Home | About Journal  | Editorial Board  | Instruction | Subscription | Advertisement | Message Board  | Contact Us | 中文
MODERN TUNNELLING TECHNOLOGY 2013, Vol. 50 Issue (4) :176-182    DOI:
Current Issue | Next Issue | Archive | Adv Search << [an error occurred while processing this directive] | [an error occurred while processing this directive] >>
Discussion of Grouting Reinforcement Technology for the Collapsed Section
of the Huangjin Tunnel on the Newly-Built Ganzhou-Shaoguan Railway
(1  China Railway Ruiwei Foundation Engineering Co. Ltd., Beijing  100055;
  2  Technology Centre of China Railway Tunnel Group Co. Ltd., Luoyang  471009)
Download: PDF (0KB)   HTML (1KB)   Export: BibTeX or EndNote (RIS)      Supporting Info
Abstract  A collapse accident occurred at DK171+050 of the Huangjin Tunnel on the Ganzhou-Shaoguan railway during which ground water seeped from the rock strata, which mainly consisted of calcirudite, siltstone, and mudstone. During the construction process, some special reinforcement schemes such as long pipe-roof pre-reinforcement, fiberglass bolt pre-reinforcement, and full-face advance curtain grouting were adopted in light of the geological conditions of the collapsed section. Furthermore, compaction grouting was conducted by a segmental-forward grouting technique on the principles of grouting from outside to inside, top to bottom, and at intervals, guaranteeing the grouting effects, improving construction efficiency, and ensuring the stability of the surrounding rocks. An analysis of the predicted and actual results was undertaken by means of numerical computation and is discussed in this paper, and treatment schemes for the collapsed sections are presented.
Service
Email this article
Add to my bookshelf
Add to citation manager
Email Alert
RSS
Articles by authors
KeywordsTunnel collapse   Treatment scheme   Grouting reinforcement   Numerical analysis     
Abstract:  A collapse accident occurred at DK171+050 of the Huangjin Tunnel on the Ganzhou-Shaoguan railway during which ground water seeped from the rock strata, which mainly consisted of calcirudite, siltstone, and mudstone. During the construction process, some special reinforcement schemes such as long pipe-roof pre-reinforcement, fiberglass bolt pre-reinforcement, and full-face advance curtain grouting were adopted in light of the geological conditions of the collapsed section. Furthermore, compaction grouting was conducted by a segmental-forward grouting technique on the principles of grouting from outside to inside, top to bottom, and at intervals, guaranteeing the grouting effects, improving construction efficiency, and ensuring the stability of the surrounding rocks. An analysis of the predicted and actual results was undertaken by means of numerical computation and is discussed in this paper, and treatment schemes for the collapsed sections are presented.
KeywordsTunnel collapse,   Treatment scheme,   Grouting reinforcement,   Numerical analysis     
published: 2013-01-20
Cite this article:   
.Discussion of Grouting Reinforcement Technology for the Collapsed Section
of the Huangjin Tunnel on the Newly-Built Ganzhou-Shaoguan Railway[J]  MODERN TUNNELLING TECHNOLOGY, 2013,V50(4): 176-182
URL:  
http://www.xdsdjs.com/EN/      或     http://www.xdsdjs.com/EN/Y2013/V50/I4/176
 
No references of article
[1] ZHANG Qing1 ZHEN Wenzhan1 FENG Kun2.Analysis of the Impact of Large Diameter Shield Tunnel Crossing Existing Expressway Bridge and Culvert[J]. MODERN TUNNELLING TECHNOLOGY, 2024,61(1): 137-145
[2] HUANG Xuanbo1, 2 DING Wenqi1, 2 ZHANG Qingzhao1, 2.Numerical Analysis of Bending Mechanical Properties of Flange Joint of Corrugated Steel Lining[J]. MODERN TUNNELLING TECHNOLOGY, 2024,61(1): 96-106
[3] DUAN Xianbiao1 HUANG Xuanbo2,3 ZHANG Qingzhao2,3 XU Yongjin1.Analysis of the Results of General Dewatering and Drainage Measures and Ground Stability of Tunnel in Water-rich Hypabyssal Rock[J]. MODERN TUNNELLING TECHNOLOGY, 2024,61(1): 146-155
[4] ZHU Caihui1,2 YING Li2 YANG Qiqiang2 LI Yubo3.A Study on Reduction Coefficient of External Hydraulic Pressure at the Lining of Diversion Tunnel in Saturated Q2 Loess Stratum[J]. MODERN TUNNELLING TECHNOLOGY, 2023,60(2): 94-102
[5] LIU Zonghan1,2 HAN Fenglei1,2 ZHANG Xuefu1,2 LI Hongliang3 QIN Zhen1,2 ZHAO Yicong1,2.Analysis on the Construction Hazard Causes of Tunnels with Altitude Difference in the Tilted Soft-hard Interbedded Stratum[J]. MODERN TUNNELLING TECHNOLOGY, 2022,59(6): 197-207
[6] CUI Qinglong1 LI Jin1 GAO Binyong2 XIONG Xinyue2.Mechanical Properties of Three-inclined Bolts in Longitudinal Joint of Large-diameter Shield Tunnel Segment[J]. MODERN TUNNELLING TECHNOLOGY, 2022,59(5): 63-71
[7] SUN Shuangchi1,2 SHEN Yi1 ZHOU Zhiyan2 ZHOU Long1 ZHU Hehua1.Analaysis of Deformation and Its Control Measures for Large-diameter Shield Tunnels Passing under Building Complexes[J]. MODERN TUNNELLING TECHNOLOGY, 2022,59(2): 103-110
[8] WANG Huaizheng1 SONG Zhanping1,2 ZHANG Xuewen3 TIAN Xiaoxu1,2 PAN Hongwei4.Optimization and Application of the Construction Scheme for Large-section Tunnels in Water-rich and Weakly Cemented Strata[J]. MODERN TUNNELLING TECHNOLOGY, 2022,59(2): 210-219
[9] YANG Chunshan1 Wei Lixin1 MO Haihong2.Impact on and Prediction of Segment Opening of Shield Tunnels under Seismic Action[J]. MODERN TUNNELLING TECHNOLOGY, 2022,59(1): 133-140
[10] ZHOU Xiaojun1 GUO Jian1 YANG Changyu2 QING Weichen2 XIONG Guoxing2 KUANG Wentao2.Study on the Partition Mode of Prefabricated and Assembled Secondary Lining of Double-track Railway Tunnels by Drilling and Blasting Method[J]. MODERN TUNNELLING TECHNOLOGY, 2021,58(6): 46-58
[11] HUANG Peng1,2 WEI Liangwen1,2 ZHANG Xuefu1,2.Study on Reinforcement of Large Arch Foot of Mined and Overlapped Metro Transfer Stations[J]. MODERN TUNNELLING TECHNOLOGY, 2021,58(6): 137-147
[12] LI Siming1 YU Haitao2 XUE Guangqiao3 XU Lei4.Analysis on Seismic Response of Shield Tunnels Passing Through Soil-Rock Strata[J]. MODERN TUNNELLING TECHNOLOGY, 2021,58(5): 65-72
[13] YE Xinxin1 MIAO Miao2 ZHONG Yujian2 XU Shuoshuo2 DU Ke2.Analysis on Reinforcement Effect of Surface Grouting in Shallow-Buried Tunnels with Asymmetrical Loading and Abundant Underground Water[J]. MODERN TUNNELLING TECHNOLOGY, 2021,58(4): 229-236
[14] LIU Hebing.Study on the Impact of the Capacity Expansion and Renovation Project of the Chengdu-Chongqing Expressway on Xinshuangbei Tunnel[J]. MODERN TUNNELLING TECHNOLOGY, 2021,58(3): 229-234
[15] JIA Yanling1,2,3 ZHOU Shaowen2,3 WANG Gang2,3 ZHOU Weizheng2,3 YANG Kunguang2,3.Study on the Stress Characteristics of the Mid-pillar in the Expansion of an Existing Tunnel into a Double-arch Tunnel[J]. MODERN TUNNELLING TECHNOLOGY, 2021,58(3): 130-138
Copyright 2010 by MODERN TUNNELLING TECHNOLOGY