Advanced Analyses of Heating Elements Manufactured by an Optimized Arc Spraying Process
Author:
Hauer Michél1ORCID, Ripsch Benjamin1, Gericke Andreas1, Krömmer Werner2, Henkel Knuth-Michael3
Affiliation:
1. Thermal Joining Engineering, Fraunhofer Institute for Large Structures in Production Engineering IGP, 18059 Rostock, Germany 2. Linde plc, Packaged Gases Germany Retail & Welding Applications/Thermal Spraying, 85716 Unterschleißheim, Germany 3. Faculty of Mechanical Engineering and Marine Technologies, University of Rostock, 18059 Rostock, Germany
Abstract
Heating elements in the automotive industry are currently produced by several thermal spray processes and materials. However, simpler spraying technologies such as arc spraying are investigated regarding technological suitability as a cost-effective alternative to plasma spraying in the production process of these components. Thus, several mixtures and combinations of alternative pressurizing gases and further modifications of an arc spray process were examined in this study. Consequently, coatings based on NiCr were produced, since this alloy is typical for heating elements. Coating properties were investigated by SEM, EDS, and resistivity measurements. The results demonstrate reduced oxygen content and improved morphology compared with the industrially used plasma-sprayed coatings. Additionally, the improved microstructure affects the surface quality and specific resistivity of the coatings positively. This allowed for laser texturing the arc-sprayed coatings successfully. It must be considered a drawback, though, that cracks partially appeared in the underlying coatings. In contrast, the temperature coefficients of resistance and the resistivities of the heating elements were superior to the conventional coatings, which can lay the foundation for a future industrial application. To further investigate this and to minimize the influence of potential sample preparation issues on the analysis results, different methods of cross-sectioning, i.e., in detail hot mounting, cold mounting, and ion beam polishing, were evaluated.
Subject
Materials Chemistry,Surfaces, Coatings and Films,Surfaces and Interfaces
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