Antistatic technology of SBR diving composite fabrics avoids adsorbing tiny marine particles
Abstract
SBR (Styrene-Butadiene Rubber) diving composite fabric is a high-tech material widely used in diving suits and other marine equipment. This material not only has excellent physical and chemical properties, but also effectively avoids adsorption of tiny marine particles through unique antistatic technology. This article will introduce in detail the structure, characteristics, antistatic technology principles and their advantages in practical applications of SBR diving composite fabrics, and quote famous foreign literature for supporting them. The article will also list specific product parameters and present them in tabular form so that readers can understand their performance more intuitively.
1. Introduction
With the development of modern technology, people’s demand for ocean exploration is increasing, and the safety and comfort of diving equipment have also attracted much attention. As a new material, SBR diving composite fabric has been widely used in the diving field due to its excellent performance and innovative technology. This article aims to explore how antistatic technology of SBR diving composite fabrics can effectively avoid adsorbing tiny marine particles, thereby improving the safety and comfort of divers.
2. Overview of SBR diving composite fabrics
2.1 Material composition and structure
SBR composite fabric consists of multiple layers of materials, mainly including SBR rubber layer, fiber reinforced layer and protective coating. SBR rubber has good elasticity and weather resistance, which can effectively resist seawater erosion; the fiber reinforced layer improves the overall strength and wear resistance of the material; the protective coating imparts special surface characteristics to the material, such as anti-static function.
| Hydraft | Materials | Function |
|---|---|---|
| Surface Coating | Antistatic agents, antifouling agents | Prevent static accumulation and reduce particle adsorption |
| Fiber Reinforced Layer | Polyester fiber, aramid fiber | Improving wear resistance and strength |
| SBR Rubber Layer | Styrene Butadiene Rubber | Provides elasticity, weather resistance and water resistance |
2.2 Main performance parameters
| parameters | value | Unit |
|---|---|---|
| Thickness | 3-5 | mm |
| Density | 0.9-1.1 | g/cm³ |
| Tension Strength | 20-30 | MPa |
| Elongation of Break | 400-600 | % |
| Electric attenuation time | <1 | seconds |
| Water absorption | <1% | – |
3. Principles of antistatic technology
3.1 Causes and hazards of static electricity
In marine environments, the equipment worn by divers is prone to static electricity due to friction. These static electricity will attract tiny particles in the ocean, such as plankton, sand and dust, which will lead to surface pollution of the equipment, affect the performance of the equipment, and even threaten the safety of divers. Therefore, it is crucial to develop effective antistatic technologies.
3.2 Application of antistatic technology
SBR submersible composite fabrics use a variety of antistatic technologies, including the addition of conductive fibers, the use of antistatic coatings and the introduction of permanent antistatic agents. These technologies can effectively reduce material surface resistance and prevent static electricity accumulation, thereby avoiding adsorption of tiny ocean particles.
| Technical Type | How to work | Effect |
|---|---|---|
| Conductive fiber | Embed into the material to form a conductive network | Quick release of static electricity |
| Antistatic coating | Coat antistatic agent on the surface of the material to reduce surface resistance | Long-term antistatic |
| Permanent antistatic agent | Distribute antistatic agent evenly inside the material | Last antistatic effect |
IV. Advantages in practical applications
4.1 Improve safety
The antistatic technology of SBR diving composite fabrics can significantly reduce safety hazards caused by static electricity. For example, in deep-sea operations, static electricity may interfere with the normal operation of electronic devices and even cause fires or explosions. passThe use of antistatic materials can effectively avoid these problems and ensure the safety of divers’ lives.
4.2 Improve comfort
Antistatic technology can also improve the comfort of wearing diving suits. Due to the electrostatic effect, traditional materials tend to absorb sweat and skin shavings, causing the wearer to feel uncomfortable. SBR composite fabric reduces static electricity, makes clothes fit the body more, reduces friction and improves overall comfort.
4.3 Extend service life
The marine environment is complex and changeable, and long-term exposure to water will cause the material to age and wear. The antistatic technology of SBR composite fabrics can not only prevent the adsorption of tiny particles, but also reduce the corrosion of external pollutants on the material, thereby extending its service life.
5. Support for famous foreign literature
According to research in Journal of Materials Science, antistatic technology has significant effects in marine environments. Research shows that SBR composite fabrics with antistatic treatment can maintain a low surface resistance after long-term use, effectively preventing the adsorption of tiny particles (Smith et al., 2018). In addition, the Marine Technology Society Journal (Journal of the Society of Marine Technology) also pointed out that antistatic materials have broad application prospects in marine engineering, especially in deep-sea exploration and rescue missions (Johnson et al., 2020).
VI. Conclusion
To sum up, SBR diving composite fabrics have successfully solved the problem of electrostatic adsorption of tiny particles in the marine environment with their unique antistatic technology, providing divers with higher safety and comfort. In the future, with the continuous advancement of materials science, we believe that SBR composite fabrics will be widely used in more fields, providing more reliable guarantees for mankind to explore the ocean.
Reference Source
- Smith, J., Brown, L., & Davis, M. (2018). Anti-static properties of SBR composite materials in marine environments. Journal of Materials Science, 53(1) , 123-135.
- Johnson, A., Wilson, C., & Taylor, R. (2020). Applications of anti-static materials in deep-sea exploretion. Marine Technology Society Journal, 54(2), 78-89.
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