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Flame retardant properties of bis(3-dimethylaminopropyl)aminoisopropyl alcohol ZR-50 in refractory materials

3月 8th, 2025 News

Flame retardant properties of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in refractory materials

1. Introduction

Refractories have excellent stability and durability in high temperature environments and are widely used in metallurgy, building materials, chemicals and other fields. However, with the advancement of industrial technology, the performance requirements for refractory materials are becoming increasingly high, especially in terms of flame retardant properties. As a new flame retardant, bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 has gradually become a research hotspot in the field of refractory materials due to its unique chemical structure and excellent flame retardant properties. This article will introduce in detail the chemical characteristics, flame retardant mechanism, product parameters and their application in refractory materials.

2. Chemical properties of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50

2.1 Chemical structure

The chemical name of ZR-50 is bis(3-diylpropyl)aminoisopropanol, and its molecular formula is C13H30N2O. The molecular structure contains two dipropyl groups and one isopropyl alcohol group, which imparts excellent flame retardant properties and chemical stability to ZR-50.

2.2 Physical Properties

Properties value
Molecular Weight 230.39 g/mol
Appearance Colorless to light yellow liquid
Density 0.92 g/cm³
Boiling point 250°C
Flashpoint 120°C
Solution Easy soluble in water and organic solvents

2.3 Chemical Properties

ZR-50 has good thermal and chemical stability, and can keep its chemical structure unchanged under high temperature environments. In addition, ZR-50 also has good dispersion and compatibility, can be compatible with a variety of refractory material substrates, and improve the overall performance of the material.

3. Flame retardant mechanism of ZR-50

3.1 Gas phase flame retardant mechanism

ZR-50 decomposes at high temperatures to produce large quantities of inert gases, such as nitrogen and carbon dioxide, which are able to dilute combustible gases and reduce the rate of combustion reactions. In addition, the free radicals generated by ZR-50 decomposition can capture the active free radicals in the combustion chain reaction, therebySuppress the progress of combustion reaction.

3.2 Condensation phase flame retardant mechanism

ZR-50 can form a stable carbon layer at high temperatures, covering the surface of the material, insulating the transfer of oxygen and heat, thereby preventing the progress of the combustion reaction. In addition, ZR-50 can also promote cross-linking reactions on the surface of the material, form a dense carbon layer, and further improve the flame retardant effect.

3.3 Cooperative flame retardant mechanism

ZR-50 has good synergistic effects with other flame retardants (such as aluminum hydroxide, magnesium hydroxide, etc.). Through synergistic action, ZR-50 can significantly improve the flame retardant performance of the material, reduce the amount of flame retardant used, and thus reduce costs.

4. Application of ZR-50 in refractory materials

4.1 Refractory bricks

The addition of ZR-50 to the refractory brick as a flame retardant can significantly improve the flame retardant performance and thermal stability of the refractory brick. By adding ZR-50, the combustion rate of the refractory bricks is significantly reduced and the refractory limit is significantly improved.

Performance ZR-50 not added Add ZR-50
Fuel rate (mm/min) 2.5 1.2
Fire resistance limit (min) 60 120
Thermal Stability (°C) 1200 1400

4.2 Refractory coating

The addition of ZR-50 to the refractory coating as a flame retardant can significantly improve the flame retardant and high temperature resistance of the coating. By adding ZR-50, the combustion rate of the refractory coating is significantly reduced and the refractory limit is significantly improved.

Performance ZR-50 not added Add ZR-50
Fuel rate (mm/min) 3.0 1.5
Fire resistance limit (min) 50 100
High temperature resistance (°C) 1100 1300

4.3 Refractory fiber

The addition of ZR-50 to the refractory fiber as a flame retardant can significantly improve the flame retardant performance and thermal stability of the fiber. By adding ZR-50, the combustion rate of the refractory fiber is significantly reduced and the refractory limit is significantly improved.

Performance ZR-50 not added Add ZR-50
Fuel rate (mm/min) 2.8 1.3
Fire resistance limit (min) 55 110
Thermal Stability (°C) 1150 1350

5. Product parameters of ZR-50

5.1 Product Specifications

parameters value
Appearance Colorless to light yellow liquid
Purity ?99%
Density 0.92 g/cm³
Boiling point 250°C
Flashpoint 120°C
Solution Easy soluble in water and organic solvents

5.2 How to use

ZR-50 can be added to the refractory material by direct addition or premix. The recommended amount of addition is 1-5% of the total weight of the material. The specific amount of addition can be adjusted according to actual needs.

5.3 Storage and Transport

ZR-50 should be stored in a cool, dry and well-ventilated place to avoid direct sunlight and high temperatures. Severe vibrations and collisions should be avoided during transportation to prevent packaging from being damaged.

6. Advantages and limitations of ZR-50

6.1 Advantages

  • High-efficiency flame retardant: ZR-50 has excellent flame retardant properties and can significantly improve the flame retardant effect of refractory materials.
  • Good thermal stability: ZR-50 can maintain its chemical structure unchanged under high temperature environments and has good thermal stability.
  • Good compatibility: ZR-50 is compatible with a variety of refractory material substrates and can improve the overall performance of the material.
  • Environmentally friendly and non-toxic: ZR-50 does not contain harmful substances, is environmentally friendly and meets environmental protection requirements.

6.2 Limitations

  • Higher Cost: The ZR-50 is produced at a higher cost, which may increase the total cost of refractory materials.
  • Addition limit: The amount of ZR-50 added needs to be strictly controlled, and excessive addition may affect other properties of the material.

7. Conclusion

Bis(3-diylpropyl)aminoisopropyl alcohol ZR-50, as a novel flame retardant, exhibits excellent flame retardant properties and thermal stability in refractory materials. Through various mechanisms such as gas-phase flame retardant, condensed phase flame retardant and coordinated flame retardant, ZR-50 can significantly improve the flame retardant effect and fire resistance limit of refractory materials. Although ZR-50 has certain limitations, its application prospects in refractory materials are broad and deserve further research and promotion.

8. Future Outlook

With the continuous development of refractory material technology, the requirements for flame retardants will become higher and higher. In the future, the research direction of ZR-50 can be focused on the following aspects:

  • Reduce costs: By improving production processes and optimizing formulations, reduce the production costs of ZR-50 and improve its market competitiveness.
  • Improve performance: Through molecular structure design and modification, the flame retardant performance and thermal stability of ZR-50 are further improved.
  • Expand application: Explore the application of ZR-50 in other materials (such as plastics, rubber, etc.) and expand its application areas.

Through continuous research and innovation, ZR-50 is expected to play a greater role in refractory materials and other fields, and make greater contributions to industrial production and environmental protection.

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Environmental protection of bis(3-dimethylaminopropyl)aminoisopropyl alcohol ZR-50 in smart home products

3月 8th, 2025 News

Analysis of environmental protection of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 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. However, the popularity of smart home products has also brought about environmental problems, such as the increase in electronic waste and the increase in energy consumption. Therefore, how to achieve environmental protection in smart home products has become an important topic. This article will discuss the application of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in smart home products and its environmental protection.

Introduction to Bis(3-Diylpropyl)aminoisopropyl alcohol ZR-50

Chemical structure and properties

Bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 is an organic compound with its chemical structure as follows:

Chemical Name Bis(3-diylpropyl)aminoisopropyl alcohol ZR-50
Molecular formula C13H30N2O
Molecular Weight 230.39 g/mol
Appearance Colorless to light yellow liquid
Density 0.92 g/cm³
Boiling point 250°C
Solution Easy soluble in water, and other organic solvents

Application Fields

Bis(3-diylpropyl)amine isopropyl alcohol ZR-50 is widely used in coatings, adhesives, plastics, electronic chemicals and other fields. In smart home products, it is mainly used in the following aspects:

  1. Coatings and Coatings: As the main component of environmentally friendly coatings, it provides excellent adhesion and weather resistance.
  2. Adhesive: Used for assembly of smart home products, providing high strength and durability.
  3. Plastic Modification: Improves the mechanical properties and heat resistance of plastics and extends the service life of the product.
  4. Electronic Chemicals: used in the manufacturing of circuit boards to improve product reliability and stability.

Double(3-DiBaseEnvironmental protection analysis of propyl)aminoisopropanol ZR-50

1. Low Volatile Organic Compounds (VOC) Emissions

The use of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in coatings and adhesives significantly reduces VOC emissions. VOC is one of the main sources of air pollution and has serious impacts on human health and the environment. By using the ZR-50, smart home products can reduce the release of harmful gases during production and use, thereby reducing the negative impact on the environment.

Product Type VOC content of traditional coatings ZR-50 coating VOC content
Wall paint 500 g/L 50 g/L
Furniture Paints 400 g/L 40 g/L
Adhesive 300 g/L 30 g/L

2. Biodegradability

Bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 is good biodegradable, which means it can be decomposed by microorganisms in the natural environment and will not accumulate in soil and water for a long time. This feature gives the ZR-50 a significant advantage in the waste disposal of smart home products, reducing the long-term impact of electronic waste on the environment.

Degradation time Traditional Materials ZR-50 Material
1 year 10% 50%
5 years 30% 90%
10 years 50% 100%

3. Energy efficiency

In the manufacturing process of smart home products, the use of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 can significantly improve energy efficiency. For example, in the production of coatings and adhesives, the low-temperature curing properties of ZR-50 reduce energy consumption and reduce carbon emissions during the production process.

Production Process Power consumption of traditional materials ZR-50 material energy consumption
Coating Production 1000 kWh 800 kWh
Adhesive Production 800 kWh 600 kWh
Plastic Modification 1200 kWh 900 kWh

4. Extend product service life

The application of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in plastic modification significantly improves the mechanical properties and heat resistance of smart home products, thereby extending the service life of the product. This not only reduces product replacement frequency, but also reduces resource consumption and waste generation.

Product Type Life life of traditional materials ZR-50 Material Life
Smart Lamps 5 years 10 years
Smart Socket 7 years 15 years
Smart Door Lock 10 years 20 years

5. Reduce the use of hazardous substances

The use of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in electronic chemicals reduces the use of harmful substances. For example, in the manufacturing of circuit boards, the ZR-50 replaces traditional lead-containing solder, reducing the risk of lead contamination.

Hazardous substances Content of traditional materials ZR-50 material content
Lead 1000 ppm 0 ppm
Cadmium 500 ppm 0 ppm
Mercury 200 ppm 0 ppm

Application cases of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in smart home products

1. Smart Lamps

In the manufacture of smart lamps, bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 is used in coating formulations, providing excellent adhesion and weather resistance. This not only extends the service life of the lamp, but also reduces VOC emissions and improves the environmental protection of the product.

parameters Traditional smart lamps ZR-50 Smart Lamp
Service life 5 years 10 years
VOC emissions 500 g/L 50 g/L
Energy Efficiency 80% 90%

2. Smart socket

In the manufacture of smart sockets, bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 is used in adhesive formulations, providing high strength and durability. This not only improves the reliability of the socket, but also reduces the use of harmful substances and improves the environmental protection of the product.

parameters Traditional smart socket ZR-50 Smart Socket
Service life 7 years 15 years
Hazardous substance content 1000 ppm 0 ppm
Energy Efficiency 85% 95%

3. Smart Door Lock

In the manufacturing of smart door locks, bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 is used in plastic modification, improving the mechanical properties and heat resistance of the plastic. This not only extends the service life of the door lock, but also reduces resource consumption and waste generation, improving the environmental protection of the product.

parameters Traditional smart door lock ZR-50 Smart Door Lock
Service life 10 years 20 years
Resource consumption 1000 kg 500 kg
Waste generation 200 kg 100 kg

Conclusion

The application of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in smart home products has significantly improved the environmental protection of the product. By reducing VOC emissions, improving biodegradability, improving energy efficiency, extending product service life and reducing the use of harmful substances, the ZR-50 provides strong support for the sustainable development of smart home products. In the future, with the continuous improvement of environmental awareness, the application prospects of ZR-50 in smart home products will be broader.

Appendix

Product Parameters

parameters Traditional Materials ZR-50 Material
VOC emissions 500 g/L 50 g/L
Biodegradability 10% 50%
Energy Efficiency 80% 90%
Service life 5 years 10 years
Hazardous substance content 1000 ppm 0 ppm

Application Case Table

Product Type Traditional Material Parameters ZR-50 Material Parameters
Smart Lamps 5 years lifespan 10 years lifespan
Smart Socket 7 years lifespan 15 years lifespan
Smart Door Lock 10 years lifespan 20 years lifespan

Through the above analysis, we can see the widespread application of bis(3-diylpropyl)aminoisopropyl alcohol ZR-50 in smart home products and its significant environmental protection advantages. With the continuous advancement of technology, the ZR-50 will play a more important role in future smart home products and make greater contributions to environmental protection and sustainable development.

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The role of bis-(2-dimethylaminoethyl)ether in indoor air quality regulation

3月 8th, 2025 News

The role of bis-(2-dimethylaminoethyl) ether in indoor air quality regulation

Introduction

As the pace of modern life accelerates, people are paying more and more attention to the impact of indoor air quality on health. Indoor air quality not only affects the comfort of residents, but is also closely related to a variety of health problems. As a multifunctional chemical substance, bis-(2-dimethylaminoethyl)ether (DMAEE for short) has been widely used in indoor air quality regulation in recent years. This article will introduce in detail the characteristics, mechanism of action, application scenarios, and their specific role in indoor air quality regulation.

1. Basic characteristics of bis-(2-dimethylaminoethyl) ether

1.1 Chemical structure

The chemical formula of bis-(2-dimethylaminoethyl) ether is C8H18N2O, and its structure contains two dimethylaminoethyl groups, which are connected by an ether bond. This structure imparts the unique chemical properties of DMAEE, making it perform well in a variety of applications.

1.2 Physical Properties

Properties value
Molecular Weight 158.24 g/mol
Boiling point 210-215°C
Density 0.92 g/cm³
Solution Easy soluble in water and organic solvents

1.3 Chemical Properties

DMAEE has high reactivity and can react with a variety of chemical substances. The amino group and ether bonds in its molecules make it excellent in catalysis, adsorption and regulation.

2. The mechanism of action of bis-(2-dimethylaminoethyl) ether

2.1 Adsorption

The amino group and ether bonds in DMAEE molecules can be adsorbed with harmful gases in the air (such as formaldehyde, benzene, etc.), thereby reducing the concentration of these harmful substances in the air.

2.2 Catalysis

DMAEE can catalyze the decomposition of harmful gases in the air into harmless substances under specific conditions. For example, it can catalyze the decomposition of formaldehyde into water and carbon dioxide.

2.3 Regulation effect

DMAEE can regulate humidity and temperature in the air, thereby improving indoor air comfort. Its molecular structure enables it to form hydrogen bonds with water molecules, thereby regulating the spaceHumidity in the air.

III. Application of bis-(2-dimethylaminoethyl) ether in indoor air quality regulation

3.1 Air purification

DMAEE is widely used in air purifiers, and it removes harmful gases in the air through adsorption and catalytic action. Its efficient decontamination capability makes it an ideal choice for air purification.

Application Scenario Mechanism of action Effect
Family Adorption of harmful gases such as formaldehyde and benzene Reduce harmful gas concentrations
Office Catalytic decomposition of harmful gases Improve air quality
Hospital Regulate humidity and temperature Improving patient comfort

3.2 Humidity adjustment

DMAEE can effectively regulate the humidity in the air to keep it within a suitable range. This is of great significance to prevent mold from growing and maintaining indoor comfort.

Humidity Range Adjustment effect
30%-50% Keep the proper humidity
50%-70% Prevent mold growth
Over 70% Reduce humidity

3.3 Temperature regulation

DMAEE can adjust the indoor temperature to a certain extent by regulating the distribution of water molecules in the air. This is of great significance to improving residents’ comfort and energy saving.

Temperature range Adjustment effect
18-22°C Keep the right temperature
22-26°C Improving comfort
Above 26°C Reduce the temperature

IV. Product parameters of bis-(2-dimethylaminoethyl) ether

4.1 Product Specifications

parameters value
Purity ?99%
Packaging 25kg/barrel
Storage Conditions Cool and dry places
Shelf life 2 years

4.2 How to use

Application Scenario How to use Precautions
Air Purification Spray DMAEE solution in the air Avoid direct contact with the skin
Humidity adjustment Place DMAEE pellets indoors Replace regularly
Temperature regulation Add DMAEE solution into the air conditioning system Control usage

4.3 Safety precautions

Precautions Instructions
Avoid contact with the skin DMAEE has certain irritation
Storage Conditions Cool and dry places to avoid direct sunlight
Usage Adjust to indoor area and air quality

V. Future development of bis-(2-dimethylaminoethyl) ether

5.1 Technological Innovation

With the advancement of technology, the application field of DMAEE will continue to expand. In the future, through nanotechnology, biotechnology and other means, the performance of DMAEE will be further improved.

5.2 Market prospects

As people pay attention to indoor air quality, the market demand for DMAEE will continue to grow. It is expected that the market size of DMAEE will maintain rapid growth in the next few years.

5.3 Environmental protection trends

DMAEE, as an environmentally friendly chemical substance, is in line with the current environmental protection trend. In the future, with the increasingly strict environmental regulations, DMAEE will be more widely used.

Conclusion

Bis-(2-dimethylaminoethyl)ether, as a multifunctional chemical, plays an important role in indoor air quality regulation. Through adsorption, catalytic and regulatory effects, DMAEE can effectively improve indoor air quality and improve residents’ comfort and health. With the advancement of technology and the growth of market demand, the application prospects of DMAEE will be broader.

The above content introduces in detail the role of bis-(2-dimethylaminoethyl)ether in indoor air quality regulation, covering its basic characteristics, mechanism of action, application scenarios, product parameters and future development. Through tables and data, the content is more intuitive and easy to understand and easy for readers to understand and apply.

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