Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge
Dam reliability analysis is performed to determine the structural integrity of dams and, hence, to prevent dam failure. The Chenderoh Dam structure is divided into five parts: the left bank, right bank, spillway, intake section, and bottom outlet, with each element performing standalone functions to...
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my.uniten.dspace-343002024-10-14T11:18:55Z Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge Mohd Radzi M.R. Zawawi M.H. Abas M.A. Ahmad Mazlan A.Z. Mohd Arif Zainol M.R.R. Hassan N.H. Che Wan Zanial W.N. Dullah H. Kamaruddin M.A. 57223347606 39162217600 56893346700 57216895962 57193313971 57204683370 57205239441 57199323863 44361188400 Ansys bottom outlet computational fluid dynamics (CFD) fluid flow dynamic fluid-structural interaction Dams Failure (mechanical) Fracture mechanics Reliability analysis Reservoirs (water) Structural analysis Yield stress Ansys Bottom outlet Computational fluid dynamic Fluid flow dynamics Fluid structural interactions Fluid-structure interaction Integrity analysis Interaction modeling Outlet structures Structure integrity boundary condition computational fluid dynamics dam failure fluid flow fluid-structure interaction three-dimensional modeling Computational fluid dynamics Dam reliability analysis is performed to determine the structural integrity of dams and, hence, to prevent dam failure. The Chenderoh Dam structure is divided into five parts: the left bank, right bank, spillway, intake section, and bottom outlet, with each element performing standalone functions to maintain the overall Dam�s continuous operation. This study presents a numerical reliability analysis of water dam reservoir banks using fluid�structure interaction (FSI) simulation of the bottom outlet structures operated at different discharge conditions. Three-dimensional computer-aided drawings were used to view the overall Chenderoh Dam. Next, a two-way fluid�structure interaction (FSI) model was developed to explore the influence of fluid flow and structural deformation on dam systems. The FSI modeling consists of Ansys Fluent and Ansys Structural modules to consider the boundary conditions separately. The reliability and performance of the reservoir bottom outlet structure was effectively simulated and recognised using FSI. The maximum stress on the bottom outlet section is 18.4 MPa, which is lower than the yield stress of mild steel of 370 MPa. Therefore, there will be no structural failure being observed on the bottom outlet section when the butterfly valve is fully closed. With a few exceptions, the FSI models projected that bottom outlet structures would be able to run under specified conditions without structural collapse or requiring interventions due to having lower stress than the material�s yield strength. � 2023 by the authors. Final 2024-10-14T03:18:55Z 2024-10-14T03:18:55Z 2023 Article 10.3390/w15061039 2-s2.0-85152380350 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85152380350&doi=10.3390%2fw15061039&partnerID=40&md5=5771a0d5d25585bce2fa37dd8c74f88d https://irepository.uniten.edu.my/handle/123456789/34300 15 6 1039 All Open Access Gold Open Access MDPI Scopus |
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Ansys bottom outlet computational fluid dynamics (CFD) fluid flow dynamic fluid-structural interaction Dams Failure (mechanical) Fracture mechanics Reliability analysis Reservoirs (water) Structural analysis Yield stress Ansys Bottom outlet Computational fluid dynamic Fluid flow dynamics Fluid structural interactions Fluid-structure interaction Integrity analysis Interaction modeling Outlet structures Structure integrity boundary condition computational fluid dynamics dam failure fluid flow fluid-structure interaction three-dimensional modeling Computational fluid dynamics |
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Ansys bottom outlet computational fluid dynamics (CFD) fluid flow dynamic fluid-structural interaction Dams Failure (mechanical) Fracture mechanics Reliability analysis Reservoirs (water) Structural analysis Yield stress Ansys Bottom outlet Computational fluid dynamic Fluid flow dynamics Fluid structural interactions Fluid-structure interaction Integrity analysis Interaction modeling Outlet structures Structure integrity boundary condition computational fluid dynamics dam failure fluid flow fluid-structure interaction three-dimensional modeling Computational fluid dynamics Mohd Radzi M.R. Zawawi M.H. Abas M.A. Ahmad Mazlan A.Z. Mohd Arif Zainol M.R.R. Hassan N.H. Che Wan Zanial W.N. Dullah H. Kamaruddin M.A. Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge |
| description |
Dam reliability analysis is performed to determine the structural integrity of dams and, hence, to prevent dam failure. The Chenderoh Dam structure is divided into five parts: the left bank, right bank, spillway, intake section, and bottom outlet, with each element performing standalone functions to maintain the overall Dam�s continuous operation. This study presents a numerical reliability analysis of water dam reservoir banks using fluid�structure interaction (FSI) simulation of the bottom outlet structures operated at different discharge conditions. Three-dimensional computer-aided drawings were used to view the overall Chenderoh Dam. Next, a two-way fluid�structure interaction (FSI) model was developed to explore the influence of fluid flow and structural deformation on dam systems. The FSI modeling consists of Ansys Fluent and Ansys Structural modules to consider the boundary conditions separately. The reliability and performance of the reservoir bottom outlet structure was effectively simulated and recognised using FSI. The maximum stress on the bottom outlet section is 18.4 MPa, which is lower than the yield stress of mild steel of 370 MPa. Therefore, there will be no structural failure being observed on the bottom outlet section when the butterfly valve is fully closed. With a few exceptions, the FSI models projected that bottom outlet structures would be able to run under specified conditions without structural collapse or requiring interventions due to having lower stress than the material�s yield strength. � 2023 by the authors. |
| author2 |
57223347606 |
| author_facet |
57223347606 Mohd Radzi M.R. Zawawi M.H. Abas M.A. Ahmad Mazlan A.Z. Mohd Arif Zainol M.R.R. Hassan N.H. Che Wan Zanial W.N. Dullah H. Kamaruddin M.A. |
| format |
Article |
| author |
Mohd Radzi M.R. Zawawi M.H. Abas M.A. Ahmad Mazlan A.Z. Mohd Arif Zainol M.R.R. Hassan N.H. Che Wan Zanial W.N. Dullah H. Kamaruddin M.A. |
| author_sort |
Mohd Radzi M.R. |
| title |
Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge |
| title_short |
Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge |
| title_full |
Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge |
| title_fullStr |
Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge |
| title_full_unstemmed |
Structure Integrity Analysis Using Fluid�Structure Interaction at Hydropower Bottom Outlet Discharge |
| title_sort |
structure integrity analysis using fluid�structure interaction at hydropower bottom outlet discharge |
| publisher |
MDPI |
| publishDate |
2024 |
| _version_ |
1814061174321315840 |
| score |
13.23648 |