2) inductively coupled
电感耦合
1.
Designed the control system based on ATmega 16 according to the requirement of inductively coupled plasma spectrum instrument.
针对电感耦合等离子光谱仪控制要求,设计了以ATm ega 64为核心的控制系统,给出了相应的控制方案和器部件选型,并提出软件的模块化设计。
3) coupled inductor
耦合电感
1.
A coupled inductor was used to substitute inductor, so that the circulating current in the zero state could be zero.
该变换器用耦合电感代替常规电感,耦合电感通过变压器反射到原边,使变换器在零状态时的环流减小到零,实现了外管零电压开通,内管零电流关断。
2.
Based on the analysis of the shortage of the single-phase Boost converter in the high gain applications,a method of adding an equivalent DC voltage source was proposed,and a type of Boost converter using coupled inductor was described.
在分析普通单相Boost变换器在高增益变换场合显现的不足的基础上,提出了串入等效电压源的概念,采用耦合电感实现了高增益变换。
3.
The auxiliary circuit is composed of an auxiliary switch,a coupled inductor(flyback transformer) and a feedback diode.
辅助电路由辅助开关管、耦合电感(反激变压器)和反馈二极管构成。
4) tapped inductor
耦合电感
1.
A tapped inductor ia attached at the secondary side of transformer instead of common filter inductor,the voltage induced by tapped inductor reflects to the primary side,which makes the circulating current of converter during the zero state decreas-es to zero.
该变换器以耦合电感取代常规滤波电感,耦合电感所感应出的电压通过功率变压器反射回初级,使变换器在零状态时的循环电流减小直至零,以实现内管的零电流关断。
2.
A tapped inductor was adopted to substitute for the normal inductor,so that the circulating current in the zero state could be reset to zero.
利用耦合电感取代常规滤波电感,耦合电感所感应出的电压通过功率变压器反射回原边,使变换器在零状态时的循环电流减小至零,以实现内管的零电流关断。
3.
To overcome the high voltage stress of the secondary side of the transformer, a novel zero-voltage and zero-current-switching (ZVZCS) three level converter is proposed: The free-wheeling primary current is reset to zero through introducing a tapped inductor attached at the secondary side.
针对零电流技术中因引入储能电容而引起的副边高电压应力问题,提出了一种新型的零电压零电流软开关三电平直流变换电路拓扑:通过耦合电感实现电流回零,通过改变耦合电感的变比来方便地设定原边环流置零时间,降低环流损耗,实现内管的零电流关断。
5) Mutual inductance coupling
互感耦合
1.
Factors that affect the mutual inductance coupling have been studied based on this model, including magnetic core material, position of the primary winding, winding method of the secondary winding and its position.
基于此仿真模型,研究了影响非接触电能传输系统互感耦合的因素,包括磁芯材料、原边导线的位置、副边线圈的绕线方式以及绕线位置等因素。
2.
Because the equivalent parasitic parameters of the capacitance and inductance of the EMI filter may affect EMI performance under highfrequency conditions,the mutual inductance coupling between equivalent parasitic parameters of highfrequency apparatus is used to improve the highfrequency performance of t.
在高频状态下,EMI电源滤波器的电容器和电感器所带有的等效寄生参数会影响EMI高频性能,基于此提出了利用高频元器件的等效寄生参数间的互感耦合改善滤波器高频性能的措施,考虑了差模电感与电容器的寄生串联电感之间存在互感耦合以及2个串联支路的串联电感之间存在耦合电感2种情况。
3.
Based on the principle of mutual inductance coupling,this system adopts to the techniques such as DDS and realized the accurate testing of the quality parameters of electronic labels.
系统基于ARM嵌入式硬件平台,根据互感耦合原理,应用DDS频率合成技术、FIFO数据缓冲结构及数字信号处理技术实现了电子标签质量参数的精确测量。
6) inductive coupling
电感耦合
1.
A brief talk about inductive coupling plasma atomic emission spectrograph(ICP-AES)
浅析电感耦合等离子体发射光谱仪
2.
Using self-made device, the functions of preventing electromagnetic interference of coaxial cable are studied, such as the capacitance coupling frequency characteristics, the shielding effects of the capacitive coupling and the inductive coupling.
利用自制实验装置 ,研究了同轴电缆的电容耦合频率特性、电容耦合屏蔽效果、电感耦合屏蔽效果 。
补充资料:感应耦合
感应耦合
inductive coupling
单位长度的平行导线间的电容值,对距离很近的导线可取c,=一opF/m。 图(b)为两条平行导线间磁场祸合的情况,11为干扰源电流有效值,频率为f,通过两导线间的互感M在另一导线的负荷RL:上产生电压UZ,R02为电源内阻,通常RoZ《R12,可用下式计算,即 UZ尧I,口M(2) 。一2二f,M可根据公式计算:M一M、l,M飞为单位长度的平行导线间的互感值,对距离很近的导线可取Ml=1拜H/m。 式(1)中的C、式(2)中的M都随两导线间距离的增加而减小,故加大干扰源与敏感设备的距离,也是减小感应祸合的方法之一。gonylng ouhe感应报合(induetive eoupling)近场辐射藕合的藕合方式,在工业技术中通常的术语是感应祸合。近场辐射辆合只用于说明基本的物理概念(见辐射藕合)。感应报合分为电场祸合(容性报合)和磁场报合(感性藕合)两种。 电场报合和磁场藕合的分析计算通常可用带有集中参数的电容或互感的等效电路.下图为两条导线之间的藕合及其等效电路.图(a)为两条平行导线间电场报合的情况,Ul为干扰源电压有效值,频率为f,通电越目卜· 电场辆合和磁场祸合及等效电路 (a)电场祸合;(b)磁场拐合过两导线间的电容C在另一回路的负荷电阻RLZ上产生干扰电压U:,RoZ为该回路电源内阻,通常RoZ《RL:。因电源电势不影响干扰电压,在图上未表示出。UZ可用下式估算,即 _R,,R。,_。__ U,勺U,口C二二业牛架一勺Uo CR。,(l) 一‘一‘一RLZ+RoZ一’一‘、U‘ 。~2二f,C可根据导线长度l计算:C一‘,l,‘,为
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参考词条