Overall Design of Chongming-Taicang Yangtze River Crossing Tunnel of Shanghai-Chongqing-Chengdu High-Speed Railway（沪渝蓉高铁崇太长江隧道总体设计方案研究）

doi:10.3973/j.issn.2096-4498.2023.12.012

中国科学引文数据库（CSCD）来源期刊
中文核心期刊中文科技核心期刊
Scopus RCCSE中国核心学术期刊
美国EBSCO数据库俄罗斯《文摘杂志》
《日本科学技术振兴机构数据库（中国）》

隧道建设（中英文） ›› 2023, Vol. 43 ›› Issue (12): 2098-2113.DOI: 10.3973/j.issn.2096-4498.2023.12.012

Overall Design of Chongming-Taicang Yangtze River Crossing Tunnel of Shanghai-Chongqing-Chengdu High-Speed Railway（沪渝蓉高铁崇太长江隧道总体设计方案研究）

王乐明1，唐国荣2，孟庆余1，马志富1，巩江峰2

（1.中国铁路设计集团有限公司，天津 300308； 2. 中国铁路经济规划研究院有限公司，北京 100038）

出版日期:2023-12-20 发布日期:2024-01-04
作者简介:王乐明（1985—），男，山西吕梁人，2011年毕业于西南交通大学，桥梁与隧道工程专业，硕士，高级工程师，现从事隧道及地下工程的设计与研究工作。Email： sdswangleming@126.com。

Overall Design of Chongming-Taicang Yangtze River Crossing Tunnel of Shanghai-Chongqing-Chengdu High-Speed Railway

WANG Leming1, TANG Guorong2, MENG Qingyu1, MA Zhifu1, GONG Jiangfeng2

(1. China Railway Design Corporation, Tianjin 300308, China；2. China Railway Economic and Planning Research Institute Co., Ltd., Beijing 100038, China)

Online:2023-12-20 Published:2024-01-04

摘要/Abstract

摘要： 针对长江口复杂环境下建设高速铁路特长越江隧道面临的重难点问题和技术难题，以沪渝蓉高铁崇太长江隧道为背景，结合工程建设条件开展了越江隧道线位、纵断面布置、隧道分合修、衬砌结构选型、施工组织和运营防灾疏散等方案分析和论证。在河床河槽稳定性分析的基础上，通过技术、经济比较，推荐采用七丫口通道隧址方案，对河床局部深潭采取绕避措施；在分析河床地形、河底冲刷、地质条件和锚击影响的基础上，提出V形坡纵断面布置方案和越江隧道埋深控制原则；经过技术、经济比较，推荐采用单洞双线大断面盾构隧道；根据局部河床冲刷影响分析结果，采用“预制管片衬砌+现浇内衬”复合式双层衬砌结构；按照“保护环境、风险可控、动态调整”的原则，提出采用2台盾构下穿长江独头掘进的施工组织设计方案；利用竖井和盾构轨下通道，在隧道洞身范围设计紧急出口、轨下疏散通道和待避区，制定了“以疏散为主、安全待避、快速救援”的隧道防灾疏散预案。

关键词: 高速铁路, 越江盾构隧道, 设计方案, 双层衬砌

Abstract: The location, longitudinal profile, mode (doubletrack tunnel tube or twin singletrack tunnel tubes), lining structure, construction organization, and disaster prevention and evacuation of ChongmingTaicang Yangtze river crossing tunnel of ShanghaiChongqingChengdu highspeed railway are studied: (1) The Qiyakou tunnel location is recommended on the basis of analysis on the stability of the riverbed and by means of technical and economic comparisons. (2) A Vshaped longitudinal profile of the tunnel and the principle of controlling the overburden of the river crossing tunnel are proposed on the basis of analyzing the topographical conditions, scouring conditions, geological conditions, and ship anchorage impact of the riverbed. (3) Largediameter doubletrack shield tunnel is proposed after technical and economic comparisons. (4) Composite doublelayer lining structure consisting of prefabricated segment lining and castinsitu concrete lining is proposed on basis of analysis on the impact of the scouring of the riverbed at local areas. (5) Two shield machines are proposed for the construction of the tunnel according to the principle of "environmental protection, controllable risks and dynamic adjustment". (6) Emergency exits, undertrack evacuation passages, and refuge areas are arranged for the tunnel by using the vertical shafts and the space under the track.

Key words: highspeed railway, shield tunnel, rivercrossing tunnel, tunnel design, composite lining

王乐明, 唐国荣, 孟庆余, 马志富, 巩江峰. Overall Design of Chongming-Taicang Yangtze River Crossing Tunnel of Shanghai-Chongqing-Chengdu High-Speed Railway（沪渝蓉高铁崇太长江隧道总体设计方案研究）[J]. 隧道建设, 2023, 43(12): 2098-2113.

WANG Leming, TANG Guorong, MENG Qingyu, MA Zhifu, GONG Jiangfeng. Overall Design of Chongming-Taicang Yangtze River Crossing Tunnel of Shanghai-Chongqing-Chengdu High-Speed Railway[J]. Tunnel Construction, 2023, 43(12): 2098-2113.

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Overall Design of Chongming-Taicang Yangtze River Crossing Tunnel of Shanghai-Chongqing-Chengdu High-Speed Railway（沪渝蓉高铁崇太长江隧道总体设计方案研究）

Overall Design of Chongming-Taicang Yangtze River Crossing Tunnel of Shanghai-Chongqing-Chengdu High-Speed Railway

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