聚能爆破在石材切割应用中的试验研究

摘 要 简单分析了聚能爆破装药在孔内爆破的力学效应‚阐明了聚能爆破对岩石定向破裂 的控制机理。在聚能爆破切割石材过程中‚聚能射流起到前期切割出定向裂缝的作用‚石材 的最终开裂由后期爆破产生的气体的准静态胀楔作用来完成。通过提高炸药爆速、增大装药 密度等方法可以提高聚能装药爆炸后形成射流的能量和改善聚能爆破切割石材的效果。     

深海底钻机自动接杆卸杆储管机构

本文介绍了一种深海底使用的钻杆钻具储管机构的工作原理和结构特点。按照深海底钻孔工艺,设计了自动接杆、卸杆、存储机构。这一种机构采用两个单排转笼式储管架,分别存放钻杆和钻具管组件。每一个储管架各配备一双机械手,用于夹持钻杆和钻具在孔口位和储管架管口位之间的移送和卡紧定位。该机构可靠性高,取心率高,结构简单,方便操作。     

非传统钻进方法热能碎岩的原理及其初步实践

提出了一种非传统的利用热能破碎岩石的新型钻进方法,包括热力钻进法,热熔岩石钻 和超高频电加热－机械切割组合钻进法,介绍了其碎岩机理,适用范围,初步应用情况及前景。     

煤矿井巷用PDC锚杆钻头的研究

通过对ＰＤＣ锚杆钻头的一系列室内试验研究及多次改进设计,获得了钻头的优化结构参数、优化切削齿形状,合理的钻头体材质以及热处理工艺,现场试验结果表明,ＰＤＣ锚杆钻头是钻进中硬岩层的理想钻头。     

利用全站仪直线放样功能测量定线的精度分析

针对测量定线过程中出现的问题,介绍了全站仪直线放样功能用于测量定线的基本原理,并对测线上的转点和整条测线进行了精度分析。为了提高测线精度,提出了依据实地观测条件,分别在各测线段引入转点分段测量的方法。     

全站仪坐标法放样在公路放样测量中的应用

随着测量仪器和测量方法的改进,测量工作更加灵活多变,本文阐述了全站仪坐标法在公路施工放样应用中的计算原理和方法,最后讨论了全站仪在实际工作中的注意问题及优势。     

新型地震预警方法研究及预警能力分析

本文研究了一种不同于传统地震预警方法的新型预警方法。这种预警方法利用数据同化技术对实时波动场进行精确估计,然后再利用基于辐射传输理论的蒙特卡洛直接模拟法对波动能量的传播做数值模拟,并最终计算预警目标区烈度并做阈值判断发出预警警报。整个预警过程无需触发、无需定位、无需测定震级、无需利用衰减关系,较传统预警方法具有明显不同的技术手段,比较有效避免了传统地震预警方法中一系列基于经验统计规律的误差累积和单纯依靠初至P波信息在应对复杂地震时的局限性。本文选择了2011年3月11日日本M_w9.0地震和2016年2月6日台湾M_w6.7美浓地震作为预警模拟震例,分析并论证了本文预警方法在处理网外地震、网内地震以及复杂地震时的预警能力,最终得出本文预警方法在应对网内地震时具有良好的预警准确性和时效性,以及相对于传统预警方法在处理复杂地震时具有较大的优势。最后,总结并展望了本文研究工作的不足之处和有待继续研究的地方。     

老滑坡路段路堑开挖与超前支护效果

为防止老滑坡路段路堑开挖过程中出现路堑边坡失稳的问题,以在建某高速公路老滑坡段路堑失稳边坡为例,借助数值分析,进行了老滑坡路段路堑开挖与超前支护效果研究。结果表明：1）一般宽平台开挖模式能提高边坡的整体稳定性;然而,对于存在具有膨胀性质滑带土的牵引式老滑坡,坡脚采用宽平台刷坡减重不利于路堑边坡的稳定,必须要采取超前支护,如锚索、抗滑桩等,必要时要紧急采取清方卸载措施。2）锚索超前支护能够有效抑制边坡变形,需采用有效措施提高设置在坡脚处锚索的抗拉强度,如施加预应力等。3）抗滑桩超前支护应注意桩位、桩长、桩距的优化设计。建议抗滑桩采用锚拉,对桩前坡体中的滑带进行超前注浆,有必要沿老滑坡主滑方向布置多排抗滑桩,或采用h型桩体设计。     

Seismic performance of masonry walls retrofitted with steel reinforced grout

An innovative solution for the seismic protection of existing masonry structures is proposed and investigated through shake table tests on a natural scale wall assemblage. After a former test series carried out without reinforcement, the specimen was retrofitted using Steel Reinforced Grout. The strengthening system comprises horizontal strips of ultra‐high strength steel cords, externally bonded to the masonry with hydraulic lime mortar, and connectors to transversal walls, applied within the thickness of the plaster layer. In order to assess the seismic performance of the retrofitted wall, natural accelerograms were applied with increasing intensity up to failure. Test results provide a deep understanding of the effectiveness of mortar‐based composites for improving the out‐of‐plane seismic capacity of masonry walls, in comparison with traditional reinforcements with steel tie‐bars. The structural implications of the proposed solution in terms of dynamic properties and damage development under earthquake loads are also discussed.Copyright © 2015 John Wiley & Sons, Ltd.     

Bidirectional behavior of unreinforced masonry walls

Most of the studies related to the modeling of masonry structures have by far investigated either the in‐plane (IP) or the out‐of‐plane (OP) behavior of walls. However, seismic loads mostly impose simultaneous IP and OP demands on load‐bearing or shear masonry walls. Thus, there is a need to reconsider design equations of unreinforced masonry walls by taking into account bidirectional effects. The intent of this study is to investigate the bidirectional behavior of an unreinforced masonry wall with a typical aspect ratio under different displacement‐controlled loading directions making use of finite element analysis. For this purpose, the numerical procedure is first validated against the results of the tests on walls with different failure modes conducted by the authors. Afterward, the response of the wall systems is evaluated with increasing top displacement having different orientations. A set of 19 monotonic and three cyclic loading analyses are performed, and the results are discussed in terms of the variation of failure modes and load–displacement diagrams. Moreover, the results of wall capacity in each loading condition are compared with those of the ASCE41‐06 formulations. The results indicate that the direction of the resultant force, vectorial summation of IP and OP forces, of the wall is initially proportional to the ratio of stiffness in the IP and the OP directions. However, with the increase of damage, the resultant force direction inclines towards the wall's longitudinal direction regardless of the direction of the imposed displacement. Finally, recommendations are made for applicability of ASCE41‐06 formulations under different bidirectional loading conditions. Copyright © 2014 John Wiley & Sons, Ltd.