Prospects for Creating Bearing Details Using Secondary Materials

  • Urishev Gulyam Andijan Machine-Building Institute, Department of "Materials Science and Technology of New Materials", candidate of technical sciences, docent
  • Mo`minov Shukurillo Maribjon o`g`li Andijan Machine-Building Institute, Department of "Materials Science and Technology of New Materials", master's degree
Keywords: Bearing, secondary metal, bearing ring, induction furnace, ШХ15, ШХ18, chrome steel

Abstract

This article talks about the future prospects of the production of bearings from secondary metal waste and their use in machine building, aviation, and shipbuilding. Bearings made of secondary metals are economically more convenient and have a significant positive impact on the environment.

References

1. Tojiboyev, B. M., Muhiddinov, N. Z., Karimov, R. I., & Jalilov, R. R. O. G. L. (2021). Ikkilamchi termoplast polimerlar asosida qurilish sanoati uchun polimerkeramik kompozitsion materiallarni olish jarayonini takomillashtirish. Oriental renaissance: Innovative, educational, natural and social sciences, 1(9), 386-392.
2. Tojiboyev, B. M., & Muhiddinov, N. Z. (2022). TERMOPLAST POLIMERLAR ASOSIDA OLINGAN KOMPOZITSION MATERIALLARNING XOSSALARI. Scientific progress, 3(4), 1058-1064.
3. Zuxridinovich, M. N., & Muxammadzokir ogli, R. M. (2021). To improve the technology of obtaining polymer composite materials on the basis of fillers that provide special properties. Texas Journal of Multidisciplinary Studies, 3, 168-171.
4. Wittaker D. Production of Structural PM Parts // International Powder Metallugy Directory Yearbook. 11-th Edition – 2004/2005. – p. 31-47.
5. William D., Callister Jr., David G. Rethwisch. Materials Science and Engineering / New Jersey, Wiley and Sons, 2015. – 992 p.
6. MPIF Standard 35, Materials Standards for PM Structural Parts – 2012. Edition, Metal Powder Industries Federation, Princeton, NJ, 2012. - p.71.
7. Sample Preparation for the Chemical Analysis of the Metallic Elements in PM Materials // MPIF Standard 67, Standard Test Methods for Metal Powders and Powder Metallurgy Products, Metal Powder Industries Federation, Princeton, NJ, 2012. – 691 p.
8. Schatt W., Wieters K-P. Powder Metallurgy. Processing and Materials. EPMA, Shrewsbury, 1997. – 492 p.
9. Salak A. Ferrous Powder Metallurgy. Cambridge, 1995. – 460 p.
10. Singer I.L., Pollock H. Fundamentals of Friction: Macroscopic and Springer Sciens Business, 2012. – p. 330.
11. Simchi A., Danninger H., Weiss B. Microstructural Modeling of Electrical Conductivity and Mechanical Properties of Sintered Ferrous Materials // Powder Metallurgy, 2000, Vol. 43, No.3, -p.219-227.
12. Powder Metallurgy. Materials, Processes and Applications // A Product of the European Commission’s Ieonardoda Vinci Programme. EPMA, CD-Rom, 2000. – 789 p.
13. Neikov O.D., Naboychenko S.S., Murashova I. V., Gopienko, Hahdbook of Non-Ferrous metal powder-technologies and Applications. – I st edition. – Philadelphia: Elsevier, 2009. – 671 p.
14. Metallographic Etching. 2-nd Ed. G. Petzow, ASM Inter, 1999. – 240 p.
15. Mikel P. Groover Fundamentals of Modern manufacturing: materials, processes and systems / four Th edition, New Jersey, John Wiley and Sons, 2010. – 435 p.
16. Materials information Socicty. Handbook ASMI. Powder Metallurgy. Vol.7. 9-10 Th Edition, N.-Y. 2002. – 1230 p.
17. T. Kibble W. B., Berkshire Frank H. Classical Mechanics, Imperial College Press, 2004. - p.114.
18. Ludema Kenneth, Layo Ajayi. Friction, Wear, Lubrication: A textbook in Tribology, second Edition, CRC Press, 2018. – p. 6-48.
19. Krasnobaev A., Lyulko V., Kudrjakov O., Barkov A. Preparation Techniqus of Gradient Structures Received by Updating of Metals and Alloys Surface by Energy Concentrated Streams // Powder Metallurgy – 2004. World Congress. Vienna, Proc. Vol.2. 2004. – p.675-681.
20. W. B. James and K.S. Narasimham, Warm Compaction and Warm-Die Compaction of Ferrous PM Materials, presented at PM Association of India Conference, Pune, 2013. – 448 p.
21. J. F. Isaza, P. and C. Aumund-Koopp, Additive Manufacturing with Metal Powders: Design for Manufacture Evolves into Design for Function, Powder Metall. Rev. Vol 3 (No 2), 2014. – P.41-51.
22. Hoganas Handbook For Warn Compaction, Hoganas AB, Sweden, 2004. – p.289.
23. Hoganas Handbook For Warn Compaction, Hoganas AB, Sweden, 2004. – p.112.
24. Hoganas Iron and Steel Powder for Sintered Components. Hoganas AB / SE-263 83 Hogaas. Sweden. 2003/06. - 4 p.
25. Hamill J.A., Welding Jr. Powder Metal Technologies and Applications, Vol 7, ASM Hahdbook, ASM International, 1998. – p. 656-662.
26. German R.M. Powder Metallurgy of Particulate materials Processing, Metal Powder Industries Federation, Princeton, NJ, 2005. - p.308.
27. Danninger H., Gierl C., Processes in PM Stell compacts during the initial stages of sintering. Materials Chemistry and Physics 67. 2001. – p.49-50.
28. Danninger H. Powder Metallurgy Research Institutions in Austria // PM, 2004, Vol. 47, No.3, p.216-220.
29. Cuervo P.A., Santa J.F., Toro A. Correlations between wear mechanisms and rail grinding operations in a commercial railroad. Tribology Inter-national, 2015. – p. 265-273.
30. Bhushan B. Modern Tribology Handbook (Principles of Tribology), 2001. - p.412.
Published
2023-05-09
How to Cite
Gulyam, U., & o`g`liM. S. M. (2023). Prospects for Creating Bearing Details Using Secondary Materials. International Journal on Orange Technologies, 5(5), 23-26. Retrieved from https://journals.researchparks.org/index.php/IJOT/article/view/4341