Settlement Control Technology for Shield Tunneling  under Buildings in Saturated Fine Sand

doi:10.3973/j.issn.1672-741X.2012.z2.014

Tunnel Construction ›› 2012, Vol. 32 ›› Issue (增刊2): 72-78.DOI: 10.3973/j.issn.1672-741X.2012.z2.014

Previous Articles Next Articles

Settlement Control Technology for Shield Tunneling  under Buildings in Saturated Fine Sand

MAO Zhiyi¹， LI Fayong²， YANG Qiongpeng^2

（1.Nanjing Metro Co., Ltd., Nanjing 210008, China; 2.China Railway Tunnel Stock Company, Zhengzhou 450003, Henan）

Received:2012-07-31 Revised:2012-09-05 Online:2012-12-20 Published:2013-02-19

Abstract

Abstract:

Ground settlement is hard to control during EPB shield tunneling in saturated fine sand. If the supporting measures for buildings, which are underpassed by shield, are not adequate, the buildings are easy to settlement, crack or collapses. Taking the settlement control for Tianruncheng commercial building and Tianruncheng bus station, which are located on No.3 line of Nanjing metro and underpassed by EPB shield in saturated fine sand of Yangtze River floodplain, as study object, experimental driving and parameter election before shield tunneling, tunneling parameters analysis and adjustment during shield driving and buildings monitoring and evaluation after shield driving are presented in this paper. In light of the analysis of measures and parameters used in shield driving under buildings, some suggestions are proposed for shield driving in fine sand and settlement control, including immediately filling clearance between surrounding rock and segments during shield driving in saturated fine sand; thrust, advance speed, rotation speed of cutterhead and muck conditioning during tunneling is vital for stratum stability; efficiently settlement control and environmental protection can be achieved, via efficient settlement control measures and comprehensive and careful analysis and dynamic parameters adjustment during shield driving. 

Key words: shield, floodplain of Yangtze River, saturated fine sand, settlement control

MAO Zhiyi，LI Fayong，YANG Qiongpeng. Settlement Control Technology for Shield Tunneling  under Buildings in Saturated Fine Sand[J]. Tunnel Construction, 2012, 32(增刊2): 72-78.

[1]	CHEN Jian, XUE Feng, SU Xiuting, LU Yao, LIU Tao. Key Technologies of Cutterhead Configuration and Cutter Replacement for Large diameter Shield under High Water Pressure [J]. Tunnel Construction, 2020, 40(7): 1057-1065.
[2]	ZHANG Li, SU Rui, HE Chuan, FENG Kun, FANG Ruoquan, XU Peikai. Fullscale Experimental Study on Bending Performance of Segmental Joints of Large Crosssection Shield Tunnel under Pure Compressive Bending Condition [J]. Tunnel Construction, 2020, 40(7): 997-1003.
[3]	ZHANG Yujie, WANG Yuan, WANG Zhikui, FENG Di, LIU Sijin, XU Shujun. Influence of Particle Size and Content of Coarseparticle Materials on Filmforming Effect of Slurry in High Permeability Formation [J]. Tunnel Construction, 2020, 40(7): 1004-1010.
[4]	YAO Yanming, HU Xinpeng, LI Fayong, XIAO Guangliang, HUANG Yi, XIA Hanyong, ZHOU Junhong. Construction Technology and Application of Disassembled Shield Passing Through Station in Confined Space: a Case Study on Ningbo Railway Station [J]. Tunnel Construction, 2020, 40(7): 1035-1040.
[5]	ZHANG Longguan, LI Zhigang, TAN Jiang. Launching and Receiving Technology of Large Crosssection Horseshoeshaped Shield Used in Baicheng Tunnel [J]. Tunnel Construction, 2020, 40(7): 1041-1048.
[6]	HAN Yun. Study on Treatment Technology of Water Gushing and Mud Bursting Caused by Segment Drilling of Underwater Shield Tunnel [J]. Tunnel Construction, 2020, 40(7): 1049-1056.
[7]	GONG Tingmin, JIA Lianhui, CHEN Wentao, ZHENG Yongguang. Key Technologies of Hard Rock Slurry Balance Pipe Jacking Machine for Composite Ground [J]. Tunnel Construction, 2020, 40(6): 880-889.
[8]	ZHANG Yazhou. Numerical Simulation on Waterproof Capacity of Shield Tunnel Joints Considering Working State of Sealing Gasket Surface [J]. Tunnel Construction, 2020, 40(6): 813-820.
[9]	SHI Qingtao, WU Wenqing, LU Ye. Mixing Proportion and Working Mechanism of Inorganic Binder-Waste Mud Composite Cementing Materials [J]. Tunnel Construction, 2020, 40(5): 629-635.
[10]	CHEN Xianzhi, CHENG Yong, YANG Xiaolong, LIU Fei, HU Qinxin, LIU Pengfei. Experimental Study on Ground Conditioning Technology for EPB Shield Boring in Water-rich Gravel Stratum [J]. Tunnel Construction, 2020, 40(5): 636-643.
[11]	宋超业, 贺维国, 吴钇君. 高水压过海盾构隧道建设关键技术可行性初探 [J]. Tunnel Construction, 2020, 40(5): 717-726.
[12]	WANG Famin, SUN Zhenchuan, ZHANG Lianghui, LI Fengyuan, ZHANG Bing, WANG Guo′an. Design of Super-large Diameter Slurry Shield Used in Shantou Bay Tunnel and Construction Countermeasures for Unfavorable Geology [J]. Tunnel Construction, 2020, 40(5): 735-746.
[13]	JIN Yuelang, DING Wenqi, XIAO Mingqing, SUN Wenhao, WU Weifeng, YE Meixi, TU Xinbin. Experimental Research on Sealing Behavior of Segmental Joints of Sutong GIL Utility Tunnel under Ultra-high Water Pressure [J]. Tunnel Construction, 2020, 40(4): 538-544.
[14]	DU Chuangdong, ZHANG Jie, WU Yuebin. Application of Construction Technology of "Tunneling First and Then Station" in Tel Aviv Red Line Project in Israel [J]. Tunnel Construction, 2020, 40(4): 562-568.
[15]	LI Fayong. Key Construction Technology of Shield Cutting Pile Foundation Group of Cast-in-place Piles: a Case Study on Qianhubeilu Station-Qiubi Station Section of Ningbo Metro Line No. 3 [J]. Tunnel Construction, 2020, 40(4): 569-585.

Settlement Control Technology for Shield Tunneling  under Buildings in Saturated Fine Sand

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments