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In modern precision machining, diamond coated end mills are ideal for cutting hard materials and non-metallic composites due to their exceptional wear resistance and thermal stability. Whether machining graphite molds, ceramics, or performing high-efficiency dry milling of CFRP, diamond coated carbide end mills significantly improve tool life and machining efficiency. Compared to traditional uncoated tungsten […]

In modern CNC precision machining, diamond milling tools are rapidly becoming the go-to solution for processing high-hardness and wear-resistant materials. Thanks to their exceptional wear resistance, thermal stability, and ability to deliver consistent results, these tools outperform traditional cutters in challenging applications such as graphite, ceramics, carbon fiber composites, and even under extreme conditions like

In modern manufacturing, the growing use of high-hardness materials has raised the bar for cutting tool performance. Whether in aerospace, electric vehicles, or precision mold making, materials such as graphite, silicon carbide, aluminum alloys, and ceramics present serious challenges in terms of wear resistance, cutting efficiency, and surface quality. To meet these demands, diamond tools

In precision machining and high-performance cutting applications, CVD diamond coated end mills are rapidly becoming the go-to solution for high-wear materials. Through CVD, a high-purity PCD layer is formed on a carbide substrate, delivering exceptional hardness, wear resistance, and tool life—particularly when cutting abrasive materials like graphite, CFRP, and ceramics. Compared with conventional coated tools,

In modern high-precision machining, diamond end mills are increasingly favored for their outstanding wear resistance and superior cutting performance—especially when working with hard and brittle materials. From dry cutting of ceramics, graphite, and glass fiber-reinforced plastics (GFRP) to high-efficiency mold manufacturing and composite machining in aerospace, diamond end mill cutting tools offer clear advantages. In

Graphite is widely used in high-precision machining fields such as mold manufacturing, EDM electrodes, and semiconductor packaging due to its excellent conductivity and high-temperature resistance. However, graphite materials are highly brittle and strongly abrasive, placing higher demands on the wear resistance and machining efficiency of cutting tools. Among the various graphite milling tools available, diamond

With the continuous development of CNC precision machining technology, high-speed dry cutting has gradually become a prominent trend that combines efficiency with environmental sustainability. In this context, diamond milling cutters—particularly PCD tools and CVD diamond-coated milling cutters—demonstrate excellent wear resistance, high thermal conductivity, and superior surface finishing capabilities. These tools are widely recognized for their

In the field of modern high-precision machining, tool life has become one of the most critical factors influencing machining efficiency and cost control. Especially when working with high-hardness or high-brittle materials such as graphite electrodes, carbon fiber reinforced composites (CFRP), and ceramics, traditional carbide tools often lead to production inefficiencies, reduced surface quality, and frequent

In precision machining, ceramics are widely used in high-end manufacturing industries such as semiconductors, medical devices, and aerospace due to their exceptional hardness, brittleness, and high-temperature resistance. However, these outstanding properties also make ceramics a typical difficult-to-machine material, placing high demands on the tool’s wear resistance, strength, and cutting stability. Currently, diamond coated milling cutters