上海市地铁二号线东昌路车站DN1200原水引水管以下部分的地下连续墙施工

本文简要叙述了采用长臂反铲和液压槽壁机在ＤＮ１２００原水引水管下方进行地下连续墙施工，从而达到保护管线的目的。     

基于TBM工法的隧洞工程进度定量分析——以引红济石隧洞工程TBM段为例

文章结合QTBM理论,对引红济石隧洞工程前期的开挖进度数据进行了分析统计,结果表明:该工区TBM在Ⅲ类、Ⅳ类围岩中掘进速率较为稳定,而在V类围岩中掘进速率较低;同时,获得了适合该工区的岩体品质参数以及TBM净掘进速率、平均使用率等相关参数;并据此对该工程TBM待开挖段的工程进度进行预测,预测表明剩余6600m的开挖尚需...     

光滑明渠非恒定流量变化规律研究

建立了一套高精度的明渠非恒定流试验系统,并通过40组水槽试验研究光滑明渠内连续非恒定流传播过程中的流量变化规律。试验表明:1)非恒定流在传播过程中,当周期较长时,出口处的波峰流量趋近于进口处最大流量Qmax,波谷流量趋近于进口处最小流量Qmin;2)周期较小时,出口处的波峰、波谷流量均趋近于进口处的平均流量Q;3)在非恒定流传播过程中平均流量Q沿程保持不变。通过对40组试验结果分析,得到了明渠非恒定流传播时波峰流量Qmax及波谷流量Qmin的计算公式,相关分析表明两式均具有较好的精度。     

西辽河总办窝堡引水枢纽工程泥沙模型设计

<正>1 概述 西辽河总办窝堡引水工程由24孔拦河闸、3孔冲沙闸、左岸莫力庙取水口和右岸引辽济清取水口4部分组成,其中,左岸莫力庙取水口在拦门河闸上游800m处,其它3部分均处于同一断面上.该河段属游荡性河流,水流含沙量大,河道冲淤迅速.汛期最大含沙量为166kg/m~3,河床质平均粒径为0.25mm,推移质平均粒径为0.117mm,悬移质平均粒径为0.04mm.该工程的设计标准为二十年一遇,流量为847m~3/s;校核标准为五十年一遇,流量为1964m~3/s.该工程试验要求在流量大于100m~3/s时,保证莫力庙取水口与引辽济清取水口能同时引水,并且要求在讯期各取水口不被淤堵,拦河闸、冲沙闸能顺畅地泄洪排沙.     

九圩港闸闸下兴建桥梁工程模型试验研究

九圩港闸下新建桥梁工程，不能单独从泥沙问题来考虑其影响，还应考虑工程后对九圩港闸引、排水功能以及对闸上已有桥梁工程的影响。通过物理模型试验研究将较好地解决相关难题，为工程决策、设计提供科学依据。研究结果表明，桥梁工程方案实施后潮位最大壅高0．028m，对流速影响较大的范围在桥轴线上下100m之内，对九圩港闸引、排水流量的影响在3％以内。     

小半径曲线隧道钢筋砼衬砌施工

主要研究汶川姜射坝和桑坪电站有压引水隧道砼衬砌施工技术,包括地下水处治,小半径曲线圆型洞室钢筋砼衬砌施工方案和施工工艺等。     

锦屏二级水电站深埋特大引水隧洞关键技术

Seven tunnels across Jinping Mountain are arranged for Jinping Ⅱ Hydropower Station, with a total length of about 120 km. Among them, four headrace tunnels have a length of 16.67 km, an excavated diameter of 12.4-14.6 m, and a cover depth of 1 500-2 000 m in general. The maximum cover depth is 2 525 m, and the maximum external water pressure is more than 10 MPa. The tunnels are featured by great length, great depth and large diameter. It is the largest and most difficult among the underground tunnel groups built or under construction in China and even the world. With complex hydrogeological conditions and special topographical conditions along the tunnels, many challenging problems, such as rock burst under high in situ stresses, groundwater inrush in karst strata and failure of loading bearing structure, were encountered during construction. A great amount of groundbreaking studies were carried out regarding these problems. The key technical problems during construction of extremely large and deep tunnels were solved successfully. Safe and rapid tunnel construction and stable operation were achieved. The hydropower station started operation in 2014 and has been in a safe and stable operation state. The successful construction of headrace tunnels of Jinping Ⅱ Hydropower Station can provide some experiences and reference for deep tunnel projects in the world.