Thermally conductive materials
Quantum dot materials
Biomedical coating materials
Smart Textile Raw Materials
High performance polymers
Ion spray coating
Glass coating
Flexible Electronics
Precision optical materials
Optoelectronic Materials
Composite Materials
Magnetic fluids and smart materials
Aerospace Materials
3D Printing Materials
Thermally conductive fillers
The ability to grind thermal conductive filler raw materials to nanometer level makes the filler particles finer, increases the specific surface area, increases the contact area between the filler and the base material, and improves the thermal conductivity
Quantum dot materials
The quantum dot raw materials are ground into the required small particle size range, and a fine dispersion mechanism is used to ensure uniform distribution of particles, thus avoiding performance fluctuations that may be caused by uneven particle size.
Biomedical coating materials
Solve the problems of insufficient raw material refinement, uneven particle size distribution, and maintaining material biocompatibility and purity in the production of biomedical coating materials
Smart Textile Raw Materials
Smart textile raw materials often need to reach nanoscale or ultra-fine particle size to ensure that they have excellent properties, such as conductivity, sensing, temperature regulation, etc.
High performance polymers
During the preparation of high-performance polymers, strict requirements are placed on the particle size, particle size distribution and dispersion state of the raw materials. Too large a particle size or uneven distribution will affect the physical and mechanical properties of the polymer, such as strength and toughness.
Ion spray coating
It can achieve uniform distribution of spray powder particle size, which is crucial for the density and performance stability of ion spray coating.
Glass coating
Glass coating production has strict requirements on the particle size and distribution of raw materials, because the uniformity of the coating material directly affects the flatness and optical properties of the coating layer.
Flexible Electronics
Able to grind flexible electronic materials to nanometer level and achieve uniform dispersion of materials, avoiding agglomeration and sedimentation of particles
Precision optical materials
Solve the problems of insufficient raw material refinement, uneven particle distribution and incomplete impurity removal in the production of precision optical materials, ensuring the purity, uniformity and optical performance of optical materials
Optoelectronic Materials
The performance of optoelectronic materials depends largely on their microstructure and surface morphology, including particle size, shape, distribution, and surface roughness.
Composite Materials
Able to grind composite materials to nanometer level and achieve full mixing and uniform dispersion of raw materials
Magnetic fluids and smart materials
Ability to achieve nano-scale processing of smart material raw materials, ensuring uniform distribution of material components and fine control of microstructure
Aerospace Materials
Make the material particles achieve ideal particle size distribution and surface state, thereby increasing the specific surface area and activity of the material and enhancing the physical and chemical properties of the material.
3D Printing Materials
Grind the raw materials to a fine particle size that meets the requirements of 3D printing, and use fine dispersion technology to ensure uniform distribution of particles
