The company has a special research and development department, and each project team under the research and development department is specially responsible for promoting process research and development, optimization, innovation and promotion, improving the level of construction technology and enhancing the company's construction service advantages in the industry. The project team is engaged in the research and development of whisker carbon nanotubes and the innovation of technology. The R & D department has established a standard project development process, adopting the method of setting up scientific and technological projects and combining production, teaching and research to carry out the R & D of new products in the field of nano carbon materials.
KELAIWEI company will continue to invest in top expert teams and research and development funds to devote itself to the research and development of nanomaterials technology and equipment, providing you with nanomaterials products with high stability and high technical standards. In the past 20 years, the R & D team of KELAIWEI company-the expert team led by Professor Sun Xiaogang of Nanchang University has independently researched and developed the production and preparation technology of whisker carbon nanotubes. Our company has invested 0.45 billion in the construction of whisker carbon nanotubes powder project, today's KELAIWEI products have been exported to the world.
KELAIWEI company relies on the research and development achievements of the expert research and development team of Professor Sun Xiaogang of Nanchang University in China for more than 20 years to carry out the industrial and mass production application of high-end nanomaterials. After years of unremitting efforts and continuous investment, our company has achieved the production capacity of far infrared heating paper reaching 30 tons per year, and the production capacity of designed whisker carbon nanotube powder production line reaching 300 tons per year, around 2008, 0.45 billion yuan has been spent on production capacity expansion.
The annual spring sports meeting of Henan KELAIWEI Nano Carbon Material Co., Ltd. was held on schedule in the staff sports ground of Dengfeng production center company. Through the fun sports meeting, KELAIWEI employees can exercise the solidarity and cooperation spirit of KELAIWEI employees, promote the communication between different departments of KELAIWEI, and make KELAIWEI employees pay attention to sports health, KELAIWEI company not only attaches importance to staff skill training, but also always pays attention to the health of the company's employees.
Carbon nanotubes can be used to make touch screen products the film made of carbon nanotubes has very good transparency and conductivity, waterproof, high flexibility, strong shielding interference, high tensile wear resistance, advantages such as high knocking resistance at present, wearable devices and high-end intelligent household products have a bright future in the industry, and carbon nano-tube materials have unique advantages in the application of such products due to their excellent performance, and the efficacy of nano-carbon.
Fundamentally speaking, are there any essential differences between common carbon nanomaterials and graphene? Graphene is a thin film material. The thickness of graphene is only one carbon atom. The mechanism of graphene is fundamentally different from that of common carbon nanomaterials. Graphene, fullerene nanomaterials, carbon nanotube nanomaterials and so on, these carbon nanomaterials are different in structure and form, it can be said that the physical properties of graphene and carbon nanomaterials are still different.
Far infrared emission paper presents a new heating mechanism. Different from traditional heating, it first heats itself and then conducts heat through temperature difference. After we electrify the far infrared transmitting paper, the whisker carbon nanotubes in it will have friction, oscillation, drift and other activities in the nanometer level, and generate electromagnetic waves, the so-called phonon oscillation generates heat. Phonon energy is transmitted in the form of far infrared, without internal phonon scattering loss, the object can be heated quickly.
