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Reliability guarantee framework for the Sichuan–Tibet Railway |
Chunfang LU1, Yongjie PAN2( ), Chaoxun CAI2 |
1. China Academy of Railway Sciences Corporation Limited, Beijing 100081, China
2. China Academy of Railway Sciences Corporation Limited, Beijing 100081, China; State Key Laboratory for Track Technology of High-speed Railway, Beijing 100081, China |
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Abstract The Sichuan–Tibet Railway is facing extraordinary challenges in terms of construction, operation, and maintenance because of its extremely complicated natural environment and geological conditions. Consequently, countermeasures are necessary and urgent to ensure its safety and reliability in the whole life cycle. This study proposes a novel reliability framework to guarantee the ideal operation state of the Sichuan–Tibet Railway. Reliability application in many fields are summarized, including military equipment, rail locomotive, and railway engineering. Given the fact that the Sichuan–Tibet Railway is a complex giant system, Nine-Connotation was summarized (i.e., safety, inherent reliability, testability, maintainability, supportability, environmental adaptability, predictability, resilience, and durability) under the goal of optimizing the operational efficiency. On the basis of the concept of the Nine-Connotation and the understanding of reliability transmission mechanism, the framework of reliability for the Sichuan–Tibet Railway was established, which can facilitate a comprehensive and real-time evaluation of all situations with a clear hierarchy. The proposed framework is composed of a resilience management system, an integrated technology system, and a dynamic reliability assessment system. The pathway for its application on railway construction was developed in this study. The proposed framework can assist in well-informed decisions for the construction, as well as the operation of the Sichuan–Tibet Railway. On the basis of a top–down design concept for the first time, this study emphasizes the railway’s availability and validity to complete the assigned tasks as a whole, that is, operational efficiency. It also shows the reliability transmission and control mechanism of the railway’s giant complex system, innovating and establishing the management principle of great safety and great reliability over the life cycle.
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| Keywords
Sichuan–Tibet Railway
operational efficiency
reliability guarantee
Nine-Connotation
implementation pathway
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Corresponding Author(s):
Yongjie PAN
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Just Accepted Date: 26 July 2021
Online First Date: 07 September 2021
Issue Date: 01 November 2021
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| 1 |
F Chen, Z M Yuan, L Yan, W Xu, Y F Miao, B W Gao (2020a). Reliability and safety evaluation of autonomous computer system of intelligent CTC in high speed railway. Acta Automatica Sinica, 46(3): 463–470 (in Chinese)
|
| 2 |
H Q Chen, S X Zeng, Q K Su (2020b). Towards management of panoramic innovation in megaprojects: The case of Hong Kong–Zhuhai–Macao Bridge Project. Management World, 36(12): 212–227 (in Chinese)
|
| 3 |
S K Chen, B H Mao, T J He, J F Liu, H D Liu (2006). Reliability evaluation of railway traction power supply system based on accident tree analysis. Journal of the China Railway Society, 28(6): 123–129 (in Chinese)
|
| 4 |
H Cheng, Y Han (2012). Systematic thinking of engineering management and engineering life cycle management. Journal of Southwest University (Philosophy and Social Science Edition), 14(2): 36–40 (in Chinese)
|
| 5 |
H B Cheng, Y F Cao, J X Wang, W Zhang, H Zeng (2019). A preventive opportunistic maintenance strategy for the catenary system of high-speed railways based on reliability. Journal of Rail and Rapid Transit, 234(10): 1149–1155
|
| 6 |
S Z Ding (2014). Engineering Project Management. 2nd ed. Beijing: China Architecture Publishing & Media Co., Ltd. (in Chinese)
|
| 7 |
X Feng, S W He, Y B Li (2019). Temporal characteristics and reliability analysis of railway transportation networks. Transportmetrica A: Transport Science, 15(2): 1825–1847
https://doi.org/10.1080/23249935.2019.1647308
|
| 8 |
S Gu, K P Li (2019). Reliability analysis of high-speed railway network. Journal of Risk and Reliability, 233(6): 1060–1073
|
| 9 |
S Hidirov, H Guler (2019). Reliability, availability and maintainability analyses for railway infrastructure management. Structure and Infrastructure Engineering, 15(9): 1221–1233
https://doi.org/10.1080/15732479.2019.1615964
|
| 10 |
W H Huang (2013). Reliability of large-scale natural gas pipeline network. Acta Petrolei Sinica, 34(2): 401–404 (in Chinese)
|
| 11 |
C G Jia, R Song, S W He, S B Chen (2015). Study on evaluation index system of railway industry safety production. Railway Transport and Economy, 37(3): 69–73 (in Chinese)
|
| 12 |
R Kang (2012). Fundamentals of Reliability & Maintenability & Supportability Engineering. Beijing: National Defense Industry Press (in Chinese)
|
| 13 |
R Kang, Z L Wang (2005). Theoretical and technical framework of reliability system engineering. Acta Aeronautica et Astronautica Sinica, 26(5): 633–636 (in Chinese)
|
| 14 |
C F Lu (2015). Innovation and practice for engineering quality management of high speed railway in China. China Railway Science, 36(1): 1–10 (in Chinese)
|
| 15 |
C F Lu, C X Cai (2019). Challenges and countermeasures for construction safety during the Sichuan–Tibet Railway Project. Engineering, 5(5): 833–838
https://doi.org/10.1016/j.eng.2019.06.007
|
| 16 |
Q Mahboob, E Zio (2018). Handbook of RAMS in Railway Systems—Theory and Practice. CRC Press
|
| 17 |
X L Meng, Y H Wang, L M Jia, L Li (2020). Reliability optimization of a railway network. Sustainability, 12(23): 9805
https://doi.org/10.3390/su12239805
|
| 18 |
B Naticchia, A Corneli, A Carbonari (2020). Framework based on building information modeling, mixed reality, and a cloud platform to support information flow in facility management. Frontiers of Engineering Management, 7(1): 131–141
https://doi.org/10.1007/s42524-019-0071-y
|
| 19 |
A S Nowak, K R Collins (2005). Reliability of Structures. Chongqing: Chongqing University Press
|
| 20 |
X S Qian (2005). A new field of science—Open Complex Giant System and its methodology. Urban Development Studies, (5): 1–8 (in Chinese)
|
| 21 |
Y H Qin, N J Lu (2011). Evolution of reliability in engineering systems. Journal of Northeastern University (Social Science Edition), 13(4): 295–299 (in Chinese)
|
| 22 |
X J Sun (2012). Review of military reliability assurance standards. Electronic Product Reliability and Environmental Testing, 30(1): 61–65 (in Chinese)
|
| 23 |
Y Yang (2011). Research on RAMS Evaluation for Power Supply System of High-speed Railways. Dissertation for the Doctoral Degree. Beijing: Beijing Jiaotong University (in Chinese)
|
| 24 |
S X Zeng, H Q Chen, Z Z Jin, Q K Su (2019). The evolution of mega project innovation ecosystem and enhancement of innovation capability. Management World, 35(4): 28–38 (in Chinese)
|
| 25 |
W Q Zhang (2017). Interpretation and enlightenment of generalized RAMS. Chinese Engineering Consultants, (10): 32–35 (in Chinese)
|
| 26 |
B T Zhong, H T Wu, L Y Ding, H B Luo, Y Luo, X Pan (2020). Hyperledger fabric-based consortium blockchain for construction quality information management. Frontiers of Engineering Management, 7(4): 512–527
https://doi.org/10.1007/s42524-020-0128-y
|
| 27 |
M M Zhu (2021). A new framework of complex system reliability with imperfect maintenance policy. Annals of Operations Research, in press, doi: 10.1007/s10479-020-03852-w
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