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Thermal Sensitive Catalyst SA-1: Future-oriented Polyurethane Technology Innovation

admin 3月 11th, 2025 News

Thermal-sensitive catalyst SA-1: Future-oriented polyurethane technology innovation

Introduction

Polyurethane (PU) is a polymer material widely used in the fields of construction, automobile, furniture, shoe materials, packaging, etc. Its excellent physical properties and chemical stability make it one of the indispensable materials in modern industry. However, with the improvement of environmental protection requirements and technological advancement, traditional polyurethane production technology faces many challenges. The emergence of the thermally sensitive catalyst SA-1 has brought new technological breakthroughs to the polyurethane industry and promoted the innovation and development of polyurethane materials.

1. Overview of the thermosensitive catalyst SA-1

1.1 What is the thermosensitive catalyst SA-1?

Thermal-sensitive catalyst SA-1 is a new type of polyurethane reaction catalyst with temperature sensitivity. It is able to efficiently catalyze the reaction of polyurethanes in a specific temperature range, while exhibiting lower activity at other temperatures. This characteristic allows SA-1 to achieve more precise reaction control during the polyurethane production process, thereby improving product quality and production efficiency.

1.2 Main features of SA-1

Temperature Sensitivity: SA-1 exhibits high catalytic activity in a specific temperature range, but is less active at other temperatures.
Environmentality: SA-1 does not contain heavy metals and harmful substances, and meets environmental protection requirements.
High efficiency: SA-1 can significantly improve the speed and efficiency of polyurethane reaction.
Stability: SA-1 shows good stability during storage and use.

1.3 Application areas of SA-1

SA-1 is widely used in the production of various polyurethane products, including:

Foaming materials: such as soft foam, rigid foam, etc.
Elastomer: such as soles, seals, etc.
Coatings and Adhesives: such as water-based polyurethane coatings, adhesives, etc.
Composite materials: such as fiberglass, carbon fiber composite materials, etc.

2. Technical parameters of SA-1

2.1 Physical and chemical properties

parameter name	Value/Description
Appearance	Colorless to light yellow liquid
Density (20?)	1.05 g/cm³
Viscosity (25?)	50-100 mPa·s
Flashpoint	>100?
Solution	Easy soluble in organic solvents, slightly soluble in water

2.2 Catalytic properties

parameter name	Value/Description
Catalytic Temperature Range	50-80?
Catalytic Efficiency	20-30% higher than traditional catalysts
Reaction time	Short by 10-15%
Selective	High selectivity, reduce side effects

2.3 Safety and Environmental Protection

parameter name	Value/Description
Toxicity	Low toxicity, meet environmental protection standards
Storage Stability	Stable at room temperature, shelf life of 12 months
User security	No special protection is required, easy to operate

III. Application of SA-1 in polyurethane production

3.1 Foam material production

In the production of polyurethane foam materials, SA-1 can significantly improve the foaming speed and foam uniformity. By precisely controlling the reaction temperature, SA-1 can reduce bubbles and defects in the foam and improve the physical properties of the foam.

3.1.1 Soft foam

parameter name	Before using SA-1	After using SA-1
Foaming speed	Medium	Quick
Foam density	Ununiform	Alternate
Physical Performance	General	Excellent

3.1.2 Rigid foam

parameter name	Before using SA-1	After using SA-1
Foaming speed	Slow	Quick
Foam density	Ununiform	Alternate
Physical Performance	General	Excellent

3.2 Elastomer production

In the production of polyurethane elastomers, SA-1 can improve the reaction speed and the mechanical properties of the product. By precisely controlling the reaction temperature, SA-1 can reduce defects in the elastomer and improve the wear resistance and tear resistance of the product.

3.2.1 Sole material

parameter name	Before using SA-1	After using SA-1
Response speed	Medium	Quick
Abrasion resistance	General	Excellent
Tear resistance	General	Excellent

3.2.2 Seals

parameter name	Before using SA-1	After using SA-1
Response speed	Slow	Quick
Sealing Performance	General	Excellent
Service life	Short	Long

3.3 Coating and adhesive production

In the production of polyurethane coatings and adhesives, SA-1 can improve the reaction speed and product adhesion. By precisely controlling the reaction temperature, SA-1 can reduce bubbles and defects in coatings and adhesives, and improve the coating performance and bonding strength of the product.

3.3.1 Water-based polyurethane coating

parameter name	Before using SA-1	After using SA-1
Response speed	Medium	Quick
Coating performance	General	Excellent
Adhesion	General	Excellent

3.3.2 Adhesive

parameter name	Before using SA-1	After using SA-1
Response speed	Slow	Quick
Bonding Strength	General	Excellent
Service life	Short	Long

3.4 Composite material production

In the production of polyurethane composite materials, SA-1 can improve the reaction speed and the mechanical properties of the product. By precisely controlling the reaction temperature, SA-1 can reduce defects in composite materials and improve product strength and durability.

3.4.1 FRP

parameter name	Before using SA-1	After using SA-1
Response speed	Medium	Quick
Strength	General	Excellent
Durability	General	Excellent

3.4.2 Carbon fiber composite material

parameter name	Before using SA-1	After using SA-1
Response speed	Slow	Quick
Strength	General	Excellent
Durability	General	Excellent

IV. SA-1’s advantages and future prospects

4.1 Advantages of SA-1

Improving Production Efficiency: SA-1 can significantly improve the speed and efficiency of polyurethane reaction and shorten the production cycle.
Improving product quality: By precisely controlling the reaction temperature, SA-1 can reduce defects in the product and improve the physical and mechanical properties of the product.
Environmental Safety: SA-1 does not contain heavy metals and harmful substances, meets environmental protection requirements, and is safe to use.
Widely used: SA-1 is suitable for the production of various polyurethane products and has a wide range of application prospects.

4.2 Future Outlook

With the improvement of environmental protection requirements and technological advancement, the thermal catalyst SA-1 will play an increasingly important role in the polyurethane industry. In the future, SA-1 is expected to make breakthroughs in the following aspects:

Development of new polyurethane materials: The efficient catalytic performance of SA-1 will promote the development of new polyurethane materials, such as high-performance foams, elastomers, coatings and composite materials.
Green Production Technology: The environmentally friendly characteristics of SA-1 will promote the development of polyurethane production in a green and environmentally friendly direction, reducing the risk ofLess pollution to the environment.
Intelligent Production: The temperature sensitivity of SA-1 will promote the development of polyurethane production in the direction of intelligence and automation, achieving more precise reaction control.

V. Conclusion

As a new type of polyurethane reaction catalyst, the thermosensitive catalyst SA-1 has the advantages of temperature sensitivity, environmental protection, high efficiency and stability. Its application in polyurethane foams, elastomers, coatings, adhesives and composite materials has significantly improved production efficiency and product quality. With the continuous advancement of technology, SA-1 will play an increasingly important role in the polyurethane industry and promote the innovation and development of polyurethane materials.

Through the introduction of this article, I believe that readers have a deeper understanding of the thermal catalyst SA-1. In the future, SA-1 will continue to lead the technological innovation of the polyurethane industry and provide better quality and environmentally friendly polyurethane materials to all walks of life.

Unique application of the thermosensitive catalyst SA-102 in temperature-responsive materials

admin 3月 11th, 2025 News

The unique application of thermal-sensitive catalyst SA-102 in temperature-responsive materials

Introduction

Thermal-sensitive catalyst SA-102 is a material that exhibits significant catalytic activity in a specific temperature range and is widely used in temperature-responsive materials. Its unique temperature response characteristics make it have a wide range of application prospects in many fields. This article will introduce in detail the product parameters, working principles, application fields of SA-102 and its unique application in temperature-responsive materials.

Product Parameters

1. Basic parameters

parameter name	parameter value
Chemical Name	Thermal Sensitive Catalyst SA-102
Molecular formula	C10H15N5O2
Molecular Weight	237.26 g/mol
Appearance	White Powder
Melting point	120-125°C
Decomposition temperature	250°C
Density	1.25 g/cm³
Solution	Easy soluble in organic solvents

2. Catalytic performance parameters

parameter name	parameter value
Catalytic Temperature Range	50-200°C
Outstanding catalytic temperature	100-150°C
Catalytic Efficiency	>95%
Stability	Stable in the air
Service life	>1000 hours

Working Principle

Work principle basis of the thermosensitive catalyst SA-102Reversible changes in the reactive groups in their molecular structure over a specific temperature range. When the temperature rises to its catalytic temperature range, the molecular structure of SA-102 changes, exposing active sites, thereby catalyzing a specific chemical reaction. When the temperature drops, the molecular structure returns to its original state and the catalytic activity disappears.

1. Temperature response mechanism

The temperature response mechanism of SA-102 depends mainly on the thermosensitive groups in its molecular structure. These groups undergo conformational changes at specific temperatures, thereby changing catalytic activity. Specifically, when the temperature increases, the heat-sensitive group stretches, exposing the active site; when the temperature decreases, the heat-sensitive group shrinks, and the active site is masked.

2. Catalytic reaction mechanism

The catalytic reaction mechanism of SA-102 involves multiple steps, including substrate adsorption, active site exposure, reaction progression and product desorption. The specific steps are as follows:

Substrate Adsorption: Substrate molecules are adsorbed on the surface of SA-102.
Active site exposure: The temperature rises, the heat-sensitive group stretches, and the active site is exposed.
Reaction proceeds: The substrate molecule undergoes chemical reaction at the active site.
Product Desorption: The reaction product is desorbed from the surface of SA-102.

Application Fields

1. Smart Materials

The application of SA-102 in smart materials is mainly reflected in its temperature response characteristics. By embedding SA-102 into the polymer matrix, smart materials with temperature response characteristics can be prepared. These materials will undergo changes in shape, color or mechanical properties at specific temperatures and are widely used in smart windows, smart textiles and other fields.

1.1 Smart Window

Smart windows are materials that can automatically adjust light transmittance according to external temperature. SA-102 is embedded in the window glass. When the temperature rises, SA-102 catalyzes the chemical reaction in the glass, changing the light transmittance of the glass, thereby adjusting the indoor temperature.

1.2 Smart Textiles

Smart textiles are materials that can automatically adjust breathability according to body temperature. When SA-102 is embedded in textiles, when the body temperature rises, SA-102 catalyzes chemical reactions in textiles, changing the breathability of the textiles, thereby improving wear comfort.

2. Drug Controlled Release System

The application of SA-102 in drug controlled release systems is mainly reflected in its temperature response characteristics. By embedding SA-102 into the drug carrier, a controlled release system with temperature response characteristics can be prepared. These systems are specialThe drug will be released at a fixed temperature, thereby achieving accurate controlled release of the drug.

2.1 Temperature-responsive drug carrier

Temperature-responsive drug carrier is a material that automatically releases drugs based on body temperature. SA-102 is embedded in the drug carrier. When the body temperature rises, SA-102 catalyzes the chemical reaction in the drug carrier and releases the drug, thereby achieving accurate controlled release of the drug.

2.2 Tumor Heat Therapy

Tumor thermotherapy is a treatment method that uses high temperature to kill tumor cells. SA-102 is embedded in tumor thermotherapy drugs. When the temperature of the tumor site increases, SA-102 catalyzes the chemical reactions in the drug and releases the drug, thereby improving the therapeutic effect.

3. Environmental Monitoring

The application of SA-102 in environmental monitoring is mainly reflected in its temperature response characteristics. By embedding the SA-102 into the environmental monitoring sensor, an environmental monitoring sensor with temperature response characteristics can be prepared. These sensors change at specific temperatures, enabling real-time monitoring of ambient temperature.

3.1 Temperature Sensor

The temperature sensor is a device that can monitor ambient temperature in real time. Embed SA-102 into a temperature sensor. When the ambient temperature rises, SA-102 catalyzes the chemical reaction in the sensor, changing the electrical performance of the sensor, thereby achieving real-time monitoring of ambient temperature.

3.2 Fire warning system

The fire warning system is a device that can monitor ambient temperature in real time and warning of fires. Embed SA-102 into the fire early warning system. When the ambient temperature rises to the fire early warning temperature, the chemical reaction in the SA-102 catalyzed the system triggers the early warning signal, thereby achieving real-time early warning of the fire.

Unique Application

1. Temperature-responsive coating

Temperature responsive coating is a coating that can automatically change color according to the ambient temperature. When SA-102 is embedded in the coating, when the ambient temperature rises, SA-102 catalyzes the chemical reaction in the coating, changing the color of the coating, thereby achieving real-time display of the ambient temperature.

1.1 Building exterior wall coating

Building exterior wall coating is a paint that can automatically change color according to the ambient temperature. Embed SA-102 into the exterior paint of the building. When the ambient temperature rises, SA-102 catalyzes the chemical reaction in the coating, changing the color of the coating, thereby achieving real-time temperature display of the exterior wall of the building.

1.2 Automotive Paint

Automotive coating is a coating that can automatically change color according to the ambient temperature. When SA-102 is embedded in the automotive coating, when the ambient temperature rises, SA-102 catalyzes the chemical reaction in the coating, changing the color of the coating, thereby achieving real-time temperature display of the automotive appearance.

2. Temperature-responsive adhesive

Temperature responsive adhesive is an adhesive that can automatically change the bonding strength according to the ambient temperature. When SA-102 is embedded in the adhesive, when the ambient temperature rises, SA-102 catalyzes the chemical reaction in the adhesive, changing the adhesive strength of the adhesive, thereby achieving real-time adjustment of the adhesive strength.

2.1 Electronic component bonding

Electronic component bonding is a process that requires precise control of the bonding strength. SA-102 is embedded in the electronic component adhesive. When the ambient temperature rises, SA-102 catalyzes the chemical reaction in the adhesive, changing the adhesive strength of the adhesive, thereby achieving accurate bonding of the electronic component.

2.2 Medical device bonding

Medical device bonding is a process that requires precise control of the bonding strength. When the ambient temperature rises, SA-102 catalyzes the chemical reaction in the adhesive, changing the adhesive strength of the adhesive, thereby achieving accurate bonding of the medical device.

3. Temperature-responsive lubricant

Temperature responsive lubricant is a lubricant that can automatically change lubricating performance according to ambient temperature. When SA-102 is embedded in the lubricant, when the ambient temperature rises, SA-102 catalyzes the chemical reaction in the lubricant, changing the lubricant performance of the lubricant, thereby achieving real-time adjustment of the lubricant performance.

3.1 Mechanical Equipment Lubrication

Luction of mechanical equipment is a process that requires precise control of lubrication performance. SA-102 is embedded in the lubricant of mechanical equipment. When the ambient temperature rises, SA-102 catalyzes the chemical reaction in the lubricant, changing the lubricant performance of the lubricant, thereby achieving accurate lubrication of mechanical equipment.

3.2 Automobile engine lubrication

Automotive engine lubrication is a process that requires precise control of lubrication performance. When the ambient temperature rises, SA-102 catalyzes the chemical reaction in the lubricant, changing the lubricating performance of the lubricant, thereby achieving accurate lubrication of the automobile engine.

Conclusion

Thermal-sensitive catalyst SA-102 has a wide range of application prospects in temperature-responsive materials due to its unique temperature response characteristics. By embedding SA-102 in intelligent materials, drug controlled release systems, environmental monitoring sensors, temperature-responsive coatings, adhesives and lubricants, real-time adjustment of material performance can be achieved, thereby improving the intelligence level and application value of the material. In the future, with the further research and development of SA-102, its application potential in more fields will be fully tapped.

How the thermal catalyst SA-102 changes the properties of polyurethane foam

admin 3月 11th, 2025 News

How the thermosensitive catalyst SA-102 changes the properties of polyurethane foam

Introduction

Polyurethane foam is a polymer material widely used in construction, furniture, automobiles, packaging and other fields. The quality and service life of the final product are directly affected. As a new catalyst, the thermosensitive catalyst SA-102 has been widely used in the production of polyurethane foams in recent years. This article will discuss in detail how the thermal catalyst SA-102 changes the characteristics of polyurethane foam, including its mechanism of action, product parameters, application effects, etc.

1. Basic introduction to the thermally sensitive catalyst SA-102

1.1 Definition of the Thermal Sensitive Catalyst SA-102

Thermal-sensitive catalyst SA-102 is a catalyst that can be activated at a specific temperature and is mainly used in the production of polyurethane foams. It can remain stable at lower temperatures and quickly activate after reaching a certain temperature, thereby accelerating the reaction process of polyurethane foam.

1.2 Main components of the thermosensitive catalyst SA-102

The main components of the thermosensitive catalyst SA-102 include organotin compounds, amine compounds, etc. These components can work together at specific temperatures to accelerate the reaction process of polyurethane foam.

1.3 Product parameters of the thermosensitive catalyst SA-102

parameter name	parameter value
Appearance	Colorless transparent liquid
Density (g/cm³)	1.05-1.10
Viscosity (mPa·s)	50-100
Flash point (?)	>100
Active temperature range (?)	50-120
Storage temperature (?)	5-30

2. The mechanism of action of the thermosensitive catalyst SA-102

2.1 Activation mechanism of thermally sensitive catalyst

Thermal-sensitive catalyst SA-102 remains stable at low temperatures and does not have a significant impact on the reaction process of the polyurethane foam. However, when the temperature reaches its active temperature range (50-120°C), the organotin compounds and amine compounds in the catalyst are activated rapidly, forming active centers and accelerating the polymerizationThe reaction process of urethane foam.

2.2 Effect of thermally sensitive catalysts on polyurethane foam reaction

Activation of the thermosensitive catalyst SA-102 can significantly accelerate the reaction process of polyurethane foam, which is specifically reflected in the following aspects:

Shorten the reaction time: The activation of the thermosensitive catalyst SA-102 can significantly shorten the reaction time of polyurethane foam and improve production efficiency.
Improve the foam structure: The activation of the thermosensitive catalyst SA-102 can improve the cell structure of polyurethane foam, making it more uniform and delicate.
Improving foam performance: Activation of the thermal-sensitive catalyst SA-102 can improve the mechanical properties, thermal insulation properties of polyurethane foam.

III. Effect of the thermal-sensitive catalyst SA-102 on the properties of polyurethane foam

3.1 Effect on the density of polyurethane foam

Activation of the thermosensitive catalyst SA-102 can significantly affect the density of the polyurethane foam. Specifically manifested as:

Catalytic Dosage (%)	Foam density (kg/m³)
0	30
0.5	28
1.0	26
1.5	24

It can be seen from the above table that as the amount of the heat-sensitive catalyst SA-102 increases, the density of the polyurethane foam gradually decreases. This is because activation of the heat-sensitive catalyst SA-102 can accelerate the reaction process of the polyurethane foam, making the gas in the foam more likely to escape, thereby reducing the density of the foam.

3.2 Effect on the mechanical properties of polyurethane foam

Activation of the thermosensitive catalyst SA-102 can significantly improve the mechanical properties of the polyurethane foam. Specifically manifested as:

Catalytic Dosage (%)	Tension Strength (MPa)	Elongation of Break (%)
0	0.5	150
0.5	0.6	160
1.0	0.7	170
1.5	0.8	180

It can be seen from the above table that with the increase in the amount of the heat-sensitive catalyst SA-102, the tensile strength and elongation of break of the polyurethane foam have been improved. This is because the activation of the thermally sensitive catalyst SA-102 can improve the cell structure of the polyurethane foam, making it more uniform and delicate, thereby improving the mechanical properties of the foam.

3.3 Effect on the thermal insulation properties of polyurethane foam

Activation of the thermally sensitive catalyst SA-102 can significantly improve the thermal insulation performance of polyurethane foam. Specifically manifested as:

Catalytic Dosage (%)	Thermal conductivity coefficient (W/m·K)
0	0.035
0.5	0.033
1.0	0.031
1.5	0.029

It can be seen from the above table that with the increase in the amount of the heat-sensitive catalyst SA-102, the thermal conductivity of the polyurethane foam gradually decreases. This is because the activation of the thermally sensitive catalyst SA-102 can improve the cell structure of the polyurethane foam, making it more uniform and delicate, thereby reducing the thermal conductivity of the foam and improving its thermal insulation performance.

3.4 Effect on the aging resistance of polyurethane foam

Activation of the thermosensitive catalyst SA-102 can significantly improve the aging resistance of polyurethane foam. Specifically manifested as:

Catalytic Dosage (%)	Tension strength retention rate after aging (%)	Retention rate of elongation after aging (%)
0	80	75
0.5	85	80
1.0	90	85
1.5	95	90

It can be seen from the above table that with the increase in the amount of the heat-sensitive catalyst SA-102, the tensile strength retention rate and elongation retention rate of the polyurethane foam after aging have increased. This is because the activation of the thermally sensitive catalyst SA-102 can improve the cell structure of the polyurethane foam, making it more uniform and delicate, thereby improving the aging resistance of the foam.

IV. Application effect of the thermal catalyst SA-102

4.1 Application in the field of construction

The application of the thermosensitive catalyst SA-102 in the construction field is mainly reflected in the following aspects:

Improving thermal insulation performance: The activation of the thermally sensitive catalyst SA-102 can significantly improve the thermal insulation performance of polyurethane foam, thus becoming widely used in building insulation materials.
Improving durability: Activation of the thermal catalyst SA-102 can significantly improve the aging resistance of polyurethane foam, thereby extending the service life of building insulation materials.
Improving construction efficiency: Activation of the thermally sensitive catalyst SA-102 can significantly shorten the reaction time of polyurethane foam, thereby improving construction efficiency.

4.2 Application in the field of furniture

The application of the thermosensitive catalyst SA-102 in the furniture field is mainly reflected in the following aspects:

Improving Comfort: Activation of the thermal catalyst SA-102 can significantly improve the mechanical properties of polyurethane foam, thereby improving the comfort of furniture.
Improving durability: Activation of the thermal catalyst SA-102 can significantly improve the aging resistance of polyurethane foam, thereby extending the service life of furniture.
Improving Production Efficiency: Activation of the thermally sensitive catalyst SA-102 can significantly shorten the reaction time of the polyurethane foam, thereby improving production efficiency.

4.3 Application in the automotive field

The application of the thermosensitive catalyst SA-102 in the automotive field is mainly reflected in the following aspects:

Improving Comfort: Activation of the thermal catalyst SA-102 can significantly improve the mechanical properties of polyurethane foam, thereby improving the comfort of the car seat.
Improving safety: Activation of the thermal catalyst SA-102 can significantly improve the aging resistance of polyurethane foam, thereby improving the safety of the automotive interior.
Improving Production Efficiency: Activation of the thermally sensitive catalyst SA-102 can significantly shorten the reaction time of the polyurethane foam, thereby improving production efficiency.

4.4 Application in the packaging field

The application of the thermosensitive catalyst SA-102 in the packaging field is mainly reflected in the following aspects:

Improving protection performance: Activation of the thermal catalyst SA-102 can significantly improve the mechanical properties of polyurethane foam, thereby improving the protection performance of packaging materials.
Improving durability: Activation of the thermal catalyst SA-102 can significantly improve the aging resistance of polyurethane foam, thereby extending the service life of the packaging material.
Improving Production Efficiency: Activation of the thermally sensitive catalyst SA-102 can significantly shorten the reaction time of the polyurethane foam, thereby improving production efficiency.

V. Precautions for the use of the thermally sensitive catalyst SA-102

5.1 Storage conditions

Thermal-sensitive catalyst SA-102 should be stored in a cool, dry and well-ventilated place to avoid direct sunlight and high temperatures. The storage temperature should be controlled between 5-30?.

5.2 Usage temperature

The active temperature range of the thermosensitive catalyst SA-102 is 50-120°C. Therefore, when used, the reaction temperature should be ensured within this range to ensure the activation effect of the catalyst.

5.3 Dosage control

The amount of the heat-sensitive catalyst SA-102 should be adjusted according to the specific production process and product requirements. Generally speaking, it is advisable to control the dosage between 0.5-1.5%.

5.4 Safety Protection

Thermal-sensitive catalyst SA-102 should avoid direct contact with the skin and eyes during use, and should wear protective gloves and goggles during operation. If you are not careful, you should immediately rinse with a lot of clean water and seek medical help.

VI. Future development of the thermosensitive catalyst SA-102

6.1 Research and development of environmentally friendly thermal catalysts

With the increase in environmental awareness, the future research and development of the thermal catalyst SA-102 will pay more attention to environmental protection performance. For example, develop low-toxic, non-toxic organotin and amine compounds to reduce harm to the environment and the human body.

6.2 Research and development of multifunctional thermal catalysts

The FutureThe research and development of the thermal catalyst SA-102 will pay more attention to versatility. For example, the development of thermal catalysts with various functions such as flame retardant, antibacterial, and antistatic to meet the needs of different fields.

6.3 Research and development of intelligent thermal catalysts

With the development of intelligent technology, the future research and development of the thermal catalyst SA-102 will pay more attention to intelligence. For example, a thermally sensitive catalyst capable of automatically adjusting activity according to reaction conditions is developed to improve production efficiency and product quality.

Conclusion

As a new catalyst, thermistor SA-102 has a wide range of application prospects in the production of polyurethane foams. Its activation can significantly shorten the reaction time, improve the foam structure, and improve the foam performance, thus becoming widely used in the fields of construction, furniture, automobiles, packaging, etc. In the future, with the development of environmentally friendly, multifunctional and intelligent technologies, the research and development of the thermal catalyst SA-102 will pay more attention to environmentally friendly performance, versatility and intelligence to meet the needs of different fields.

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