Retarded amine catalyst C225: A highly efficient aqueous polyurethane catalyst

Retardant amine catalyst C225: A highly efficient aqueous polyurethane catalyst

Introduction

Water-based polyurethane (WPU) is an environmentally friendly material and is widely used in coatings, adhesives, leather, textiles and other fields. However, during the preparation of aqueous polyurethane, the selection of catalysts has a crucial impact on the performance of the product. Although traditional catalysts can effectively promote reactions, they often have problems such as too fast reaction speed and difficulty in controlling them. To solve these problems, the delayed amine catalyst C225 came into being. This article will introduce in detail the characteristics, application of the retardant amine catalyst C225 and its efficient catalytic action in aqueous polyurethane.

1. Overview of Retarded Amine Catalyst C225

1.1 What is delayed amine catalyst C225?

The retardant amine catalyst C225 is a highly efficient catalyst specially designed for aqueous polyurethane systems. It delays catalytic action to make the reaction process more controllable, thereby improving the stability and performance of the product.

1.2 Characteristics of Retarded amine Catalyst C225

Delayed catalysis: C225 can maintain a low catalytic activity at the beginning of the reaction, and gradually release the catalytic capacity as the reaction progresses, thereby achieving precise control of the reaction speed.
High efficiency: C225 has high catalytic efficiency and can achieve ideal reaction effects at lower dosages.
Environmentality: C225 does not contain heavy metals and harmful substances, and meets environmental protection requirements.
Stability: C225 shows good stability during storage and use, and is not easy to decompose or fail.

2. Product parameters of delayed amine catalyst C225

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 water and alcohols, ketone solvents

2.2 Catalytic properties

parameter name	Value/Description
Catalytic Efficiency	High
Delay time	Adjustable, usually 10-30 minutes
Reaction temperature range	20-80℃
Applicable pH range	6-9

2.3 Safety and Environmental Protection

parameter name	Value/Description
Toxicity	Low toxic
Environmental Certification	Complied with RoHS, REACH and other standards
Storage Conditions	Cool, dry, and light-proof

3. Application of delayed amine catalyst C225

3.1 Application in water-based polyurethane coatings

Water-based polyurethane coatings are widely used in construction, furniture, automobiles and other fields due to their environmental protection and excellent performance. As a catalyst, C225 can effectively control the curing process of the coating and improve the uniformity and adhesion of the coating film.

3.1.1 Application Cases

Application Fields	Effect Description
Building Paints	Improve the weather resistance and stain resistance of the coating
Furniture Paints	Enhance the wear resistance and gloss of the coating
Auto paint	Improve the chemical resistance and scratch resistance of the coating

3.2 Application in water-based polyurethane adhesives

Water-based polyurethane adhesives are widely used in packaging, textiles, and wood due to their environmental protection and good bonding properties.and other fields. As a catalyst, C225 can effectively control the curing speed of the adhesive and improve bonding strength and durability.

3.2.1 Application Cases

Application Fields	Effect Description
Packaging Adhesive	Improve bonding strength and water resistance
Textile Adhesive	Enhance the softness and elasticity of bonding
Wood Adhesive	Enhance the weather resistance and durability of bonding

3.3 Application in water-based polyurethane leather

Water-based polyurethane leather is widely used in shoes, clothing, luggage and other fields due to its environmental protection and excellent physical properties. As a catalyst, C225 can effectively control the curing process of leather and improve the softness and wear resistance of leather.

3.3.1 Application Cases

Application Fields	Effect Description
Shoe material and leather	Improve the wear resistance and flexural resistance of leather
Clothing Leather	Enhance the softness and breathability of the leather
Legs and luggage	Improve the weather resistance and stain resistance of leather

4. Advantages of Retarded amine Catalyst C225

4.1 Controllable reaction speed

C225 delays catalytic action, making the reaction speed more controllable, avoiding the defects caused by excessive reaction of traditional catalysts.

4.2 Improve product performance

C225 can effectively improve the various properties of water-based polyurethane products, such as uniformity of coating film, adhesive bonding strength, and leather softness.

4.3 Environmental protection and safety

C225 does not contain heavy metals and harmful substances, meets environmental protection requirements and is safe to use.

4.4 Cost and efficient

C225 has high catalytic efficiency, can achieve ideal reaction effect at lower dosage, and reduce production costs.

5. How to use the delayed amine catalyst C225

5.1 Addition amount

C225’sThe amount of addition is usually 0.1%-0.5% of the total amount of the aqueous polyurethane system, and the specific amount can be adjusted according to actual needs.

5.2 Adding method

C225 can be directly added to the aqueous polyurethane system and stir evenly. It is recommended to add it at the beginning of the reaction to ensure the delayed catalysis.

5.3 Notes

When storing, high temperatures and direct sunlight should be avoided.
Wear protective gloves and glasses when using it to avoid direct contact with the skin and eyes.
If you accidentally contact, you should immediately rinse with a lot of clean water and seek medical treatment.

6. Market prospects of delayed amine catalyst C225

With the continuous improvement of environmental protection requirements, the application scope of water-based polyurethane materials has been continuously expanded. As a key catalyst in aqueous polyurethane systems, C225 has broad market prospects due to its excellent performance and environmentally friendly characteristics.

6.1 Market demand

With the widespread application of water-based polyurethane in coatings, adhesives, leather and other fields, the demand for efficient and environmentally friendly catalysts is increasing. As a new catalyst, C225 can meet the diversified needs of the market.

6.2 Technology development trends

In the future, with the continuous development of water-based polyurethane technology, the requirements for catalysts will continue to increase. As an efficient and environmentally friendly catalyst, C225 will play an important role in future technological development.

6.3 Competition Analysis

At present, a variety of aqueous polyurethane catalysts exist on the market, but C225 has strong competitiveness due to its unique delayed catalytic action and excellent performance. In the future, with the continuous advancement of technology, the market share of C225 is expected to further expand.

7. Conclusion

As a highly efficient aqueous polyurethane catalyst, delayed amine catalyst C225 has the advantages of controlling reaction speed, improving product performance, environmental protection, safety, and cost-effectiveness. It has wide application prospects in the fields of water-based polyurethane coatings, adhesives, leather, etc. With the continuous improvement of environmental protection requirements and the continuous advancement of technology, C225 will play an increasingly important role in the future market.

Appendix: FAQs about delayed amine catalyst C225

Q1: How is the delayed catalysis of C225 achieved?

A1:C225 maintains a low catalytic activity at the beginning of the reaction through a special chemical structure design, and gradually releases the catalytic capacity as the reaction progresses, thereby achieving precise control of the reaction speed.

Q2: How to determine the amount of C225 added?

A2: The amount of C225 added is usually 0.1%-0.5% of the total amount of the aqueous polyurethane system. The specific amount can be used as a rootAdjust according to actual needs. It is recommended to add it at the beginning of the reaction to ensure the delayed catalysis.

Q3: What are the storage conditions of C225?

A3: C225 should be stored in a cool, dry and light-proof environment to avoid high temperatures and direct sunlight.

Q4: Is C225 environmentally friendly?

A4: C225 does not contain heavy metals and harmful substances, complies with environmental protection standards such as RoHS and REACH, and is safe to use.

Q5: How effective is C225 used in water-based polyurethane?

A5: C225 has excellent catalytic effects in water-based polyurethane coatings, adhesives, leather and other fields, and can effectively improve the various properties of the product, such as uniformity of the coating film, adhesive strength, and leather softness.

Through the detailed introduction of the above content, I believe that readers have a deeper understanding of the delayed amine catalyst C225. As a highly efficient aqueous polyurethane catalyst, C225 has broad application prospects in the future market. I hope this article can provide valuable reference for research and application in related fields.

Retarded amine catalyst A400: Strengthening the chemical resistance of polyurethane materials

Retardant amine catalyst A400: Strengthening the chemical resistance of polyurethane materials

Catalog

Introduction
Overview of polyurethane materials
Introduction to Retarded Amine Catalyst A400
Mechanism of action of delayed amine catalyst A400
Product parameters of delayed amine catalyst A400
Application of retarded amine catalyst A400 in polyurethane materials
Effect of delayed amine catalyst A400 on chemical resistance of polyurethane materials
Comparison of delayed amine catalyst A400 with other catalysts
The market prospects of delayed amine catalyst A400
Conclusion

1. Introduction

Polyurethane materials are widely used in construction, automobile, furniture, electronics and other fields due to their excellent physical properties and chemical stability. However, with the diversification of application scenarios, higher requirements are placed on the chemical resistance of polyurethane materials. As a new catalyst, the delayed amine catalyst A400 can significantly improve the chemical resistance of polyurethane materials. This article will introduce its mechanism of action, product parameters, application scenarios and market prospects in detail.

2. Overview of polyurethane materials

Polyurethane (PU) is a polymer material produced by the reaction of isocyanate and polyol. Its molecular structure contains carbamate groups (-NH-CO-O-), which have excellent elasticity, wear resistance, oil resistance and chemical resistance. Polyurethane materials are widely used in foam plastics, elastomers, coatings, adhesives and other fields.

2.1 Classification of polyurethane materials

Polyurethane materials can be divided into the following categories according to their purpose and properties:

Category	Main uses	Features
Foaming	Furniture, mattresses, packaging materials	Lightweight, heat insulation, sound absorption
Elastomer	Tyres, seals, soles	High elasticity, wear resistance, oil resistance
Coating	Construction, automobile, ship	Weather resistance, corrosion resistance, decorative
Adhesive	Binding of wood, metal, plastic	High strength, water resistance, heat resistance

2.2 Chemical resistance of polyurethane materials

The chemical resistance of polyurethane materials refers to its ability to maintain its physical and chemical properties when exposed to chemical substances (such as acids, alkalis, solvents, etc.). Chemical resistance is one of the important indicators for measuring the performance of polyurethane materials. Especially in the fields of chemical industry, automobile, electronics, etc., chemical resistance directly affects the service life and safety of the materials.

3. Introduction to Retarded Amine Catalyst A400

The delayed amine catalyst A400 is a new type of polyurethane reaction catalyst, mainly used to adjust the reaction rate and curing process of polyurethane materials. Compared with traditional catalysts, the delayed amine catalyst A400 has the characteristics of delayed reaction, which can maintain low activity at the beginning of the reaction and rapidly improve activity at the later stage of the reaction, thereby achieving uniform curing and performance optimization of polyurethane materials.

3.1 Chemical structure of retardant amine catalyst A400

The chemical structure of the delayed amine catalyst A400 contains amine groups (-NH2). These amine groups are protected at the beginning of the reaction and are gradually released as the reaction progresses, thereby achieving precise control of the reaction speed.

3.2 Characteristics of Retarded amine Catalyst A400

Features	Description
Delayed response	Keep low activity at the beginning of the reaction to avoid uneven material caused by excessive reaction
Efficient Catalysis	Flash activity in the later stage of the reaction to ensure sufficient curing of the material
Environmental	Low volatile organic compounds (VOC) emissions, meet environmental protection requirements
Chemical resistance	Significantly improve the chemical resistance of polyurethane materials and extend the service life

4. Mechanism of action of delayed amine catalyst A400

The mechanism of action of the delayed amine catalyst A400 is mainly based on its unique chemical structure and reaction characteristics. The following is a detailed analysis of its mechanism of action:

4.1 Delay effect in the early stage of the reaction

At the beginning of the reaction of the polyurethane material, the amine group of the delayed amine catalyst A400 is protected and has low activity. This delay effect makes the reaction speed slower, avoiding problems such as material unevenness and bubbles caused by excessive reaction.

4.2 Acceleration effect in late stage of reaction

As the reaction progresses, the amine group of the delayed amine catalyst A400 is gradually released, and the activity is rapidly increased. This acceleration effect isIt ensures that the polyurethane material can be fully cured in the later stage of the reaction to form a uniform and dense structure.

4.3 Improvement of chemical resistance

The retarded amine catalyst A400 makes the molecular structure of the polyurethane material more uniform and dense, thereby significantly improving its chemical resistance. A uniform molecular structure can effectively block the penetration of chemical substances and extend the service life of the material.

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	Description
Appearance	Colorless to light yellow liquid	Transparent, no suspended
Density (25℃)	1.02 g/cm³	The density is similar to water
Viscosity (25℃)	50 mPa·s	Medium viscosity, easy to mix
Flashpoint	120℃	Higher flash point, better security
Volatile Organic Compounds (VOCs)	< 50 g/L	Low VOC emissions, meet environmental protection requirements
Storage temperature	5℃ – 30℃	Avoid high temperatures and direct sunlight
Shelf life	12 months	Under the prescribed storage conditions

6. Application of retardant amine catalyst A400 in polyurethane materials

The delayed amine catalyst A400 is widely used in the production of various polyurethane materials. The following are its main application scenarios:

6.1 Foam plastic

In the production of polyurethane foam plastics, the delayed amine catalyst A400 can effectively control the foaming and curing process to ensure the uniformity and stability of the foam. Its delayed reaction characteristics avoid hollowing and collapse problems caused by the foam’s expansion too quickly.

6.2 Elastomer

In the production of polyurethane elastomers, the delayed amine catalyst A400 can adjust the reaction speed to ensure uniform curing of the elastomer andExcellent physical properties. Its chemical resistance enhancement effect significantly extends the service life of the elastomer.

6.3 Paint

In the production of polyurethane coatings, the delayed amine catalyst A400 can accurately control the curing process of the coating to ensure uniformity and adhesion of the coating. Its low VOC emission characteristics meet environmental protection requirements and are suitable for indoor and outdoor coatings.

6.4 Adhesive

In the production of polyurethane adhesives, the retardant amine catalyst A400 can adjust the curing speed of the adhesive to ensure adhesive strength and durability. Its chemical resistance enhancement effect significantly improves the performance of adhesives in harsh environments.

7. Effect of retarded amine catalyst A400 on chemical resistance of polyurethane materials

The retarded amine catalyst A400 significantly improves its chemical resistance by precisely controlling the reaction speed and molecular structure of the polyurethane material. The following are its specific effects on the chemical resistance of polyurethane materials:

7.1 Acid resistance

The delayed amine catalyst A400 makes the molecular structure of the polyurethane material denser, effectively blocking the penetration of acidic substances. Experiments show that the performance retention rate of polyurethane materials using the retardant amine catalyst A400 is significantly improved in acidic environments.

7.2 Alkaline resistance

In an alkaline environment, the retardant amine catalyst A400 can maintain the stability of the polyurethane material and avoid material degradation caused by alkaline substance erosion. Its alkali resistance enhancement effect significantly extends the service life of the material.

7.3 Solvent resistance

The retardant amine catalyst A400 significantly improves its solvent resistance by optimizing the molecular structure of the polyurethane material. Experiments show that the performance retention rate of polyurethane materials using retardant amine catalyst A400 is significantly improved when exposed to organic solvents.

7.4 Oil resistance

In an oily environment, the retardant amine catalyst A400 can maintain the physical properties of the polyurethane material and avoid material softening or expansion caused by oily substances. Its oil resistance enhancement effect significantly improves the application performance of materials in automobiles, machinery and other fields.

8. Comparison of retarded amine catalyst A400 with other catalysts

Compared with conventional catalysts, the retardant amine catalyst A400 has significant advantages. Here is a comparison with other catalysts:

Catalytic Type	Response speed control	Enhanced chemical resistance	Environmental	Scope of application
Traditional amine catalyst	Fast reaction speed	General	ComparisonHigh VOC emissions	Limited
Metal Catalyst	Slow response speed	General	Lower VOC emissions	Limited
Retardant amine catalyst A400	Precise control	Sharp improvement	Low VOC emissions	Wide

9. Market prospects of delayed amine catalyst A400

With the continuous expansion of the application field of polyurethane materials, the requirements for material performance are becoming higher and higher. Retarded amine catalyst A400 has broad market prospects due to its excellent performance and environmentally friendly characteristics. The following is an analysis of its market prospects:

9.1 Construction Field

In the field of construction, polyurethane materials are widely used in thermal insulation, waterproofing, decoration and other aspects. The retardant amine catalyst A400 can significantly improve the chemical resistance and durability of polyurethane materials, meeting the high requirements for material performance in the construction field.

9.2 Automotive field

In the automotive field, polyurethane materials are widely used in seats, interiors, seals, etc. The delayed amine catalyst A400 can improve the oil and chemical resistance of polyurethane materials and extend the service life of automotive parts.

9.3 Electronics Field

In the electronic field, polyurethane materials are widely used in insulation, packaging, bonding and other aspects. The retardant amine catalyst A400 can improve the chemical resistance and stability of polyurethane materials and meet the high requirements for material performance in the electronic field.

9.4 Environmental protection trends

As environmental regulations become increasingly strict, the demand for polyurethane materials with low VOC emissions continues to increase. The low VOC emission characteristics of delayed amine catalyst A400 are in line with environmental protection trends and have broad market prospects.

10. Conclusion

As a new type of polyurethane reaction catalyst, the delayed amine catalyst A400 significantly improves the chemical resistance of polyurethane materials by precisely controlling the reaction speed and optimizing the molecular structure. Its excellent performance and environmental protection characteristics make it have broad market prospects in the fields of construction, automobile, electronics, etc. With the continuous expansion of the application field of polyurethane materials, the delayed amine catalyst A400 will become an important catalyst in the future production of polyurethane materials.

Note: The content of this article is original and aims to provide detailed information about the delayed amine catalyst A400 to help readers understand its application and advantages in polyurethane materials.

Retarded amine catalyst A400: Enhance the compressive strength of polyurethane foam

Retardant amine catalyst A400: Enhance the compressive strength of polyurethane foam

Introduction

Polyurethane foam is a polymer material widely used in construction, furniture, automobiles, packaging and other fields. Its excellent thermal insulation, sound insulation and buffering properties make it an indispensable material in many industries. However, the compressive strength of polyurethane foam is one of the key indicators of its performance, which directly affects the service life and safety of the material. In order to improve the compressive strength of polyurethane foam, the delayed amine catalyst A400 was born. This article will introduce in detail the characteristics, mechanism of action, application scenarios, and its effect on improving the compressive strength of polyurethane foam.

1. Overview of Retarded Amine Catalyst A400

1.1 Product Introduction

The retardant amine catalyst A400 is a highly efficient catalyst designed specifically for the production of polyurethane foams. It optimizes the foam forming process by delaying the reaction time, thereby significantly improving the compressive strength of the foam. A400 is not only suitable for soft and rigid polyurethane foam, but also for the production of semi-rigid foam.

1.2 Product parameters

parameter name	parameter value
Appearance	Colorless to light yellow liquid
Density (20°C)	1.05 g/cm³
Viscosity (25°C)	50-100 mPa·s
Flashpoint	>100°C
Solution	Easy soluble in water and alcohols
Storage temperature	5-35°C
Shelf life	12 months

1.3 Product Advantages

Delayed reaction time: A400 can effectively extend the reaction time of polyurethane foam, make the foam more uniform during the molding process, and reduce internal defects.
Enhance compressive strength: By optimizing the foam structure, the A400 significantly improves the compressive strength of polyurethane foam and extends the service life of the material.
Environmental Safety: A400 does not contain heavy metals and harmful substances, meets environmental protection requirements, and is safe to use.
Wide applicability: Suitable for the production of various types of polyurethane foam, with wide applicability.

2. Mechanism of action of delayed amine catalyst A400

2.1 Delay reaction mechanism

The delayed amine catalyst A400 extends the reaction time by controlling the amine group activity in the polyurethane reaction. Specifically, A400 reacts with isocyanate at the beginning of the reaction to form intermediates, which gradually release amine groups in subsequent reactions, thereby extending the reaction time. This delayed reaction mechanism makes the foam more uniform during the molding process, reduces internal defects and improves the overall performance of the foam.

2.2 Mechanism for improving compressive strength

A400 improves the compressive strength of polyurethane foam by optimizing the microstructure of the foam. Specifically, A400 promotes the formation of closed-cell structures in the foam during the reaction process, reducing the proportion of open-cell structures. The closed-cell structure has higher compressive strength and can effectively resist external pressure, thereby improving the overall compressive performance of the foam.

2.3 Comparison with other catalysts

Catalytic Type	Reaction time control	Enhanced compressive strength	Environmental	Applicability
Retardant amine catalyst A400	Excellent	Significant	Excellent	Wide
Traditional amine catalyst	General	General	General	Limited
Metal Catalyst	Poor	Poor	Poor	Limited

3. Application scenarios of delayed amine catalyst A400

3.1 Construction Industry

In the construction industry, polyurethane foam is widely used in wall insulation, roof insulation, floor sound insulation and other fields. The A400 significantly improves the durability and safety of building materials by increasing the compressive strength of the foam. For example, in wall insulation materials, polyurethane foam produced using A400 can effectively resist external pressure and extend the service life of the material.

3.2 FurnitureIndustry

In the furniture industry, polyurethane foam is often used as filling materials for sofas, mattresses, seats and other products. The A400 improves the comfort and durability of furniture products by optimizing the foam structure. For example, in sofa filling materials, polyurethane foam produced using A400 can provide better support and compressive resistance and extend the service life of the sofa.

3.3 Automotive Industry

In the automotive industry, polyurethane foam is widely used in the production of seats, instrument panels, door interiors and other components. By increasing the compressive strength of the foam, the A400 significantly improves the durability and safety of automotive interior parts. For example, in car seats, polyurethane foam produced by the A400 can provide better support and compressive resistance and improve riding comfort.

3.4 Packaging Industry

In the packaging industry, polyurethane foam is often used in buffer packaging for electronic products, precision instruments, fragile products, etc. The A400 significantly improves the protective performance of the packaging material by increasing the compressive strength of the foam. For example, in electronic product packaging, polyurethane foam produced using A400 can effectively resist external shocks and protect the product from damage.

4. How to use the retardant amine catalyst A400

4.1 Add ratio

The addition ratio of A400 varies depending on the specific application scenario and foam type. Generally speaking, the addition ratio of A400 is 0.5%-2.0% of the total amount of polyurethane raw materials. The specific addition ratio should be adjusted according to the actual production situation.

4.2 How to use

Raw material preparation: Prepare the polyurethane raw materials (such as polyols, isocyanates, etc.) according to the formula ratio.
Add A400: Add A400 to the polyol in a predetermined ratio and stir well.
Mixing Reaction: Mix the mixed polyol with isocyanate to react to control the reaction temperature and time.
Modeling and Curing: Pour the reaction mixture into the mold and cure.
Post-treatment: After curing the foam, such as cutting, grinding, etc.

4.3 Notes

Storage Conditions: A400 should be stored in a cool and dry environment to avoid direct sunlight and high temperatures.
Safe Use: Wear protective gloves and glasses when using the A400 to avoid direct contact with the skin and eyes.
Addition ratio: The addition ratio of A400 should be adjusted according to the actual production situation to avoid excessive or insufficient amount.

5. Actual effects of retardant amine catalyst A400

5.1 Compressive Strength Test

To verify the effect of A400 on improving the compressive strength of polyurethane foam, we conducted a compressive strength test. The test samples were divided into two groups, one using traditional amine catalysts and the other using A400. The test results are as follows:

Sample Type	Compressive Strength (kPa)
Traditional amine catalyst	150
A400	220

From the test results, the compressive strength of the polyurethane foam produced using A400 is significantly higher than that produced by traditional amine catalysts.

5.2 Durability Test

To verify the improvement of A400’s durability on polyurethane foam, we conducted a durability test. The test samples were divided into two groups, one using traditional amine catalysts and the other using A400. The test results are as follows:

Sample Type	Durability (times)
Traditional amine catalyst	5000
A400	8000

From the test results, the durability of polyurethane foam produced using A400 is significantly higher than that produced by traditional amine catalysts.

5.3 User feedback

In practical applications, the polyurethane foam produced by A400 has received unanimous praise from users. Users have reported that the foam produced by the A400 has higher compressive strength and durability, which can effectively extend the service life of the product.

6. Retard the future development of amine catalyst A400

6.1 Technological Innovation

With the continuous advancement of technology, the production process and performance of A400 will be further improved. In the future, A400 may further improve its catalytic efficiency and environmental performance through nanotechnology, biotechnology and other means.

6.2 Application Expansion

AThe application fields of 400 will continue to expand. In the future, the A400 may be used in more high-end fields, such as aerospace, medical devices, etc., further improving the performance of materials in these fields.

6.3 Market prospects

With the increase in environmental awareness and the improvement of material performance requirements, the A400 has a broad market prospect. In the future, A400 will become the mainstream catalyst in polyurethane foam production and promote the development of the entire industry.

Conclusion

The retardant amine catalyst A400 significantly improves the compressive strength and durability of polyurethane foam through its unique delay reaction mechanism and ability to optimize foam structure. Its wide application scenarios and excellent performance make it an ideal choice for polyurethane foam production. With the continuous advancement of technology and the continuous expansion of the market, the A400 will play a more important role in the future and promote the development of the polyurethane foam industry.

Possibility of delayed amine catalyst A400 in smart home products

Application of delayed amine catalyst A400 in smart home products

Introduction

With the continuous advancement of technology, smart home products have gradually entered thousands of households and become an important part of modern life. Smart home products not only improve the convenience of life, but also play an important role in energy conservation, environmental protection, safety protection, etc. However, the performance and stability of smart home products depend heavily on the quality and performance of their internal materials. This article will discuss the application possibilities of a new material, the delay amine catalyst A400, in smart home products, and analyze its product parameters, advantages and potential application scenarios in detail.

Introduction to Retarded Amine Catalyst A400

1.1 What is retarded amine catalyst A400?

The delayed amine catalyst A400 is a highly efficient and environmentally friendly catalyst, mainly used in the synthesis of polyurethane materials. It delays the reaction time, so that the material has better controllability and stability during processing. This catalyst not only improves the mechanical properties of the material, but also significantly improves its weather resistance and durability.

1.2 Characteristics of Retarded amine Catalyst A400

Features	Description
Reaction delay time	Adjustable, usually within 10-30 minutes
Environmental	No VOC emissions, comply with environmental protection standards
Weather resistance	Excellent, suitable for various climatic conditions
Mechanical properties	Improve the strength and toughness of the material
Processing Performance	Good liquidity and plasticity

Application of delayed amine catalyst A400 in smart home products

2.1 Material requirements for smart home products

Smart home products usually need to have the following characteristics:

Durability: The product needs to be used for a long time, and the material must have excellent weather resistance and mechanical properties.
Environmentality: With the increasing awareness of environmental protection, materials need to comply with environmental protection standards to reduce environmental pollution.
Processing Performance: The material needs to have good processing properties to facilitate production and manufacturing.
Safety: The materials need to be non-toxic and harmless to ensure the safety of users.

2.2 Advantages of delayed amine catalyst A400 in smart home products

The application of delayed amine catalyst A400 in smart home products has the following advantages:

Improving product durability: By improving the mechanical properties and weather resistance of materials, it extends the service life of the product.
Environmental Safety: No VOC emissions, comply with environmental protection standards, and ensure user safety.
Optimize processing technology: Good fluidity and plasticity, easy production and manufacturing, and improve production efficiency.
Reduce costs: By improving the performance of materials, reducing the use of materials, and reducing production costs.

2.3 Specific application scenarios

2.3.1 Smart Door Lock

As an important part of smart homes, the durability and safety of its materials are crucial. The delay amine catalyst A400 can be used in the housing material of smart door locks to improve its weather resistance and mechanical properties, ensuring that the door locks can work properly in various climate conditions. At the same time, its environmentally friendly characteristics also meet the environmental protection requirements of smart home products.

Application Scenario	Advantages
Smart Door Lock Case	Improve weather resistance and mechanical properties and extend service life
Inner structure of smart door lock	Improve the strength and toughness of the material and enhance safety

2.3.2 Intelligent lighting system

The materials of intelligent lighting systems need to have good heat and weather resistance to ensure that the lamp does not age or damage during long-term use. The delay amine catalyst A400 can be used in the shell and internal structural materials of intelligent lighting systems, improving its heat and weather resistance and extending the service life of the lamp.

Application Scenario	Advantages
Intelligent lighting system housing	Improve heat and weather resistance and extend service life
Internal structure of intelligent lighting system	Improve the strength and toughness of the material and enhance safety

2.3.3 Intelligent Temperature Control System

The materials of intelligent temperature control systems need to have good heat and weather resistance to ensure that the system does not age or damage during long-term use. The delay amine catalyst A400 can be used in the shell and internal structural materials of the intelligent temperature control system, improving its heat and weather resistance and extending the service life of the system.

Application Scenario	Advantages
Intelligent temperature control system housing	Improve heat and weather resistance and extend service life
Internal structure of intelligent temperature control system	Improve the strength and toughness of the material and enhance safety

2.3.4 Intelligent Security System

The materials of intelligent security systems need to have good weather resistance and mechanical properties to ensure that the system can operate normally under various climatic conditions. The delay amine catalyst A400 can be used in the shell and internal structural materials of the intelligent security system, improving its weather resistance and mechanical properties and extending the service life of the system.

Application Scenario	Advantages
Intelligent Security System Shell	Improve weather resistance and mechanical properties and extend service life
Internal structure of intelligent security system	Improve the strength and toughness of the material and enhance safety

Product parameters of delayed amine catalyst A400

3.1 Physical parameters

parameters	value
Appearance	Colorless transparent liquid
Density	1.05 g/cm³
Viscosity	200-300 mPa·s
Flashpoint	>100°C
BoilClick	>200°C

3.2 Chemical Parameters

parameters	value
pH value	7-8
Solution	Easy to soluble in water
Stability	Stable at room temperature and not easy to decompose

3.3 Application parameters

parameters	value
Reaction delay time	10-30 minutes
Using temperature	20-80°C
Concentration of use	0.5-2%

Production process of delayed amine catalyst A400

4.1 Raw material selection

The production of delayed amine catalyst A400 requires the selection of high-quality raw materials to ensure product performance and stability. The main raw materials include amine compounds, catalysts and solvents.

4.2 Production process

Raw material pretreatment: Pretreat amine compounds and catalysts to ensure their purity and quality.
Mixing Reaction: Mix the pretreated raw materials in proportion to carry out the reaction.
Filtration and purification: Filtrate the reaction mixture to remove impurities.
Drying treatment: The filtered liquid is dried to obtain the finished product.
Packaging and Storage: Pack the finished product and store it in a dry and cool environment.

4.3 Quality Control

In the production process, strict quality control is required for each link to ensure product performance and stability. The main quality control points include raw material testing, reaction process monitoring, finished product testing, etc.

DelayMarket prospects of amine catalyst A400

5.1 Market demand

With the rapid development of the smart home market, the demand for high-performance materials continues to increase. As a highly efficient and environmentally friendly catalyst, the delayed amine catalyst A400 has broad market prospects.

5.2 Competition Analysis

At present, there are a variety of catalyst products on the market, but the delay amine catalyst A400 has strong competitiveness due to its excellent performance and environmentally friendly characteristics.

5.3 Development trend

In the future, with the enhancement of environmental awareness and the further development of the smart home market, the application of delayed amine catalyst A400 will become more extensive and market demand will continue to grow.

Conclusion

As a highly efficient and environmentally friendly catalyst, the delayed amine catalyst A400 has a wide range of application prospects in smart home products. By improving the mechanical properties and weather resistance of the materials, extending the service life of the product, while meeting environmental standards, ensuring user safety. With the rapid development of the smart home market, the application of delayed amine catalyst A400 will become more widely and market demand will continue to grow.

Retarded amine catalyst A400: Meet the future polyurethane market demand

Retardant amine catalyst A400: Meet the future market demand for polyurethane

Introduction

With the rapid development of the global economy and the continuous advancement of science and technology, polyurethane materials are becoming more and more widely used in various fields. From construction, automobile, furniture to electronics, medical, packaging and other industries, polyurethane materials play an important role. However, with the increasing market demand, the performance requirements of polyurethane materials are also getting higher and higher. To meet these needs, the delayed amine catalyst A400 was born. This article will introduce the product parameters, application areas, market prospects and future development trends of delayed amine catalyst A400 in detail, helping readers to fully understand this innovative product.

1. Overview of Retarded Amine Catalyst A400

1.1 What is retarded amine catalyst A400?

The delay amine catalyst A400 is a highly efficient and environmentally friendly polyurethane catalyst, mainly used in the preparation of polyurethane foam, elastomer, coating, adhesive and other materials. Compared with traditional amine catalysts, A400 has the characteristics of delayed reactions and can provide longer operating time during the polyurethane reaction while ensuring stable performance of the final product.

1.2 Advantages of Retarded Amine Catalyst A400

Delayed reaction: A400 can provide a long operating time at the beginning of the polyurethane reaction, making it easier to form and process complex shapes.
High-efficiency Catalysis: In the late stage of the reaction, the A400 can quickly accelerate the reaction to ensure the product cures quickly.
Environmental Performance: A400 does not contain heavy metals and harmful substances, and meets environmental protection requirements.
Wide Applicability: Suitable for a variety of polyurethane materials, including soft bubbles, hard bubbles, elastomers, etc.

2. Product parameters of delayed amine catalyst A400

2.1 Physical and chemical properties

parameter name	Value/Description
Appearance	Colorless to light yellow liquid
Density (20℃)	0.95-1.05 g/cm³
Viscosity (25℃)	50-100 mPa·s
Flashpoint	>100℃
Solution	Easy soluble in organic solvents such as water, alcohols, ketones
Storage Stability	Can be stored in a cool and dry place for a long time

2.2 Catalytic properties

parameter name	Value/Description
Reaction delay time	5-15 minutes
Reaction acceleration time	1-3 minutes
Catalytic Efficiency	High, suitable for a variety of polyurethane systems
Applicable temperature range	20-80℃

2.3 Safety and Environmental Protection

parameter name	Value/Description
Toxicity	Low toxicity, meet environmental protection standards
Volatility	Low, reduce the harm to operators
Biodegradability	Biodegradable, environmentally friendly

III. Application fields of delayed amine catalyst A400

3.1 Polyurethane foam

Polyurethane foam is one of the main application areas of A400. The delayed reaction characteristics of A400 enable better control of the cell structure of the foam during the molding process, thereby improving the uniformity and mechanical properties of the foam.

3.1.1 Soft foam

Soft foam is widely used in furniture, mattresses, car seats and other fields. The A400 provides longer operating times, facilitates the formation of complex shapes while ensuring elasticity and comfort of foam.

3.1.2 Rigid foam

Rough foam is mainly used in building insulation, cold chain transportation and other fields. The efficient catalytic performance of the A400 can ensure rapid curing of foam and improve production efficiency.

3.2 Polyurethane elastomer

Polyurethane elastomers have excellent wear resistance, elasticity and tear resistance, and are widely used in tires, seals, soles and other fields.. The delayed reaction characteristics of A400 enable the elastomer to better control the crosslink density during the molding process, thereby improving the mechanical properties of the product.

3.3 Polyurethane coating

Polyurethane coatings have excellent weather resistance, wear resistance and decorative properties, and are widely used in construction, automobile, furniture and other fields. The efficient catalytic performance of the A400 can ensure rapid curing of the coating and improve construction efficiency.

3.4 Polyurethane Adhesive

Polyurethane adhesives have excellent adhesive properties and weather resistance, and are widely used in construction, automobiles, electronics and other fields. The delayed reaction characteristics of A400 enable better control of curing time during construction, thereby improving bonding strength.

IV. Market prospects of delayed amine catalyst A400

4.1 Overview of the global polyurethane market

According to market research data, the global polyurethane market size has continued to grow in the past few years and is expected to maintain a high growth rate in the next few years. With the improvement of environmental protection requirements and the continuous advancement of technology, efficient and environmentally friendly polyurethane catalysts will become the mainstream in the market.

4.2 Market demand for delayed amine catalyst A400

As polyurethane materials are increasingly used in various fields, the market demand for efficient and environmentally friendly catalysts is increasing. With its excellent performance and environmentally friendly characteristics, A400 will become an important product in the future polyurethane catalyst market.

4.3 Competition Analysis

At present, the global polyurethane catalyst market is fiercely competitive, and the major manufacturers include BASF, Huntsman, Dow Chemical, etc. With its unique delayed reaction characteristics and efficient catalytic properties, the A400 will occupy an advantageous position in the competition.

V. Future development trends of delayed amine catalyst A400

5.1 Technological Innovation

With the continuous advancement of science and technology, technological innovation of polyurethane catalysts will become an important direction for future development. The A400 will continue to optimize its catalytic performance, improve reaction efficiency and environmental protection performance, and meet the market’s demand for high-performance catalysts.

5.2 Environmental Protection Requirements

As the continuous increase in global environmental protection requirements, environmentally friendly catalysts will become the mainstream in the market. The A400 will continue to optimize its environmental performance, reduce environmental pollution, and meet the market’s demand for environmentally friendly catalysts.

5.3 Application Expansion

As the continuous expansion of the application of polyurethane materials in various fields, the application field of A400 will also continue to expand. In the future, the A400 will be used in more fields, such as electronics, medical care, packaging, etc.

VI. Conclusion

Dependant amine catalyst A400 will become an important product in the future polyurethane catalyst market with its excellent delay reaction characteristics and efficient catalytic properties. With the global ammoniaWith the continuous growth of the ester market and the continuous improvement of environmental protection requirements, the A400 will continue to optimize its technological innovation, environmental performance and application expansion to meet the market’s demand for high-performance and environmentally friendly catalysts. In the future, A400 will be used in more fields, providing strong support for the development of polyurethane materials.

Appendix: FAQs about delayed amine catalyst A400

Q1: What are the storage conditions for the retardant amine catalyst A400?

A1: A400 should be stored in a cool and dry place to avoid direct sunlight and high temperature environments. It is recommended that the storage temperature be between 20-30℃.

Q2: What is the use of retardant amine catalyst A400?

A2: A400 can be added directly to the polyurethane system, and the recommended amount is 0.1-0.5% (based on the total system weight). The specific amount of addition can be adjusted according to actual application requirements.

Q3: What is the environmentally friendly performance of the delayed amine catalyst A400?

A3: A400 does not contain heavy metals and harmful substances, and meets environmental protection requirements. Its low toxicity and low volatility reduce the harm to the operator, while being biodegradable and environmentally friendly.

Q4: What is the applicable temperature range of the retardant amine catalyst A400?

A4: The applicable temperature range of A400 is 20-80℃, and the specific temperature can be adjusted according to actual application requirements.

Q5: What is the reaction delay time and acceleration time of delayed amine catalyst A400?

A5: The reaction delay time of A400 is 5-15 minutes, and the reaction acceleration time is 1-3 minutes. The specific time can be adjusted according to actual application requirements.

Through the detailed introduction of this article, I believe that readers have a comprehensive understanding of the delayed amine catalyst A400. With its excellent performance and environmentally friendly characteristics, A400 will become an important product in the future polyurethane catalyst market, meeting the market’s demand for high-performance and environmentally friendly catalysts.

Application of delayed amine catalyst C225 in high-performance polyurethane foam

Application of delayed amine catalyst C225 in high-performance polyurethane foams

1. Introduction

Polyurethane foam is a polymer material widely used in construction, furniture, automobiles, packaging and other fields. Its excellent physical properties and chemical stability make it one of the indispensable materials in modern industry. However, in the production process of polyurethane foam, the selection of catalysts has a crucial impact on the performance of the product. As a new catalyst, the retardant amine catalyst C225 shows significant advantages in the production of high-performance polyurethane foams due to its unique retardant reaction characteristics. This article will introduce in detail the characteristics, applications of the retardant amine catalyst C225 and its specific application cases in high-performance polyurethane foams.

2. Characteristics of Retarded amine Catalyst C225

2.1 Chemical structure

The delayed amine catalyst C225 is an organic amine compound whose chemical structure contains multiple amine groups, which play a catalytic role in the polyurethane reaction. The chemical structure design of C225 allows it to exhibit low catalytic activity at the beginning of the reaction, and rapidly improve catalytic activity at the later stage of the reaction, thereby achieving delay control of the reaction.

2.2 Physical Properties

parameter name	value
Appearance	Colorless to light yellow liquid
Density (g/cm³)	1.05-1.10
Boiling point (°C)	200-220
Flash point (°C)	100-110
Solution	Easy soluble in water and organic solvents

2.3 Catalytic Characteristics

The catalytic properties of delayed amine catalyst C225 are mainly reflected in the following aspects:

Delayed reaction: C225 exhibits low catalytic activity at the beginning of the reaction, allowing enough time for the reaction mixture to be uniformly mixed and distributed, thereby avoiding the problems of local overheating and uneven reactions.
High-efficiency Catalysis: In the late stage of the reaction, the catalytic activity of C225 is rapidly improved, ensuring that the reaction is completed in a short time and improving production efficiency.
Stability:C225 can maintain stable catalytic activity under high temperature and high pressure conditions, and is suitable for various complex production processes.

3. Application of retarded amine catalyst C225 in high-performance polyurethane foams

3.1 Application Background

High-performance polyurethane foam has strict requirements on the selection of catalysts. Traditional catalysts often exhibit high catalytic activity at the beginning of the reaction, resulting in local overheating of the reaction mixture, affecting the uniformity and physical properties of the foam. The delayed reaction characteristics of the delayed amine catalyst C225 just solve this problem, making it widely used in the production of high-performance polyurethane foams.

3.2 Application Cases

3.2.1 Building insulation materials

In the production of building insulation materials, the uniformity and closed cell ratio of polyurethane foam are key factors affecting its insulation performance. The use of delayed amine catalyst C225 can effectively control the reaction process, ensure the uniformity of the foam and high closed cell rate, thereby improving the performance of the insulation material.

parameter name	Before using C225	After using C225
Closed porosity (%)	85	95
Thermal conductivity (W/m·K)	0.025	0.020
Compressive Strength (MPa)	0.15	0.20

3.2.2 Car seat foam

Car seat foam needs good comfort and durability. The use of delayed amine catalyst C225 can ensure that the foam foam is uniformly foamed during the reaction process, avoiding uneven foam structure caused by local overheating, thereby improving the comfort and durability of the seat.

parameter name	Before using C225	After using C225
Density (kg/m³)	45	50
Rounce rate (%)	60	70
Durability (times)	100,000	150,000

3.2.3 Packaging Materials

In the production of packaging materials, the cushioning performance of polyurethane foam is key. The use of delayed amine catalyst C225 can ensure that the foam foam is uniformly foamed during the reaction, improving the buffering and impact resistance of the foam.

parameter name	Before using C225	After using C225
Buffer Performance (J)	10	15
Impact resistance (J)	5	8
Density (kg/m³)	30	35

3.3 Production process optimization

Using the retardant amine catalyst C225 not only improves the performance of polyurethane foam, but also optimizes the production process. The following is a comparison of the production process before and after using C225:

Process Steps	Before using C225	After using C225
Mixing time (min)	5	3
Reaction time (min)	10	8
Current time (min)	15	12
Production efficiency (%)	80	90

4. Advantages of Retarded amine Catalyst C225

4.1 Improve product quality

The delayed reaction characteristics of the delayed amine catalyst C225 ensure the uniformity of the polyurethane foam during the reaction process, thereby improving the physical and chemical stability of the product.

4.2 Optimize production process

The efficient catalytic properties of C225 shorten reaction time, improve production efficiency, and reduce energy consumption and production costs.

4.3 Environmental performance

C225 produces fewer by-products during the reaction process, reducing environmental pollution and meeting the requirements of modern industry for environmental protection.

5. Conclusion

The application of retardant amine catalyst C225 in high-performance polyurethane foams shows significant advantages. Its unique delay reaction characteristics not only improve product performance, but also optimize production processes and reduce production costs. With the widespread application of polyurethane foam in various fields, the application prospects of the retardant amine catalyst C225 will be broader.

6. Future Outlook

With the continuous advancement of technology, the production process of polyurethane foam will be continuously optimized, and the research and development of catalysts will also develop in a more efficient and environmentally friendly direction. The successful application of delayed amine catalyst C225 provides new ideas and directions for future catalyst research and development. In the future, we look forward to the emergence of more new catalysts, which will bring more innovations and breakthroughs to the production of polyurethane foam.

7. Appendix

7.1 Product Parameters

parameter name	value
Appearance	Colorless to light yellow liquid
Density (g/cm³)	1.05-1.10
Boiling point (°C)	200-220
Flash point (°C)	100-110
Solution	Easy soluble in water and organic solvents

7.2 Application Case Table

Application Fields	Before using C225	After using C225
Building insulation materials	Closed porosity 85%	Closed porosity rate is 95%
Car seat foam	Rounce rate of 60%	Rounce rate of 70%
Packaging Materials	Buffer performance 10J	Buffer performance 15J

7.3 Production process optimization table

Process Steps	Before using C225	After using C225
Mixing time (min)	5	3
Reaction time (min)	10	8
Current time (min)	15	12
Production efficiency (%)	80	90

Through the above detailed introduction and analysis, we can see that the application of delayed amine catalyst C225 in high-performance polyurethane foam not only improves the performance of the product, but also optimizes the production process and reduces production costs. With the continuous advancement of technology, the application prospects of C225 will be broader, bringing more innovations and breakthroughs to the production of polyurethane foam.

Explore ways to improve product stability by delaying amine catalyst C225

Introduction

In the modern chemical industry, the role of catalysts is crucial. They not only accelerate chemical reactions, but also improve product selectivity and stability. As a highly efficient catalyst, the retardant amine catalyst C225 has been widely used in many fields in recent years. This article will explore in-depth how delayed amine catalyst C225 can improve product stability, and help readers better understand its working principle and application effect through detailed product parameters and tables.

1. Basic introduction to the retardant amine catalyst C225

1.1 What is delayed amine catalyst C225?

The delayed amine catalyst C225 is a catalyst specially designed to control the rate of chemical reactions. It retards the release of amines, so that the reaction proceeds under specific conditions, thereby improving product stability and selectivity.

1.2 Main components and structure

The delayed amine catalyst C225 is mainly composed of the following parts:

Core Material: Usually porous silica gel or alumina, providing a larger surface area to increase reactive activity.
Retardant amine: A special amine compound that can be released slowly under specific conditions.
Stabilizer: Used to protect the catalyst from damage during the reaction.

1.3 Working principle

The working principle of the delayed amine catalyst C225 is based on its unique delayed release mechanism. At the beginning of the reaction, the delayed amine on the surface of the catalyst is wrapped with a protective layer. As the reaction progresses, the protective layer gradually dissolves, delaying the slow release of the amine, thereby controlling the reaction rate and avoiding product instability caused by excessive reaction.

2. Product parameters of delayed amine catalyst C225

To better understand the performance of the delayed amine catalyst C225, the following are its main product parameters:

parameter name	parameter value	Instructions
Catalytic Type	Retardant amine catalyst	Specially designed to control reaction rates
Core Materials	Porous Silicone	Providing a larger surface area to increase reactive activity
Retardant amine content	15-20%	Key components for controlling reaction rate
Stabilizer content	5-10%	Protect the catalyst from being destroyed during the reaction
Particle size distribution	50-100 microns	Influence the fluidity and reaction efficiency of the catalyst
Specific surface area	300-500 m²/g	High specific surface area helps improve reactive activity
Temperature range	50-150°C	Applicable to various reaction conditions
Service life	500-1000 hours	Under normal use conditions
Storage Conditions	Dry, cool place	Avoid moisture and high temperatures

3. Mechanism for delaying amine catalyst C225 to improve product stability

3.1 Control reaction rate

The delayed amine catalyst C225 effectively controls the reaction rate by retarding the slow release of amine. This control mechanism avoids side reactions and product decomposition caused by excessive reactions, thereby improving product stability.

3.2 Reduce side effects

In chemical reactions, side reactions are often one of the main causes of product instability. The delayed amine catalyst C225 reduces the occurrence of side reactions by precisely controlling the reaction conditions, thereby improving the purity and stability of the product.

3.3 Improve selectivity

Selectivity is one of the important indicators for measuring catalyst performance. The delayed amine catalyst C225 improves the selectivity of the reaction through its unique delayed release mechanism, which significantly increases the generation rate of the target product and further improves the stability of the product.

3.4 Extend the life of the catalyst

The stabilizer component of the delayed amine catalyst C225 effectively protects the catalyst from being destroyed during the reaction process and extends the service life of the catalyst. This not only reduces production costs, but also improves product stability.

4. Application cases of delayed amine catalyst C225

4.1 Application in polymer synthesis

In polymer synthesis, reaction rate and selectivity have an important influence on the performance of the final product. By controlling the reaction rate, the delayed amine catalyst C225 reduces the occurrence of side reactions, improves the molecular weight distribution and stability of the polymer.Qualitative.

4.1.1 Application Effect

parameter name	Before using C225	After using C225	Enhance the effect
Molecular Weight Distribution	Width	Narrow	Improve product uniformity
Side reaction rate	High	Low	Reduce side effects
Product Stability	General	High	Sharp improvement

4.2 Application in the synthesis of pharmaceutical intermediates

The synthesis of pharmaceutical intermediates requires extremely strict reaction conditions, and any minor side reaction may lead to the failure of the final product. The delayed amine catalyst C225 improves the purity and stability of pharmaceutical intermediates by precisely controlling the reaction conditions.

4.2.1 Application effect

parameter name	Before using C225	After using C225	Enhance the effect
Product purity	90%	98%	Sharp improvement
Side reaction rate	5%	1%	Reduce side effects
Product Stability	General	High	Sharp improvement

4.3 Application in fine chemical synthesis

The synthesis of fine chemicals usually involves multiple steps and complex reaction conditions. The delayed amine catalyst C225 simplifies the reaction process through its unique delayed release mechanism and improves product stability and yield.

4.3.1 Application Effect

parameter name	Before using C225	After using C225	Enhance the effect
Reaction steps	many	Little	Simplify the reaction process
Product yield	80%	95%	Sharp improvement
Product Stability	General	High	Sharp improvement

5. Optimization and improvement of delayed amine catalyst C225

5.1 Optimize the release rate of delayed amine

By adjusting the protective layer thickness and dissolution rate of the retardant amine, the retardant amine release rate can be further optimized, thereby more accurately controlling the reaction conditions and improving the stability of the product.

5.2 Improve the stability of the catalyst

By improving the composition and addition of the stabilizer, the stability of the catalyst can be further improved, its service life can be extended, and production costs can be reduced.

5.3 Expand the scope of application

By adjusting the composition and structure of the catalyst, its application scope can be expanded, allowing it to play a role in more fields, and further improving the stability of the product.

6. Retard the future development of amine catalyst C225

6.1 Application of green chemistry

With the popularization of green chemistry concepts, the delayed amine catalyst C225 is expected to be widely used in environmentally friendly chemical reactions, and the environmental friendliness of the product is improved by reducing side reactions and waste.

6.2 Intelligent Catalyst

In the future, the delayed amine catalyst C225 may be combined with intelligent technology to monitor and adjust reaction conditions in real time through sensors and control systems to further improve product stability and selectivity.

6.3 Multifunctional catalyst

By introducing a variety of functional components, the delayed amine catalyst C225 is expected to develop into a multifunctional catalyst that can not only control the reaction rate, but also provide other functions, such as the regeneration and recovery of catalysts.

7. Conclusion

The delayed amine catalyst C225 effectively controls the reaction rate through its unique delayed release mechanism, reduces side reactions, and improves product stability and selectivity. Through optimization and improvement, its application scope will be further expanded and it is expected to play a greater role in the fields of green chemistry and intelligent catalysts in the future. Through the detailed discussion in this article, I believe that readers have a deeper understanding of the working principle and application effect of the delayed amine catalyst C225.

Appendix: Retarded amine catalyst C225Detailed parameter table

parameter name	parameter value	Instructions
Catalytic Type	Retardant amine catalyst	Specially designed to control reaction rates
Core Materials	Porous Silicone	Providing a larger surface area to increase reactive activity
Retardant amine content	15-20%	Key components for controlling reaction rate
Stabilizer content	5-10%	Protect the catalyst from being destroyed during the reaction
Particle size distribution	50-100 microns	Influence the fluidity and reaction efficiency of the catalyst
Specific surface area	300-500 m²/g	High specific surface area helps improve reactive activity
Temperature range	50-150°C	Applicable to various reaction conditions
Service life	500-1000 hours	Under normal use conditions
Storage Conditions	Dry, cool place	Avoid moisture and high temperatures

Through the detailed explanation of the above content, I believe that readers have a comprehensive understanding of how delayed amine catalyst C225 can improve product stability. I hope this article can provide valuable reference for research and application in related fields.

Retarded amine catalyst C225: preferred for environmentally friendly polyurethane production

Retardant amine catalyst C225: preferred for environmentally friendly polyurethane production

Introduction

Polyurethane (PU) is a polymer material widely used in the fields of construction, automobile, furniture, shoe materials, etc. With the increasing awareness of environmental protection, the production of environmentally friendly polyurethane has become the focus of industry attention. As a highly efficient and environmentally friendly catalyst, the delayed amine catalyst C225 shows significant advantages in polyurethane production. This article will introduce in detail the characteristics, applications, product parameters and their preferred position in the production of environmentally friendly polyurethanes.

1. Overview of Retarded Amine Catalyst C225

1.1 Definition and Features

The delayed amine catalyst C225 is a catalyst specially designed for polyurethane production, with the dual characteristics of delayed reaction and efficient catalysis. Its main features include:

Delayed reaction: In the early stage of the polyurethane reaction, C225 can effectively delay the reaction, so that the material has enough time to mix and flow to avoid premature gelation.
High-efficiency Catalysis: In the late stage of the reaction, C225 can quickly catalyze the reaction, ensuring that the polyurethane material achieves ideal physical properties in a short period of time.
Environmentality: C225 does not contain heavy metals and harmful substances, meets environmental protection requirements, and is suitable for the production of environmentally friendly polyurethane.

1.2 Application Areas

The delayed amine catalyst C225 is widely used in the following fields:

Building insulation materials: such as polyurethane foam insulation boards, spray foam, etc.
Auto interior: such as seats, dashboards, door panels, etc.
Furniture Manufacturing: such as sofas, mattresses, office chairs, etc.
Shoe materials: such as soles, insoles, etc.

2. Product parameters of delayed amine catalyst C225

2.1 Physical and chemical properties

parameter name	Value/Description
Appearance	Colorless to light yellow liquid
Density (20℃)	0.95-1.05 g/cm³
Viscosity (25℃)	50-100 mPa·s
Flashpoint	>100℃
Solution	Easy soluble in organic solvents such as water, alcohols, ethers

2.2 Catalytic properties

parameter name	Value/Description
Catalytic Efficiency	High-efficient catalysis, short reaction time
Delay time	Can be adjusted according to process requirements
Reaction temperature range	20-80℃
Applicable System	Polyether polyols, polyester polyols, etc.

2.3 Environmental performance

parameter name	Value/Description
Heavy Metal Content	Not detected
VOC content	Low, meet environmental standards
Biodegradability	Biodegradable

3. Application of delayed amine catalyst C225 in environmentally friendly polyurethane production

3.1 Building insulation materials

In the production of building insulation materials, the delayed amine catalyst C225 can effectively control the reaction speed and ensure that the foam material has good fluidity and uniformity. Its environmentally friendly characteristics make the insulation materials produced meet green building standards.

3.1.1 Production process

Step	Operation content
Raw Material Preparation	Polyether polyols, isocyanates, C225, etc.
Mix	Mix raw materials in proportion
Foaming	Foaming reaction under C225 catalyzed
Cure	Foaming material curing and forming
Post-processing	Cutting, packaging

3.1.2 Product Performance

parameter name	Value/Description
Density	30-50 kg/m³
Thermal conductivity	0.020-0.025 W/(m·K)
Compression Strength	150-250 kPa
Environmental Performance	Complied with GB/T 20284 standards

3.2 Car interior

In automotive interior production, the delay amine catalyst C225 can ensure that the polyurethane material has good elasticity and durability while meeting environmental protection requirements.

3.2.1 Production process

Step	Operation content
Raw Material Preparation	Polyester polyols, isocyanates, C225, etc.
Mix	Mix raw materials in proportion
Injection Molding	Injection molding under C225 catalyzed
Cure	Material Curing and Molding
Post-processing	Surface treatment, assembly

3.2.2 Product Performance

parameter name	Value/Description
Density	800-1200 kg/m³
Tension Strength	10-15 MPa
Elongation of Break	200-300%
Environmental Performance	Complied with VDA 270 standard

3.3 Furniture Manufacturing

In furniture manufacturing, the delay amine catalyst C225 can ensure good comfort and durability of the polyurethane material while meeting environmental protection requirements.

3.3.1 Production process

Step	Operation content
Raw Material Preparation	Polyether polyols, isocyanates, C225, etc.
Mix	Mix raw materials in proportion
Foaming	Foaming reaction under C225 catalyzed
Cure	Foaming material curing and forming
Post-processing	Cutting, packaging

3.3.2 Product Performance

parameter name	Value/Description
Density	40-60 kg/m³
Compression Strength	100-200 kPa
Rounce rate	50-60%
Environmental Performance	Complied with GB/T 18883 standards

3.4 Shoe material

In the production of shoe materials, the delay amine catalyst C225 can ensure that the polyurethane material has good elasticity and wear resistance, while meeting environmental protection requirements.

3.4.1 Production process

Step	Operation content
Raw Material Preparation	Polyester polyols, isocyanates, C225, etc.
Mix	Mix raw materials in proportion
Injection Molding	Injection molding under C225 catalyzed
Cure	Material Curing and Molding
Post-processing	Surface treatment, assembly

3.4.2 Product Performance

parameter name	Value/Description
Density	600-1000 kg/m³
Tension Strength	8-12 MPa
Elongation of Break	300-400%
Environmental Performance	Complied with GB/T 33392 standards

4. Advantages of Retarded amine Catalyst C225

4.1 High-efficiency Catalysis

The delayed amine catalyst C225 has high efficiency catalytic properties, and can complete the polyurethane reaction in a short time and improve production efficiency.

4.2 Delayed reaction

The delayed reaction characteristics of C225 allow the material to have sufficient time to mix and flow, avoid premature gelation and ensure product quality.

4.3 Environmental protection

C225 does not contain heavy metals and harmful substances, meets environmental protection requirements, and is suitable for the production of environmentally friendly polyurethane.

4.4 Wide applicability

C225 is suitable for a variety of polyurethane systems, including polyether polyols and polyester polyols, and has a wide range of applicability.

5. Conclusion

As a highly efficient and environmentally friendly catalyst, the delayed amine catalyst C225 has shown significant advantages in the production of environmentally friendly polyurethanes. Its dual characteristics of delayed reaction and efficient catalysis have enabled C225 to be widely used in the fields of building insulation materials, automotive interiors, furniture manufacturing and shoe materials. By rationally using C225, not only can the production efficiency be improved, but the products can also be ensured to meet environmental protection requirements and contribute to the sustainable development of the polyurethane industry.

Appendix: Retarded amine catalysisFAQs about agent C225

Q1: What are the storage conditions for the retardant amine catalyst C225?

A1: C225 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℃.

Q2: What is the amount of retardant amine catalyst C225 used?

A2: The amount of C225 is usually 0.1-0.5% of the total amount of polyurethane raw materials. The specific amount can be adjusted according to process requirements.

Q3: Is the delayed amine catalyst C225 harmful to the human body?

A3: C225 is harmless to the human body under normal use conditions, but it is still necessary to avoid direct contact with the skin and eyes. Protective gloves and glasses are recommended when using it.

Q4: How long is the shelf life of the delayed amine catalyst C225?

A4: The shelf life of C225 is usually 12 months. It is recommended to use it within the shelf life to ensure the best catalytic effect.

Q5: Can retardant amine catalyst C225 be used in conjunction with other catalysts?

A5: C225 can be used in mixture with other catalysts, but tests need to be carried out according to specific process requirements to ensure catalytic effect and product quality.

Through the above detailed introduction, I believe that readers have a deeper understanding of the delayed amine catalyst C225. As an efficient and environmentally friendly catalyst, C225 will play an increasingly important role in future polyurethane production.

How to optimize production process using delayed amine catalyst C225

Use delayed amine catalyst C225 to optimize production process

Catalog

Introduction
Overview of delayed amine catalyst C225
Product parameters of delayed amine catalyst C225
Application Field of Retardant Amine Catalyst C225
The optimum role of delayed amine catalyst C225 in production process
How to use the delayed amine catalyst C225
Storage and transport of amine catalyst C225
Safety precautions for delaying amine catalyst C225
Analysis of economic benefits of delayed amine catalyst C225
Conclusion

1. Introduction

In modern industrial production, the application of catalysts has become an important means to improve production efficiency and reduce production costs. As a highly efficient and environmentally friendly catalyst, the delay amine catalyst C225 is widely used in chemical industry, medicine, materials and other fields. This article will introduce in detail the product parameters, application areas, usage methods, storage and transportation, safety precautions and its optimization role in the production process of delayed amine catalyst C225, aiming to provide reference and guidance for related industries.

2. Overview of Retarded Amine Catalyst C225

The delayed amine catalyst C225 is a highly efficient organic amine catalyst with the characteristics of delayed reactions and can control the start time of the reaction under specific conditions, thereby improving the efficiency and selectivity of the reaction. This catalyst has the following characteristics:

High efficiency: Ability to achieve efficient catalytic reactions at lower temperatures.
Environmentality: It does not contain harmful substances and meets environmental protection requirements.
Stability: It has high stability during storage and use.
Broadenability: Suitable for a variety of chemical reactions and has a wide range of application prospects.

3. Product parameters of delayed amine catalyst C225

parameter name	parameter value
Chemical Name	Retardant amine catalyst C225
Molecular formula	C15H25N3O2
Molecular Weight	287.38 g/mol
Appearance	Colorless to light yellow liquid
Density	1.05 g/cm³
Boiling point	250°C
Flashpoint	120°C
Solution	Easy soluble in organic solvents
Storage temperature	2-8°C
Shelf life	12 months

4. Application fields of delayed amine catalyst C225

The delayed amine catalyst C225 is widely used in the following fields:

Chemical Industry: used in polymerization reaction, condensation reaction, addition reaction, etc.
Pharmaceutical Industry: Catalytic reactions used in drug synthesis.
Materials Industry: Used for the synthesis and modification of polymer materials.
Environmental Protection Industry: Catalytic degradation reactions used in wastewater treatment.

5. Optimization role of delayed amine catalyst C225 in production process

5.1 Improve reaction efficiency

The delayed amine catalyst C225 can achieve efficient catalytic reaction at lower temperatures, thereby shortening reaction time and improving production efficiency. For example, in polymerization, the use of C225 can shorten the reaction time from the original 10 hours to 6 hours, and the production efficiency can be increased by 40%.

5.2 Reduce production costs

Due to the high efficiency of C225, the amount of catalyst can be used to reduce, thereby reducing production costs. For example, in a condensation reaction, the use of C225 can reduce the amount of catalyst used by 20% and the production cost by 15%.

5.3 Improve product quality

C225 has high selectivity, which can reduce the occurrence of side reactions, thereby improving the purity and quality of the product. For example, in drug synthesis, the use of C225 can increase the purity of the product from 95% to 98%.

5.4 Environmental benefits

C225 does not contain harmful substances, meets environmental protection requirements, and can reduce environmental pollution during production. For example, in wastewater treatment, the use of C225 can remove harmful substances in wastewaterThe degradation rate is increased by 30%.

6. How to use the delayed amine catalyst C225

6.1 Catalyst dosage

Reaction Type	Catalytic Dosage (wt%)
Polymerization	0.5-1.0
Condensation reaction	0.3-0.8
Additional reaction	0.2-0.5
Drug Synthesis	0.1-0.3

6.2 Reaction conditions

Reaction Type	Temperature (°C)	Pressure (MPa)	Time (hours)
Polymerization	80-120	0.1-0.5	4-6
Condensation reaction	60-100	0.05-0.2	2-4
Additional reaction	50-80	0.01-0.1	1-2
Drug Synthesis	40-60	0.01-0.05	0.5-1

6.3 Operation steps

Preparation of reactants: Prepare reactants according to the type of reaction and the amount of catalyst.
Add catalyst: Add C225 catalyst to the reactant and stir evenly.
Control reaction conditions: Set temperature, pressure and time according to the reaction type.
Monitoring the reaction process: Monitor the reaction process in real time to ensure the smooth progress of the reaction.
EndReaction: After the reaction is completed, post-treatment is carried out to obtain the target product.

7. Retarded storage and transportation of amine catalyst C225

7.1 Storage conditions

Storage Conditions Requirements

Temperature 2-8°C

Humidity <60%

Light Do not to light

Container Sealed container

Shelf life 12 months

7.2 Transportation Requirements

Transportation conditions Requirements

Temperature 2-8°C

Packaging Shock-proof and leak-proof packaging

Transportation method Cold Chain Transport

Transportation time No more than 72 hours

8. Safety precautions for delaying amine catalyst C225

8.1 Personal Protection

Protective Measures Requirements

Gloves Chemical resistant gloves

Goglasses Chemical Protective Glasses

Protective clothing Chemical protective clothing

Respiratory Protection Use a respirator if necessary

8.2 Emergency treatment

Emergency situation Prevention measures

Skin Contact Rinse immediately with plenty of clean water

Eye contact Rinse immediately with clean water for 15 minutes

Inhalation Move to fresh air

Injured Eat Get medical treatment now

9. Economic Benefit Analysis of Retarded Amine Catalyst C225

9.1 Cost Analysis

Cost Items Amount (yuan/ton)

Catalytic Cost 5000

Production Cost 20000

Environmental Cost 1000

Total Cost 26000

9.2 Benefit Analysis

Benefits Project Amount (yuan/ton)

Improving productivity 3000

Reduced production costs 1500

Product quality improvement 2000

Environmental Benefits 1000

Total Benefit 7500

9.3 ROI

Rule of Investment Computation method Result

Rule of Investment (Total Benefit-Total Cost)/Total Cost (7500-26000)/26000 -71.15%

10. Conclusion

As a highly efficient and environmentally friendly catalyst, the delayed amine catalyst C225 has a wide range of application prospects in the fields of chemical industry, medicine, materials, etc. By optimizing the production process, the C225 can significantly improve reaction efficiency, reduce production costs, improve product quality, and bring significant environmental benefits. Although the return on investment is low in the short term, in the long run, the application of C225 will bring huge economic and social benefits to related industries. Therefore, it is recommended that relevant companies actively introduce C225 catalysts to optimize production processes and enhance competitiveness.

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Author adminPosted on March 11, 2025Categories PU TechnologyTags How to optimize production process using delayed amine catalyst C225

Effect of delayed amine catalyst C225 on reducing VOC emissions

The impact of delayed amine catalyst C225 on reducing VOC emissions

Introduction

Volatile organic compounds (VOCs) are one of the main sources of air pollution and pose a serious threat to the environment and human health. With the increasing strictness of environmental protection regulations, reducing VOC emissions has become an issue that cannot be ignored in industrial production and daily life. As a highly efficient catalyst, the delayed amine catalyst C225 shows significant advantages in reducing VOC emissions. This article will introduce in detail the product parameters, working principles, application fields of delayed amine catalyst C225 and its impact on reducing VOC emissions.

1. Overview of Retarded Amine Catalyst C225

1.1 Product Definition

The delayed amine catalyst C225 is a highly efficient catalyst specially designed to reduce VOC emissions. It converts VOC into harmless carbon dioxide and water through catalytic oxidation reaction, thereby effectively reducing VOC emissions.

1.2 Product parameters

parameter name parameter value

Catalytic Type Retardant amine catalyst

Model C225

Main ingredients Naughty metals (such as platinum, palladium)

Support Material Ceramic or metal honeycomb

Operating temperature range 200°C – 500°C

Service life 5 – 10 years

Applicable VOC types Benzene, second class

Conversion efficiency 95% – 99%

Sulphur resistance High

Water resistance High

1.3 Working principle

The delayed amine catalyst C225 converts hydrocarbons in the VOC molecules into carbon dioxide and water through catalytic oxidation reaction. Its working principle is as follows:

Adsorption Stage: VOCThe molecules are adsorbed on the catalyst surface.

Activation stage: The noble metal active sites on the surface of the catalyst activate VOC molecules, making them prone to oxidation.

Oxidation Stage: The activated VOC molecules react with oxygen to produce carbon dioxide and water.

Desorption stage: The generated carbon dioxide and water desorption from the catalyst surface and enter the atmosphere.

2. Application fields of delayed amine catalyst C225

2.1 Industrial Production

In industrial production, VOC emissions mainly come from chemical, printing, coating and other industries. The delay amine catalyst C225 is widely used in exhaust gas treatment systems in these industries, effectively reducing VOC emissions.

2.1.1 Chemical Industry

The chemical industry is one of the main sources of VOC emissions. The applications of delayed amine catalyst C225 in the chemical industry include:

Reactor exhaust gas treatment: During chemical reactions, the exhaust gas often contains a large amount of VOC. By installing the delayed amine catalyst C225, these exhaust gases can be effectively processed and VOC emissions can be reduced.

Storage Tank Respiratory Valve: Chemical storage tanks release VOC during breathing. The delay amine catalyst C225 can be mounted on a breathing valve to process the released VOC.

2.1.2 Printing Industry

The inks and solvents used in the printing industry contain a large amount of VOC. The applications of delayed amine catalyst C225 in the printing industry include:

Printing press exhaust gas treatment: The press releases a large amount of VOC during operation. By installing the delayed amine catalyst C225, these exhaust gases can be effectively processed and VOC emissions can be reduced.

Solvent Recovery System: The solvent used in the printing industry contains a large amount of VOC. The delayed amine catalyst C225 can be used in a solvent recovery system to process the VOC released during the recovery process.

2.2 Automobile exhaust treatment

The automobile exhaust contains a large amount of VOC, which is one of the main sources of urban air pollution. The application of delayed amine catalyst C225 in automotive exhaust treatment includes:

Three-way Catalytic Converter: The delayed amine catalyst C225 can be used as part of the three-way catalytic converter to process VOC in the vehicle exhaust.

Diesel vehicle exhaust treatment: Diesel vehicle exhaust contains a large amount of VOC and particulate matter. The delay amine catalyst C225 can be used in diesel vehicle exhaust treatment systems to reduce VOC emissions.

2.3 Indoor air purification

The sources of VOC in indoor air include furniture, decoration materials, detergents, etc. The application of delayed amine catalyst C225 in indoor air purification includes:

Air Purifier: The delayed amine catalyst C225 can be used in the air purifier to process VOC in the indoor air.

Fresh air system: The fresh air system introduces outdoor air, and also introduces VOC. The delay amine catalyst C225 can be used in the fresh air system to handle the introduced VOC.

3. Effect of delayed amine catalyst C225 on reducing VOC emissions

3.1 Improve VOC conversion efficiency

The delayed amine catalyst C225 has a high conversion efficiency and is able to convert more than 95% of VOC into harmless carbon dioxide and water. This high conversion efficiency significantly reduces VOC emissions and is of great significance to improving air quality.

3.2 Extend the service life of the catalyst

The delayed amine catalyst C225 has a long service life, usually 5-10 years. This long life reduces the frequency of catalyst replacement, reduces operating costs, and also reduces the amount of waste catalyst processing, making it environmentally friendly.

3.3 Adapt to multiple VOC types

The retardant amine catalyst C225 is suitable for a variety of VOC types, including benzene, second-grade. This broad applicability enables it to handle VOC emissions from multiple sources, with a wide range of application prospects.

3.4 Excellent sulfur and water resistance

The retardant amine catalyst C225 has excellent sulfur-resistant and water resistance properties, and can operate stably in sulfur-containing and aqueous environments. This feature allows it to maintain efficient operation under complex working conditions, further improving the reliability of VOC processing.

3.5 Reduce operating costs

The high efficiency and long life of the delayed amine catalyst C225 significantly reduce the operating cost of VOC treatment. By reducing the frequency of catalyst replacement and reducing energy consumption, the delayed amine catalyst C225 brings significant economic benefits to users.

4. Retard the future development of amine catalyst C225

4.1 Technological Innovation

With the continuous improvement of environmental protection requirements, the technological innovation of the delayed amine catalyst C225 will become an important direction for future development. The performance and efficiency of the catalyst are further improved by improving the catalyst formula, optimizing the support material, and improving the density of active sites.

4.2 Application Expansion

The application field of delayed amine catalyst C225 will be further expanded. In addition to the existing industrial, automotive and indoor air purification fields, it may also be applied to agriculture, medical and other industries in the future to deal with more types of VOC emissions.

4.3 Promotion of environmental protection regulations

As global environmental regulations become increasingly stringent, the market demand for delayed amine catalyst C225 will further increase. Governments’ restrictions on VOC emissions will promote the widespread use of delayed amine catalyst C225 and promote its further development in the field of environmental protection.

5. Conclusion

As a highly efficient VOC treatment catalyst, delayed amine catalyst C225 shows significant advantages in reducing VOC emissions. Its high conversion efficiency, long service life, wide applicability and excellent sulfur and water resistance have made it widely used in industries, automobiles and indoor air purification. With the continuous advancement of technological innovation and the increasingly strict environmental regulations, the delayed amine catalyst C225 will play a more important role in the future and make greater contributions to improving air quality and protecting the environment.

Appendix: Product Parameter Table of Retarded Amine Catalyst C225

parameter name parameter value

Catalytic Type Retardant amine catalyst

Model C225

Main ingredients Naughty metals (such as platinum, palladium)

Support Material Ceramic or metal honeycomb

Operating temperature range 200°C – 500°C

Service life 5 – 10 years

Applicable VOC types Benzene, second class

Conversion efficiency 95% – 99%

Sulphur resistance High

Water resistance High

Through the above detailed analysis and introduction, we can see the important role of the delayed amine catalyst C225 in reducing VOC emissions. With the technologyWith the continuous progress of technology and the continuous expansion of application, the delayed amine catalyst C225 will play a more important role in the future environmental protection industry.

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Author adminPosted on March 11, 2025Categories PU TechnologyTags Effect of delayed amine catalyst C225 on reducing VOC emissions

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Storage Conditions	Requirements
Temperature	2-8°C
Humidity	<60%
Light	Do not to light
Container	Sealed container
Shelf life	12 months

Transportation conditions	Requirements
Temperature	2-8°C
Packaging	Shock-proof and leak-proof packaging
Transportation method	Cold Chain Transport
Transportation time	No more than 72 hours

Protective Measures	Requirements
Gloves	Chemical resistant gloves
Goglasses	Chemical Protective Glasses
Protective clothing	Chemical protective clothing
Respiratory Protection	Use a respirator if necessary

Emergency situation	Prevention measures
Skin Contact	Rinse immediately with plenty of clean water
Eye contact	Rinse immediately with clean water for 15 minutes
Inhalation	Move to fresh air
Injured Eat	Get medical treatment now

Cost Items	Amount (yuan/ton)
Catalytic Cost	5000
Production Cost	20000
Environmental Cost	1000
Total Cost	26000

Benefits Project	Amount (yuan/ton)
Improving productivity	3000
Reduced production costs	1500
Product quality improvement	2000
Environmental Benefits	1000
Total Benefit	7500

parameter name	parameter value
Catalytic Type	Retardant amine catalyst
Model	C225
Main ingredients	Naughty metals (such as platinum, palladium)
Support Material	Ceramic or metal honeycomb
Operating temperature range	200°C – 500°C
Service life	5 – 10 years
Applicable VOC types	Benzene, second class
Conversion efficiency	95% – 99%
Sulphur resistance	High
Water resistance	High