K. Bobzin scite author profile

K. Bobzin

3Publications

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RWTH Aachen University

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Investigation of Novel Nano-carbide WC/CoCr Coatings Applied by HVAF

et al. 2023

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Wear leads to high material and energy losses in various industries. The manufacturing of novel nano-carbide WC/CoCr powder feedstock materials promises a further increase in the performance of thermally sprayed wear protection coatings. A novel experimental powder and a commercial ultra-fine carbide WC/CoCr reference are thermally sprayed onto a 1.0038 substrate by High Velocity Air Fuel (HVAF) spraying. The specimens are metallographically prepared and analyzed by means of light microscopy (LM) and scanning electron microscopy (SEM). Vickers Hardness testing is conducted by micro-indentation, and the porosities are determined by optical image analysis. X-ray diffractometry (XRD) analysis is used to investigate the phase retention. Fine nanocrystalline WC structures are preserved in the dense coatings. A significant effect of powder type on the porosity of the coating was found. No systematic relationships could be identified between the coating structure and the two parameter settings. It was possible to influence decarburization via both the powder type and the selected parameters. The resulting experimental and commercial nanostructured WC/CoCr coatings exhibit high, narrow hardness values with medians of 1.400 < HV0.3 < 1.470. The novel nanostructured coating can contribute to reduced wear and therefore improve the efficient utilization of critical raw materials like tungsten.

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Investigation of Novel Nano-Carbide WC/CoCr Coatings Applied by HVAF

Bobzin¹,

Wietheger²,

Burbaum³

et al. 2022

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Wear leads to high material and energy losses in various industries. The manufacturing of novel nano-carbide WC/Co powder feedstock materials promises a further increase in the performance of thermally sprayed wear protection coatings. A novel experimental powder and a commercial ultra-fine carbide WC/CoCr reference are thermally sprayed onto a 1.0038 substrate by High Velocity Air Fuel (HVAF) spraying. The specimens are metallographically prepared and analyzed by means of light microscopy (LM) and scanning electron microscopy (SEM). Vickers Hardness testing is conducted by microindentation and the porosities are determined by optical image analysis. X-ray diffractometry (XRD) analysis are used to investigate the phase retention. Fine nanocrystalline WC-structures are preserved in the dense coatings. A significant effect of powder type on the porosity of the coating was found. No systematic relationships could be identified between the coating structure and the parameter settings. It was possible to influence decarburization via both the powder type and the selected parameters. The resulting experimental coatings exhibit high hardness values in the range of the commercial ultrafine carbide WC reference. The novel nano-structured coating can contribute to reduced wear and therefore improve the efficient utilization of critical raw materials like tungsten.

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Wear Resistant Nano-Carbide WC-CoCr Coating by Novel Powder Manufacturing Method

Matikainen¹,

Lagerbom²,

Kaunisto³

et al. 2022

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Surface quality lifetime and wear resistance of protective coatings can be improved by decreasing carbide grain size from submicron to nanoscale. In this study, experimental WC-CoCr powders were manufactured via novel powder manufacturing approach using water-soluble raw materials. Produced powders were sprayed with the High-Velocity Air-Fuel (HVAF) spray process to control the particle temperature and to avoid in-flight decomposition of the nanocarbides. As a result, dense and wear resistant coatings with nanosized carbides were produced. Reference coatings were sprayed using commercial sub-micron WC-CoCr powder to compare the properties of the experimental coatings to the current state-of-the-art. Phase composition and microstructural characterization of the coatings were carried out with X-ray diffraction and electron microscopy, respectively. Mechanical properties were studied by using microhardness tester, as well as rubber wheel abrasion and cavitation erosion wear tests. The wear surfaces were characterized after the abrasion and cavitation erosion tests to understand the effect of nano-carbides on degradation mechanisms. Coatings with the nanosized carbides in the structure showed excellent mechanical properties in wear testing, and even outperformed reference coatings in cavitation erosion test. Based on the obtained results, these novel nano-carbide coatings are promising alternatives for demanding applications in which better surface quality lifetime is vital.

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K. Bobzin

Investigation of Novel Nano-carbide WC/CoCr Coatings Applied by HVAF

Investigation of Novel Nano-Carbide WC/CoCr Coatings Applied by HVAF

Wear Resistant Nano-Carbide WC-CoCr Coating by Novel Powder Manufacturing Method

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