安庆铜矿综合治水工程及其评价

介绍安庆铜矿矿山的生产及水文地质概况，指出矿山生产中存在的水文地质、环境地质等问题，提出总体治理方案和实施措施，对治水工程进行了综合评价。     

反倾层状岩质边坡内开挖隧道引发边坡失稳与隧道塌方的机制和治理研究

在反倾层状边坡内,开挖边坡并修筑隧道洞口后,出现岩体从隧道掌子面整体挤出和洞顶塌方现象,并导致边坡出现后缘拉裂、坡体内出现多处裂缝和岩块崩塌等坡体失稳迹象。通过对该边坡失稳和隧道塌方的勘察和机制分析,确定该坡体的变形破坏模式,提出针对性治理方案。     

京郊门城镇地面塌陷危险性研究

采空地面塌陷是门城镇地区危害性最严重的地质灾害类型。根椐实地勘察资料 ,论述了地面塌陷的分布特征和形成条件 ;选取与塌陷密切相关的 1 1个因素 ,采用二级模糊综合评判法对地面塌陷的危险度进行了分区预测。     

T形短肢剪力墙静力性能有限元仿真分析

利用有限元分析软件ANSYS,首先采用其中三维实体单元SOLID65建立了T形短肢剪力墙有限元分析模型,从弹性到混凝土开裂直至破坏的全过程进行了仿真试验分析。分析了影响短肢剪力墙受力的几种因素:混凝土强度等级、配筋率、轴压比、墙肢截面高厚比对短肢剪力墙承载能力、变形能力及延性的影响,剖析了短肢剪力墙破坏过程及其原因。比较真实的反映了短肢剪力墙在轴压力和逐步加载侧向力共同作用下的响应。试验结果表明:增加混凝土等级和轴压比能提高试件的开裂、屈服和极限荷载,但应综合考虑其与变形能力、延性的关系。截面配筋率具有其特殊性,配筋率在1.4%1.6%之间时试件的承载能力、变形能力及延性较好。墙肢截面高厚比是不稳定因素但在高厚比为6.57.1时,延性及变形能力较强。     

公路隧道局部塌方洞段的围岩稳定性评价

结合某公路隧道工程,以现场地质调查和监测资料为基础,在结构面发育且可能发生大规模塌方的围岩洞段,根据现场实际统计的优势结构面产状,采用关键块体理论、非连续变形方法（DDA）首先确定围岩主要的失稳破坏模式,然后运用连续介质分析程序FLAC,在DDA方法确定的围岩实际变形破坏塌方形态的基础上进行计算分析,评价围岩的整体稳定性及加固措施的有效性。分析表明,围岩破坏的主要模式为受结构面控制的局部块体的失稳,工程开挖后围岩不会发生大变形,这与实际情况基本一致,为安全施工提供了保证。采用非连续变形方法和连续介质计算相结合的分析方法对隧道工程塌方稳定性进行研究,取得了较好的效果,研究方法和经验可为类似工程参考并借鉴。     

广西合山电厂灰水对岩土层工程特性的影响

采用溶滤试验和渗透变形试验等方法,重点研究了广西合山电厂灰水对岩土工程性质的影响: 在灰水的长期作用下,溶解并带走土体中难溶的碳酸盐和Al2O3 胶结物等物质,造成土体骨架疏松,降低土体的胶结力,破坏土体的结构,从而使土体含水量、液性指数、渗透系数快速增长,土体渗透变形临界坡降则大幅度下降。因此,在灰水长期作用下,大大降低了土体抗变形和抗塌陷破坏的能力,加速土层中土洞的形成和发展。另外,灰水长期作用,还促进了岩溶作用,扩大了岩溶管道和裂隙,有利于塌陷的形成和发育。      

重庆市中梁山地区隐伏塌陷特征及物探勘测的思路

为查明隐伏塌陷区域,分析重庆市中梁山地区岩溶塌陷的特征,发现塌陷主要发生在以岩溶裂隙发育为主的松散粉质黏土区域;地震映像法能方便、快速地查清土层的松散状态,而高密度电阻率法通过正演模拟发现只能探测出2～3倍电极距的异常范围,但能反映出岩溶裂隙发育的漏斗形态,即只要能找出岩溶裂隙的大致位置和浅表松散土层的范围就能圈定隐伏塌陷的区域。对中梁山地区某居民点进行野外勘测,综合以上两种方法圈定隐伏塌陷区域,其推断结果与钻探资料十分吻合,说明这种隐伏岩溶探测思路是可行的。     

陷落柱中“止水塞”的快速建立技术

论述了通过注浆在特大型垂向导水通道——陷落柱中建立人工\     

Notes邮件系统管理维护及典型故障分析

从LotusDomino服务器系统的监控、维护、服务器系统重要文件的备份操作及系统优化等方面介绍了Domino服务器的管理维护方法：分析了Domino服务器和notes客户端的典型故障,给出了具体的故障解决思路及方法。     

Sector collapse,sedimentation and clast population evolution at an active island-arc volcano: Stromboli,Italy

Sciara del Fuoco is the subaerial part of a partially filled sector-collapse scar that extends to 700 m below sea level on Stromboli volcano. The collapse occurred <5000 years ago, involved 1.81 km³ of rock and is the latest of a series of major collapses on the north-west flank of Stromboli. A north-east trending arc-axial fault system channels magmas into the volcano and has caused tilting and/or downthrow to the north-west. The slope of the partial cone constructed between the lateral walls of the collapse scar acts as a channelway to the sea for most eruptive products. From 700 m below sea level and extending to >2200 m and >10 km from the shore to the NNW, a fan-shaped mounded feature comprises debris avalanche deposits (>4 km³) from two or more sector collapses. Volcaniclastic density currents originating from Sciara del Fuoco follow the topographic margin of the debris avalanche deposits, although overbank currents and other unconfined currents widely cover the mounded feature with turbidites. Historical (recorded) eruptive activity in Sciara del Fuoco is considerably less than that which occurred earlier, and much of the partial fill may have formed from eruptions soon after the sector collapse. It is possible that a mass of eruptive products similar to that in the collapse scar is dispersed as volcanogenic sediment in deep water of the Tyrhennian basin. Evidence that the early post-collapse eruptive discharge was greater than the apparent recent flux (2kg/s) counters suggestions that a substantial part of Stromboli's growth has been endogenous. The partial fill of Sciaria del Fuoco is dominated by lava and spatter layers, rather than by the scoria and ash layers classically regarded as main constituents of Strombolian (cinder) cones. Much of the volcanic slope beneath the vents is steeper than the angle of repose of loose tephra, which is therefore rapidly transported to the sea. Delicate pyroclasts that record the magmatic explosivity are selectively destroyed and diluted during sedimentary transport, mainly in avalanches and by shoreline wave reworking, and thus the submarine deposits do not record well the extent and diversity of explosive activity and associated clast-forming processes. Considerable amounts of dense (non-vesicular) fine sand and silt grains are produced by breakage and rounding of fragments of lava and agglutinate. The submarine extension of the collapse scar, and the continuing topographic depression to >2200 m below sea level, are zones of considerable by-passing of fine sand and silt, which are transported in turbidity currents. Evidently, volcanogenic sediments dispersed around island volcanoes by density currents are unlikely to record well the true spectrum and relative importance of clast-forming processes that occurred during an eruption. Marine sedimentary evidence of magmatic explosivity is particularly susceptible to partial or complete obliteration, unless there is a high rate of discharge of pyroclastic material into the sea.