Modeling transient fluid flow and heat transfer phenothena in stationary pulsed current TIG weld pool

A mathematical model is presented to describe transient behavior of heat transfer and fluid flow in stationary pulsed current tungsten inert gas (PC-TIG) weld pool, which considers three kinds of driving, forces for weld pool convection, i,e. buoyancyforce, electromagnetic force and surface tension force. furthermore. the effect of vaporization heat flux at the free surface of weld pool and the temperature coefficient of surface tenston which is a function of temperatuer and composition are considered in the model In order to accelerate the convergence of iteration the AST(additive source term)method which concerns with the thermal energv boundary conditions is extended successfully to deal with the momentum boundary conditions by which the transient momentum equation and energy equation are mutually coupled. At the same time. ADI (Alternating direction implicit) method and DBC (double blocks correction) technque are employed to solve the finite difference equations. The results of numerical simulation demonstrate the transient behavior of PC-TIG weld pool, as well as the periodic variation of fluid flow and heat transfer with the periodic variation of welding current in stationary PC-TIG weld pool. The theoretical predictions based on this model are, shown to be in good accordance with the experimental measurements.

Synthesis of Co-Cr-Mo Fluorapatite Nano-Composite Coatings by Pulsed Laser Deposition for Dental Applications

Aim: The study was to fabricate FA nanopowder/Co-Cr-Mo dental alloy nanocomposite using pulsed laser deposition (PLD), and to evaluate bioactivity properties on simulated body fluid. Methods: In this work, the FA nanopowder was prepared by mixing calcium hydroxide (Ca(OH)2), phosphorouspent oxide (P2O5) and calcium fluoride (CaF2) in a planetary high energy ball mill using zirconium vial. Fluorapatite (FA) nanopowder was processed in the form of pellet for pulsed laser deposition process. The Co-Cr-Mo alloy was coated with FA nanopowder which was approximately 35 - 65 nm at various laser energy, pressure and time. The X-ray diffraction (XRD) was used to analyze phase, crystallinity and size distribution of Co-Cr-Mo/FA nanocomposite. The surface analysis was by scanning electron microscopy (SEM), Atomic Force microscopy (AFM) and Energy dispersive spectroscopy (EDS). Results: From the results obtained, It was shown that FA nanopowder deposited on Co-Cr-Mo alloy was stable during 14 days of incubation on simulated body fluid. It was also observed that the FA nanopowder coated on the surface of the alloy was still intact after the deposition process, which indicated the bioactivity and biocompatibility of the material. Conclusions: The fabrication of FA nanocomposite based dental alloys (Co-Cr-Mo) using PLD was done successfully. This was confirmed by various characterization techniques, which included XRD, AFM, SEM and EDS.

The Effect of Material Surface Microstructure on the Enhancement of Bone-Bonding Ability of a Hydroxyapatite-Implant by Low-Intensity Pulsed Ultrasound (LIPUS)

Excellent firm bonding between the biomaterials and bone tissue (osseointegration and osteo-conductivity) has been desired for the stability in vivo of dental implants and artificial joints. Much has been learned about this concept, which has led to significant improvements in the design and surface modification of implants in the field of implant dentistry, orthopedic surgery. We have already reported that low-intensity pulsed ultrasound (LIPUS) irradiation can accelerate the bone bonding ability of the bio-conductive materials such as bioactive titanium and hydroxyapatite implant. However, it is still unclear whether the LIPUS could have same effect to different types of the bioactive-materials. Therefore, in this study, the differences of bone-like hydroxyapatite formation on some kind of hydroxyapatite surface in simulated body fluid (SBF) under the LIPUS irradiation were investigated. Two kinds of hydroxyapatite samples immersed in SBF was exposed to ultrasound waves, the bone-like apatite on the surface was analyzed by Scanning electron microscopy and X-ray diffraction. As a result, the enhancement of hydroxyapatite formation on the surface by LIPUS was confirmed, the initial epitaxial nucleation and crystal growth of apatite depended on crystal structure of the surface of matrix materials.

Helmholtz型空化射流喷嘴结构优化数值模拟研究

目前Helmholtz型空化射流喷嘴结构尺寸偏大,不适用于空化射流洗井解堵作业,且与其相关研究缺乏对射流脉冲特性的评价。为此,利用CFD数值模拟方法探讨了结构参数对Helmholtz型空化射流喷嘴脉冲性能的影响规律,对该类型喷嘴的结构进行了优化。研究结果表明:在入口长度为5~15 mm时,空化射流脉冲特性和入口长度呈反比关系;在出口长度为5~10 mm时,空化射流的脉冲峰值和脉冲幅度与出口长度呈正比关系,脉冲频率基本不受影响;所得喷嘴最优结构尺寸为喷嘴入口直径2.5 mm,入口长度5.0 mm,谐振腔入口圆角1.0 mm,谐振腔直径10.0 mm,谐振腔长度2.0 mm,碰撞壁夹角60°,出口长度10.0 mm,出口直径3.0 mm。研究结果可为空化射流解堵技术中空化射流喷嘴结构优化设计提供理论参考。

单相脉冲整流器故障在线智能诊断实验设计

针对高速列车电力牵引系统中单相脉冲整流器的功率器件开路故障和传感器故障,设计了基于数据驱动的故障在线智能诊断实验。首先,对单相脉冲整流器系统进行数学建模,分析功率器件开路故障的故障拓扑和传感器故障的故障机理;然后,基于极限学习机算法和非线性自回归结构设计智能诊断模型,并将故障在线智能诊断实验分为离线训练和在线验证2个阶段;最后,基于RT Box半实物仿真器搭建快速原型控制实验平台,对故障模型和诊断模型进行实验验证。实验结果表明,构建的单相脉冲整流器故障在线智能诊断模型可以在1/4个基波周期内检测到故障的发生,并在3/4个基波周期内识别出具体故障类型。

深海浮球内部气压对水下内爆波的抑制机理

深海潜器常携带中空浮球来为其提供浮力。陶瓷因其高强度、低密度等优点成为浮球的理想材料。然而,中空结构在外部高压环境下易发生内爆,产生的内爆波会对周围结构产生毁灭性损害。为了探索浮球内部初始气压对内爆波的影响,首先,利用气泡动力学对其不考虑球壳影响时进行理论分析,得到内爆波压力脉冲沿径向以指数-1衰减,并指出其物理意义和隐含假设,进而从能量分析得到增加内压使压缩空气消耗的能量增加,从而减弱释放到水中的压力波能量;其次,采用三相流固耦合有限元模型进行计算,考虑水的可压缩性和球壳因挤压引起的脆性破裂的影响,得到更为接近实际的内爆压力的分布。由于两侧挤压球壳,外部的水在不断扩大的缺口处产生向内的射流,造成内部气体非球形塌缩,后续压力波呈现出与球壳碎裂方式有关的方向性差异。通过有限元模型对内部初始气压的研究表明,增加初始内部气体压力到1 MPa时,压力脉冲在球壳表面处下降了15.6%~24.8%。这一结果表明,在几乎不增加浮球质量的条件下,增加内部初始气压具有很好地抑制近端内爆波强度的效果。

海上风电二极管整流方案的多重化整流电路谐波分析

二极管不控整流单元作为海上风电送出系统的整流侧器件是海上风电领域的技术热点。二极管不控整流一般选择多重化整流电路,以12脉波整流电路居多。通过对多重化整流电路中的12脉波整流电路和24脉波整流电路的串联多重联结和并联多重联结分别进行理论分析,研究其交流侧电流和直流侧电压的谐波特性,得出其谐波次数与谐波幅值的计算方法,求出电流谐波总畸变率和电压纹波因数。对比分析12脉波整流电路和24脉波整流电路的特性,探讨将24脉波整流电路应用于二极管不控整流单元的可行性,并基于PSCAD/EMTDC进行了仿真验证。

基于高阶EKF的锂电池SOC测算精度研究

锂电池荷电状态是电池管理系统运行的前提和核心任务,为能够准确跟踪测算电池SOC值,以18650-20R型锂电池为主要研究对象,建立二阶Thevenin等效电路模型,经脉冲特性实验对电路模型参数进行辨识,在恒流、脉冲放电及Fuds工况下验证模型的准确性,并在此基础上实现了利用一阶、二阶及高阶EKF算法对电池荷电状态的估计。最后通过Matlab仿真结果验证,高阶EKF在锂离子电池动静态SOC测算时均具有更高的测算精度。

双级PIN限幅器的微波脉冲响应机理及规律

基于双级限幅器中两个PIN二极管的多物理场仿真模型与限幅器中其他电路元器件的SPICE模型,搭建了Si基双级PIN限幅器的场路协同仿真模型,利用这一模型对微波脉冲作用下限幅器中两级PIN二极管的温度响应特性进行了仿真.在此基础上对限幅器在不同频率、幅值微波脉冲信号作用下内部发生熔化现象所需的时间与能量进行了仿真,并对这一过程进行了机理分析与响应特性规律总结.仿真结果表明,当限幅器中第一级PIN二极管内部最高温度已达到材料熔点时,第二级PIN二极管的温度变化幅度较小.限幅器内部发生熔化现象所消耗的时间与能量随信号幅值、频率的变化呈现出规律性关系,发生熔化现象所需的时间随信号幅值或频率的提升而减小;发生熔化现象所需的能量随频率的提升而降低,随幅值的变化存在极大值点;限幅器的响应特性对信号参数表现出了不同的敏感性.

单开关谐振脉冲电源的过电压抑制

单开关谐振电路只需使用一个开关即可产生高压脉冲,然而当开关在谐振电流为正关断时会产生关断过电压,使开关损坏。为解决该问题,可在开关两端并联RCD(Resistance-Capacitance-Diode)吸收电路或在变压器原边并联R-D(Resistance-Diode)续流支路。但在高压脉冲条件下,这两种过电压抑制电路在不同负载下的带载特性以及效果优劣不明确。文中对比分析了两种电路的过电压抑制机理、参数选择依据、过电压抑制效果和元器件功耗。结果表明,含R-D支路的电源开关过电压与漏感电流和支路电阻R成正比,若R较大,其过电压系数大于含RCD吸收电路的电源。若R较小,元器件功率损耗较大。在高压脉冲电源中,RCD吸收电路的电容不需要在开关导通时将电放完。由于漏感限制,谐振脉冲电路在短路时电流不会过大而烧毁开关。同时,在驱动容性介质阻挡放电时电流能够自动反向,可实现零电流关断。

基于BUCK恒流电路的LED光源调节控制技术研究

为了提高气溶胶激光雷达(ALD)的测量精准度,设计一套模拟光源来校准ALD的接收系统。将BUCK电路和嵌入式控制系统相结合,提出了一种高准确性、低功耗的ALD校准光源调节控制技术。首先,设计了LED光源的控制系统和LED恒流驱动的控制电路结构;其次,根据继电反馈控制和Ziegler Nichols(Z-N)法设计了LED工作电流的比例、积分和微分(PID)自整定算法;最后,通过实验验证了控制电路具有低功耗、高准确性的特点。

SVPWM逆变器供电时FSCW-PMSM损耗特性研究

为探究空间矢量脉宽调制(space vector pulse width modulation,SVPWM)逆变器引入的时间谐波电流对分数槽集中绕组永磁同步电机(fractional-slot concentrated-winding permanent magnet synchronous machine,FSCW-PMSM)损耗特性的影响,文中提出一种SVPWM逆变器与FSCW-PMSM联合系统中电机损耗谐波特性分析方法。首先,理论分析了考虑时间谐波电流时电机损耗的时空谐波特性。其次,以一台三相双层绕组10极12槽PMSM为例,搭建电机与SVPWM逆变器的场路联合仿真模型,求解样机在恒转矩和恒功率调速时损耗的谐波特性,揭示各谐波损耗的产生机理。结果表明:转子谐波损耗由基波电流与次谐波、iZ±p次齿谐波和(f_(c)±4 f)/f、(f_(c)±2 f)/f次时间谐波电流与p、Z±p次空间谐波引起;定子铁芯谐波损耗由基波磁场、谐波励磁磁场及(f_(c)±4 f)/f、(f_(c)±2 f)/f次时间谐波电流引起。该结论适用于其他极槽组合的FSCW-PMSM。最后,通过实验验证了该分析方法的有效性。

高电压脉冲放电破岩系统建模分析

等离子体通道是高电压脉冲放电破岩的“工具”,通道形成及膨胀使岩石破碎过程伴随着通道阻抗的急剧变化。为更好地分析高电压脉冲放电破岩系统的能量利用效率,结合破岩空腔的脱模分析获得了通道的穿透深度及实际长度,基于能量平衡方程建立了等离子体通道阻抗模型,建立了高电压脉冲放电破岩系统的电路分析模型,仿真计算与试验结果对比表明该模型能够准确分析高电压脉冲放电破岩系统的输出特性,为系统优化提供理论指导。

二维脉宽调制转阀压力损失特性分析

传统的阀控液压系统通过改变控制阀的节流面积来实现流量控制,不可避免地会产生节流损失。可以认为高速开关阀在全开和全关状态下没有节流损失。受液压系统数字化和高速开关阀的启发,提出了一种新型的高频二维脉宽调制转阀。与由脉宽调制(PWM)信号驱动的电控开关阀不同,该转阀能够通过机械机构将流体以脉宽调制的形式被离散化,以实现根据系统执行器的需求进行流量分配。该转阀在实际工作中,阀口的打开仍然是一个渐进的过程,这不可避免地会造成部分压力损失。因此,采用计算流体动力学(CFD)的方法,建立了二维脉宽调制转阀的数值模型,分析了该转阀在旋转过程中和不同占空比下的压力损失特性,最终搭建了实验平台,对仿真结果进行了验证。结果表明,该阀在旋转过程中压力损失较小(阀口开度极小时暂不考虑),在50%占空比,10 L/min输出流量的工况下,其最大开度时的压降为0.1 MPa。

滤筒除尘器清灰均匀性影响因素及影响程度的模拟与优化研究

针对滤筒除尘器多孔脉冲喷吹清灰不均匀的问题,利用FLUENT数值模拟的方式建立了49种喷吹管设计参数与除尘器运行参数不同的正交试验组合模型,研究喷吹管管径D、喷孔直径d、喷嘴个数N、喷嘴间距L、喷嘴高度H和喷吹压力P等6个因素对多孔脉冲喷吹清灰不均匀度σ的影响程度,通过数值模拟试验与数据分析得到了6个因素影响程度的排序,基于喷孔直径d对清灰不均匀度σ影响程度最大的结果,以5孔脉冲喷吹管为例进行了对喷孔直径的优化改进,优化后的模型使滤筒除尘器的清灰均匀度提高了3倍,对喷吹管的参数设计具有指导意义。

结合深度神经网络的大气压脉冲放电转化CO_(2)研究

为了提高等离子数值模拟在放电等离子体转化利用CO_(2)研究中的计算效率,提出了采用具有多个隐藏层的深度神经网络(DNN)来研究大气压脉冲放电转化CO_(2)的放电特性与等离子体化学性质,经过训练的DNN能够极大地提高计算效率。DNN预测结果表明:当外加电压幅值不变时,增加脉冲上升率可以提高放电电流密度和击穿电压,同时增强鞘层区域的电场;脉冲坪区宽度的增加会提高介质板表面电荷密度,增强反向感应电场的强度,进而提高脉冲下降阶段的放电电流密度。此外,提高脉冲上升率和坪区宽度都会提高CO、O_(2)等产物的密度,导致CO_(2)转化率的增加。基于有限的训练集,DNN能快捷、准确地给出海量的数据以揭示CO_(2)放电的演化特性与转化规律,这为研究放电等离子体技术转化CO_(2)提供了新的计算工具。

轴配流液压脉冲发生器内泄漏规律研究

为了探究轴配流液压脉冲发生器的内泄漏影响因素,利用Solidworks建立简化的间隙流场模型,通过ICEM进行网格划分,使用Fluent软件进行流体仿真,以开度、高压侧间隙高度、偏心量、入口压力作为变量,计算不同高压侧间隙下的周向、轴向的泄漏量并进行比较,得到了转阀内泄漏变化的规律。结果表明:高压侧间隙高度是影响内泄漏量的主要因素,且周向泄漏量大于轴向;低压工况下,各偏心量的内泄漏量基本不变,而高压时偏心量对内泄漏量有明显影响;开度对内泄漏量的影响取决于腔体窗口是否与阀芯高/低压侧连通,腔体窗口的通断使内泄漏量产生约0.5 L/min的突变,不利于保持内泄漏量的稳定;入口压力的升高总使内泄漏量增加,在同样的压力下,高压侧间隙高度或偏心量越大,内泄漏增量越大。

基于Proteus的组合逻辑电路中竞争——冒险现象的仿真分析

为了生动直观地向学生讲授组合逻辑电路中的竞争—冒险现象,基于Proteus仿真软件搭建了仿真模块电路,对电路竞争—冒险的产生与消除进行了仿真实验测试,软件界面清晰展现了竞争—冒险的尖峰脉冲及消除结果。教学实践表明,通过仿真学生直观地观察到竞争—冒险产生的过程及采取不同措施后竞争—冒险的消除,为学生提供了学习理解竞争—冒险现象的新场景,提高了教学效果。

Meat Grinder放电特性分析

作为电磁轨道炮脉冲功率电源的Meat Grinder电路结构具有储能密度高,体积小等优势。针对Meat Grinder输出性能的影响因素不明确,工程应用困难的问题,对Meat Grinder的基础电路工作原理进行了探究。基于电磁耦合原理,分析了Meat Grinder的放电过程,给出了耦合系数和级数对Meat Grinder电流放大倍数、能量损耗以及能量利用率的影响特性,对比分析了多级Meat Grinder和单级耦合等效电路的输出性能。研究结果表明,耦合系数是影响电路输出性能的最主要因素。此外,单级耦合等效电路能够达到与多级Meat Grinder相同的输出性能,且工程应用更易实现。

MODELING TWO-PHASE FLOW IN PULSED FLUIDIZED BED

Mathematical models for pulsed fluidization are systematically discussed. Several undetermined constitutive relationships are included in the General Two-Fluid Model (GTFM), the adjustable parameters of which are always chosen at will to some extent. Although there are no adjustable parameters in the Basic Two-Fluid Model (BTFM), its eigenvalues are complex numbers and it is ill-posed for initial-value problems. The Local Equilibrium Model (LEM), a further simplification of BTFM, is discussed at length. Although the model is very simple, it is highly capable of simulating complex processes in pulsed fluidization over a broad range of operating parameters, and its numerical results well fit experimental results in both the variation of bed height and the distribution of particle concentration as fluidizing velocity varies.