Development of ultra-narrow gap welding with constrained arc by flux band

Narrow gap welding has merits of lower residual stress and distortion, and superior mechanical properties of joints. A major problem of this process is the lack of fusion in sidewalls, hence many methods of weaving arc have been developed to increase heating effect of arc to the sidewalls. In this work, a new approach Without weaving arc is attempted to ensure the penetration of sidewall, and ultra-narrow gap welding with the gap of less than 5 mm was executed successfully. In this approach, the width of gap is decreased further, so that the sidewalls are made within range of arc heating to obtain the enough heat. In order to prevent the arc from being attracted by sidewall and going up along the sidewalls, two pieces of flux bands consisting of the specified aggregates are adhered to the sidewalls to constrain the arc. In addition, when flux band being heated by the arc, slag and gases are formed to shield the arc and the weld pool. This technique was tested on the welding experiment of pipeline steel with thickness of 20 mm. The involved welding parameters were obtained, that is, the width of gap is 4 mm, the welding current 250 A, and the heat input 0. 5 kJ/mm, the width of heat-affected zone is 1 -2 mm.

Weld formation and heating mechanism in ultra-narrow gap withconstricted arc by ultra-fine granular flux

Ultra-narrow gap welding （UNGW） process with high stabilization, reliability and without spatter can be achieved with constricted arc by molten slag wall, which is made from melted flux. The experiments are carried out by changing voltage under different currents. The results indicate voltage range being fit for UNGW is about 22 -31 V under the current range of 200 -320 A. With the increasing of voltage, weld formation of UNGW has the law of lack of fusion on sidewall, good weld and undercut in turn under a certain current. In addition, the action relationships among arc, molten slag wall and sidewalls can be improved by properly adjusting voltage and current of arc, which makes cathode spot properly distribute in ultra-narrow gap. Therefore, the effective control of weld formation of UNGW has been achieved.

Study on Axial Flux Hysteresis Motors Considering Airgap Variation

Axial flux hysteresis motor (AFHM) is self-starting synchronous motor that uses the hysteresis characteristics of magnetic materials. It is known that the magnetic characteristics of hysteresis motor could be easily affected by air gap and structure dimensions variation. Air gap length plays an important role in flux distribution in hysteresis ring and influences the output torque, terminal current, efficiency and even optimal value of other structural parameters of AFHM. Regarding this issue, in this study effect of air gap variation on performance characteristics of an axial flux hysteresis motor and effect of air gap length on hysteresis ring thickness and stator winding turns is investigated. Effect of air gap length on electrical circuit model is perused. Finally, simulation of AFHM in order to extract the output values of motor and sensitivity analysis on air gap variation is done using 3D-Finite Element Model. Hysteresis loop in the shape of an inclined ellipse is adopted. This study can help designers in design approach of such motors.

基于径向气隙磁密和定子电流的永磁同步电机均匀退磁故障诊断研究

该文提出一种基于径向气隙磁密和定子电流的永磁同步电机均匀退磁故障诊断方法。首先,建立电机的d轴等效磁路模型,分析均匀退磁故障后径向气隙磁密的变化规律;然后,获取电机的径向气隙磁密和定子电流信号,对各极下径向气隙磁密幅值进行归一化处理,并绘制雷达图,根据雷达图和比较相同定子电流幅值下健康电机和故障电机的各极下径向气隙磁密幅值的平均值,来诊断均匀退磁故障;利用空载各极下径向气隙磁密幅值的平均值计算故障程度。最后,仿真和实验结果均验证所提均匀退磁故障诊断方法的有效性。

Characteristics of land-atmosphere energy and turbulentfluxes over the plateau steppe in central Tibetan Plateau

The land-atmosphere energy and turbulence exchange is key to understanding land surface processes on the Tibetan Plateau(TP). Using observed data for Aug. 4 to Dec. 3, 2012 from the Bujiao observation point(BJ) of the Nagqu Plateau Climate and Environment Station(NPCE-BJ), different characteristics of the energy flux during the Asian summer monsoon(ASM) season and post-monsoon period were analyzed. This study outlines the impact of the ASM on energy fluxes in the central TP. It also demonstrates that the surface energy closure rate during the ASM season is higher than that of the post-monsoon period. Footprint modeling shows the distribution of data quality assessments(QA) and quality controls(QC) surrounding the observation point. The measured turbulent flux data at the NPCE-BJ site were highly representative of the target land-use type. The target surface contributed more to the fluxes under unstable conditions than under stable conditions. The main wind directions(180° and 210°) with the highest data density showed flux contributions reaching 100%, even under stable conditions. The lowest flux contributions were found in sectors with low data density, e.g., 90.4% in the 360° sector under stable conditions during the ASM season. Lastly, a surface energy water balance(SEWAB) model was used to gap-fill any absent or corrected turbulence data. The potential simulation error was also explored in this study. The Nash-Sutcliffe model efficiency coefficients(NSEs) of the observed fluxes with the SEWAB model runs were 0.78 for sensible heat flux and 0.63 for latent heat flux during the ASM season, but unrealistic values of-0.9 for latent heat flux during the post-monsoon period.

表贴式高速永磁同步电机失磁故障及磁体选区渗重稀土研究

针对表贴式高速永磁同步电机永磁体在受到高温、强退磁磁场等因素影响易产生局部不可逆失磁故障问题,本文基于有限元分析方法,分别建立了一台24 kW表贴式高速永磁同步电机的二维和三维仿真计算模型,在计及该电机在各类不同的退磁因素作用下,确定了电机磁体发生局部不可逆失磁故障的位置,并预测了磁体的进一步失磁扩散趋势。对比了电机在有无失磁故障情况下的空载气隙磁密和反电动势,并研究磁体不可逆失磁故障对电机运行的影响。由于永磁体易在部分区域发生不可逆失磁,故本文将磁体材料更换为较低牌号,并运用选区渗重稀土技术改善易失磁区域材料特性来提升磁体整体抗失磁能力。在此基础上,探究了更为合理的重稀土渗入区域及渗入梯度,从而保证在不失电机性能的前提下,实现了重稀土元素的极限应用,为表贴式永磁电机磁体选区渗重稀土技术提供了参考。

基于气隙磁密差信号峭度因子的永磁同步电机局部退磁故障诊断

该文提出一种新型基于气隙磁密信号差峭度因子的永磁同步电机局部退磁故障诊断方法。首先,建立永磁同步电机等效磁路模型,根据简化模型分析局部退磁故障后各极主磁路下径向气隙磁密的变化规律。然后,将预存健康电机空载状态下气隙磁密信号与测量的在线状态下气隙磁密信号作差并计算其峭度值,作为故障特征值。取健康电机空载状态下气隙磁密信号与不同工况下气隙磁密信号差峭度值的最大值作为参考值,根据故障特征值与参考值的大小诊断出局部退磁。最后,仿真和实验结果均验证提出的局部退磁故障诊断方法的有效性。

气隙偏心对同步发电机定子绕组温升特性的影响

为了分析同步发电机气隙偏心对定子绕组的铜耗及温升的影响规律。首先理论推导了正常情况和偏心下的磁通密度及相应的铜耗,分析了绕组的温升特性;然后建立了CS-5型故障模拟发电机的三维有限元模型,计算得到了发电机在不同负载和不同故障程度下定子绕组的铜耗和温度变化规律;最后在CS-5型故障模拟发电机上对定子绕组温度进行了实测,所得实验结果和仿真数据与理论分析结论基本一致。研究发现:定子绕组直线段温度高于端部温度;定子绕组的铜耗和温度在气隙偏心工况下均高于正常情况,且随着偏心量和负载的增加呈现升高趋势;在静偏心下靠近小气隙一侧的绕组温度高于其他部位。

Flux qubit with a large loop size and tunable Josephson junctions

We present the design of a superconducting flux qubit with a large loop inductance. The large loop inductance is desirable for coupling between qubits. The loop is configured into a gradiometer form that could reduce the interference from environmental magnetic noise. A combined Josephson junction, i.e., a DC-SQUID is used to replace the small Josephson junction in the usual 3-JJ （Josephaon junction） flux qubit, leading to a tunable energy gap by using an independent external flux line. We perform numerical calculations to investigate the dependence of the energy gap on qubit parameters such as junction capacitance, critical current, loop inductance, and the ratio of junction energy between small and large junctions in the flux qubit. We suggest a range of values for the parameters.

基于磁热双向耦合的PMSM转子动态偏心研究

针对外转子永磁同步电机(permanent magnet synchronous motor,PMSM)在制造、装配及使用过程中负载作用引起的动态偏心的影响,以120槽48级PMSM为研究对象,使用一种考虑温度变化对电机材料属性影响并反馈到电磁分析中进行多次迭代计算的磁热双向耦合分析方法,通过建立PMSM磁热双向耦合模型,基于额定工况对模型进行仿真计算,求解并分析了转子动态偏心对PMSM各部分损耗、温升、电磁性能及径向不平衡磁拉力的影响规律。研究表明,随着偏心率的增加,气隙磁密出现不均匀分布,并产生径向不平衡电磁力,其中径向电磁力密度谐波起主要作用的为低次、奇数谐波;磁密变化造成PMSM损耗和温升增加。通过对比表明,磁热双向耦合与单向磁热耦合相比更接近真实数据,具有更高的分析精度和可靠性。

基于槽极比选择的切向永磁同步电机永磁体涡流损耗抑制措施

为抑制切向永磁同步电机的永磁体涡流损耗,基于麦克斯韦方程和本构方程,对永磁体形状进行近似假设,构建了永磁体涡流损耗的估算模型。使用一种基于卡特系数概念的磁导函数来估算由于定子开槽引起的槽下磁感应强度变化。基于五台槽极比分别为1.05、1.20、1.30、2.40和3.60的电机设计方案对理论分析结论进行了验证。在负载电流和两倍负载电流下,分析永磁体损耗,得到了每台电机的径向气隙磁密曲线及其谐波含量。考虑到增加槽极比对定子铁耗和永磁体涡流损耗的削弱效果,给出了电机槽极比选择策略。研究结果表明,增加槽极比能减弱定子槽下磁感应强度变化,从而抑制气隙磁场中低次谐波含量,减小永磁体涡流损耗,使电机运行更加可靠,但也会引入更多高次谐波,从而增加定子铁耗。

风能接入电机气隙磁链定向矢量控制技术

风能是中国最具潜力的可再生能源之一,而影响风能转化应用的主要因素是风力发电机的控制方法及特性。针对风能转化应用过程中遇到的风力发电机控制方法难以实现对风能的有效捕获问题,提出一种基于气隙磁链定向的矢量控制技术,通过6s/2r矢量变换得到旋转坐标系下电机的数学模型;对气隙磁链定向矢量控制技术进行研究,设计电机电流电压混合磁链观测模型,实现对电机转矩与磁通的独立控制;以双Y移30°六相同步电机为例进行仿真分析。结果表明:所提技术在电机空载启动与突加负载时具有较好的稳态性能和动态性能,解决多相电机控制的非线性和耦合性,提高模型的通用性和快速性。

新型Halbach阵列盘式永磁电机的磁场解析

基于印制电路板(PCB)技术的盘式永磁电机(AFPMM)提出一种新型Halbach阵列的转子结构,该阵列结构简单、易于优化。运用矢量磁位法对新型转子产生的空载气隙磁密进行解析推导,获得关于气隙磁场的数学模型。基于该模型,保持永磁体总用量不变,以永磁体极弧系数比和径向长度比作为优化变量,气隙磁密基波幅值和谐波畸变率作为优化目标,确立最优转子结构参数。三维有限元仿真结果表明,解析法所得的气隙磁密波形与有限元法基本一致,验证了所提出解析模型的合理性。与传统Halbach阵列相比,新型Halbach阵列气隙磁密基波幅值提升了10.3%,同时谐波畸变率由19.8%降至4.8%,优化效果明显,可以有效降低高频工况下电机的涡流损耗、提升电机效率。最后制造一台样机进行相关实验测试,验证了解析和仿真分析的正确性,对PCB定子AFPMM的设计具有一定参考价值。

极弧系数和磁极边缘角度齿槽转矩优化设计

齿槽转矩对永磁电机的动态性能影响较大,削弱齿槽转矩是永磁电机设计的重点之一。本文运用复磁导率法结合麦克斯韦应力张量方程,推导出了齿槽转矩的解析求解方法,并基于解析法和遗传算法分别对电机极弧系数及磁极边缘角度进行了优化,在优化过程中不降低电机的整体气隙磁密。通过有限元软件Maxwell进行验证,结果表明所求得的最优极弧系数精度在3%以内,优化后的磁极边缘角度可使电机齿槽转矩幅值最高降低48%。本文所使用的优化方法不需要较长求解时间,且具有较高的优化精度,通过优化极弧系数和磁极边缘角度可以有效降低齿槽转矩幅值,为电机的齿槽转矩削弱及动态性能优化设计提供了一定的工程意义。

盘式实心磁力耦合器气隙磁场分布及转矩分析

针对一台9对极盘式实心磁力耦合器,为研究其气隙磁场分布及转矩,引入层理论模型,将磁力耦合器划分为非导电区域和导电区域两部分,推导二维标量磁位法,求解非导电区域的标量磁位和导电区域的磁场强度,同时引入卡特系数进行校正,推导出盘式实心磁力耦合器的气隙磁密和输出转矩公式;然后,通过有限元软件模拟得到磁力耦合器的三维气隙磁场分布、涡流分布和输出转矩,并分析了不同工作参数对输出转矩的影响;最后,搭建三维气隙磁场测量试验平台和传动试验平台进行三维气隙磁场和转矩的试验,所得试验结果与理论计算结果、仿真结果基本吻合。结果表明,推导的气隙磁密和输出转矩公式具有较高的准确性,为进一步研究盘式实心磁力耦合器的传动特性提供参考。

升力体缝隙模型红外测热试验及分析

针对升力体缝隙模型在中国空气动力研究与发展中心的Φ0.3 m高超声速低密度风洞中开展了红外测热试验,试验马赫数12、总温668 K、总压4.731 MPa、攻角0°和35°,获取了模型的红外热图结果,并开展了相应的数值仿真分析。在此基础上,研究了选取不同帧次的红外热图进行数据处理对热流密度结果的影响,分析了缝隙干扰引起的热流密度增量。结果表明:投放后模型抖动对数据处理存在明显影响,建议在数据处理中采用模型投放稳定后(约1.2 s)的红外热图结果;“T”字型缝干扰区的热流密度增量需要引起重视,攻角35°情况下的峰值热流密度能达到无缝隙时热流密度的8倍以上;红外测热试验数据与CFD数据吻合较好,两者仅在很小的峰值干扰区域存在差异。下一步需要在CFD建模倒角处理、红外方案优化等方面开展工作。

异步起动永磁同步电机径向电磁力优化分析

异步起动永磁同步电机由于定转子开槽,且转子上有永磁体,气隙磁密谐波含量更高,由气隙磁场产生的径向电磁力谐波较大。现以一台异步起动永磁同步电机为研究对象,通过优化转子磁路结构,改善气隙磁密波形,从而削弱电机的径向电磁力谐波。对比优化前后的电机,优化后电机的径向电磁力谐波得到削弱,电机的空载反电势谐波、齿槽转矩、负载转矩脉动也明显减小,起动转矩波动得到优化。最后通过试验测试了电机的振动加速度和噪声水平,验证了优化设计的合理性和有效性。

一种应用于精密隔振平台的双曲线磁通磁轴承设计

针对精密隔振系统磁轴承存在悬浮力密度小、波动大以及耦合力大问题,设计了一种双曲线磁通结构的磁轴承(MBHFM)。首先利用等效电流法和永磁体镜像法推导了带有磁轭的双曲线磁通的磁轴承的气隙磁场和悬浮力的表达式,并分析了磁轴承悬浮力波动对隔振性能的影响。其次根据双曲线磁通的磁轴承悬浮力线性分布特点,采用电流前馈补偿方法使磁轴承获取更低悬浮力波动的恒定悬浮力。最后,对双曲线磁通的磁轴承与常见的双边Halbach结构磁轴承(MBBH)进行了仿真分析与测试。仿真结果表明所设计双曲线磁通的磁轴承样机静态悬浮力平均值为153.75 N,静态耦合力系数为0.42%,电流前馈补偿后合成悬浮力波动系数为0.15%,较双边Halbach结构磁轴承静态悬浮力密度提高了20%,静态耦合力系数减小了72.2%,合成悬浮力波动系数减小了89.3%。测试结果进一步验证了所设计样机的高性能。

球磨机振动仿真及分析

球磨机作为石油化工企业的关键耗能设备,在国民经济中占据核心地位。其采用的永磁直驱系统显著提升了运行效率,并在节能方面取得显著成效。然而,转子与辊筒的一体设计使得偏心等机械问题复杂且突出,同时定转子间缺乏支撑结构,气隙均匀度难以保证,导致转子偏心风险增加,加剧球磨机振动。聚焦于球磨机永磁同步电机的电磁力研究,通过计算径向气隙磁密和电磁力密度,并仿真不同偏心状态下的振动加速度,探究了抑制偏心和减振的方法。本研究旨在为球磨机的稳定运行提供理论和技术支持,以期降低能耗、提升效率,并减少机械故障。

10kN推力电动振动台磁路仿真

电动振动台磁路计算是电动振动台设计阶段的重要一环,气隙磁感应强度和台面漏磁是其两个重要性能指标。在设计阶段准确计算出电动振动台气隙磁通密度分布和台面漏磁具有重要意义,有利于缩短研发周期和减少研发成本。本文以10kN推力电动振动台为例,采用有限元法计算其气隙磁通密度分布和台面漏磁,并以实测数据进行对比,结果表明:气隙平均磁通密度仿真结果与实测结果接近,误差仅为1.3%;台面漏磁仿真结果与实测结果误差为29.3%。