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[1]陶 勇,吕所章,杨 平,等.南京江北新区相邻深浅基坑开挖时序优化研究[J].建筑科学与工程学报,2021,38(06):108-118.[doi:10.19815/j.jace.2021.09021]
 TAO Yong,LYU Suo-zhang,YANG Ping,et al.Study on Excavation Time Sequence Optimization of Adjacent Deep and Shallow Foundation Pits in Jiangbei New District of Nanjing[J].Journal of Architecture and Civil Engineering,2021,38(06):108-118.[doi:10.19815/j.jace.2021.09021]
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南京江北新区相邻深浅基坑开挖时序优化研究(PDF)
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《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

卷:
38卷
期数:
2021年06期
页码:
108-118
栏目:
出版日期:
2021-11-05

文章信息/Info

Title:
Study on Excavation Time Sequence Optimization of Adjacent Deep and Shallow Foundation Pits in Jiangbei New District of Nanjing
文章编号:
1673-2049(2021)06-0108-11
作者:
陶 勇1,吕所章2,杨 平1,张 婷1,王晓觅2
(1. 南京林业大学 土木工程学院,江苏 南京 210037; 2. 江苏建科工程咨询有限公司,江苏 南京 210008)
Author(s):
TAO Yong1, LYU Suo-zhang2, YANG Ping1, ZHANG Ting1, WANG Xiao-mi2
(1. College of Civil Engineering, Nanjing Forestry University, Nanjing 210037, Jiangsu, China; 2. Jiangsu Jianke Engineering Consulting Co., Ltd., Nanjing 210008, Jiangsu, China)
关键词:
相邻基坑 变形规律 时序优化 数值模拟
Keywords:
adjacent foundation pit deformation law time sequence optimization numerical simulation
分类号:
TU470
DOI:
10.19815/j.jace.2021.09021
文献标志码:
A
摘要:
依托南京江北新区江漫滩地层地下空间基坑群工程,对深度、面积差别较大的两相邻基坑进行开挖数值模拟研究,提出3种不同开挖时序,对比了不同开挖时序下围护结构变形、地表沉降、坑底隆起规律。结果表明:不同开挖时序控制下基坑外墙与共墙变形作用不同,深浅交替时序控制作用最大,先深后浅次之,先浅后深最小; 在开挖深坑下部土方时,先浅后深时序下,共墙最大变形位置在浅坑底部附近,而另外2种开挖时序下共墙最大变形位置上移到墙顶; 在减小坑外地表沉降方面,深浅交替时序作用最大,先深后浅次之,先浅后深最小; 先浅后深时序施工深坑上部土方时,最大沉降位置逐渐靠近坑壁,而先深后浅时序施工浅坑时最大沉降位置远离坑壁,深浅交替时序施工时,最大沉降位置亦远离坑壁; 在深坑下部土方未开挖时,深浅交替时序对控制浅坑坑底隆起作用最大; 深坑与浅坑均开挖完时,先浅后深时序最有利于控制深坑坑底隆起; 对比各时序基坑变形规律,建议采用深浅交替时序开挖此类相邻基坑。
Abstract:
Based on the underground space foundation pit group project in Jiangbei New District of Nanjing, the numerical simulation study on the excavation of two adjacent foundation pits with large differences in depth and area was conducted, and three different excavation time sequences were proposed. The laws of retaining structure deformation, surface settlement and pit bottom uplift under different excavation time sequences were compared. The results show that the deformation of the outer wall of the foundation pit and the common wall are different under different time sequences. The depth and shallow alternate time sequence has the greatest control effect, followed by depth first and then shallow, and shallow first and then deep is the least. When excavating the lower part of the deep pit, the position of the maximum deformation of the common wall is near the bottom of the shallow pit under the time sequence of first shallow and then deep, while the position moves up to the top of the wall under the other two time sequences. In terms of surface subsidence outside the pit, the alternating sequence of depth and shallow has the greatest control effect, followed by depth first and then shallow, and shallow first and then deep is the least. During the construction of the upper part of the deep pit under the sequence of shallow first and then deep, the maximum settlement position is gradually close to the wall of the pit, and when the shallow pit is constructed under the sequence of deep first and then shallow, the position is far away from the wall. When the deep and shallow pits are constructed alternately, the position is also far away from the pit wall. When the soil under the deep pit is not excavated, the alternating depth and shallow sequence plays the most important role in controlling the bottom uplift of the shallow pit. When both the deep pit and the shallow pit are excavated, the time sequence of first shallow and then deep is most conducive to controlling the uplift of the deep pit bottom. Comparing the deformation laws of foundation pits in various time sequences, it is recommended to excavate such adjacent foundation pits in alternate depth and shallow time sequences.

参考文献/References:

[1] 郑 刚,王 琦,邓 旭,等.不同围护结构变形模式对坑外既有隧道变形影响的对比分析[J].岩土工程学报,2015,37(7):1181-1194.
ZHENG Gang,WANG Qi,DENG Xu,et al.Comparative Analysis of Influences of Different Deformation Modes of Retaining Structures on Deformation of Existing Tunnels Outside Excavations[J].Chinese Journal of Geotechnical Engineering,2015,37(7):1181-1194.
[2]苏子升.地铁车站深基坑施工方式对基坑围护结构变形影响分析[J].现代城市轨道交通,2019(12):37-41.
SU Zi-sheng.Analysis of Impact of Deep Foundation Pit Construction Method on Retaining Structure Deformation[J].Modern Urban Transit,2019(12):37-41.
[3]WANG Z,GUO X,WANG C.Field Monitoring Analysis of Construction Process of Deep Foundation Pit at Subway Station[J].Geotechnical and Geological Engineering,2019,37(2):549-559.
[4]YANG J,KONG D.Deformation of Deep and Large Foundation Pit in Soft Soil of Fuzhou Subway[J].Arabian Journal of Geosciences,2020,13(1):36.
[5]HUANG M,LIU X,ZHANG N,et al.Calculation of Foundation Pit Deformation Caused by Deep Excavation Considering Influence of Loading and Unloading[J].Journal of Central South University,2017,24(9):2164-2171.
[6]MA Q,LIU S,ZHAO X.PCA-NARX Time Series Prediction Model of Surface Settlement During Excavation of Deep Foundation Pit[J].IOP Conference Series:Earth and Environmental Science,2020,560:012056.
[7]吴昌将,孙召花,赖允瑾,等.软土地区地下连续墙深大基坑的变形性状研究[J].岩土力学,2018,39(增2):245-253.
WU Chang-jiang,SUN Zhao-hua,LAI Yun-jin,et al.Study of Deformation Characteristics of Diaphragm Wall Induced by Deep Large Excavation in Soft Soil Region[J].Rock and Soil Mechanics,2018,39(S2):245-253.
[8]XIAO H,ZHOU S,SUN Y.Wall Deflection and Ground Surface Settlement Due to Excavation Width and Foundation Pit Classification[J].KSCE Journal of Civil Engineering,2019,23(4):1537-1547.
[9]童 星,袁 静,姜叶翔,等.基于Mindlin解的基坑分层卸荷附加应力计算及回弹变形的多因素影响分析[J].岩土力学,2020,41(7):1-9.
TONG Xing,YUAN Jing,JIANG Ye-xiang,et al.Calculation of Layered Unloading Additional Stress of Foundation Pit Based on Mindlin Solution and the Analysis of Multiple Factors Influencing the Rebound Deformation[J].Rock and Soil Mechanics,2020,41(7):1-9.
[10]严钟来,邓湾湾.基于FLAC 3D的地铁深基坑数值模拟分析[J].低温建筑技术,2020,42(2):111-113,124.
YAN Zhong-lai,DENG Wan-wan.Numerical Simulation Analysis of Deep Foundation Pit of Subway Based on FLAC3D[J].Low Temperature Architecture Technology,2020,42(2):111-113,124.
[11]范 凡,章红兵,王建华,等.软土地区分隔型基坑群变形特性实测分析[J].上海交通大学学报,2018,52(2):133-140.
FAN Fan,ZHANG Hong-bing,WANG Jian-hua,et al.Deformation Characteristics of Divided Excavation Groups in Soft Soil[J].Journal of Shanghai Jiaotong University,2018,52(2):133-140.
[12]欧阳武姿.深厚软土地区多基坑联合开挖相互影响分析[D].广州:广州大学,2019.
OUYANG Wu-zi.Analysis on Mutual Influence of Multiple Foundation Pits Joint Excavation for Deep Soft Ground[D].Guangzhou:Guangzhou University,2019.
[13]林 楠,刘发前.填海区邻近基坑开挖施工相互影响研究[J].地下空间与工程学报,2019,15(增1):278-285.
LIN Nan,LIU Fa-qian.Research on Influence of Adjacent Foundation Pits Excavation in Reclamation Area[J].Chinese Journal of Underground Space and Engineering,2019,15(S1):278-285.
[14]李 辉.地铁与紧邻地块深基坑同步开挖相互影响分析[J].铁道工程学报,2019,36(4):65-69.
LI Hui.Mutual Influence Analysis of Simultaneous Excavation of Subway and Adjacent Block Deep Foundation Pits[J].Journal of Railway Engineering Society,2019,36(4):65-69.
[15]SUN Y,XIAO H.Wall Displacement and Ground-surface Settlement Caused by Pit-in-Pit Foundation Pit in Soft Clays[J].KSCE Journal of Civil Engineering,2021,25:1262-1275.
[16]宋德鑫,陶 铸,范钦建.分坑施工在控制基坑长边效应中的应用[J].岩土工程技术,2015,29(2):84-89.
SONG De-xin,TAO Zhu,FAN Qin-jian.Construction Technology of Separate Pit Applied to Control Long Side Effect of Foundation Pit[J].Geotechnical Engineering Technique,2015,29(2):84-89.
[17]卫 军,徐国元,刘启清.既有盾构隧道上方基坑群开挖顺序优化研究[J].铁道建筑,2018,58(8):84-87.
WEI Jun,XU Guo-yuan,LIU Qi-qing.Research on Optimization Excavation Sequence of Foundation Pit Group Above Existing Shield Tunnels [J].Railway Engineering,2018,58(8):84-87.
[18]殷一弘.深厚软土地层紧邻地铁深大基坑分区设计与实践[J].岩土工程学报,2019,41(增1):129-132.
YIN Yi-hong.Design and Practice of Partitioning of Deep Large Foundation Pits Close to Subway in Thick Soft Soils[J].Chinese Journal of Geotechnical Engineering,2019,41(S1):129-132.
[19]奚家米,陈让清.软土超深大基坑分区对称开挖围护结构变形及地表沉降实测分析[J].建筑科学,2020,36(3):143-150.
XI Jia-mi,CHEN Rang-qing.Deformation and Surface Settlement Analysis of Super-deep and Large Foundation Pit Excavation Enclosure Structures in Soft Soil Area[J].Building Science,2020,36(3):143-150.
[20]XU Z L,WANG X,LI M G,et al.Design and Application of a Digital System for Information Management and Synchronous Analysis in a Foundation Pit Group[J].Advances in Civil Engineering,2021,2021:6624521.

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备注/Memo

备注/Memo:
收稿日期:2021-09-11
基金项目:国家自然科学基金项目(51478226)
作者简介:陶 勇(1995-),男,江苏南通人,工学博士研究生,E-mail:1102012038@qq.com。
更新日期/Last Update: 2021-11-01