4.6 Article

Change in Dimensions and Surface Roughness of 42CrMo4 Steel after Nitridation in Plasma and Gas

Journal

COATINGS
Volume 12, Issue 10, Pages -

Publisher

MDPI
DOI: 10.3390/coatings12101481

Keywords

plasma nitriding; gas nitriding; dimensional accuracy; roughness; functional properties

Funding

  1. Department of Mechanical Engineering, University of Defence in Brno [SV20-216]
  2. grant Modern technologies for processing advanced materials used for interdisciplinary applications [FSI-S-22-7957]
  3. Project for the Development of the Organization DZRO VAROPS

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This paper investigates the influence of plasma nitriding and gas nitriding processes on the surface roughness and dimensional accuracy of 42CrMo4 steel. Both processes lead to changes in surface texture and the formation of a compound layer. Optimizing the nitriding parameters shows no changes in surface roughness evaluated using the Ra parameter, but changes are observed when using a multi-parameter evaluation. Nitriding also leads to changes in dimensions, with an average increase of 0.032mm. The magnitude of the change is related to the chemical composition of the material, and gas nitriding results in a larger increase in dimensions. The change in dimensional accuracy is one degree for both processes compared to the ground part.
The influence of plasma nitriding and gas nitriding processes on the change of surface roughness and dimensional accuracy of 42CrMo4 steel was investigated in this paper. Both processes almost always led to changes in the surface texture. After plasma nitriding, clusters of nitride ions were formed on the surface of steel, while gas nitriding very often led to the new creation of a formation of a plate-like surface texture. In both cases of these processes, a compound layer in specific thickness was formed, although the parameters of the processes were chosen with the aim of suppressing it. After the optimizing of nitriding parameters during nitriding processes, it was found that there were no changes in the surface roughness evaluated using the Ra parameter. However, it turned out that when using a multi-parameter evaluation of roughness (the parameters Rz, Rsk and Rku were used), there were presented some changes in roughness due to nitriding processes, which affect the functional behavior of the components. Roughness changes were also detected by evaluating surface roughness profiles, where nitriding led to changes in peak heights and valley depths. Nitriding processes further led to changes in dimensions in the form of an increase of 0.032 mm on average. However, the magnitude of the change has some context on chemical composition of material. A larger increase in dimensions was found with gas nitriding. The change in the degree of IT accuracy is closely related to the change in dimension. For both processes, there was a change of one degree of IT accuracy compared to the ground part (from IT8 to IT9). On the basis of the achieved dimensional accuracy results, a coefficient of change in the degree of accuracy IT was created, which can be used to predict changes in the dimensional accuracy of ground surfaces after nitriding processes in degrees of accuracy IT3-IT10. In this study, a tool for predicting changes in degrees of accuracy of ground parts after nitriding processes is presented.

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