PSI - Issue 81

Mykola Stashkiv et al. / Procedia Structural Integrity 81 (2026) 143–150

150

Nanda, B., Maity, D., Maiti, D.K., 2014. Crack assessment in frame structures using modal data and unified particle swarm optimization technique. Advances in Structural Engineering 17 (5), 747 – 766. DOI: 10.1260/1369-4332.17.5.747. Pashaee, P., Ghasemzadeh, H.R., 2023. Validation of simulated dynamic behavior of sprayer boom in Solidworks through actual field experiments. Agricultural Engineering International: CIGR Journal 25 (1), 132 – 137. http://orcid.org/0000-0001-7062-6509. Pidgurskyi, I., Yasniy, P., Pidgurskyi, M., Baranovsky, V., Shelestovskii, B., Stashkiv, M., 2022. Mathematical model for estimating SIF K1 during coalescence of two identical surface cracks. Procedia Structural Integrity. 1st Virtual International Conference “In service Damage of Ma terials: Diagnostics and Prediction”, 36, 171 – 176. Pidgurskyi, M., Stashkiv, M., Pidgurskyi, I., 2021. Modeling of crack opening mode SIF for a crack in a thin-walled structural channel beam. Scientific Journal of TNTU (Tern.), vol 102, no 2, pp. 78 – 86. Pidgurskyi, M., Stashkiv, M., Pidgurskyi, I., 2025. Stress redistribution and failure of mobile machines frame during propagation of crack-like defects. Engineering Failure Analysis 170, 109217. https://doi.org/10.1016/j.engfailanal.2024.109217. Pidgurskyi, M., Stashkiv, M., Pidgurskyi, I., Oleksyuk, V., Pidluzhnyi, O., Bykiv, D., Borys, I., Bulaienko, R., Stashkiv, V., Mushak, A., 2024. Methodology of experimental and analytical research of technical systems. Scientific Journal of TNTU (Tern.) 116/4, 50 – 58. Pidgurskyi, M., Stashkiv, M., Rohatynskyi, R., Pidgurskyi, I., Senchyshyn, V., Mushak A., 2024. Investigation of the Stress Intensity Factor for the Edge Crack in I- beam Under Bending Moment. VII International Conference “In -service Damage of Materials: Diagnostics and Prediction (DMDP 2023), 59, 322 – 329. Polishchuk, L., Bilyy, O., Kharchenko, Y., 2016. Prediction of the propagation of crack-like defects in profile elements of the boom of stack discharge conveyor. Eastern-European Journal of Enterprise Technologies 6 (1), 44 – 52. DOI: 10.15587/1729-4061.2016.85502. Rusiński, E., Moczko, P., Czmochowski, J., 2008. Numerical and experimental analysis of a mine's loader boom crack. Automatio n in Construction 17, 3, 271 – 277. Stashkiv, M., 2023. Field Test Data Processing for the Implementation of Accelerated Rig Test of Sprayer Booms. The 3rd International Workshop on Information Technologies: Theoretical and Applied Problems 2023 (ITTAP 2023), 3628. 690 – 701. Stashkiv, M., Lytvynenko I., Stashkiv V., 2022. Test Data Processing Use for Structural Fatigue Life Assessment. The 2st International Workshop on Information Technologies: Theoretical and Applied Problems 2022 (ITTAP 2022), 3309. 241 – 258. Syrotyuk, А.М., Babii, А.V., Barna, R.А., Leshchak, R.L., Marushchak, P.О., 2021. Corrosion -Fatigue Crack-Growth Resistance of Steel of the Frame of a Sprayer Boom. Materials Sciencethis link is disabled 56(4), 466 – 471. DOI 10.1007/s11003-021-00452-2. Vaddadi, R., Gomez, C., Rajkhowa, R., 2021. Virtual Simulation of Sprayer Composite Boom Using 1D Approach. SAE Technical Paper 2021-01-0349. https://doi.org/10.4271/2021-01-0349. Yan, J, Xue, X, Cui, L, Ding, S, Gu, W, Le, F., 2021. Analysis of Dynamic Behavior of Spray Boom under Step Excitation. Applied Sciences 11(21), 10129. https://doi.org/10.3390/app112110129. Yasniy, O., Pyndus, Yu., Iasnii, V., Lapusta , Y. . 2017. Residual lifetime assessment of thermal power plant superheater header. Engineering Failure Analysis 82, 390 - 403