Experimental-numerical analysis of the fracture process in smooth and notched V specimens

Alzyod, H., Ficzere, P. 2023. Correlation Between Printing Parameters and Residual Stress in Additive Manufacturing: A Numerical Simulation Approach . Production Engineering Archives, 29(3), 279-287. DOI: 10.30657/pea.2023.29.32 Search in Google Scholar

ASTM E8 / E8M-16ae1, 2016. ASTM E8 / E8M-16ae1, Standard Test Methods for Tension Testing of Metallic Materials. ASTM International, West Conshohocken. Search in Google Scholar

Bai, Y., Wierzbicki, T., 2008. A new model of metal plasticity and fracture with pressure and Lode dependence. International Journal of Plasticity 24, 1071–1096. DOI: 10.1016/j.ijplas.2007.09.004 Search in Google Scholar

Bao, Y., Wierzbicki, T., 2004. On fracture locus in the equivalent strain and stress triaxiality space. International Journal of Mechanical Sciences, 46, 81–98. DOI: 10.1016/j.ijmecsci.2004.02.006 Search in Google Scholar

Benhamena, A., Fatima, B., Foudil, K., Baltach,, Chaouch, M. 2023. Numerical analysis of fracture behavior of functionally graded materials using 3D-XFEM. Advances in Materials Science, 23(3), 33-46. DOI: 10.2478/adms-2023-0015 Search in Google Scholar

Bokůvka, O., Jambor, M., Trško, L., Nový, F., Lisiecka, B., 2018. Fatigue lifetime of 20MnV6 steel with holes manufactured by various methods. Production Engineering Archives 19, 3–5. DOI: 10.30657/pea. 2018.19.01 Search in Google Scholar

Bucchi, F., Frendo, F., Moreschini, C., 2022. Influence of the stress history and of the Lode angle on the determination of the ductile fracture locus for two steel alloys. Engineering Fracture Mechanics 274, 108759. DOI: 10.1016/j.engfracmech.2022.108759 Search in Google Scholar

Castillo, C., Fernandez, V., Lordan, O., 2021. A Markovian-based simulation model for the evolution of employees’ emotional states during an organizational change. Polish Journal of Management Studies, 23(1), 119-135. DOI: 10.17512/pjms.2021.23.1.08 Search in Google Scholar

Cravero, S., Ruggieri, C., 2007. Estimation procedure of J-resistance curves for SE(T) fracture specimens using unloading compliance. Engineering Fracture Mechanics 74, 2735–2757. DOI: 10.1016/j.engfracmech. 2007.01.012 Search in Google Scholar

Dzioba, I., Lipiec, S., 2019. Fracture Mechanisms of S355 Steel–Experimental Research, FEM Simulation and SEM Observation. Materials, 12, 3959. DOI: 10.3390/ma12233959 Search in Google Scholar

Fan, W., Yang, H., Taylor, A.C., 2023. Numerical analysis of fracture in interpenetrating phase composites based on crack phase field model, Composites Science and Technology, 232, 109873, DOI: 10.1016/j.compscitech.2022.109873. Search in Google Scholar

Fonzo, A., Meleddu, A., Di Biagio, M., 2006. Crack propagation modeling and crack arrestor design for X120. International Pipeline Conference, 317-325. DOI: 10.1115/IPC2006-10319 Search in Google Scholar

Gumen, O., Ujma, A., Kruzhkova, M., 2021. Research into the process of spraying complex titanium and zirconium nitride on structural steel and reaction times relating to the final finish and quality obtained. BoZPE 10, 71–76. DOI: 10.17512/bozpe.2021.1.07 Search in Google Scholar

Jian, S., Hong, Z., Kui, X., 2004. Numerical simulation of dynamic cracks propagation in gas transmission pipeline. Oil and Gas Storage and Transportation, 23, 5–8. Search in Google Scholar

Karkowski, M., Grondys, K., 2021. Performance Assessment of Balance Algorithm Based Motorway Car Park Occupancy Information System. Polish Journal of Management Studies, 24(2), 178-193. DOI: 10.17512/pjms.2021.24.2.11 Search in Google Scholar

Kosiń, M., Pawłowski, K., 2017. Numeryczna analiza złącza przegrody zewnętrznej wykonanej w technologii szkieletowej. BoZPE, 19, 111–120. DOI: 10.17512/bozpe.2017.1.16 Search in Google Scholar

Misawa, K., Imai, Y., Aihara, S., 2011. A New Model for Dynamic Crack Propagation and Arrest in Gas Pipelines. Presented at the 2010 8th International Pipeline Conference, American Society of Mechanical Engineers Digital Collection, 685–694. DOI: 10.1115/IPC2010-31475 Search in Google Scholar

Mitsuya, M., Motohashi, H., Oguchi, N., Aihara, S., 2013. Calculation of Dynamic Stress Intensity Factors for Pipes During Crack Propagation by Dynamic Finite Element Analysis. Journal of Pressure Vessel Technology, 136. DOI: 10.1115/1.4025617 Search in Google Scholar

Neimitz, A., Gałkiewicz, J., Lipiec, S., Dzioba, I., 2018. Estimation of the onset of crack growth in ductile materials. Materials, 11, 1–19. Search in Google Scholar

Parlak, B.O., Yavasoglu, H.A., 2023. A Comprehensive Analysis of In-Line Inspection Tools and Technologies for Steel Oil and Gas Pipelines. Sustainability, 15(3):2783. DOI: 10.3390/su15032783 Search in Google Scholar

Perić, D., Neto, E.A. de S., 1999. A new computational model for Tresca plasticity at finite strains with an optimal parametrization in the principal space. Computer Methods in Applied Mechanics and Engineering, 171, 463–489. DOI: 10.1016/S0045-7825(98)00221-7 Search in Google Scholar

Piątkowski, J, Gajdzik, B, Mesjasz, A., 2020, Assessment of Material Durability of Steam Pipelines Based on Statistical Analysis of Strength Properties–Selected Models. Energies, 13(14), 3633. ttps://doi.org/10.3390/en13143633 Search in Google Scholar

PN-EN ISO 6892-1:2020-05, 2019. PN-EN ISO 6892-1:2020-05, Metallic materials – Tensile testing – Part 1: Method of test at room temperature. International Organization for Standardization, Geneva. Search in Google Scholar

Sharma, V.B,, Singh, K., Gupta, R., Joshi, A., Dubey, R., Gupta, V., Bharadwaj, S., Zafar, M.I, Bajpai, S, Khan, M.A,, et al. 2021, Review of Structural Health Monitoring Techniques in Pipeline and Wind Turbine Industries. Applied System Innovation, 2021; 4(3), 59. DOI: 10.3390/asi4030059 Search in Google Scholar

Song, J.-H., Belytschko, T., 2009. Dynamic Fracture of Shells Subjected to Impulsive Loads. Journal of Applied Mechanics 76. DOI: 10.1115/1.3129711 Search in Google Scholar

Świt, G., Dzioba, I., Adamczak-Bugno, A., Krampikowska, A., 2022. Identification of the Fracture Process in Gas Pipeline Steel Based on the Analysis of AE Signals. Materials, 15, 2659. DOI: 10.3390/ma15072659 Search in Google Scholar

Wierzbicki, T., Bao, Y., Lee, Y.-W., Bai, Y., 2005. Calibration of seven fracture models. International Journal of Mechanical Sciences, 47, 719–743. Search in Google Scholar

Xiaobin, Y., Zhuang, Z., Chuan Jing, Z., 2008. Numerical Simulation on dynamic crack extension of rich gas transmission pipeline. Journal of Tsinghua University: Natural Science Edition, 48, 1355–1358. Search in Google Scholar

Zhao, M.-C., Yang, K., Shan, Y., 2002. The effects of thermo-mechanical control process on microstructures and mechanical properties of a commercial pipeline steel. Materials Science and Engineering, 335, 14–20. DOI: 10.1016/S0921-5093(01)01904-9 Search in Google Scholar