2015
DOI: 10.1016/j.wear.2015.02.031
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Mapping of impact-abrasive wear performance of WC–Co cemented carbides

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Cited by 59 publications
(24 citation statements)
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“…The increase in temperature to 860 ∘ C and pressure up to 50 MPa ( Figure 3) enabled achieving high densification level (> 98 %). The combined impact-abrasive wear tribo-device [11] was applied to test samples, with impact energy of 5.6 J and frequency of impacts being 27.5 Hz provided by impact generator (industrial hammer drill from Makita). The sample was experiencing reciprocative movement and was pressed (by the dead-weight system) against the rotating wheel (made from WC-Co) with a force of 49 N; linear abrasion velocity was 1 m/s.…”
Section: Experimental Materials and Test Methodsmentioning
confidence: 99%
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“…The increase in temperature to 860 ∘ C and pressure up to 50 MPa ( Figure 3) enabled achieving high densification level (> 98 %). The combined impact-abrasive wear tribo-device [11] was applied to test samples, with impact energy of 5.6 J and frequency of impacts being 27.5 Hz provided by impact generator (industrial hammer drill from Makita). The sample was experiencing reciprocative movement and was pressed (by the dead-weight system) against the rotating wheel (made from WC-Co) with a force of 49 N; linear abrasion velocity was 1 m/s.…”
Section: Experimental Materials and Test Methodsmentioning
confidence: 99%
“…The second simulated sample having a 2×2×2 mm lattice scaffold is illustrated in Figure 12. During normal operation of the tribo-device ( Figure 10(c)) [11] both rotation of the wheel (abrasive action) and impact between the sample and the wheel are provided but for current simulation, it was important to demonstrate the extreme case with impacting only (Figure 10(a)). The position of impacting was also changed.…”
Section: Simulation Studymentioning
confidence: 99%
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“…Impact abrasive wear, as one of the forms of abrasive wear, prominently increases the mass loss of materials as it combines friction and impact [6], has been gradually reported in recent years. Latest researches, however, start focus on advanced wear service materials such as metal matrix composites, coating, and cemented carbide [7][8][9]. But it is well-known that iron and steel material cannot be replaced in engineering, such as high chromium white iron (HCWI), has widely used in several structural applications as the third-generation wear-resistant materials, which attributed to the multiple advantages of HCWI such as high strength and wear resistance [10].…”
Section: Introductionmentioning
confidence: 99%
“…无 机 材 料 学 报 第 32 卷 WC-Co 类涂层具有较高的硬度和优良的耐磨 性, 在航空航天、汽车、船舶、石油化工、机械制造、 电力、印刷等领域得到广泛应用 [1][2][3][4] 。研究发现 [5][6][7][8][9] , 超 细/纳米粉末具有特殊的小尺寸效应和表面效应等, 因此超细/纳米结构涂层具有更低的孔隙率, 更高的 结合强度, 更高的硬度、抗氧化性、耐腐蚀性, 更高 的表面质量等, 从而大大拓宽了表面涂层在机构零 件修复、强化和保护等领域的应用。 随着 WC 晶粒尺寸的减小, 硬质合金的力学性 能明显提高 [10][11][12] 。很多研究集中在 WC-Co 硬质合 金烧结材料中添加晶粒长大抑制剂 [13][14][15][16]…”
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