岩土力学
巖土力學
암토역학
Rock and Soil Mechanics
2015年
11期
3193-3200
,共8页
TBM%开挖面支护压力%可视化%复合地层
TBM%開挖麵支護壓力%可視化%複閤地層
TBM%개알면지호압력%가시화%복합지층
TBM%excavation face support pressure%visualization%complex strata
隧道掘进机(TBM)近年来在世界范围内得到了广泛应用,通常通过完全充满压力仓的泥土或泥浆来支护开挖面。但在较差的地层和水力条件下,开挖面失稳时有发生。事实上,TBM 开挖面的支护压力的大小直接决定了施工安全及地表变形。基于所建立的开挖面支护压力计算模型,并考虑复合地层下土体分层带来的影响,通过计算机编程方法,建立了界面友好、使用便捷的开挖面支护压力可视化计算平台(TBM Studio);并结合阿拉斯加隧道、钱江隧道工程实例进行了不同模型结果的验证分析,给出了各模型计算结果的差异性;讨论了软土复合地层条件下,土体自稳性对开挖面稳定的影响,认为软土地层中定量确定有效支护压力和水头高度至关重要,研究为正确评价TBM开挖面稳定性提供了相应的计算模型。
隧道掘進機(TBM)近年來在世界範圍內得到瞭廣汎應用,通常通過完全充滿壓力倉的泥土或泥漿來支護開挖麵。但在較差的地層和水力條件下,開挖麵失穩時有髮生。事實上,TBM 開挖麵的支護壓力的大小直接決定瞭施工安全及地錶變形。基于所建立的開挖麵支護壓力計算模型,併攷慮複閤地層下土體分層帶來的影響,通過計算機編程方法,建立瞭界麵友好、使用便捷的開挖麵支護壓力可視化計算平檯(TBM Studio);併結閤阿拉斯加隧道、錢江隧道工程實例進行瞭不同模型結果的驗證分析,給齣瞭各模型計算結果的差異性;討論瞭軟土複閤地層條件下,土體自穩性對開挖麵穩定的影響,認為軟土地層中定量確定有效支護壓力和水頭高度至關重要,研究為正確評價TBM開挖麵穩定性提供瞭相應的計算模型。
수도굴진궤(TBM)근년래재세계범위내득도료엄범응용,통상통과완전충만압력창적니토혹니장래지호개알면。단재교차적지층화수력조건하,개알면실은시유발생。사실상,TBM 개알면적지호압력적대소직접결정료시공안전급지표변형。기우소건립적개알면지호압력계산모형,병고필복합지층하토체분층대래적영향,통과계산궤편정방법,건립료계면우호、사용편첩적개알면지호압력가시화계산평태(TBM Studio);병결합아랍사가수도、전강수도공정실례진행료불동모형결과적험증분석,급출료각모형계산결과적차이성;토론료연토복합지층조건하,토체자은성대개알면은정적영향,인위연토지층중정량학정유효지호압력화수두고도지관중요,연구위정학평개TBM개알면은정성제공료상응적계산모형。
The tunnel boring machine (TBM) tunnelling has been successfully applied worldwide in recent years, and TBMs provide continuous support to the tunnel face by using the freshly-excavated wet soil or slurry which completely fills up the work chamber under pressure. Under extremely unfavorable geological and hydrogeological conditions, however, face instabilities may occur. In fact, the excavation face support pressure for TBM in soft ground determines the construction safety and surface deformation. A visual platform for calculating the excavation face support pressure conveniently, TBM Studio, is constructed by computer programming based on the suggested models. In this visual platform, the influence of stratified soils can be considered. Furthermore, a comparison of the results of Alaskan way tunnel and Qianjiang tunnel by different calculation models is done, the differences between different models are revealed. In addition, the effects of the stratified soil layers’ self-stability on excavation face stability in complex strata are also discussed, demonstrating that it is crucial for determining quantitatively the relationships between the effective support pressure required and the hydraulic head in the soft ground.