电磁在线(英文视频)【低频篇】- 3. 无线充电
讲师:Christian Kremers
01:30 电感耦合
04:00 软磁材料:铁氧体线性化
09:30 铁氧体损耗:Steinmetz拟合
10:45 铁氧体损耗:磁导虚部获取
12:40 绞合线损耗:半分析模型
19:00 绞合线损耗:等效材料模型
22:30 后处理:变压器电路
26:30 系统级仿真:电源电路
Wireless Electrical Vehicle Charging (WEVC) is expected to play a major part in the roll-out of electric vehicles, allowing them to be charged conveniently in garages, car parks and bus stops.
In this video, we focus on:
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Workflows and best practices to predict the performance of individual coils as well as inductively coupled systems in the automotive environment. A magnetic coupler coil design was simulated.
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The accurate loss prediction in litz wires and ferrite materials
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Extraction of equivalent circuit parameter and relevant design quantities using a specialized postprocessing template was shown.Based on circuit description the operating point was deduced. Field and loss distributions at operating point were calculated and postprocessed to check exposure limits.
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Examples of electric vehicle charging and the charging of electronic devices inside the car
“Steinmetz coefficients”:
The losses Pc in W/set in a soft ferrite core may be expressed as
Where:
f (kHz) is the actual operating frequency and B (mT) the actual operating peak sinusoidal flux density at an operating temperature Top (°C);
pvsin is the loss density in kW/m3 at temperature Top(°C), frequency fb (kHz) and peak sinusoidal flux density Bm (mT);
Ve (mm3) is the magnetic volume of the core;
Alpha is the Steinmetz exponent for frequency and Beta the Steinmetz exponent for flux density for the ferrite material at Top;
pvsin is measured on standard ring cores;
KF is a multiplication factor for the particular core shape in use;