Characterization of WC-Co composite thermal spray powders and coatings

       

1.    INTRODUCTION

Thermal spray coatings have a wide range of applications, for instance, by repairing machine parts damaged in service or by the production of parts with high wear resistance. The wear resistance of a coating does not depend only on the spray system used, but also on the characteristics of the particular spray powder. Previous studies have demonstrated  that the use of recycled hardmetal powders in the formation of detonation coatings leads to numerous problems. Hardmetal powder particles sized from 32 to 40 µm in a detonation spray produce very porous (4 to 5%) non-uniform coatings. Therefore, a new technology – mechanically activated synthesis  – was used to produce experi- 436 mental WC-based composite spray powders. The new experimental powder increases the wear resistance of the coating . To guarantee high abrasive wear resistance of a coating, it is necessary to optimize the structure of the coating. Microstructure analysis gives combined characterization of the morphology, elemental composition and crystallography of the coating . Studies of the composite powder granule structure  show that no single universal method exists to acquire all the information needed for the material structure characterization. Thus the choice of the method depends on the researcher. However, sometimes the chosen methods do not provide reliable information because of insufficient experience. Inaccurate results typically occur, when computer-aided measurements are relied on with no reservations. In fact, computer-aided microstructural analysis can provide highly accurate information in a short time. The article focuses on the analysis of the structure of the coating and the use of the obtained data with the aim to improve abrasive wear resistance of the coating.

2.    EXPERIMENTAL

  To analyse the structure of the particles and coatings, cross-section polishes were made by a mechanical grinding-polishing procedure. To analyse the structure and composition of a coating, cross-section polishes were made by hot mounting. The best results for the powder were obtained with a fluid (not viscous) cold mounting with an epoxy-based compound that was mounted by help of the Buehler vacuum impregnation system. The cross-section polishes of the coating were made by hot mounting. Due to the high hardness of WCparticles, diamond grinding-polishing was used. The microstructure of the powder granules and the coating was investigated by means of the optical microscope Axiovert 25 and scanning electron microscope (SEM) Jeol JSM-840A using backscattered electron imaging. Quantitative results of the structure analysis were obtained by the image analysis systems Buehler Omnimet Image Analysis System Version 5.40 (OM) and Image Pro 3.0. To describe the microstructure of the grains and the shape of the powder granules, the following parameters were used: roughness is defined as the ratio of the convex perimeter to the perimeter (if there are no concave parts at the perimeter of the particle, the roughness of the particle is 1.0); sphericity is defined as 4π × area/(perimeter squared) (if the shape of the particle is a perfect circle, the sphericity of the particle is 1); aspect ratio refers to the longest axis of the observed object, divided by the shortest axis of the latter [6 ]. The phase composition study of investigated samples was carried out on a Bruker D5005 X-ray diffractometer (XRD), using Cu Ka radiation at 40 kV and 40 mA. The range was 11 to 70° by step 0.040° and step time was 3 s.

3.    RESULTS

To produce composite powders with sub-micrometric WC grains, it is necessary to analyse a sub-micrometric powder. Indirect methods like BET or XRD can be used to measure the WC powder (from 20 to 500 nm). The BET method enables us to find the size of the surface area and then calculate the average particle size. The 438 XRD method provides a picture of distribution (not precise, though) and an average value of the crystal size. In the case of nano-size powders, the grain and the crystal are usually of the same size. When treating nano-size particles, care should be taken not to oxidize particles during measurements. For thermal spray, the granule size of the powder should range from 20 to 45 µm to achieve high productivity of spraying and to avoid oxidation processes [7 ]. It is much easier to determine the size and size distribution of composite powder granules because of their larger size. For these purposes, range, sieve and laser particle size analysis can be used. Sieve and laser analysis may yield different results because of the elongation of the granules (Fig. 1b). To characterize their elongation, the aspect ratio AS [6 ] was used. The mean aspect ratio was 1.96, which means that the longest diagonal of the particle is almost twice as long as the smallest one. Because of such elongation, the granule size, measured by a laser diffraction analyser, was larger than 45 µm (the largest by sieving). By the laser analysis, 28% of the granules measured over 50 µm and 5% less than 20 µm (smallest by sieving). Granules over 45 µm can go through the sieve because of their elongated shape [8 ]. Granule size distribution is shown in Fig. 2.