«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

¡¶½¨Öþ¿ÆѧÓ빤³Ìѧ±¨¡·[ISSN:1673-2049/CN:61-1442/TU]

¾í:

35¾í

ÆÚÊý:

2018Äê04ÆÚ

Ò³Âë:

19-26

À¸Ä¿:

³ö°æÈÕÆÚ:

2018-07-30

ÎÄÕÂÐÅÏ¢/Info

Title:

Seismic Response Analysis and Performance Evaluation of Long-span Cable-stayed Bridge Based on ANSYS

×÷Õß:

ÕÔÈ˴ÐíÖÇÇ¿£¬×Þ½¨²¨£¬¼Ö Ò㣬Àº£

Î÷ÄϽ»Í¨´óѧÍÁľ¹¤³ÌѧԺ

Author(s):

ZHAO Ren-da, XU Zhi-qiang, ZOU Jian-bo, JIA Yi, LI Fu-hai

School of Civil Engineering, Southwest Jiaotong University

¹Ø¼ü´Ê:

бÀ­ÇÅ; µØÕðÏìÓ¦·ÖÎö; ·ÇÏßÐÔʱ³Ì·ÖÎö·¨; ¶¯Á¦ÌØÐÔ; Íä¾ØÇúÂÊ; ÄÜÁ¦ÐèÇó±È

Keywords:

cable-stayed bridge;  seismic response analysis;  nonlinear time-history analysis method;  dynamic characteristic;  moment curvature;  capacity demand ratio

·ÖÀàºÅ:

-

DOI:

-

ÎÄÏ×±êÖ¾Âë:

A

ÕªÒª:

ΪÑо¿Î÷²¿¸ßÁҶȵØÇø´ó¿ç¶ÈбÀ­ÇŵĵØÕðÏìÓ¦Ìص㣬ÒÔÀ¼ÖÝÊÐÄÏÈƳǸßËÙ¹«Â·ÉÏÒ»×ù¿ç¾¶Îª177 m+360 m+177 mµÄ½áºÏÁºÐ±À­ÇÅΪÑо¿¶ÔÏó£¬ÀûÓÃÓÐÏÞÔªÈí¼þANSYS½¨Á¢Æä¿Õ¼ä¼ÆËãÄ£ÐÍ£¬·ÖÎöÁ˸ÃÇŵĶ¯Á¦ÌØÐÔ¡£ÔËÓ÷ÇÏßÐÔʱ³Ì·ÖÎö·¨¼ÆËãÇÅÁº½á¹¹ÔÚ50Ä곬Խ¸ÅÂÊ10%ºÍ2%Á½ÖÖµØÕðˮƽ×÷ÓÃϵĵØÕðÏìÓ¦£¬²¢ÒÔ¹¹¼þµÄÄÜÁ¦ÐèÇó±ÈÆÀ¹ÀÁ˸ÃÇŵĿ¹ÕðÐÔÄÜ¡£½á¹û±íÃ÷£ºµØÕð×÷ÓÃÏÂÖ÷Áº×ÝÏòÕñ¶¯ÓëºáÏòÕñ¶¯»ù±¾²»ñîºÏ£¬ÆäÊúÏòλÒÆÊÜ×ÝÏòµØÕð×÷ÓÃÓ°Ïì½Ï´ó£»ÓÉÓڽṹµÄ·Ç¶Ô³ÆÐÔ£¬5ª¬#Ëþ£¨ÄÏÇÅËþ£©µÄËþ¶¥Î»ÒƼ°Ëþµ×Íä¾Ø¾ù´óÓÚ4ª¬#Ëþ£¨±±ÇÅËþ£©£»ÔÚE1ºÍE2Á½ÖÖˮƽµØÕð×÷ÓÃÏ£¬¸÷ÇŶպÍÇÅËþ¹Ø¼ü½ØÃæÒÔ¼°Ð±À­Ë÷×îСÄÜÁ¦ÐèÇó±È¾ù´óÓÚ1£¬Âú×㿹ÕðÐÔÄÜÒªÇ󣻸÷ÇŶÕ×ÝÇÅÏòÄÜÁ¦ÐèÇó±ÈСÓÚºáÇÅÏò£¬¶øÇÅËþ×ÝÇÅÏòÄÜÁ¦ÐèÇó±È´óÓÚºáÇÅÏò£¬½¨ÒéÔÚ¹ý¶É¶ÕºÍ¸¨Öú¶ÕÉÏ°²×°¼õ¸ôÕð×°Ö㬼ÓÇ¿Æä×ÝÇÅÏò¿¹ÕðÐÔÄÜ¡£

Abstract:

In order to study the seismic response characteristics of the long-span cable-stayed bridge in the western high-intensity area, a long-span cable-stayed bridge with span of 177 m+360 m+177 m on Lanzhou south bypass expressway was taken as study object. The spatial dynamic model was established by finite element software ANSYS, the dynamic characteristics of the bridge were analyzed. The nonlinear seismic time-history analysis was used to calculate the seismic response of bridge structure under the 50-year probability of over 10% and over 2%. Besides, the seismic performance of the bridge was evaluated by the capacity demand ratio method. The results show that the longitudinal vibration of the main girder is not coupled with the lateral vibration under the earthquake. The vertical displacement of the main girder is greatly influenced by the longitudinal seismic action. Due to the asymmetry of the structure, the tower top displacement and the bottom bending moment of the tower 5 (south bridge tower) are all larger than those of the tower 4(north bridge tower). Under the two kinds of horizontal earthquakes of E1 and E2, the minimum capacity demand ratios of the key sections of piers and towers and the cables are greater than 1, and the seismic performance requirements are met. The longitudinal capacity demand ratio of piers is smaller than transverse ratio, while the longitudinal capacity demand ratio of bridge tower is larger that transverse ratio. It is recommended to install the antiª²seismic device on the transition pier and the auxiliary piers to strengthen the longitudinal bridge seismic performance.

²Î¿¼ÎÄÏ×/References:

ÏàËÆÎÄÏ×/References:

[1]ÑîÏþÑÞ,¹±½ðöÎ,ÕÅÆôΰ.Ëæ»ú³µÁ¾ºÉÔØ×÷ÓÃÏÂбÀ­Ë÷Ë÷Á¦µÄ¸ÅÂÊÄ£Ðͼ°¿É¿¿¶È·ÖÎö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2014,31(02):90.
¡¡[J].Journal of Architecture and Civil Engineering,2014,31(04):90.
[2]Íõ ÌÎ,ÉòÈñÀû.ÁгµºÉÔØ×÷ÓÃÏÂÌú·бÀ­ÇÅË÷-ÁºÏà¹ØÕñ¶¯Ñо¿[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2015,32(06):92.
¡¡WANG Tao,SHEN Rui-li.Research on Characteristics of Cable-beam Vibration of Railway Cable-stayed Bridge Under Train Load[J].Journal of Architecture and Civil Engineering,2015,32(04):92.
[3]ÍõÁ¬»ª,¶¡±üê»,ÀîÁ¢·å.бÀ­ÇÅêÀ­°å×ã³ßÄ£ÐÍÆ£ÀÍÊÔÑé[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2016,33(05):50.
¡¡WANG Lian-hua,DING Bing-hao,LI Li-feng.Fatigue Test of Full-scale Model of Tensile Anchor Plate in Cable-stayed Bridge[J].Journal of Architecture and Civil Engineering,2016,33(04):50.
[4]ÖÜÊ¿½ð,ÁõÈÙ¹ð,²Ì¶«Éý,µÈ.CFRPË÷ºÍ¸ÖË÷бÀ­ÇŵØÕðÏìÓ¦·ÖÎöÓ뿹ÕðÑéËã[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2009,26(03):76.
¡¡ZHOU Shi-jin,LIU Rong-gui,CAI Dong-sheng,et al.Seismic Response Analysis and Seismic Resistance Checking of Cable-stayed Bridges with CFRP Cables and Steel Cables[J].Journal of Architecture and Civil Engineering,2009,26(04):76.
[5]¸ß½£,ÅááºÉ½.´ó¿ç¶ÈбÀ­ÇÅË÷ÁºÃªÏä¿Õ¼äÊÜÁ¦·ÖÎö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2006,23(03):66.
¡¡GAO Jian,PEI Min-shan.Analysis of Space Stress in Anchoring Box Between Cable andBeam of Long-Span Cable-Stayed Bridge[J].Journal of Architecture and Civil Engineering,2006,23(04):66.
[6]ÕÔÈË´ï,×Þ½¨²¨,ÂÀ Áº,µÈ.´ó¿ç¶ÈµþºÏÁºÐ±À­ÇÅ·ÇÏßÐÔÎȶ¨Ñо¿[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2018,35(04):11.
¡¡ZHAO Ren-da,ZOU Jian-bo,LU Liang,et al.Research on Nonlinear Stability of Long-span Composite Girder Cable-stayed Bridge[J].Journal of Architecture and Civil Engineering,2018,35(04):11.
[7]ÀîÁ¢·å,²Ü·½ÁÁ,ºú˼´Ï,µÈ.Ðв¨Ð§Ó¦Ï¸߶նàËþбÀ­ÇŵØÕðÒ×ËðÐÔ·ÖÎö[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2019,36(02):77.
¡¡LI Li-feng,CAO Fang-liang,HU Si-cong,et al.Seismic Fragility Analysis of High-pier Multi-tower Cable-stayed Bridge Under Traveling Wave Effect[J].Journal of Architecture and Civil Engineering,2019,36(04):77.
[8]º« ʯ,ÁõÓÀ½¡,ÍõÕñ»ª,µÈ.¸ßº®µØÇø×éºÏÁºÐ±À­ÇÅÊ©¹¤½×¶ÎζÈЧӦÑо¿[J].½¨Öþ¿ÆѧÓ빤³Ìѧ±¨,2021,38(05):107.[doi:10.19815/j.jace.2021.04004]
¡¡HAN Shi,LIU Yong-jian,WANG Zhen-hua,et al.Study on Temperature Effect of Composite Girder Cable-stayed Bridge During Construction in Alpine Region[J].Journal of Architecture and Civil Engineering,2021,38(04):107.[doi:10.19815/j.jace.2021.04004]

±¸×¢/Memo

±¸×¢/Memo:

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2018-07-18