三峡库区巫山县城新址岩质库岸再造预测

巫山县城新址位于西坪和大宁河两岸.组成该库段的基岩主要为泥岩、粉砂岩、泥灰岩等,岩性较软弱,且地质构造变动强烈,褶皱、断裂发育,岩层破碎,崩塌、滑坡分布较多,库岸再造问题严重;同时,岸坡再造又严重影响着新县城的规划和库岸的防护.因此把稳态坡形类比法应用于巫山县城新址基岩岸坡的再造预测,定量预测库岸的最终再造宽度,以指导新城的规划与建设.     

Analysis on Bearing Capacity of Tunnel-Type Anchorage of a Long-Span Suspension Bridge

INTRODUCTION Tunnel typeanchoragehasobviousadvantages inbearingcapacityversusinvestment(LiuandHu,1996).However,itisrarelyusedinapracticalpro jectbecauseofitsrequirementofgoodrockcondi tions.Siduhebridge(Fig.1),whichliesintheBa dongmountainsinthewestplatea…     

关于桥梁墩柱模板角点坐标的计算方法及其校核的研究

针对桥梁建设中各构筑物放样坐标的计算及校核存在不严谨之处,本文提出一种计算放样坐标的新方法可以作为放样坐标的第一计算方法或检核方法。对其中所涉及的坐标系的转换和方位角的计算方法进行详细说明,并编制程序使计算智能化,可以应用在实际工程中,具有一定的实际应用价值。     

高速铁路桥墩偏移整治工程线上监测及结果分析

高速铁路建成运营后,受外部因素的影响,如在桥墩一侧施工、堆载等,会造成桥墩发生偏移,影响线路的平顺性,严重威胁高速铁路行车安全,需对其进行纠偏整治。本文以某城际高铁K19段高架桥桥墩的偏移整治工程为例,在整治期间,对线上监测点和轨道线形监测,根据监测结果指导施工,直至达到纠偏目标。监测结果表明了监测方案的有效性、正确性,能够对施工起到较好的指导作用,且能够为纠偏是否达到目标提供可靠的判断依据。可为类似高速铁路的纠偏整治及线上监测提供良好的参考。     

浙江省青田县石平川钼矿床新发现及找矿前景

长期以来,石平川钼矿床一直被认为是典型的石英脉型矿床,矿体分布于石平川岩体内外接触带上下100m以内。经过近年的地质工作发现,距石平川岩体外接触带400m~500m的侏罗系西山头组第二岩性段地层中存在细脉型辉钼矿体,从而形成下部大脉型石英辉钼矿体、上部细脉型辉钼矿体的二元结构。这一发现为开展深部及外围找矿,扩大资源储量规模提供了新的前景。     

三稀矿产资源新兴产业发展及政策建议

三稀矿产资源是战略性新兴产业发展的基础原料,广泛应用在国防、航天、高端电子设备、核工业、发光材料等高精尖技术领域。本文在系统收集国内外三稀矿产资源生产、消费领域、价格以及进出口资料的基础上,提出了促进三稀矿产资源新兴产业发展的政策建议     

关于新型测绘的探索

探索新型测绘的产生背景与科学内涵等问题,对新时期测绘地理信息事业转型升级与跨越发展具有重要意义。该文首先从经济社会发展需求、测绘发展新阶段、测绘地理信息转型升级、测绘地理信息跨越发展4个方面阐述了新型测绘产生的背景;其次,从新型测绘关系角度给出了新型测绘的内涵与架构,从范围、内容、技术手段、体制机制方面描述了新型测绘的特征;再次,从新型测绘目标出发,描述了新型基础测绘的内涵、要求与主要任务,地理国情监测的总体目标与主要任务,公共服务与应急测绘的新需求与主要任务;最后围绕测绘地理空间数据获取、处理、管理、分析、服务与应用主线,探讨了新型测绘需要着重研究的新理论、新方法、新技术装备,旨在为新型测绘的研究与发展奠定基础。     

基于Arc GIS Server的高铁基础设施安全监测管理系统研究

为了提高高铁基础设施安全监测的信息化水平,实现监测超标预警的实时性,研究实现高铁基础设施安全监测管理系统。利用ArcScan进行影像矢量化和属性数据录入,系统业务数据库采用Oracle 11g,并在其中建立基于ArcSDE的空间数据库,通过ArcGIS Sever发布地图服务。系统采用B/S体系结构,利用WebSocket技术实现服务器端和浏览器端的实时通信,调用ArcGIS API for JavaScript完成了系统GIS模块功能。通过在试验工程中的应用表明,系统实用性强,提高高铁基础设施安全监测的信息化水平,具有较高的应用价值。     

A New Progress of the Proterozoic Chronostratigraphical Division

The Precambrian, an informal chronostratigraphical unit, represents the period of Earth history from the start of the Cambrian at ca. 541 Ma back to the formation of the planet at 4567 Ma. It was originally conceptualized as a "Cryptozoic Eon" that was contrasted with the Phanerozoic Eon from the Cambrian to the Quaternary, which is now known as the Precambrian and can be subdivided into three eons, i.e., the Hadean, the Archean and the Proterozoic. The Precambrian is currently divided chronometrically into convenient boundaries, including for the establishment of the Proterozoic periods that were chosen to reflect large-scale tectonic or sedimentary features(except for the Ediacaran Period). This chronometric arrangement might represent the second progress on the study of chronostratigraphy of the Precambrian after its separation from the Phanerozoic. Upon further study of the evolutionary history of the Precambrian Earth, applying new geodynamic and geobiological knowledge and information, a revised division of Precambrian time has led to the third conceptual progress on the study of Precambrian chronostratigraphy. In the current scheme, the Proterozoic Eon began at 2500 Ma, which is the approximate time by which most granite-greenstone crust had formed, and can be subdivided into ten periods of typically 200 Ma duration grouped into three eras(except for the Ediacaran Period). Within this current scheme, the Ediacaran Period was ratified in 2004, the first period-level addition to the geologic time scale in more than a century, an important advancement in stratigraphy. There are two main problems in the current scheme of Proterozoic chronostratigraphical division:(1) the definition of the Archean–Proterozoic boundary at 2500 Ma, which does not reflect a unique time of synchronous global change in tectonic style and does not correspond with a major change in lithology;(2) the round number subdivision of the Proterozoic into several periods based on broad orogenic characteristics, which has not met with requests on the concept of modern stratigraphy, except for the Ediacaran Period. In the revised chronostratigraphic scheme for the Proterozoic, the Archean–Proterozoic boundary is placed at the major change from a reducing early Earth to a cooler, more modern Earth characterized by the supercontinent cycle, a major change that occurred at ca. 2420 Ma. Thus, a revised Proterozoic Eon(2420–542 Ma) is envisaged to extend from the Archean–Proterozoic boundary at ca. 2420 Ma to the end of the Ediacaran Period, i.e., a period marked by the progressive rise in atmospheric oxygen, supercontinent cyclicity, and the evolution of more complex(eukaryotic) life. As with the current Proterozoic Eon, a revised Proterozoic Eon based on chronostratigraphy is envisaged to consist of three eras(Paleoproterozoic, Mesoproterozoic, and Neoproterozoic), but the boundary ages for these divisions differ from their current ages and their subdivisions into periods would also differ from current practice. A scheme is proposed for the chronostratigraphic division of the Proterozoic, based principally on geodynamic and geobiological events and their expressions in the stratigraphic record. Importantly, this revision of the Proterozoic time scale will be of significant benefit to the community as a whole and will help to drive new research that will unveil new information about the history of our planet, since the Proterozoic is a significant connecting link between the preceding Precambrian and the following Phanerozoic.     

我国地质钻探现状和发展前景分析

我国经济社会发展已步入“新常态”。作为地质调查和矿产勘查工作重要技术支撑的地质钻探行业,资金投入显著减少,地质钻探工作量大幅下滑,常规钻探施工产能过剩;另一方面,地质钻探新的服务领域不断扩大,包括深部科学钻探,地热能及非常规能源勘查,海洋、灾害防治、生态环境、地外天体、极地方面的钻探等。如何应对地勘行业出现的问题,是全行业共同面对的挑战。在对当前及今后一段时期地质钻探工程面临的困难、挑战和机遇等进行调研分析的基础上,对我国地质钻探未来的发展前景进行了预测,认为地质钻探工作量将进一步减少,新领域、新业态的钻探工程及先进钻探技术和装备需求将进一步加大,更加贴近国家需求,更加注重环保理念。