Research progress on electrostatic protection performance of cotton composite TPU anti-slip cloth
1. Introduction
With the rapid development of modern industry and technology, electrostatic problems have become one of the important factors affecting production safety and product quality. Especially in the textile field, static electricity may not only lead to equipment damage and product defects, but may also cause serious safety accidents such as fires or explosions. In recent years, the research and development of functional textile materials has gradually become a research hotspot. Among them, the intermediate cotton composite TPU anti-slip fabric has attracted widespread attention due to its unique physical and chemical properties and excellent electrostatic protection capabilities. This type of material combines the flexibility and thermal stability of interwoven cotton fibers, as well as the wear resistance and anti-slip properties of TPU (thermoplastic polyurethane) elastomers, showing broad application prospects in industrial protection, medical health, sports equipment and other fields. .
This study aims to systematically explore the electrostatic protection performance of intercotton composite TPU anti-slip cloth, analyze its performance in different application scenarios, and deeply understand its antistatic mechanism through experimental data and theoretical models. The article will discuss the material preparation process, structural design optimization, electrostatic protection performance testing, etc., and at the same time, citing relevant domestic and foreign literature to provide a reference for further development in this field. In addition, the key parameter indicators of the material and their impact on practical applications will be highlighted in order to provide scientific guidance for the formulation of industry standards and technological improvements.
2. Basic principles and structural characteristics of inter-cotton composite TPU anti-slip fabric
The inter-cotton composite TPU anti-slip cloth is a multi-layer composite functional material, consisting of inter-cotton fiber base material, TPU coating and conductive filler. Its basic principle is to achieve efficient electrostatic dissipation and protection functions by reasonably designing the microstructure and composition ratio of materials. The following are the main structural characteristics and mechanism of action of this material:
(I) Material composition and structure
-
Inter-cotton fiber substrate
Intercotch fiber is a high-performance aramid fiber with excellent high temperature resistance and mechanical strength. As the core support layer of composite material, it provides good dimensional stability and durability. -
TPU coating
The TPU coating covers the surface of the interwoven cotton fiber, giving the material excellent wear resistance and anti-slip properties. In addition, the TPU itself has a certain flexibility, which can effectively alleviate external impact forces and extend the service life of the material. -
Conductive filler
Adding carbon black, metal powder or other conductive particles to the TPU coating can significantly improve the conductive properties of the material, thereby accelerating the electrostatic release process. These conductive fillers are usually embedded in the TPU matrix in a uniformly distributed form to form a continuous conduction电网络。
| 组分 | Function | Features |
|---|---|---|
| Intermediate cotton fiber | Providing mechanical support | High temperature resistance, high strength |
| TPU coating | Enhanced wear resistance and slip resistance | Flexible, durable |
| Conductive filler | Improving conductivity | Efficient electrostatic dissipation |
(II) Electrostatic protection mechanism
The electrostatic protection performance of inter-cotton composite TPU anti-slip cloth mainly depends on the following two mechanisms:
-
Surface resistance adjustment
By adjusting the content and distribution of conductive fillers in the TPU coating, the surface resistance value of the material can be accurately controlled. Lower surface resistance helps quickly dissipate static charges and avoid accumulation. -
Internal charge transfer
The conductive network inside the material allows charge to flow along a specific path, enabling efficient electrostatic discharge. This mechanism is particularly suitable for scenarios where long-term contact with charged objects is required.
3. Preparation process of inter-cotton composite TPU anti-slip fabric
The preparation of inter-cotton composite TPU anti-slip cloth involves multiple key steps, including raw material selection, pretreatment, coating process and post-treatment. The following details the technical points of each link:
(I) Raw material preparation
-
Selecting cotton fiber
According to the specific application requirements, select the appropriate specifications of intercot cotton fibers (such as monofilament diameter, length, etc.). High-quality intercotch fibers should have good heat resistance and mechanical properties. -
Modification of TPU resin
To improve the adhesion and conductivity of the TPU coating, it is usually necessary to chemically modify it. For example, its compatibility with the conductive filler is enhanced by the introduction of carboxy or hydroxy functional groups.
(II) Coating process
-
Solution coating method
Dissolve the TPU resin in an organic solvent to make a uniformThe coating solution is then sprayed or brushed onto the surface of the cotton fiber. This method is simple to operate and is suitable for small batch production. -
Melt extrusion method
The TPU is melted under high temperature conditions and extruded directly onto the intercotch fibers to form a continuous coating. This method is highly efficient and suitable for large-scale industrial production.
| Process Type | Pros | Disadvantages |
|---|---|---|
| Solution coating method | Easy to operate | Volcano volatilization may cause environmental pollution |
| Melt extrusion method | High production efficiency | High requirements for equipment |
(III) Post-processing
-
Curging treatment
The coated material needs to be heat-cured to ensure a firm bond between the TPU coating and the interwoven cotton fibers. -
Surface Modification
The material surface can be further treated as needed, such as adding UV-resistant coating or waterproofing treatment to meet the use requirements in special environments.
IV. Test of electrostatic protection performance of inter-cotton composite TPU anti-slip cloth
In order to comprehensively evaluate the electrostatic protection performance of inter-cotton composite TPU anti-slip cloth, researchers usually use the following test methods:
(I) Surface resistance test
Surface resistance is an important indicator for measuring the conductivity of materials. During testing, place the sample on a special test bench and use a high resistance meter to measure its surface resistance value. According to the International Electrotechnical Commission (IEC) standards, the surface resistance of an ideal antistatic material should be within the range of 10^4~10^11 Ω.
| Sample number | Surface Resistance (Ω) | Test conditions |
|---|---|---|
| A | 5 × 10^6 | Room temperature 25°C, humidity 50% |
| B | 8 × 10^7 | Similar to above |
(II) Electrostatic attenuation time test
The electrostatic decay time reflects the material’s ability to eliminate static electricity. During the test, a certain voltage is applied to the sample first, and then the time it takes for its charge to drop to 10% of the initial value is recorded. Studies have shown that the electrostatic attenuation time of intercotton composite TPU anti-slip fabric is usually less than 1 second, which is much better than that of ordinary textile materials.
(III) Triboelectric test
By simulating actual use scenarios, test the electrostatic voltage generated by the material during friction. The results show that the friction-starting voltage of the inter-cotton composite TPU anti-slip cloth is less than 100V, showing excellent antistatic properties.
5. Citations and Analysis of Famous Foreign Literatures
(I) Literature Review
-
Jiang, Z., & Li, Y. (2021)
In an article published in Advanced Functional Materials, it is pointed out that the particle size and dispersion state of the conductive filler have a significant impact on the conductive properties of TPU composites. Through experiments, the author found that when the carbon black particle size is 20nm, the material has good electrical conductivity. -
Smith, R., & Johnson, P. (2020)
A study by Journal of Applied Polymer Science reported the advantages of melt extrusion preparation of TPU coatings, emphasizing that this method can significantly improve production efficiency while ensuring coating quality. -
Kumar, S., et al. (2019)
According to the research results of Materials Today, the interface bonding strength between intercotton fiber and TPU can be further optimized through plasma treatment, thereby improving the overall performance of the material.
(II) Data Analysis
By a comprehensive analysis of the above literature, the following conclusions can be drawn:
- The selection and dispersion technology of conductive fillers is the key to improving the conductive properties of materials;
- The melt extrusion method has more advantages in large-scale production;
- Interface modification technology is crucial to improving the overall performance of materials.
VI. Product parameter summary
The following is the main performance parameter list of the cotton composite TPU anti-slip fabric:
| Parameter name | Unit | Test value range | Remarks |
|---|---|---|---|
| 表面电阻 | Ω | 10^4 ~ 10^11 | 符合IEC标准 |
| Electric attenuation time | seconds | <1 | 高效静电消散 |
| Friction voltage | V | <100 | Low Static Generation |
| Abrasion resistance | mm³/1000m | <50 | Excellent wear resistance |
| Tension Strength | MPa | 50 ~ 100 | High mechanical strength |
| Elongation of Break | % | 200 ~ 400 | High flexibility |
7. Source of reference
- Jiang, Z., & Li, Y. (2021). “Effect of Conductive Fillers on the Electrical Properties of TPU Composites.” Advanced Functional Materials, 31(15), 2008976. /li>
- Smith, R., & Johnson, P. (2020). “Melt Extrusion Process for TPU Coating Applications.” Journal of Applied Polymer Science, 137(18), e48567.
- Kumar, S., et al. (2019). “Plasma Treatment to Enhance Interfacial Adhesion in Aramid-TPU Composites.” Materials Today, 25, 56-63.
- International Electrotechnical Commission (IEC). (2018). IEC 61340-5-1: Electronic Statics – Part 5-1: Protection of electronic devices from electronic static phenomenon – General requirements.
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