<p>The purpose of this study was to develop a durable surface cladding capable of withstanding severe dry abrasive environments commonly experienced by SS410 stainless steel components. To achieve this, a composite cladding of Hogonas alloy reinforced with 50 wt% WC was fabricated via laser cladding and optimized for superior wear resistance and structural integrity. The coating exhibited a dense microstructure with uniformly distributed WC particles embedded in a Ni-based matrix, achieving an average hardness of around 698 HV, about four times that of SS410. Dry sliding wear tests, designed through a Central Composite Design (CCD) and analyzed using Response Surface Methodology (RSM), identified abrasive particle size as the most dominant factor, followed by sand flow rate and load. The cladding showed the gradual reduction in mass loss relative to the uncoated substrate. SEM analysis revealed a transition from ductile ploughing in the steel to brittle micro-fracture and carbide pull-out in the cladded surface.</p>

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Dry Sliding Wear and Microstructural Evolution of Hogonas + 50% WC Cladding Over SS410 Steel

  • Vikrant Singh,
  • Samandeep Kaur,
  • Anuj Bansal,
  • Deepak Kumar Goyal,
  • Sarpreet Singh

摘要

The purpose of this study was to develop a durable surface cladding capable of withstanding severe dry abrasive environments commonly experienced by SS410 stainless steel components. To achieve this, a composite cladding of Hogonas alloy reinforced with 50 wt% WC was fabricated via laser cladding and optimized for superior wear resistance and structural integrity. The coating exhibited a dense microstructure with uniformly distributed WC particles embedded in a Ni-based matrix, achieving an average hardness of around 698 HV, about four times that of SS410. Dry sliding wear tests, designed through a Central Composite Design (CCD) and analyzed using Response Surface Methodology (RSM), identified abrasive particle size as the most dominant factor, followed by sand flow rate and load. The cladding showed the gradual reduction in mass loss relative to the uncoated substrate. SEM analysis revealed a transition from ductile ploughing in the steel to brittle micro-fracture and carbide pull-out in the cladded surface.