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    請使用永久網址來引用或連結此文件: http://ir.lib.ncu.edu.tw/handle/987654321/94511


    題名: 應用多項式摩擦單擺支承於鋼筋混凝土建築之非線性動力歷時分析
    作者: 劉辰星;LIU, CHEN-XING
    貢獻者: 土木工程學系
    關鍵詞: 多項式摩擦單擺支承;摩擦單擺支承;Takeda 遲滯模型;Modified Takeda 模型;基於等效節點割線特性之隱式動力分析程序;近斷層震波;Polynomial Friction Pendulum Isolator;Friction Pendulum Isolator;Takeda model;modified Takeda model;Implicit Dynamic Analysis Procedure based on Equivalent Nodal Secant Properties;Near-Fault Ground Motion
    日期: 2024-07-30
    上傳時間: 2024-10-09 14:50:32 (UTC+8)
    出版者: 國立中央大學
    摘要: 根據過去經驗,傳統有限元素法在面對大量非線性的問題時容易產生數值發散問題,導致分析時間過長或是無法順利完成分析,為解決此問題本研究使用基於等效節點割線特性之隱式動力分析程序(Implicit Dynamic Analysis Procedure based on Equivalent Nodal Secant Properties, IDAP-ENSP)。
    本研究分析之模型為位於台中之5層樓鋼筋混凝土建物,因其建造年代較為久遠,分析上應考慮到其勁度衰減之情形,因此本研究新增Modified Takeda模型進入IDAP-ENSP中,並由於梁斷面上下層配筋量不同,吾將模型改善為可考慮斷面上下層配筋不同情形。
    分析上雖然非線性動力歷時分析能夠更真實的反應結構物面臨地震作用下之實際行為,但非線性動力歷時分析較為繁複且礙於現今市面上可用軟體其計算上耗時且容易數值發散,且難以模擬建物破壞後之高度非線性之行為,因此使用上較為困難,因此工程師較習慣以非線性靜力分析代替。本研究將考慮目標建物倒塌破壞前之行為,並分析1.未隔震 2.使用FPS隔震 3.使用PFPI隔震,與(1)使用Takeda模型(2)使用Modified Takeda模型作為塑鉸遲滯行為之建物。可得知使用PFPI之隔震效果最佳,其次FPS最後是未隔震建物;遲滯模型的選用上因本研究建物年代較為久遠,房屋會有所損傷耐震能力會衰減因此使用Modified Takeda較為合適。
    本研究亦比較傳統使用性能設計考慮層間變位之方式與本研究直接設定構件降伏、破壞行為之關聯。可以發現考慮層間變位之結果本研究結論相符。
    ;Based on past experience, traditional finite element methods tend to
    encounter numerical divergence issues when dealing with highly nonlinear
    problems, leading to prolonged analysis times or the inability to complete the
    analysis successfully. To address this issue, this study employs an Implicit
    Dynamic Analysis Procedure based on Equivalent Nodal Secant Properties
    (IDAP-ENSP).
    The model analyzed in this study is a five-story reinforced concrete building
    located in Taichung. Given its age, the analysis considers the stiffness degradation
    of the structure. Therefore, this study incorporates the Modified Takeda model
    into IDAP-ENSP. Additionally, due to the different reinforcement amounts in the
    upper and lower layers of the beam section, the model is improved to account for
    these differences.
    Although nonlinear dynamic time-history analysis can more realistically
    reflect the actual behavior of structures under seismic action, it is more complex
    and, given the current software available on the market, time-consuming in
    calculation and prone to numerical divergence. Moreover, it is difficult to simulate
    highly nonlinear behavior after the building′s failure, making its use more
    challenging. As a result, engineers often prefer nonlinear static analysis instead.
    This study considers the behavior of the target building before collapse and
    analyzes three scenarios: 1. without seismic isolation, 2. with FPS seismic
    isolation, and 3. with PFPI seismic isolation. It also examines the building′s plastic
    hinge hysteretic behavior using (1) the Takeda model and (2) the Modified Takeda
    model. The results show that PFPI provides the best seismic isolation, followed
    by FPS, and lastly, the building without seismic isolation. Given the building′s
    age, which may lead to reduced seismic resistance due to damage, the Modified
    Takeda model is more appropriate.
    ii
    This study also compares the traditional performance design method, which
    considers inter-story displacement, with this study′s approach of directly setting
    the relationship between component yield and failure behavior. It is found that the
    results considering inter-story displacement are consistent with the conclusions of
    this study.
    顯示於類別:[土木工程研究所] 博碩士論文

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