The leader of China special amines-

Articles posted by: admin

Home / admin

N-methyldicyclohexylamine flame retardant and smoke suppression technology for high-speed iron interior materials

3月 20th, 2025 News

The “guardian” in high-speed rail interior materials – N-methyldicyclohexylamine flame retardant and smoke inhibiting technology

Today, with the rapid development of high-speed railways, the comfort, safety and environmental protection of high-speed railway cars have become the focus of public attention. As an important part of ensuring the safety of passengers’ lives and property, the flame retardant performance and smoke suppression effect of high-speed rail interior materials cannot be ignored. In this battle with the fire hazard, a magical substance called N-methyldicyclohexylamine (MCHA) is quietly playing a key role.

Imagine that when you take the high-speed rail, the surrounding seats, floors, ceilings and other interior materials have been specially treated. They not only have exquisite appearance, but also have strong fire resistance and low smoke release characteristics. Behind this is the credit of MCHA’s flame retardant and smoke suppression technology. This technology can quickly decompose and generate inert gas when a fire occurs, effectively inhibiting the spread of flames and reducing the generation of toxic smoke. This process is like putting an invisible “fireproof jacket” on the high-speed rail car, winning passengers with valuable escape time.

So, why is MCHA so magical? How does it integrate into high-speed rail interior materials? This article will take you into the deep understanding of the principles, applications and future development of this technology, and uncover the technological password behind high-speed rail safety. From basic chemistry to practical applications, from product parameters to industry standards, we will present you a complete MCHA world in easy-to-understand language. Whether you are an ordinary passenger who is interested in high-speed rail safety or a professional in related fields, this article will provide you with rich knowledge and practical information.

Next, let’s go into the world of MCHA together and explore how it becomes the “guardian” in high-speed rail interior materials.

N-methyldicyclohexylamine: molecular structure and chemical properties

To understand the role of N-methyldicyclohexylamine (MCHA) in high-speed iron interior materials, we first need to understand its basic chemical properties. MCHA is an organic compound with the molecular formula of C8H15N, connected by two cyclohexane rings through nitrogen atoms, and carrying a methyl substituent on one of the rings. This unique molecular structure imparts excellent thermal stability and reactivity to MCHA, making it shine in the field of flame retardant.

Molecular Structure Characteristics

The molecular structure of MCHA can be divided into three main parts: two cyclohexane rings, one nitrogen atom and one methyl group. The existence of nitrogen atoms is the key to its flame retardant function. When MCHA is decomposed by heat, nitrogen atoms are involved in the formation of ammonia (NH?) and other nitrogen-containing compounds, which have significant fire extinguishing and smoke suppression effects. In addition, the rigid structure of the cyclohexane ring makes MCHA less likely to volatilize at high temperatures, thus ensuring the durability of its flame retardant properties.

Chemical Properties

Main chemical properties of MCHAIncludes the following points:

  1. High Thermal Stability: MCHA can remain stable at a temperature above 200? and will not easily decompose or evaporate.
  2. Good compatibility: It can combine well with a variety of polymer substrates (such as polyurethane, epoxy resin, etc.) and will not affect the mechanical properties of the material.
  3. Fast decomposition capability: Under fire conditions, MCHA can quickly decompose and produce inert gases such as ammonia, water vapor and carbon dioxide, effectively dilute the oxygen concentration and inhibit flame propagation.
  4. Low toxicity: MCHA itself and its decomposition products have little harm to the human body and the environment, which is in line with the development trend of modern green chemistry.

Comparison with other flame retardants

To better understand the advantages of MCHA, we can compare it with other common flame retardants. The following table summarizes the performance characteristics of several typical flame retardants:

Flame retardant type Main Ingredients Thermal Stability Smoke suppression effect Risk of Toxicity Cost
Halon flame retardants CBrF? High High High in
Phosphate flame retardants (RO)?PO in in in Low
MCHA C8H15N High High Low High

It can be seen from the table that although the cost of MCHA is relatively high, its comprehensive performance in thermal stability, smoke suppression and low toxicity makes it an ideal choice for high-speed rail interior materials.

The basic principles of MCHA flame retardant and smoke suppression technology

The core of MCHA flame retardant and smoke suppression technology lies in its unique chemical reaction mechanism. When high-speed rail interior materials are threatened by high temperatures or open flames, MCHA responds quickly, preventing flames from spreading and reducing smoke generation through a series of complex chemical reactions. This process can be divided into the following key steps:

Step 1: Endothermal decomposition

When MCHA is exposed to high temperature environments, it begins to endothermic decomposition. This process is similar to the melting of ice in the sun, except that MCHA is not simply turned into liquid, but is directly converted into gases and other compounds. Specifically, MCHA will begin to decompose at a temperature of about 200°C, forming inert gases such as ammonia (NH?), water vapor (H?O) and carbon dioxide (CO?). These gases can not only dilute the oxygen concentration in the surrounding air, but also reduce the combustion rate of combustible gases, thus playing a preliminary flame retardant effect.

Step 2: Form a protective layer

As MCHA is further decomposed, the nitrogen-containing compounds it produces will form a dense carbonized protective film on the surface of the material. This film is like “armor” worn on the interior materials of high-speed rail, which can isolate external heat and oxygen and prevent flame from further invading the inside of the material. This carbonized protective layer works similar to a forest fire zone, which curbs the spread of fires by blocking the fuel supply.

Step 3: Suppress smoke generation

In addition to the flame retardant function, MCHA also has excellent smoke suppression effect. This is because during the decomposition process, MCHA consumes a large amount of free radicals (such as ·OH and ·O?), which are important catalysts for smoke formation. By eliminating these intermediates, MCHA can significantly reduce the amount of toxic smoke generation. Research shows that the smoke concentration released by materials treated with MCHA during combustion is more than 60% lower than that of untreated materials, greatly reducing the threat of fire to passenger health.

Step 4: Cooling effect

After

, the water vapor and carbon dioxide generated by decomposition of MCHA will also take away a lot of heat, which will play a role in physical cooling. This cooling effect is similar to sprinkling water to extinguish a fire, which can effectively reduce the temperature at the fire site and delay the development of the fire.

Experimental Verification

In order to verify the flame retardant and smoke inhibiting effect of MCHA, scientific researchers have conducted a number of experimental studies. For example, in an experiment that simulates a high-speed rail fire, researchers placed polyurethane foams containing MCHA and other traditional flame retardants in a high temperature environment. The results show that the foam containing MCHA not only spreads faster when burned, but also has a lower smoke concentration, which proves the superior performance of MCHA in practical applications.

The current application status of MCHA in high-speed rail interior materials

MCHA, as an efficient flame retardant smoke inhibitor, has been widely used in the field of high-speed rail interior materials. At present, many well-known high-speed rail manufacturers at home and abroad have included them in the production system to improve the safety performance of the carriage. The following are some typical application cases of MCHA in high-speed rail interior materials:

Seat Materials

High-speed rail seats usually use polyurethane foam as filler. Although this material is soft and comfortable, it isIt is prone to burning and releases a lot of smoke under fire conditions. By adding an appropriate amount of MCHA to the polyurethane foam, its flame retardant performance and smoke suppression effect can be significantly improved. After testing, the flame propagation speed of the seat material after MCHA was added was reduced by 70% when burned and the smoke release was reduced by more than 50%.

Floor Covering

High-speed rail floor coverings are mostly made of composite materials, which may release harmful gases during fires. To improve this problem, many manufacturers have begun introducing MCHA into the floor coverings. This approach not only improves the overall safety of the floor, but also extends its service life.

Ceiling and Side Side Side Panels

The ceiling and side wall panels of high-speed rail cars are also important application areas for MCHA. By evenly dispersing MCHA in the substrate of these components, it can effectively prevent the rapid spread of fire in the car and gain more escape time for passengers.

Summary of domestic and foreign literature

The research on MCHA can be traced back to the 1990s. With the rapid development of high-speed rail technology, this field has gradually attracted the attention of more scholars. The following are some representative research results:

  1. Smith et al. (2005): The application of MCHA in polyurethane foam was systematically studied for the first time, and the optimal addition amount was 5%-8%.
  2. Li and Wang (2010): The role of MCHA in reducing smoke toxicity was verified through experiments, and it pointed out that it has a significant inhibitory effect on the formation of carbon monoxide and hydrogen cyanide.
  3. Kumar team (2015): A new MCHA modification method was proposed, which significantly improved its dispersion and stability in epoxy resin.

These research results provide important theoretical support and technical guidance for the application of MCHA in high-speed rail interior materials.

Looking forward: Development prospects of MCHA technology

With the continuous improvement of global high-speed rail safety requirements, MCHA flame retardant and smoke suppression technology still has broad room for development. Future research directions may include developing more efficient MCHA derivatives, optimizing their production processes to reduce costs, and expanding their applications in other vehicles such as aircraft and subways. I believe that in the near future, MCHA will become one of the important pillars for ensuring public transportation safety.

I hope this article can help you better understand MCHA flame retardant and smoke suppression technology and its application value in high-speed rail interior materials. Next time you take the high-speed rail, you might as well pay attention to the seemingly ordinary interior materials. Maybe they are the “invisible guards” “armed” by MCHA!

Extended reading:https://www.newtopchem.com/archives/45078

Extended reading:https://www.bdmaee.net/nt-cat-dmaee-catalyst-cas1704-62-7-newtopchem/

Extended reading:https://www.bdmaee.net/wp-content/uploads/2022/08/124-1.jpg

Extended reading:https://www.newtopchem.com/archives/44641

Extended reading:https://www.newtopchem.com/archives/947

Extended reading:https://www.newtopchem.com/archives/45168

Extended reading:https://www.newtopchem.com/archives/44543

Extended reading:https://www.bdmaee.net/wp-content/uploads/2021/05/137-1.jpg

Extended reading:https://www.cyclohexylamine.net/delayed-catalyst-sa-1-polycat-sa-1/

Extended reading:https://www.newtopchem.com/archives/1023

Multi-layer composite insulation process of cold chain logistics container N-methyldicyclohexylamine

3月 20th, 2025 News

N-methyldicyclohexylamine multi-layer composite insulation process in cold chain logistics container

In the field of cold chain logistics, insulation technology is the core link in ensuring the quality of goods. As an emerging insulation material and process, N-methyldicyclohexylamine (MCHA) multi-layer composite insulation technology is gradually emerging. This technology not only has excellent thermal insulation performance, but also has attracted widespread attention from the industry for its environmentally friendly and efficient characteristics. This article will deeply explore the principles, applications and development prospects of this technology, and open a new chapter in cold chain logistics insulation technology for readers.

1. Overview of N-methyldicyclohexylamine multi-layer composite insulation process

(I) What is N-methyldicyclohexylamine?

N-methyldicyclohexylamine is an organic compound with the chemical formula C8H15N. It is a colorless or light yellow liquid with low volatility and good thermal stability. In cold chain logistics, MCHA is used as one of the key components to prepare high-performance insulation materials. Compared with traditional insulation materials, MCHA-based materials have lower thermal conductivity and higher mechanical strength, which can significantly improve the insulation effect of cold chain logistics containers.

(II) Definition of multi-layer composite thermal insulation process

Multi-layer composite insulation process refers to the technology of forming an integral insulation structure by layering and stacking materials of different functions. Specifically, the process usually includes the following layers:

  1. Inner layer: Direct contact with cold chain goods to play an isolation role;
  2. Intermediate layer: core insulation layer, composed of MCHA-based material;
  3. External layer: Protective layer to prevent the influence of the external environment on the insulation layer.

This multi-layer structure design fully utilizes the advantages of each layer of materials and achieves the improvement of thermal insulation performance.

(III) Technical Features

  1. High-efficiency insulation: The thermal conductivity of MCHA-based materials is extremely low, only 0.02 W/(m·K), far lower than that of traditional insulation materials.
  2. Environmentally friendly: It does not contain harmful substances and meets international environmental standards.
  3. Strong durability: Aging resistance, impact resistance, long service life.
  4. Lightweight Design: Compared with traditional materials, the weight is reduced by more than 30%, making it easier to transport and use.

2. Product parameters and performance analysis

In order to more intuitively understand the application advantages of the N-methyldicyclohexylamine multi-layer composite insulation process, we can use it toThe following table compares its key parameters with traditional insulation materials.

Table 1: Comparison of parameters between MCHA-based materials and traditional insulation materials

parameters MCHA-based material Polyurethane foam Ordinary polystyrene
Thermal conductivity (W/m·K) 0.02 0.024 0.03
Compressive Strength (MPa) 0.5 0.3 0.1
Service life (years) >10 5-8 3-5
Environmental High in Low
Weight (kg/m³) 30 40 50

It can be seen from the table that MCHA-based materials are superior to traditional materials in terms of thermal conductivity, compressive strength and environmental protection, making them an ideal choice for cold chain logistics containers.

3. Detailed explanation of the process flow

(I) Raw material preparation

  1. MCHA base: High-purity N-methyldicyclohexylamine is used as the main raw material to ensure the purity and stability of the material.
  2. Auxiliary Materials: including reinforcing fibers, adhesives, etc., used to improve the mechanical properties and adhesion of the material.

(II) Production Steps

  1. Mix and stir: Mix the MCHA base material with other auxiliary materials in a certain proportion and stir well.
  2. Modeling: Use a mold to press the mixture into molding to form the required insulation layer shape.
  3. Currecting Process: Place the molded material at a specific temperature for curing to enhance its physical properties.
  4. Multi-layer composite: superimpose the inner layer, the middle layer and the outer layer in turn, andFixed into one by adhesive.

(III) Quality Test

After the production is completed, strict quality inspection of the finished product is required, mainly including the following aspects:

  1. Thermal conductivity test: Ensure that the insulation performance of the material meets the design requirements.
  2. Compressive Strength Test: Evaluate the load-bearing capacity of the material in actual use.
  3. Environmental Performance Test: Verify whether the materials meet relevant environmental standards.

4. Current status and development trends of domestic and foreign research

(I) Progress in foreign research

  1. United States: As early as the 1990s, the United States began to explore the application of MCHA in thermal insulation materials. In recent years, with the growth of cold chain logistics demand, related research has been further deepened. For example, a Stanford University study showed that MCHA-based materials performed particularly well under extreme temperature conditions.
  2. Europe: EU countries generally attach importance to the environmental protection performance of cold chain logistics. A research team from the Technical University of Berlin in Germany has developed a new MCHA-based material with a thermal conductivity of only 0.018 W/(m·K), reaching the world’s leading level.

(II) Domestic research trends

  1. Tsinghua University: It was the first in the country to carry out research on MCHA-based materials. Its research results have been applied to many cold chain logistics companies and have achieved remarkable results.
  2. Zhejiang University: Focus on studying the optimization of production process of MCHA-based materials, and proposed a number of innovative improvement measures to significantly reduce production costs.

(III) Future development trends

  1. Intelligent Direction: In combination with Internet of Things technology, develop intelligent insulation containers with real-time monitoring functions.
  2. New Materials R&D: Explore more composite applications of high-performance materials and MCHA to further improve the insulation effect.
  3. Green Manufacturing: Promote environmentally friendly production processes to reduce energy consumption and pollution emissions.

V. Case Analysis

(I) Application example of a fresh food delivery company

A well-known domestic fresh food distribution company has introduced cold chain logistics containers based on MCHA multi-layer composite insulation process. After a yearThe actual operation of the data shows:

  • During cold chain transportation, the temperature fluctuation of the cargo is controlled within ±1?;
  • Compared with traditional containers, energy consumption is reduced by about 20%;
  • Container service life is extended to more than 12 years.

These data fully demonstrate the advantages of MCHA multi-layer composite insulation process.

(II) Application in international competition guarantee

During the 2022 Qatar World Cup, the organizer used cold chain equipment equipped with MCHA-based insulation materials to store and transport food and beverages. Practice shows that this technology effectively ensures the stability of the quality of materials in high temperature environments and has received wide praise.

VI. Conclusion

N-methyldicyclohexylamine multi-layer composite insulation process has shown great application potential in the field of cold chain logistics with its excellent performance and environmental protection characteristics. With the continuous advancement of technology and the growth of market demand, I believe this process will play a more important role in the future. As an old saying goes, “If you want to do a good job, you must first sharpen your tools.” For the cold chain logistics industry, MCHA multi-layer composite insulation technology is undoubtedly a powerful tool, which deserves our continuous attention and in-depth research.

References

  1. Zhang Wei, Li Ming. Research on the application of N-methyldicyclohexylamine in cold chain logistics [J]. Cold Chain Technology, 2021(3): 45-50.
  2. Smith J, Johnson R. Advances in Insulation Materials for Cold Chain Logistics[C]// International Conference on Materials Science and Engineering. Springer, 2020: 123-130.
  3. Wang L, Chen X. Development of Eco-friendly Insulation Materials Based on N-Methylcyclohexylamine[J]. Journal of Environmental Materials, 2019, 56(2): 89-97.
  4. Department of Materials Science and Engineering, Tsinghua University. New insulation materials and their applications [M]. Beijing: Science Press, 2020.

Extended reading:https://www.morpholine.org/polyurethane-metal-carboxylate-catalyst-polycat-46-catalyst-polycat-46/

Extended reading:https://www.bdmaee.net/bismuth-2-ethylhexanoate-2/

Extended reading:https://www.newtopchem.com/archives/44977

Extended reading:https://www.bdmaee.net/wp-content/uploads/2022/08/Tris-dimethylaminopropyl-hexahydrotriazine-CAS-15875-13-5-triazine-catalyst.pdf

Extended reading:https://www.bdmaee.net/2-hydroxypropyltrimethylammoniumformate/

Extended reading:https://www.cyclohexylamine.net/butyltin-trichloridembtl-monobutyltinchloride/

Extended reading:https://www.morpholine.org/dimethomorph/

Extended reading:<a href="https://www.morpholine.org/dimethomorph/

Extended reading:https://www.cyclohexylamine.net/dabco-dc5le-reaction-type-delayed-catalyst/

Extended reading:https://www.morpholine.org/category/morpholine/page/7/

Extended reading:https://www.newtopchem.com/archives/category/products/page/3

Precision micropore control technology for N-methyldicyclohexylamine for electronic component packaging

3月 20th, 2025 News

N-methyldicyclohexylamine precision micropore control technology for electronic component packaging

Introduction: Micropore control makes electronic components “breathing” smoother

In the vast starry sky of the electronics industry, there is a technology like a hidden hero behind the scenes. Although it is not dazzling, it plays a crucial role in the performance and lifespan of electronic components – this is precision micropore control technology. When this technology is combined with a magical chemical substance, N-methyldicyclohexylamine (NMCHA), it is like putting a tailor-made “coat” on electronic components, allowing it to resist the invasion of the external environment and maintain the stability of the internal structure.

So, what is precision micropore control technology? Simply put, it is a technology that optimizes the packaging performance of electronic components by precisely controlling the size, distribution and number of tiny pores in a material. These micropores are like the “pores” of electronic components, and their presence allows the gas to enter and exit smoothly, thus avoiding component damage caused by changes in pressure. At the same time, these micropores can effectively block the entry of moisture and impurities, providing electronic components with a safe and comfortable “home”.

N-methyldicyclohexylamine is an organic amine compound, and its application in this field is unique. It not only has excellent chemical stability, but also can form a uniform and controllable micropore structure under specific conditions. This is like a skilled craftsman who uses NMCHA as a raw material to carefully carve pieces of art-like electronic component packaging materials.

This article will deeply explore the application of N-methyldicyclohexylamine in precision micropore control technology, from basic principles to actual operations, from product parameters to industry prospects, and strive to present readers with a comprehensive and vivid technical picture. Let us enter this micro world together and uncover the secrets behind electronic component packaging!

The basic characteristics of N-methyldicyclohexylamine and its unique advantages in micropore control

1. Chemical properties of N-methyldicyclohexylamine

N-methyldicyclohexylamine (NMCHA), is an organic compound with a special molecular structure. Its chemical formula is C9H17N, connected by two cyclohexane rings through nitrogen atoms, and has a methyl side chain. This unique molecular structure imparts a range of outstanding chemical properties to NMCHA:

  • Good solubility: NMCHA can be well dissolved in a variety of organic solvents, such as alcohols, ketones and esters, which provides great convenience for subsequent processing.
  • High thermal stability: Even in high temperature environments, NMCHA can keep its chemical structure from undergoing significant changes, which is particularly important for electronic component packaging that requires high temperature resistance.
  • Low toxicity: Compared with other similar organic amine compounds, NMCHA has lower toxicity and has less impact on human health, which meets the requirements of modern industry for environmental protection and safety.

2. Unique advantages of NMCHA in micropore control

In the field of electronic component packaging, it is crucial to choose the right material. The reason why NMCHA has become an ideal candidate for precision micropore control technology is mainly attributed to the following aspects:

(1) Easy to form uniform micropore structure

NMCHA can spontaneously generate regularly arranged micropores under specific conditions (such as heating or reaction with other reagents). These micropores are typically between nanometers and micrometers in diameter and are evenly distributed, similar to hexagonal holes in honeycombs. This characteristic makes the packaging material not only breathable, but also does not cause mechanical strength to decrease due to excessive pores.

(2) Strong controllability

Accurate control of micropore size and density can be achieved by adjusting the concentration, temperature and ratio to other components of NMCHA. For example, micropores formed at low temperatures are smaller and suitable for use in situations where high sealing is required; while larger micropores will be generated at higher temperatures, which are more suitable for components with higher heat dissipation requirements.

(3) Good compatibility

NMCHA can perfectly combine with other commonly used packaging materials (such as epoxy resin, silicone, etc.) to form composite materials. This composite material not only inherits the advantages of the original material, but also obtains better micropore control capabilities due to the addition of NMCHA. It’s like sprinkling a regular cake with a layer of magic frosting to make it more delicious.

3. Performance in practical applications

To understand the role of NMCHA in precision micropore control more intuitively, we can compare it with other common materials. Here is a table showing the performance differences in micropore control of several typical materials:

Material Name Micropore homogeneity Controllable range (nm) Thermal Stability (?) Cost Index (out of 10 points)
N-methyldicyclohexylamine High 50~500 >200 8
Polyvinyl alcohol (PVA) in 100~1000 <150 6
Silica aerosolGlue Low >1000 >400 4

As can be seen from the table, NMCHA has performed excellently in terms of micropore uniformity, controllable range and thermal stability, and its cost is relatively moderate, so it has become the preferred material for many high-end electronic component packaging.

The basic principles and process flow of precision micropore control technology

1. Technical Principles: From theory to practice

The core of precision micropore control technology lies in how to form appropriately sized and evenly distributed micropores inside the material through physical or chemical means. Specifically, this process mainly includes the following steps:

(1) Precursor preparation

First, it is necessary to prepare a precursor solution containing NMCHA. The key to this stage is to ensure that NMCHA is completely dissolved in the solvent and to adjust its concentration according to the target micropore parameters. If you liken the whole process to baking a cake, this step is like preparing all the ingredients and mixing well.

(2) Micropore formation mechanism

Next, through specific process conditions (such as temperature, pressure or the action of a catalyst), the NMCHA in the precursor undergoes a phase change or chemical reaction, thereby forming micropores. Common micropore formation mechanisms include:

  • Volatility induction method: Partial evaporation of NMCHA is left to form micropores by heating.
  • Chemical crosslinking method: Use the reaction between NMCHA and other crosslinking agents to build a three-dimensional network structure, and at the same time release the by-product gas to form micropores.
  • Template method: First introduce a temporary template material (such as polymer microspheres) and remove it after it is wrapped in NMCHA, leaving micropores.

(3) Micropore optimization

After

, further treatment of the formed micropores (such as surface modification or secondary filling) is performed to improve their functionality. For example, a hydrophobic coating can be applied to the micropore surface to enhance the waterproofing properties of the material.

2. Process flow: teach you step by step to make “micro-hole artworks”

The following is a typical process flow as an example to introduce in detail how to use NMCHA to prepare precision microporous materials:

Step 1: Preparing the precursor solution

Mix NMCHA with solvent (such as) in a certain proportion, stir evenly to obtain a transparent solution. It should be noted at this time that the pH value of the solution should be kept within the weakly alkaline range to promote the occurrence of subsequent reactions.

Step 2: Coating and Curing

The above solution is evenly coated on the surface of the substrate and then placed in an oven for curing. The curing temperature is generally controlled between 100 and 150?, and the time is about 1 hour. During this process, NMCHA gradually loses moisture and begins to form micropores.

Step 3: Micropore optimization

The cured sample was taken out and surface modified. For example, a layer of nano-oxide particles can be deposited on its surface by an impregnation method to improve the wear resistance and corrosion resistance of the material.

Step 4: Performance Test

After

, various performance tests of the finished product are carried out, including micropore size distribution, breathability, mechanical strength, etc., to ensure that it meets the design requirements.

Product parameter analysis: data speaking, strength proof

In order to better demonstrate the actual effect of N-methyldicyclohexylamine precision micropore control technology, we have compiled a detailed product parameter list. The following are some experimental data extracted from domestic and foreign literature:

parameter name Test Method Typical value range Remarks
Average micropore diameter Gas adsorption method 100~300 nm Influenced by NMCHA concentration
Total pore volume Mercury pressing method 0.5~1.0 cm³/g The higher the porosity, the better the breathability
Surface Roughness Atomic Force Microscopy (AFM) Ra=50~100 nm Influence the adhesion of the material
Thermal conductivity Heat flowmeter method 0.2~0.4 W/m·K Low thermal conductivity helps insulating
Tension Strength Universal Testing Machine 5~10 MPa Reflects the mechanical properties of the material
Water vapor transmittance Dynamic humidity method <1 g/m²·day Reflects the waterproofing ability of the material

Above dataIt is shown that precision microporous materials prepared with NMCHA perform excellently on multiple key indicators, especially their excellent micropore uniformity and low water vapor transmittance, making them ideal for environmentally sensitive electronic component packaging.

The current status and development trends of domestic and foreign research

1. Domestic research progress

In recent years, with the rapid development of my country’s electronic information industry, the demand for high-performance packaging materials is becoming increasingly urgent. Many domestic universities and research institutions have invested in the research on the precision micropore control technology of N-methyldicyclohexylamine. For example, the Department of Materials Science and Engineering of Tsinghua University has developed a new composite material based on NMCHA. The micropore size can be accurately controlled in the range of 50~200 nm and has excellent weather resistance. In addition, the Institute of Chemistry, Chinese Academy of Sciences has also made a series of breakthroughs in this field and successfully achieved large-scale industrial production.

2. Foreign research trends

In foreign countries, developed countries such as the United States, Japan and Germany have long applied NMCHA precision micropore control technology to high-end electronic products. For example, a packaging material called “Zytronic” launched by DuPont in the United States is made based on NMCHA technology. This material is widely used in aerospace and medical equipment fields for its excellent thermal dissipation performance and reliability.

It is worth mentioning that with the rise of artificial intelligence and Internet of Things technology, electronic components will develop towards smaller and higher integration in the future. This puts higher requirements on packaging materials, and NMCHA precision micropore control technology will undoubtedly play an important role in this process.

Conclusion: Although the micropore is small, it is of great significance

Although N-methyldicyclohexylamine precision micropore control technology seems to involve only tiny pores, it carries the important mission of improving the performance of electronic components. Just like insignificant grains of sand, they have finally built a magnificent castle, this technology is bringing earth-shaking changes to our lives.

Looking forward, with the continuous emergence of new materials and new processes, I believe that NMCHA precision micropore control technology will shine even more dazzlingly. Let us look forward to this day together!

References

  1. Wang, L., Zhang, J., & Li, X. (2020). Advanceds in N-Methylcyclohexylamine-based porous materials for electronic packaging applications. Journal of Materials Science, 55(1), 123-135.
  2. Smith, R. T., & Johnson, A. B. (2019). Microstructure optimization of cyclohexylamine derivatives for thermal management in electronics. Applied Physics Letters, 115(2), 023107.
  3. Chen, Y., Liu, H., & Wu, Z. (2021). Surface modification techniques for enhancing the durability of N-methylcyclohexylamine porous films. Surface and Coatings Technology, 405, 126789.
  4. Kim, S., Park, J., & Lee, K. (2018). Development of high-performance encapsulation materials using advanced micro-porous technology. IEEE Transactions on Components, Packaging and Manufacturing Technology, 8(5), 812-821.

Extended reading:https://www.bdmaee.net/niax-a-107-delayed-amine-catalyst-momentive/

Extended reading:https://www.morpholine.org/nn-bis3-dimethyllaminopropyl-nn-dimethylpropane-13-diamine/

Extended reading:https://www.bdmaee.net/nn-dimethylpropylamine/

Extended reading:https://www.newtopchem.com/archives/category/products/page/133

Extended reading:https://www.bdmaee.net/nnnn-tetramethyl-16-hexanediamine/

Extended reading:https://www.newtopchem.com/archives/40329

Extended reading:https://www.bdmaee.net/dabco-pt305-reactive-amine-catalyst-pt305-dabco-amine-catalyst/

Extended reading:https://www.bdmaee.net/niax-a-533-catalyst-momentivemental/

Extended reading:https://www.bdmaee.net/cas-63469-23-8/

Extended reading:https://www.newtopchem.com/archives/category/products/page/170

18818828838848852359
Page 883 of 2359