EUREKA: Physics and Engineering.

In connection with the global increase in the intensity of use of working equipment related to high-risk facilities and the expiry of the service life limit, the question arises of determining the actual technical condition and forecasting the residual resource. From the analysis of the approaches to determining the technical state and on the analysis of regulatory documents, it becomes clear that the regulated methods of assessing the technical state are obsolete, such that they do not ensure the reliability of the obtained control results.

A new technique for determining the actual technical state through monitoring the level of stresses in the body of high-risk objects is proposed. The new technique takes into account additional physical and mechanical parameters that affect the stress-strain state, and have not yet been used. In other words, the technique of multivariable control of stress determination was proposed.

Mathematical models of the process of deformation and stress for cylindrical vessels with a spherical and conic dome operating under the action of high pressure are proposed.

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Karpash, A., Tatsakovych, N., Dotsenko, Ye. (2016). Features of the modern control techniques application to determine metal constructions deflected mode. Scientific proceedings «NDT Day 2016», 1 (187), 319–324.

Karpash, O., Karpash, М., Dotsenko, Ye. (2008). Doslidzhennia vzaiemozviazku mizh strukturnym stanom stalei ta fizyko-mekhanichnymy kharakterystykamy stalei. Fizyko-khimichna mekhanika materialiv, 2 (7), 724–729.

Karpash, A. (2012). Analiz vidomykh metodiv kontroliu fizyko-mekhanichnykh kharakterystyk metalu. Naftohazova enerhetyka, 1 (17), 70–82.

Vashchyshak, S., Karpash, А. (2012). Current approaches to the determination of physic-mechanical properties of metals oil and gas facilities. Scientific proceedings «NDT Day 2012», 1 (133), 260–264.

Skalsky, V., Hirnyj, S., Basarab, R. (2013). Nondestructive evaluation of pipelines: magnetoacoustic diagnostics of deformation. Oil and Gas Business, 5, 301–313.

Karpash, M., Dotsenko, Ye., Tatsakovych, N. (2011). New non-destructive methods for physical and mechanical properties evaluation of metalworks materials. Edition of Scientific Machine Union, 19, 32–36.

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Bogusz, P., Poplawski, A., Morka, A., Niezgoda, T. (2015). Evaluation of true stress in engineering materials using optical deformation measurement methods. Journal of KONES. Powertrain and Transport, 19 (4), 53–64. doi: 10.5604/12314005.1138307

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