Plasma nitriding (Ion nitriding) is a plasma supported thermochemical case hardening process used to increase wear resistance, surface hardness and fatigue by generation of a hard layer including compressive stresses.
The advantages of gaseous nitriding processes can be surpassed by plasma nitriding. Particularly when applied to higher alloyed steels, plasma nitriding imparts a high surface hardness which promotes high resistance to wear, scuffing, galling and seizure. Fatigue strength is increased mainly by the development of surface compressive stresses. Plasma nitriding is a smart choice whenever parts are required to have both nitrided and soft areas. The possibility of generating a compound layer free diffusion layer is often used in plasma nitriding prior to PVD or CVD coating. Tailor made layers and hardness profiles can be achieved.
Typical applications include gears, crankshafts, camshafts, cam followers, valve parts, extruder screws, pressure-die-casting tools, forging dies, cold forming tools, injectors and plastic-mould tools, long shafts, axis, clutch and engine parts. Plasma nitriding and plasma nitrocarburising are often preferred to the corresponding gas processes if masking is required.
Plasma nitriding is suitable for all ferrous materials, even sintered steels with higher porosity, cast iron and high alloyed tool steels even with chromium contents higher than 12%. Stainless steels and nickel based alloys can be plasma nitrided and keep most of their corrosion resistance if low temperatures are applied. Special applications are plasma nitriding of titanium and aluminium alloys. For heavy loads on large machine parts such as shafts and spindles, the use of special chromium and aluminium alloyed nitriding steels gives a huge benefit as plasma nitriding generates a surface hardness of more than 1000 HV.
Plasma nitriding/ion nitriding is a modern thermochemical treatment which is carried out in a mixture of nitrogen, hydrogen and an optional carbon spending gas. In this low pressure process, a voltage is applied between the batch and the furnace wall. A glow discharge with a high ionisation level (plasma) is generated around the parts. On the surface area that is directly charged by the ions, nitrogen-rich nitrides are formed and decompose, releasing active nitrogen into the surface. Due to this mechanism shielding is easily done by covering the concerning areas with a metal blanket. Plasma nitriding allows modification of the surface according to the desired properties. Tailor made layers and hardness profiles can be achieved by adapting the gas mixture: from a compound layer-free surface with low nitrogen contents up to 20 microns thick, to a compound layer with high nitrogen contents and an add-on of carbonic gas (plasma nitro-carburation). The wide applicable temperature range enables a multitude of applications, beyond the possibilities of gas or salt bath processes.
Plasma nitriding (Ion nitriding) is a plasma supported thermochemical case hardening process used to increase wear resistance, surface hardness and fatigue by generation of a hard layer including compressive stresses.
The advantages of gaseous nitriding processes can be surpassed by plasma nitriding. Particularly when applied to higher alloyed steels, plasma nitriding imparts a high surface hardness which promotes high resistance to wear, scuffing, galling and seizure. Fatigue strength is increased mainly by the development of surface compressive stresses. Plasma nitriding is a smart choice whenever parts are required to have both nitrided and soft areas. The possibility of generating a compound layer free diffusion layer is often used in plasma nitriding prior to PVD or CVD coating. Tailor made layers and hardness profiles can be achieved.
Typical applications include gears, crankshafts, camshafts, cam followers, valve parts, extruder screws, pressure-die-casting tools, forging dies, cold forming tools, injectors and plastic-mould tools, long shafts, axis, clutch and engine parts. Plasma nitriding and plasma nitrocarburising are often preferred to the corresponding gas processes if masking is required.
Plasma nitriding is suitable for all ferrous materials, even sintered steels with higher porosity, cast iron and high alloyed tool steels even with chromium contents higher than 12%. Stainless steels and nickel based alloys can be plasma nitrided and keep most of their corrosion resistance if low temperatures are applied. Special applications are plasma nitriding of titanium and aluminium alloys. For heavy loads on large machine parts such as shafts and spindles, the use of special chromium and aluminium alloyed nitriding steels gives a huge benefit as plasma nitriding generates a surface hardness of more than 1000 HV.
Plasma nitriding/ion nitriding is a modern thermochemical treatment which is carried out in a mixture of nitrogen, hydrogen and an optional carbon spending gas. In this low pressure process, a voltage is applied between the batch and the furnace wall. A glow discharge with a high ionisation level (plasma) is generated around the parts. On the surface area that is directly charged by the ions, nitrogen-rich nitrides are formed and decompose, releasing active nitrogen into the surface. Due to this mechanism shielding is easily done by covering the concerning areas with a metal blanket. Plasma nitriding allows modification of the surface according to the desired properties. Tailor made layers and hardness profiles can be achieved by adapting the gas mixture: from a compound layer-free surface with low nitrogen contents up to 20 microns thick, to a compound layer with high nitrogen contents and an add-on of carbonic gas (plasma nitro-carburation). The wide applicable temperature range enables a multitude of applications, beyond the possibilities of gas or salt bath processes.
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