Tungsten Carbide Mold Parts


Custom tungsten carbide mold parts are used to create workpieces of high-precision sizes. Standard parts are available from automotive, ceramic, electrical, and 3C industry manufacturers. Read the Best info about Stamping Die Parts.

CraftAlloy Tungsten Carbide Core Pins, Inserts, and Ejectors offer maximum tooling rigidity to reduce core shift/deflection for superior part quality and repeatability.


Manufacturing functional micro/nanostructured components has become an integral component of various technological fields, such as nano-optics and optical engineering, tribology and surface engineering, biological and medical engineering, and others. Key to their production process is precision mold materials used during molding. To meet such stringent standards for mold fabrication processes, various mechanical and nonmechanical techniques, including cutting, etching, laser machining, electrical discharge machining (EDM), and hybrid methods, are designed for particular tasks within these domains.

Carbide is a durable yet brittle material used for precision milling tough materials with great accuracy. Its thermal conductivity enables higher operating temperatures, increasing the precision and efficiency of manufacturing processes. Carbide can also be shaped into complex forms by forging. Its excellent thermal conductivity enables fast machining speeds, increasing the precision and efficiency of manufacturing operations.

Yize Mould is dedicated to providing customers with high-quality precision connector mold inserts and other mold components at competitive prices. We perform 100% inspection on every product we produce to ensure its flawless surfaces when it leaves our factory while offering quick delivery times – only 7-10 production days are needed from order placement until shipment! Choosing us as your supplier could not be more advantageous; we hope we look forward to working together in the near future!


Durability is of the utmost importance in mold and die manufacturing, which makes carbide-cutting tools invaluable in this industry. These cutting tools have proven their worth over years of use due to their ability to withstand high-heat environments while still maintaining their cutting edge longer than other tooling materials, providing greater precision with reduced costs.

Durability is of utmost importance in the aerospace industry, where precision must be met at all costs. Tungsten carbide is an ideal choice for milling complex composites and metals at high temperatures; additionally, it is capable of withstanding vibrational shock and thermal shock stress and handling abrasion and corrosion well.

Tungsten carbide is an excellent material choice for precision plastic injection molding, thanks to its durability and wear resistance properties. The mold can continue operating without losing accuracy over time, making this material perfect for producing large volumes of identical parts at the same time.

Tungsten carbide is a composite material made by combining tungsten powder with metallic binder materials such as cobalt or nickel. This allows the material to be easily formed into desired shapes for precise applications. Tungsten carbide punches and dies for stamping forming are made using this material and are designed to withstand the pressure exerted by stamping presses without deforming.


Precision mold parts are vital to the success of any production process. Precision tooling must withstand stress from heavy loads and high temperatures while meeting stringent quality standards, making tungsten carbide an excellent material for this purpose.

Tungsten carbide offers outstanding machinability and can be machined using various tools for precise results. Furthermore, its highly durable surface resists scratches and cracks as well as high-speed machining temperatures, making this an affordable option that provides reliability to make products successful.

Tungsten carbide can also be used to manufacture medical devices and automobile parts. It is available in different grades and compositions, so manufacturers can tailor products to specific applications. This makes tungsten carbide even more cost-effective in the market, helping businesses win new clients while increasing revenues.

Precision tungsten carbide mold parts are manufactured using various finishing techniques, including precision grinding. This enables them to meet the stringent dimensional accuracy requirements necessary for high-cavitation molding while simultaneously cutting cycle times by up to 25% and saving your business significant money in cycle times and material costs.


Tooling costs associated with precision metal parts manufacturing can be pretty high. Fees vary based on your design, part complexity, and metal type, but there are ways to minimize their price. If multiple identical parts need to be produced simultaneously, consider rapid prototyping methods such as 3D printers or other rapid prototyping technologies, which require significantly less equipment and professional labor than injection molding.

Injection molding is a process in which polymerized metal powders are used to form small metal parts using injection. The finished pieces are highly durable and able to withstand intense wear and tear, making injection molding an attractive option for manufacturing high-volume medical, aerospace, and firearms parts. Although accurate parts with small production runs may be challenging to produce accurately due to mold creation needs for each new design change, injection molds are popularly chosen due to this capability.

Production costs associated with creating a new mold can be significant for manufacturers. Not only are there associated expenses like design and development fees, material expenses, and production, but there may also be hidden costs, such as design services such as 3D printing. But with careful planning and some clever tricks, you can significantly lower these costs when undertaking injection molding projects—for instance, using services like Xometry 3D Printing to produce prototypes for testing before investing in complex tooling solutions.