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The company is a company specializing in the production and processing of automatic four-column hydraulic press, diamond synthetic components, pyrophyllite blocks, magnesium oxide rings/cups, graphite tubes and other products, with a complete and scientific quality management system.


Liaocheng Xinke Pyrophyllite Co.,Ltd.

SINCE 2011

Plant Equipment
Plant Equipment
Plant Equipment
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Plant Equipment
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About Us
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Brand strength

Professional production and processing company, has a complete and scientific quality management system.

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Technical experience

Reliable quality, complete specifications, long-term stock of conventional products, fast delivery.

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Timely delivery

We promise that after the customer orders, the spot products will be delivered on the same day, and the professional logistics network will be provided.

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Quality service

Integrity, strength and quality of products recognized by the industry. Welcome friends from all walks of life to visit, guidance and business negotiation.


Professor Li Xiaoyan of Tsinghua University/Academician Tian Yongjun of Yanshan University "Nature Materials": Important Progress in Room Temperature Conductive Superhard Materials

Materials with high strength, high hardness and room temperature conductivity are high performance materials required in various fields of science and industry. Traditional metals have excellent electrical conductivity, but their yield strength is relatively low, and they soften at higher temperatures. Ceramics generally have superior strength/hardness, wear resistance, and high temperature stability compared to metals, but most ceramics are poor conductors of electricity. The ceramic may be electrically conductive by elemental doping or incorporation of a conductive second phase. However, the low diffusion rate of doping elements in ceramics limits their doping concentration, resulting in limited conductivity improvement. Compared with single-phase ceramics, the mechanical properties and conductivity of conductive ceramic composites can not be improved synchronously due to the weak heterogeneous interface between the matrix and the second phase. Therefore, how to obtain materials with excellent mechanical properties and electrical conductivity is one of the key scientific problems to be solved in the field of materials science.


The wide application of diamond semiconductors is just around the corner

Diamond is the "ultimate material", with the best physical properties of all materials in terms of hardness, sound velocity, thermal conductivity, Young's modulus, etc.; other properties include transmittance, thermal and chemical stability, and controllable resistance and conductivity across a wide wavelength spectrum from ultraviolet to infrared. These properties make diamond useful in a variety of applications such as heat sinks, processing tools, optical components, audio components, and semiconductors. So far, this kind of material with extreme performance has only been widely used for its high hardness and wear resistance. In recent years, with the development of science and technology, its excellent performance in the semiconductor industry has gradually been developed and utilized.


Diamond "into" the field of new energy vehicles, innovative applications on the road

Global carbon emission reduction actions are in-depth, and the number of new energy vehicles driven by electrification in the transportation field is increasing. At the same time, the emergence of new materials has brought advantages for the promotion of new energy vehicles. As a new material with unique physical and chemical properties, diamond will also be widely used in the field of new energy vehicles.


World's first 100mm single crystal diamond wafer

Diamond Foundry Inc, headquartered in San Francisco, California, has produced the world's first single crystal diamond wafer with a diameter of 100mm. The company plans to offer diamond substrates as a way to improve thermal performance, which in turn could improve artificial intelligence computing and wireless communications as well as smaller power electronics.