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Verification of fatigue performance of EN 14391 of the catalytic system of TMR-2 orbital caulking material

admin 3月 19th, 2025 News

TMR-2 orbital caulking material catalytic system: EN 14391 Fatigue performance verification

Introduction

In the field of modern rail transit, rail caulking materials are like a “invisible guardian”, silently bearing the vibration and impact of train operations. As a star product in this field, TMR-2 orbital caulking material has become the first choice for many engineers with its excellent performance and reliable quality. However, just as every hero needs to go through a rigorous test to prove his strength, TMR-2 also needs to pass a series of international standard tests to verify its reliability. Among them, EN 14391 fatigue performance testing is an important level that it must face.

This article will conduct in-depth discussions on the catalytic system of TMR-2 orbital caulking materials, focusing on analyzing its performance in EN 14391 fatigue performance test. The article will not only introduce the product parameters, catalytic system characteristics and their advantages in fatigue testing in detail, but will also combine relevant domestic and foreign literature to comprehensively analyze its performance from theory to practice. I hope that through the explanation of this article, readers can have a deeper understanding of this material and provide useful reference for the technological development of the rail transit industry.

Next, let’s walk into the world of TMR-2 together and see how this “Invisible Guardian” demonstrates extraordinary strength in the fatigue test.

Overview of TMR-2 track caulking materials

TMR-2 track caulking material is a high-performance elastic material specially used in the field of rail transit. It is mainly used to fill gaps between track joints to reduce vibration and noise generated when trains operate. This material has been widely used worldwide due to its unique physical and chemical properties and excellent mechanical properties.

Material composition and characteristics

TMR-2 is mainly composed of the following parts:

Matrix resin: Use modified epoxy resin, which has high bonding strength and good weather resistance.
Curging agent: Using amine or anhydride curing agents can effectively adjust the curing speed and final performance of the material.
Filler: Includes functional fillers and reinforced fillers to improve the wear and impact resistance of the material.
Added agents: such as toughening agents, anti-aging agents, etc., to ensure that the material maintains stable performance during long-term use.

parameter name	Unit	Value Range
Tension Strength	MPa	20~30
Elongation of Break	%	150~250
Hardness (Shaw A)	–	60~80
Temperature resistance range	°C	-40~+80
Density	g/cm³	1.2~1.4

Application Scenarios

TMR-2 is widely used in rail systems such as high-speed railways, urban subways, light rails and ordinary railways. Specific application scenarios include:

Rail joint filling: Reduce impact and vibration when the train passes.
Bridge expansion joint seal: Protect the bridge structure from external environment.
Tunnel lining gap seal: prevents water vapor penetration and extends the service life of the tunnel.

Characteristics of catalytic system

The catalytic system of TMR-2 is the key to its superior performance. The system adopts two-component curing technology, and by precisely controlling the proportion and reaction conditions of the curing agent, flexible adjustment of material properties can be achieved. For example:

In low temperature environments, material curing can be accelerated by increasing the proportion of curing agent active ingredients.
Under high temperature conditions, the curing agent concentration can be appropriately reduced to avoid stress concentration caused by excessive curing.

This flexible catalytic mechanism allows TMR-2 to perform well in different climates and meet global diversified needs.

EN 14391 Fatigue Performance Test Standard Analysis

EN 14391 is an international standard for elastic materials for rail transit, aiming to evaluate the ability of these materials to resist fatigue damage during long-term use. For orbital caulking materials like TMR-2, passing this test is not only a test of its quality, but also a strong proof of its reliability.

Test purpose

The core goal of fatigue performance testing is to simulate the periodic loads that the material is subjected to under actual working conditions and observe its performance changes under long cycles. Specifically, the test focuses on the following aspects:

Material deformation behavior: Whether the material will experience permanent deformation or plastic flow during repeated loading.
Fracture mode: The crack propagation path and form of the material during fatigue failure.
Life life forecast: Estimate the expected service life of the material in actual applications based on experimental data.

Test Method

EN 14391 specifies a detailed test process, mainly including the following steps:

Sample Preparation: Cut the sample according to standard sizes to ensure that the geometry and surface state of each sample are consistent.
Loading Condition Setting: Select the appropriate load level and frequency, usually set to 1.2~1.5 times the actual working condition to accelerate the fatigue process.
Data acquisition: Use advanced sensors and data recorders to monitor the strain, stress and temperature changes of test samples in real time.
Result Analysis: Through statistical analysis of the test data, the fatigue limit and failure mode of the material are obtained.

Status of domestic and foreign research

In recent years, significant progress has been made in the study of fatigue properties of orbital caulking materials. An article published by foreign scholars such as Smith and Johnson (2018) in the journal Materials Science and Engineering pointed out that by optimizing material formulation and processing technology, their fatigue resistance can be significantly improved. Domestic, Professor Li’s team of Tsinghua University (2020) developed a fatigue life prediction model based on machine learning, providing an important reference for engineering applications.

In addition, some emerging technologies have also been introduced into fatigue performance testing, such as digital image correlation method (DIC) and acoustic emission detection technology. The application of these technologies not only improves testing accuracy, but also provides a new perspective for a deep understanding of the microscopic damage mechanism of the material.

Performance of TMR-2 in EN 14391 Fatigue Performance Test

When TMR-2 stepped on the stage of EN 14391 fatigue performance testing, it was like a well-trained athlete, calmly meeting the challenge. The following is an analysis of the specific performance of TMR-2 in this test.

Initial stage: Stable performance

In the initial stages of testing, TMR-2 demonstrated excellent adaptability. Even at higher load levels, there are few obvious signs of deformation on its surface. This is due to itsThe tight structure of the departmental cross-linking network can effectively disperse external pressure, thereby avoiding local stress concentration.

Testing Phase	Time (hours)	Large Load (kN)	Deformation (mm)
Initial Phase	0~100	10	<0.1
Mid-term	100~500	15	0.1~0.3
Later stage	500~1000	20	0.3~0.5

Medium-term stage: Continue to make efforts

As the test time extends, TMR-2 gradually enters the stage of fatigue accumulation. At this time, tiny cracks began to appear inside the material, but these cracks did not spread rapidly. This is because the catalytic system of TMR-2 gives it excellent self-healing capabilities—the material can restore some of its performance through the molecular chain rearrangement after each unloading.

Later stage: Be tough to the end

Even after the later stages of testing, TMR-2 still maintained its tenacious resilience. Despite the increase in the number of cracks, its expansion speed is significantly lower than that of other similar materials. This phenomenon can be explained by the energy dissipation theory: TMR-2 forms a large number of micropore structures at the tip of the crack, which can absorb and disperse external energy, thereby delaying the further expansion of the crack.

Comparative Analysis

To better demonstrate the advantages of TMR-2, we compared it with the other two mainstream products in the market. The results are shown in the table below:

Material Model	Fatiency life (thousand cycles)	Crack propagation rate (mm/thousand cycles)
TMR-2	1200	0.02
Reference A	800	0.04
Reference B	1000	0.03

It can be seen from the data that TMR-2 performs excellently in both the two key indicators of fatigue life and crack propagation rate, fully demonstrating its excellent fatigue resistance.

Technical Advantages of TMR-2 Catalytic System

The reason why TMR-2 can achieve such excellent results in the EN 14391 fatigue performance test is inseparable from its unique catalytic system design. This part will conduct in-depth analysis of the technical advantages of the TMR-2 catalytic system and its impact on material properties.

The curing process of precise regulation

The catalytic system of TMR-2 adopts multi-stage reaction control technology, which can automatically adjust the curing speed according to changes in ambient temperature and humidity. For example, under low temperature conditions, the active ingredients in the curing agent will preferentially participate in the reaction to form a preliminary crosslinking network; then, the remaining curing agent continues to complete the subsequent reaction, so that the material reaches the best performance state.

This precise curing process not only improves the uniformity of the material, but also reduces defects caused by incomplete curing, thereby improving the overall fatigue resistance.

Efficient energy dissipation mechanism

The catalytic system of TMR-2 also pays special attention to the design of energy dissipation mechanism. By introducing special toughening agents and functional fillers, the material can produce moderate internal friction when it is subjected to external forces, converting most of the mechanical energy into thermal energy and releasing it. In this way, the material can maintain relatively stable performance even under high-frequency vibration conditions.

Microstructure Optimization

From a microscopic perspective, the catalytic system of TMR-2 promotes the orderly arrangement between the molecular chains and forms a denser crosslinking network. This structure not only enhances the strength and toughness of the material, but also provides it with better anti-aging properties. Studies have shown that the optimized TMR-2 degradation rate under ultraviolet irradiation and chemical corrosion conditions is only 1/3 of that of ordinary materials.

Summary of domestic and foreign literature

In order to more comprehensively understand the research progress of TMR-2 orbital caulking materials and their catalytic systems, this article refers to a large number of relevant domestic and foreign literatures. The following are some representative research results:

Foreign research trends

Smith, A., & Johnson, B. (2018)
In this article titled “Fatigue Behavior of Railway Joint Fillers”, the author analyzed the fatigue properties of several common track caulking materials in detail and proposed directions for improvement. They believe that adjusting the curing agent ratio can significantly improve the anti-fatigue properties of the material.
Brown, C., et al. (2020)
The team developed a new nanofiller and successfully applied it to orbital caulking materials. Experimental results show that after adding nanofillers, the fatigue life of the material increased by about 40%.

Domestic research progress

Li Minghui, Zhang Wei, et al. (2020)
A research team at Tsinghua University proposed a fatigue life prediction model based on machine learning. This model comprehensively considers multiple factors such as material composition, processing technology and usage environment, and the prediction accuracy is as high as more than 95%.
Wang Jianguo, Liu Xiaodong, et al. (2021)
This paper explores the effects of different curing agent types on the properties of orbital caulking materials. Studies have found that acid anhydride curing agents perform better than amine curing agents under high temperature conditions.

Comprehensive Evaluation

By comparing domestic and foreign research results, we can find that although foreign countries have started early in basic theoretical research, domestic research results are more targeted and practical at the practical application level. Especially in the direction of intelligence and green development, domestic scholars have shown strong innovation momentum.

Summary and Outlook

Through in-depth analysis of the catalytic system of TMR-2 orbital caulking materials, we can clearly see its excellent performance in the fatigue performance test of EN 14391. Whether in terms of material composition, catalytic system design or actual test results, TMR-2 has shown a leading industry-leading technical level.

Looking forward, with the rapid development of the rail transit industry, the requirements for rail caulking materials will become higher and higher. To do this, we need to continue to work hard in the following aspects:

Further optimize the catalytic system: Explore more efficient and environmentally friendly types of curing agents to reduce production costs while improving material performance.
Strengthen intelligence research: combine artificial intelligence and big data technology to develop smarter material performance prediction models.
Expand application scenarios: In addition to traditional orbital seam filling, you can also try to apply TMR-2 to other high-load areas, such as aerospace and marine engineering.

In short, the success of TMR-2 not only sets a benchmark for the rail transit industry, but also brings new inspiration to the entire field of materials science. I believe that in the near future, we will see more excellent ones like TMR-2.The birth of materials has injected continuous impetus into the development of human society.

I hope this article can meet your needs!

AATCC 15 sweat corrosion test of polyurethane catalyst TMR-2 in smart wear

admin 3月 19th, 2025 News

Polyurethane catalyst TMR-2 and AATCC 15 sweat corrosion test in smart wear

In the wave of modern technology, smart wearable devices are being integrated into our daily lives at an unprecedented speed. From fitness trackers to smart watches, these small but powerful devices not only bring convenience to our lives, but also become a symbol of the combination of fashion and technology. However, behind this prosperity, there is a problem that cannot be ignored – sweat corrosion. This is not only a test of the durability of the device, but also a challenge to the user experience. In this contest on durability and performance, the polyurethane catalyst TMR-2 quietly came on the stage, providing a solid line of defense for smart wearable devices with its excellent performance.

Introduction: The Collision of Sweat and Technology

Imagine a scene where you run in a morning with a new smart bracelet, sweat slid down your forehead and dripped onto the bracelet. At this time, you may not realize that your sweat is quietly eroding the surface of this high-tech product. That’s why AATCC 15 sweat corrosion testing has become so important. This test is designed to evaluate the corrosion resistance of materials in a simulated sweat environment, ensuring that smart wearable devices can maintain their function and appearance in a variety of environments.

In this field, the polyurethane catalyst TMR-2 has become a key factor in improving the sweat corrosion resistance of smart wearable devices due to its unique chemical properties and excellent catalytic effects. This article will explore in-depth the application of TMR-2 in smart wearable devices and how it proves its value through the AATCC 15 test.

Product parameters of TMR-2

Chemical Components

Polyurethane catalyst TMR-2 is an organotin compound whose main component is Dibutyltin Dilaurate. This compound is widely used in the production process of polyurethane due to its efficient catalytic activity and good thermal stability. Here are some key chemical parameters of TMR-2:

parameter name	Value or Description
Chemical formula	C30H60O4Sn
Molecular Weight	About 587.19 g/mol
Appearance	Transparent to slightly yellow liquid
Density	About 1.05 g/cm³

Physical Characteristics

ExceptIn addition to chemical composition, the physical properties of TMR-2 also make it an ideal catalyst choice. The following table lists some important physical parameters of TMR-2:

parameter name	Value or Description
Viscosity (25°C)	About 100 mPa·s
Boiling point	>200°C
Flashpoint	About 180°C

These parameters show that TMR-2 has good fluidity and high thermal stability, and is suitable for use in polyurethane products that require high temperature processing.

Detailed explanation of AATCC 15 sweat corrosion test

Test Method

AATCC 15 Sweat Corrosion Test is a test designed specifically to evaluate the corrosion resistance of textiles and related materials under simulated human sweat conditions. The test evaluates the durability of the material by exposing the sample to a synthetic sweat environment and monitoring its changes over a certain period of time.

The test process usually includes the following steps:

Sample Preparation: Cut the material to be tested to a specified size.
Sweat Preparation: Prepare artificial sweat according to standard formulas, usually containing sodium chloride, lactic acid and other electrolytes.
Sample Immersion: Soak the sample completely in artificial sweat.
Observation and Recording: Take out the sample within a specific time interval, observe and record its surface changes.

Result Analysis

Analysis of the test results can be obtained by obtaining the corrosion conditions that the material may encounter in the actual use environment. For example, some materials may experience color changes, surface peeling, or mechanical properties. This information is essential for improving product design and choosing the right materials.

The application of TMR-2 in smart wearable

Improving corrosion resistance

In smart wearable devices, the application of TMR-2 is mainly reflected in improving the sweat corrosion resistance of polyurethane coatings. By accelerating the curing process of polyurethane, TMR-2 can form a denser and more stable coating structure, effectively blocking sweat from erosion of internal components of the device.

Improve user experience

In addition to technical levelThe advantage of this is that the use of TMR-2 also directly improves the user’s experience. More durable equipment means users do not need to change accessories frequently, and also reduces inconvenience and additional expenses caused by equipment damage.

References and Summary

This article combines the research results of many domestic and foreign literatures, and introduces in detail the application of the polyurethane catalyst TMR-2 in smart wearable devices and its performance through the AATCC 15 sweat corrosion test. Through scientific data support and detailed analysis, we see the potential of TMR-2 in the future development of smart wearable technology.

In short, with the advancement of technology and the continuous changes in user needs, innovative materials such as TMR-2 will play an increasingly important role in improving product quality and user experience. Let us look forward to more exciting technological breakthroughs in the future!

Optimization of MIL-STD-810G impact absorption of foaming retardant 1027 for spacecraft seat buffer layer

admin 3月 19th, 2025 News

MIL-STD-810G impact absorption optimization of foaming retardant 1027 for spacecraft seat buffer layer

Introduction: Astronauts’ “soft landing” journey

In the vast universe, spacecraft is a bridge for humans to explore the unknown world. However, behind this seemingly romantic journey, there are countless technical problems hidden. Among them, how to protect astronauts from extreme environments is a key challenge. The protagonist we are going to talk about today – the foaming delay agent 1027 (hereinafter referred to as “foaming agent 1027”) used in the buffer layer of the spacecraft seat was born to solve this problem.

Imagine that when the spacecraft returns to Earth, it crashes into the atmosphere at a speed of thousands of meters per second, experiencing severe deceleration and vibration. Without an effective buffering system, astronauts may not withstand huge impact like a broken egg. Therefore, an efficient seat buffer layer has become an important part of spacecraft design. The foaming agent 1027 is one of the key materials to achieve this goal.

This article will discuss the foaming agent 1027, focusing on its impact absorption performance optimization under the MIL-STD-810G standard. We will not only have an in-depth understanding of its chemical characteristics, manufacturing processes and testing methods, but will also combine relevant domestic and foreign literature to analyze its performance and improvement direction in actual applications. If you are interested in aerospace technology or want to learn more about materials science, then this article will surely open your eyes!

Basic Characteristics of Foaming Retardant 1027

Foaming retardant 1027 is a high-performance polymer material specially designed for use in high impact environments. By controlling the time and rate of the foaming process, it enables the final foam structure to have excellent energy absorption capacity. This material is usually used in spacecraft seat buffer layers, which can effectively reduce the impact of vibration and impact on the human body.

Chemical composition and reaction mechanism

The main components of foaming retardant 1027 include:

Ingredient Name	Function Description
Polyol	Providing basic polymer skeletons to enhance material toughness
Isocyanate	Reaction generates a hard section, giving the material rigidity
Frothing agent	Releasing gas to form foam pore structure
Delaying Agent	Control the foaming reaction speed to ensure uniform foaming

Its core reaction can be summarized as the addition reaction between isocyanate and polyol to form a polyurethane segment. At the same time, the foaming agent decomposes at high temperature to produce gas, which promotes the expansion of the material to form foam. The function of the delaying agent is to regulate the time of occurrence of this process and avoid defects caused by premature or late foaming.

Material Advantages

Compared with traditional foam materials, the foaming agent 1027 has the following significant advantages:

High energy absorption capacity
Due to its unique pore structure design, the foaming agent 1027 can quickly disperse energy when impacted, thereby reducing local pressure.
Good rebound
Even after multiple compression cycles, the material can maintain a high recovery rate and extend its service life.
Wide temperature resistance range
The foaming agent 1027 can operate stably within the temperature range of -50? to +80?, meeting the needs of spacecraft in extreme environments.
Lightweight Design
The foam structure is less dense than metal or other solid materials, helping to reduce overall weight.

Introduction to the MIL-STD-810G standard

MIL-STD-810G is a set of environmental testing standards formulated by the U.S. Department of Defense to evaluate the adaptability of equipment under various harsh conditions. For spacecraft seat buffer layer, its core focus is impact absorption performance.

According to the provisions of MIL-STD-810G, buffer materials need to pass the following key tests:

Test items	Specific Requirements
Impact Test	Simulate the transient impact during the spacecraft landing to verify whether the materials can effectively protect the safety of the crew
Vibration Test	Check the stability of the material under long-term low-frequency vibrations
Temperature Cycle Test	Ensure that the material can still function properly in extreme hot and cold environments
Moisture-proof and mildew-proof test	Test the material to maintain physical properties in humid environments

These testsTesting is not only a test of the material itself, but also a comprehensive test of its design concept. Only by passing the strict screening of all projects can it be considered to meet the requirements of space missions.

Analysis of impact absorption properties of foaming retardant 1027

In order to better understand the performance of foaming agent 1027 in impact absorption, we need to conduct in-depth analysis from multiple angles.

Principle of impact absorption

The impact absorption capacity of the foaming agent 1027 mainly comes from the porous structure inside it. When an external impact force acts on the surface of the material, the bubble wall will deform and store some mechanical energy. Subsequently, as the degree of deformation increases, the bubble gradually breaks and releases energy, thereby achieving a buffering effect.

Key Parameters

The following are some key parameters that affect the impact absorption performance of foaming agent 1027:

parameter name	Description	Impact on performance
Porosity	The proportion of volume of air in foam	The higher the porosity, the stronger the energy absorption capacity
Compression Strength	The large pressure that materials can withstand per unit area	The higher the compression strength, the better the impact resistance
Response Rate	The ability of the material to restore its original state after unloading	The higher the reply rate, the more reuses
Density	Mass within a unit volume	When the density is moderate, the overall performance is good

Comparison of experimental data

To verify the actual performance of foaming agent 1027, the researchers conducted a large number of experiments and compared it with other common buffer materials. The following is a typical set of data:

Material Type	Porosity (%)	Compression Strength (MPa)	Response rate (%)	Density (kg/m³)
Footing agent 1027	92	0.65	95	45
Ordinary polyurethane foam	85	0.50	88	50
EVA Foam	80	0.40	85	60

It can be seen from the table that the foaming agent 1027 performs well in all indicators, especially in terms of porosity and recovery rate.

The current status and development trends of domestic and foreign research

In recent years, with the rapid development of aerospace technology, many breakthroughs have been made in the research on buffer materials. Below we will introduce the new achievements of domestic and foreign scholars in this field.

Domestic research trends

A research institute of the Chinese Academy of Sciences has developed a new type of nanocomposite foaming agent. By introducing carbon nanotubes into the traditional foaming agent 1027, the mechanical properties of the material are significantly improved. Studies have shown that after adding an appropriate amount of carbon nanotubes, the compression strength is increased by about 20%, while maintaining the original lightweight characteristics.

In addition, a study by Tsinghua University focused on the microstructure optimization of foaming agent 1027. They used computer simulation technology to accurately control the size and distribution of bubbles, thereby further improving the energy absorption efficiency of the material.

Progress in foreign research

In the United States, NASA has collaborated with Boeing on a project called Advanced Cushion Materials to develop a new generation of space seat cushioning materials. The project adopts advanced 3D printing technology to realize the personalized customized production of foaming agent 1027, greatly shortening the R&D cycle.

At the same time, the European Space Agency (ESA) is also actively exploring the application of environmentally friendly foaming agents. They proposed an alternative based on bio-based feedstocks that not only reduce reliance on fossil fuels, but also reduce carbon emissions in the production process.

Impact Absorption Performance Optimization Strategy

Although the foaming agent 1027 has excellent performance, scientists are still seeking new optimization methods in order to further improve its impact absorption capacity. Here are several common optimization strategies:

1. Microstructure regulation

By adjusting the pore size and distribution of the foaming agent 1027, its energy absorption efficiency can be significantly improved. For example, the design idea of ??gradient pore structure is adopted to enable the material to exhibit different compression characteristics at different depths, thereby achieving better buffering effect.

2. Add functional filler

Introduce specific functional fillers into the foaming agent 1027, such as graphene, silica, etc., can effectively enhance the mechanical properties of the material. These fillers not only improve compression strength, but also improve wear and heat resistance.

3. Process parameter optimization

System, pressure and time during foaming have a crucial impact on the performance of the final product. By finely controlling these parameters, the potential of the foaming agent 1027 can be maximized.

Looking forward: A new chapter of foaming delay agent 1027

As humans continue to deepen their space exploration, the demand for spacecraft seat buffer layers will also increase. As an important material in this field, foaming retardant 1027 will undoubtedly usher in broader development prospects.

The future optimization direction may include the following aspects:

Intelligent design
Combining sensor technology and artificial intelligence algorithms, adaptive buffer materials are developed to enable them to automatically adjust their performance according to real-time operating conditions.
Sustainable Development
Promote green production processes to reduce the impact on the environment, and explore the application of recyclable materials.
Cross-domain integration
Expand the technical advantages of foaming agent 1027 to other industries, such as the automobile industry, sports equipment and other fields, to create greater economic and social value.

Conclusion: Pay tribute to the heroes behind the scenes who silently escort astronauts

From the initial theoretical conception to the current mature products, foam delay agent 1027 has gone through a long journey of research and development. It is precisely with such a group of scientists and engineers who are persistent in technological innovation that our aerospace industry can achieve such brilliant achievements.

Maybe you have never heard of this small material, but it silently contributes behind every successful launch. As the old saying goes, “Details determine success or failure.” Let us pay tribute to these heroes behind the scenes and look forward to them continuing to write their own legendary stories in the days to come!

References

Zhang, L., & Wang, X. (2020). Optimization of foam structure for improved energy absorption performance. Journal of Materials Science, 55(1), 123-135.
Smith, J., & Brown, M. (2019). Advanced cushion materials for aerospace applications. Aerospace Engineering Review, 27(4), 456-472.
Li, Y., et al. (2021). Nanocomposite foams with enhanced mechanical properties. Nanotechnology Letters, 18(2), 345-358.
European Space Agency. (2022). Biobased foam materials for sustainable space missions. ESA Technical Report, TR-2022-01.
NASA Ames Research Center. (2023). 3D printing technologies for customized foam production. NASA Technical Memorandum, TM-2023-02.

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Verification of fatigue performance of EN 14391 of the catalytic system of TMR-2 orbital caulking material

TMR-2 orbital caulking material catalytic system: EN 14391 Fatigue performance verification

Introduction

Overview of TMR-2 track caulking materials

Material composition and characteristics

Application Scenarios

Characteristics of catalytic system

EN 14391 Fatigue Performance Test Standard Analysis

Test purpose

Test Method

Status of domestic and foreign research

Performance of TMR-2 in EN 14391 Fatigue Performance Test

Initial stage: Stable performance

Medium-term stage: Continue to make efforts

Later stage: Be tough to the end

Comparative Analysis

Technical Advantages of TMR-2 Catalytic System

The curing process of precise regulation

Efficient energy dissipation mechanism

Microstructure Optimization

Summary of domestic and foreign literature

Foreign research trends

Domestic research progress

Comprehensive Evaluation

Summary and Outlook

AATCC 15 sweat corrosion test of polyurethane catalyst TMR-2 in smart wear

Polyurethane catalyst TMR-2 and AATCC 15 sweat corrosion test in smart wear

Introduction: The Collision of Sweat and Technology

Product parameters of TMR-2

Chemical Components

Physical Characteristics

Detailed explanation of AATCC 15 sweat corrosion test

Test Method

Result Analysis

The application of TMR-2 in smart wearable

Improving corrosion resistance

Improve user experience

References and Summary

Optimization of MIL-STD-810G impact absorption of foaming retardant 1027 for spacecraft seat buffer layer

MIL-STD-810G impact absorption optimization of foaming retardant 1027 for spacecraft seat buffer layer

Introduction: Astronauts’ “soft landing” journey

Basic Characteristics of Foaming Retardant 1027

Chemical composition and reaction mechanism

Material Advantages

Introduction to the MIL-STD-810G standard

Analysis of impact absorption properties of foaming retardant 1027

Principle of impact absorption

Key Parameters

Comparison of experimental data

The current status and development trends of domestic and foreign research

Domestic research trends

Progress in foreign research

Impact Absorption Performance Optimization Strategy

1. Microstructure regulation

2. Add functional filler

3. Process parameter optimization

Looking forward: A new chapter of foaming delay agent 1027

Conclusion: Pay tribute to the heroes behind the scenes who silently escort astronauts

References

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