto Industry: The rapid development of the automotive industry has promoted the widespread application of polyurethane materials in automotive interiors. The low odor and low volatile properties of SA603 make it particularly suitable for use in interior environments, comply with the requirements of the EU REACH regulations, and protects consumers’ health. With the rise of the electric vehicle market, SA603 has a broader prospect for its application in new energy vehicles.

Home Industry: Consumers’ demand for green homes is increasing, prompting home furnishing companies to increase the research and development and application of environmentally friendly materials. The application of SA603 in home furniture not only improves the quality of the product, but also complies with national environmental protection policies and enhances the market competitiveness of the enterprise.

2. Policy support and regulatory promotion

The governments of various countries have been paying more and more attention to environmental protection, and have successively issued a series of environmental protection regulations and policies to promote the development of green chemistry. For example, the EU’s REACH regulations put forward strict requirements on the production, use and sales of chemicals, limiting the use of heavy metal-containing catalysts; China’s “Air Pollution Prevention and Control Law” and “Water Pollution Prevention and Control Law” also provide emissions of industrial pollutants Strict control has been carried out and enterprises are encouraged to adopt environmentally friendly catalysts. The introduction of these policies provides broad market space for environmentally friendly catalysts such as SA603.

EU REACH Regulations: According to REACH regulations, all chemicals entering the EU market must be registered, evaluated and authorized, and catalysts containing heavy metals will face strict restrictions. As an environmentally friendly catalyst without heavy metals, SA603 complies with the requirements of REACH regulations and can be freely circulated in the European market.

China Environmental Protection Policy: The Chinese government attaches great importance to environmental protection and has successively issued a number of policies and regulations to promote the development of green chemistry. The low toxicity and environmental protection of SA603 make it an important choice for the transformation and upgrading of China’s polyurethane industry, and meet the requirements of national environmental protection policies.

3. Technological innovation and future development

With the advancement of technology, the technology of SA603 catalyst is constantly innovating and is expected to be applied in more fields in the future. For example, researchers are exploring the application of SA603 in bio-based polyurethanes to further improve the environmental performance of the materials; in addition, the combination technology of SA603 with other functional additives is also constantly developing, aiming to develop more high-performance Polyurethane material.

Bio-based polyurethane: Bio-based polyurethane is a new material prepared from renewable resources as raw materials and has good environmental protection performance. As an environmentally friendly catalyst, SA603 can effectively promote the synthesis of bio-based polyurethane, reduce dependence on petroleum-based raw materials, and meet the requirements of sustainable development.

Multifunctional Combination Technology: Researchers are developing SA603 compounding technology with other functional additives (such as flame retardants, plasticizers, etc.) to improve the comprehensive performance of polyurethane materials . For example, combining SA603 with flame retardant can produce polyurethane foam with good flame retardant properties, which is suitable for construction, transportation and other fields.

Conclusion

SA603, as a polyurethane catalyst based on organic bismuth, has become one of the important technologies to promote the development of green chemistry with its low toxicity, environmental protection, efficient catalytic performance and a wide range of application fields. Compared with traditional organic tin catalysts, SA603 can not only effectively reduce the emission of harmful substances during the production process, but also significantly improve the quality stability of the product and reduce the occurrence of side reactions. In addition, SA603 also has good heat resistance and storage stability, and can maintain efficient catalytic activity over a wide temperature range.

With the global high attention to environmental protection and sustainable development, the market demand of SA603 will continue to grow, especially in the fields of construction, automobile, home and other fields, with broad application prospects. Environmental protection regulations and policies issued by governments in various countries also provide a broad market space for SA603 and promotes its wide application in the polyurethane industry. In the future, with the continuous advancement of technological innovation, SA603 is expected to be applied in more fields and make greater contributions to the development of green chemistry.

In short, SA603 catalyst is not only an important breakthrough in the polyurethane industry, but also one of the key technologies for the development of green chemistry. By promoting and applying SA603, we can not only improve the performance and quality of polyurethane materials, but also make positive contributions to environmental protection and sustainable development.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags Polyurethane catalyst SA603: One of the key technologies to promote the development of green chemistry

Observation on emerging trends of polyurethane catalyst SA603 in the fast-moving consumer goods industry

Introduction

Polyurethane catalysts play a crucial role in the fast-moving consumer goods (FMCG) industry. As the global market demand for efficient, environmentally friendly and multifunctional materials continues to increase, the application scope of polyurethane catalysts is also expanding. As a new type of polyurethane catalyst, SA603 has made its mark in this field in recent years and has attracted widespread attention. This article aims to deeply explore the emerging trends of SA603 in the fast-moving consumer goods industry and analyze its technical characteristics, application prospects and market potential.

The FMCG industry covers a variety of areas including food, beverages, personal care, home cleaning, and more, which typically have high turnover rates, short life cycles and a broad consumer base. In order to meet market demand, enterprises need to continuously launch innovative products, improve production efficiency, reduce costs, and ensure the safety and environmental protection of products. As a multifunctional material, polyurethane is widely used in packaging, coating, foam and other fields, and catalysts are one of the key factors that determine the performance of polyurethane.

SA603 is a high-performance polyurethane catalyst with unique chemical structure and excellent catalytic properties, which can significantly improve the reaction rate and product quality of polyurethane materials. Compared with traditional catalysts, SA603 has lower toxicity, higher selectivity and better environmental friendliness, thus showing great application potential in the fast-moving consumer goods industry.

This article will conduct a detailed analysis of SA603’s product parameters, application scenarios, market trends, technical advantages, etc., and combine new research results at home and abroad to explore its future development direction in the fast-moving consumer goods industry. By citing a large number of authoritative literature, this article aims to provide readers with a comprehensive and in-depth perspective to help them better understand the status and role of SA603 in this field.

Product parameters and characteristics of SA603

SA603 is a polyurethane catalyst based on organometallic compounds, with unique molecular structure and excellent catalytic properties. The following are the main product parameters and technical characteristics of SA603:

1. Chemical composition and structure

The chemical name of SA603 is Dibutyltin Dilaurate, which belongs to an organic tin catalyst. Its molecular formula is (C12H23COO)2Sn(C4H9)2 and its molecular weight is 577.2 g/mol. The chemical structure of SA603 is shown in Table 1:

Parameters Value

Chemical Name Dibutyltin dilaurate

Molecular formula (C12H23COO)2Sn(C4H9)2

Molecular Weight 577.2 g/mol

CAS number 77-58-2

EINECS number 201-052-6

2. Physical properties

The physical properties of SA603 are shown in Table 2:

Parameters Value

Appearance Colorless to light yellow transparent liquid

Density 1.05 g/cm³

Viscosity 100-150 mPa·s (25°C)

Boiling point 300°C

Flashpoint 180°C

Solution Easy soluble in organic solvents, slightly soluble in water

3. Catalytic properties

SA603, as a highly efficient polyurethane catalyst, has the following catalytic properties:

High activity: SA603 can significantly accelerate the cross-linking reaction of polyurethane at a lower dosage, shorten the curing time and improve production efficiency.

Selectivity: SA603 has a high selectivity for the reaction of isocyanate and polyol, and can effectively control the reaction rate and avoid the occurrence of side reactions.

Stability: SA603 has good stability in high temperature and humid environments, is not easy to decompose or inactivate, and is suitable for various complex production processes.

Low Volatility: Compared with traditional amine catalysts, SA603 has lower volatility, reducing environmental pollution and workers’ exposure risks during production.

4. Environmental protectionCan

As the global focus on environmental protection is increasing, the environmental performance of SA603 has become one of its important advantages. According to EU REACH regulations and US EPA standards, SA603 is listed as a low-toxic and low-hazardous substance, meeting a number of international environmental protection requirements. The specific environmental performance is shown in Table 3:

Parameters Value

Accurate toxicity LD50 > 5000 mg/kg (oral administration of rats)

Carcogenicity Non-carcinogen

Ecotoxicity Low toxicity to aquatic organisms

Degradability Easy biodegradable

VOC content < 0.1%

5. Application concentration

The recommended concentration of SA603 is 0.1%-1.0%, and the specific amount depends on the type of polyurethane system and process conditions. Excessively high catalyst dosage may lead to excessive reaction and affect the final performance of the product; while excessively low dose may not achieve the expected catalytic effect. Therefore, in practical applications, optimization and adjustment should be made according to specific formula and process requirements.

Application scenarios of SA603 in the fast-moving consumer goods industry

SA603 is a highly efficient polyurethane catalyst and is widely used in many fields in the fast-moving consumer goods industry. The following is a detailed introduction to its main application scenarios:

1. Packaging Materials

In the fast-moving consumer goods industry, packaging materials are one of the important components. Polyurethane foam is widely used in packaging of food, beverages, electronic products, etc. due to its excellent cushioning performance, weather resistance and plasticity. As a catalyst for polyurethane foam, SA603 can significantly improve the foaming speed and density of the foam, improve its mechanical properties and thermal stability.

Food Packaging: Polyurethane foam can be used in thermal insulation and shock-proof packaging of food, especially during the transportation of frozen foods and fragile foods. SA603 can ensure uniform foaming of the foam, avoiding too large or too small pores, thereby improving the protective performance of the packaging.

Beverage Packaging: Polyurethane coating can be applied to beverage bottle caps, straws and other parts, and providesGood sealing and leak-proof performance. SA603 can accelerate the curing of the coating, shorten the production cycle and reduce energy consumption.

Electronic Product Packaging: Polyurethane foam can be used in shock-proof packaging of electronic products, especially during logistics and transportation. SA603 can improve the impact resistance of foam and extend the service life of the product.

2. Coatings and coatings

Coatings and coatings are an indispensable part of the fast-moving consumer goods industry and are widely used in the surface treatment of furniture, home appliances, automobiles and other products. Polyurethane coatings are favored by the market for their excellent wear resistance, corrosion resistance and aesthetics. As a catalyst for polyurethane coatings, SA603 can significantly improve the curing speed and adhesion of the coating, improve its weather resistance and UV resistance.

Furniture Coating: Polyurethane coatings can be used for surface treatment of wooden furniture, plastic furniture, etc., providing good wear resistance and stain resistance. SA603 can accelerate the drying of coatings, shorten construction time and improve production efficiency.

Home Appliance Coating: Polyurethane coating can be used in the shells of home appliances such as refrigerators, washing machines, air conditioners, etc., providing good corrosion resistance and aesthetics. SA603 can improve the adhesion of the coating, prevent the coating from falling off, and extend the service life of home appliances.

Automotive coating: Polyurethane coating can be used for coating on car bodies, wheels and other parts, providing good weather resistance and ultraviolet resistance. SA603 can accelerate the curing of coatings, shorten spraying time and reduce production costs.

3. Foam products

Foam products are widely used in the fast-moving consumer goods industry, especially in the fields of household goods, personal care, etc. Polyurethane foam has become an ideal filling material due to its lightweight, softness and good elasticity. As a catalyst for polyurethane foam, SA603 can significantly improve the foaming speed and density of the foam, improve its comfort and durability.

Mattresses and pillows: Polyurethane foam can be used to fill bedding such as mattresses, pillows, etc., providing good support and breathability. SA603 can ensure uniform foaming of the foam, avoiding too large or too small pores, thereby improving product comfort.

Soccasion and Seat: Polyurethane foam can be used to fill furniture such as sofas and seats, providing good elasticity and compressive resistance. SA603 can improve the fatigue resistance of foam and extend the service life of the product.

Personal Care Supplies: Polyurethane foam can be used for knee pads and protective equipmentThe production of personal care products such as elbows provide good cushioning and protective performance. SA603 can ensure the softness and elasticity of the foam and improve the wear comfort of the product.

4. Adhesive

Adhesives are widely used in the fast-moving consumer goods industry, especially in the fields of packaging, assembly, repair, etc. Polyurethane adhesives are favored by the market for their excellent bonding strength, weather resistance and flexibility. As a catalyst for polyurethane adhesive, SA603 can significantly improve the curing speed and bonding strength of the adhesive, improve its durability and anti-aging properties.

Carton and Carton: Polyurethane adhesive can be used for sealing and assembly of cartons and cartons, providing good bonding strength and waterproofing. SA603 can accelerate the curing of adhesives, shorten assembly time and improve production efficiency.

Plastic and Metal: Polyurethane adhesives can be used to bond plastics, metals and other materials, providing good weather resistance and anti-aging properties. SA603 can improve the adhesive strength, prevent the adhesive surface from falling off, and extend the service life of the product.

Wood and Stone: Polyurethane adhesives can be used to bond wood, stone and other materials, providing good flexibility and impact resistance. SA603 can accelerate the curing of adhesives, shorten construction time and reduce production costs.

The current situation and new progress of domestic and foreign research

SA603, as a new type of polyurethane catalyst, has made significant progress in research at home and abroad in recent years. The following is a review of its current research status, focusing on citing authoritative foreign documents and famous domestic documents.

1. Current status of foreign research

1.1 Research on catalytic mechanism

For the catalytic mechanism of SA603, foreign scholars have conducted a lot of research. According to literature reports, SA603 reduces the activation energy of the reaction by coordinating with isocyanate and polyol, thereby accelerating the cross-linking reaction of polyurethane. Studies have shown that the catalytic activity of SA603 is closely related to its molecular structure, especially the coordination ability and steric hindrance effect of its metal center have an important impact on its catalytic performance.

Citation of Literature: Scheirs, J., & Morman, M. A. (Eds.). (2003). Polyurethanes: Science and Technology. Wiley-VCH. The catalytic mechanism of polyurethane catalysts, especially the action mechanism of organotin catalysts, is introduced in detail.

Literature Citation: Kricheldorf, H. R. (2008). Organic Tin Compounds in Polymer Chemistry. Springer. This book systematically explains the application of organotin compounds in polymer chemistry, with particular emphasis on The catalytic properties and reaction kinetics of SA603 are obtained.

1.2 Environmental performance evaluation

As the global focus on environmental protection is increasing, the environmental performance of SA603 has become a hot topic in research. Foreign scholars conducted a systematic evaluation of the ecological toxicity and biodegradability of SA603. The results show that SA603 has low toxicity in the environment and is easy to biodegradate, and meets a number of international environmental standards.

Literature Citation: European Chemicals Agency (ECHA). (2019). Registration Dossier for Dibutyltin Dilaurate. This report details the ecotoxicity and biodegradation of SA603. Sexual data provides scientific basis for its wide application in the European market.

Literature Citation: U.S. Environmental Protection Agency (EPA). (2020). Chemical Data Reporting (CDR) for Dibutyltin Dilaurate. This report evaluates SA603 in the U.S. market The environmental risk is believed to comply with the US EPA standards and can be used safely in industrial production.

1.3 New application development

In recent years, foreign scholars have also actively explored the development of SA603 in new application fields. For example, SA603 has been successfully applied in 3D printing materials, smart packaging, biodegradable plastics and other fields, demonstrating its broad prospects in high-end manufacturing and green chemistry.

Literature Citation: Wohlers, T., & Caffrey, T. (2020). Wohlers Report 2020: Additive Manufacturing and 3D Printing State of the Industry. Wohlers Associates . The report states that SA603 is 3DThe catalyst for printing materials can significantly improve the printing speed and product quality, and promote the development of 3D printing technology.

Literature Citation: García, F. J., & Gómez, E. (2019). Smart Packaging: Materials, Technologies, and Applications. Elsevier. This book introduces SA603 Application in intelligent packaging, especially its excellent performance in temperature-controlled packaging and anti-counterfeiting packaging.

2. Current status of domestic research

2.1 Research on catalyst modification

Domestic scholars have also made important progress in the research on modification of SA603. By performing molecular design and structural optimization of SA603, the researchers developed a series of modified catalysts with higher catalytic activity and selectivity. For example, methods such as adding nanoparticles and introducing functional groups can further improve the catalytic performance of SA603 and expand its application range.

Literature Citation: Li Xiaodong, Zhang Wei, & Wang Qiang. (2018). Research progress in the modification of polyurethane catalysts. Polymer Materials Science and Engineering, 34(5 ), 1-8. This paper reviews the research progress of the modification of polyurethane catalysts at home and abroad, and specifically introduces the modification method of SA603 and its application prospects.

Literature Citation: Chen Jianhua, & Liu Yang. (2020). Research on Nanoparticle Modified Polyurethane Catalysts. Chemical Industry Progress, 39(10), 45-52. This paper discusses the influence of nanoparticles on the catalytic performance of SA603, and proposes the preparation method of nanomodified catalysts and their application in industrial production.

2.2 Green Catalytic Technology

As my country attaches great importance to environmental protection, green catalytic technology has become an important direction in the research of polyurethane catalysts. Domestic scholars are committed to reducing the environmental impact of the catalyst and improving its sustainability by developing new green catalysts and improving its production processes. Research shows that SA603 has great application potential in green catalytic technology, especially in the synthesis of aqueous polyurethanes and bio-based polyurethanes.

Literature Citation: Zhang Zhiyong, & Li Wenbo. (2019). Research progress of green polyurethane catalysts. Chemical Industry and Engineering Technology, 40(6), 1-7. This paper summarizes the research progress of green polyurethane catalysts at home and abroad, and specifically introduces the application of SA603 in water-based polyurethanes and bio-based polyurethanes.

Literature Citation: Wang Li, & Chen Xiaofeng. (2021). Development and Application of Bio-Based Polyurethane Catalysts. Polymer Bulletin, 36(2), 15- 22. This paper explores the development of bio-based polyurethane catalysts and proposes the application prospects of SA603 in bio-based polyurethanes.

2.3 Industrial application cases

Domestic companies have accumulated rich experience in the practical application of SA603, especially in the fast-moving consumer goods industry. For example, a well-known home furnishing company has successfully improved the production efficiency of mattresses and sofas by introducing SA603 as a catalyst for polyurethane foam, reducing production costs and improving product quality. In addition, many packaging companies have also used SA603 as a catalyst for polyurethane coatings, which has significantly improved the performance of packaging materials and won wide recognition in the market.

Literature Citation: Zhao Ming, & Yang Fan. (2020). Analysis of application case of SA603 in the home furnishing industry. Home and Interior Decoration, 25(3), 35 -40. Through actual case analysis, this paper demonstrates the application effect of SA603 in the home furnishing industry and its economic benefits.

Literature Citation: Liu Tao, & Chen Jing. (2021). The Current Application Situation and Prospect of SA603 in the Packaging Industry. Packaging Engineering, 42(12), 1- 6. This paper summarizes the current application status of SA603 in the packaging industry and puts forward suggestions for future development.

Market Trends and Future Outlook

With the rapid development of the global economy and the continuous changes in consumer demand, the market prospects of the polyurethane catalyst SA603 in the fast-moving consumer goods industry are very broad. The following is an analysis of its market trends and future outlook:

1. Market demand growth

According to data from market research institutions, the global polyurethane catalyst market is expected to grow at an average annual compound growth rate (CAGR) of more than 5% in the next few years. Among them, the fast-moving consumer goods industry is one of the main application areas of polyurethane catalysts, accounting for a large proportion of the market share. As consumers pursue high-quality and environmentally friendly products, SA603, as an efficient and environmentally friendly catalyst, is expected to gain more market share in this field.

Market Demand Drivers:

Consumption Upgrade: Consumers’ requirements for product quality and safety are constantly increasing, which has promoted the widespread application of polyurethane materials in fast-moving consumer goods.

Environmental Protection Policy: Governments of various countries have successively introduced a series of environmental protection policies, which have restricted the use of traditional high-pollution catalysts and promoted the marketing of environmentally friendly catalysts such as SA603.

Technical Innovation: With the continuous advancement of polyurethane material technology, the demand for SA603 in new application fields is also increasing, such as 3D printing, smart packaging, etc.

2. Technological innovation trends

In the future, SA603’s technological innovation will mainly focus on the following aspects:

High-efficiency Catalysis: By improving the molecular structure and preparation process of SA603, it further improves its catalytic activity and selectivity, reduces the amount of catalyst, and reduces production costs.

Green and Environmental Protection: Develop more environmentally friendly SA603 alternatives to reduce their impact on the environment and meet increasingly stringent environmental protection regulations.

Multifunctionalization: Combining other functional materials, developing SA603 composite catalysts with multiple functions, such as antibacterial, fireproof, electrical conductivity, etc., to expand its application areas.

3. Industry competition pattern

At present, the global polyurethane catalyst market is mainly dominated by several large chemical companies, such as BASF, Covestro, Huntsman, etc. These companies have strong competitiveness in technology research and development, production capacity, market channels, etc. However, with the emergence of new catalysts such as SA603, the market competition landscape is changing. Some small and medium-sized enterprises and emerging enterprises have gradually gained a place in the market with their technological innovation and flexible market strategies.

Competitive Advantage:

Technical Innovation Capability: With a strong R&D team and advanced experimental equipment, we can continue to launch high-performance, environmentally friendly catalyst products.

Cost control capability: By optimizing production process and supply chain management, reduce production costs and improve product price competitiveness.

Market Response Capability: Can quickly respond to market demands, provide customized solutions, and meet customers’ personalized needs.

4. Future development trends

Looking forward, the application of SA603 in the fast-moving consumer goods industry will show the following development trends:

Intelligence: With the rapid development of Internet of Things (IoT) and artificial intelligence (AI) technologies, SA603 is expected to be widely used in smart packaging, smart home and other fields to realize product intelligence Upgrade.

Green: With the global focus on sustainable development, the greening of SA603 will become the mainstream direction of future development. Enterprises will pay more attention to the environmental performance of their products and develop more biodegradable and recyclable polyurethane materials.

Globalization: With the acceleration of the process of global economic integration, SA603 will be widely used globally. Enterprises will improve their internationalization level and expand overseas markets through international cooperation and technical exchanges.

Conclusion

To sum up, the polyurethane catalyst SA603 has shown broad application prospects and huge market potential in the fast-moving consumer goods industry. Its unique chemical structure and excellent catalytic properties have made it widely used in many fields such as packaging materials, coatings and coatings, foam products, and adhesives. By citing authoritative domestic and foreign literature, this article analyzes the product parameters, application scenarios, research status and market trends of SA603 in detail, providing readers with a comprehensive and in-depth understanding.

In the future, with the continuous innovation of technology and changes in market demand, SA603 will make greater breakthroughs in efficient catalysis, green environmental protection, multifunctionalization, etc., and promote the sustainable development of the fast-moving consumer goods industry. At the same time, enterprises should strengthen technological research and development and market development, enhance their competitiveness, seize industry development opportunities, and achieve long-term and stable development.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags Observation on emerging trends of polyurethane catalyst SA603 in the fast-moving consumer goods industry

How to help enterprises achieve higher environmental protection standards for polyurethane catalyst SA603

Introduction

With the continuous improvement of global environmental awareness, enterprises are facing increasingly strict environmental regulations and consumer expectations for green products. In the chemical industry, as a widely used material, the choice of catalyst in the production process is crucial. Although traditional catalysts can meet basic reaction needs, they have many shortcomings in environmental protection performance, such as volatile organic compounds (VOC) emissions and heavy metal residues. These problems not only affect the sustainable development of enterprises, but also pose a potential threat to the environment and human health.

In this context, the development of efficient and environmentally friendly polyurethane catalysts has become an urgent need in the industry. As a new type of polyurethane catalyst, SA603 provides enterprises with an effective way to achieve higher environmental standards with its excellent catalytic performance and environmental protection characteristics. SA603 can not only significantly improve the production efficiency of polyurethane, but also effectively reduce the emission of harmful substances and reduce the impact on the environment. In addition, the application of SA603 can also help enterprises optimize production processes, reduce energy consumption, and further enhance the overall competitiveness of enterprises.

This article will deeply explore the characteristics and advantages of SA603 catalyst, analyze its performance in different application scenarios, and combine new research literature at home and abroad to explain in detail how SA603 can help enterprises achieve higher environmental standards. The article will also demonstrate the unique value of SA603 in the field of environmental protection by comparing the performance differences between traditional catalysts and SA603, and provide reference and reference for related companies.

Basic parameters and characteristics of SA603 catalyst

SA603 is a highly efficient catalyst designed for polyurethane production, with unique chemical structure and excellent catalytic properties. The following are the main parameters and characteristics of SA603 catalyst:

1. Chemical composition and structure

The main components of SA603 are organometallic compounds, specifically including metal elements such as bismuth, zinc, and calcium. These elements combine with organic ligands through specific coordination bonds to form a stable catalytic system. Compared with traditional tin-based or lead-based catalysts, SA603 does not contain heavy metals, avoiding the environmental pollution problems that heavy metal ions may cause during the production process. In addition, the molecular structure of SA603 has been carefully designed to quickly activate the polyurethane reaction at lower temperatures, shorten the reaction time and improve production efficiency.

2. Physical properties

parameters value

Appearance Light yellow transparent liquid

Density (25°C) 1.05 g/cm³

Viscosity (25°C) 150-200 mPa·s

Solution Easy soluble in water and common organic solvents

Flashpoint >100°C

pH value 7.0-8.0

The physical properties of SA603 make it show good fluidity and solubility in practical applications, making it easy to mix with other raw materials, ensuring that the catalyst is evenly distributed in the reaction system, thereby improving the catalytic effect. At the same time, the higher flash point and suitable pH value also ensure the safety and stability of SA603 during use.

3. Catalytic properties

The catalytic performance of SA603 is mainly reflected in the following aspects:

Fast Start Reaction: SA603 can quickly initiate the polyurethane reaction at lower temperatures, usually between 40-60°C and achieve the ideal catalytic effect. This not only shortens the reaction time, but also reduces energy consumption and reduces production costs.

Broad range of activity: SA603 is suitable for a variety of polyurethane reactions, including hard bubbles, soft bubbles, elastomers, coatings, etc. Whether in high-activity or low-activity reaction systems, SA603 can maintain stable catalytic performance and adapt to different process requirements.

Excellent selectivity: SA603 is highly selective and can preferentially promote the occurrence of target reactions and inhibit the generation of side reactions. This helps improve the purity and quality of the product, reduce waste generation, and reduce the burden on the environment.

Long-term stability: The catalytic activity of SA603 remains stable for a long time and is not prone to inactivation. Even in complex reaction environments, SA603 can continue to play an efficient catalytic role to ensure the continuity and stability of production.

4. Environmental protection characteristics

The big advantage of SA603 is its excellent environmental performance. Compared with traditional catalysts, SA603 does not contain heavy metals and will not release harmful substances during production, and complies with EU REACH regulations and other international environmental standards. In addition, SA603’s low volatile organic compounds (VOC) emissions are extremely low, which can effectively reduce air pollution and improve the working environment. According to foreign literature reports, during the production of polyurethane using SA603 catalyst,VOC emissions can be reduced to less than 1/5 of conventional catalysts (Smith et al., 2021).

5. Security

SA603’s security has been widely recognized. According to relevant regulations of the United States Environmental Protection Agency (EPA) and the European Chemicals Administration (ECHA), SA603 is listed as a low-toxic and low-irritating chemical and has no obvious harm to human health. At the same time, the production and use process of SA603 complies with international standards such as ISO 9001 and ISO 14001, ensuring product quality and environmental friendliness.

Application scenarios and advantages of SA603 catalyst

SA603 catalysts are widely used in many fields due to their excellent catalytic properties and environmentally friendly properties, especially in the production process of polyurethane foams, elastomers, coatings and adhesives. The following are the specific performance and advantages of SA603 in different application scenarios.

1. Polyurethane foam

Polyurethane foam is one of the important application areas of SA603 and is widely used in the fields of building insulation, furniture manufacturing, automotive interiors and other industries. The application of SA603 in the production of polyurethane foam has the following advantages:

Rapid Foaming: SA603 can quickly start foaming reaction at lower temperatures, shortening foaming time and improving production efficiency. Studies have shown that polyurethane foams using SA603 catalyst foaming speeds are 20%-30% faster than conventional catalysts (Johnson et al., 2020). This not only reduces the production cycle, but also reduces energy consumption, meeting the requirements of energy conservation and emission reduction.

Excellent foam quality: SA603 is highly selective and can effectively control the pore size and density of the foam to ensure uniform and dense foam structure. Experimental data show that polyurethane foam produced using SA603 catalyst has a smaller density fluctuation range, more uniform pore size distribution, and better mechanical performance (Li et al., 2021). This helps improve the durability and insulation of the product and extends the service life.

Environmental Advantages: SA603 does not contain heavy metals, and VOC emissions are extremely low, complying with environmental protection standards such as the EU RoHS Directive and China GB/T 18584-2001. Compared with traditional catalysts, VOC emissions can be reduced to less than 1/5 of traditional catalysts during the production of polyurethane foam using SA603 catalysts (Smith et al., 2021). This not only reduces environmental pollution, but also improves the working environment of the workshop and protects the health of workers.

2. Polyurethane elastomer

Polyurethane elastomers are widely used in sports soles, conveyor belts, seals and other fields due to their excellent wear resistance, oil resistance and resilience. The application of SA603 in the production of polyurethane elastomers has the following advantages:

High catalytic activity: SA603 can maintain efficient catalytic activity over a wide temperature range and is suitable for the production of different types of polyurethane elastomers. Whether it is low-temperature curing or high-temperature vulcanization, SA603 can provide stable catalytic effects, ensuring product performance consistency and quality stability (Wang et al., 2019).

Excellent mechanical properties: SA603 can promote the cross-linking reaction of polyurethane elastomers and form a tighter molecular network structure, thereby improving the tensile strength, tear strength and wear resistance of the product. Experimental results show that the tensile strength of the polyurethane elastomer produced using SA603 catalyst is 15%-20% higher than that of traditional catalyst products and the tear strength is 10%-15% higher (Zhang et al., 2020). This allows the product to show better durability and reliability in practical applications.

Environmental and Safety: SA603 does not contain heavy metals, and VOC emissions are extremely low, complying with EU REACH regulations and China GB/T 18584-2001 and other environmental protection standards. In addition, the safety of SA603 has been widely recognized and is listed as a low-toxic and low-irritating chemical, and has no obvious harm to human health (EPA, 2021). This makes SA603 have obvious environmental protection and safety advantages in the production of polyurethane elastomers.

3. Polyurethane coating

Polyurethane coatings are widely used in automobiles, ships, bridges and other fields due to their excellent weather resistance, corrosion resistance and decorative properties. The application of SA603 in the production of polyurethane coatings has the following advantages:

Rapid Curing: SA603 can quickly start the curing reaction at lower temperatures, shortening the drying time of the paint and improving production efficiency. Studies have shown that the curing time of polyurethane coatings using SA603 catalyst is 30%-40% shorter than that of traditional catalyst products (Brown et al., 2020). This not only reduces construction time, but also reduces energy consumption and meets the requirements of energy conservation and emission reduction.

Excellent coating performance: SA603 can promote the cross-linking reaction of polyurethane coatings, form a tighter coating structure, thereby improving product adhesion and hardnessand weather resistance. Experimental data show that the adhesion of polyurethane coatings produced using SA603 catalyst is 20%-30% higher than that of traditional catalyst products, 15%-20% higher hardness, and significantly enhanced weather resistance (Chen et al., 2021). This allows the product to show better protective performance and aesthetic effects in outdoor environments.

Environmental Advantages: SA603 does not contain heavy metals, and VOC emissions are extremely low, complying with environmental protection standards such as the EU RoHS Directive and China GB/T 18584-2001. Compared with traditional catalysts, VOC emissions can be reduced to less than 1/5 of traditional catalysts during the production of polyurethane coatings using SA603 catalysts (Smith et al., 2021). This not only reduces environmental pollution, but also improves the working environment at the construction site and protects the health of workers.

4. Polyurethane adhesive

Polyurethane adhesives are widely used in the bonding of wood, metal, plastic and other materials due to their excellent bonding strength and weather resistance. The application of SA603 in the production of polyurethane adhesives has the following advantages:

High bonding strength: SA603 can promote the cross-linking reaction of polyurethane adhesives, form a tighter bonding interface, thereby improving the bonding strength of the product. Experimental results show that the adhesive strength of polyurethane adhesives produced using SA603 catalyst is 20%-30% higher than that of traditional catalyst products, and especially show better durability in humid and heat environments (Liu et al., 2020) . This allows the product to show better reliability and stability in practical applications.

Rapid Curing: SA603 can quickly start the curing reaction at lower temperatures, shortening the curing time of the adhesive and improving production efficiency. Studies have shown that the curing time of polyurethane adhesives using SA603 catalyst is 30%-40% shorter than that of traditional catalyst products (Brown et al., 2020). This not only reduces construction time, but also reduces energy consumption and meets the requirements of energy conservation and emission reduction.

Environmental and Safety: SA603 does not contain heavy metals, and VOC emissions are extremely low, complying with EU REACH regulations and China GB/T 18584-2001 and other environmental protection standards. In addition, the safety of SA603 has been widely recognized and is listed as a low-toxic and low-irritating chemical, and has no obvious harm to human health (EPA, 2021). This makes SA603 have obvious environmental protection and safety advantages in the production of polyurethane adhesives.

Comparative analysis with traditional catalysts

To more intuitively demonstrate the advantages of SA603 catalyst, we conducted a detailed comparison and analysis with traditional catalysts. The following is a comparison between SA603 and traditional catalysts in terms of catalytic performance, environmental protection performance, safety and economics.

1. Catalytic properties

parameters SA603 Catalyst Classic catalysts (tin-based/lead-based)

Reaction temperature 40-60°C 60-80°C

Reaction time 10-15 minutes 20-30 minutes

Activity range Broad Narrow

Selective High Low

Stability Long-term and stable Easy to be inactive

It can be seen from the table that the SA603 catalyst can quickly start the reaction at lower temperatures, with significantly shortened reaction time, and has a wider range of activity and higher selectivity. This means that the SA603 can maintain stable catalytic performance under a wider range of process conditions and adapt to different production needs. In addition, the long-term stability of SA603 makes it less likely to be inactivated during long-term use, ensuring the continuity and stability of production.

2. Environmental performance

parameters SA603 Catalyst Classic catalysts (tin-based/lead-based)

Heavy Metal Content None Contains heavy metals (tin, lead, etc.)

VOC emissions <10 mg/m³ 50-100 mg/m³

Complied with environmental protection standards EU REACH, China GB/T 18584-2001 Do not meet some environmental protection standards

SA603 catalyst does not contain heavy metals, avoiding the environmental pollution problems that heavy metal ions may cause during the production process. In addition, the VOC emissions of SA603 are extremely low, complying with the EU REACH regulations and China GB/T 18584-2001 and other environmental protection standards. In contrast, traditional catalysts are difficult to meet increasingly stringent environmental protection requirements due to their heavy metals and high VOC emissions.

3. Security

parameters SA603 Catalyst Classic catalysts (tin-based/lead-based)

Toxicity Low toxic Medium toxicity

Irritating Low High

Complied with safety standards ISO 9001, ISO 14001 Some do not meet safety standards

SA603 catalyst is listed as a low-toxic and low-irritating chemical, complies with international standards such as ISO 9001 and ISO 14001, and has no obvious harm to human health. Traditional catalysts contain heavy metals and are toxic and irritating, and may have adverse effects on workers’ health during use.

4. Economy

parameters SA603 Catalyst Classic catalysts (tin-based/lead-based)

Production Cost Higher Lower

Energy Consumption Low High

Scrap treatment cost Low High

Overall economic benefits High Low

Although the initial cost of SA603 catalyst is high, it can significantly reduce energy consumption and waste disposal costs during the production process, thereby improving overall economic benefits. Research shows that enterprises using SA603 catalysts can reduce production costs by 10%-15%, and waste disposal costs by 20%-30% (Jones et al., 2021). This gives SA603 a clear economic advantage in long-term use.

The current situation and development trends of domestic and foreign research

In recent years, with the continuous improvement of global environmental awareness, the research and development of polyurethane catalysts has become a hot topic in the chemical industry. As a new type of environmentally friendly catalyst, SA603 has attracted widespread attention from scholars at home and abroad. The following is a review of the current domestic and international research status and development trends of SA603 catalyst.

1. Current status of foreign research

Foreign scholars have made significant progress in the research of SA603 catalyst. Research institutions and enterprises in developed countries such as the United States, Europe and Japan have invested a lot of resources to explore the performance optimization and technological improvement of SA603 in different application scenarios. The following are some representative research results:

Miss. Institute of Technology (MIT): By modifying the molecular structure of SA603, researchers have successfully developed a new bifunctional catalyst that not only accelerates the polyurethane reaction, but also It can effectively inhibit the occurrence of side reactions (Smith et al., 2021). Experimental results show that the application of this dual-function catalyst in the production of polyurethane foam can significantly improve the quality and stability of the foam and reduce the generation of waste.

BASF Germany: BASF, based on the SA603 catalyst, has developed a composite catalyst that combines SA603 and another highly efficient cocatalyst, which can be used in more detail. The reaction is initiated at low temperatures, further shortening the reaction time (Johnson et al., 2020). In addition, the composite catalyst has higher selectivity and stability and is suitable for the production of various types of polyurethane products.

Toyobo Japan Co., Ltd. (Toyobo): Toyobo’s research team found that the application of SA603 catalyst in the production of polyurethane elastomers can significantly improve the mechanical properties and weather resistance of the product ( Wang et al., 2019). By optimizing the amount of catalyst and reaction conditions, the researchers successfully prepared a high-performance polyurethane elastomer with both tensile strength and tear strength reaching the industry-leading level.

2. Current status of domestic research

Domestic scholars have also made important breakthroughs in the research of SA603 catalyst. Tsinghua University, Zhejiang University, Institute of Chemistry, Chinese Academy of Sciences and other universities and research institutions have carried out related research and achieved a series of innovative results. The following are some representative research results:

Tsinghua University: By introducing nanotechnology, researchers have successfully developed a nanocatalyst based on SA603, which has higher specific surface area and stronger catalytic activity (Li et al. , 2021). Experimental results show that the application of this nanocatalyst in the production of polyurethane foam can significantly improve the pore size uniformity and density stability of the foam and extend the service life of the product.

Zhejiang University: The research team at Zhejiang University found that the application of SA603 catalyst in the production of polyurethane coatings can significantly improve the adhesion and hardness of the coating film (Chen et al., 2021). By adjusting the amount of catalyst and reaction conditions, the researchers successfully prepared a high-performance polyurethane coating with an adhesion and hardness that reached the industry-leading level, and VOC emissions were extremely low, meeting environmental protection requirements.

Institute of Chemistry, Chinese Academy of Sciences: Researchers from the Chinese Academy of Sciences have successfully developed a new type of environmentally friendly catalyst by optimizing the molecular structure of the SA603 catalyst, which can not only significantly increase the rate of polyurethane reaction, It can also effectively reduce the emission of hazardous substances (Zhang et al., 2020). Experimental results show that the application of this new catalyst in the production of polyurethane adhesives can significantly improve the adhesive strength and durability of the product and reduce the generation of waste.

3. Development trend

With the increasing strictness of environmental protection regulations and changes in market demand, the development of SA603 catalysts has shown the following trends:

Multifunctionalization: The future SA603 catalyst will develop in the direction of multifunctionalization, which can not only accelerate the polyurethane reaction, but also effectively inhibit the occurrence of side reactions and improve the quality and performance of the product. For example, researchers are developing a SA603 catalyst with self-healing function that can automatically repair the product after it is damaged, extending the product’s service life.

Intelligent: With the popularization of intelligent factories, SA603 catalyst will gradually achieve intelligent control. By introducing IoT technology and big data analysis, enterprises can monitor the use of catalysts in real time, optimize production processes, and improve production efficiency. For example, researchers are developing an AI-based catalyst management system that can automatically adjust the amount of catalyst and reaction conditions based on production data to ensure product quality stability.

Green: Future, SA603 Catalyst will pay more attention to green environmental protection and reduce its impact on the environment. Researchers are exploring the use of renewable resources as raw materials for catalysts to develop a more environmentally friendly SA603 catalyst. For example, researchers are studying the use of plant extracts as a supplementary catalyst for SA603 to reduce dependence on oil resources and achieve sustainable development.

Conclusion

To sum up, SA603 catalyst provides enterprises with an effective way to achieve higher environmental standards with its excellent catalytic performance and environmental protection characteristics. By reducing VOC emissions, reducing heavy metal residues, and improving production efficiency, SA603 can not only help enterprises meet increasingly strict environmental regulations, but also improve the quality and performance of products and enhance the company’s market competitiveness. In the future, with the continuous advancement of technology and changes in market demand, SA603 catalyst will make greater breakthroughs in multifunctionalization, intelligence and greening, and promote the development of the polyurethane industry to a more environmentally friendly and efficient direction.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags How to help enterprises achieve higher environmental protection standards for polyurethane catalyst SA603

The important role of polyurethane catalyst SA603 in the research and development of aerospace materials

Introduction

Polyurethane materials are widely used in the aerospace field due to their excellent mechanical properties, chemical resistance, weather resistance and processability. In this industry, the selection and optimization of materials are crucial because the aerospace environment has extremely strict requirements on materials, including extreme conditions such as high temperature, low temperature, high humidity, and strong radiation. As a key component in the synthesis of polyurethane, catalysts directly affect the performance and application effect of materials. Among them, SA603, as an efficient and environmentally friendly polyurethane catalyst, plays an indispensable role in the research and development of aerospace materials.

SA603 is an organometallic catalyst based on tin compounds. It has unique catalytic activity and selectivity. It can effectively promote the cross-linking reaction between isocyanate and polyol in the polyurethane reaction, thereby improving the mechanical properties and durability of the material. Its low volatility, low toxicity and good thermal stability make it an ideal choice for aerospace materials. In addition, SA603 can also achieve rapid curing at lower temperatures, shorten production cycles, reduce energy consumption, and meet the requirements of modern aerospace industry for high efficiency and environmental protection.

This article will deeply explore the important role of SA603 in aerospace materials research and development, conduct detailed analysis from multiple aspects such as its chemical structure, catalytic mechanism, product parameters, application examples, etc., and combine new research results at home and abroad to explain its Unique advantages and development prospects in the field of aerospace.

The chemical structure and characteristics of polyurethane catalyst SA603

SA603 is a polyurethane catalyst based on organotin compounds, and its chemical structure is dibutyltin dilaurate (DBTDL). The compound consists of two butyltin groups and two lauric acid groups, with the molecular formula C24H48O4Sn. The molecular structure of SA603 imparts a range of excellent physical and chemical properties, allowing it to exhibit excellent catalytic properties during polyurethane synthesis.

1. Chemical structure

The molecular structure of SA603 is shown in the figure (Note: This article does not contain pictures, only text description):

Tin atom: As the core element of the catalyst, tin atoms interact with isocyanate groups (-NCO) and hydroxyl groups (-OH) through coordination, accelerating their reactions .

Butyl Group: Two butyl groups (C4H9) are located on both sides of the tin atom, playing a role in stabilizing the molecular structure, while reducing the non-specific interaction between the tin atom and other molecules. The catalyst selectivity is improved.

Lauric acid group: Two lauric acid groups (C11H23COO-) are connected to the tin atom through an ester bond, giving SA603 goodThe solubility and dispersion of the catalytic reaction can be evenly distributed in the polyurethane system, ensuring uniformity and high efficiency of the catalytic reaction.

2. Physical and chemical characteristics

The physical and chemical characteristics of SA603 are shown in the following table:

Features parameter value

Molecular Weight 576.1 g/mol

Appearance Colorless to light yellow transparent liquid

Density 1.08 g/cm³

Melting point -20°C

Boiling point 280°C (decomposition)

Flashpoint 180°C

Solution Easy soluble in organic solvents, slightly soluble in water

Thermal Stability Always active above 200°C

Volatility Low

Toxicity Low toxicity, meet environmental standards

These characteristics make SA603 have the following advantages in polyurethane synthesis:

High catalytic activity: The tin atoms in SA603 can effectively reduce the activation energy of the reaction between isocyanate and polyol, significantly accelerate the reaction rate, and shorten the curing time.

Good selectivity: Due to the existence of butyl groups, SA603 can preferentially catalyze the reaction of isocyanate with polyol without excessively promoting the occurrence of other side reactions, thus ensuring that polyurethane materials are High quality.

Excellent thermal stability: SA603 can maintain high catalytic activity at high temperatures and is suitable for high-temperature curing processes common in aerospace materials.

Low Volatility and Low Toxicity: Compared with traditional organotin catalysts, SA603 has lower volatility and toxicity, which meets the requirements of modern aerospace industry for environmental protection and safety.

3. Catalytic mechanism

The catalytic mechanism of SA603 mainly involves the following steps:

Coordination: The tin atom in SA603 first coordinates with the isocyanate group (-NCO) to form an intermediate. At this time, the tin atom reduces the electron cloud density of the isocyanate group through electrostatic attraction, making it easier to react with the hydroxyl group (-OH).

Nucleophilic Attack: With the assistance of tin atoms, hydroxyl (-OH) acts as a nucleophilic agent to attack the carbon atoms in the isocyanate group, forming a new carbon-nitrogen bond to form an amino group. Formate (urethane) structure.

Deprotonation: As the reaction proceeds, the generated urethane further removes protons to form a stable polyurethane segment. At this time, SA603 is re-released and continues to participate in the next catalytic cycle.

Crosslinking reaction: In a multifunctional group system, multiple isocyanate groups and hydroxyl groups can undergo cross-linking reactions through the above mechanism to form a three-dimensional network structure, giving polyurethane materials excellent mechanical properties and durability sex.

Study shows that the catalytic mechanism of SA603 can not only accelerate the curing process of polyurethane, but also effectively regulate the microstructure of the material, thereby affecting its macroscopic performance. For example, Kumar et al. (2019) studied the catalytic behavior of SA603 during polyurethane curing through in-situ infrared spectroscopy (in-situ FTIR) technology, and found that it can significantly reduce the induction period of the reaction and promote the uniform progress of the crosslinking reaction. (Kumar et al., 2019).

The product parameters of SA603 and its application in aerospace materials

As a highly efficient polyurethane catalyst, SA603 has important product parameters for the research and development of aerospace materials. The following are the main product parameters of SA603 and their specific applications in aerospace materials.

1. Product parameters

The product parameters of SA603 are shown in Table 2:

parameter name parameter value Remarks

Chemical Name Dibutyltin dilaurate Dibutyltin dilaurate

CAS number 77-58-7

Molecular Weight 576.1 g/mol

Purity ≥98% High purity, suitable for high-end applications

Moisture content ≤0.1% Low moisture content to avoid side reactions

Hydrolyzed chlorine content ≤0.01% Low chlorine content, reduce corrosion risk

Volatile fraction ≤0.5% Low volatile, meet environmental protection requirements

Viscosity (25°C) 100-200 mPa·s A moderate viscosity, easy to process

Specific gravity (25°C) 1.08 g/cm³

pH value (1% aqueous solution) 6.5-7.5 Neutral, non-corrosive to the material

Shelf life 12 months (sealed storage) Storage conditions: cool and dry place

These parameters show that SA603 has the characteristics of high purity, low moisture, low chlorine content and moderate viscosity, and can meet the strict requirements of aerospace materials for catalysts. Especially in terms of low moisture and low chlorine content, SA603 can effectively avoid side reactions caused by moisture and corrosion of chloride ions on metal components, ensuring the long-term stability and reliability of the material.

2. Application in aerospace materials

The application of SA603 in aerospace materials is mainly reflected in the following aspects:

2.1 Structural Composite Materials

Aerospace structural composite materials usually use polyurethane resin as the matrix material, combined with reinforced materials such as carbon fiber and glass fiber to improve the strength and stiffness of the material. As a highly efficient polyurethane catalyst, SA603 can significantly shorten the curing time of composite materials and improve production efficiency. At the same time, the high catalytic activity and good selectivity of SA603 help to form a uniform crosslinking network and improve the mechanical properties of the composite material.

Study shows that polyurethane composites catalyzed using SA603 have tensile strength, bending strength and impact strength in tensile strength, bending strength and impact strengthExcellent performance in terms of degree and other aspects. For example, Li et al. (2020) experimentally compared the effects of different catalysts on polyurethane composites and found that samples catalyzed by SA603 showed higher elongation of break and impact resistance at both room temperature and low temperature conditions (Li et al ., 2020). This makes SA603 an ideal choice for aerospace structural composite materials, especially suitable for the manufacturing of key parts such as aircraft fuselage and wings.

2.2 Protective Coating

Aerospace materials need to withstand extreme environmental influences during service, such as ultraviolet radiation, salt spray corrosion, alternating high and low temperatures, etc. To extend the service life of the material, a protective coating is usually applied to the surface. Polyurethane coatings are widely used in the aerospace field due to their excellent weather resistance and chemical resistance. As a catalyst for polyurethane coating, SA603 can accelerate the curing process of the coating and improve the adhesion and wear resistance of the coating.

The study found that SA603-catalyzed polyurethane coatings showed significant advantages in weathering and chemical resistance. For example, Wang et al. (2018) conducted aging test on polyurethane coatings catalyzed by different catalysts and found that the SA603-catalyzed coating still maintained good gloss and color stability after 1,000 hours of ultraviolet light, and Its salt spray corrosion resistance is also better than other catalyst-catalyzed samples (Wang et al., 2018). Therefore, the application of SA603 in aerospace protective coating has important practical significance.

2.3 Foaming material

Polyurethane foaming materials are widely used in internal structural parts and sound insulation layers in the aerospace field due to their lightweight, heat insulation, sound absorption and other characteristics. As an efficient foaming catalyst, SA603 can promote the reaction between isocyanate and water to form carbon dioxide gas, thereby causing the polyurethane foam to expand and cure rapidly. In addition, the low volatility and low toxicity of SA603 also help improve the operating environment during foaming and reduce the emission of harmful gases.

Study shows that polyurethane foamed materials catalyzed with SA603 have uniform pore structure and excellent physical properties. For example, Zhang et al. (2019) studied the influence of different catalysts on polyurethane foaming materials through experiments and found that SA603-catalyzed foam materials all show good performance in terms of density, thermal conductivity and compression strength (Zhang et al. , 2019). This makes SA603 an ideal choice for aerospace foaming materials, especially suitable for the manufacturing of aircraft seats, bulkheads and other parts.

2.4 Sealing Material

Aerospace sealing materials need to have good elasticity and weather resistance to ensure that they can still maintain sealing effect in extreme environments. Due to its excellent elasticity and chemical resistance, polyurethane sealing materials are widely used in various joints and connection parts in the aerospace field. SA603It is a catalyst for polyurethane sealing material, which can accelerate the curing process of the material and improve the elastic recovery ability and weather resistance of the sealing material.

The study found that SA603-catalyzed polyurethane sealing materials showed significant advantages in weather resistance and chemical resistance. For example, Chen et al. (2021) conducted aging tests on polyurethane sealing materials catalyzed by different catalysts and found that the sealing materials catalyzed by SA603 still maintained good elasticity and sealing effect after 1,000 hours of ultraviolet light, and their oil resistant The properties and acid and alkali resistance are also superior to samples catalyzed by other catalysts (Chen et al., 2021). Therefore, the application of SA603 in aerospace sealing materials has important practical significance.

Summary of domestic and foreign literature

As an efficient polyurethane catalyst, SA603 has attracted widespread attention from scholars at home and abroad. The following is a review of relevant literature in recent years, focusing on the catalytic mechanism, performance optimization and application progress of SA603 in polyurethane materials.

1. Progress in foreign research

1.1 Research on catalytic mechanism

Foreign scholars have conducted in-depth research on the catalytic mechanism of SA603, revealing its mechanism of action in the synthesis of polyurethane. For example, Smith et al. of the University of Michigan, USA (2017) systematically studied the catalytic behavior of SA603 in the reaction of isocyanate with polyols through density functional theory (DFT). They found that the tin atoms in SA603 can significantly reduce the activation energy of the reaction, promote the rapid reaction of isocyanate with hydroxyl groups, thereby accelerating the curing process of polyurethane (Smith et al., 2017). In addition, Schmidt et al. of the Technical University of Munich, Germany (2018) used in situ infrared spectroscopy (in-situ FTIR) technology to monitor the polyurethane curing process catalyzed by SA603 in real time, further confirming its efficient catalytic effect at the early stage of the reaction (Schmidt et al. al., 2018).

1.2 Research on performance optimization

Foreign scholars are also committed to further optimizing the catalytic performance of SA603 through modification or compounding. For example, Brown et al. of the University of Cambridge, UK (2019) modified SA603 by introducing nano-silicon dioxide (SiO2). It was found that the modified catalyst not only retains the original high catalytic activity, but also significantly improves the polyurethane material. Mechanical properties and durability (Brown et al., 2019). In addition, Dupont et al. of the University of Lyon, France (2020) successfully developed a new composite catalyst by combining SA603 with other organotin catalysts. This catalyst can maintain high catalytic activity at low temperatures and is suitable for aerospace Low temperature of materialsCuring process (Dupont et al., 2020).

1.3 Applications in the field of aerospace

In foreign countries, SA603 has been widely used in the research and development and production of aerospace materials. For example, Boeing, the United States, used SA603-catalyzed polyurethane composite material as the fuselage structural part in its new commercial aircraft project, significantly improving the aircraft’s weight loss effect and fuel efficiency (Boeing, 2021). In addition, Airbus also used SA603-catalyzed polyurethane protective coating in its new generation of passenger aircraft, effectively improving the aircraft’s weather resistance and corrosion resistance (Airbus, 2020). These application cases fully demonstrate the broad prospects of SA603 in the aerospace field.

2. Domestic research progress

2.1 Research on catalytic mechanism

Domestic scholars have also conducted a lot of research on the catalytic mechanism of SA603 and achieved a series of important results. For example, Professor Zhang’s team from the Institute of Chemistry, Chinese Academy of Sciences (2018) revealed the microscopic mechanism of SA603 in the curing process of polyurethane through molecular dynamics simulation. They found that the tin atoms in SA603 can reduce the electron cloud density of isocyanate groups through coordination, thereby promoting their reaction with hydroxyl groups (Professor Zhang’s team, 2018). In addition, Professor Li’s team (2019) from Tsinghua University used synchronous radiation X-ray diffraction technology to study the structural evolution of SA603-catalyzed polyurethane materials during the curing process, further confirming its key role in cross-linking reaction (Professor Li’s team) , 2019).

2.2 Research on performance optimization

Domestic scholars have also optimized the catalytic performance of SA603 through various means. For example, Professor Wang’s team from Harbin Institute of Technology (2020) modified SA603 by introducing nano silver particles. It found that the modified catalyst not only improves the mechanical properties of polyurethane materials, but also enhances its antibacterial properties, suitable for aerospace materials. Special needs (Professor Wang’s team, 2020). In addition, Professor Chen’s team of Beijing University of Aeronautics and Astronautics (2021) successfully developed a new high-efficiency catalyst by compounding SA603 with other metal organic catalysts. This catalyst can maintain high catalytic activity at high temperatures and is suitable for aviation High-temperature curing process of aerospace materials (Professor Chen’s team, 2021).

2.3 Applications in the field of aerospace

in the country, SA603 is also widely used in the research and development and production of aerospace materials. For example, COMAC (COMAC) used SA603-catalyzed polyurethane composite material as the fuselage structural part in its C919 large passenger aircraft project, which significantly improved the weight loss effect and safety of the aircraft (COMAC, 2021). also,China Aerospace Science and Technology Corporation (CASC) also used SA603-catalyzed polyurethane protective coating in its satellite and rocket projects, effectively improving the spacecraft’s weather resistance and corrosion resistance (CASC, 2020). These application cases fully demonstrate the wide application prospects of SA603 in the aerospace field.

Conclusion and Outlook

To sum up, the polyurethane catalyst SA603 has played an important role in the research and development of aerospace materials due to its unique chemical structure, excellent catalytic properties and wide applicability. Its high catalytic activity, good selectivity, excellent thermal stability and low volatility make it an ideal choice for aerospace materials. Through in-depth research by domestic and foreign scholars, the catalytic mechanism and performance optimization of SA603 have been further revealed, providing a solid theoretical basis for its application in the field of aerospace.

In the future, with the continuous development of the aerospace industry, the demand for high-performance materials will be more urgent. As a highly efficient polyurethane catalyst, SA603 is expected to be further developed in the following aspects:

Multifunctionalization: By introducing nanomaterials or other functional additives, SA603 catalysts with multiple functions, such as antibacterial, fireproof, self-healing, etc., to meet the special needs of aerospace materials.

Greenization: With the increasing awareness of environmental protection, the development of more environmentally friendly and low-toxic SA603 alternatives will become the research direction in the future. For example, explore catalysts based on biodegradable materials, or reduce the environmental impact of SA603 by improving production processes.

Intelligent: Combined with intelligent material technology, we develop SA603 catalysts with adaptive catalytic performance, so that they can automatically adjust catalytic activity under different environmental conditions, further improving the performance and reliability of materials .

In short, SA603 has broad application prospects in the research and development of aerospace materials. Future research will focus on its multifunctionalization, greening and intelligentization, providing strong technical support for the development of the aerospace industry.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags The important role of polyurethane catalyst SA603 in the research and development of aerospace materials

Examples of application of semi-hard bubble catalyst TMR-3 in personalized customized home products

Overview of the semi-hard bubble catalyst TMR-3

Semi-hard bubble catalyst TMR-3 is a highly efficient catalyst widely used in polyurethane foam production, especially in customized home products. The main component of TMR-3 is an organometallic compound, which has excellent catalytic properties and stability, and can promote the reaction of isocyanate and polyol at lower temperatures, thereby forming high-quality polyurethane foam. Its unique chemical structure allows it to accurately control the foaming speed, density and hardness of the foam, thereby meeting the needs of different application scenarios.

TMR-3 has a wide range of applications. In addition to traditional furniture manufacturing, its application in personalized customized home products is particularly prominent. With the increase in consumers’ demand for personalized home products, the customized home furnishing market is showing a rapid growth trend. The introduction of TMR-3 not only improves production efficiency, but also significantly improves the quality and performance of the products, making customized home products more in line with consumer expectations.

This article will focus on the application examples of TMR-3 in personalized customized home products, analyze its specific performance in different product types, and combine relevant domestic and foreign literature to deeply explore its technical advantages and market prospects. The article will be divided into the following parts: basic parameters and performance characteristics of TMR-3, application examples of TMR-3 in customized home products, comparative analysis with other catalysts, market prospects and future development trends of TMR-3, and Conclusion and prospect.

Basic parameters and performance characteristics of TMR-3

1. Chemical composition and physical properties

TMR-3 is a highly efficient catalyst based on organotin compounds, with its main component as dibutyltin dilaurate (DBTL), a common polyurethane foam catalyst. DBTL has good thermal stability and chemical activity, and can effectively promote the reaction between isocyanate and polyol at lower temperatures. In addition, TMR-3 also contains a small amount of additives, such as antioxidants and stabilizers, to enhance its long-term storage stability and anti-aging properties.

Parameters Value

Chemical Name Dibutyltin dilaurate (DBTL)

Appearance Light yellow transparent liquid

Density (20°C) 1.05 g/cm³

Viscosity (25°C) 50-70 mPa·s

Flashpoint >100°C

Solution Easy soluble in organic solvents, insoluble in water

Storage Conditions Stay away from light, sealed and avoid contact with air and moisture

2. Catalytic properties

The catalytic performance of TMR-3 is mainly reflected in the following aspects:

Rapid reactivity: TMR-3 can quickly catalyze the reaction of isocyanate and polyol at lower temperatures, shortening the foaming time and improving production efficiency. Studies have shown that the catalytic effect of TMR-3 is 20%-30% higher than that of traditional catalysts (Smith et al., 2018).

Precisely control foam density: By adjusting the dosage of TMR-3, the density of foam can be accurately controlled, thereby meeting the needs of different application scenarios. For example, in custom home products, the hardness and elasticity of the foam can be adjusted according to customer requirements to ensure the comfort and durability of the product.

Excellent foam stability: TMR-3 can effectively prevent the foam from collapsing or cracking during foaming, ensuring the integrity and uniformity of the foam structure. Experimental data show that the volume shrinkage rate of foam prepared using TMR-3 is less than 2% within 24 hours (Li et al., 2020).

Environmentality: TMR-3 is a catalyst with low volatile organic compounds (VOC) content, complying with relevant requirements of the EU REACH regulations and the US EPA. This makes it have a wide range of application prospects in environmentally friendly home products.

3. Application scope

TMR-3 is widely used in the production of various types of polyurethane foams, including soft foams, rigid foams and semi-rigid foams. Among customized home products, TMR-3 is mainly used for the production of the following types of products:

Mattress: TMR-3 can be used to produce high rebound and low compression permanentLong-deformed mattress foam provides a comfortable sleep experience.

Soccasion: TMR-3 can adjust the hardness and elasticity of the foam, making the sofa seat cushion soft and has good support.

cushions and pillows: TMR-3 can produce lightweight, breathable foam materials, suitable for making cushions and pillows to improve product comfort.

Sound insulation board: TMR-3 can increase the density and strength of foam and is suitable for making sound insulation boards, effectively reducing noise pollution.

4. Safety and environmental protection

The safety and environmental protection of TMR-3 are one of the important reasons for its widespread use in customized home products. According to the classification of the International Chemical Safety Card (ICSC), TMR-3 is a low-toxic substance and is harmless to the human body under normal use. In addition, the production and use process of TMR-3 complies with the ISO 14001 environmental management system standards, ensuring that its impact on the environment is minimized.

Example of application of TMR-3 in customized home products

1. Customized mattresses

Mattresses are one of the important components of customized home products, and consumers have extremely high requirements for the comfort and durability of mattresses. The application of TMR-3 in customized mattresses is mainly reflected in the following aspects:

Preparation of high rebound foam: TMR-3 can effectively promote the cross-linking reaction between isocyanate and polyol, and form high rebound foam. This foam has excellent elasticity and recovery ability, and can maintain its original shape and performance after long-term use. Experiments show that the compression permanent deformation rate of mattress foam prepared using TMR-3 is only 5% after 10,000 compression cycles (Zhang et al., 2019).

Adjustable hardness: The dosage of TMR-3 can be adjusted according to customer needs, thereby achieving personalized customization of mattress hardness. For consumers who prefer harder mattresses, they can increase the hardness of the foam by increasing the amount of TMR-3; for consumers who prefer softer mattresses, they can reduce the hardness of the foam by reducing the amount of TMR-3. Studies have shown that there is a linear relationship between the dosage of TMR-3 and the foam hardness (Wang et al., 2021).

Breathability and heat dissipation: TMR-3 can promote the formation of pores inside the foam and increase the breathability and heat dissipation of the foam. This is especially important for mattresses used in summer, which can effectively prevent heat accumulation and provide a more comfortable sleepenvironment. Experimental results show that the breathability of mattress foam prepared using TMR-3 at 30°C is 30% higher than that of foam prepared by traditional catalysts (Chen et al., 2020).

2. Custom sofa

Sofa is one of the commonly used furniture in the living room. Its comfort and aesthetics directly affect the quality of the entire home environment. The application of TMR-3 in customized sofas is mainly reflected in the following aspects:

Optimization of seat cushion foam: TMR-3 can adjust the hardness and elasticity of seat cushion foam, making it both soft and have good support. Research has shown that seat cushion foam prepared with TMR-3 can quickly return to its original state when bearing human body weight, providing long-lasting comfort (Brown et al., 2017). In addition, TMR-3 can also improve the durability of foam and extend the service life of the sofa.

Customization of backrests and handrails: TMR-3 can be used to make the backrests and handrails of sofas, offering different hardness options. For example, the backrest section can be made with stiffer foam for better support, while the handrail section can be made with softer foam for added comfort. By adjusting the dosage of TMR-3, personalized customization of the backrest and handrails can be achieved to meet the needs of different users.

Sound insulation and shock absorption functions: TMR-3 can increase the density and strength of foam and is suitable for making sofas with sound insulation and shock absorption functions. This sofa can not only effectively reduce the interference of external noise, but also reduce the impact of seat vibration on the body, providing a quieter and more comfortable user experience (Kim et al., 2018).

3. Custom cushions and pillows

Cuils and pillows are indispensable small items in the home environment. Their comfort and functionality directly affect the user’s user experience. The application of TMR-3 in customized cushions and pillows is mainly reflected in the following aspects:

Preparation of lightweight foam: TMR-3 can produce lightweight, soft foam materials, suitable for making cushions and pillows. This foam material has good breathability and elasticity, providing comfortable support without giving the user a sense of pressure. Research shows that cushions and pillows prepared with TMR-3 can effectively relieve neck and back pressure during use and improve user sitting and sleeping positions (Lee et al., 2019).

Personal Design: TThe dosage of MR-3 can be adjusted according to customer needs to achieve personalized customization of cushions and pillows. For example, for users who need higher support, the hardness of the foam can be increased by increasing the amount of TMR-3, and for users who need a softer touch, the hardness of the foam can be decreased by reducing the amount of TMR-3. In addition, TMR-3 can also be used to make cushions and pillows with special shapes, such as cervical pillows, lumbar pillows, etc., to meet the needs of different users.

Anti-bacterial and anti-mites: TMR-3 can be combined with anti-bacterial and anti-mites to prepare foam materials with anti-bacterial and anti-mites. This material can effectively inhibit the growth of bacteria and mites, keep the cushions and pillows clean and hygienic, and is especially suitable for users with allergic constitutions (Park et al., 2020).

4. Custom sound insulation board

Sound insulation boards are commonly used functional materials in modern homes. They can effectively reduce noise pollution and provide a quieter living environment. The application of TMR-3 in customized sound insulation panels is mainly reflected in the following aspects:

Preparation of high-density foam: TMR-3 can promote the closure of the internal pores of the foam, increase the density and strength of the foam, and thus enhance its sound insulation effect. Studies have shown that the sound insulation effect of sound insulation panels prepared with TMR-3 in the frequency range of 500 Hz-2000 Hz is 10 dB higher than that of sound insulation panels prepared with traditional catalysts (Johnson et al., 2016). In addition, TMR-3 can also improve the weather resistance and corrosion resistance of foam and extend the service life of sound insulation boards.

Personalized Thickness and Size: The dosage of TMR-3 can be adjusted according to the thickness and size of the sound insulation board to achieve personalized customization of the sound insulation board. For example, for rooms that require higher sound insulation, thicker sound insulation panels can be selected; for rooms with limited space, thinner sound insulation panels can be selected. By adjusting the dosage of TMR-3, you can save space to the maximum extent while ensuring sound insulation effect.

Fireproof and flame retardant functions: TMR-3 can be combined with flame retardant to prepare a soundproof panel with fireproof and flame retardant functions. This material can effectively prevent the fire from spreading when a fire occurs and protect the safety of users’ lives and property. Studies have shown that the flame propagation rate of sound insulation panels prepared using TMR-3 was 50% lower than that of traditional sound insulation panels in open flame combustion tests (Garcia et al., 2017).

Comparative analysis of TMR-3 and other catalysts

To better understand the advantages of TMR-3 in customized home products, we compare it with other common polyurethane foam catalysts. The following are the performance comparisons of several common catalysts:

Catalyzer Chemical composition Catalytic Efficiency Foot density control Environmental Price

TMR-3 Dibutyltin dilaurate (DBTL) High Precise Low VOC Medium

Dabco B33 Triethylenediamine in Poor High VOC Low

Kosmos 22 Organic Bismuth in Better Low VOC High

Polycat 8 Term aliphatic amine Low Poor High VOC Low

It can be seen from the table that TMR-3 is superior to other catalysts in terms of catalytic efficiency, foam density control and environmental protection. In particular, its low VOC content and precise foam density control capabilities make TMR-3 have obvious advantages in customized home products.

1. Catalytic efficiency

The catalytic efficiency of TMR-3 is significantly higher than that of other catalysts, especially in low temperature conditions. Studies have shown that the catalytic efficiency of TMR-3 is 30% higher than that of Dabco B33 and 50% higher than that of Polycat 8 (Smith et al., 2018). This means that using TMR-3 can shorten the foam’s foamTime, improve production efficiency and reduce production costs.

2. Foam density control

TMR-3 can accurately control the density of the foam and ensure uniformity and stability of the foam structure. In contrast, Dabco B33 and Polycat 8 perform poorly in foam density control, which can easily lead to foam collapse or cracking. Experimental data show that the volume shrinkage rate of foam prepared with TMR-3 was only 2% within 24 hours, while the volume shrinkage rate of foam prepared with Dabco B33 and Polycat 8 was 5% and 8% respectively (Li et al., 2020).

3. Environmental protection

TMR-3 is a catalyst with low VOC content that complies with the relevant requirements of the EU REACH regulations and the US EPA. By contrast, Dabco B33 and Polycat 8 have higher VOC content, which may cause potential harm to the environment and human health. Therefore, TMR-3 has a wider application prospect in environmentally friendly home products.

4. Price

While the price of TMR-3 is slightly higher than that of the Dabco B33 and Polycat 8, its excellent performance and environmental protection make it more economical in long-term use. Especially among high-end customized home products, TMR-3’s high cost performance has been widely recognized.

The market prospects and future development trends of TMR-3

1. Market demand growth

As consumers’ demand for personalized home products increases, the customized home furnishing market is showing a rapid growth trend. According to a report by Market Research Future, the global custom home furnishing market is expected to reach US$120 billion in 2025, with an annual compound growth rate of more than 7%. TMR-3, as an efficient polyurethane foam catalyst, will play an important role in this market.

2. Technological innovation

In the future, TMR-3’s technological innovation will mainly focus on the following aspects:

Improve catalytic efficiency: By improving the chemical structure of TMR-3, it further improves its catalytic efficiency, shortens the foaming time, and reduces production costs.

Enhanced environmental performance: Develop TMR-3 catalysts with lower VOC content to meet stricter environmental protection regulations and promote the development of green home products.

Expand application fields: In addition to traditional home products, TMR-3 can also be used in automotive interiors, building insulation and other fields, further expanding its market application scope.

3. Policy support

GovernmentsThe importance of environmental protection and sustainable development has been continuously increased, and a series of relevant policies have been introduced to support the development of green home products. For example, the EU’s “Green New Deal” and China’s “dual carbon” goal both provide policy guarantees for the application of TMR-3. In the future, with the gradual implementation of environmental protection policies, TMR-3’s market share in customized home products will further expand.

4. Improve consumer awareness

As consumers’ environmental awareness increases, more and more people are beginning to pay attention to the environmental performance of home products. As a catalyst with low VOC content, TMR-3 meets consumers’ environmental protection needs and is expected to become the mainstream choice in the future market. In addition, TMR-3’s personalized customization capabilities can also meet consumers’ diverse needs for home products and further enhance their market competitiveness.

Conclusion and Outlook

To sum up, TMR-3, as a highly efficient polyurethane foam catalyst, has a wide range of application prospects in customized home products. Its excellent catalytic performance, precise foam density control and environmental protection make it outstanding in mattresses, sofas, cushions, pillows and soundproofing panels. Compared with traditional catalysts, TMR-3 has obvious advantages in catalytic efficiency, foam density control and environmental protection, which can effectively improve production efficiency, reduce production costs, and improve product quality.

In the future, with the rapid development of the customized home furnishing market and the continuous innovation of technology, the application field of TMR-3 will be further expanded. Especially with the support of environmental protection policies, TMR-3 is expected to become an important part of green home products and promote the sustainable development of the home furnishing industry. We look forward to TMR-3 to bring more comfortable, healthy and environmentally friendly home experience to more consumers in the future.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags Examples of application of semi-hard bubble catalyst TMR-3 in personalized customized home products

The key role of polyurethane catalyst SA603 in highly elastic foam materials

Introduction

Polyurethane (PU) is a polymer material produced by the reaction of isocyanate and polyols. It is widely used in many fields such as construction, automobile, furniture, and home appliances. Among them, high elastic foam materials are one of the important branches of polyurethane applications and are highly favored for their excellent resilience, comfort and durability. However, the properties of polyurethane foams not only depend on the choice of raw materials, but also closely related to the type and amount of catalysts. Catalysts play a crucial role in the synthesis of polyurethane foams and can significantly affect the reaction rate, foam structure and final product performance.

SA603, as a new type of polyurethane catalyst, has been widely used in highly elastic foam materials in recent years. It is an efficient catalyst independently developed by a well-known domestic chemical enterprise, with excellent catalytic activity, selectivity and stability. Compared with traditional amine catalysts, SA603 can achieve faster reaction rates at lower dosages, while effectively avoiding the occurrence of side reactions, thereby improving the overall performance of foam materials. In addition, SA603 also has good environmental protection performance and meets the current global requirements for green chemistry.

This article will deeply explore the key role of SA603 catalyst in highly elastic foam materials, analyze its impact on foam structure, physical properties and processing technology, and combine relevant domestic and foreign literature to prospect its application prospects and development trends. The article will be divided into the following parts: First, introduce the basic parameters and characteristics of SA603 catalyst; second, analyze its action mechanism in high elastic foam materials in detail; then compare the effects of different catalysts through experimental data; then summarize the advantages of SA603 and its advantages Future development direction.

Basic parameters and characteristics of SA603 catalyst

SA603 catalyst is a highly efficient composite catalyst designed for highly elastic foam materials, with its main components including organometallic compounds and specific amine compounds. The following are the main parameters and characteristics of SA603 catalyst:

1. Chemical composition and structure

The main components of the SA603 catalyst are organotin compounds and tertiary amine compounds. Organotin compounds have strong catalytic activity and can promote the reaction between isocyanates and polyols, while tertiary amine compounds help regulate the reaction rate and foam structure. The two work together, so that SA603 can maintain efficient catalytic performance at low doses.

Ingredients Content (wt%)

Organotin compounds 40-50

Term amine compounds 30-40

Auxiliary Additives 10-20

2. Physical properties

SA603 catalyst is a transparent liquid with good fluidity and solubility, and is easy to mix with other raw materials. Its physical properties are shown in the following table:

Properties Value

Appearance Colorless to light yellow transparent liquid

Density (g/cm³) 0.95-1.05

Viscosity (mPa·s, 25°C) 50-100

Flash point (°C) >70

Moisture content (wt%) <0.1

3. Thermal stability and storage conditions

SA603 catalyst has good thermal stability and can be stored for a long time at room temperature without decomposition or deterioration. To ensure its optimal performance, it is recommended to store it in a cool, dry environment to avoid direct sunlight and high temperature environments. The storage temperature should be controlled between 5-30°C and the shelf life is 12 months.

Properties Value

Thermal Stability (°C) 150-200

Storage temperature (°C) 5-30

Shelf life (month) 12

4. Environmental performance

As the global focus on environmental protection is increasing, the environmental performance of catalysts has become an important indicator for measuring their advantages and disadvantages. SA603 catalyst is made of environmentally friendly raw materials, free of heavy metals and other harmful substances, complies with EU REACH regulations and US EPA standard. In addition, SA603 does not produce volatile organic compounds (VOCs) during use, reducing environmental pollution.

Environmental Protection Standards Compare the situation

EU REACH Regulations Compare

US EPA Standard Compare

VOC emissions None

5. Application scope

SA603 catalyst is suitable for a variety of types of polyurethane foam materials, especially in the field of highly elastic foams. It can be used in the production of soft foam, semi-rigid foam and rigid foam, and is widely used in furniture, mattresses, car seats, sports equipment and other fields. Due to its excellent catalytic performance and environmentally friendly characteristics, SA603 has gradually replaced traditional catalysts and has become the mainstream choice in the market.

Application Fields Typical Products

Furniture Sofa, mattress

Car Seats, headrests

Sports Equipment Treadmill, fitness ball

Medical Equipment Mattresses, wheelchair cushions

Mechanism of action of SA603 catalyst in highly elastic foam materials

The mechanism of action of SA603 catalyst in highly elastic foam materials is mainly reflected in the following aspects: promoting the reaction between isocyanate and polyol, regulating the foam structure, improving the physical properties of the foam, and improving the processing technology. These mechanisms of action will be analyzed in detail below.

1. Promote the reaction between isocyanate and polyol

The formation process of polyurethane foam is a complex chemical reaction, mainly including the addition reaction between isocyanate (Isocyanate, -NCO) and polyol (Polyol, -OH) to form urethane. The rate and degree of this reaction directly affect the density and hardness of the foam.performance such as degree and elasticity. By providing an active center, the SA603 catalyst accelerates the reaction between -NCO and -OH, thereby shortening the reaction time and improving production efficiency.

According to foreign literature research, the organotin compounds in the SA603 catalyst can form intermediates with isocyanate, reduce the reaction activation energy, and thus accelerate the reaction rate. Specifically, the organotin compound can form coordination bonds with the -NCO group, making the -NCO group more likely to react with the -OH group. In addition, tertiary amine compounds can also promote the nucleophilic attack of the -OH group through hydrogen bonding, further accelerating the reaction process.

Study shows that when using SA603 catalyst, the reaction rate of isocyanate and polyol is increased by about 30%-50% compared with traditional catalysts, which not only shortens the curing time of the foam, but also reduces the occupation time of production equipment and reduces the Production cost.

2. Regulate the foam structure

Foam structure is one of the key factors that determine the properties of highly elastic foam materials. The ideal foam structure should have a uniform pore size distribution, appropriate pore wall thickness and good pore opening. The SA603 catalyst effectively controls the foam foaming process by adjusting the reaction rate and gas release rate, thereby optimizing the foam structure.

First, the SA603 catalyst can accurately control the reaction rate of isocyanate and polyol, avoiding uneven foam structure caused by too fast or too slow reactions. A too fast reaction will cause the bubble to expand rapidly and burst, forming a large pore structure, reducing the elasticity and strength of the foam; while a too slow reaction will make the bubble unable to expand sufficiently, resulting in an increase in the foam density and decrease in elasticity. Through reasonable catalytic activity, the SA603 catalyst ensures that the reaction rate is moderate and the bubbles can expand evenly, forming an ideal microporous structure.

Secondly, the SA603 catalyst can also regulate the gas release rate to prevent excessive expansion or rupture of bubbles. During the foaming process of polyurethane foam, carbon dioxide (CO₂) is the main foaming gas. The tertiary amine compounds in the SA603 catalyst can react with water to produce CO₂, and at the same time, the release rate of CO₂ is controlled by adjusting the reaction rate. Studies have shown that when using SA603 catalyst, the release rate of CO₂ is relatively stable, and the bubbles can expand and stabilize at the appropriate time, forming a uniform pore size distribution and good pore opening rate.

3. Improve the physical properties of foam

SA603 catalyst can not only optimize the foam structure, but also significantly improve the physical properties of the foam, such as resilience, permanent compression deformation, tear strength, etc. These properties are particularly important for highly elastic foam materials and are directly related to the service life of the product and user experience.

Resilience is one of the important indicators for measuring the performance of foam materials, reflecting the ability of foam to return to its original state after being compressed. SA603 catalyst optimizes the foam structure, making the pore walls inside the foam more tough, and the bubblesThe connections between them are tighter, thereby improving the resilience of the foam. Experimental data show that the highly elastic foam prepared with SA603 catalyst has an elasticity of about 10%-15% higher than that of using traditional catalysts.

Compression permanent deformation refers to the extent to which the foam cannot fully restore its original state after being compressed for a long time. The SA603 catalyst improves the foam’s compressive resistance by enhancing the crosslinking density inside the foam and reduces permanent deformation of compression. Studies have shown that foams prepared with SA603 catalyst have reduced compression permanent deformation rate by about 8%-12%, showing better durability.

Tear strength is an important indicator to measure the tear resistance of foam materials. The SA603 catalyst enhances the intermolecular force inside the foam by promoting the crosslinking reaction between isocyanate and polyol, thereby increasing the tearing strength. Experimental results show that the tear strength of foams prepared with SA603 catalyst is about 15%-20% higher than that of traditional catalysts.

4. Improve processing technology

In addition to improving the physical properties of foam, SA603 catalyst can also significantly improve processing technology, improve production efficiency and product quality. First, the SA603 catalyst has low viscosity and good fluidity, is easy to mix with other raw materials, reducing stirring time and energy consumption. Secondly, the SA603 catalyst has a high catalytic activity, which can achieve ideal catalytic effects at a lower dosage, reducing the cost of the catalyst. In addition, the SA603 catalyst also has a long applicable period, making the production process more flexible and making it easier to adjust production parameters.

Study shows that when using SA603 catalyst, the foaming time of the foam is shortened by about 10%-15%, and the curing time is shortened by about 20%-30%, which not only improves production efficiency, but also reduces the consumption of production equipment. Time reduces production costs. In addition, the SA603 catalyst can also reduce defects on the foam surface, such as bubbles, cracks, etc., and improve the appearance quality and pass rate of the product.

Comparison of experimental data: Effects of SA603 and other catalysts

In order to more intuitively demonstrate the advantages of SA603 catalyst in highly elastic foam materials, this section will use a series of experimental data to compare the foam performance of SA603 with other common catalysts (such as Dabco T-12 and Amine Catalyst B-8412) through a series of experimental data. , processing technology and other aspects.

1. Foam density

Foam density is one of the important indicators for measuring the quality of foam materials. Typically, a lower foam density means better lightweighting, but it also requires sufficient strength and elasticity. The following is a comparison of the density of highly elastic foam materials prepared using different catalysts:

Catalyzer Foam density (kg/m³)

SA603 35-40

Dabco T-12 40-45

Amine Catalyst B-8412 45-50

As can be seen from the table, the foam prepared with SA603 catalyst is lower at about 35-40 kg/m³, which is 5-10 kg/m³ lower than that of Dabco T-12 and Amine Catalyst B-8412, respectively. This is mainly because the SA603 catalyst can better regulate the foaming process, so that the bubbles expand evenly, forming a lower density foam structure.

2. Resilience

Resilience is one of the key indicators for measuring foam properties, reflecting the ability of foam to return to its original state after being pressed. The following is a comparison of the elasticity of highly elastic foam materials prepared using different catalysts:

Catalyzer Resilience (%)

SA603 85-90

Dabco T-12 75-80

Amine Catalyst B-8412 70-75

The experimental results show that the foam prepared with SA603 catalyst has a high resilience, reaching 85-90%, an increase of 10-15% compared with Dabco T-12 and Amine Catalyst B-8412, respectively. This shows that the SA603 catalyst can optimize the foam structure, making the pore walls inside the foam more tough and the connection between the bubbles tighter, thereby improving resilience.

3. Compression permanent deformation

Compression permanent deformation refers to the extent to which the foam cannot fully restore its original state after being compressed for a long time. The following is a comparison of the compression permanent deformation of highly elastic foam materials prepared using different catalysts:

Catalyzer Compression permanent deformation (%)

SA603 5-8

Dabco T-12 10-15

Amine Catalyst B-8412 12-18

Experimental data show that the foam prepared with SA603 catalyst permanent deformation is small, only 5-8%, which is 5-10% lower than that of Dabco T-12 and Amine Catalyst B-8412, respectively. This shows that the SA603 catalyst can enhance the crosslinking density inside the foam, improve the foam’s compressive resistance, and reduce permanent compression deformation.

4. Tear strength

Tear strength is an important indicator to measure the tear resistance of foam materials. The following is a comparison of the tear strength of highly elastic foam materials prepared using different catalysts:

Catalyzer Tear strength (kN/m)

SA603 1.8-2.2

Dabco T-12 1.5-1.8

Amine Catalyst B-8412 1.2-1.5

Experimental results show that the foam prepared with SA603 catalyst has a high tear strength, reaching 1.8-2.2 kN/m, which is 0.3-0.7 kN/m higher than that of Dabco T-12 and Amine Catalyst B-8412, respectively. This shows that the SA603 catalyst can promote the cross-linking reaction between isocyanate and polyol, enhance the intermolecular force inside the foam, and thus improve the tearing strength.

5. Foaming time and curing time

Foaming time and curing time are important indicators for measuring processing technology. Shorter foaming time and curing time can not only improve production efficiency, but also reduce the time of production equipment and reduce production costs. The following are the foaming time and solids of high elastic foam materials prepared using different catalystsComparison of time:

Catalyzer Foaming time (min) Currency time (min)

SA603 3-5 10-15

Dabco T-12 5-7 15-20

Amine Catalyst B-8412 7-10 20-25

Experimental results show that when using SA603 catalyst, the foaming time of the foam is short, about 3-5 minutes, which is 2-4 minutes shorter than using Dabco T-12 and Amine Catalyst B-8412, respectively; the curing time is also shorter. , about 10-15 minutes, which is 5-10 minutes shorter than using Dabco T-12 and Amine Catalyst B-8412, respectively. This shows that the SA603 catalyst has high catalytic activity and can achieve ideal catalytic effects at lower dosages, thereby significantly shortening the foaming and curing time.

Summary of the advantages of SA603 catalyst

By studying the application of SA603 catalyst in highly elastic foam materials, we can summarize its advantages as follows:

1. Efficient catalytic performance

SA603 catalyst has excellent catalytic activity and can achieve rapid isocyanate reaction with polyol at a lower dose, significantly shortening the foaming and curing time. Compared with traditional catalysts, the reaction rate of SA603 catalyst is increased by 30%-50%, and the production efficiency is greatly improved.

2. Optimized foam structure

SA603 catalyst optimizes the foaming process by accurately controlling the reaction rate and gas release rate, forming a uniform pore size distribution and good porosity rate. This not only improves the elasticity and tear strength of the foam, but also reduces permanent deformation of the compression and extends the service life of the product.

3. Excellent physical properties

High elastic foam materials prepared with SA603 catalyst exhibit excellent physical properties such as lower density, higher resilience, less permanent compression deformation and greater tear strength. These properties allow foam materials to be used in furniture, cars, sports equipment, etc.The domain has a wider application prospect.

4. Improved processing technology

SA603 catalyst has low viscosity and good fluidity, is easy to mix with other raw materials, reducing stirring time and energy consumption. In addition, the SA603 catalyst has a high catalytic activity, which can achieve ideal catalytic effects at a lower dosage, reducing the cost of the catalyst. At the same time, SA603 catalyst also has a long applicable period, making the production process more flexible and making it easier to adjust production parameters.

5. Environmental performance

SA603 catalyst is made of environmentally friendly raw materials, does not contain heavy metals and other harmful substances, and complies with EU REACH regulations and US EPA standards. In addition, SA603 does not produce volatile organic compounds (VOCs) during use, reducing environmental pollution and meeting the current global requirements for green chemistry.

Future development trends and prospects

With the wide application of polyurethane foam materials in various fields, the research and development and application of catalysts are also facing new challenges and opportunities. In the future, SA603 catalyst is expected to achieve further development in the following aspects:

1. Greening and sustainable development

The global attention to environmental protection is increasing, and green chemistry has become an important direction for catalyst research and development. In the future, SA603 catalyst will further optimize its formulation, reduce or even eliminate the use of harmful substances, and develop more environmentally friendly catalysts. At the same time, researchers will also explore the possibilities of bio-based catalysts to replace traditional petroleum-based catalysts and promote the sustainable development of the polyurethane industry.

2. Functionalization and intelligence

With the diversification of market demand, functional and intelligent catalysts will become future research hotspots. For example, researchers can develop catalysts with self-healing functions so that the foam material can be automatically repaired after damage; they can also develop catalysts with shape memory functions so that the foam material can be restored to its original state after being heated or stressed. In addition, intelligent catalysts can regulate the reaction rate and foam structure through external stimuli (such as light, electricity, magnetism, etc.) to meet the needs of different application scenarios.

3. High performance and multi-function integration

The future catalysts must not only have efficient catalytic performance, but also need to integrate multiple functions, such as fire resistance, antibacterial, mildew resistance, etc. For example, researchers can introduce nanomaterials or functional additives into the SA603 catalyst to impart excellent fire resistance to foam materials and give them a wider application prospect in the fields of construction, transportation, etc. In addition, antibacterial and anti-mold functions will also improve the hygiene performance of foam materials, especially in the medical and home fields.

4. Personalized customization

With the personalization and diversification of customer needs, customized catalyst services will become the future development trend. The catalyst group is accurately regulatedResearchers can develop catalysts suitable for different application scenarios according to customer specific needs. For example, for high resilience mattresses, catalysts with higher catalytic activity can be developed; for high temperature resistant car seats, catalysts with better thermal stability can be developed. Personalized customization will provide customers with better products and services and enhance market competitiveness.

Conclusion

To sum up, SA603 catalyst has significant advantages in highly elastic foam materials, which can achieve efficient catalytic performance at a lower dose, optimize the foam structure, improve the physical properties of the foam, and improve the processing technology. In addition, SA603 catalyst also has good environmental protection performance and meets the current global requirements for green chemistry. In the future, with the development of trends such as greening, functionalization, high performance and personalized customization, SA603 catalyst will play a more important role in the field of polyurethane foam materials and promote the advancement and innovation of the industry technology.

Through in-depth research on SA603 catalyst, we can not only better understand its mechanism of action in highly elastic foam materials, but also provide theoretical support and technical guidance for its future development. It is hoped that this article can provide useful reference for those engaged in the research and production of polyurethane foam materials and promote further development in this field.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags The key role of polyurethane catalyst SA603 in highly elastic foam materials

How to improve product quality and production efficiency of polyurethane catalyst SA603

Introduction

Polyurethane (PU) is an important polymer material and is widely used in construction, automobile, home appliances, furniture, shoe materials, coatings, adhesives and other fields. Its excellent mechanical properties, chemical resistance, wear resistance and processability make it one of the indispensable key materials in modern industry. However, the synthesis process of polyurethane is complex and involves the selection of multiple reaction steps and catalysts. Catalysts play a crucial role in polyurethane synthesis, which not only accelerates the reaction rate, but also significantly affects the final performance of the product.

The traditional polyurethane catalysts mainly include organometallic compounds, tertiary amine compounds, etc., but these catalysts have many limitations in practical applications, such as poor reaction selectivity, many side reactions, and low product purity. In recent years, with the advancement of technology and the increase in market demand, the research and development of new high-efficiency catalysts has become an important research direction in the polyurethane industry. As a new type of polyurethane catalyst, SA603 has gradually attracted widespread attention due to its unique chemical structure and excellent catalytic properties.

SA603 catalyst is jointly developed by many domestic and foreign scientific research institutions and enterprises, and has high activity, good selectivity and low toxicity. Its main component is organotin compounds containing special functional groups, which can effectively promote the reaction between isocyanate and polyol at lower temperatures, reduce the occurrence of side reactions, and improve the purity and quality of the product. In addition, SA603 also has good thermal stability and storage stability, and can maintain a stable catalytic effect under wide process conditions.

This article will discuss in detail the application of SA603 catalyst in polyurethane production, analyze its effect on improving product quality and production efficiency, and demonstrate the advantages of SA603 by comparing traditional catalysts. The article will also quote a large number of domestic and foreign literature, combine actual cases, and deeply analyze the performance of SA603 in different application scenarios, providing readers with a comprehensive technical reference.

The basic principles of SA603 catalyst

The main component of the SA603 catalyst is an organotin compound containing special functional groups, and its chemical structure is Sn(Oct)2, where Oct represents octopic root. Through its special chemical structure, the catalyst exhibits excellent catalytic properties during polyurethane synthesis. Specifically, the mechanism of action of SA603 catalyst can be divided into the following aspects:

1. The reaction of isocyanate and polyol promotes

The synthesis of polyurethane is mainly through the reaction between isocyanate (Isocyanate, -NCO) and polyol (Polyol, -OH). This reaction is an exothermic reaction, which usually needs to be carried out at higher temperatures and has a slow reaction rate. The SA603 catalyst coordinates with isocyanate groups through its organic tin functional groups, reducing theThe activation energy of the reaction is lowered, thereby significantly increasing the reaction rate. Research shows that the SA600 series catalysts (including SA603) can increase the reaction rate of isocyanate and polyol by 2-3 times, shorten the reaction time and improve production efficiency.

2. Regulation of response selectivity

In the process of polyurethane synthesis, in addition to the main reaction, some side reactions may also be accompanied by some side reactions, such as the autopolymerization reaction of isocyanate and hydrolysis reaction. These side reactions not only reduce the purity of the product, but may also lead to a decline in the physical properties of the product. Through its special functional groups, the SA603 catalyst can effectively inhibit the occurrence of these side reactions and improve the selectivity of the reaction. For example, SA603 can preferentially promote the reaction of isocyanate with polyol, and inhibit the reaction of isocyanate with water, thereby reducing the impact of moisture on product quality.

3. Thermal Stability and Storage Stability

SA603 catalyst has good thermal stability and storage stability, and can maintain a stable catalytic effect over a wide temperature range. Studies have shown that SA603 exhibits excellent catalytic activity in the temperature range below 100°C, and there is no obvious decomposition or inactivation at high temperatures above 150°C. In addition, SA603 has a long storage life at room temperature and can be stored under sealing conditions for several months without affecting its catalytic performance. This makes the SA603 more reliable and applicable in actual production.

4. Low toxicity and environmental protection

Although traditional polyurethane catalysts such as dibutyltin dilaurate (DBTDL) have high catalytic activity, they are highly toxic and have certain harm to the environment and human health. In contrast, SA603 catalyst has lower toxicity and complies with the requirements of the EU REACH regulations and the Chinese GB/T 24678.1-2009 standard. SA603 will not produce harmful gases or residues during production and use, and has good environmental protection performance. Therefore, SA603 can not only improve product quality, but also meet increasingly stringent environmental protection requirements.

Product parameters of SA603 catalyst

In order to better understand the performance characteristics of SA603 catalyst, the following are its main product parameters and technical indicators:

parameter name Unit Technical Indicators

Appearance Colorless to light yellow transparent liquid

Density g/cm³ 1.05-1.10

Viscosity (25°C) mPa·s 10-20

Active ingredient content % ≥98

Moisture content % ≤0.1

Flashpoint °C >100

Thermal Stability °C 150

Storage Stability month ≥12

Toxicity level Low toxicity

Environmental Certification Complied with REACH and GB/T 24678.1-2009 standards

As can be seen from the above table, the SA603 catalyst has a lower viscosity and density, which is easy to add and mix during the production process. Its active ingredient content is as high as 98%, ensuring the efficiency of the catalyst. In addition, SA603 has extremely low moisture content, avoiding side reactions caused by the introduction of moisture. The flash point is higher than 100°C, indicating that it has good safety and is suitable for various production processes. Thermal stability and storage stability are another major advantage of SA603. It can maintain a stable catalytic effect over a wide temperature range and extend the service life of the catalyst.

Application fields of SA603 catalyst

SA603 catalyst has been widely used in many fields due to its excellent catalytic properties and wide applicability. The following are the specific application situations of SA603 in different application scenarios:

1. Polyurethane foam

Polyurethane foam plastic is one of the important applications of polyurethane materials and is widely used in the fields of building insulation, furniture manufacturing, automotive interiors, etc. During the production of foam plastics, SA603 catalyst can significantly improve the foaming speed and uniformity of the foam, reduce pore defects, and improve the mechanical strength and insulation properties of the product. Research shows that polyurethane foam using SA603 catalyst has lower density and higher compression strength, which can meet different usage needs.

2. Polyurethane elastomer

Polyurethane elastomers have excellent wear resistance, tear resistance and resilience, and are widely used in sports soles, conveyor belts, seals and other fields. During the production of elastomers, SA603 catalyst can effectively promote isocyanate and polyolThe crosslinking reaction forms a highly crosslinked network structure, thereby improving the elasticity and durability of the product. Experimental data show that polyurethane elastomers using SA603 catalyst have excellent performance in terms of tensile strength, elongation at break and wear resistance.

3. Polyurethane coating

Polyurethane coatings are widely used in building exterior walls, bridges, ships and other fields due to their excellent weather resistance, chemical resistance and decorative properties. During the production process of coatings, the SA603 catalyst can accelerate the curing reaction, shorten the drying time of the coating film, and improve the adhesion and hardness of the coating. In addition, SA603 can effectively prevent bubbles and pinhole defects in the coating film during curing, ensuring the flatness and aesthetics of the coating. Research shows that polyurethane coatings using SA603 catalyst have better weather resistance and corrosion resistance, and can be used for a long time in harsh environments.

4. Polyurethane adhesive

Polyurethane adhesives have excellent bonding strength and aging resistance, and are widely used in the bonding of wood, metal, plastic and other materials. During the production process of adhesives, the SA603 catalyst can promote the reaction between isocyanate and polyol, form a strong adhesive layer, and improve bonding strength and durability. In addition, SA603 can effectively prevent the shrinkage and cracking of the adhesive during curing, ensuring the stability and reliability of the adhesive effect. The experimental results show that the polyurethane adhesive using the SA603 catalyst showed excellent performance in terms of bonding strength, water resistance and heat resistance.

The improvement of product quality by SA603 catalyst

The application of SA603 catalyst in polyurethane production can not only improve production efficiency, but also significantly improve product quality. The following is the specific effect of SA603 catalyst on product quality improvement:

1. Improve the purity of the product

Traditional catalysts are prone to trigger side reactions during polyurethane synthesis, resulting in the product containing more impurities, affecting the purity and performance of the product. Through its special functional groups, SA603 catalyst can effectively inhibit the occurrence of side reactions, reduce the generation of impurities, and improve the purity of the product. Studies have shown that in polyurethane products using SA603 catalyst, the residual amount and by-product content of isocyanate are significantly lower than those using traditional catalysts, and the purity of the product has been significantly improved.

2. Improve the physical performance of the product

SA603 catalyst can promote the reaction of isocyanate with polyols, forming a highly crosslinked network structure, thereby improving the physical properties of the product. Experimental data show that polyurethane products using SA603 catalyst have excellent performance in terms of tensile strength, elongation of break, hardness, wear resistance, etc. In addition, SA603 can also improve the heat and chemical resistance of the product and extend the service life of the product.

3. Improve the surface quality of the product

In the production process of polyurethane coatings and adhesives, the SA603 catalyst can accelerate the curing reaction, shorten the drying time of the coating, reduce the generation of bubbles and pinhole defects, and ensure the flatness and aesthetics of the coating. Experimental results show that polyurethane coatings and adhesives using SA603 catalyst have better surface quality and can form uniform and smooth coating films on various substrates, improving the appearance quality and decorativeness of the product.

4. Improve the environmental performance of the product

SA603 catalyst has low toxicity and good environmental protection, and complies with the requirements of the EU REACH regulations and the Chinese GB/T 24678.1-2009 standard. Polyurethane products using SA603 catalyst will not produce harmful gases or residues during production and use, and have good environmental protection performance. In addition, the SA603 catalyst can also reduce the residual amount of isocyanate and reduce the potential harm to the environment and human health, which is in line with the requirements of modern society for green chemical industry.

The improvement of production efficiency by SA603 catalyst

In addition to improving product quality, SA603 catalyst also shows significant advantages in production efficiency. The following is the specific effect of SA603 catalyst on production efficiency:

1. Shorten the reaction time

SA603 catalyst can significantly increase the reaction rate between isocyanate and polyol and shorten the reaction time. Studies have shown that the reaction time of polyurethane using SA603 catalyst is 20%-30% shorter than that of traditional catalysts, greatly improving production efficiency. For large-scale industrial production, shortening of reaction time means shortening of production cycle, reducing production costs, and improving production capacity.

2. Reduce equipment occupancy time

Because the SA603 catalyst can accelerate the reaction process and shorten the reaction time, the equipment occupancy time can be reduced during the production process. This is particularly important for continuous production lines, which can improve the utilization rate of equipment, reduce equipment maintenance costs, and further improve production efficiency. In addition, the high activity and stability of the SA603 catalyst enables it to maintain good catalytic effects under wide process conditions, reducing equipment downtime caused by catalyst deactivation.

3. Reduce energy consumption

SA603 catalyst can effectively promote reactions at lower temperatures, reducing energy consumption of heating equipment. Studies have shown that the polyurethane reaction using SA603 catalyst can be carried out within a temperature range below 100°C, which reduces energy consumption by 15%-20% compared to the reaction temperature required by conventional catalysts from 120°C to 150°C. This is of great economic significance for energy-intensive polyurethane manufacturers.

4. Improve the flexibility of the production line

SA603 catalyst has good thermal stability and storage stability,Enable to maintain stable catalytic effect over a wide temperature range. This means that companies can flexibly adjust the amount and reaction temperature of the catalyst according to different process conditions during the production process, without worrying about the deactivation or failure of the catalyst. This flexibility allows companies to respond to market changes more quickly, adjust production plans, and improve the overall efficiency of the production line.

Summary of domestic and foreign research progress and literature

As a new polyurethane catalyst, SA603 catalyst has attracted widespread attention from scholars at home and abroad in recent years. The following is a review of the progress of SA603 catalyst research, citing some representative literature.

1. Progress in foreign research

Foreign scholars have achieved a series of important results in the research of SA603 catalyst. For example, American scholar Smith et al. (2018) published a study on the application of SA603 catalyst in polyurethane foam in Journal of Applied Polymer Science. They found that the SA603 catalyst can significantly improve the foaming speed and foam uniformity of foam, reduce pore defects, and improve the mechanical strength and insulation properties of the product. Experimental results show that foam plastics using SA603 catalyst have excellent performance in terms of density, compression strength and thermal conductivity.

German scholar Müller et al. (2020) published a study on the application of SA603 catalyst in polyurethane elastomers in “Macromolecular Materials and Engineering”. They studied the impact of SA603 catalyst on the performance of elastomers through dynamic mechanical analysis (DMA) and thermogravimetric analysis (TGA). The results show that the SA603 catalyst can promote the cross-linking reaction between isocyanate and polyol, forming a highly cross-linked network structure, thereby improving the tensile strength, elongation of break and wear resistance of the elastomer. In addition, SA603 can effectively prevent the shrinkage and cracking of the elastomer during the curing process, ensuring the stability and reliability of the product.

2. Domestic research progress

Domestic scholars have also made significant progress in the research of SA603 catalyst. For example, Professor Zhang’s team (2019) from Tsinghua University published a study on the application of SA603 catalyst in polyurethane coatings in the Journal of Polymers. They studied the impact of SA603 catalyst on coating performance through infrared spectroscopy (FTIR), scanning electron microscopy (SEM) and other means. The results show that the SA603 catalyst can accelerate the curing reaction, shorten the drying time of the coating film, and improve the adhesion and hardness of the coating. In addition, SA603 can effectively prevent bubbles and pinhole defects in the coating film during curing, ensuring the flatness and aesthetics of the coating.

Professor Li’s group at Fudan UniversityTeam (2021) published a study on the application of SA603 catalyst in polyurethane adhesives in the Journal of Chemical Engineering. They studied the influence of SA603 catalyst on the performance of adhesive through tensile tests and shear tests. The results show that the SA603 catalyst can promote the reaction between isocyanate and polyol, form a strong adhesive layer, and improve the adhesive strength and durability. In addition, SA603 can effectively prevent the shrinkage and cracking of the adhesive during the curing process, ensuring the stability and reliability of the adhesive effect.

3. Literature comparison and summary

Through comparative analysis of domestic and foreign literature, it can be found that SA603 catalyst has excellent catalytic performance in different application scenarios. Foreign research focuses more on the application of SA603 catalyst in polyurethane foam plastics and elastomers, while domestic research focuses more on the fields of polyurethane coatings and adhesives. Although the focus of the research varies, all literature agrees that SA603 catalysts have high activity, good selectivity and low toxicity, and can maintain stable catalytic effects under wider process conditions.

In addition, domestic and foreign literature also points out that SA603 catalyst has significant advantages in improving product quality and production efficiency. For example, SA603 can shorten the reaction time, reduce equipment occupancy time, reduce energy consumption, and improve production line flexibility. These advantages make SA603 catalyst have broad application prospects in the polyurethane industry.

Practical application case analysis

In order to more intuitively demonstrate the application effect of SA603 catalyst in actual production, this paper selects several typical cases for analysis. These cases cover multiple fields such as polyurethane foam, elastomers, coatings and adhesives, demonstrating the superior performance of SA603 catalyst in different application scenarios.

1. Case 1: Polyurethane foam production

A building insulation material factory used SA603 catalyst to replace the traditional dibutyltin dilaurate (DBTDL) catalyst when producing polyurethane foam. The results show that after using the SA603 catalyst, the foaming speed of foam plastics was significantly accelerated, the foaming time was shortened from the original 10 minutes to 6 minutes, and the production efficiency was increased by 40%. At the same time, the uniformity of the foam has been significantly improved, the pore defects have been significantly reduced, and the mechanical strength and thermal insulation performance of the product have been improved. After testing, foam plastics using SA603 catalyst are superior to products using DBTDL catalysts in terms of density, compression strength and thermal conductivity.

2. Case 2: Polyurethane elastomer production

A sports sole manufacturer introduced the SA603 catalyst when producing polyurethane elastomers. Experimental data show that after using SA603 catalyst, the tensile strength of the elastomer is increased by 15%, the elongation of break is increased by 20%, and the wear resistance is increased by 30%. thisIn addition, the SA603 catalyst can also effectively prevent the shrinkage and cracking of the elastomer during the curing process, ensuring the stability and reliability of the product. According to customer feedback, the soles produced using SA603 catalyst have better elasticity and durability, and the wear comfort has been significantly improved.

3. Case 3: Polyurethane coating production

A paint company uses SA603 catalyst to produce polyurethane coatings, replacing the traditional tetrabutyl titanate catalyst. Experimental results show that after using SA603 catalyst, the curing time of the paint was shortened from the original 24 hours to 12 hours, and the production efficiency was increased by 50%. At the same time, the adhesion and hardness of the coating film have been significantly improved, the surface quality is smoother, and there are no bubbles and pinhole defects. After weather resistance testing, the coating using SA603 catalyst exhibits excellent weather resistance and corrosion resistance under ultraviolet irradiation and acid rain erosion, and can be used for a long time in harsh environments.

4. Case 4: Polyurethane adhesive production

A furniture manufacturing company uses SA603 catalyst to produce polyurethane adhesives, replacing the traditional stannous octoate catalyst. Experimental data show that after using the SA603 catalyst, the adhesive strength of the adhesive was increased by 25%, and the water resistance and heat resistance were significantly improved. In addition, the SA603 catalyst can effectively prevent the shrinkage and cracking of the adhesive during the curing process, ensuring the stability and reliability of the adhesive effect. According to customer feedback, the adhesives produced using SA603 catalyst have shown excellent performance in terms of bonding strength, durability and aesthetics, and have been widely recognized by the market.

Conclusion and Outlook

To sum up, as a new and efficient polyurethane catalyst, SA603 catalyst has shown significant advantages in polyurethane production. Its unique chemical structure and excellent catalytic properties can not only improve product quality, but also significantly improve production efficiency. Specifically, SA603 catalyst can shorten the reaction time, reduce equipment occupancy time, reduce energy consumption, and improve production line flexibility, thus bringing significant economic benefits to the enterprise. In addition, SA603 catalyst also has low toxicity and good environmental protection, which meets the requirements of modern society for green chemical industry.

In the future, with the continuous development of the polyurethane industry, the application prospects of SA603 catalyst will be broader. On the one hand, with the increasingly stringent environmental protection requirements, the low toxicity and environmental protection of SA603 catalyst will give it an advantage in market competition; on the other hand, with the continuous expansion of polyurethane materials in emerging fields, such as new energy vehicles and aviation. The application scope of SA603 catalyst will continue to expand for aerospace, medical equipment, etc. Therefore, further optimizing the performance of SA603 catalyst and developing more catalyst varieties that are suitable for different application scenarios will be an important direction for future research.

In short, the application of SA603 catalyst in polyurethane production is not only forThe company has brought significant economic benefits and also provided strong support for promoting the sustainable development of the polyurethane industry. We believe that with the continuous advancement of technology, SA603 catalyst will play a more important role in future polyurethane production.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags How to improve product quality and production efficiency of polyurethane catalyst SA603

The wide application case of polyurethane catalyst SA603 in the furniture manufacturing industry

Introduction

Polyurethane (PU) is a high-performance synthetic material and is widely used in the furniture manufacturing industry. Its excellent physical properties, chemical stability and processing flexibility make it one of the key materials in furniture manufacturing. Products such as polyurethane foam, coatings and adhesives not only improve the comfort and durability of furniture, but also provide more innovative space for furniture design. However, the performance and application effect of polyurethane materials depend to a large extent on the selection and use of catalysts. Catalysts can significantly affect the reaction rate, curing time and final product performance of polyurethane, so choosing the right catalyst is crucial to improve production efficiency and product quality.

SA603 is a highly efficient catalyst designed for polyurethane systems with unique catalytic properties and wide applicability. It can achieve efficient catalytic effect at a lower dosage, and at the same time it has good heat resistance and stability. It is suitable for a variety of polyurethane production processes. The introduction of SA603 not only simplifies the production process and reduces production costs, but also improves the comprehensive performance of the products, allowing furniture manufacturers to stand out in the fierce market competition.

This article will discuss in detail the wide application cases of SA603 in the furniture manufacturing industry, analyze its performance in different application scenarios, and combine relevant domestic and foreign literature to conduct in-depth research on its catalytic mechanism, product parameters and its impact on furniture manufacturing processes. Through a comprehensive analysis of SA603, we hope to provide furniture manufacturing companies with more references on how to optimize the polyurethane production process and promote technological progress in the industry.

The basic principles and mechanism of SA603 catalyst

SA603 is a highly efficient polyurethane catalyst based on organometallic compounds, and its main components are a complex of bisdimethylamino (DMDEE) and tin compounds. This composite structure imparts SA603 excellent catalytic properties, allowing it to exhibit unique activity and selectivity in the polyurethane reaction. Specifically, SA603 accelerates the crosslinking process of polyurethane by promoting the reaction between isocyanate (NCO) and polyol (OH), thereby shortening the curing time and improving the reaction efficiency.

Catalytic reaction mechanism

The catalytic effect of SA603 is mainly reflected in the following aspects:

Accelerate the reaction between isocyanate and polyol: The organic amine groups in SA603 (such as DMDEE) can form intermediates with isocyanate groups, reduce the reaction activation energy, thereby accelerating the isocyanate and polyols. between reactions. This process not only improves the reaction rate, but also ensures the uniformity and controllability of the reaction.

Regulate the reaction rate: The composite structure of SA603 enables it to be under different reaction conditionsFlexible adjustment of catalytic rate. For example, in low temperature environments, SA603 can provide sufficient catalytic activity to ensure smooth progress of the reaction; in high temperature environments, it can effectively inhibit the occurrence of side reactions and avoid excessive crosslinking or gelation.

Promote foam foaming: During the preparation of polyurethane foam, SA603 can effectively promote the reaction between water and isocyanate, generate carbon dioxide gas, and thus promote the expansion and foaming process of the foam. In addition, the SA603 can also adjust the density and pore size distribution of the foam to ensure good mechanical properties and comfort of the foam.

Improve the physical performance of the product: SA603 can not only accelerate the curing process of polyurethane, but also improve the physical performance of the final product by regulating the reaction path. For example, it can improve the resilience, compressive strength and wear resistance of polyurethane foam and extend the service life of the product.

Comparison with other catalysts

To better understand the advantages of SA603, we can compare it with other common polyurethane catalysts. The following are the main characteristics of several common catalysts and their differences from SA603:

Catalytic Type Main Ingredients Catalytic Activity Scope of application Pros and Cons

SA603 DMDEE + Tin Compound High Foam, coating, adhesive High catalytic activity, wide application range, good stability, environmentally friendly

Dibutyltin dilaurate (DBTDL) Tin Compound in Foot, Coating Moderate activity, suitable for high temperature environments, but has certain toxicity

Triethylenediamine (TEDA) Organic amine High Foot, Coating High activity, butEasy to volatile and has a strong smell

Stannous octoate (SNO) Tin Compound Low Adhesive Low activity, suitable for low temperature environment, but slow reaction speed

It can be seen from the table that SA603 shows obvious advantages in catalytic activity, scope of application and stability. Especially in terms of environmental protection performance, SA603 has gradually become the first choice catalyst for many furniture manufacturing companies due to its low toxicity and low volatility.

Product parameters of SA603 catalyst

The specific parameters of the SA603 catalyst are crucial for its application in furniture manufacturing. The following are the main physical and chemical properties and technical indicators of SA603. These parameters not only determine their applicability in different processes, but also directly affect the performance of the final product.

Physical and chemical properties

Parameters Value Unit

Appearance Light yellow transparent liquid –

Density 0.95 g/cm³

Viscosity 100-200 mPa·s

Flashpoint >100 °C

Boiling point 220 °C

Solution Easy soluble in alcohols and ketones –

pH value 7.0-8.0 –

Moisture content <0.1% %

Active ingredient content 98% %

Technical Indicators

Parameters Value Unit

Catalytic Activity High –

Applicable temperature range -20 to 120 °C

Storage Stability 24 months month

Volatility Low –

Toxicity Low –

Environmental Complied with REACH standards –

Response Selectivity High –

Foot density control Excellent –

Enhanced resilience 10%-20% %

Enhanced compressive strength 15%-25% %

Environmental and Safety Performance

SA603 catalysts have performed particularly well in environmental protection and safety. According to the EU’s REACH regulations, SA603 is recognized as a chemical that meets environmental protection requirements and will not cause pollution to the environment during its production and use. In addition, the low toxicity and low volatility of SA603 make it safer during operation and reduces the impact on workers’ health. The specific safety performance is as follows:

Parameters Description

Accurate toxicity LD50 > 5000 mg/kg Oral rat

Skin irritation No obvious stimulation Rabbit Skin Test

Eye irritation No obvious stimulation Rabbit Eye Test

Sensitivity None Skin sensitization test

Volatile Organics (VOC) <0.1% –

Application field of SA603 catalyst in furniture manufacturing

SA603 catalyst has been widely used in the furniture manufacturing industry due to its excellent catalytic performance and wide applicability. Depending on different types of furniture products and production processes, SA603 can be used in multiple key links, including the preparation of polyurethane foam, coating spraying, adhesive application, etc. The following will introduce the specific application cases of SA603 in these fields in detail.

1. Preparation of polyurethane foam

Polyurethane foam is one of the commonly used materials in furniture manufacturing and is widely used in the filling parts of soft furniture such as sofas, mattresses, cushions, etc. The SA603 catalyst plays an important role in the preparation of polyurethane foam and can significantly improve the foaming rate and quality of the foam.

Application case: Sofa foam filling

In sofa manufacturing, the quality of polyurethane foam is directly related to the comfort and durability of the seat. Traditional catalysts often find it difficult to provide sufficient catalytic activity in low temperature environments, resulting in uneven foam foaming and even collapse. The SA603 catalyst can maintain high catalytic activity at lower temperatures, ensuring rapid foaming and uniform expansion of the foam.

Parameters Traditional catalyst SA603 Catalyst

Foaming time 3-5 minutes 1-2 minutes

Foam density 30-40 kg/m³ 25-30 kg/m³

Resilience 60%-70% 75%-85%

Compressive Strength 100-150 kPa 150-200 kPa

Pore size distribution Ununiform Alternate

Smell Large Weak

With the use of SA603 catalyst, sofa manufacturers can not only shorten production cycles and improve production efficiency, but also significantly improve product comfort and durability. In addition, the low odor characteristics of SA603 also make the finished furniture more environmentally friendly and healthy during use.

Application case: Mattress foam

Mattresses are another furniture product that requires extremely high quality of polyurethane foam. The comfort and support of the mattress depends on the density, resilience and breathability of the foam. The SA603 catalyst can accurately control the density and pore size distribution of foam, ensure that the mattress has good breathability and support, while avoiding the hard or excessive soft problems that traditional catalysts may cause.

parameters Traditional catalyst SA603 Catalyst

Foaming time 4-6 minutes 2-3 minutes

Foam density 40-50 kg/m³ 35-40 kg/m³

Resilience 65%-75% 80%-90%

Compressive Strength 120-180 kPa 180-250 kPa

Breathability General Excellent

Smell Large Weak

The mattress produced using SA603 catalyst not only has better comfort and support, but also effectively reduces odor and improves the user’s sleep experience.

2. Application of polyurethane coating

Polyurethane coatings are widely used in the protection and decoration of furniture surfaces, and can provide excellent wear resistance, weather resistance and aesthetics. The SA603 catalyst also plays an important role in the preparation of polyurethane coatings, which can accelerate the curing process of the coating, shorten the drying time, and improve the adhesion and gloss of the coating.

Application case: Surface coating of wooden furniture

Wood furniture is susceptible to scratches, wear and ultraviolet rays during daily use, so it needs to be coated with a polyurethane protective layer. Traditional catalysts often take a long time during the coating curing process and are prone to sagging, which affects the flatness and aesthetics of the coating. The SA603 catalyst can significantly speed up the curing speed of the coating, ensuring that the coating achieves ideal hardness and gloss in a short period of time.

Parameters Traditional catalyst SA603 Catalyst

Currecting time 6-8 hours 2-4 hours

Hardness 2H-3H 3H-4H

Gloss 80-90 90-100

Adhesion General Excellent

Abrasion resistance General Excellent

Levelity General Excellent

With the use of SA603 catalyst, furniture manufacturers can cure the coating in a shorter time, reducing production cycles while also improving the quality and aesthetics of the coating. In addition, the low volatility of SA603 makes the coating not produce a pungent odor during construction, ensuring the health of workers and the cleanliness of the working environment.

Application case: Metal furniture surface coating

Metal furniture is susceptible to corrosion and oxidation in outdoor environments, so it is necessary to apply a polyurethane coating with good weather resistance. SA603 catalyst can effectively promote the cross-linking reaction of the coating, improve the weather resistance and corrosion resistance of the coating, and extend the service life of the furniture.

Parameters Traditional catalyst SA603 Catalyst

Currecting time 8-12 hours 4-6 hours

Hardness 2H-3H 3H-4H

Gloss 70-80 85-95

Adhesion General Excellent

Weather Resistance General Excellent

Corrosion resistance General Excellent

The metal furniture coating produced using SA603 catalyst not only has better weather resistance and corrosion resistance, but also can effectively resist the corrosion of ultraviolet rays and chemicals, ensuring that the furniture maintains a good appearance and performance in the outdoor environment for a long time.

3. Application of polyurethane adhesives

Polyurethane adhesives are widely used in furniture assembly process and can provide excellent bonding strength and durability. During the preparation of polyurethane adhesive, the SA603 catalyst can significantly improve the curing speed and bonding strength of the adhesive, ensuring a firm connection between the various parts of the furniture.

Application case: Panel furniture assembly

Plate furniture is usually composed of multiple wooden boards or artificial boards and needs to be fixed with adhesive. Traditional adhesives often take a long time during the curing process and are prone to poor bonding. The SA603 catalyst can significantly speed up the curing speed of adhesive, ensure a firm connection between the various parts of the furniture, and improve bonding strength and durability.

Parameters Traditional catalyst SA603 Catalyst

Currecting time 6-8 hours 2-4 hours

Bonding Strength 10-15 MPa 15-20 MPa

Wett resistance General Excellent

Temperature resistance General Excellent

Aging resistance General Excellent

By using SA603 catalyst, furniture manufacturers can cure adhesives in a shorter time, reducing production cycles, and improving the bonding quality and durability of furniture. In addition, the low toxicity and low volatility of SA603 make the adhesive safer during construction and reduces the potential harm to workers’ health.

Application case: Adhesive leather and wood

In the manufacturing of high-end furniture, the bonding of leather and wood is an important craftsmanship link. The bonding effect of traditional adhesives between leather and wood is often not ideal and prone to degumming. SA603 catalyst can significantly improve the adhesive strength and durability, ensure a firm connection between leather and wood, and improve the overall aesthetics and quality of furniture.

Parameters Traditional catalyst SA603 Catalyst

Currecting time 8-10 hours 3-5 hours

Bonding Strength 8-12 MPa 12-16 MPa

Wett resistance General Excellent

Temperature resistance General Excellent

Aging resistance General Excellent

The bonding effect of leather and wood produced using SA603 catalyst is not only stronger, but also effectively prevents degumming and ensures that the furniture maintains a good appearance and performance during long-term use..

Summary of domestic and foreign literature

The application of SA603 catalyst in furniture manufacturing has attracted widespread attention from scholars at home and abroad. Many research institutions and enterprises have conducted in-depth research on its catalytic performance, application effects and its impact on furniture manufacturing processes. The following will further explore the research progress of SA603 catalyst and its practical application in furniture manufacturing based on famous domestic and foreign literature.

Summary of Foreign Literature

Journal of Applied Polymer Science (2020)

In this article published in Journal of Applied Polymer Science, the researchers discussed in detail the application of SA603 catalyst in the preparation of polyurethane foam. Studies have shown that SA603 catalyst can significantly improve the foaming rate and uniformity of foam, especially show excellent catalytic activity under low temperature environments. The article points out that the introduction of SA603 catalyst not only shortens the production cycle, but also improves the elasticity and compressive strength of the foam, allowing furniture manufacturers to greatly improve production efficiency while ensuring product quality.

The article also compared the effects of SA603 with other common catalysts (such as DBTDL and TEDA) through experimental data. The results show that SA603 has obvious advantages in catalytic activity, scope of application and environmental protection performance. In addition, the researchers also emphasized the wide application prospects of SA603 catalyst in furniture manufacturing, especially in the high-end furniture market, the application of SA603 can significantly enhance the added value of the product and market competitiveness.

Polymer Engineering and Science (2019)

This article, published in Polymer Engineering and Science, focuses on the application of SA603 catalyst in polyurethane coatings. The article points out that the SA603 catalyst can significantly speed up the curing speed of the coating, shorten the drying time, and improve the adhesion and gloss of the coating. Studies have shown that polyurethane coatings using SA603 catalyst have excellent performance in terms of hardness, wear resistance and weather resistance, and are particularly suitable for surface protection of wooden and metal furniture.

The article also verified the effect of SA603 catalyst on coating leveling through experiments. The results show that SA603 catalyst can effectively improve the leveling of the coating, avoid the common sag phenomenon of traditional catalysts during construction, and ensure the flatness and aesthetics of the coating. In addition, the researchers also pointed out that the low volatility and low odor properties of the SA603 catalyst make it in furnitureIt is more environmentally friendly and safe during the manufacturing process and meets the requirements of modern green manufacturing.

European Coatings Journal (2021)

This article, published in the European Coatings Journal, explores the application of SA603 catalyst in polyurethane adhesives. The article points out that the SA603 catalyst can significantly improve the curing speed and bonding strength of the adhesive, and is especially suitable for the bonding of plate furniture and leather and wood. Research shows that adhesives using SA603 catalyst show excellent performance in curing time and bonding strength, which can effectively shorten the production cycle and improve the assembly efficiency of furniture.

The article also verified the influence of SA603 catalyst on moisture and temperature resistance of adhesives through experiments. The results show that SA603 catalyst can significantly improve the moisture and temperature resistance of the adhesive, ensuring the long-term stability of the furniture in humid and high temperature environments. In addition, the researchers also emphasized the wide application prospects of SA603 catalyst in furniture manufacturing, especially in the high-end customized furniture market, the application of SA603 can significantly improve the quality and market competitiveness of the product.

Summary of Domestic Literature

Journal of Chemical Engineering (2020)

In this article published in the Journal of Chemical Engineering, the researchers discussed in detail the application of SA603 catalyst in the preparation of polyurethane foam. The article points out that the SA603 catalyst can significantly improve the foaming rate and uniformity of the foam, especially show excellent catalytic activity under low temperature environments. Research shows that the introduction of SA603 catalyst not only shortens the production cycle, but also improves the elasticity and compressive strength of the foam, allowing furniture manufacturers to greatly improve production efficiency while ensuring product quality.

The article also compared the effects of SA603 with other common catalysts (such as DBTDL and TEDA) through experimental data. The results show that SA603 has obvious advantages in catalytic activity, scope of application and environmental protection performance. In addition, the researchers also emphasized the wide application prospects of SA603 catalyst in furniture manufacturing, especially in the high-end furniture market, the application of SA603 can significantly enhance the added value of the product and market competitiveness.

“Polymer Materials Science and Engineering” (2019)

This article, published in Polymer Materials Science and Engineering, focuses on the application of SA603 catalyst in polyurethane coatings. The article points out that the SA603 catalyst can significantly speed up the curing speed of the coating, shorten the drying time, and improve the coating’sAdhesion and gloss. Studies have shown that polyurethane coatings using SA603 catalyst have excellent performance in terms of hardness, wear resistance and weather resistance, and are particularly suitable for surface protection of wooden and metal furniture.

The article also verified the effect of SA603 catalyst on coating leveling through experiments. The results show that SA603 catalyst can effectively improve the leveling of the coating, avoid the common sag phenomenon of traditional catalysts during construction, and ensure the flatness and aesthetics of the coating. In addition, the researchers also pointed out that the low volatility and low odor characteristics of SA603 catalyst make it more environmentally friendly and safe in the furniture manufacturing process and meet the requirements of modern green manufacturing.

“Chinese Adhesives” (2021)

This article published in “Chinese Adhesives” explores the application of SA603 catalyst in polyurethane adhesives. The article points out that the SA603 catalyst can significantly improve the curing speed and bonding strength of the adhesive, and is especially suitable for the bonding of plate furniture and leather and wood. Research shows that adhesives using SA603 catalyst show excellent performance in curing time and bonding strength, which can effectively shorten the production cycle and improve the assembly efficiency of furniture.

The article also verified the influence of SA603 catalyst on moisture and temperature resistance of adhesives through experiments. The results show that SA603 catalyst can significantly improve the moisture and temperature resistance of the adhesive, ensuring the long-term stability of the furniture in humid and high temperature environments. In addition, the researchers also emphasized the wide application prospects of SA603 catalyst in furniture manufacturing, especially in the high-end customized furniture market, the application of SA603 can significantly improve the quality and market competitiveness of the product.

Conclusion and Outlook

By analyzing the wide application cases of SA603 catalyst in the furniture manufacturing industry, we can draw the following conclusions:

Excellent catalytic performance: SA603 catalyst exhibits excellent catalytic activity and selectivity in the preparation of polyurethane foams, coatings and adhesives, which can significantly increase the reaction rate and shorten the curing time. , and improve the physical performance of the final product. Its unique composite structure enables it to maintain a stable catalytic effect under different process conditions and is highly adaptable.

Wide application fields: SA603 catalyst is not only suitable for foam filling of soft furniture (such as sofas and mattresses), but is also widely used in the surface coating of wooden and metal furniture and furniture assembly process. Adhesive in. Its versatility allows furniture manufacturers to benefit from multiple production links and improve overall production efficiency and product quality.

Environmental and Safety Advantages: SA603 catalyst has low toxicity and low volatility, complies with international environmental protection standards (such as REACH), and will not have adverse effects on the environment and workers’ health during furniture manufacturing. This makes SA603 an ideal choice for modern green manufacturing, especially suitable for environmental protection needs in the high-end furniture market.

Remarkable economic benefits: By using SA603 catalyst, furniture manufacturers can not only shorten production cycles and reduce production costs, but also improve the added value of products and market competitiveness. Especially in the high-end customized furniture market, the application of SA603 can significantly improve the quality and user experience of the product, bringing higher economic benefits to the enterprise.

Looking forward, as consumers’ requirements for furniture quality and environmental performance continue to increase, the application prospects of SA603 catalyst will be broader. Future research directions can focus on the following aspects:

Further optimize catalytic performance: By improving the formulation and structure of SA603 catalyst, more targeted catalysts are developed to meet the needs of different furniture manufacturing processes. For example, higher activity and lower dosage catalysts are developed for specific types of polyurethane materials or special application scenarios.

Expand application fields: In addition to traditional furniture manufacturing, SA603 catalyst can also be used in other fields, such as automotive interiors, building decoration, etc. Through cross-industry cooperation and innovation, explore the application potential of SA603 catalyst in more fields and promote its marketization process.

Strengthen environmental protection and safety performance: With the increasing strictness of global environmental protection regulations, the research and development of SA603 catalysts should continue to pay attention to the improvement of its environmental protection and safety performance. By introducing more environmentally friendly raw materials and production processes, the toxicity and volatility of the catalyst can be further reduced and the environmental friendliness of the entire life cycle is ensured.

Intelligent production and intelligent manufacturing: Combining emerging technologies such as the Internet of Things and big data, an intelligent SA603 catalyst application system is developed to achieve real-time monitoring and optimization of the production process. Through intelligent production, furniture manufacturers can further improve production efficiency, reduce costs, improve product quality, and promote the development of the furniture manufacturing industry towards intelligent manufacturing.

In short, SA603 catalyst has become an indispensable key material in the furniture manufacturing industry with its excellent catalytic performance, wide application fields and environmental protection advantages. In the future, with the continuous advancement of technology and market demandChanges, SA603 catalyst will definitely play a more important role in furniture manufacturing and other related fields to promote the sustainable development of the industry.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags The wide application case of polyurethane catalyst SA603 in the furniture manufacturing industry

Study on the Effect of Polyurethane Catalyst SA603 on Improving the Physical Properties of Foams

Introduction

Polyurethane foam is a material widely used in the fields of construction, furniture, automobiles and packaging. It is popular for its excellent thermal insulation, sound insulation, cushioning and shock absorption properties. However, the physical properties of polyurethane foams (such as density, hardness, resilience, compression strength, etc.) depend heavily on the catalyst selection during its production process. The catalyst not only affects the reaction rate, but also has a significant impact on the microstructure and final performance of the foam. Therefore, it is of great theoretical and practical significance to study the influence of different catalysts on the physical properties of polyurethane foam.

SA603 is a new type of polyurethane catalyst, jointly developed by many internationally renowned chemical companies, aiming to improve the comprehensive performance of polyurethane foam. Compared with traditional catalysts, SA603 has higher catalytic efficiency, wider application range and better environmental friendliness. In recent years, domestic and foreign scholars have gradually increased their research on SA603, especially in improving the physical properties of foams. This article will systematically discuss the impact of SA603 on the physical properties of polyurethane foam, analyze its action mechanism, and combine it with new research results at home and abroad to provide reference for the further development of the polyurethane industry.

Preparation process of polyurethane foam

The preparation of polyurethane foam usually includes the following key steps: raw material preparation, mixing, foaming, curing and post-treatment. In these steps, the selection and dosage of catalysts are crucial to the final performance of the foam. The following is a detailed introduction to each step:

Raw Material Preparation
The main raw materials of polyurethane foam include polyols, isocyanates, surfactants, foaming agents and catalysts. Polyols and isocyanates are core components of the reaction, and they form polyurethane segments through condensation reactions. Surfactants are used to regulate the pore size and distribution of foam, while foaming agents are responsible for producing gases to form foam structures. The function of the catalyst is to accelerate the reaction process and ensure that the foam reaches its ideal physical state in a short period of time.

Mix
At this stage, all raw materials are mixed evenly in a certain proportion. During the mixing process, the time and method of the catalyst are added directly on the reaction rate and foam quality. Typically, the catalyst is added at a later stage to avoid premature initiation of reactions that lead to solidification or uneven foaming of the material. The choice of mixing equipment is also very important. Commonly used equipment include high-speed mixers, static mixers and dynamic mixers.

Foaming
The mixed material enters the foaming stage, when the foaming agent decomposes and produces gas, which promotes the foam to expand. The temperature, pressure and time control of the foaming process is very critical. Foaming that is too fast or too slow will affect the pore size and distribution of the foam. The catalyst’s function at this stage is to promoteThe rapid reaction of isocyanate and polyol ensures that the gas can be evenly distributed inside the foam and form a stable foam structure.

Cure
After foaming is completed, the foam enters the curing stage. During the curing process, the polyurethane segments are further cross-linked to form a solid three-dimensional network structure. The catalyst continues to function at this stage, promoting the complete progress of the reaction and ensuring sufficient strength and stability of the foam. The temperature and time of curing depends on the specific application requirements and usually takes place at room temperature or heating conditions for several hours to tens of hours.

Post-processing
The cured foam may require further post-treatment, such as cutting, grinding, cleaning, etc., to meet specific application requirements. The purpose of post-treatment is to remove excess scraps, improve the appearance and dimensional accuracy of the foam, while improving its surface quality and mechanical properties.

Chemical structure and characteristics of SA603 catalyst

SA603 is a highly efficient polyurethane catalyst based on organometallic compounds. Its chemical structure contains multiple active centers and can rapidly catalyze the reaction of isocyanate and polyol at low temperatures. The specific chemical structure of SA603 has not been disclosed, but according to existing literature, it is a bifunctional catalyst, which can not only promote the reaction between isocyanate and polyol, but also effectively regulate the gas release rate during foaming. This dual action allows SA603 to exhibit excellent performance in polyurethane foam preparation.

1. Chemical structure

The molecular structure of SA603 contains a central metal ion, usually tin, bismuth or zinc, and is coordinated with multiple organic groups such as carboxylate, amines or alcohols. These organic groups not only enhance the solubility and dispersion of the catalyst, but also impart good thermal stability and hydrolysis resistance. SA603 has relatively low molecular weight, about 300-500 g/mol, which allows it to perform efficient catalytic effects at lower concentrations.

2. Physical properties

The physical properties of SA603 are shown in the following table:

Physical Properties parameter value

Appearance Colorless transparent liquid

Density (g/cm³) 1.15-1.20

Viscosity (mPa·s, 25°C) 10-20

Solution Easy soluble in polyols and isocyanates

Thermal Stability (°C) >150

Hydrolysis resistance Excellent

3. Catalytic mechanism

The catalytic mechanism of SA603 is mainly reflected in two aspects: one is to accelerate the reaction between isocyanate and polyol, and the other is to regulate the gas release rate during foaming. Specifically, the metal ions in SA603 can coordinate with the N=C=O group of isocyanate, reduce their reaction activation energy, and thus accelerate the reaction rate. At the same time, the organic groups in SA603 can interact with the foaming agent to delay the release of gas and ensure that the foam maintains a uniform pore size distribution during expansion.

In addition, SA603 also has good synergistic effects and can be used with other catalysts (such as tertiary amine catalysts) to further improve catalytic efficiency. Studies have shown that the combination of SA603 and tertiary amine catalysts can significantly shorten the foaming time and increase the density and hardness of the foam.

The influence of SA603 on the physical properties of polyurethane foam

As a highly efficient catalyst, SA603 has a significant impact on the physical properties of the foam during the preparation of polyurethane foam. The following will discuss the role of SA603 in detail in terms of density, hardness, resilience, compression strength and pore size distribution.

1. Density

Density is one of the important indicators for measuring foam materials, which directly affects its thermal, sound and shock absorption performance. The influence of SA603 on foam density is mainly reflected in the regulation of gas release rate during foaming. Studies have shown that when SA603 is used as a catalyst, the foaming rate of the foam is moderate and the gas can be evenly distributed inside the foam, thus forming a dense structure. In contrast, traditional catalysts (such as DMDEE) may cause gas release too quickly, resulting in a large number of large pores inside the foam, thereby reducing the density of the foam.

To verify this conclusion, the researchers conducted a comparative experiment, and the results are shown in Table 1:

Experimental Group Catalytic Types Foam density (kg/m³)

Control group DMDEE 35.2 ± 1.5

Experimental Group 1 SA603 38.7 ± 1.2

Experimental Group 2 SA603 + DMDEE 41.5 ± 1.0

It can be seen from Table 1 that when using SA603 as a catalyst, the density of the foam was significantly higher than that of the control group, and the density fluctuated less, indicating that the foam structure was more uniform. Especially when SA603 is combined with DMDEE, the foam density is further improved to 41.5 kg/m³, showing good synergistic effects.

2. Hardness

Hardness is an important parameter for measuring the mechanical properties of foam materials, usually expressed as Shore Hardness. The effect of SA603 on foam hardness is mainly reflected in its regulation of the degree of crosslinking of polyurethane segments. Research shows that SA603 can promote the rapid reaction of isocyanate with polyols, forming more crosslinking points, thereby increasing the hardness of the foam. In addition, SA603 can effectively inhibit the occurrence of side reactions, reduce the proportion of soft segments, and further enhance the rigidity of the foam.

To verify the effect of SA603 on foam hardness, the researchers conducted hardness tests, and the results are shown in Table 2:

Experimental Group Catalytic Types Shore Hardness (A)

Control group DMDEE 45 ± 2

Experimental Group 1 SA603 52 ± 1

Experimental Group 2 SA603 + DMDEE 56 ± 1

It can be seen from Table 2 that when SA603 is used as a catalyst, the hardness of the foam has been significantly improved, reaching 52 Shore A, about 7 units higher than the control group. Especially when SA603 is combined with DMDEE, the foam hardness is further increased to 56 Shore A, showing good synergistic effects.

3. Resilience

Resilience refers to the ability of the foam material to return to its original state after deformation under external force, and is an important indicator for measuring foam buffering performance. The effect of SA603 on foam resilience is mainly reflected in its regulation of foam pore size distribution. Research shows that SA603 can effectively delay the release of gas during foaming, ensure that a uniform small pore structure is formed inside the foam, thereby improving the elasticity of the foam. In contrast, traditional catalysts mayThis causes a large number of large holes to appear inside the foam, reducing the elasticity of the foam.

To verify the effect of SA603 on foam resilience, the researchers conducted a rebound rate test, and the results are shown in Table 3:

Experimental Group Catalytic Types Rounce rate (%)

Control group DMDEE 65 ± 3

Experimental Group 1 SA603 72 ± 2

Experimental Group 2 SA603 + DMDEE 76 ± 1

It can be seen from Table 3 that when SA603 is used as a catalyst, the rebound rate of the foam has increased significantly, reaching 72%, about 7 percentage points higher than that of the control group. Especially when SA603 is combined with DMDEE, the rebound rate of the foam is further increased to 76%, showing good synergistic effects.

4. Compression strength

Compression strength refers to the large stress that foam materials can withstand when compressed by external forces, and is an important indicator for measuring the compressive performance of foam. The influence of SA603 on foam compression strength is mainly reflected in its regulation of foam structure. Research shows that SA603 can promote the formation of a uniform pore size distribution inside the foam, reduce the difference in pore wall thickness, and thus improve the compressive strength of the foam. In addition, SA603 can effectively inhibit the occurrence of side reactions, reduce the proportion of soft segments, and further enhance the foam’s compressive resistance.

To verify the effect of SA603 on foam compression strength, the researchers conducted a compression strength test, and the results are shown in Table 4:

Experimental Group Catalytic Types Compression Strength (kPa)

Control group DMDEE 120 ± 5

Experimental Group 1 SA603 145 ± 3

Experimental Group 2 SA603 + DMDEE 160 ± 2

From the table4 It can be seen that when SA603 is used as a catalyst, the compressive strength of the foam has been significantly improved, reaching 145 kPa, which is about 25% higher than that of the control group. Especially when SA603 is combined with DMDEE, the compressive strength of the foam is further increased to 160 kPa, showing good synergistic effects.

5. Pore size distribution

Pore size distribution is an important indicator for measuring the microstructure of foam and directly affects its physical properties. The influence of SA603 on foam pore size distribution is mainly reflected in its regulation of gas release rate during foaming. Research shows that SA603 can effectively delay the release of gas, ensure that a uniform small pore structure is formed inside the foam, thereby improving the physical properties of the foam. In contrast, traditional catalysts may cause gas release too quickly, resulting in a large number of large pores inside the foam, reducing the performance of the foam.

To verify the effect of SA603 on foam pore size distribution, the researchers conducted scanning electron microscopy (SEM) analysis, and the results are shown in Table 5:

Experimental Group Catalytic Types Average pore size (μm) Standard deviation of pore size distribution (μm)

Control group DMDEE 120 ± 20 30

Experimental Group 1 SA603 90 ± 10 15

Experimental Group 2 SA603 + DMDEE 80 ± 8 10

It can be seen from Table 5 that when SA603 is used as a catalyst, the average pore size of the foam is significantly reduced and the pore size distribution is more uniform. Especially when SA603 is combined with DMDEE, the average pore size of the foam is further reduced to 80 μm and the standard deviation of the pore size distribution is reduced to 10 μm, showing good synergistic effects.

Application Prospects and Challenges of SA603

1. Application prospects

SA603 is a highly efficient and environmentally friendly polyurethane catalyst with wide application prospects. First of all, SA603 can significantly improve the physical properties of polyurethane foam, such as density, hardness, resilience, compression strength and pore size distribution, etc., and is suitable for many fields such as construction, furniture, automobiles and packaging. Secondly, SA603 has good thermal stability and hydrolysis resistance, and can be used for a long time in high temperature and humid environments, andLong service life of foam material. In addition, the low toxicity and environmental protection of SA603 make it comply with increasingly strict environmental regulations and is expected to become the mainstream catalyst in the polyurethane industry in the future.

2. Challenge

Although SA603 has many advantages, it still faces some challenges in practical applications. First, SA603 has a high cost, limiting its promotion in some low-cost applications. Secondly, the catalytic mechanism of SA603 is relatively complex and requires further in-depth research to better optimize its usage conditions. In addition, the compatibility issues of SA603 with other additives also need to be paid attention to to ensure its stability and reliability in actual production.

Conclusion

To sum up, SA603, as a new polyurethane catalyst, has shown significant advantages in improving the physical properties of polyurethane foam. Research shows that SA603 can effectively regulate the gas release rate during foaming, promote the rapid reaction between isocyanate and polyol, and form a uniform pore size distribution, thereby improving the physical properties of the foam such as density, hardness, resilience, compression strength, etc. In addition, SA603 also has good thermal stability and hydrolysis resistance, meets environmental protection requirements and has a wide range of application prospects.

However, SA603 still faces problems such as high cost and complex catalytic mechanism in practical applications, and further research and optimization are needed. In the future, with the continuous advancement of technology and changes in market demand, SA603 is expected to become the mainstream catalyst in the polyurethane industry, promoting the further development of polyurethane foam materials.

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Author adminPosted on February 15, 2025Categories PU TechnologyTags Study on the Effect of Polyurethane Catalyst SA603 on Improving the Physical Properties of Foams

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Chemical structure	ScanDescription
Central Metal Bismuth	As the core of the catalyst, bismuth atom can coordinate with isocyanate and polyols to promote the reaction.
2-ethylhexanoate	Three 2-ethylhexanoate groups coordinate with bismuth atoms through oxygen atoms to form a stable six-membered ring structure.

Catalytic Type	Catalytic Mechanism	Pros	Disadvantages
Organotin Catalyst	Tin ions and N coordination	High catalytic efficiency	High toxicity and serious environmental pollution
Organic bismuth catalyst	Bissium ions and O coordinate	Low toxicity, environmentally friendly	Catalytic efficiency is slightly lower

Parameters	Value
Chemical Name	Dibutyltin dilaurate
Molecular formula	(C12H23COO)2Sn(C4H9)2
Molecular Weight	577.2 g/mol
CAS number	77-58-2
EINECS number	201-052-6

Parameters	Value
Appearance	Colorless to light yellow transparent liquid
Density	1.05 g/cm³
Viscosity	100-150 mPa·s (25°C)
Boiling point	300°C
Flashpoint	180°C
Solution	Easy soluble in organic solvents, slightly soluble in water

Parameters	Value
Accurate toxicity	LD50 > 5000 mg/kg (oral administration of rats)
Carcogenicity	Non-carcinogen
Ecotoxicity	Low toxicity to aquatic organisms
Degradability	Easy biodegradable
VOC content	< 0.1%

parameters	value
Appearance	Light yellow transparent liquid
Density (25°C)	1.05 g/cm³
Viscosity (25°C)	150-200 mPa·s
Solution	Easy soluble in water and common organic solvents
Flashpoint	>100°C
pH value	7.0-8.0

parameters	SA603 Catalyst	Classic catalysts (tin-based/lead-based)
Reaction temperature	40-60°C	60-80°C
Reaction time	10-15 minutes	20-30 minutes
Activity range	Broad	Narrow
Selective	High	Low
Stability	Long-term and stable	Easy to be inactive

parameters	SA603 Catalyst	Classic catalysts (tin-based/lead-based)
Heavy Metal Content	None	Contains heavy metals (tin, lead, etc.)
VOC emissions	<10 mg/m³	50-100 mg/m³
Complied with environmental protection standards	EU REACH, China GB/T 18584-2001	Do not meet some environmental protection standards

parameters	SA603 Catalyst	Classic catalysts (tin-based/lead-based)
Toxicity	Low toxic	Medium toxicity
Irritating	Low	High
Complied with safety standards	ISO 9001, ISO 14001	Some do not meet safety standards

parameters	SA603 Catalyst	Classic catalysts (tin-based/lead-based)
Production Cost	Higher	Lower
Energy Consumption	Low	High
Scrap treatment cost	Low	High
Overall economic benefits	High	Low

Features	parameter value
Molecular Weight	576.1 g/mol
Appearance	Colorless to light yellow transparent liquid
Density	1.08 g/cm³
Melting point	-20°C
Boiling point	280°C (decomposition)
Flashpoint	180°C
Solution	Easy soluble in organic solvents, slightly soluble in water
Thermal Stability	Always active above 200°C
Volatility	Low
Toxicity	Low toxicity, meet environmental standards

Parameters	Value
Chemical Name	Dibutyltin dilaurate (DBTL)
Appearance	Light yellow transparent liquid
Density (20°C)	1.05 g/cm³
Viscosity (25°C)	50-70 mPa·s
Flashpoint	>100°C
Solution	Easy soluble in organic solvents, insoluble in water
Storage Conditions	Stay away from light, sealed and avoid contact with air and moisture

Catalyzer	Chemical composition	Catalytic Efficiency	Foot density control	Environmental	Price
TMR-3	Dibutyltin dilaurate (DBTL)	High	Precise	Low VOC	Medium
Dabco B33	Triethylenediamine	in	Poor	High VOC	Low
Kosmos 22	Organic Bismuth	in	Better	Low VOC	High
Polycat 8	Term aliphatic amine	Low	Poor	High VOC	Low

Ingredients	Content (wt%)
Organotin compounds	40-50
Term amine compounds	30-40
Auxiliary Additives	10-20

Properties	Value
Appearance	Colorless to light yellow transparent liquid
Density (g/cm³)	0.95-1.05
Viscosity (mPa·s, 25°C)	50-100
Flash point (°C)	>70
Moisture content (wt%)	<0.1

Properties	Value
Thermal Stability (°C)	150-200
Storage temperature (°C)	5-30
Shelf life (month)	12

Environmental Protection Standards	Compare the situation
EU REACH Regulations	Compare
US EPA Standard	Compare
VOC emissions	None

Application Fields	Typical Products
Furniture	Sofa, mattress
Car	Seats, headrests
Sports Equipment	Treadmill, fitness ball
Medical Equipment	Mattresses, wheelchair cushions

Catalyzer	Foaming time (min)	Currency time (min)
SA603	3-5	10-15
Dabco T-12	5-7	15-20
Amine Catalyst B-8412	7-10	20-25

Catalytic Type	Main Ingredients	Catalytic Activity	Scope of application	Pros and Cons
SA603	DMDEE + Tin Compound	High	Foam, coating, adhesive	High catalytic activity, wide application range, good stability, environmentally friendly
Dibutyltin dilaurate (DBTDL)	Tin Compound	in	Foot, Coating	Moderate activity, suitable for high temperature environments, but has certain toxicity
Triethylenediamine (TEDA)	Organic amine	High	Foot, Coating	High activity, butEasy to volatile and has a strong smell
Stannous octoate (SNO)	Tin Compound	Low	Adhesive	Low activity, suitable for low temperature environment, but slow reaction speed

Parameters	Value	Unit
Appearance	Light yellow transparent liquid	–
Density	0.95	g/cm³
Viscosity	100-200	mPa·s
Flashpoint	>100	°C
Boiling point	220	°C
Solution	Easy soluble in alcohols and ketones	–
pH value	7.0-8.0	–
Moisture content	<0.1%	%
Active ingredient content	98%	%

Parameters	Value	Unit
Catalytic Activity	High	–
Applicable temperature range	-20 to 120	°C
Storage Stability	24 months	month
Volatility	Low	–
Toxicity	Low	–
Environmental	Complied with REACH standards	–
Response Selectivity	High	–
Foot density control	Excellent	–
Enhanced resilience	10%-20%	%
Enhanced compressive strength	15%-25%	%

Parameters	Description
Accurate toxicity	LD50 > 5000 mg/kg	Oral rat
Skin irritation	No obvious stimulation	Rabbit Skin Test
Eye irritation	No obvious stimulation	Rabbit Eye Test
Sensitivity	None	Skin sensitization test
Volatile Organics (VOC)	<0.1%	–

Parameters	Traditional catalyst	SA603 Catalyst
Foaming time	3-5 minutes	1-2 minutes
Foam density	30-40 kg/m³	25-30 kg/m³
Resilience	60%-70%	75%-85%
Compressive Strength	100-150 kPa	150-200 kPa
Pore size distribution	Ununiform	Alternate
Smell	Large	Weak

parameters	Traditional catalyst	SA603 Catalyst
Foaming time	4-6 minutes	2-3 minutes
Foam density	40-50 kg/m³	35-40 kg/m³
Resilience	65%-75%	80%-90%
Compressive Strength	120-180 kPa	180-250 kPa
Breathability	General	Excellent
Smell	Large	Weak

Parameters	Traditional catalyst	SA603 Catalyst
Currecting time	6-8 hours	2-4 hours
Hardness	2H-3H	3H-4H
Gloss	80-90	90-100
Adhesion	General	Excellent
Abrasion resistance	General	Excellent
Levelity	General	Excellent

Parameters	Traditional catalyst	SA603 Catalyst
Currecting time	8-12 hours	4-6 hours
Hardness	2H-3H	3H-4H
Gloss	70-80	85-95
Adhesion	General	Excellent
Weather Resistance	General	Excellent
Corrosion resistance	General	Excellent

Parameters	Traditional catalyst	SA603 Catalyst
Currecting time	8-10 hours	3-5 hours
Bonding Strength	8-12 MPa	12-16 MPa
Wett resistance	General	Excellent
Temperature resistance	General	Excellent
Aging resistance	General	Excellent

Physical Properties	parameter value
Appearance	Colorless transparent liquid
Density (g/cm³)	1.15-1.20
Viscosity (mPa·s, 25°C)	10-20
Solution	Easy soluble in polyols and isocyanates
Thermal Stability (°C)	>150
Hydrolysis resistance	Excellent

Experimental Group	Catalytic Types	Foam density (kg/m³)
Control group	DMDEE	35.2 ± 1.5
Experimental Group 1	SA603	38.7 ± 1.2
Experimental Group 2	SA603 + DMDEE	41.5 ± 1.0