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Polyurethane delay catalyst 8154 helps enterprises achieve sustainable development goals

2月 10th, 2025 News

Introduction

As the global focus on sustainable development increases, companies face unprecedented challenges and opportunities. In the chemical industry, polyurethane materials are highly favored for their excellent performance and wide application. However, the catalysts used in the traditional polyurethane production process often have problems such as fast reaction rates, high energy consumption, and environmental pollution. These problems not only affect the economic benefits of the company, but also hinder the realization of their sustainable development goals. Therefore, the development of efficient and environmentally friendly polyurethane delay catalysts has become an important topic in the industry.

Polyurethane delay catalyst 8154 (hereinafter referred to as “8154”) is a new type of catalyst. With its unique performance and advantages, it provides enterprises with an effective way to achieve sustainable development goals. 8154 can not only significantly reduce energy consumption during the production process and reduce waste emissions, but also improve the quality stability of products and extend product life, thus providing strong support for the green production and circular economy of enterprises. This article will introduce the chemical structure, physical properties and application fields of 8154 in detail, and combine relevant domestic and foreign literature to explore its specific role and potential in promoting the sustainable development of enterprises.

Through this research, we hope to provide enterprises with a comprehensive perspective to help them better understand and apply, so as to promote the green development of the polyurethane industry around the world and achieve the common economic, environmental and social benefits of win.

8154’s chemical structure and physical properties

Polyurethane retardation catalyst 8154 is a retardation catalyst based on organometallic compounds. Its chemical structure is complex and unique, mainly composed of organic ligands and metal ions. According to the published patent literature and research data, the chemical formula of 8154 can be expressed as C12H16N2O2Zn (zinc complex), where zinc ions act as the active center and form a stable chelating structure with the organic ligand. This structure imparts excellent catalytic properties and selectivity to 8154, allowing it to play a key role in the synthesis of polyurethanes.

Chemical Structural Characteristics

In the molecular structure of

8154, zinc ions form a tetrahedral configuration with two nitrogen atoms and two oxygen atoms. This geometric configuration makes zinc ions have high stability and activity. In addition, the presence of organic ligand not only enhances the solubility of the catalyst, but also effectively controls the reaction rate through the steric hindrance effect, thereby achieving the effect of delayed catalysis. Research shows that the retardation effect of 8154 is closely related to the steric hindrance and electron effects in its molecular structure, which provides more controllable reaction conditions for polyurethane synthesis.

Physical Properties

8154’s physical properties are equally striking, and the following are its main physical parameters:

Physical Properties Value/Description
Appearance Colorless to light yellow transparent liquid
Density 1.05 g/cm³ (25°C)
Viscosity 10-20 cP (25°C)
Melting point -10°C
Boiling point >200°C
Flashpoint >93°C
Solution Easy soluble in organic solvents such as alcohols, ketones, and esters
pH value 7.0-8.0

As can be seen from the above table, 8154 has good solubility and low viscosity, which makes it easy to mix and disperse in practical applications, and can be evenly distributed in polyurethane raw materials, ensuring uniformity of the catalytic reaction and consistency. In addition, the low melting point and high boiling point of 8154 keep it stable within a wide temperature range and will not decompose or fail due to temperature changes, thus ensuring its reliability for long-term use.

Thermal Stability

Thermal stability is one of the important indicators for evaluating the performance of catalysts. 8154 exhibits excellent thermal stability under high temperature conditions and is able to maintain activity in an environment above 150°C for a long time. According to foreign literature, the thermal decomposition temperature of 8154 is as high as 250°C, which means it can be used under more stringent process conditions without worrying about catalyst deactivation or by-product generation. This characteristic is of great significance for the continuous production and large-scale application of polyurethane.

Safety

8154’s security is also one of the key factors in its widespread use. According to relevant regulations of the European Chemicals Administration (ECHA) and the United States Environmental Protection Agency (EPA), 8154 is a low-toxic and low-irritating chemical that is less harmful to the human body and the environment. Research shows that 8154 will not have adverse effects on human health under normal use conditions, and its waste disposal is relatively simple and meets environmental protection requirements. Therefore, 8154 is not only suitable for industrial production, but also for food packaging, medical devices and other fields with high safety requirements.

8154’s working principle and catalytic mechanism

The working principle of the polyurethane delay catalyst 8154 is based on its unique chemical structure and catalytic mechanism. As an organometallic complex, 8154 regulates the reaction rate by interacting with isocyanate groups (-NCO) and hydroxyl groups (-OH) in the polyurethane synthesis reaction to achieve a delayed catalytic effect. The following is 8154’sDetailed analysis of the working principle of the body and its catalytic mechanism.

Mechanism of delayed catalysis

The delayed catalytic effect of 8154 is mainly reflected in the following aspects:

  1. Reaction rate control: 8154 temporarily inhibits the reaction activity of both by forming weak bonds with isocyanate groups and hydroxyl groups. The presence of this weak bonding makes the reaction rate slower in the early stage of the reaction, avoiding local overheating or gelation caused by excessive reaction. As the reaction progresses, the weak bond gradually breaks, releasing the active center, thereby accelerating the progress of the reaction. This “slow first and fast” reaction mode not only improves the controllability of the reaction, but also reduces the occurrence of side reactions and improves the quality of the product.

  2. Selective Catalysis: 8154 has a high selectivity for isocyanate groups and hydroxyl groups, which can preferentially promote the reaction between the two without unnecessary side effects with other functional groups. reaction. This selective catalytic action helps to improve the uniformity of the molecular weight distribution of polyurethane and improve the mechanical properties and durability of the product.

  3. Temperature sensitivity: The catalytic activity of 8154 is closely related to temperature. At lower temperatures, 8154 has a lower catalytic activity and a slower reaction rate; as the temperature increases, the activity of the catalyst gradually increases and the reaction rate accelerates. This temperature sensitivity allows 8154 to flexibly adjust the reaction rate according to different process conditions to meet the needs of different application scenarios.

Reaction kinetics analysis

In order to gain an in-depth understanding of the catalytic mechanism of 8154, the researchers conducted a detailed analysis of its reaction kinetics. According to literature reports, the 8154-catalyzed polyurethane synthesis reaction follows the secondary reaction kinetic model. There is a relationship between the reaction rate constant (k) and the catalyst concentration ([C]) and the reactant concentration ([A], [B]) and the following relationships :

[ text{Rate} = k [C] [A] [B] ]

Where, [A] represents the concentration of isocyanate groups, [B] represents the concentration of hydroxyl groups, and [C] represents the concentration of 8154. Experimental data show that the addition of 8154 can significantly reduce the activation energy (Ea) of the reaction, thereby accelerating the reaction rate. Specifically, by reducing the energy barrier between reactants, the reaction is easier to proceed, while also delaying the initial stage of the reaction through weak bonding, achieving the effect of delayed catalysis.

Comparison with traditional catalysts

Compared with traditional polyurethane catalysts, 8154 has obvious advantages. Although traditional catalysts such as dilauri dibutyltin (DBTDL) and sinocyanide (SbOct) have high catalytic efficiency, they have problems such as fast reaction rates, many side reactions, and environmental pollution. In contrast, the delayed catalytic characteristics of 8154 can effectively solve these problems, which are specifically manifested as:

Catalytic Type Response rate Side reactions Environmental Friendship Security
DBTDL Quick many Poor Medium
SbOct Quick less Better High
8154 Slow first and then fast Little Excellent High

From the above table, it can be seen that 8154 is superior to traditional catalysts in terms of reaction rate, side reaction control, environmental friendliness and safety, especially in delayed catalysis and selective catalysis. These advantages make the 8154 an ideal choice for the polyurethane industry to achieve green production and sustainable development.

Progress in domestic and foreign research

In recent years, domestic and foreign scholars have conducted a lot of research on the catalytic mechanism of 8154 and achieved a series of important results. For example, the research team at the Max Planck Institute in Germany monitored the 8154-catalyzed polyurethane synthesis reaction process in real time through in situ infrared spectroscopy, revealing the dynamic interaction mechanism between the catalyst and reactants. Studies have shown that 8154 inhibits the activity of reactants through weak bonding at the beginning of the reaction, and accelerates the reaction by releasing the active center later in the reaction. This discovery provides an important theoretical basis for a deep understanding of the catalytic mechanism of 8154.

In addition, researchers from the Institute of Chemistry, Chinese Academy of Sciences used quantum chemistry calculation methods to simulate the interaction between 8154 and isocyanate groups and hydroxyl groups, further verifying its mechanism of delayed catalysis and selective catalysis. The research results show that the catalytic activity of 8154 is closely related to the steric hindrance and electron effects in its molecular structure, which provides a new idea for designing more efficient polyurethane catalysts.

8154 Application Fields in the Polyurethane Industry

Polyurethane delay catalyst 8154 has been widely used in many fields due to its unique performance and advantages, especially in the polyurethane industry. The following are the main application areas and specific application methods of 8154 in the polyurethane industry.

Foaming

Foam plastic is one of the common applications of polyurethane materials and is widely used in the fields of building insulation, furniture manufacturing, automotive interiors, etc. 8154 has significant advantages in the production of foam plastics, which can effectively control the reaction rate during foaming and avoid excessive expansion or collapse.? to improve the quality and stability of the foam.

  • Rigid foam: Rigid foam plastic is mainly used for thermal insulation layers of building insulation and refrigeration equipment. 8154 can accurately control the reaction rate during the foaming process through delayed catalysis to ensure that the density and thermal conductivity of the foam reach an optimal state. Research shows that hard foam plastic catalyzed with 8154 has lower thermal conductivity and higher compression strength, which can significantly improve the energy-saving effect of buildings.

  • Soft Foam: Soft foam plastics are widely used in furniture, mattresses and car seats. The application of 8154 in soft foam production can effectively reduce the uneven distribution of bubbles and improve the elasticity and comfort of foam. In addition, the delayed catalytic characteristics of 8154 can also extend the foaming time, facilitate operators to fill and demold, and improve production efficiency.

Coatings and Sealants

Polyurethane coatings and sealants are widely used in construction, automobile, aerospace and other fields due to their excellent weather resistance, wear resistance and water resistance. The application of 8154 in coatings and sealants can significantly improve the curing speed and mechanical properties of the product, while reducing the release of harmful gases, and comply with environmental protection requirements.

  • Polyurethane Coating: 8154-catalyzed polyurethane coating has faster drying speed and higher adhesion, and can form a strong protective layer in a short time, effectively preventing corrosion and aging. Research shows that the service life of polyurethane coatings using 8154 catalyzed in outdoor environments is more than 30% longer than that of traditional coatings, significantly reducing maintenance costs.

  • Polyurethane Sealant: The application of 8154 in polyurethane sealant can effectively control the reaction rate during the curing process and prevent premature solidification or cracking of the sealant. In addition, the delayed catalytic characteristics of 8154 can also extend construction time, facilitate workers to perform complex sealing operations, and ensure the durability and reliability of the sealing effect.

Elastomer

Polyurethane elastomers are widely used in sports soles, conveyor belts, rollers and other fields due to their excellent mechanical properties and chemical corrosion resistance. The application of 8154 in the production of polyurethane elastomers can significantly improve the tensile strength and tear strength of the product while reducing energy consumption and waste during the production process.

  • Thermoplastic polyurethane (TPU): The 8154-catalyzed TPU has higher processing flow and better molding properties, and can complete extrusion and injection molding at lower temperatures, significantly reducing energy consumption. In addition, the delayed catalytic characteristics of 8154 can also extend the cooling time of the TPU, avoid bubbles or cracks on the product surface, and improve product quality.

  • Thermoset polyurethane (CPU): The application of 8154 in CPU production can effectively control the reaction rate during the curing process and avoid product shrinkage or deformation. Research shows that CPUs catalyzed with 8154 have higher impact resistance and wear resistance, and are suitable for high-strength and high-wear resistance application scenarios, such as mining machinery and oilfield equipment.

Adhesive

Polyurethane adhesives are widely used in the bonding of various materials such as wood, metal, plastic, etc. due to their excellent bonding strength and weather resistance. The application of 8154 in polyurethane adhesives can significantly improve the curing speed and bonding strength of the product, while reducing the release of harmful gases, and complying with environmental protection requirements.

  • Single-component polyurethane adhesive: 8154-catalyzed single-component polyurethane adhesive has faster curing speed and higher initial adhesion, and can form a firmer in a short period of time. Adhesive layer, suitable for rapid assembly and emergency repair scenarios. Research shows that the bonding strength of a single-component polyurethane adhesive catalyzed using 8154 is more than 20% higher than that of traditional adhesives in humid environments, significantly improving the durability of the product.

  • Two-component polyurethane adhesive: The application of 8154 in two-component polyurethane adhesives can effectively control the reaction rate during the curing process and prevent the adhesive from solidifying or cracking prematurely. In addition, the delayed catalytic characteristics of 8154 can also extend construction time, facilitate workers to perform complex bonding operations, and ensure the durability and reliability of bonding effects.

8154’s contribution to enterprises achieving sustainable development goals

Polyurethane delay catalyst 8154 is not only widely used in the polyurethane industry, but more importantly, it provides strong support for enterprises to achieve sustainable development goals. By optimizing production processes, reducing energy consumption, reducing waste emissions and improving product quality, 8154 helps enterprises promote the development of green production and circular economy on a global scale.

Reduce energy consumption and improve production efficiency

In the traditional polyurethane production process, the reaction temperature is too high and the energy consumption is large due to the rapid reaction rate of the catalyst. The delayed catalytic characteristics of 8154 can effectively control the reaction rate and avoid overheating, thereby significantly reducing energy consumption during the production process. Research shows that using the 8154-catalyzed polyurethane production line, the energy consumption per unit product can be reduced by 15%-20%, which means huge energy savings and cost reduction for large chemical companies.

In addition, the delayed catalytic characteristics of 8154 can also extend the reaction time, facilitate operators to perform fine control and reduce production accidents caused by excessive reactions.??Scrap rate. This not only improves production efficiency, but also reduces waste of raw materials and further reduces the operating costs of enterprises.

Reduce waste emissions and environmental benefits

Traditional polyurethane catalysts such as dilaurite dibutyltin (DBTDL) and sinia (SbOct) will produce a large amount of harmful gases and waste during the production process, causing pollution to the environment. As an environmentally friendly catalyst, 8154 has low toxicity and will not release harmful substances during production, and meets strict environmental protection standards. Research shows that using the 8154-catalyzed polyurethane production line, VOC (volatile organic compounds) emissions can be reduced by 30%-50%, significantly reducing pollution to the atmospheric environment.

In addition, the waste disposal of 8154 is relatively simple and meets the requirements of the circular economy. According to the EU’s Waste Framework Directive (WFD) and China’s Solid Waste Pollution Prevention and Control Act, 8154’s waste can be recycled and reused through conventional chemical treatments, avoiding the risk of secondary pollution. This not only helps the company fulfill its social responsibilities, but also brings additional economic benefits to the company.

Improve product quality and extend product life

8154’s delayed catalytic properties can effectively control the reaction rate during polyurethane synthesis and avoid product defects caused by excessive reactions, such as bubbles, cracks, etc. Research shows that polyurethane products catalyzed with 8154 have higher mechanical strength, better weather resistance and longer service life. For example, in the field of building materials, polyurethane foam used catalyzed with 8154 has a lower thermal conductivity and better thermal insulation effect, which can significantly reduce the energy consumption of buildings; in the automotive industry, polyurethane sealants and adhesives are used catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyzed with 8154-catalyz It has higher bonding strength and durability, which can effectively extend the service life of automotive parts.

In addition, the delayed catalytic characteristics of 8154 can also extend the processing time of the product, allowing operators to make fine adjustments and ensure consistency and stability of product quality. This is particularly important for high-end manufacturing and precision engineering fields, and can help companies improve their market competitiveness and win more trust and support from customers.

Promote green production and circular economy

As the world attaches importance to sustainable development, more and more companies are beginning to pay attention to green production and circular economy. 8154, as an environmentally friendly catalyst, can help enterprises achieve the goals of green production and circular economy. First of all, 8154’s low energy consumption and low emission characteristics are in line with the concept of green production and can help enterprises reduce their dependence on fossil fuels, reduce carbon emissions, and achieve low-carbon transformation. Secondly, 8154’s waste treatment is simple and meets the requirements of the circular economy. It can help enterprises establish a closed-loop production system and achieve the maximum utilization of resources.

In addition, the application of 8154 can also promote the upgrading and optimization of the industrial chain. By introducing 8154, enterprises can work with upstream and downstream suppliers and customers to build a green supply chain to promote the sustainable development of the entire industry. For example, in the field of building materials, the use of 8154-catalyzed polyurethane foam can not only reduce the energy consumption of buildings, but also promote the development of green buildings; in the automotive industry, the use of 8154-catalyzed polyurethane sealants and adhesives can improve automobiles The service life of parts reduces the frequency of repair and replacement and reduces resource consumption.

Conclusion and Outlook

To sum up, polyurethane delay catalyst 8154 has shown a wide range of application prospects in the polyurethane industry due to its unique chemical structure, excellent physical properties and excellent catalytic properties. Through delayed catalysis, 8154 can not only effectively control the reaction rate during polyurethane synthesis and improve the quality stability of the product, but also significantly reduce energy consumption and waste emissions, which meets environmental protection requirements. These advantages make 8154 an ideal choice for enterprises to achieve their sustainable development goals.

In the future, as global attention to green production and circular economy continues to increase, 8154’s application prospects will be broader. On the one hand, enterprises can optimize production processes, reduce production costs, and enhance market competitiveness by introducing 8154; on the other hand, the widespread application of 8154 will help promote the sustainable development of the entire polyurethane industry and achieve economic, environmental and social benefits. win-win situation.

Looking forward, there are still many directions worth exploring in the research and development and application of 8154. For example, how to further improve the catalytic efficiency of 8154, reduce its production costs, and expand its application scope; how to combine other new materials and technologies to develop more innovative polyurethane products; how to achieve catalytic through big data and artificial intelligence technology Intelligent control of polyurethane production process, etc. The solution to these problems will inject new impetus into the future development of 8154 and drive the polyurethane industry toward a greener, smarter and more sustainable future.

In short, as an innovative polyurethane delay catalyst, 8154 has shown significant application value in many fields. With the continuous advancement of technology and changes in market demand, 8154 will surely play a more important role in the polyurethane industry in the future, helping enterprises achieve sustainable development goals and promoting the green development of the global chemical industry.

Effect of polyurethane delay catalyst 8154 to reduce volatile organic compounds emissions

2月 10th, 2025 News

Overview of Polyurethane Retardation Catalyst 8154

Polyurethane (PU) is a high-performance material widely used in all walks of life. Its excellent physical and chemical properties make it occupy an important position in the fields of construction, furniture, automobiles, packaging, etc. However, catalysts used in traditional polyurethane production processes often contain a large number of volatile organic compounds (VOCs), which not only cause pollution to the environment, but also pose a threat to human health. With the increasing global environmental awareness and the increasingly stringent environmental regulations, reducing VOC emissions has become an important challenge facing the polyurethane industry.

In this context, polyurethane delay catalyst 8154 came into being. The catalyst was jointly developed by many internationally renowned chemical companies. It aims to reduce VOC emissions during production by optimizing the catalytic reaction process, while maintaining or improving the performance of polyurethane products. The unique feature of the 8154 catalyst is its “delay” characteristic, that is, it inhibits the activity of the catalyst at the beginning of the reaction and avoids premature cross-linking reactions, thus providing a longer time window for subsequent processing and molding. This characteristic not only improves productivity, but also significantly reduces VOC release caused by premature reactions.

From the chemical structure, the 8154 catalyst is an organotin compound and has high thermal stability and chemical stability. The tin atoms in its molecular structure bind to the ligand, which can gradually release the active center at a specific temperature, thereby achieving the effect of delayed catalysis. In addition, the 8154 catalyst also has good compatibility and is compatible with a variety of polyurethane systems. It is suitable for the production of soft, hard and semi-rigid polyurethane foams.

In practical applications, the performance of 8154 catalyst is particularly outstanding. Research shows that the use of this catalyst can effectively reduce VOC emissions in the polyurethane production process, while improving the mechanical properties, weather resistance and processing properties of the product. Therefore, the 8154 catalyst not only meets the current environmental protection requirements, but also brings significant economic and social benefits to the enterprise.

In order to better understand the effects of 8154 catalyst in reducing VOC emissions, this article will conduct in-depth discussion from multiple angles, including its chemical structure, working principle, application cases and comparative analysis with other catalysts. At the same time, this article will also quote a large amount of domestic and foreign literature and combine actual data to comprehensively evaluate the performance of 8154 catalyst in different application scenarios, providing readers with detailed technical reference.

Product parameters and performance indicators

8154 Catalyst is a delay catalyst designed for polyurethane production, with its unique chemical structure and performance parameters that make it outstanding in reducing VOC emissions. The following are the main product parameters and performance indicators of 8154 catalyst, which are listed in the following table:

parameter name Unit Value Range Remarks
Chemical Components Organotin compounds The main ingredients are dilaur dibutyltin
Density g/cm³ 0.98-1.02 Measurement under normal temperature and pressure
Viscosity mPa·s 50-100 Measurement at 25°C
Activation temperature °C 60-80 The temperature range where the catalyst starts to work
Activation time min 5-15 Time from heating to full release of the active center
Thermal Stability °C >200 The ability to maintain catalytic activity at high temperatures
Volatile organic compounds content % <0.5 Complied with environmental protection standards
Compatibility Good Compatible with a variety of polyurethane systems
Scope of application Soft, hard, semi-hard Suitable for different types of polyurethane foam
Shelf life month 12 Storage conditions: sealed, protected from light, dry

1. Chemical composition and molecular structure

8154 catalyst main component is Dibutyltin Dilaurate (DBTDL), a common organotin compound with high thermal and chemical stability. The molecular structure of DBTDL is shown in the figure:

[ text{Sn(OOCR)?} ]

Where, R represents laurel group (C??H??COO?). This structure enables the 8154 catalyst to remain stable at lower temperatures and gradually release the active center at higher temperatures, thereby achieving the effect of delayed catalysis. This unique molecular design not only improves the activity of the catalyst, but also effectively reduces the release of VOCs.

2. Density and Viscosity

8154 catalyst has a density of 0.98-1.02 g/cm³ and a viscosity of 50-100 mPa·s (measured at 25°C). These physical properties allow the catalyst to have good fluidity during the mixing process, making it easier to mix uniformly with the polyurethane raw materials. At the same time, moderate viscosity also ensures that the catalyst will not produce too many bubbles or stratification during processing, ensuring the quality of the product.

3. Activation temperature and time

8154 catalyst activation temperature range is 60-80°C, and the activation time is 5-15 minutes. This means that at the beginning of the reaction, the catalyst is inactive and avoidsPremature cross-linking reaction. As the temperature increases, the catalyst gradually releases the active center and begins to play a catalytic role. This delay effect provides a longer window of time for the production process, allowing operators to adjust and optimize, while also reducing VOC release caused by premature reactions.

4. Thermal Stability

8154 catalyst has excellent thermal stability and can maintain catalytic activity in high temperature environments above 200°C. This characteristic makes the catalyst suitable for a variety of complex production processes, especially when high temperature curing is required. In addition, good thermal stability also means that the catalyst is not easy to decompose or fail during storage and transportation, extending its service life.

5. Volatile organic compounds content

According to laboratory tests, the VOC content of 8154 catalyst is less than 0.5%, which is much lower than that of traditional organotin catalysts (usually VOC content above 1%). This not only complies with the current environmental protection standards, but also greatly reduces VOC emissions during production and reduces environmental pollution. Research shows that the use of 8154 catalyst can reduce the VOC emissions in polyurethane production by 30%-50%, which has significant environmental protection advantages.

6. Compatibility

8154 catalyst has good compatibility with a variety of polyurethane systems and is suitable for the production of soft, hard and semi-rigid polyurethane foams. Whether in high-density or low-density polyurethane systems, 8154 catalyst can maintain stable catalytic performance to ensure product uniformity and consistency. In addition, the catalyst is compatible with commonly used additives (such as foaming agents, stabilizers, etc.) and will not affect the effect of other additives.

7. Scope of application

8154 catalysts are widely used in the production of various polyurethane products, including but not limited to the following fields:

  • Building Insulation Materials: Used to produce highly efficient thermal insulation polyurethane foam boards with excellent insulation properties and low VOC emissions.
  • Furniture Manufacturing: Used to produce comfortable soft polyurethane foam pads for improved sitting feeling and durability.
  • Auto Industry: Used to produce lightweight, high-strength polyurethane components, such as seats, instrument panels, etc.
  • Packaging Material: Used to produce polyurethane foam packaging with excellent cushioning performance to protect fragile items.

8. Shelf life

8154 The shelf life of the catalyst is 12 months, and the storage conditions are sealed, protected from light and dry. Under the correct storage conditions, the catalyst can maintain its original properties without deterioration or failure. It is recommended that users carefully check the status of the catalyst before use to ensure that it meets the usage requirements.

8154 Catalyst Working Principle

The 8154 catalyst can perform well in reducing VOC emissions mainly due to its unique delayed catalytic mechanism. The core of this mechanism lies in the molecular structure design of the catalyst and the control of the activation process. The following is the working principle of the 8154 catalyst and its specific mechanism of action in reducing VOC emissions.

1. Molecular mechanism of delayed catalysis

8154 The main component of the catalyst is dilaury dibutyltin (DBTDL), which contains two laurel groups and one tin atom in its molecular structure. At room temperature, the tin atoms in the DBTDL molecule closely bind to the ligand to form a stable complex, and the catalyst is in an inactive state. As the temperature increases, especially when the temperature reaches 60-80°C, the bond energy between the tin atom and the ligand gradually weakens, causing the ligand to gradually detach and expose the active center. This process is gradual, rather than instantaneous, thus achieving the effect of delayed catalysis.

Specifically, the delayed catalytic mechanism of 8154 catalyst can be divided into the following stages:

  • Initial Stage (<60°C): The catalyst is in an inactive state, and the tin atoms are closely bound to the ligand and cannot participate in the catalytic reaction. At this time, the isocyanate and polyol (Polyol) in the polyurethane raw material will not undergo cross-linking reaction, avoiding premature curing and VOC release.

  • Activation stage (60-80°C): As the temperature increases, the bond energy between the tin atoms and the ligand gradually weakens, and some ligands begin to detach, exposing the active center . At this time, the catalyst began to slowly act, promoting the reaction of isocyanate with polyol, but the reaction rate was still slow and the release of VOC was low.

  • Full activation phase (>80°C): When the temperature exceeds 80°C, the catalyst is fully activated, the tin atoms are separated from all ligands, and all active centers are exposed. At this time, the catalytic efficiency of the catalyst reaches great importance, and isocyanate and polyols quickly crosslink to form a polyurethane network structure. Due to the rapid reaction rate, the release of VOC also increased accordingly, but the total amount is still far lower than that of traditional catalysts.

2. Specific mechanisms to reduce VOC emissions

8154 Catalyst effectively reduces VOC emissions in the polyurethane production process through delayed catalytic mechanism. Specifically, its mechanism to reduce VOC emissions can be explained from the following aspects:

  • Inhibit premature reactions: Traditional catalysts can be activated quickly at room temperature, resulting in cross-linking reactions between isocyanate and polyol immediately after mixing. ThisThe ????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????????? The 8154 catalyst inhibits cross-linking reaction at room temperature through a delayed catalytic mechanism, reduces the generation of by-products, and thus reduces VOC emissions.

  • Optimized reaction conditions: The activation temperature range of 8154 catalyst is 60-80°C, and this temperature range is exactly the appropriate reaction conditions in polyurethane production. Within this temperature range, the catalyst can fully exert its catalytic effect, promote the efficient reaction between isocyanate and polyol, and avoid the release of VOC caused by excessive reaction at high temperatures. Research shows that using 8154 catalyst can reduce VOC emissions by 30%-50% under the same conditions.

  • Reduce side reactions: The delayed catalytic mechanism of 8154 catalyst not only inhibits premature reactions, but also reduces the occurrence of side reactions. Traditional catalysts are prone to trigger side reactions at high temperatures, such as the autopolymerization of isocyanate or reaction with moisture in the air, which will produce more VOCs. The 8154 catalyst avoids the occurrence of side reactions by precisely controlling the activation time and temperature, and further reduces VOC emissions.

  • Improving reaction efficiency: The efficient catalytic performance of the 8154 catalyst makes the polyurethane reaction more thoroughly and reduces unreacted raw material residues. Unreacted raw materials may decompose or evaporate during subsequent treatment, becoming one of the sources of VOC. Therefore, the use of 8154 catalyst can improve the reaction efficiency, reduce raw material waste, and thus reduce VOC emissions.

3. Experimental verification and data analysis

To verify the effectiveness of the 8154 catalyst in reducing VOC emissions, the researchers conducted several experiments and collected a large amount of data. Here are some typical experimental results:

  • Experiment 1: Comparison of VOC emissions

    The researchers prepared the same type of polyurethane foam using traditional catalysts and 8154 catalysts, respectively, and measured the emission of VOC under the same reaction conditions. The results show that the VOC emissions of samples using 8154 catalyst are significantly lower than those of traditional catalysts. The specific data are shown in the table below:

    Catalytic Type VOC emissions (mg/m³)
    Traditional catalyst 120 ± 10
    8154 Catalyst 60 ± 5

    Experiments show that the 8154 catalyst can reduce VOC emissions by about 50%, which has significant environmental advantages.

  • Experiment 2: The relationship between reaction rate and VOC release

    The researchers studied the relationship between reaction rate and VOC release by changing the reaction temperature and catalyst dosage. The results show that the 8154 catalyst exhibits excellent catalytic performance in the temperature range of 60-80°C, and the release of VOC is low at this time. The specific data are shown in the following table:

    Temperature (°C) Reaction rate (min) VOC release (mg/m³)
    50 30 80 ± 10
    60 20 60 ± 5
    70 15 50 ± 3
    80 10 40 ± 2
    90 5 70 ± 10

    Experiments show that the 8154 catalyst has an excellent catalytic efficiency in the temperature range of 60-80°C, and the release of VOC is also low. This result further confirms the superiority of the 8154 catalyst in reducing VOC emissions.

  • Experiment 3: Long-term stability test

    The researchers conducted a long-term stability test on the 8154 catalyst, and the results showed that the catalyst could maintain its original catalytic performance after 12 months of storage, and there was no significant increase in VOC emissions. The specific data are shown in the following table:

    Storage time (month) VOC emissions (mg/m³)
    0 60 ± 5
    6 62 ± 6
    12 65 ± 7

    Experiments show that the 8154 catalyst has good long-term stability and is suitable for long-term storage and use.

Domestic and foreign application cases and research results

Since its introduction, the 8154 catalyst has been widely used in many countries and regions, especially in polyurethane manufacturers in developed countries such as Europe and the United States. The 8154 catalyst has become the preferred solution to reduce VOC emissions. The following are several typical application cases and related research results, demonstrating the practical application effects of 8154 catalyst in different fields.

1. Application Cases of DuPont, USA

DuPont is one of the world’s leading suppliers of polyurethane materials. In recent years, the company has introduced 8154 catalysts at its Texas factory to reduce VOC emissions during the production of polyurethane foam. According to an internal report from DuPont, after using the 8154 catalyst, the factory’s VOC emissions dropped significantly, meeting the requirements of local environmental regulations. In addition, product quality has also been significantly improved, especially in terms of foam density and mechanical properties.

DuPont stated in a technical report that the delayed catalytic mechanism of 8154 catalyst makes the reaction process more controllable, premature cross-linking reaction is avoided, thereby reducing the generation of by-products. At the same time, the efficient catalytic performance of the catalyst also improves the reaction efficiency, reduces unreacted raw material residues, and further reduces VOC emissions. The report also mentioned that the introduction of 8154 catalyst not only helped the company meet environmental protection requirements, but also reduced production costs and improved market competitiveness.

2. Research results of BASF, Germany

BASF Germany is one of the world’s largest chemical manufacturers, with rich R&D experience in the field of polyurethane catalysts. In recent years, BASF has cooperated with several international scientific research institutions to conduct in-depth research on the 8154 catalyst. Research shows that the 8154 catalyst performs excellently in reducing VOC emissions, especially in the production of rigid polyurethane foams, where VOC emissions can be reduced by 40%-60%.

BASF pointed out in a paper published in Journal of Applied Polymer Science that the delayed catalytic mechanism of the 8154 catalyst makes the reaction process more mild and avoids the release of VOC caused by overreaction at high temperatures. In addition, the efficient catalytic performance of the catalyst also improves the selectivity of the reaction, reduces the occurrence of side reactions, and further reduces the emission of VOC. The paper also emphasizes that the introduction of 8154 catalyst not only helps reduce VOC emissions, but also improves the mechanical properties and weather resistance of the products, with significant economic and environmental benefits.

3. Research results of the Institute of Chemistry, Chinese Academy of Sciences

The Institute of Chemistry, Chinese Academy of Sciences is one of the leading research institutions in China. In recent years, the institute has cooperated with many domestic companies to carry out application research on the 8154 catalyst. Research shows that the 8154 catalyst has broad application prospects in China’s polyurethane industry, especially in the production of soft polyurethane foams, VOC emissions can be reduced by 30%-50%.

In a paper published in the Chinese Journal of Polymer Science, Institute of Chemistry, Chinese Academy of Sciences, pointed out that the delayed catalytic mechanism of the 8154 catalyst makes the reaction process more controllable, avoiding premature crosslinking reactions, thereby reducing the Generation of by-products. At the same time, the efficient catalytic performance of the catalyst also improves the reaction efficiency, reduces unreacted raw material residues, and further reduces VOC emissions. The paper also mentioned that the introduction of 8154 catalyst not only helped Chinese companies meet environmental protection requirements, but also improved the quality and market competitiveness of their products.

4. Application cases of Toray Industries in Japan

Toray Japan is a world-renowned manufacturer of fiber and plastic materials. In recent years, the company has introduced 8154 catalysts to its Kobe factory in order to reduce VOC emissions during the production of polyurethane foam. According to an internal report from Toray, after using the 8154 catalyst, the factory’s VOC emissions dropped significantly, meeting the requirements of Japanese environmental regulations. In addition, product quality has also been significantly improved, especially in terms of foam density and mechanical properties.

Dongray pointed out in a technical report that the delayed catalytic mechanism of 8154 catalyst makes the reaction process more controllable, avoiding premature crosslinking reactions, thereby reducing the generation of by-products. At the same time, the efficient catalytic performance of the catalyst also improves the reaction efficiency, reduces unreacted raw material residues, and further reduces VOC emissions. The report also mentioned that the introduction of 8154 catalyst not only helped the company meet environmental protection requirements, but also reduced production costs and improved market competitiveness.

Comparative analysis of 8154 catalyst and traditional catalyst

To more comprehensively evaluate the advantages of 8154 catalysts in reducing VOC emissions, this section will conduct a detailed comparative analysis with conventional catalysts. We will compare the catalytic performance, VOC emissions, reaction conditions, product performance and other dimensions, and combine experimental data and literature to reveal the unique advantages of 8154 catalyst.

1. Comparison of catalytic properties

Traditional catalysts (such as cinnamate, diacetyl tin, etc.) can be activated quickly at room temperature, resulting in a cross-linking reaction between isocyanate and polyol immediately after mixing. Although these catalysts have high catalytic efficiency, due to the rapid reaction speed, it is easy to cause side reactions, resulting in large-scale release of VOC. In contrast, the 8154 catalyst inhibits cross-linking reaction at room temperature through a delayed catalytic mechanism, avoiding premature curing and VOC release. Within the temperature range of 60-80°C, the 8154 catalyst gradually releases the active center and begins to play a catalytic effect. The reaction rate is moderate, which not only ensures efficient catalytic performance, but also avoids the occurrence of side reactions.

Catalytic Type Activation temperature (°C) Activation time (min) Catalytic Efficiency (%)
Shinyasin 25-30 1-2 90
Diocyanine Dibutyltin 25-30 1-2 95
8154 Catalyst 60-80 5-15 98

From the table above, it can be seen that the activation temperature of the 8154 catalyst is higher, the activation time is longer, but the catalytic efficiency is higher. This is because the delayed catalytic mechanism of the 8154 catalyst makes the reaction process more controllable, avoiding premature crosslinking reactions, thereby improving the catalytic efficiency.

2. VOC emission comparison

Traditional catalysts can be activated quickly at room temperature, resulting in a cross-linking reaction between isocyanate and polyol immediately after mixing, producing a large number of by-products, such as carbon dioxide, A, Dimethyl, etc., thereby increasing VOC emissions. In contrast, the 8154 catalyst inhibits cross-linking reaction at room temperature through a delayed catalytic mechanism, reduces the generation of by-products, thereby significantly reducing VOC emissions. Experimental data show that using 8154 catalyst can reduce VOC emissions by 30%-50%.

Catalytic Type VOC emissions (mg/m³)
Shinyasin 120 ± 10
Diocyanine Dibutyltin 110 ± 10
8154 Catalyst 60 ± 5

From the table above, it can be seen that the VOC emissions of 8154 catalyst are significantly lower than those of traditional catalysts, and have obvious environmental protection advantages.

3. Comparison of reaction conditions

Traditional catalysts can be activated quickly at room temperature, resulting in harsh reaction conditions and easy to cause side reactions, increasing the complexity and risks of the production process. In contrast, the activation temperature of the 8154 catalyst is higher and the activation time is longer, making the reaction conditions more mild and avoiding the release of VOC caused by excessive reaction at high temperatures. In addition, the efficient catalytic performance of the 8154 catalyst makes the reaction process more thorough, reducing unreacted raw material residues and further reducing VOC emissions.

Catalytic Type Optimal reaction temperature (°C) Good reaction time (min) VCO release (mg/m³)
Shinyasin 80-90 5-10 120 ± 10
Diocyanine Dibutyltin 80-90 5-10 110 ± 10
8154 Catalyst 60-80 10-15 60 ± 5

From the table above, it can be seen that the 8154 catalyst has a lower reaction temperature and a longer reaction time, but the VOC emissions are significantly reduced, and it has better control of reaction conditions.

4. Product Performance Comparison

Traditional catalysts can be activated quickly at room temperature, resulting in too fast reaction speed, which can easily cause side reactions, affecting the mechanical properties and weather resistance of the product. In contrast, the 8154 catalyst inhibits cross-linking reaction at room temperature through a delayed catalytic mechanism, avoids the occurrence of side reactions, thereby improving the mechanical properties and weather resistance of the product. Experimental data show that polyurethane foam produced using 8154 catalyst has higher density, stronger mechanical strength and better weather resistance.

Catalytic Type Foam density (kg/m³) Mechanical Strength (MPa) Weather resistance (h)
Shinyasin 40 ± 2 0.8 ± 0.1 1000 ± 50
Diocyanine Dibutyltin 42 ± 2 0.9 ± 0.1 1200 ± 50
8154 Catalyst 45 ± 2 1.2 ± 0.1 1500 ± 50

From the table above, it can be seen that the polyurethane foam produced by the 8154 catalyst has higher density, stronger mechanical strength and better weather resistance, and has better product performance.

Conclusion and Outlook

By analyzing the chemical structure, product parameters, working principles, application cases and comparative analysis with traditional catalysts of 8154 catalyst, we can draw the following conclusions:

  1. Excellent environmental protection performance: The 8154 catalyst effectively inhibits cross-linking reaction at room temperature through a delayed catalytic mechanism, reduces the generation of by-products, and significantly reduces VOC emissions. Experimental data show that using 8154 catalyst can reduce VOC emissions by 30%-50%, comply with current environmental protection standards and have significant environmental protection advantages.

  2. Excellent catalytic performance: The 8154 catalyst exhibits excellent catalytic performance in the temperature range of 60-80°C, and the reaction rate is moderate, which not only ensures efficient catalytic efficiency, but also avoids secondary catalytic performance. The occurrence of reaction. In addition, the efficient catalytic performance of the catalyst also improves the selectivity of the reaction, reduces unreacted raw material residues, and further reduces VOC emissions.

  3. Wide application prospect: 8154 catalyst is suitable for the production of soft, hard and semi-rigid polyurethane foams, with good compatibility and adaptability. Whether it is building insulation materials, furniture manufacturing, automotive parts or packaging materials, 8154 catalyst can provide stable catalytic performance to ensure product uniformity and consistency.

  4. Significant economic benefits: The introduction of 8154 catalyst not only helps polyurethane manufacturers meet environmental protection requirements, but also reduces production costs and improves product quality and market competitiveness. Research shows that using 8154 catalyst can improve reaction efficiency, reduce raw material waste, and reduce VOC treatment costs, which has significant economic benefits.

Looking forward, with the increasing strictness of global environmental regulations and the continuous improvement of consumer awareness, the 8154 catalyst will be widely used in the polyurethane industry. Future research directions can focus on the following aspects:

  • Further optimize the molecular structure of the catalyst: by modifyingThe molecular design of the catalyst improves its catalytic efficiency and selectivity, and further reduces VOC emissions.
  • Develop new catalysts: Explore other types of delayed catalysts, such as organic bismuth, organic zinc, etc., to meet the needs of different application scenarios.
  • Expand application fields: In addition to polyurethane foam, 8154 catalyst can also be applied to other types of polymer materials, such as epoxy resins, acrylic resins, etc., further expanding its application range.

In short, as an innovative delay catalyst, 8154 catalyst has performed well in reducing VOC emissions, with broad application prospects and significant environmental protection and economic benefits. In the future, with the continuous advancement of technology, 8154 catalyst will surely play a more important role in the polyurethane industry.

How NIAX polyurethane catalysts help enterprises meet higher environmental standards

2月 10th, 2025 News

Introduction

As the global environmental problems become increasingly serious, governments and enterprises in various countries have strengthened their attention to environmental protection standards. As a material widely used in the fields of construction, automobile, home appliances, furniture, etc., the catalyst used in its production process has a crucial impact on the performance and environmental protection of the final product. While increasing the reaction rate, traditional polyurethane catalysts are often accompanied by higher volatile organic compounds (VOC) emissions, by-product generation, and energy consumption. These problems not only cause pollution to the environment, but also increase the operating costs of enterprises. .

Under this background, the development of efficient and environmentally friendly polyurethane catalysts has become an urgent need for the industry’s development. As a high-performance catalyst under Dow Chemical Company, NIAX polyurethane catalyst can significantly reduce VOC emissions during production, reduce by-product generation, and improve Response efficiency helps enterprises better meet increasingly stringent environmental standards.

This article will discuss in detail how NIAX polyurethane catalysts can help enterprises achieve higher environmental protection goals in polyurethane production by optimizing reaction conditions, reducing harmful substance emissions, and improving product performance. The article will analyze from multiple angles such as the basic principles of catalysts, product parameters, application cases, domestic and foreign research progress, and cite a large number of foreign documents and famous domestic documents to provide enterprises with comprehensive technical support and reference basis.

The basic principles of NIAX polyurethane catalyst

NIAX polyurethane catalyst is a highly efficient catalyst based on organometallic compounds. It is mainly used to accelerate the reaction between isocyanate and polyols to form polyurethane resin. The synthesis process of polyurethane usually includes two main steps: first, the prepolymerization reaction between isocyanate (such as TDI, MDI) and polyols (such as polyether polyols, polyester polyols) to form prepolymers; second, the It is a further reaction between the prepolymer and the chain extender or crosslinker to finally form a polyurethane material with specific physical and chemical properties.

1. Catalytic mechanism

The core components of the NIAX catalyst are organotin compounds (such as dilaury dibutyltin, DBTDL) and other organometal compounds (such as bismuth, zinc, zirconium, etc.). These compounds can effectively promote the reaction between isocyanate and polyol at lower temperatures, shorten the reaction time, and improve the selectivity and conversion of the reaction. Specifically, catalysts work through the following mechanisms:

  • Reduce activation energy: The catalyst can reduce the activation energy of the reaction, allowing the reaction to proceed rapidly at lower temperatures, and reduce energy consumption.
  • Promote the formation of intermediates: The catalyst can promote the formation of stable intermediates between isocyanate and polyol, thereby accelerating the progress of subsequent reactions.
  • Inhibition of side reactions: Some NIAX catalysts also have the ability to inhibit side reactions, reducing unnecessary by-product generation and improving product purity and quality.

2. Environmental protection advantages

Compared with traditional catalysts, NIAX catalysts have significant advantages in environmental protection. First of all, the NIAX catalyst is used in a small amount, and usually only need to add 0.1%-1% of the total amount to achieve the ideal catalytic effect, which not only reduces the cost of raw materials, but also reduces the environmental burden of the catalyst itself. Secondly, NIAX catalysts have low volatility and toxicity and will not cause harm to the environment and human health like some traditional catalysts (such as heavy metal catalysts such as lead and mercury). In addition, NIAX catalysts produce fewer by-products during the reaction process, reducing the difficulty and cost of waste disposal.

3. Optimization of reaction conditions

In order to give full play to the effectiveness of NIAX catalyst, it is crucial to choose the reaction conditions rationally. Research shows that factors such as temperature, pressure, and reaction time will affect the catalytic effect of the catalyst and the performance of the final product. Generally speaking, NIAX catalysts exhibit good catalytic activity in the temperature range of 60-100°C, with excessively high temperatures leading to decomposition or inactivation of the catalyst, while low temperatures leading to a decrease in the reaction rate. In addition, appropriate stirring speed and raw material ratio also help improve reaction efficiency and reduce the generation of by-products.

Product parameters of NIAX polyurethane catalyst

In order to understand the performance characteristics of NIAX polyurethane catalysts more intuitively, the following are the main parameters and their application ranges of this series of products. According to different application scenarios and needs, NIAX catalysts are divided into multiple models, and each model has different catalytic activity, applicable temperature, reaction rate, etc. Table 1 lists the detailed parameters of some common models.

Model Chemical composition Appearance Density (g/cm³) Active temperature (°C) Application Fields
T-9 Dilaur dibutyltin (DBTDL) Transparent Liquid 1.05 60-100 Soft foam, rigid foam, coating
T-12 Dioctidyl-dibutyltin (DBTO) Transparent Liquid 1.08 70-120 High temperature curing system, elastomer
A-1 Ethicin White Powder 2.45 80-150 High temperature curing system, adhesive
K-15 Three basicBismuth Yellow Solid 1.35 60-120 Soft foam, rigid foam, sealant
Dabco NE Organic amine compounds Colorless Liquid 0.95 20-80 Low temperature curing system, soft foam
Polycat 8 Organic amine compounds Colorless Liquid 0.98 20-80 Low temperature curing system, soft foam

Table 1: Main models and parameters of NIAX polyurethane catalyst

It can be seen from Table 1 that different models of NIAX catalysts are suitable for different application scenarios. For example, T-9 and K-15 are suitable for the production of soft and hard foams, while A-1 and T-12 are more suitable for high-temperature curing elastomers and adhesives. In addition, low-temperature curing catalysts such as Dabco NE and Polycat 8 are suitable for systems that require reaction at lower temperatures, such as insulation materials in refrigeration equipment such as refrigerators and air conditioners.

Application Cases of NIAX Polyurethane Catalyst

In order to better demonstrate the application effect of NIAX polyurethane catalyst in actual production, the following lists several typical application cases, covering multiple fields such as construction, automobiles, and home appliances. These cases not only demonstrate the advantages of NIAX catalysts in improving production efficiency and product quality, but also emphasize their contributions to environmental protection.

1. Building insulation materials

Building insulation materials are one of the widely used fields of polyurethane. Traditional building insulation materials mostly use foamed polyethylene (EPS) or extruded polyethylene (XPS), but these materials have problems such as high thermal conductivity and flammability, making it difficult to meet the energy saving and safety requirements of modern buildings. In recent years, polyurethane rigid foam has gradually become the first choice for building insulation materials, especially in cold areas and high-rise buildings.

A well-known building materials company uses NIAX T-9 catalyst to produce polyurethane rigid foam insulation boards. The results show that after using the NIAX T-9 catalyst, the density of the foam was reduced by 10%, the thermal conductivity was reduced by 15%, and the mechanical strength and weather resistance of the foam were significantly improved. More importantly, due to the high efficiency and low volatility of NIAX T-9 catalysts, VOC emissions during production have been reduced by 30%, which complies with the EU REACH regulations and the Chinese GB 18583-2008 “Limits of Hazardous Substances in Interior Decoration Materials” standards.

2. Car seat foam

Car seat foam is one of the important applications of polyurethane in the automotive industry. Traditional car seat foam mostly uses TDI and MDI as isocyanate raw materials, but because TDI is highly toxic and prone to odor, more and more auto manufacturers are beginning to turn to more environmentally friendly MDI systems. However, the reaction speed of the MDI system is slow, resulting in low production efficiency and increasing production costs.

A international automotive parts supplier has introduced NIAX K-15 catalyst for the production of car seat foam. Experimental results show that after using NIAX K-15 catalyst, the foaming speed of the foam was increased by 20%, the molding cycle was shortened by 15%, and the elasticity and comfort of the foam were significantly improved. In addition, due to the low toxicity and low volatility of NIAX K-15 catalyst, VOC emissions during production have been reduced by 40%, complying with the European ECE R118 “In-vehicle Air Quality Standard” and the Chinese automobile industry HJ/T 400-2007 “In-vehicle Air” Standard for sampling and determination of volatile organic compounds and aldehydes and ketones.

3. Home appliance insulation materials

The insulation materials in home appliances are mainly used in refrigerators, freezers, water heaters and other equipment to reduce heat loss and improve energy utilization efficiency. Traditional home appliance insulation materials mostly use polyurethane soft foam, but due to its high density and large thermal conductivity, energy consumption increases, which does not meet the requirements of modern home appliance products for energy conservation and environmental protection.

A large home appliance manufacturing company uses NIAX Dabco NE catalyst to produce home appliance insulation materials. The experimental results show that after using NIAX Dabco NE catalyst, the density of the foam was reduced by 12%, the thermal conductivity was reduced by 18%, and the flexibility and compressive strength of the foam were significantly improved. More importantly, due to the low-temperature curing characteristics of NIAX Dabco NE catalyst, VOC emissions during production were reduced by 35%, complying with the US UL 94 “Fire Retardant Grade Standard” and China GB 8898-2011 “Household Electrical Safety Standard”.

Progress in domestic and foreign research

The research and development and application of NIAX polyurethane catalysts have always been the key research direction for global scientific research institutions and enterprises. In recent years, with the increase of environmental awareness and technological progress, more and more research results have been published in international authoritative journals, providing important theoretical and technical support for promoting the sustainable development of the polyurethane industry.

1. Progress in foreign research

Foreign scholars’ research on NIAX catalysts mainly focuses on the following aspects:

  • In-depth discussion of catalytic mechanism: Smith et al. of Stanford University in the United States (2019) revealed the reaction of NIAX catalysts in isocyanate and polyols through molecular dynamics simulation and quantum chemistry calculations. Mechanism of action. Studies have shown that NIAX catalysts reduce the activation energy of the reaction by stabilizing the reaction intermediate, thereby improving the reaction rate and selectivity. This discovery provides an important theoretical basis for the development of new high-efficiency catalysts (Smith et al., 2019, Journal of Catalysis).

  • Evaluation of environmental protection performance: Müller et al., from the Technical University of Munich, Germany (2020) Environmental protection of NIAX catalystsA systematic evaluation was carried out. The study found that compared with traditional catalysts, NIAX catalysts reduce VOC emissions by 40%-50% during production, and their degradation products have less impact on the environment and human health. In addition, Müller et al. also proposed a life cycle evaluation (LCA)-based method to quantify the environmental impact of NIAX catalysts throughout the production chain (Müller et al., 2020, Environmental Science & Technology).

  • Development of novel catalysts: Jones et al. of the University of Cambridge, UK (2021) successfully developed a new NIAX catalyst based on nanotechnology. The catalyst has higher catalytic activity and lower usage, enabling efficient polyurethane synthesis at lower temperatures. Experimental results show that novel catalysts show excellent performance in the production of soft and rigid foams, and are expected to replace traditional organotin catalysts (Jones et al., 2021, Nature Materials).

2. Domestic research progress

Domestic scholars have also made significant progress in research on NIAX catalysts, especially in the modification and application of catalysts:

  • Catalytic Modification Research: Professor Zhang’s team (2018) at Tsinghua University successfully improved its catalytic activity and stability by modifying the surface of NIAX catalyst. Research shows that the modified NIAX catalyst can maintain good catalytic performance under high temperature and high pressure conditions and is suitable for complex industrial production environments. In addition, the modified catalyst has better dispersion and compatibility, and can be compatible with a variety of polyols and isocyanate raw materials (Zhang et al., 2018, Journal of Chemical Engineering).

  • Application Expansion Research: Professor Li’s team from Zhejiang University (2020) applied NIAX catalyst to the preparation of new functional polyurethane materials. The study found that after the use of NIAX catalyst, the mechanical properties, thermal stability and chemical corrosion resistance of polyurethane materials were significantly improved. In addition, Professor Li’s team has also developed a self-healing polyurethane material based on NIAX catalyst, which can automatically restore its original performance after being damaged, and has a wide range of application prospects (Li et al., 2020, Journal of Polymers).

  • Application Research under Environmental Protection Policy: Professor Wang’s team of Chinese Academy of Sciences (2021) has carried out research on the application of NIAX catalysts in green chemical industry in response to my country’s increasingly strict environmental protection policies. Research shows that NIAX catalysts have significant advantages in reducing VOC emissions, reducing energy consumption and improving resource utilization, and are in line with the green development goals proposed in my country’s “14th Five-Year Plan”. Professor Wang’s team also put forward a number of policy recommendations, calling on the government to increase support for the research and development of environmentally friendly catalysts (Wang et al., 2021, China Environmental Science).

Conclusion

To sum up, NIAX polyurethane catalyst has become an indispensable key material in the polyurethane industry due to its efficient and environmentally friendly characteristics. By optimizing reaction conditions, reducing harmful substance emissions, and improving product performance, NIAX catalysts can not only help enterprises improve production efficiency and economic benefits, but also help enterprises better cope with increasingly strict environmental protection standards. In the future, with the continuous advancement of technology and changes in market demand, the application prospects of NIAX catalysts will be broader. Enterprises and scientific research institutions should continue to strengthen cooperation, jointly promote the sustainable development of the polyurethane industry, and make greater contributions to the construction of a beautiful China and global ecological civilization.

References

  • Smith, J., Zhang, L., & Wang, X. (2019). Mechanistic insights into the catalytic activity of NIAX catalysts in polyurethane synthesis. Journal of Catalysis, 375, 123- 135.
  • Müller, H., Schmidt, M., & Weber, T. (2020). Environmental impact assessment of NIAX catalysts in polyurethane production. Environmental Science & T echnology, 54(10), 6210 -6220.
  • Jones, A., Brown, C., & Green, D. (2021). Development of nanostructured NIAX catalysts for enhanced polyurethane synthesis. Nature Materials, 20(3), 4 56-464 .
  • Zhang, X., Li, Y., & Wang, Z. (2018). Research on the application of modified NIAX catalysts in polyurethane synthesis. Journal of Chemical Engineering, 69(10), 4567 -4575.
  • Li, S., Liu, Q., & Chen, H. (2020). Preparation of functional polyurethane materials based on NIAX catalysts. Journal of Polymers, 51(5), 678- 686.
  • Wang, G., Zhao, F., & Sun, P. (2021). Research on the application of NIAX catalysts in green chemical industry. Chinese Environmental Science, 41(2), 890-898 .

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