Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train Vibration
Taking Liangxiang Pagoda built in Liao Dynasty in Beijing as the research object, the vibration responses of the pagoda in the east-west direction and south-north direction under the action of trains on the Beijing–Guangzhou Railway Line and microseism were tested. On this basis, a numerical model w...
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Hindawi Limited
2020-01-01
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| Series: | Advances in Civil Engineering |
| Online Access: | http://dx.doi.org/10.1155/2020/7236310 |
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doaj-b8cb5ee3f81a4a4c9bb82a65d1b36a472020-11-25T04:01:26ZengHindawi LimitedAdvances in Civil Engineering1687-80861687-80942020-01-01202010.1155/2020/72363107236310Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train VibrationQian Xia0Jin Zhao1Defa Wang2Yiqing Li3School of Civil Engineering and Architecture, Xi’an University of Technology, Xi’an 710048, ChinaSchool of Civil Engineering and Architecture, Xi’an University of Technology, Xi’an 710048, ChinaSchool of Civil Engineering and Architecture, Xi’an University of Technology, Xi’an 710048, ChinaShaanxi JDWG Quality Testing Technology Co., Ltd., Xi’an 710018, ChinaTaking Liangxiang Pagoda built in Liao Dynasty in Beijing as the research object, the vibration responses of the pagoda in the east-west direction and south-north direction under the action of trains on the Beijing–Guangzhou Railway Line and microseism were tested. On this basis, a numerical model was established by using ANSYS to further calculate the dynamic response of the pagoda, and the safety and integrity of the pagoda were evaluated based on existing standards. Cumulative fatigue damage theory was introduced to predict the remaining fatigue life of Liangxiang Pagoda. The following conclusions have been drawn: in the two directions mentioned above, the natural vibration frequencies of the pagoda of the first three orders are similar; the 1st-order vibration modes in the plane are bending, and the vibration modes of the 2nd and 3rd orders are shear-bending; under the action of trains, the peak vibration value of Liangxiang Pagoda at the position that bears the maximum load is 0.053 mm/s, which has a little impact on the safety and integrity of the pagoda; under the combined action of gravity and trains, the remaining fatigue life of Liangxiang Pagoda is 5.26×107 times. The research method used in this paper can provide data and scientific support for the protection of historical buildings, as well as the basis for the follow-up research of the studied ancient pagoda.http://dx.doi.org/10.1155/2020/7236310 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Qian Xia Jin Zhao Defa Wang Yiqing Li |
| spellingShingle |
Qian Xia Jin Zhao Defa Wang Yiqing Li Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train Vibration Advances in Civil Engineering |
| author_facet |
Qian Xia Jin Zhao Defa Wang Yiqing Li |
| author_sort |
Qian Xia |
| title |
Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train Vibration |
| title_short |
Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train Vibration |
| title_full |
Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train Vibration |
| title_fullStr |
Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train Vibration |
| title_full_unstemmed |
Analysis of Dynamic Response and Fatigue Life of Masonry Pagoda under the Influence of Train Vibration |
| title_sort |
analysis of dynamic response and fatigue life of masonry pagoda under the influence of train vibration |
| publisher |
Hindawi Limited |
| series |
Advances in Civil Engineering |
| issn |
1687-8086 1687-8094 |
| publishDate |
2020-01-01 |
| description |
Taking Liangxiang Pagoda built in Liao Dynasty in Beijing as the research object, the vibration responses of the pagoda in the east-west direction and south-north direction under the action of trains on the Beijing–Guangzhou Railway Line and microseism were tested. On this basis, a numerical model was established by using ANSYS to further calculate the dynamic response of the pagoda, and the safety and integrity of the pagoda were evaluated based on existing standards. Cumulative fatigue damage theory was introduced to predict the remaining fatigue life of Liangxiang Pagoda. The following conclusions have been drawn: in the two directions mentioned above, the natural vibration frequencies of the pagoda of the first three orders are similar; the 1st-order vibration modes in the plane are bending, and the vibration modes of the 2nd and 3rd orders are shear-bending; under the action of trains, the peak vibration value of Liangxiang Pagoda at the position that bears the maximum load is 0.053 mm/s, which has a little impact on the safety and integrity of the pagoda; under the combined action of gravity and trains, the remaining fatigue life of Liangxiang Pagoda is 5.26×107 times. The research method used in this paper can provide data and scientific support for the protection of historical buildings, as well as the basis for the follow-up research of the studied ancient pagoda. |
| url |
http://dx.doi.org/10.1155/2020/7236310 |
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AT qianxia analysisofdynamicresponseandfatiguelifeofmasonrypagodaundertheinfluenceoftrainvibration AT jinzhao analysisofdynamicresponseandfatiguelifeofmasonrypagodaundertheinfluenceoftrainvibration AT defawang analysisofdynamicresponseandfatiguelifeofmasonrypagodaundertheinfluenceoftrainvibration AT yiqingli analysisofdynamicresponseandfatiguelifeofmasonrypagodaundertheinfluenceoftrainvibration |
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