<strong>摘要</strong>
●磁性元件对功率变换器的重要性
●磁性元件的设计考虑与相应模型
●磁性元件模型参数对电路性能的影响
●变压器的涡流(场)特性-损耗效应
●变压器的磁(场)特性-感性效应
●变压器的电(场)特性-容性效应
<strong>功率变换器中的功率磁性元件</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28355-1.jpg"){kind=link}
●作用:起磁能的传递和储能作用,必不可少的元件
●特点:体积大,重量大,损耗大,对电路性能影响大
●挑战:对变换器功率密度影响很大,成为发展瓶颈
<strong>功率变换器技术与磁性元件</strong>
●拓扑: 正激,反激,推挽,全桥移相,LLC,等,磁集成,磁耦合;
●控制: 控制芯片+控制电路,变压器环节+滤波器环节;
●封装: PCB绕组,绕组+同步MOS, 超薄磁元件;
●元件: 有源器件,电容,磁性元件(设计+定制);
●仿真: 电路模型,器件模型(IC, MOS, Diode, Cap, 磁性元件);
●电磁兼容: 布板,EMI滤波器, 分布参数, 近场耦合;
●制造: 自动化, 磁性元件(人工制作)
●品质: 磁性元件测试,失效分析。
<strong>磁性元件的模型</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28356-2.jpg"){kind=link}
<strong>变压器模型</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28357-3.jpg"){kind=link}
<strong>电感器模型</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28358-4.jpg"){kind=link}
<strong>反激变换器实际工作波形</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28359-5.jpg"){kind=link}
<strong>DCM下波形与变压器参数</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28360-6.jpg"){kind=link}
<strong>CCM下波形与变压器参数</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28361-7.jpg"){kind=link}
<strong>电感分布电容EPC对损耗的影响</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28362-8.jpg"){kind=link}
<strong>变压器中的磁场/涡流场分布特性</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28363-9.jpg"){kind=link}
<strong>铜箔导体的涡流损耗特性</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28364-10.jpg"){kind=link}
<strong>降低变压器的绕组损耗--基本结构考虑</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28365-11.jpg"){kind=link}
<strong>不同绕组结构的磁场和电流密度分布</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28366-12.jpg"){kind=link}
<strong>绕组的分布电容EPC</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28367-13.jpg"){kind=link}
<strong>电感绕组分布电容的形成机理</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28368-14.jpg"){kind=link}
<strong>电感绕组不同绕法对分布电容的影响</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28369-15.jpg"){kind=link}
<strong>分布电容计算的基本方法</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28370-16.jpg"){kind=link}
<strong>线圈分布电容的近似理论计算</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28371-17.jpg"){kind=link}
<strong>多层线圈的分布电容</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28372-18.jpg"){kind=link}
<strong>带屏蔽层的绕组分布电容</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28373-19.png"){kind=link}
<strong>分段绕组的分布电容特性</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28374-20.jpg"){kind=link}
<strong>变压器内部的电荷分布情况与分布电容</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28375-21.jpg"){kind=link}
<strong>有屏蔽层变压器内部的电荷分布情况</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…; alt=“” width="600"></center>
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28376-22.jpg"){kind=link}
<strong>变压器副边电荷的抵消设计</strong>
<center><img src="http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…;
![http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28…](http://mouser.eetrend.com/files/2017-10/%E5%8D%9A%E5%AE%A2/100008483-28377-23.jpg"></center>){kind=link}
<strong>结论</strong>
●磁性元件技术对功率变换器是十分重要的;
●磁性元件的分布参数对电路性能(效率,功率密度和可靠性)具有重要的影响;
●从磁性元件内部的磁场、电场和涡流场层次,可以更深入完整地理解磁性元件的各项参数;
本文转载自<a href="https://mp.weixin.qq.com/s/bc7Xhv_qbcR9t6GvxrsL4Q">电源研发精英圈</a>
转载地址:https://mp.weixin.qq.com/s/bc7Xhv_qbcR9t6GvxrsL4Q
声明:本文为转载文章,转载此文目的在于传递更多信息,版权归原作者所有,如涉及侵权,请联系小编进行处理。