{"id":22580,"date":"2024-04-18T16:26:20","date_gmt":"2024-04-18T08:26:20","guid":{"rendered":"https:\/\/www.meetyoucarbide.com\/?p=22580"},"modified":"2024-04-18T16:26:20","modified_gmt":"2024-04-18T08:26:20","slug":"safe-and-stable-stainless-steel-processing","status":"publish","type":"post","link":"https:\/\/www.meetyoucarbide.com\/tr\/safe-and-stable-stainless-steel-processing\/","title":{"rendered":"How to Achieve Safe and Stable Processing Stainless Steel \uff1f"},"content":{"rendered":"
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Compared to the machinability of 45# steel, austenitic stainless steel is only 0.4, ferritic stainless steel is only 0.48, and martensitic stainless steel is only 0.55. Among them, the machinability of a mixture of austenite and carbide is even worse.<\/p>\n
Stainless steel undergoes severe work hardening, especially the mixture of austenite and ferrite, where the hardness of the hardened layer is 1.4 to 2.2 times higher than that of the base material, with a strength of R=1470~1960MPa. This type of stainless steel has high plasticity and strengthening coefficient. Moreover, austenite is unstable and easily transforms into martensite under the action of cutting forces.<\/p>\n
Stainless steel has high plasticity, especially austenitic stainless steel, with a elongation rate 2.5 times that of 45# steel. During milling, there is significant plastic deformation, increasing cutting forces, severe work hardening, high thermal strength, and difficulty in chip curling and breakage.<\/p>\n
Stainless steel has significant plastic deformation and increased friction, with a relatively low thermal conductivity. Therefore, under the same conditions, the milling temperature of stainless steel is about 200 degrees higher than that of 45# steel.<\/p>\n
When processing stainless steel, chip adhesion and built-up edge formation are common issues. Stainless steel has high plasticity and toughness, making chip breaking during milling difficult. Under high temperature and pressure, the tool is prone to adhesive wear and built-up edge formation.<\/p>\n
When machining stainless steel, stainless steel milling cutters should be used because the TiC hard points in stainless steel easily cause severe tool wear. Under high-speed, high-temperature, and high-pressure conditions, cutting and tooling easily experience adhesive wear, diffusion, and crescent-shaped wear.<\/p>\n
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To process stainless steel, hard alloy materials should be used, selecting tungsten-cobalt alloys with fine or ultra-fine grains containing TaC or NbC. Examples include YG6x, YG813, YW4, YD15, etc. When milling stainless steel, extreme pressure emulsion or sulfurized cutting oil should be used. For hard alloy stainless steel milling cutters, the milling speed should be between 40~60m\/min to avoid cutting into the hardened layer, accelerating tool wear. The feed rate should be greater than 0.1mm. Some companies may use high-hardness tools for stainless steel machining, but for common stainless steel materials like 304 and 202, hard alloy tools are sufficient. When machining 316 stainless steel or quenched and tempered stainless steel, in addition to using high-hardness tools, the tool edges should be sharp, preferably using stainless steel-specific tools from reputable brands.<\/p>\n
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