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Study on adaptability to fault slide and aseismic behavior of exposed steel penstock for fault-crossing inverted siphon

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ã€Authorã€‘ SHI Changzheng1,WU Hegao1,LI Yun2,MA Guoping2(1.State Key Laboratory of Water Resources and Hydropower Engineering Science,Wuhan University,Wuhan 430072; 2.Kunming Hydropower Investigation,Design and Research Institute,CHECC,Kunming 650051)

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ã€Abstractã€‘ This paper uses finite element method to analyze the adaptability to fault slide and aseismic behavior of an exposed steel penstock for an inverted siphon that crosses an active fault in a high-intensity earthquake region.The results show that an effective measure for a better adaptability to fault slide is to arrange enough number of bellow expansion joints and install slide supports and hinge supports at certain spacing.By this measure,most of the mass is lumped on the penstock and each span of the penstock separated by the joints has a larger stiffness,so that under earthquake conditions the penstock can move rigidly and only its internal water pressure produce stresses inside its structure.Its axial displacement,however,will be greater and the support rings of hinge supports may be bent seriously.To improve its axial aseismic ability,excessive number of expansion joints should be avoided.The slide supports work as base isolation supports and the hinge supports restrict excessive horizontal displacement.Thus a suitable arrangement of both supports is advantageous in adaptability to differential settlement and also in aseismic ability.To strengthen the supports that must have enough strength,restraining devices should be used to avoid penstock sliding off.æ›´å¤š è¿˜åŽŸ