泥页岩井壁稳定研究及在临盘地区的应用

从岩石力学和物理化学两个主要因素简要分析了井壁失稳的机理，指出泥页岩井壁失稳是由力学与化学两方面因素共同作用的结果。钻井液与泥页岩存在化学势差，并改变了井壁附近的孔隙压力，降低岩石强度。借助于井壁处有效应力的变化,将泥页岩与钻井液相互作用时页岩水化所产生的力学效应与纯力学效应结合起来，计算出任意井斜方位井眼围岩应力状态，利用测井资料求出有关岩石力学参数和Mohr Couloumb准则，计算得出防塌的临界钻井液密度。     

纳米氧化锌在全钢载重子午线轮胎胎面胶和胎侧胶中的应用

研究纳米氧化锌作为活性剂替代普通氧化锌在全钢载重子午线轮胎胎面胶和胎侧胶中的应用效果.结果表明,纳米氧化锌替代普通氧化锌可以提高胶料的加工安全性和弹性,改善胎面胶的耐磨性能;纳米氧化锌减量约30%替代普通氧化锌,胎面胶和胎侧胶的综合性能较好,原材料成本降低,成品轮胎的高速性能提高.     

测井资料在井壁稳定性研究中的应用

井壁稳定性问题是石油钻井工业面临的一个重大课题。利用测井资料研究井壁稳定性是一种有效的方法。文章利用声波、密度测井资料计算了岩石力学参数、岩石强度参数，在此基础上进行了地应力计算、进而确定了地层破裂压力和坍塌压力，预测了安全钻井液密度范围，为钻井设计提供参考，并可指导安全钻井。通过新疆X 201井安全钻井液密度窗口的测井预测值与实钻钻井液密度对比分析，证明利用测井资料评价井壁稳定性的可行性和准确性，具有工程应用价值。     

多荷载耦合作用下立井井壁潜在破坏区的确定

首先采用弹性理论对立井井壁进行了分析,建立了井壁破坏的理论模型,进而采用通用有限元软件ANSYS,建立了立井井壁的大型三维分离式有限元数值模型。运用这两种模型详细研究了多种荷载耦合作用对立井井壁的影响,多种荷载包括：随深度变化的土压力、随时间变化的疏水附加力以及井壁自身重量。确定了立井井壁在这三种荷载综合作用下的应力、应变集中区,论证了井壁破坏理论中疏水附加力理论的正确性,对井壁设计理论以及加固区域的确定提供了一定的理论指导。本文有限元模型的建立方法以及得到的结论,在一定程度上丰富了立井井壁理论的内容,增加了立井井壁理论研究的方法,促进了井壁附加应力说的发展。     

窄间隙P-GMAW多信息融合侧壁熔合状态识别研究

窄间隙焊缝坡口间距小且焊道较深,摆动中心与焊缝中心偏差较大时,坡口两侧侧壁受热不良,易发生未熔合缺陷。为了及时了解窄间隙侧壁熔合情况,掌握侧壁内部焊接质量,本文提出了一种基于BP神经网络和D-S证据理论的多信息融合方法,预测侧壁熔合状态。对窄间隙焊接未熔合缺陷产生机制进行了分析,研究发现焊接电弧信号和熔池变化与侧壁成形质量存在密切关系,为此进行了一系列偏差实验,建立了电弧电信号和电弧熔池图像信号的实时采集系统,采用批量特征提取算法,提取了与侧壁熔合状态密切关联的峰值电流、峰值电压、电弧弧长、熔池长宽比、熔池面积和熔池周长等特征参量。采用BP算法训练神经网络,在此基础上通过D-S证据理论进行决策级融合。实验结果表明,该模型识别率可达96.667%,避免了神经网络识别时的误诊,获得了比单一传感信息更好的预测结果,提高了熔合状态识别的准确度和可靠度。     

大型点焊机器人特种作业程序镜像修正技术研究

以不锈钢列车车体点焊机器人作业路径规划编程为研究对象,针对车体对称部件,如左右侧墙点焊的的问题,提出点焊路径规划编程镜像的方法,引入X,Y,Z主轴以及龙门架E1轴系统偏差的修正和A,B,C旋转轴镜像处理的方法来调整焊钳位姿同时对焊接路径点焊位置修正镜像,并依据镜像规则在Windows环境下使用VC++语言开发了镜像程序生成器.通过仿真结果表明,该软件生成的镜像程序可与作业基准点完美衔接,最后在车间复杂环境下的实际运行验证了该方法的有效性.     

冻结法施工中某矿主井外壁钢筋轴力的实测与分析

为指导冻结法凿井的安全施工,开展主井井筒的信息化监测,获得主井外壁钢筋轴力的发展变化规律,通过与钢筋屈服应力相比,预测井壁的安全性。分析得出：混凝土浇筑初期,外壁钢筋轴力先是受压,而后压力趋于减小,部分竖向钢筋变为受拉,主井外壁环向钢筋的最大轴力远大于竖向钢筋,竖向、环向最大轴力均远小于其屈服荷载,因此,从钢筋应力状态考虑,井壁结构处于正常工作状态。井壁结构安全。     

The effects of etching and deposition on the performance and stress evolution of open through silicon vias

The effects of silicon etching using the Bosch process and LPCVD oxide deposition on the performance of open TSVs are analyzed through simulation. Using an in-house process simulator, a structure is generated which contains scalloped sidewalls as a result of the Bosch etch process. During the LPCVD deposition step, oxide is expected to be thinner at the trench bottom when compared to the top; however, additional localized thinning is observed around each scallop. The scalloped structure is compared to a structure where the etching step is not performed, but rather a flat trench profile is assumed. Both structures are imported into a finite element tool in order to analyze the effects of processing on device performance. The scalloped structure is shown to have an increased resistance and capacitance when compared to the flat TSV. Additionally, the scalloped TSV does not perform as well at high frequencies, where the signal loss is shown to increase. However, the scallops allow the TSV to respond better to an applied stress. This is due to the scallops’ enhanced range of motion and displacement, meaning they can compensate for the stress along the entire sidewall and not only on the TSV top, as in the flat structure.     

基于时空分布模型的混凝土面板堆石坝挤压边墙变形监测资料分析

基于挤压边墙多测点变形监测资料,通过引入监测点的空间坐标标量,结合场理论建立了挤压边墙变形时空分布模型。结合建设中的涔天河水库扩建工程挤压边墙的实测变形资料,验证了本文建立的挤压边墙变形时空分布模型。结果表明,该混凝土面板堆石坝挤压边墙的监测区域上部仍处于发展状态,尚不适合面板混凝土的施工。     

Effects of Internal and External Connection of Electrodes in Diagonal Type Nonequilibrium Plasma MHD Generator

In this paper, by a two-dimensional analysis in the duct cross section perpendicular to the plasma flow, the authors investigate comparatively the current distribution, the electrical efficiency etc. in the diagonal type nonequilibrium plasma generator of the window frame construction and the one of the insulating sidewall. Their numerical computations are made for an example of the cesium-seeded helium in nonequilibrium ionization, where it is assumed that the ionization instability does not occur.

It is shown that the current in the generator duct of the diagonal conducting wall tends to flow uniformly in the cross section of the duct, and on the other hand, the current in the duct of the insulating sidewall does in its central part; thus the performance characteristics of the former becomes better than those of the latter. This tendency increases with the load factor and wall temperature of the generator. Also the generator characteristics are improved with increasing the inclination factor, and the electrode voltage drop decreases with the load factor.