Silicone ring structure can produce many products that were previously unimaginable
Silicon is the second largest element on earth, and 28% of the earth's crust is silicon, present in sand, silicates and many minerals like quartz. The silicon atom and the oxygen atom are connected to form a long chain of the polymer, and the long chain forms a ring structure to synthesize a silicone resin. These polymers look like coils and have a buffer-like function1. Unlike other molecules, this coil can be crimped and coiled and can be unwinded under ambient conditions.
This crimped structure exists in a range of materials ranging from gaseous to brittle solids and can be fabricated in a wide variety of different viscosities, densities, structures and functions. The unique combination of properties of this coil inspires industrial production, creating many products that were previously unimaginable.
Unique performance
The unique properties of silicone cover a wide range of functions. The most noticeable is the excellent temperature resistance. The silicone resin remains stable at -90-330 °C. This fairly wide range contrasts with most organics, which begin to solidify above 0 °C and begin to fade and oxidize at 120 °C. Due to its inherent UV resistance and oxidation resistance, silicone is very weather resistant, making it ideal for outdoor use. Silicone does not fade and cleave over time as organics do.
Silicone's electrical insulation properties are close to that of glass products, so it is also perfect for use in electronic products. In addition, special ozone and corona resistance make it suitable for high pressure applications. Silicone provides good water resistance and water immersion stability, so they can be found in the field of underwater instruments. As a rubber, it is used in the field of gaskets and seals because of its high resistance to compression and deformation. Its own bonding ability is used for the conveyor belt of the oven for baking food, and it can also be used for the elastic mold of injection molding materials and low melting point alloys.
Silicone's exceptional UV resistance for high-energy lighting, instrumentation and solar installations. In the 1950s and 1960s, a large number of artificial heart problems were studied. Since then, the biocompatibility of silicone has begun to be used in a variety of implants, wound care and drug delivery systems. .


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