Wear-Resistant Composites Produced from Tool Steel Waste for Contact Joints of High-Speed Printing Machines

IF 0.9 4区 材料科学 Q3 MATERIALS SCIENCE, CERAMICS
T. A. Roik, O. A. Gavrysh, Iu. Iu. Vitsiuk, V. V. Kholiavko
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Abstract

The paper examines the effect of doping elements on the structurization and properties of a new antifriction composite produced from grinding waste of the R2AM9K5 high-speed tool steel and CaF2 solid lubricant. The composite is intended for operation at loads of 2.0–3.0 MPa and high rotation speeds (5,000–7,000 rpm) in contact joints of high-speed printing machines. The production process imparted a heterophase structure to the antifriction composite. The composite consists of a metal pearlite–carbide and carbonitride matrix and CaF2 solid lubricant particles being evenly distributed in it. Valuable Mo, Cr, W, V, N, and Co doping elements contained in the R2AM9K5 steel waste particles promote the formation of strengthening phases in the composite’s metal matrix. In combination with CaF2 solid lubricant, these strengthening phases impart high antifriction properties to the material under high-speed friction at speeds up to 7,000 rpm and loads of 2.0–3.0 MPa. Comparative tests of the new R2AM9K5 steel + (4.0−8.0)% CaF2 composite demonstrated significant advantages in the antifriction properties over cast brass, currently used for units of modern rotary printing machines and can perform effectively only under continuous liquid lubrication. The R2AM9K5 steel waste composite containing CaF2 solid lubricant permanently forms a protective antifriction film on the contact surfaces in the friction process, which was confirmed by electron microscopy studies. Under these friction conditions, the film is continuous, uniform, and smooth and is constantly restored on its worn areas, leading to self-lubrication. When the rotation speed increases up to 8,000 rpm, the composite antifriction properties decrease as the film on the contact surfaces becomes discontinuous. The research allowed operating limits to be determined for applying the new composite and proved the effectiveness of industrial grinding waste in developing high-quality structural materials through a reasoned choice of secondary raw materials, considering the nature of doping elements present in them.

Abstract Image

Abstract Image

高速印刷机接触接头用废工具钢耐磨复合材料的研究
研究了稀土元素对R2AM9K5高速工具钢磨削废渣与CaF2固体润滑剂复合材料的组织和性能的影响。该复合材料适用于高速印刷机的接触接头在2.0-3.0 MPa的负荷和高转速(5000 - 7000转/分)下运行。该生产工艺使减摩复合材料具有异相结构。该复合材料由金属珠光体碳化物和碳氮化物基体组成,其中均匀分布着CaF2固体润滑剂颗粒。R2AM9K5钢废颗粒中含有有价值的Mo、Cr、W、V、N和Co掺杂元素,促进了复合材料金属基体中强化相的形成。与CaF2固体润滑剂相结合,这些强化相使材料在高达7,000 rpm的转速和2.0-3.0 MPa的载荷下具有高的抗摩擦性能。新型R2AM9K5钢+(4.0−8.0)% CaF2复合材料的对比试验表明,与铸造黄铜相比,新型R2AM9K5钢+(4.0−8.0)% CaF2复合材料在抗摩擦性能方面具有显著优势。铸造黄铜目前用于现代轮转印刷机的部件,只能在连续液体润滑下有效发挥作用。含有CaF2固体润滑剂的R2AM9K5钢废复合材料在摩擦过程中,在接触表面永久形成一层保护性的抗摩擦膜,这一点通过电镜研究得到证实。在这些摩擦条件下,膜是连续的、均匀的、光滑的,并不断地在其磨损区域上恢复,从而导致自润滑。当转速增加到8,000 rpm时,复合材料的抗摩擦性能下降,因为接触面上的膜变得不连续。该研究确定了应用新复合材料的操作限制,并证明了工业磨削废料在开发高质量结构材料方面的有效性,通过合理选择二次原料,考虑到其中掺杂元素的性质。
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来源期刊
Powder Metallurgy and Metal Ceramics
Powder Metallurgy and Metal Ceramics 工程技术-材料科学:硅酸盐
CiteScore
1.90
自引率
20.00%
发文量
43
审稿时长
6-12 weeks
期刊介绍: Powder Metallurgy and Metal Ceramics covers topics of the theory, manufacturing technology, and properties of powder; technology of forming processes; the technology of sintering, heat treatment, and thermo-chemical treatment; properties of sintered materials; and testing methods.
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