Abstract
One of the methods for improving metal-ceramic interface and suppression of agglomeration is the formation of a monolayer electroless coating on the particles. Investigations indicated that Ni-B monolayers should be first formed to develop in the next process an electroless Ni–P coating with the morphology of cauliflower. It was possible to produce a Ni-B layer on WC particles when a bath was heated at a temperature of 95 °C by using sodium borohydride and an appropriate stabilizer. Following this process, the Ni–P electroless coating was deposited on WC particles at 85 °C. In this way, two layers of electroless coating of Ni–B/Ni–P on the WC ceramic particles without using the surface activator were produced successfully. The coating morphology and surface analysis were performed by scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDX). The results showed that only the degreasing with acetone as a surface preparation of ceramic particles is sufficient to make a Ni–P or Ni–B coating. Electroless Ni–B coating with appropriate adhesion to the surface produces an acceptable surface for the electroless Ni – P coating formation.
Highlights
Composites have attained particular attention in various industries, due to their high mechanical and corrosion properties
Jafari et al [4,5,6] produced an electroless nickel coating on the particles used in the high-velocity oxygen fuel (HVOF) process that reduces the porosity and increases the fracture toughness of the coating
Recent studies about the electroless coating of nickelboron and nickel-phosphorus on the surface of ceramic particles show that coating requires different activation methods on the particles, such as palladium activation [8]
Summary
Composites have attained particular attention in various industries, due to their high mechanical and corrosion properties. A layer of electroless nickel reduced the required temperature for powder metallurgy process as well as improved the bond between the particles. Jafari et al [4,5,6] produced an electroless nickel coating on the particles used in the high-velocity oxygen fuel (HVOF) process that reduces the porosity and increases the fracture toughness of the coating.
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