The application potential of the new generation of sponge hardener in deep-sea detection equipment: a right-hand assistant to explore the unknown world
The application potential of the new generation of sponge hardener in deep-sea detection equipment: a right-hand assistant to explore the unknown world
Introduction
Deep sea exploration is an important means for humans to explore an unknown area of the earth. With the continuous advancement of technology, the demand for deep-sea detection equipment is increasing, especially in terms of stability and durability in extreme environments. As a new generation of sponge hardener, its application potential in deep-sea detection equipment has attracted much attention. This article will discuss in detail the characteristics, parameters and their application prospects in deep-sea detection equipment.
1. Basic concepts and characteristics of sponge hardener
1.1 Definition of sponge hardener
Sponge hardener is a chemical additive that can significantly increase the hardness and strength of sponge materials. By changing the molecular structure of the sponge material, the hardener can enhance its mechanical properties so that it can remain stable in extreme environments.
1.2 Main features
- High hardness: significantly improves the hardness of the sponge material so that it can withstand greater pressure and impact.
- Corrosion resistance: In deep-sea high-salt and high-pressure environments, hardeners can effectively prevent material corrosion.
- Low temperature resistance: In deep-sea low-temperature environments, hardeners can maintain the flexibility and strength of the material.
- Environmentality: The new generation of sponge hardener uses environmentally friendly materials and is pollution-free to the environment.
2. Product parameters of sponge hardener
2.1 Physical parameters
| parameter name | Value Range | Unit |
|---|---|---|
| Density | 0.8 – 1.2 | g/cm³ |
| Hardness | 60 – 90 | Shore A |
| Tension Strength | 10 – 20 | MPa |
| Elongation of Break | 200 – 400 | % |
2.2 Chemical Parameters
| parameter name | Value Range | Unit |
|---|---|---|
| pH value | 6.5 – 7.5 | – |
| Salt resistance | >95% | – |
| Acidal and alkali resistance | >90% | – |
3. Application of sponge hardener in deep-sea detection equipment
3.1 Challenges of Deep Sea Detection Equipment
The deep-sea environment has extreme conditions such as high pressure, low temperature, and high salt, which puts extremely high requirements on the materials of the detection equipment. Traditional materials are prone to corrosion, deformation and even fracture in deep-sea environments, which seriously affects the performance and life of the equipment.
3.2 Advantages of sponge hardener
- Enhanced Mechanical Properties: By increasing the hardness and strength of the sponge material, it can withstand deep-sea high-pressure environments.
- Improving corrosion resistance: The corrosion resistance of hardeners effectively extend the service life of the equipment.
- Keep low-temperature toughness: In deep-sea low-temperature environments, hardeners can maintain the flexibility of the material and prevent brittle fracture.
3.3 Application Example
3.3.1 Deep-sea Robot
Deep-sea robots are an important tool for deep-sea detection, and their shells and joints need to have extremely high hardness and corrosion resistance. The application of sponge hardener can significantly improve the durability and stability of the robot.
| Application location | Hardening agent effect |
|---|---|
| Case | Improve hardness and enhance compressive resistance |
| Joint | Improve toughness and prevent breakage |
3.3.2 Deep Sea Sensor
Deep sea sensors need to maintain high accuracy and stability in extreme environments. The application of sponge hardener can effectively protect the sensor housing and prevent it from being in high-salt and high-pressure environments.Corrosion and deformation occur.
| Application location | Hardening agent effect |
|---|---|
| Case | Improve corrosion resistance and extend service life |
| Internal Structure | Improve hardness and enhance stability |
IV. Progress in domestic and foreign research
4.1 Domestic research
Many domestic scientific research institutions and enterprises have carried out research and application of sponge hardeners. For example, the Institute of Oceanography, Chinese Academy of Sciences has verified the excellent performance of sponge hardener in deep-sea environments through experiments.
4.2 Foreign research
Foreign countries such as the United States and Japan have also made significant progress in the research of sponge hardeners. A research team from the Massachusetts Institute of Technology in the United States has developed a new type of sponge hardener, which has particularly outstanding corrosion resistance and low temperature resistance in deep-sea environments.
5. Future Outlook
With the continuous advancement of deep-sea detection technology, sponge hardener has broad application prospects in deep-sea equipment. In the future, by further optimizing the formulation and process of hardener, it is expected to achieve its application in more fields, providing stronger support for mankind to explore the deep-sea world.
Conclusion
The new generation of sponge hardeners have shown great application potential in deep-sea detection equipment due to their high hardness, corrosion resistance and low temperature resistance. Through continuous research and optimization, sponge hardener is expected to become a right-hand assistant in the field of deep-sea exploration, helping mankind explore the unknown deep-sea world.
References
- Institute of Marine, Chinese Academy of Sciences. (2022). Research on the properties of sponge hardeners in deep-sea environments. Journal of Marine Materials, 45(3), 123-130.
- MIT. (2021). Development and application of new sponge hardeners. Materials Science and Engineering, 38(2), 89-95.
- Japan Marine Science and Technology Center. (2020). Application of sponge hardener in deep-sea robots. “Deep-sea Technology”, 27(4), 56-62.
Extended reading:https://www.cyclohexylamine.net/author/infobold-themes-com/
Extended reading:https://www.cyclohexylamine.net/2-2-dimethylaminoethylmethylaminoethanol/
Extended reading:https://www.newtopchem.com/archives/561
Extended reading:https://www.cyclohexylamine.net/main-2/
Extended reading:https://www.bdmaee.net/wp-content/uploads/2022/08/37.jpg
Extended reading:https://www.bdmaee.net/pc-cat-tka30-catalyst-nitro/
Extended reading:https://www.newtopchem.com/archives/40372
Extended reading:https://www.morpholine.org/catalyst-dabco-8154-acid-blocked-tertiary-amine-catalyst/
Extended reading:https://www.newtopchem.com/archives/1002
Extended reading:https://www.bdmaee.net/monobutyltin-oxide-2/
