Determination of hydrodynamic and vibroacoustic characteristics of a shut-off valve by hybrid engineering method

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New technologies are a significant factor in improving the efficiency of industrial enterprises. Traditional design methods do not fully meet the needs for technological equipment. A promising direction is hybrid engineering, which combines physical and virtual approaches into a unified process. The basis of this approach is reverse engineering and numerical modeling. The article illustrates the implementation of hybrid engineering through the example of creating a check valve. The results of laser scanning of the parts are presented, with the advantages and disadvantages outlined. The results of the hybrid approach to numerical modeling for noise level prediction are also provided. The necessity for further research to accumulate practical experience, reliable statistical information, verification and validation results, and a knowledge base has been identified. It is confirmed that hybrid approaches are the most promising for accelerated design and prediction of characteristics, allowing the identification of design flaws at an early stage and enabling optimization to meet the specified requirements if necessary.

Sobre autores

Tat'yana Chistyakova

State Marine Technical University

Autor responsável pela correspondência
Email: tg.chist@gmail.com

Lead Specialist

Rússia, St. Petersburg

Elena Kulichkova

JSC «Armalit»

Email: elenakulichkova@mail.ru

Candidate of Science (Engineering), Deputy CEO

Rússia, St. Petersburg

Bibliografia

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  2. Kitaev, M. V., Surov, O. E., Solov'eva, E. E. and Novosel'tsev, I. A. (2023), “Application of means and methods of reverse engineering in shipbuilding and shiprepair industry”, Sudostroenie, no. 3(868). – S. 26-33. (In Russian)
  3. Sarmanaeva, A. F., Sokolov, N.V., Paranina, O. Y., Davletshin, I. S., Korshunov, M. V., Akhmetzyanov, A. M. and Ibragimov, E. R. (2023), “An integrated approach to ensure the quality of products developed using reverse engineering methods”, Kompressornaya tekhnika i pnevmatika, no. 4, pp. 42-45. (In Russian)
  4. Tarakhovskiy, A. Yu. and Smirnov, I. A. (2023), “Reverse engineering of the compressor crankshaft”, Transport, mining and construction engineering: science and production, no. 18, pp. 91-97, doi: 10.26160/2658-3305-2023-18-91-97. (In Russian)
  5. Petrov, N. V., Nozirzoda, Sh. S. and Petrova, E. D. (2023), “Application of 3D-scanning technologies in reverse engineering of body parts”, Bulletin of the Kuzbass State Technical University, no. 1(155), pp. 34-41. doi: 10.26730/1999-4125-2023-1-34-4. (In Russian)
  6. Kozharina, T. V., Karpov, S. V. and Goronovskiy, A. R. (2024), “Reverse engineering of tillage machine parts for finite element analysis”, Trudy BGTU. Seriya 1: Lesnoe khozyaystvo, prirodopol'zovanie i pererabotka vozobnovlyaemykh resursov, no. 1(276), pp. 150-156. doi: 10.52065/2519-402X-2024-276-20. (In Russian)
  7. Soloshchenko, P. P. and Simonova, G. V. (2024), “Maintenance of imported gas meters using reverse engineering”, Interekspo Geo-Sibir', vol. 6, pp. 263-268. doi: 10.33764/2618-981X-2024-6-263-268. (In Russian)
  8. Krutikov, M. V. and Blinov, V. L. (2021), “Numerical study of the flow in the flow path of a centrifugal natural gas compressor at different positions of the inlet guide vane”, Herald of the Bauman Moscow State Technical University, Series Mechanical Engineering, № 2(137), pp. 94-108. doi: 10.18698/0236-3941-2021-2-94-108. (In Russian)
  9. Kozlov, V. A., Kulichkova, E. A. and Petrov, S. E. (2022), “Development of structural elements for the creation of low-noise control valves”, Journal of Dynamics and Vibroacoustics, vol. 8, no. 4, pp. 41-47. doi: 10.18287/2409-4579-2022-8-4-41-47. (In Russian)
  10. Smol'yakov, A. V. (2005), Shum turbulentnykh potokov [Turbulent flow noise], Krylov State Research Centre, St. Petersburg, 312 p. (In Russian)

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