Silicon carbide applicable materials：

Non-metallic materials: This is its traditional area of strength. Including glass, stone, ceramics, jade, etc. It can efficiently cut these hard and brittle materials.

Non-ferrous metals: Such as aluminum, copper, brass, zinc alloys, etc. Due to their properties, they are less prone to the "plowing" effect, effectively cutting without excessive embedding in soft materials.

Titanium alloys: Also a common application of silicon carbide.

Cast iron, certain steels: Can be used for initial grinding.

Boron carbide applicable materials：

Hard metals and alloys: Such as high-speed steel, mold steel, stainless steel, etc.

Ceramics and engineering ceramics: Such as alumina, silicon carbide ceramics, etc.

Gemstones and jade: Used for grinding and pre-polishing hard gemstones.

Hard coatings and surface treatments: Such as grinding thermal spray coatings and plasma-hardened layers.

As a "budget-friendly alternative" to diamond: In some applications where efficiency and lifespan requirements are not extremely stringent, boron carbide can replace expensive diamonds to reduce costs.

Diamond Applicable Materials：

Hard alloys: This is diamond's most classic and irreplaceable application area. Used for polishing tungsten carbide tools, molds, etc.

Optical glass and crystals: Such as camera lenses, laser crystals, and semiconductor wafers. Usually used in conjunction with cerium oxide, diamond provides rapid removal, while cerium oxide ensures a final ultra-smooth surface.

Advanced ceramics: Such as zirconium oxide, aluminum nitride, and polycrystalline diamond (PCD).

Gemstones: Diamond is indispensable for the cutting and polishing of all high-end gemstones.