Slurry erosion performance analysis and characterization of high-velocity oxy-fuel sprayed Ni and Co hardsurfacing alloy coatings

Q1 Chemical Engineering
Jashanpreet Singh
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引用次数: 11

Abstract

In this paper, the performance of hardsurfacing Cobalt alloy (Stellite 6) and Nickel alloy (Colmonoy 88) was tested in tribological slurry conditions by using a pot tester. Thermal spraying powders were deposited on AISI 316L substrates by using a high-velocity oxy-fuel (HVOF) technique. Wear experiments are carried out using a lab-scale pot tester at low velocities like 1.81, 2.71, 3.61, and 4.59 m/s. The high mass flux of ashes (ranging 30–60 wt%) is used to produce severe accelerated conditions. The effect of the size fraction of eroding particles was evaluated by preparing the multi-sized slurries of size fractions (ASTM: −200, −140 + 200, −100 + 140, and −60 + 100). Results show that the microhardness of AISI 316L was improved by the HVOF depositing of Cobalt alloy-6 and Nickel alloy-88. The average surface microhardness of Cobalt alloy-6 was found lower (439 ± 19 HV1000) than the Nickel alloy-88 coating (601 ± 11 HV1000). Erosion performance of coatings was found to be increased with an increase in the value of the velocity, time, mass flux, and weighted mean size of eroding particles. Results show that the Ni-alloy improved the wear resistance of AISI 316L by 2.03 ± 0.021 times in fly ash slurry conditions and 3.21 ± 0.035 times in bottom ash slurry conditions. However, the Co-alloy was beneficial in reducing the wear of AISI 316L by 1.48 ± 0.019 times in fly ash and 2.50 ± 0.032 times in bottom ash slurry conditions. Moreover, the maximum wear of AISI 316L steel was observed at an impingement angle of 30° whereas 60° and 45° for Ni-alloy and Co-alloy coatings respectively in fly ash conditions. Although, the AISI 316L and Ni-alloy coating show maximum wear at the same impingement conditions under the bottom ash slurry conditions. However, the Co-alloy coating showed maximum wear at 60° in bottom ash slurry conditions.

高速氧喷涂Ni和Co硬质堆焊合金涂层的浆液侵蚀性能分析与表征
本文采用罐式试验机对钴合金(钨铬钴合金6号)和镍合金(Colmonoy 88号)在摩擦学浆料条件下的堆焊性能进行了测试。采用高速氧燃料(HVOF)技术在AISI 316L基体上沉积了热喷涂粉末。磨损实验是使用实验室规模的锅式测试仪在1.81、2.71、3.61和4.59 m/s等低速下进行的。灰烬的高质量流量(范围为30–60 wt%)用于产生严重的加速条件。通过制备粒度级分(ASTM:−200、−140+200、−100+140和−60+100)的多粒度浆料来评估侵蚀颗粒粒度级分的影响。结果表明,6号钴合金和88号镍合金的HVOF沉积提高了AISI 316L的显微硬度。钴合金-6涂层的平均表面显微硬度(439±19HV1000)低于镍合金88涂层(601±11HV1000)。涂层的侵蚀性能随着侵蚀颗粒的速度、时间、质量流量和加权平均尺寸的增加而增加。结果表明,在飞灰浆条件下,镍合金使AISI 316L的耐磨性提高了2.03±0.021倍,在底灰浆条件上提高了3.21±0.035倍。然而,在飞灰条件下,Co合金有利于将AISI 316L的磨损降低1.48±0.019倍,在底灰浆料条件下有利于将磨损降低2.50±0.032倍。此外,在飞灰条件下,在30°的冲击角下观察到AISI 316L钢的最大磨损,而Ni合金和Co合金涂层的最大磨损分别为60°和45°。尽管如此,AISI 316L和Ni合金涂层在底灰浆条件下的相同冲击条件下显示出最大磨损。然而,在底灰浆条件下,钴合金涂层在60°时显示出最大磨损。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of King Saud University, Engineering Sciences
Journal of King Saud University, Engineering Sciences Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
12.10
自引率
0.00%
发文量
87
审稿时长
63 days
期刊介绍: Journal of King Saud University - Engineering Sciences (JKSUES) is a peer-reviewed journal published quarterly. It is hosted and published by Elsevier B.V. on behalf of King Saud University. JKSUES is devoted to a wide range of sub-fields in the Engineering Sciences and JKSUES welcome articles of interdisciplinary nature.
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