水工有压隧洞衬砌启裂水头及围岩联合承载影响分析

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摘要利用数值仿真模型,研究分析围岩变形能力、衬砌混凝土标号、回填灌浆压力以及灌浆结石体变形能力等对水工有压隧洞衬砌启裂水头及围岩与衬砌联合承载比例的影响,结果表明:围岩弹性模量对于围岩与衬砌荷载分担比影响明显,围岩弹性模量越高,所分担荷载越大;衬砌混凝土标号和灌浆结石体影响较小;回填灌浆压力基本无影响;围岩弹性模量、回填灌浆压力以及灌浆结石体弹性模量增加,衬砌启裂所需要的内水水头均增加,围岩弹性模量与回填灌浆对启裂水头的影响更为明显,但由于混凝土标号增加,衬砌荷载分担比加大,衬砌启裂水头逐渐降低。研究结果可为水工有压隧洞衬砌设计与灌浆参数的合理选取提供支撑。

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	刘立鹏
	王彦兵
	宋倩

关键词: 隧道工程水工有压隧洞衬砌开裂联合承载

Abstract: Using the numerical simulation model, the effects of the surrounding rock deformation capacity, lining concrete label, backfill grouting pressure, and grouting stone deformation capacity on the hydraulic head of the hydraulic pressure tunnel lining and the joint bearing ratio of the surrounding rock and lining were analyzed. The result showed that: the elastic modulus of the surrounding rock had a significant effect on the joint bearing ratio of the surrounding rock and the lining. When the higher the elastic modulus of the rock mass, the greater the load shared. The effect of the lining concrete label and the grouting stones was small, and the backfill grouting pressure had no effect basically. The modulus of surrounding rock and grouting stones, grouting pressure increased, and the internal water head required for lining cracking increased. The influence of elastic modulus of surrounding rock and backfill grouting on cracking head was more obvious, but due to the concrete rank increase, the lining load sharing ratio increased, and the lining cracking head gradually decreased. The research results could provide support for the design of hydraulic pressure tunnel lining and the reasonable selection of grouting parameters.

Key words: tunneling engineering hydraulic pressure tunnel lining cracking joint bearing

发布日期: 2021-02-25 期的出版日期: 2020-12-20

中图分类号:

TU45

作者简介: 刘立鹏(1983— ),男,安徽六安人,博士,高级工程师,主要研究方向为地下洞室及结构工程稳定性. E-mail:liulip@iwhr.com

引用本文:

刘立鹏,王彦兵,宋倩. 水工有压隧洞衬砌启裂水头及围岩联合承载影响分析[J]. 隧道与地下工程灾害防治, 2020, 2(4): 52-58.
LIU Lipeng, WANG Yanbing, SONG Qian. Influence analysis of cracking strength and interaction of hydraulic pressure tunnel lining. Hazard Control in Tunnelling and Underground Engineering, 2020, 2(4): 52-58.

链接本文:

http://tunnel.sdujournals.com/CN/Y2020/V2/I4/52

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