超临界CO2直旋混合射流破岩特性的实验研究

超临界二氧化碳(CO₂)射流破岩既能降低岩石门限压力又能有效保护储层,直旋混合射流兼具直射流和旋转射流特点可提高破岩效率,基于此提出了超临界CO₂直旋混合射流的破岩方法。为了揭示超临界CO₂直旋混合射流破岩特性,设计加工出叶轮式直旋混合射流喷嘴,通过岩石定点冲击破碎实验对比了该射流与常规水射流的破岩效果,并研究了叶轮长度、叶轮中心孔直径、混合腔长度、喷射距离、射流压力等重要参数对超临界CO₂直旋混合射流破岩效果的影响。结果表明:相同实验条件下,该射流方法的平均破岩能力比常规水射流提高了42.9%;超临界CO₂直旋混合射流破岩易出现较大体积岩屑崩落现象;随着叶轮长度、混合腔长度、喷射距离的增大破岩效果均先增强后减弱,实验条件下上述参数存在最优范围值;叶轮中心孔直径的增大会导致岩石破碎孔深度增加、直径减小;随着射流压力的升高,超临界CO₂直旋混合射流破岩效果有着较为明显的提升。研究结果可为超临界CO₂直旋混合射流破岩方法的进一步研究提供实验依据。     

弹体高速侵彻效率的实验和量纲分析

为了研究高速侵彻时弹体撞击速度、材料强度等对质量侵蚀特性和侵彻效率的影响规律,开展了不同材料强度和长径比的弹体高速侵彻半无限厚素混凝土靶实验,弹体撞击速度为880~1 900 m/s,弹头形状为尖卵型(半径口径比为3),口径为30 mm。由实验发现:弹体撞击速度对侵彻效率的影响呈抛物线分布,最大侵彻效率时的弹体特征撞击速度约1 400 m/s;高速侵彻时弹体的质量侵蚀主要发生在卵形头部,弹身及尾部损伤极少;速度超过特征撞击速度时,弹体侵蚀严重,甚至弯曲变形或解体;弹体强度提高至约2倍时,质量侵蚀率降低约80%。基于实验,利用量纲分析原则建立了量纲一侵彻效率和量纲一弹体撞击速度的函数关系式,可估算出最大侵彻效率对应的弹体撞靶速度,为高速侵彻效应模拟实验提供理论指导。     

CsB_3O_5晶体潮解机理及防潮研究

三硼酸铯(CsB3O5)晶体在Nd:YAG 1064 nm激光三倍频转换方面具有优良的性能,限制该晶体器件实用化的一个重要因素是其在空气中较易潮解.本文用化学侵蚀法研究了CsB3O5晶体的潮解取向,并从晶体结构上给予了解释:由于CsB3O5晶体的B-O骨架在(010)方向存在较大的通道,水分子较易沿(010)方向进入晶体而导致晶体潮解.采用了用光学增透膜结合疏水保护膜的方法防止CsB3O5晶体潮解的技术手段,使CBO晶体器件能够在常规环境中保存及使用.     

低能离子束诱导Ag表面纳米金字塔微结构

利用离子束溅射诱导实验方法,在单晶Si(100)基底上辅助沉积银膜,研究了低能Ar+离子束30°入射时,不同离子束能量和束流密度以及基底温度对Ag纳米结构的影响.结果表明:在较低基底温度下(32~100℃)辅助沉积银膜,膜层表面会呈现排列紧密、晶粒尺寸一致的金字塔状纳米结构.当温度升高时(32~200℃),纳米微结构横向尺寸λc迅速增加,而粗糙度先减小(32~100℃)后迅速增大(100~200℃);当离子束能量1 400eV、束流密度15~45μA/cm2时,在相同温度下,随着离子束束流密度的增大,纳米晶粒横向尺寸基本不变,粗糙度略有增加;当离子束流密度为15μA/cm2、能量1 000~1 800eV时,在相同温度下,随着离子束能量的增加,银纳米结构尺寸增加,而表面粗糙度先增加,然后缓慢减小.自组织纳米结构的转变是溅射粗糙化和表面驰豫机制相互作用的结果.     

Abnormal crowd behavior detection by using the particle entropy

The crowd distribution information is the crucial information for abnormal behaviors detection in the crowd scenes. In this paper, we firstly refer to the definition of the entropy and propose an algorithm effectively and accurately representing the crowd distribution information in the crowd scenes. The proposed algorithm not only avoids unstable foreground extraction, but also owns low computational complexity. To detect the abnormal crowd behaviors, we use the Gaussian Mixture Model (GMM) over the normal crowd behaviors to predict the abnormal crowd behaviors since GMM usually can deal well with the unbalanced problem. In this paper we simultaneously use the crowd distribution information and the crowd speed information to estimate the parameters of GMM over the normal crowd behaviors and predict abnormal crowd behaviors. Experiment conducted on publicly available dataset consisting of gathering and dispersion events validates that the proposed approach can preeminently reflect the crowd distribution information. In addition, experiments conducted on publicly UMN dataset demonstrate that the proposed abnormal crowd behavior detection method has an excellent performance and outperforms the state-of-the-art methods.     

气体火花开关电极烧蚀研究

采用Mo,WCu和W分别作为三种气体火花开关的主电极材料,进行放电条件下电极烧蚀实验,研究开关电极烧蚀率和烧蚀形貌,分析电极烧蚀特征。结果表明,Mo,WCu和W开关的主电极烧蚀率分别为3.32×10-2 C-1·m-2,2.63×10-2 C-1·m-2和1.74×10-2 C-1·m-2,W开关主电极烧蚀率最小。实验后开关的主电极中心烧蚀严重,呈现明显裂纹和烧蚀坑。Mo主电极表面呈现明显熔融态,阴极表面形成大量裂纹(宽度达10μm)和孔隙(孔径达10μm);WCu和W主电极表面形成少量圆球状W突起(粒径达20μm及以上)。开关外壳内壁沉积了喷溅颗粒。WCu开关外壳沉积颗粒较大(粒径达10μm),Mo开关外壳沉积颗粒居中(粒径为2μm),W开关外壳沉积颗粒最小(近1μm)。因此可优先选用具有优异抗烧蚀性能的W作为气体火花开关电极材料。     

Spatiotemporal breather in diffraction decreasing media

The similarity transformation between the (3+1$3+1$)-dimensional nonlinear Schrödinger equation with different distributed transverse diffraction and the standard nonlinear Schrödinger equation is found, and a spatiotemporal breather solution is given based on this transformation. The control for the evolutional behaviors of a spatiotemporal breather is discussed. Our results manifest that the relation between the maximum accumulated time _Tm$T_m$ and the accumulated time, _T0$T_0$, with the maximum amplitude, is the basis to realize the control and manipulation of propagation behaviors of breathers, such as fast and slow excitations, sustainment and restraint. These results are potentially useful for future experiments in the optical communications and Bose–Einstein condensations.     

Effects of Ce,Sm and Yb on cavitation erosion of NAB alloy in 3.5% NaCl solution

The influences of Ce, Sm and Yb on cavitation erosion of NAB alloy in 3.5% NaCl solution are evaluated using mass loss, SEM, 3D morphology and Tafel plot, respectively. The results show that the addition of Ce or Sm or Yb enhances the mechanical property of NAB alloy, and the sizes of κ_Ⅰ and κ_Ⅱ phases within NAB alloy decrease with adding Ce or Sm or Yb, resulting in the prevention of the propagation of the cracks caused by cavitation erosion initially originated at the phase boundaries between α and κ phases, and finally the cavitation erosion damage significantly decreases with adding Ce or Sm or Yb. The corrosion of NAB alloy in 3.5% NaCl solution can promote the cavitation erosion of NAB alloy, while the corrosion resistance of NAB alloy increases with the addition of Ce or Sm or Yb, and then the cavitation erosion resistance is accordingly improved with the addition of rare earth element.     

Magnetocaloric effect in Y-doped La0.6Ca0.4MnO3 enhanced by Griffiths phase and re-entrance of first-order phase transition

It has been known that bulk La_0.6Ca_0.4MnO₃ is an intermediate material of the first- and second-order characters with the tricritical-point exponents, and the doping of a metal ion in it usually causes a continuous second-order transition. The present work reports the re-entrance of a discontinuous first-order transition in orthorhombic La_0.6-xY_xCa_0.4MnO₃ (x = 0.03–0.09) compounds. This enhances the magnetocaloric effect. For the field H = 30 kOe, the maximum magnetic-entropy change (|ΔS_max|) and relative cooling power (RCP) have been evaluated being about 5.45–6.3 J/kg·K and 130–185 J/kg, respectively. If combining these compounds as refrigerant blocks in a rotary ring model, a magnetic cooling device can operate at temperatures T = 85–280 K, with |ΔS_max| ≈ 5.5 J/kg⋅K and RCP ≈ 1073 J/kg. Aside from the re-entranced first-order phase transition, the magnetization and structural analyses have proved the enhanced magnetocaloric effect in La_0.6-xY_xCa_0.4MnO₃ related to a Griffiths singularity, and local Jahn-Teller distortions of the perovskite structure (since the Mn³⁺/Mn⁴⁺ ratio and orthorhombic structural phase are unchanged vs. x).     

Predicting initial erosion during the hole erosion test by using turbulent flow CFD simulation

CFD simulation with enhanced modeling of turbulence and near-wall treatment is used to model water–clay mixtures flowing through a cylindrical pipe domain. Effects on the wall-shear stress resulting from varying water clay content and applied hydraulic gradient are analyzed. Various parametric studies were performed and had shown that the two-dimensional modelling introduced in the present study does not yield a uniform wall-shear stress along the pipe wall and that clay concentration affects significantly the wall-shear stress value. This is in contrast with the common hypothesis used in one-dimensional modeling approaches where this stress is assumed constant and which gives rise to uniform erosion along the pipe wall. The obtained results had enabled predicting more realistically erosion amount and had allowed for understanding the irregular eroded hole wall shape as observed experimentally after performing the standard hole erosion test.