Single Crystal Growth Furnace

It is applied to the growth of laser crystals such as yttrium aluminum garnet (AG) and titanium-doped sapphire, as well as single-crystal materials for optical windows, like calcium fluoride and magnesium fluoride. It also involves the growth processes and properties of new single-crystal materials. By varying growth parameters such as temperature, pressure, and atmosphere, the growth mechanisms and property change laws of single - crystal materials are studied. This provides a basis for the development of new materials with special physical and chemical properties, and promotes cutting-edge research in materials science.

Graphene Film Equipment

Vertical Wafer Film Static Growth CVD

Roll to Roll CVD for Thin Film's Continuous Growth

Graphene's thin film production capacity(industrialization)equipment, Wide-width roll to roll continuous growth, APC system: Automatic control by Vacuum butterfly

Wide-format Roll-to-roll Thin-film Continuous Growth Furnace

Equipment for Graphene Film Production Capacity(Industrialization), Wide-format Roll-to-Roll Continuous Growth, Equipped with Automatic Deviation Correction

Single-walled Carbon nanotube Growth Equipment

This equipment mainly operates based on the principle of chemical vapor deposition. In this process,carbon-containing gases(such as methane and acetylene)serve as carbon sources. They decompose under the action of high temperature and a catalyst. The carbon atoms undergo chemical reactions on the surface of the catalyst and gradually deposit, ultimately growing into single-walled carbon nanotubes.

Vacuum Hydrogen Furnace/Annealing Furnace/Sintering Furnace

It is applicable to the aerospace, electro-vacuum, and heat treatment industries. It can perform annealing treatment on materials such as copper, titanium, tungsten, molybdenum, aluminum foil, high-speed steel, stainless steel, Monel alloy, and Permalloy. It also meets the requirements of sintering and brazing processes for various electro-vacuum devices, as well as the processes of reduction, sintering, annealing, and surface treatment for ceramic materials, magnetic materials, and rare refractory metals.

Zone Furnace

It is applied to the purification of rare metals in the semiconductor industry, such as germanium (Ge), antimony (Sb), and bismuth (Bi). The zone melting furnace can utilize the difference in the solubility of impurities in the solid and liquid phases. Through multiple zone melting processes. the impurities are concentrated in specific regions of the material, thus achieving the purification of rare metals. The purified rare metals can be used in the manufacture of special alloys, semiconductor electronic devices, and chemical catalysts.

Vacuum Distillation Furnace

The vacuum distillation furnace is specially designed for the high-purity purification and preparation of elemental metals. The core focuses on the deep purification of key high-purity metals such as selenium (Se), tellurium (Te), antimony (Sb), gallium (Ga), cadmium (Cd), germanium (Ge), etc., which can effectively remove impurity components from raw materials and stabilize the preparation of high-purity metals. It is widely used in the production and quality upgrading of raw materials in the fields of semiconductor materials, optoelectronics, infrared materials, high-purity chemicals, and advanced alloys.

Extrusion Furnace

The high-purity material extrusion furnace is a device used for heating and extruding high-purity materials. It enables the materials to be shaped through a die under specific temperature and pressure conditions, and is widely used in multiple fields.

Swing Furnace Continuous Melting Furnace

The high-purity material swing furnace is a device specifically designed for processing high-purity materials, and its core feature is the swing function. During operation, the furnace body can perform a swinging motion at a certain angle and frequency. During the heating process,  the high-purity materials are placed inside the furnace, and the resistance heating method is used to heat the materials to the preset temperature. Meanwhile, the swinging of the furnace body can promote the uniform mixing of the materials, heat transfer, and the progress of chemical reactions, reducing the temperature gradient and composition segregation inside the materials,  thereby improving the purity and quality uniformity of the materials.