博碩士論文 110325601 詳細資訊

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姓名 安琪拉(Angela Louise Antonio)  查詢紙本館藏   畢業系所 土木系營建管理碩士班
論文名稱
(Development of a Risk-based Maintenance Prioritization Framework for Taiwan Highway Bridges)
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摘要(中) 橋梁維護的優先順序通常根據橋梁構件的狀況來決定,而未考慮整體橋梁可能崩壞或倒塌的風險。目前,臺灣公路橋梁使用交通部(MOTC)所規定的DER&U方法進行檢測,檢測後由橋梁各個構件的D、E、R,與U值計算整體的橋梁狀況指標(Condition Index, CI)。然而,此方法的實施過程中存在諸多問題,例如:(1)橋梁狀況指標CI無法正確反應橋梁實際狀況之差異,具有相似CI值的橋梁其崩壞風險未必相同;(2)CI的計算是基於構件劣化情況的扣分機制,具大量橋梁構件的橋梁,其CI值相對會較低;(3)儘管所有D、E、R和U的檢測數據對於橋梁的整體狀況具有重要意義,但構件的U值仍然是目前維護優先順序的決定性因素。
因此,為了解決這些問題,本研究對不同國家使用的橋梁狀況指標(包括基於風險建立的指標)進行文獻回顧,參酌各國的檢測結果以及指標的建立方式,建立適合DER&U檢測方式的橋梁風險評估架構以計算橋梁的風險指標(Risk Index, RI)。本研究從台灣地區橋梁管理資訊系統(Taiwan Bridge Management System, TBMS)中隨機選擇的七種不同類型的橋梁,計算其CI和RI以驗證本研究之成果。結果顯示,重要構件劣化最嚴重的橋梁會具有最高的RI值,即維護優先順序為最高;而非重要性構件即便劣化嚴重該橋梁的RI值會較低,其維護優先順序亦較低。因此,本研究所建立的橋梁風險評估架構可凸顯整體橋梁可能的崩壞風險,可供橋梁管理機關於擬定橋梁維護優選排序決策時之參考。
摘要(英) The priority of bridge maintenance is usually determined based on the condition of bridge components, without considering the risk of collapse of the bridge. At present, Taiwan′s highway bridges use the DER&U method regulated by the Ministry of Communications (MOTC) for inspection, and the overall bridge condition index (CI) is calculated from the D, E, R and U values of each component of the bridge after inspection. However, there are many problems in the implementation of this method, such as: (1) the bridge condition index CI cannot correctly reflect the difference in the actual condition of the bridge, and the risk of collapse of bridges with similar CI values may not be the same; (2) the calculation of CI is based on a point-deduction mechanism of component deterioration, and the CI value of bridges with a large number of bridge components will be relatively low; (3) although all the detection data of D, E, R and U are important for the overall condition of the bridge, however, the U value of the component becomes the decisive factor in the current maintenance priority.
Therefore, in order to solve these issues, this study reviews the bridge condition indexes (including risk-based indexes) used in different countries, and establishes a bridge risk assessment framework suitable for DER&U inspection methodology to calculate the risk index (RI) of bridges, taking into account their inspection results and establishment of indexes. In this study, seven different types of bridges were randomly selected from the Taiwan Bridge Management System (TBMS) to calculate their CI and RI to verify the results of this study. The results show that the bridge with the most deterioration of important components will have the highest RI value, that is, the maintenance priority will be the highest. Even if the non-critical component is severely deteriorated, the RI value of the bridge will be low, and its maintenance priority will be lower. Therefore, the bridge risk assessment framework established by this study can highlight the possible collapse risk of the overall bridge, which can be used as a reference for bridge management machines when formulating bridge maintenance priority decisions.
關鍵字(中) ★ 橋梁狀況指標
★ 橋梁風險指標
★ 橋梁維護優選排序
★ DER&U檢測
關鍵字(英) ★ bridge condition index
★ bridge risk index
★ bridge maintenance prioritization
★ DER&U methodology
論文目次 摘 要 I
ABSTRACT II
ACKNOWLEDGMENT III
TABLE OF CONTENTS IV
LIST OF FIGURES VII
LIST OF TABLES IX
CHAPTER 1: INTRODUCTION 1
1.1 Research Background and Motivation 1
1.2 Research Problem 2
1.3 Research Objectives 3
1.4 Limitations 3
1.5 Research Flowchart 3
CHAPTER 2: LITERATURE REVIEW 6
2.1 Bridge Inspection Methods 6
2.1.1 China 8
2.1.2 Japan 8
2.1.3 South Korea 9
2.1.4 United States of America 9
2.1.5 United Kingdom 13
2.1.6 South Africa 15
2.1.7 Finland 16
2.1.8 France 18
2.1.9 Germany 19
2.1.10 Norway 21
2.1.11 Sweden 23
2.1.12 Denmark 24
2.1.13 Summary of Bridge Inspection Methods 26
2.2 Bridge Condition Indices 27
2.2.1 Ratio-based approach 27
2.2.2 Weighted Averaging approach 29
2.2.3 Worst-conditioned component 37
2.2.4 Qualitative Method 42
2.2.6 SR approach 45
2.2.7 Risk-based Approach 46
2.3 Taiwan bridge inspection practice and condition indices 47
2.3.1 Bridge Inspection Method 47
2.3.2 DER&U Rating 47
2.3.3 Bridge condition index 48
2.4 Bridge Deterioration and the Collapse of Nanfang’ao Bridge 50
2.4.1 Defects related to Deterioration 50
2.4.2 The Collapse of Nanfang’ao Bridge 51
2.5 Risk Assessment 52
2.5.1 Quantitative Approach 53
2.5.2 Qualitative Approach 55
2.5.3 Semi-Quantitative Risk Analysis 56
2.6 Chapter Summary 56
CHAPTER 3: METHODOLOGY 59
3.1 Risk Identification 60
3.2 Development of Bridge Risk Index (RI) 60
3.2.1 Deterioration State (DS) 60
3.2.2 Critical Component Rating (CCR) 62
3.2.3 Component Risk Factor (CFR) 63
3.3 Chapter Summary 63
CHAPTER 4: DEVELOPMENT OF A RISK-BASED BRIDGE MAINTENANCE FRAMEWORK 64
4.1 Risk Identification 64
4.2 Risk-based Bridge Maintenance Prioritization Framework 64
4.2.1 Determination of Deterioration State (DS) 65
4.2.2 Classification of Component Critical Rating (CCR) 67
4.2.3 Component Risk Factor (CRF) 73
4.2.4 Bridge Risk Index (RI) 73
4.3 Bridge Maintenance Prioritization Framework 76
4.4 Validation 77
4.4.1 Sample Calculation 77
4.4.2 Bridge A 79
4.4.3 Bridge B 81
4.4.4 Bridge C 86
4.4.5 Bridge D 91
4.4.6 Bridge E 98
4.4.7 Bridge F 102
4.4.8 Bridge G 104
4.4.9 Results 106
CHAPTER 5: CONCLUSION 109
5.1 Conclusion 109
5.2 Anticipated Research Outcome 111
5.3 Future Research 111
REFERENCES 112
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指導教授 姚乃嘉, 廖先格 審核日期 2023-2-1
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