Scattering of plane P waves by circular-arc layered alluvial valleys: An analytical solution

An analytical solution for scattering of plane P waves by circular-arc layered alluvial valleys was derived by Fourier-Bessel series expansion technique, and the solution was utilized to analyze the effects of alluvial sequence and their relative stiffness on the scattering of incident waves.

Microstructures and properties of the nitrided layers fabricated on titanium substrate by direct current nitrogen arc melting technique

The nitrided layers mainly containing TiN dendrites were fabricated by direct current nitrogen arc melting method. The test results show that the layers are harder and more resistant to wear than the titanium substrate. Arc traveling speeds and arc currents have an effect on both the microstructures and the properties of the layers. Decreasing the arc traveling speed or increasing the arc current can obviously enhance the hardness and the wear resistance of the nitrided layers.

Effects of a covering layer in a circular-arc canyon on incident plane SV waves

An analytical solution for scattering of incident plane SV waves by a circular-arc canyon with a covering layer was derived by Fourier-Bessel series expansion technique, and the solution was utilized to analyze the effects of the covering layer on incident plane SV waves. It was shown that the covering layer in a canyon, even if it is very thin, amplifies incident plane SV waves tremendously, and the amplification can be two and half times more than that for a simple canyon; the stiffness and thickness of the covering layer also have great effects on incident plane SV waves.

STUDY ON THE TRANSPORT MECHANISM IN THE ANODE BOUNDARY LAYER OF WELDING ARGON ARC

The anode region of welding arc is divided into three subzones: the anode boundary layer, the presheath and the sheath. A model is established for analyzing the transport mechanism in the anode boundary layer. The computer program is designed and the governing equations of the dominating processes with the boundary conditions taken from the solutions of LTE plasmas are solved by applying the Runge-Kutta procedure. One parameter θ, the ratio of the heavy particle temperature at the free-fall edge to the anode surface temperature, is introduced into this study. The results indicate that then the parameter θ is equal to 6, the predicted heat flux at the anode surface matches the measured one. Based on the model, various plasma properties in the boundary layer can be obtained. The calculated results are in good agreement with the measurements.

Experimental study on surface arc plasma actuation-based hypersonic boundary layer transition flow control

Effective control of hypersonic transition is essential.In order to avoid affecting the structural proflle of the aircraft,as well as reducing power consumption and electromagnetic interference,a low-frequency surface arc plasma disturbance experiment to promote hypersonic transition was carried out in theΦ0.25 m double-throat Ludwieg tube wind tunnel at Huazhong University of Science and Technology.Contacting printed circuit board sensors and non-contact focused laser differential interferometry testing technology were used in combination.Experimental results showed that the low-frequency surface arc plasma actuation had obvious stimulation effects on the second-mode unstable wave and could promote boundary layer transition by changing the spectral characteristics of the second-mode unstable wave.At the same time,the plasma actuation could promote energy exchange between the second-mode unstable wave and other unstable waves.Finally,the corresponding control mechanism is discussed.

Graphene Flakes in Arc Plasma: Conditions for the Fast Single-Layer Growth

The results of systematic numerical studies of graphene flakes growth in low-temperature arc discharge plasmas are presented. Diffusion-based growth model was developed, verified using the previously published experiments, and used to investigate the principal effects of the process parameters such as plasma density, electron temperature, surface temperature and time of growth on the size and structure of the plasma-grown graphene flakes. It was demonstrated that the higher growth temperatures result in larger graphene flakes reaching 5 μm, and simultaneously, lead to much lower density of the carbon atoms adsorbed on the flake surface. The low density of the carbon adatoms reduces the probability of the additional graphene layer nucleation on surface of growing flake, thus eventually resulting in the synthesis of the most valuable single-layered graphenes.

The Copper Thin Layer Deposition by Pulse Vacuum-Arc Sprayer

In this work, the deposition process features of a copper coating on stainless steel substrate, using the pulse vacuum arc spraying method were researched. A continuous layer of copper was deposited on a stainless steel substrate, and a high degree of coating adhesion to the substrate was demonstrated. The thickness of coating using application time was calculated, and the surface unevenness was estimated. Inside the coating layer substrate material elements were observed, that could appear as a result of simultaneously plasma spraying on the surface of the substrate. The feature of this method was discovered, that surface plasma plays a significant role in the deposition process. Finally, it was shown that the device with a pulsed arc could effectively be used in industry, since it is possible to change the layer thickness in the range of hundreds of microns by varying the deposition time.

微弧氧化后Mg-8Li合金表面MgLiAlY-LDHs@GO膜层的生长及耐蚀性能

目的提高Mg-8Li合金的耐蚀性能。方法首先在Mg-8Li合金表面制备微弧氧化膜(MAO),然后使用原位水热法在微弧氧化膜表面原位生长掺杂氧化石墨烯(GO)的四元(MgLiAlY)层状双羟基金属氧化物(LDHs)智能自修复膜层。采用SEM、XRD、FT-IR、EDS、ICP等手段研究MgLiAlY-LDHs@GO膜层的形貌、结构以及成分。通过EIS、Tafel以及浸泡试验等研究膜层的耐蚀性能,分析膜层的腐蚀行为,阐释其耐蚀机理。结果GO的掺杂可以促使LDHs纳米片生长得更加致密,主体层板中具有缓蚀作用的Y3+可以提高涂层的耐蚀性,四元LDHs的生长所需要的Mg^(2+)、Li^(+)、Al^(3+)等离子来源于镁锂合金基体以及微弧氧化膜的溶解,其中Li+也可以促进LDHs纳米片生长得更为均匀细密。膜层的腐蚀电流密度为6.03×10^(–7)A/cm^(2),比MAO膜层降低了1个数量级,提高了镁锂合金的耐蚀性能。结论GO的负载使LDHs的耐蚀性能和膜层稳定性均有一定程度的提升,引入稀土元素Y会改变LDHs的骨架,造成晶格畸变,使得LDHs微观形貌呈现褶皱状,剩下部分以Y(OH)3形式存在于涂层表面,可进一步提高膜层的耐蚀性能和稳定性。

短电弧车削蜂窝环重铸层影响实验研究

蜂窝密封结构是当代航空发动机的先进高效密封结构,传统加工难以满足其加工质量要求,且一般电加工效率低,因此选择短电弧车削。针对材料为GH3536的蜂窝密封环进行实验,为研究不同参数对其加工后重铸层的影响,设置单因素试验,以重铸层厚度和微观形貌作为检测指标,分析电流及电压波形图、工件表面扫描电镜图、截面金相图和表面能谱图。结果证明:重铸层厚度随电压和进给速度增加而增加,随工件和电极转速增加而减小,且表面质量有相同的趋势,多槽挡板电极可以得到更好的冲液效果,重铸层更薄且表面质量更好。因此,适当降低电压和进给速度、提高工件和电极转速,以及采用多槽挡板电极,可减少微裂纹、冲蚀凹坑、褶皱和熔滴颗粒等现象,提高工件表面质量,降低重铸层厚度。

ZK60镁合金表面MAO-LDH疏水膜层的一步水热法制备及其耐蚀性能

通过一步水热法在ZK60镁合金表面微弧氧化(MAO)膜层上制备了肉豆蔻酸(MA)修饰的Mg-Al层状双金属氢氧化物(LDH)复合膜层,通过场发射扫描电镜(FE-SEM)、X射线衍射仪(XRD)和傅里叶红外光谱仪(FTIR)分析了膜层的微观形貌、物相成分及结构,通过接触角测定仪及电化学工作站分析了膜层的润湿性及耐腐蚀性能。结果表明:制备的MA/LDH膜层成功封闭了MAO的微孔,水热温度为120℃时制备的MA/LDH/MAO复合膜层表面LDH片层较为完整均匀,其接触角最大,为143.42°。ZK60、MAO膜层及不同水热温度制备的MA/LDH/MAO复合膜层的耐蚀性由大到小依次为MA/LDH/MAO-120>MA/LDH/MAO-110>MA/LDH/MAO-130>MAO>ZK60,这归因于MA/LDH/MAO-120膜层具有均匀完整的LDH结构及MA插层/表面修饰LDH作用,可有效提高ZK60镁合金的耐蚀性能。

融合连续过渡模型与Helmer模型的真空断路器开断模型研究

真空断路器广泛应用于中压等级电网中,在频繁操作场景下易出现过电压问题,而真空断路器的弧后暂态过程直接决定了其分断特性和过电压特征。为解决现有真空断路器模型难以同时对其弧后过程和高频特性仿真的问题,该文搭建了融合连续过渡模型和Helmer模型的真空断路器开断模型,并通过试验和计算确定其仿真参数。以切除35kV系统用并联电抗器为例,研究该真空断路器融合模型与连续过渡模型和Helmer模型计算结果的差异。结果表明,融合模型能够同时考虑弧后介质恢复过程中重击穿和冷间隙重击穿现象;其弧后参数计算与连续过渡模型基本一致,高频开断特性和Helmer模型较为接近。通过分析高频开断过程中的鞘层生长和重击穿情况,可以得到引起真空断路器高频重击穿的主要原因。该文仿真结果验证了所提出的真空断路器开断模型的准确性,可为真空断路器高频分断条件下的弧后鞘层发展分析和重击穿原因判断提供参考。

搭接中心距对电弧增材熔池流动及熔积层形貌影响的数值模拟

搭接中心距对电弧增材搭接熔积的熔池流动及熔积层形貌有重要影响,为探究其影响机理,建立了钨极气体保护焊(Tungsten inert gas welding, TIG)电弧增材成形过程的三维数值模型,研究了不同搭接中心距对熔池流动及熔积层形貌的影响。结果表明:不同搭接中心距下熔池表面温度峰值相近,约为1900 K,表面流速呈非对称的双峰式分布。当搭接中心距小时,由于第一道焊道的支撑作用,使得第二道焊道横截面熔池流动和形貌不对称,熔池深而窄,熔池流动为单向的顺时针环流,左侧流速普遍大于右侧;随着搭接中心距的增大,第一道焊道的支撑作用逐步减弱,使得搭接焊道横截面熔池流动逐渐变为以第二道焊枪中心线为对称轴,左侧顺时针、右侧逆时针的两个环流,两侧流动逐渐对称,搭接熔池宽度逐渐增大、深度逐渐减小,两焊道逐渐分离并出现波谷,当搭接中心距为6 mm时熔积层形貌最平整。模拟与试验结果基本吻合,本研究结果可为电弧增材工艺参数调控提供理论支撑。

三门峡断陷盆地及邻区深部结构及成因——来自深地震反射与大地电磁测深的证据

近年来,围绕三门峡断陷盆地中的油气、地热资源做了大量的工作,成因机制研究较少,严重制约了矿产资源的勘探开发。本文在前人研究工作基础上,结合野外地质调查并利用高精度深反射地震剖面、大地电磁(MT)、重磁等地球物理探测技术,对三门峡盆地进行综合研究。发现三门峡盆地主要由东、西2个负花状构造构成,西花状构造体大于东花状构造体;盆地东部边缘以观音堂隆起与洛阳凹陷相邻,观音堂隆起发育有壳内透镜状低速体,其东、西两侧均发育有规模较大的隐伏逆断层。研究区内莫霍面为大约5 km厚度滑脱层,在深反射地震剖面上表现为蚯蚓状反射特征,指示滑脱层为西向运动。莫霍面滑脱层上部与下部新发现多条弧形断层。地质与地球物理资料综合研究表明,莫霍面滑脱层的解耦作用是三门峡断陷盆地花状构造形成的主因;在不同时空构造力系作用下,形成研究区新生代全地壳旋转花状构造盆地。

等离子弧熔覆Fe-C-B-V系耐磨堆焊层的组织及性能研究

以硼铁、高碳铬铁、钒铁为原料,采用等离子弧熔覆技术在Q345钢表面堆焊Fe-C-B-V系铁基合金。使用金相显微镜、扫描电镜和X射线衍射仪等研究了堆焊层的显微组织;分别使用维氏硬度计和冲击试验机测量堆焊层的显微硬度和冲击韧性。结果表明,堆焊层显微组织主要由马氏体、网格状Fe_(3)(C,B)和Fe_(2)B、弥散分布的碳化物及硼化物等(如VB_(2)、VC、Cr_(2)B)硬质相构成;堆焊层的平均硬度高达904.58 HV10、冲击功为68.5 J。堆焊过程中形成的硼化物、碳化物作为硬质相提高了堆焊层的硬度和耐磨性,形成的碳化钒使组织从鱼骨状变成网格状,细化了晶粒,提高了堆焊层的冲击韧性。

基于Arc View GIS煤矿安全生产地理信息系统的开发

为了全面提高和改善煤矿企业的安全管理水平,针对煤矿空间数据较多的实际情况,结合ArcView的突出特色空间数据和属性数据动态关联统一管理的特点,采用ArcViewGIS和VB、VC等软件进行煤矿安全生产地理信息系统的开发。系统的开发过程是开放性的,用户可以根据生产过程中的实际变化对系统中的视图和属性表进行实时的增删、修改等编辑操作,使系统不断得以更新和完善。实践证明该系统运行可靠性较高、稳定性好、实用性较强。

工艺参数对立向分体等离子弧增材制造过程的影响

【目的】为探究分体等离子弧增材制造过程中工艺参数对立向增材成形的影响,以单道熔覆层宽度和高度为评价指标对其展开研究。【方法】基于构建的立向分体等离子弧增材制造系统,通过单因素变量法研究了立向位置时丝/总电流比、离子气流量、丝材端部位置等工艺参数对熔覆层成形的影响,分析了工艺参数与基板热输入和熔敷率的关联机制。【结果】结果表明,当总电流保持不变时,丝材电流的增加会显著改善熔覆层成形,熔覆层宽度减小、高度增加;当离子气流量增加时,电弧等离子流力增强,使熔覆层宽度增加、高度减小;当送丝速度增加时,丝材端部靠近电弧中心,传质增加、传热减小,使熔覆层宽度减小、高度增加;丝材电流增加时,通过改变系统热、质、力的传输使熔覆层尺寸变化,而基板电流增加时,仅通过改变热、力传输使熔覆层尺寸变化。【结论】当总电流不变时,可采用提高丝/总电流比、减小离子气流量、丝材端部位置远离基板等措施减小基板的热输入并提高熔覆率,或直接增加丝材电流以提高熔覆率,进而实现高效增材制造。该研究将为分体等离子弧增材制造工艺在空间位置增材制造领域的拓展应用提供一定的理论指导。

基于曲面响应法的短电弧磨削蜂窝环工艺研究

蜂窝密封结构是当代航空发动机的先进高效密封结构,传统加工难以满足加工质量的要求,需要采用短电弧加工技术加工此类零部件。为获得最优的加工参数,以重铸层厚度和微观形貌为指标,分析电流及电压波形、表面能谱、工件表面和截面形貌,并进行响应曲面分析。结果表明:对重铸层厚度和加工时间影响的显著性为:进给速度>工件转速>电极转速,重铸层厚度随进给速度增加而增加,随工件和电极转速增加而减小,且表面质量有相同的趋势。多目标优化获得最佳参数为:工件转速5.863 r/min,电极转速287.114 r/min,进给速度0.087 mm/min。因此,适当降低进给速度,提高工件和电极转速,可减少微裂纹、冲蚀凹坑和熔滴颗粒等现象,提高工件表面质量,降低重铸层厚度。

消能防冲反弧段混凝土成型质量控制工艺研究

水利工程中消能防冲设施结构混凝土的成型质量直接影响消能防冲的效果,特别是反弧段混凝土的成型质量尤为重要。但因反弧段的混凝土形状复杂,浇筑成型难度大,表面平整度、光洁度更是难以控制。通过现场试验,分析了影响反弧段混凝土成型外观质量的主要原因。在实际操作中,采取了控制混凝土分层厚度和计算布置振捣点及混凝土临界初凝状态时拆模收面相结合的方法,在保证混凝土成型的基础上,彻底避免了混凝土表面的气泡、水泡的产生,与传统施工方式相比,该工艺施工操作简单易行,对于反弧段混凝土及需要立模浇筑的斜坡段的混凝土成型和消除表面气泡有一定参考意义。

工艺参数对短电弧-电化学复合加工表面质量的影响研究

针对传统短电弧铣削加工后表面存在热损伤层问题,在钛合金TC4上进行了短电弧-电化学复合加工试验研究,分析了短电弧-电化学复合加工的材料去除机制,并通过理论模型分析了影响复合加工快慢及表面质量的关键影响参数,即加工电压、工作介质电阻率和进给速度。通过单因素试验研究了关键参数对短电弧-电化学复合加工表面质量的影响。试验结果表明,利用短电弧-电化学复合加工底面间隙电化学效应可以很好地去除短电弧加工后表面热损伤层。在进给速度为4 mm/min时可以实现无热损伤层加工,加工效率为354 mm^(3)/min,加工表面粗糙度Sa为17.982μm。

大断面盾构内部弧形件拼装和填充层质量控制要点分析

文章简要介绍了大断面盾构内部结构拼装工艺的现状和发展情况。并且结合工程案例,分析了大断面盾构弧形件拼装工艺及填充层质量控制要点,形成了充盈率计算方法,最后从自密实混凝土扩展度及充盈率两方面对填充层密实性和饱满度进行控制,可供大断面盾构弧形件拼装工艺在类似工程的应用作为借鉴。