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Vol 230
Pages:
185
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RUS ENG
Electromechanics and mechanical engineering

Innovative technology of large-size products manufacture

Authors:
S. N. Sanin1
N. A. Pelipenko2
About authors
  • 1 — Belgorod State Technological University named after V.G.Shukhov
  • 2 — Belgorod State National Research University
Date submitted:
2017-10-25
Date accepted:
2018-01-17
Date published:
2018-04-25

Abstract

Advantages and prospects for the use of mobile robotic machine-tools in the manufacture of large parts in the mining, cement and nuclear industries are considered, as well as the importance of using welded structures to reduce production costs. Schemes for finishing mechanical machining of welded large-sized parts such as bodies of revolution with the use of mobile robotic machine-tools equipped with a belt-grinding tool, an enlarged description of the technological process for manufacturing a large-sized shell of a welded structure are presented. The conclusion is made that it is necessary to take into consideration the use in the industry of frameless production technology, especially for the machining of large-sized parts, and the use of small mobile robotic machine-tools is a productive approach and has a prospective character. The technological approaches proposed in the article make it possible to remove the restriction on the overall size and mass of the parts being manufactured, which are proposed to be manufactured directly at the site of future operation. The effectiveness of this technology is confirmed both by theoretical research and by practical data of the authors. It was noted that the production by the domestic machine-tool industry of mobile universal and special robotic machine-tools will allow the country's engineering industry to be brought to a new, high-quality world level.

10.25515/pmi.2018.2.185
Go to volume 230

References

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3. QUALITY CONTROL OF COMPLEX CONTOUR SURFACES IN ALUMINIUM ALLOY ITEMS DURING MAGNETIC ABRASIVE FINISHING. Tsvetnye Metally. 2023, Vol. 2023, P. 96-102. DOI: 10.17580/tsm.2023.04.13 [Scopus] (cited: 14)
4. Setup of a Mobile Robot Machine Tool for Large Annular Parts. Russian Engineering Research. May 2022, Vol. 42, P. 498-501. DOI: 10.3103/S1068798X22050239 [Scopus] (cited: 1)
5. Processing of a Large-Sized Cement Kiln Bandage by a Robotic Machine. Journal of Machinery Manufacture and Reliability. March 2021, Vol. 50, P. 171-177. DOI: 10.3103/S1052618821020114 [Scopus] (cited: 2)
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7. A study on the machinability of steels and alloys to develop recommendations for setting tool performance characteristics and belt grinding modes. Materials. September 2020, Vol. 13, DOI: 10.3390/ma13183978 [Scopus] (cited: 9)
8. Development of flux for protection of the surface of liquid-metallic low-melting-point fusible melt. Key Engineering Materials. 2020, Vol. 854 KEM, P. 126-132. DOI: 10.4028/www.scientific.net/KEM.854.126 [Scopus] (cited: 4)
9. A priori ranking and an analysis of factors affecting tire wear. IOP Conference Series: Earth and Environmental Science. 14 November 2019, Vol. 378, DOI: 10.1088/1755-1315/378/1/012001 [Scopus] (cited: 4)
10. Vibropercussion polyindenter drilling assembly. Mining Informational and Analytical Bulletin. 2019, Vol. 2019, P. 195-203. DOI: 10.25018/0236-1493-2019-09-0-195-203 [Scopus] (cited: 1)
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