PSI - Issue 59

B. Ganendra et al. / Procedia Structural Integrity 59 (2024) 238–245 Ganendra et al. / Structural Integrity Procedia 00 (2019) 000 – 000

245

8

References

ABAQUS, 2011 . Abaqus CAE User’s Manual. Dassault Systèmes Simulia Corp., Rhode Island, United States. Adie, P.W., Adiputra, R., Prabowo, A.R., Erwandi, E., Muttaqie, T., Muhayat, N., Huda, N., 2023a. Assessment of the OTEC cold water pipe design under bending loading: A benchmarking and parametric study using finite element approach. Journal of the Mechanical Behavior of Materials 32(1), 20220298. Adie, P.W., Prabowo, A.R., Muttaqie, T., Adiputra, R., Muhayat, N., Carvalho, H., Huda, N., 2023b. Non-linear assessment of cold water pipe (CWP) on the ocean thermal energy conversion (OTEC) installation under bending load. Procedia Structural Integrity 47, 142-149. Adiputra, R., Fauzi, F.N., Firdaus, N., Suyanto, E.M., Kasharjanto, A., Puryantini, N., Erwandi, E., Rasgianti, R., Prabowo, A.R., 2023. Roundness and slenderness effects on the dynamic characteristics of spar-type floating offshore wind turbine. Curved and Layered Structures 10(1), 20220213. AISC, 2022. Specification for Structural Steel Buildings. American Institute of Steel Construction, Chicago, United States. Chen, Y., Wu, D., Dai, K., Gao, W., 2022. A numerically efficient framework in failure mode evaluation of a wind turbine tower under cyclones. Marine Structures 86, 103303. Chen, J., Zhang, M., Zhu, H., Xu, F., Shao, Z, Ding, F., Xiang, P., 2024. Study on mechanical properties of wind turbine tower reinforced by ribbed interlayer. Journal of Constructional Steel Research 212, 108256. Chou, C.C., Kuo, M.C., Lee, C.S., 2021. Cyclic flexural test and loading protocol for steel wind turbine tower columns. Thin-Walled Structures 166, 108093. Do, Q.T., Ghanbari-Ghazijahani, T., Prabowo, A.R., 2023. Developing empirical formulations to predict residual strength and damages in tension-leg platform hulls after a collision. Ocean Engineering 286, 115668. Do, Q.T., Muttaqie, T., Nhut, P.-T., Vu, M.T., Khoa, N.D., Prabowo, A.R., 2022. Residual ultimate strength assessment of submarine pressure hull under dynamic ship collision. Ocean Engineering 266, 112951. El Yaakoubi, A., Bouzem, A., El Alami, R., Chaibi, N., Bendaou, O., 2023. Wind turbines dynamics loads alleviation: Overview of the active controls and the corresponding strategies. Ocean Engineering 278, 114070. European Standard., 2007. Eurocode 3 - Design of steel structures - Part 1-6: Strength and Stability of Shell Structures. European Standard s.r.o., Pilsen, Czech Republic. Ganendra, B., Prabowo, A.R., Muttaqie, T., Adiputra, R., Ridwan, R., Fajri, A., Do, Q.T., Carvalho, H., Baek, S.J., 2023. Thin-walled cylindrical shells in engineering designs and critical infrastructures: A systematic review based on the loading response. Curved and Layered Structures 10(1), 20220202. Guo, L., Yang, S., Jiao, H., 2013. Behavior of thin-walled circular hollow section tubes subjected to bending. Thin-Walled Structures 73, 281 – 289. Gupta, A., Rotea, M.A., Chetan, M., Sakib, M.S., Griffith, D.T., 2021. A Methodology for Robust Load Reduction in Wind Turbine Blades Using Flow Control Devices. Energies 14(12), 3500. Kang, S.Y., Won, D., Park, J.S., Kang, Y.J., Kim, S., 2021. Structural Behavior of Large-Diameter Cylindrical Shell with Stiffened Opening. Metals 11(9), 1413. Li, S.Z., Zhou, X.H., Gao, Y., Wang, Y.H., Gan, D., Ren, W., Lai, M.H., Zhu, R.H., 2023. Damage detection of concrete segment in steel concrete hybrid wind turbine tower. Structures 56, 105009. Lutfi, Y.M., Adiputra, R., Prabowo, A.R., Utsunomiya, T., Erwandi, E., Muhayat, N., 2023. Assessment of the stiffened panel performance in the OTEC seawater tank design: Parametric study and sensitivity analysis. Theoretical and Applied Mechanics Letters 13(4), 100452. Naufal, A.M., Prabowo, A.R., Muttaqie, T., Hidayat, A., Adiputra, R., Muhayat, N., Hadi, S., Yaningsih, I., 2023. Three-point bending assessment of cold water pipe (CWP) sandwich material for ocean thermal energy conversion (OTEC). Procedia Structural Integrity 47, 133 141. Prabowo, A.R., Byeon, J.H., Cho, H.J., Sohn, J.M., Bae, D.M., Cho, J.H., 2018. Impact phenomena assessment: Part I-Structural performance of a tanker subjected to ship grounding at the Arctic. MATEC Web of Conferences 159, 02061. Prabowo, A.R., Ridwan, R., Tuswan, T., Imaduddin, F., 2022. Forecasting the Effects of Failure Criteria in Assessing Ship Structural Damage Modes. Civil Engineering Journal (Iran) 8(10), 2053 – 2068. Prabowoputra, D.M., Prabowo, A.R., Hadi, S., Sohn, J.M., 2021. Assessment of turbine stages and blade numbers on modified 3D Savonius hydrokinetic turbine performance using CFD analysis. Multidiscipline Modeling in Materials and Structures 17(1), 253 – 272. Serrano-Gon zález, J., Lacal- Arántegui, R., 2016. Technological evolution of onshore wind turbines — a market-based analysis. Wind Energy 19(12), 2171 – 2187. Showkati, H., Shahandeh, R., 2010. Experiments on the Buckling Behavior of Ring-Stiffened Pipelines under Hydrostatic Pressure. Journal of Engineering Mechanics 136(4), 464 – 471. Yadav, K.K., Gerasimidis, S., 2019. Instability of thin steel cylindrical shells under bending. Thin-Walled Structures 137, 151 – 166. Zhang, D., Liu, Z., Li, W., Zhang, J., Cheng, L., Hu, G., 2024. Fluid-structure interaction analysis of wind turbine aerodynamic loads and aeroelastic responses considering blade and tower flexibility. Engineering Structures 301, 117289.