Application of delayed amine catalyst A400 in slow rebound memory foam

March 9, 2025by admin0

Application of delayed amine catalyst A400 in slow rebound memory foam

Catalog

Introduction
Basic concept of slow rebound memory foam
Overview of Retarded Amine Catalyst A400
Mechanism of action of delayed amine catalyst A400 in slow rebound memory foam
Product parameters of delayed amine catalyst A400
Advantages of Retarded Amine Catalyst A400
Application Cases of Retarded Amine Catalyst A400
The market prospects of delayed amine catalyst A400
Conclusion

1. Introduction

Slow rebound memory foam (Memory Foam) is a polymer material with unique properties and is widely used in mattresses, pillows, seats and other products. Its unique slow rebound properties allow it to adapt to the shape and temperature of the human body, providing excellent comfort and support. However, the selection of catalysts is crucial in the production process of slow rebound memory foam. As a highly efficient catalyst, the delayed amine catalyst A400 plays an important role in the production of slow rebound memory foam. This article will introduce in detail the application of delayed amine catalyst A400 in slow rebound memory foam, including its mechanism of action, product parameters, application advantages and market prospects.

2. Basic concepts of slow rebound memory foam

Slow rebound memory foam is a polyurethane foam material with an open cell structure. Its unique slow rebound characteristics are derived from the flexibility and elasticity of its polymer chains. When subjected to external forces, the memory foam will slowly deform and gradually return to its original state after external forces are removed. This characteristic allows the memory foam to effectively disperse pressure, reduce the pressure point between the body and the contact surface, thereby providing better comfort and support.

2.1 Main characteristics of slow rebound memory foam

Slow Resilience: The memory foam will slowly return to its original state after being affected by external forces, which enables it to effectively disperse pressure.
Temperature Sensitivity: Memory foam is sensitive to temperature and can adapt to the temperature of the human body to provide a better fit.
Open Cellular Structure: Memory foam has an open cell structure, making it have good breathability and hygroscopicity.

2.2 Application fields of slow rebound memory foam

Mattress: Memory foam mattress can adapt to the shape and temperature of the human body, providing excellent comfortand supportive.
Pillow: Memory foam pillow can effectively disperse the pressure on the head and reduce neck fatigue.
Seat: Memory foam seats can provide better support and comfort, reducing discomfort caused by long-term sitting posture.

3. Overview of Retarded Amine Catalyst A400

The delayed amine catalyst A400 is a highly efficient polyurethane catalyst, widely used in the production of slow rebound memory foam. Its unique delayed catalytic properties allow it to provide longer operating times during the polyurethane reaction while ensuring efficient progress of the reaction.

3.1 Chemical properties of retardant amine catalyst A400

Chemical Name: N,N-dimethylcyclohexylamine
Molecular formula: C8H17N
Molecular Weight: 127.23 g/mol
Appearance: Colorless to light yellow liquid
Density: 0.86 g/cm³
Boiling point: 160-162°C
Flash Point: 45°C

3.2 Main functions of retardant amine catalyst A400

Delayed Catalysis: The delayed amine catalyst A400 can provide longer operating time during the polyurethane reaction, making operation in the production process more flexible.
High-efficiency Catalysis: Despite its delayed catalytic properties, the delayed amine catalyst A400 can still ensure efficient progress of the polyurethane reaction and improve production efficiency.
Stability: The delayed amine catalyst A400 has high stability during storage and use, and is not easy to decompose or fail.

4. Mechanism of action of delayed amine catalyst A400 in slow rebound memory foam

The delayed amine catalyst A400 plays an important role in the production of slow rebound memory foam. Its mechanism of action is mainly reflected in the following aspects:

4.1 Delayed catalysis

The delayed amine catalyst A400 can provide longer operating time during the polyurethane reaction. This feature makes operation during production more flexible and can be controlled betterThe reaction process ensures the quality and performance of the product.

4.2 High-efficiency catalytic action

Despite its delayed catalytic properties, the delayed amine catalyst A400 can ensure efficient progress of the polyurethane reaction. Its efficient catalytic effect can improve production efficiency, shorten production cycles, and reduce production costs.

4.3 Stability effect

The delayed amine catalyst A400 has high stability during storage and use, and is not easy to decompose or fail. This characteristic enables it to maintain stable catalytic performance during production, ensuring product quality and consistency.

5. Product parameters of delayed amine catalyst A400

The following are the main product parameters of the delayed amine catalyst A400:

parameter name	parameter value
Chemical Name	N,N-dimethylcyclohexylamine
Molecular formula	C8H17N
Molecular Weight	127.23 g/mol
Appearance	Colorless to light yellow liquid
Density	0.86 g/cm³
Boiling point	160-162°C
Flashpoint	45°C
Storage temperature	15-25°C
Storage Conditions	Cool, dry, ventilated
Packaging Specifications	25kg/barrel
Shelf life	12 months

6. Application advantages of delayed amine catalyst A400

The delayed amine catalyst A400 has the following application advantages in the production of slow rebound memory foam:

6.1 Improve production efficiency

The efficient catalytic action of the delayed amine catalyst A400 can improve production efficiency, shorten production cycles, and reduce production costs.

6.2 Improve product quality

The delayed catalytic characteristics of the delayed amine catalyst A400 enable the generation ofThe operation during the production process is more flexible, and the reaction process can be better controlled and the quality and performance of the product are ensured.

6.3 Reduce production costs

The efficient catalytic action and stability of the delayed amine catalyst A400 can reduce production costs and improve production efficiency.

6.4 Environmental performance

The delayed amine catalyst A400 will not produce harmful substances during the production process and has good environmental protection performance.

7. Application cases of delayed amine catalyst A400

The following are the application cases of delayed amine catalyst A400 in the production of slow rebound memory foam:

7.1 Case 1: Mattress production

A mattress manufacturer uses the delayed amine catalyst A400 as a catalyst when producing slow rebound memory foam mattresses. By using the delayed amine catalyst A400, the company has successfully improved production efficiency, shortened production cycles, and ensured product quality and performance. The final production mattress has good slow rebound characteristics and comfort, and is very popular among consumers.

7.2 Case 2: Pillow production

A pillow manufacturer uses the delayed amine catalyst A400 as a catalyst when producing slow rebound memory foam pillows. By using the delayed amine catalyst A400, the company successfully improved production efficiency, reduced production costs, and ensured product quality and performance. The final production pillow has good slow rebound characteristics and comfort, which is very popular among consumers.

7.3 Case 3: Seat production

A seat manufacturer uses the delay amine catalyst A400 as a catalyst when producing slow rebound memory foam seats. By using the delayed amine catalyst A400, the company has successfully improved production efficiency, shortened production cycles, and ensured product quality and performance. The final production seats have good slow rebound characteristics and comfort, which are very popular among consumers.

8. Market prospects of delayed amine catalyst A400

With the widespread application of slow rebound memory foam in mattresses, pillows, seats and other products, the market demand for delayed amine catalyst A400 is also increasing. Its unique delayed catalytic characteristics and efficient catalytic action make it have broad application prospects in the production of slow rebound memory foam.

8.1 Market demand

As people’s requirements for comfort and health continue to increase, the market demand for slow rebound memory foam continues to increase. As a key catalyst in the production of slow rebound memory foam, the market demand for delayed amine catalyst A400 is also increasing.

8.2 Technology Development

With the continuous development of polyurethane technology, the performance of delayed amine catalyst A400 is also constantly improving. In the future, with the further development of technology, the performance of delayed amine catalyst A400 will be better and the application range will be wider.pan.

8.3 Environmental protection trends

With the continuous improvement of environmental awareness, the market demand for environmentally friendly catalysts continues to increase. The delay amine catalyst A400 has good environmental protection performance, conforms to environmental protection trends, and has broad market prospects in the future.

9. Conclusion

As a highly efficient polyurethane catalyst, the delayed amine catalyst A400 plays an important role in the production of slow rebound memory foam. Its unique delayed catalytic characteristics and efficient catalytic action make it have broad application prospects in the production of slow rebound memory foam. By using the delayed amine catalyst A400, enterprises can improve production efficiency, reduce production costs, and ensure product quality and performance. In the future, with the increasing market demand for slow rebound memory foam and the continuous development of polyurethane technology, the market prospects of delayed amine catalyst A400 will be broader.