基于等效电流密度模型的多层有限长螺线管轴线磁场分析

为了解决短杆轴向霍尔磁场探头现场校准的难题,提出了采用便携式有限长螺线管作为标准磁场发生器的方法。建立圆柱坐标系下螺线管线圈模型,并提出等效电流密度(ECD)法,结合Biot-Savrt定理及磁场叠加原理,计算其轴线磁场强度,获得多层有限长螺线管轴线磁场的分布规律。同时,建立了多层有限长螺线管静磁场有限元模型,仿真计算获得给定激励电流条件下的空间磁场分布情况。根据理论分析结果,设计了中心磁场100 mT的螺线管试验样机,对ECD模型理论计算结果、仿真分析结果和样机测试数据进行对比。结果显示,在螺线管中心处,理论计算与仿真结果偏差在0.1%以内,试验测试结果与理论计算偏差在0.8%以内。分析结果验证了ECD法分析螺线管轴线磁场的有效性。该方法对于提高螺线管结构设计效率、优化设计参数等具有重要意义。

用于多导体传输参数提取的等效电流密度法

针对电信号的有效传输受外界环境引起自身参数变化的问题,提出了一种基于有限元方法求取传输参数的等效电流密度法.通过对实验中电路参数法的研究,建立了传输电缆中的多根铜芯相互作用模型.分析了导体间涡流作用的形式,求取此作用产生的感应电压和电流密度重新分布参数,由此推导出电阻和电感传输参数求解公式,由有限元方法实现了参数提取.仿真结果表明:这种方法能够实现多导体模型电阻和电感参数的有效提取;当信号频率升高时,交流电阻及功耗有所增加;电阻和电感参数均有相应的频变特性,即在特定频段内呈线性变化.

金属液单电流电磁净化的理论分析

系统地考察了直流、交流激励下 ,圆管、矩形管中金属液的磁场分布 ,针对磁场的不均匀性 ,提出了“等效电流密度”的概念 ,解析了电磁净化效率的理论公式 计算表明 ,一般情况下 ,3× 10 6A/m2 电流可以把钢液中 90 %的2 0 μm夹杂和 5 0 %的 10

Effects of temperature variation on Li_xFe PO_4/C(0

Li Fe PO4/C was prepared via solid state reaction and characterized with X-ray powder diffraction and charge–discharge test. As-prepared Li Fe PO4/C has a triphylite structure and exhibits an excellent rate capability and capacity retention. Electrochemical impedance spectroscopy(EIS) was applied to investigate LixFe PO4/C(0<x<1) electrode on temperature variation. The valid equivalent circuit for EIS fitting was determined which contains an intercalation capacitance for Li+ ion accumulation and consumption in the electrode reaction. The surface layer impedance needs to be included in the equivalent circuit when Li Fe PO4/C is deeply delithiated at a relatively high temperature. EIS examination indicates that a temperature rise leads to a better reversibility, lower charge transfer resistance, higher exchange current density J0 and greater Li+ ion diffusion coefficient for the LixFe PO4/C electrode process. The Li+ ion concentration in LixFe PO4/C is potential to impact the Li+ ion diffusion coefficient, and a decrease in the former results in an increase in the latter.