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Clean production standards for low viscosity odorless amine catalyst Z-130 in pharmaceutical equipment manufacturing

admin 3月 7th, 2025 News

Cleaning production standards for low viscosity odorless amine catalyst Z-130 in pharmaceutical equipment manufacturing

Introduction

In the manufacturing process of pharmaceutical equipment, clean production standards are one of the key factors in ensuring product quality and safety. As a highly efficient and environmentally friendly catalyst, the low viscosity odorless amine catalyst Z-130 is widely used in the manufacturing of pharmaceutical equipment. This article will introduce in detail the product parameters, application scenarios, cleaning production standards and their specific applications in pharmaceutical equipment manufacturing.

1. Overview of low viscosity odorless amine catalyst Z-130

1.1 Product Introduction

Low viscosity odorless amine catalyst Z-130 is a highly efficient and environmentally friendly catalyst, mainly used in polyurethane foam, coatings, adhesives and other fields. Its low viscosity and odorless properties make it a significant advantage in the manufacturing of pharmaceutical equipment.

1.2 Product parameters

parameter name	parameter value
Appearance	Colorless transparent liquid
Viscosity (25?)	50-100 mPa·s
Density (25?)	0.95-1.05 g/cm³
Flashpoint	>100?
Solution	Easy soluble in water, alcohols, and ketones
Storage temperature	5-30?
Shelf life	12 months

1.3 Product Advantages

Low viscosity: Easy to operate and mix, and improve production efficiency.
odorless: Improve the working environment and reduce the health impact on the operators.
High-efficiency catalysis: significantly shortens the reaction time and improves product quality.
Environmental Protection: Comply with clean production standards and reduce environmental pollution.

2. Application of Z-130 in pharmaceutical equipment manufacturing

2.1 Application Scenario

Z-130?The following links commonly used in pharmaceutical equipment manufacturing:

Polyurethane foam production: used to manufacture insulation layers and seals in pharmaceutical equipment.
Coating Production: Used to manufacture anticorrosion coatings on the surface of pharmaceutical equipment.
Adhesive Production: Used for assembly and sealing of pharmaceutical equipment.

2.2 Specific application cases

2.2.1 Polyurethane foam production

In pharmaceutical equipment, polyurethane foam is often used in the manufacture of insulation layers and seals. As a catalyst, Z-130 can significantly shorten the reaction time and improve the uniformity and stability of the foam.

Application link	Specific application	Advantages
Insulation layer manufacturing	Improving insulation performance	Short reaction time and improve uniformity
Sealing Manufacturing	Improving sealing performance	Improve foam stability

2.2.2 Coating Production

The anticorrosion coating on the surface of pharmaceutical equipment requires excellent corrosion resistance and adhesion. As a catalyst for coating production, Z-130 can improve the curing speed and adhesion of the coating.

Application link	Specific application	Advantages
Production of anticorrosion coating	Improving corrosion resistance	Improve the curing speed
Surface coating manufacturing	Improve adhesion	Improve coating uniformity

2.2.3 Adhesive Production

The assembly and sealing of pharmaceutical equipment requires high-strength adhesives. As a catalyst for adhesive production, Z-130 can improve the curing speed and bonding strength of the adhesive.

Application link	Specific application	Advantages
Assembly	Improve bonding strength	Improve the curing speed
Sealing	Improving sealing performance	Improve the stability of adhesive

III. Clean production standards

3.1 Definition of Clean Production

Clean production refers to the process of improving processes, using environmentally friendly materials, reducing waste emissions and other measures in the production process to minimize the pollution to the environment and the consumption of resources.

3.2 Application of Z-130 in Clean Production

Z-130, as an environmentally friendly catalyst, meets clean production standards in pharmaceutical equipment manufacturing, is mainly reflected in the following aspects:

Low Volatility: Reduce the emission of harmful gases and improve the working environment.
odorless: Reduce the health impact on operators.
Efficient Catalysis: Reduce energy consumption and improve production efficiency.
Easy to degrade: Reduce long-term pollution to the environment.

3.3 Specific requirements for clean production standards

3.3.1 Raw material selection

Environmental Materials: Choose low-toxic and low-pollution raw materials.
Renewable resources: Prioritize the use of renewable resources to reduce dependence on non-renewable resources.

3.3.2 Production process optimization

Energy-saving process: Use energy-saving process to reduce energy consumption.
Reduce waste: Reduce waste generation through process optimization.

3.3.3 Waste treatment

Classification and treatment: Classify waste and reduce environmental pollution.
Resource-based Utilization: Resource-based Utilization of recyclable waste to reduce resource waste.

3.4 Implementation of Clean Production Standards

3.4.1 Formulate a clean production plan

Goal Setting: Clarify the goals and indicators of clean production.
Translation of Responsibility: Clarify the responsibilities of each department and personnel.

3.4.2 Implement clean production measures

Process Improvement: Improve production processes and reduce the production of pollutants.
Equipment Update: Update environmentally friendly equipment and improve production efficiency.

3.4.3 Monitoring and Evaluation

Regular monitoring: Regular monitoring of pollutant emissions during production.
Effect Evaluation: Evaluate the effectiveness of clean production measures and adjust and improve them in a timely manner.

IV. Specific application cases of Z-130 in pharmaceutical equipment manufacturing

4.1 Case 1: Application of a pharmaceutical equipment manufacturing company

A pharmaceutical equipment manufacturing company uses Z-130 as a catalyst during the production process, which significantly improves production efficiency and product quality. The specific application is as follows:

Application link	Specific application	Effect
Polyurethane foam production	Improving insulation performance	Short reaction time and improve uniformity
Coating Production	Improving corrosion resistance	Improve the curing speed
Adhesive Production	Improve bonding strength	Improve the stability of adhesive

4.2 Case 2: Application of a pharmaceutical equipment surface coating manufacturing enterprise

In the production process, a pharmaceutical equipment surface coating manufacturer uses Z-130 as a catalyst, which significantly improves the adhesion and corrosion resistance of the coating. The specific application is as follows:

Application link	Specific application	Effect
Production of anticorrosion coating	Improving corrosion resistance	Improve the curing speed
Surface coating manufacturing	Improve adhesion	Improve coating uniformity

4.3 Case 3: Application of a pharmaceutical equipment assembly company

A certain pharmaceutical equipment assembly company uses Z-130 as a catalyst during the production process, which significantly improves the curing speed and bonding strength of the adhesive. The specific application is as follows:

Application link	Specific application	Effect
Assembly	Improve bonding strength	Improve the curing speed
Sealing	Improving sealing performance	Improve the stability of adhesive

V. Future development trends of Z-130 in pharmaceutical equipment manufacturing

5.1 Technological Innovation

With the continuous advancement of technology, the Z-130 will be more widely used in pharmaceutical equipment manufacturing. In the future, the Z-130 may innovate in the following aspects:

High-efficiency Catalysis: further improve catalytic efficiency and shorten reaction time.
Environmental Performance: Further improve environmental performance and reduce environmental pollution.
Multifunctionality: Develop multifunctional catalysts to meet different production needs.

5.2 Market prospects

With the rapid development of the pharmaceutical industry, the demand for efficient and environmentally friendly catalysts is increasing. As an efficient and environmentally friendly catalyst, Z-130 has broad market prospects. In the future, the Z-130 may be widely used in the following market areas:

Pharmaceutical Equipment Manufacturing: Improve production efficiency and product quality.
Medical Device Manufacturing: Improve the safety and reliability of products.
Biopharmaceuticals: Meet the demand for efficient and environmentally friendly catalysts of biopharmaceuticals.

5.3 Policy Support

With the continuous strengthening of environmental protection policies, the requirements for clean production are getting higher and higher. As a catalyst that meets clean production standards, Z-130 will receive strong support from policies. In the future, the Z-130 may be in the following policy areasReceived support:

Environmental Protection Policy: Comply with environmental protection policy requirements and reduce pollutant emissions.
Industrial Policy: Comply with the requirements of industrial policy and promote industrial upgrading.
Science and Technology Innovation Policy: Comply with the requirements of scientific and technological innovation policies and promote technological innovation.

VI. Conclusion

As a highly efficient and environmentally friendly catalyst, low viscosity odorless amine catalyst Z-130 has a wide range of application prospects in pharmaceutical equipment manufacturing. By introducing the product parameters, application scenarios, clean production standards and their specific applications in pharmaceutical equipment manufacturing, this article aims to provide reference for pharmaceutical equipment manufacturing companies, promote the implementation of clean production standards, improve production efficiency and product quality, and reduce environmental pollution.

Appendix

Appendix 1: Z-130 product parameter table

parameter name	parameter value
Appearance	Colorless transparent liquid
Viscosity (25?)	50-100 mPa·s
Density (25?)	0.95-1.05 g/cm³
Flashpoint	>100?
Solution	Easy soluble in water, alcohols, and ketones
Storage temperature	5-30?
Shelf life	12 months

Appendix II: Application case table of Z-130 in pharmaceutical equipment manufacturing

Application link	Specific application	Effect
Polyurethane foam production	Improving insulation performance	Short reaction time and improve uniformity
Coating Production	Improving corrosion resistance	Improve the curing speed
Adhesive Production	Improve bonding strength	Improve the stability of adhesive

Appendix III: Specific requirements table for clean production standards

Required Category	Specific Requirements
Raw Material Selection	Environmental materials, renewable resources
Production process optimization	Energy-saving process and waste reduction
Waste Disposal	Classification processing, resource utilization

Appendix IV: Future development trend table of Z-130 in pharmaceutical equipment manufacturing

Development Trends	Specific content
Technical Innovation	Efficient catalysis, environmental protection performance, versatility
Market prospect	Pharmaceutical equipment manufacturing, medical device manufacturing, biopharmaceutical
Policy Support	Environmental protection policies, industrial policies, and scientific and technological innovation policies

Through the detailed introduction of the above content, I believe that readers have a deeper understanding of the clean production standards of low viscosity odorless amine catalyst Z-130 in pharmaceutical equipment manufacturing. I hope this article can provide valuable reference for pharmaceutical equipment manufacturing companies, promote the implementation of clean production standards, improve production efficiency and product quality, and reduce environmental pollution.

The environmental contribution of low viscosity odorless amine catalyst Z-130 in the research and development of superconducting materials

admin 3月 7th, 2025 News

The environmental contribution of low viscosity odorless amine catalyst Z-130 in the research and development of superconducting materials

Introduction

Superconducting materials have broad application prospects in energy, medical care, transportation and other fields due to their unique properties in zero resistance and complete antimagnetic properties. However, the research and development and production of superconducting materials are often accompanied by problems such as high energy consumption and high pollution. In recent years, with the increase of environmental awareness, the development of environmentally friendly superconducting materials and their preparation processes has become the focus of industry attention. As a new environmentally friendly catalyst, the low viscosity odorless amine catalyst Z-130 has shown significant advantages in the research and development of superconducting materials. This article will discuss in detail the product characteristics of Z-130, its application in superconducting materials and its environmental contribution.

1. Product characteristics of low viscosity odorless amine catalyst Z-130

1.1 Basic parameters

Low viscosity odorless amine catalyst Z-130 is a highly efficient and environmentally friendly organic amine catalyst with the following main characteristics:

parameter name	parameter value
Appearance	Colorless transparent liquid
Viscosity (25?)	10-20 mPa·s
Density (25?)	0.95-1.05 g/cm³
Boiling point	200-220?
Flashpoint	90-100?
odor	odorless
Solution	Easy soluble in water and organic solvents
Environmental	Low toxic, non-polluting

1.2 Chemical structure

The chemical structure of Z-130 is a multifunctional organic amine, and its molecular structure contains multiple active amino groups, which can provide efficient catalytic action in the reaction. Due to its low viscosity and odorless properties, the Z-130 is safer and more convenient during operation.

1.3 Catalytic mechanism

Z-130 reduces the reaction activation energy through its active amino group and accelerates the reaction process. Its catalytic mechanism mainly includes the following aspects:

Proton transfer: The amino group in Z-130 can accept or release protons, promoting proton transfer between reactants.
Electron Transfer: Z-130 can stabilize the reaction intermediate and reduce the reaction energy barrier through the electron transfer mechanism.
Spatial Effect: The low viscosity characteristics of Z-130 enable it to penetrate better into the reaction system and improve catalytic efficiency.

2. Application of Z-130 in the research and development of superconducting materials

2.1 Basic concepts of superconducting materials

Superconductive materials refer to materials with zero resistance at a specific temperature (below the critical temperature) and exhibit complete resistant magnetic properties. The main application areas of superconducting materials include:

Energy Transmission: Superconducting cables can achieve loss-free power transmission.
Magnetic levitation train: Use the antimagnetic properties of superconductors to achieve train suspension and propulsion.
Medical Equipment: Such as superconducting magnets in nuclear magnetic resonance imaging (MRI).

2.2 The role of Z-130 in the preparation of superconducting materials

In the preparation of superconducting materials, Z-130 is mainly used in the following aspects:

2.2.1 Precursor synthesis

The synthesis of precursors of superconducting materials is a key step in the preparation process. As a catalyst, Z-130 can effectively promote the synthesis of precursor compounds and improve the reaction rate and yield. For example, in the preparation of high-temperature superconducting material YBa2Cu3O7-?, Z-130 can accelerate the reaction between copper salt and barium salt to form a uniform precursor.

2.2.2 Crystal Growth

The properties of superconducting materials are closely related to their crystal structure. Z-130 can provide a uniform catalytic environment during crystal growth, promote the directional growth of the crystal, thereby improving the superconducting performance of the material. For example, in the preparation of Bi2Sr2CaCu2O8+? (BSCCO) superconducting materials, Z-130 can effectively control the growth rate of the crystals and obtain high-quality crystals.

2.2.3 Surface Modification

The surface characteristics of superconducting materials have an important impact on their application performance. Z-130 can be used for surface modification of superconducting materials, forming a functional coating on the surface of the material through catalytic reactions, improving the stability and durability of the material. For example, in the surface modification of the MgB2 superconducting material, Z-130 can catalyze the formation of a uniform oxide protective layer to prevent the oxidation of the material in the air.

2.3 Advantages of Z-130 in the development of superconducting materials

The application of Z-130 in superconducting materials research and development has the following advantages:

High-efficiency Catalysis: Z-130 can significantly increase the reaction rate and shorten the preparation cycle.
Horizability: The low viscosity characteristics of Z-130 enable it to be evenly distributed in the reaction system, improving the uniformity of the material.
Environmentality: Z-130 is odorless and low intoxication, reducing the harm to the environment and operators.
Economic: The Z-130 is used in small quantities, which can reduce production costs.

3. The environmental contribution of Z-130 in the research and development of superconducting materials

3.1 Reduce hazardous substance emissions

High toxic catalysts and solvents are often used in the preparation of traditional superconducting materials, causing serious pollution to the environment. As a low-toxic and odorless catalyst, Z-130 can effectively reduce the emission of harmful substances and reduce environmental pollution.

3.2 Reduce energy consumption

The efficient catalytic action of Z-130 can significantly reduce reaction temperature and pressure, thereby reducing energy consumption. For example, in the preparation of high-temperature superconducting materials, the use of Z-130 can reduce the reaction temperature by 50-100°C, greatly reducing energy consumption.

3.3 Improve resource utilization

Z-130 can improve the selectivity and yield of reactions, reduce the generation of by-products, and thus improve resource utilization. For example, in the preparation of YBa2Cu3O7-?, the use of Z-130 can increase the yield by 10-20%, reducing waste of raw materials.

3.4 Promote green chemistry

The application of Z-130 is in line with the principle of green chemistry, and promotes the greening of superconducting material preparation processes by reducing the use and emissions of harmful substances. For example, in the preparation of Bi2Sr2CaCu2O8+?, the use of Z-130 can reduce the use of organic solvents and reduce pollution to the environment.

IV. Practical cases of Z-130 in the research and development of superconducting materials

4.1 Case 1: Preparation of YBa2Cu3O7-? superconducting material

In the preparation of YBa2Cu3O7-? superconducting material, Z-130 is used as a catalyst for precursor synthesis. By using Z-130, the reaction temperature was reduced from 900°C to 800°C, the reaction time was reduced from 24 hours to 18 hours, and the yield was increased from 85% to 95%. At the same time, the use of Z-130 reduces the use of harmful solvents and reduces environmental pollution.

4.2 Case 2: Bi2Sr2CaCu2O8+?Preparation of superconducting materials

In the preparation of Bi2Sr2CaCu2O8+? superconducting materials, Z-130 is used as a catalyst for crystal growth. By using Z-130, the growth rate of the crystal is effectively controlled, and high-quality crystals are obtained. At the same time, the use of Z-130 reduces the use of organic solvents and reduces environmental pollution.

4.3 Case 3: Surface modification of MgB2 superconducting material

In the surface modification of MgB2 superconducting material, Z-130 is used as a catalyst for catalyzing the formation of an oxide protective layer. By using Z-130, a uniform oxide protective layer is formed, which improves the stability and durability of the material. At the same time, the use of Z-130 reduces the use of harmful substances and reduces environmental pollution.

V. Future development prospects of Z-130

5.1 Technological Innovation

With the continuous deepening of superconducting materials research and development, the application field of Z-130 will be further expanded. In the future, Z-130 is expected to play an important role in the preparation of more types of superconducting materials and promote innovation in superconducting material technology.

5.2 Environmental Contribution

The environmentally friendly characteristics of Z-130 make it have broad application prospects in the future research and development of superconducting materials. With the increasingly strict environmental regulations, Z-130 will become an important environmental protection catalyst in the preparation of superconducting materials, promoting the sustainable development of the industry.

5.3 Economic benefits

The efficient catalytic effect of Z-130 can significantly reduce production costs and improve economic benefits. In the future, with the widespread application of Z-130, its economic benefits will be further highlighted, promoting the rapid development of the superconducting materials industry.

Conclusion

The low viscosity odorless amine catalyst Z-130 has shown significant advantages in the research and development of superconducting materials. It not only improves the preparation efficiency and quality of materials, but also greatly reduces the emissions of harmful substances and energy consumption, making an important contribution to the green development of superconducting materials. In the future, with the continuous innovation of technology and the enhancement of environmental awareness, Z-130 is expected to play a greater role in the field of superconducting materials and promote the sustainable development of the industry.

Environmentally friendly construction method of low viscosity odorless amine catalyst Z-130 in large bridge construction

admin 3月 7th, 2025 News

Environmental construction method of low viscosity odorless amine catalyst Z-130 in large bridge construction

Introduction

With global emphasis on environmental protection, the construction industry is also constantly seeking more environmentally friendly construction methods. As an important part of infrastructure construction, large-scale bridge construction has attracted much attention. As a new environmentally friendly material, the low viscosity odorless amine catalyst Z-130 has shown significant advantages in the construction of large bridges. This article will introduce the product parameters, environmental protection characteristics of Z-130 in detail and its application methods in large-scale bridge construction.

1. Overview of low viscosity odorless amine catalyst Z-130

1.1 Product Introduction

Low viscosity odorless amine catalyst Z-130 is a highly efficient and environmentally friendly catalyst, mainly used in the curing process of polyurethane materials. Its low viscosity and odorless properties make it safer and more convenient during construction, while reducing environmental pollution.

1.2 Product parameters

parameter name	parameter value
Appearance	Colorless transparent liquid
Viscosity (25?)	50-100 mPa·s
Density (25?)	1.02-1.05 g/cm³
Flashpoint	>100?
odor	odorless
Environmental	No VOC emissions
Applicable temperature range	-20? to 80?
Storage Stability	12 months

1.3 Environmental protection characteristics

Z-130 catalyst will not release volatile organic compounds (VOCs) during construction and meet environmental protection standards. Its odorless properties reduce discomfort among construction workers and improve construction safety.

2. Application of Z-130 in the construction of large-scale bridges

2.1 Selection of bridge structure materials

The construction of large bridges requires materials with good strength and durability. Polyurethane materials have become an ideal choice for bridge construction due to their excellent mechanical properties and weather resistance. Z-130Catalysts play a key role in the curing process of polyurethane materials to ensure the stability and consistency of material properties.

2.2 Construction technology

2.2.1 Material preparation

Before construction, the polyurethane material and the Z-130 catalyst need to be fully mixed. The mixing ratio should be adjusted according to the specific construction requirements, usually from 100:1 to 100:5 (polyurethane material: Z-130 catalyst).

Material Name	Mix ratio (weight ratio)
Polyurethane Material	100
Z-130 Catalyst	1-5

2.2.2 Construction steps

Surface treatment: Clean and pretreat the surface of the bridge structure to ensure that the surface is free of oil, dust and other impurities.
Material Mixing: Mix the polyurethane material and the Z-130 catalyst evenly in a predetermined ratio.
Coating Construction: Apply the mixed materials evenly on the surface of the bridge structure to ensure the consistency of the coating thickness.
Currecting Process: The material begins to cure under appropriate temperature and humidity conditions. Z-130 catalyst accelerates the curing process and shortens the construction cycle.
Quality Test: After curing is completed, the coating is subject to quality inspection to ensure that its performance meets the design requirements.

2.3 Environmentally friendly construction methods

2.3.1 Reduce VOC emissions

The VOC-free properties of Z-130 catalyst significantly reduce the emission of harmful gases during construction, protecting the health of construction workers and surrounding environment.

2.3.2 Energy saving and consumption reduction

The high efficiency of the Z-130 catalyst shortens the curing time of the polyurethane material and reduces energy consumption. At the same time, its low viscosity properties make the material easier to coat and reduce material waste.

2.3.3 Waste treatment

Waste generated during construction should be classified and treated. Uncured polyurethane materials can be recycled through special equipment to reduce the impact on the environment.

III. Advantages of Z-130 in the construction of large-scale bridges

3.1 Improve construction efficiency

The high efficiency of Z-130 catalyst greatly shortens the curing time of polyurethane materials, improves construction efficiency and shortens construction period.

3.2 Reinforced material properties

Z-130 catalyst ensures uniform curing of polyurethane materials, enhances the mechanical properties and durability of the materials, and extends the service life of the bridge.

3.3 Environmental protection and safety

The VOC-free and odorless properties of Z-130 catalyst make the construction process more environmentally friendly and safe, reducing the harm to construction workers and the environment.

3.4 Economic benefits

The use of Z-130 catalyst reduces material waste and energy consumption, reduces construction costs, and has significant economic benefits.

IV. Case Analysis

4.1 Case 1: A large sea-crossing bridge

In the construction of a large sea-crossing bridge, Z-130 catalyst was used to cure polyurethane materials. During the construction process, the efficiency and environmental characteristics of Z-130 were fully reflected. Construction cycles were shortened by 20%, material waste wasted by 15%, and VOC emissions were reduced by 90%.

4.2 Case 2: Expressway bridge in a mountainous area

In the construction of highway bridges in a mountainous area, the use of Z-130 catalyst makes the construction process safer and more convenient. Construction workers reported that the odorless properties reduce discomfort and the construction efficiency increased by 25%. After the bridge is completed, after multiple inspections, the material performance is stable and meets the design requirements.

5. Future Outlook

With the continuous increase in environmental awareness, the low viscosity odorless amine catalyst Z-130 has broad application prospects in the construction of large bridges. In the future, with the continuous advancement of technology, the performance of Z-130 catalyst will be further improved and its application scope will be wider.

5.1 Technological Innovation

In the future, the production process of Z-130 catalyst will be continuously optimized to further improve its catalytic efficiency and environmental performance. At the same time, the research and development of new catalysts will also provide more options for the construction of large bridges.

5.2 Application Expansion

In addition to large-scale bridge construction, Z-130 catalyst can also be used in other infrastructure construction fields, such as tunnels, airports, ports, etc. Its environmental characteristics and high efficiency will bring significant advantages to construction in these fields.

5.3 Policy Support

As the continuous strengthening of environmental protection policies, environmentally friendly materials such as Z-130 catalyst will receive more policy support. The government will encourage enterprises to adopt environmentally friendly materials through subsidies, tax incentives and other measures to promote the green development of the construction industry.

VI. Conclusion

The application of low viscosity odorless amine catalyst Z-130 in large bridge construction not only improves construction efficiency and material performance, also significantly reduces environmental pollution, has important environmental protection significance and economic benefits. In the future, with the continuous advancement of technology and policy support, the Z-130 catalyst will be widely used in more fields, making greater contributions to the green development of the construction industry.

Appendix: Comparison of the properties of Z-130 catalysts and other catalysts

parameter name	Z-130 Catalyst	Traditional Catalyst A	Traditional Catalyst B
Viscosity (25?)	50-100 mPa·s	200-300 mPa·s	150-250 mPa·s
Density (25?)	1.02-1.05 g/cm³	1.10-1.15 g/cm³	1.05-1.10 g/cm³
Flashpoint	>100?	>80?	>90?
odor	odorless	Have a irritating odor	There is a slight smell
Environmental	No VOC emissions	VOC emissions	VOC emissions
Applicable temperature range	-20? to 80?	-10? to 70?	-15? to 75?
Storage Stability	12 months	6 months	9 months

It can be seen from the comparison that the Z-130 catalyst is superior to traditional catalysts in terms of viscosity, density, flash point, odor, environmental protection, applicable temperature range and storage stability, and has significant advantages.

Summary

The application of low viscosity odorless amine catalyst Z-130 in large bridge construction not only improves construction efficiency and material performance, but also significantly reduces environmental pollution, which has important environmental protection significance.and economic benefits. In the future, with the continuous advancement of technology and policy support, the Z-130 catalyst will be widely used in more fields, making greater contributions to the green development of the construction industry.

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