磁滞

Cable reel motor torque constant tension which has the characteristics When the load increases in the motor output shaft speed will automatically come down, volume Rao assured when cable tension unchanged. Rao nature of this excellent performance closely integrated with the Volume; Cage used motor hysteresis coupling increases in size, functionality, easy installation, the constant tension similar characteristics, we can under the conditions required output torque. They can pull the cable external circumstances, hysteresis coupling protect cables; using torque motor controller to increase frequency hysteresis couplings Surge part because of the cable reel SCR converter using a new technology operation, smoothing adjustments to the motor terminal voltage, thereby ensuring that the output torque of the motor unchanged. so that the cable can smooth the road with the truck

其中力矩电机电缆卷筒具有恒张力的特点，当负载增加时电机的输出轴转速能自动随之降低，保证电缆卷饶时张力不变，这个优越的性能与卷饶性紧密结合；采用笼型电机加磁滞式联轴器具有体积小，功能全，安装维护方便，近似恒张力等特点，既可以根据工况需要输出力矩，又可以在电缆受外力拉住的情况下，通过磁滞式联轴器保护电缆；而采用力矩控制器加变频电机加磁滞式联轴节的电缆卷筒因其调压部分采用可控硅变流新技术，可以平滑地对电机的端电压进行调节，从而保证了力矩随负载的变化而改变，使电缆能平稳的跟大车的行进。

The change and the distribution of magnetic field in magnetic core are described with system state equations of magnetic switch and Jiles-Atherton model so that whole operation of magnetic switch and its application circuit can be obtained, meanwhile total loss, eddy current loss and magnetic hysteresis loss of magnetic switch can be calculated.

利用磁开关的系统状态方程和Jiles-Atherton磁滞回线模型描述磁芯中磁场的变化和分布，从而得到磁开关及其应用电路的整体工作特性，同时计算出磁开关的总损耗、涡流损耗和磁滞损耗。

Based on the Jiles-Atherton model, the dynamic hysteresis loss model of the transformer core considering the classic eddy current loss and abnormal loss is developed, which is suitable for all the reasonable coefficient of reversible magnetization and adopting the flux density as entry variable.

该文在Jiles-Atherton基本磁滞模型的基础上，从能量平衡原理出发，考虑铁心在交流状态下的涡流损耗和异常损耗，建立了合理可逆磁化系数条件下，以磁通密度作为输入量的铁心动态磁滞损耗模型。

The magnetic hysteresis and aftereffect have been measured and simulated by the Preisach hysteresis model of Fe_3O_4 nano-particles and _5Ta multilayer films.

利用Preisach磁滞模型模拟研究了Fe_3O_4纳米颗粒和_5Ta多层膜的磁滞和磁后效行为。

A new dynamic vector Preisach model that takesaccount of the anisotropic characteristics of media and vector reversible component ispresented.

第五章对旋转磁滞问题和交变磁滞问题进行了研究，分析了一些典型的交变磁滞模型，提出了一个新的考虑媒质各向异性及矢量可逆行为的动态矢量Preisach模型。

Generally speaking, when soft and hard magnetic powder mix with each other, the hysteresis loop of the mixture will be in wasp-waisted shape. The wasp-waisted loop is constricted in the middle section, but is wider above and below section. This phenomenon actually can be found in our experiment, too.

般而言当软硬磁混合后，其磁滞曲线会呈现蜂腰(wasp-waisted)结构，即磁滞曲线呈现中间部分较狭窄而旁较为宽胖，而实验的测也确实发现此现象。

Our works discuss the magnetic characteristics of wasp-waisted hysteresis loops and outline a rationale for this type of behavior by superposition of hard and soft magnetic phases. Because of the absence of magnetic interactions between particles, in measurement procedure, we could sum the magnetization mathematically of the isolated particles at each field value to create a composite hysteresis loops.

进一步再以复合模型磁相叠加的特性，以考虑忽略软硬磁晶粒间彼此交互作用的前提下，将软磁与硬磁的磁滞曲线以线性叠加得到不同磁场强度下各材料的磁化强度以描绘出该复合模型的磁滞曲线，并发现磁相叠加与实际量测的磁滞曲线虽相近但仍有其差异，而其差异则系由於软硬磁混合样品中其晶粒间仍有交互作用之存在。

The M-H behavior has displayed a ferromagnetic hysteresis loop with a wasp-waisted shape, which constricted in the middle section, while wider at above and below section.Further, various amount (1, 3, 5%)of NdFeB were mixed with Ni-Zn ferrites. The M-H behavior has shown markedly different coercivity and wasp-waisted hystsresis.

为了进行本研究，在样品制备上系以燃烧合成法制备奈米级镍锌铁氧体软磁磁粉，并与市售微米级铷铁硼硬磁磁粉加以均匀混合，最后压制成软硬磁复合之块材，并经由震荡样品磁性量测仪对软磁、硬磁与复合磁材加以量测以描绘出其磁滞曲线。

The cause of the C-V curve stretch-out is interface trapped charge.The hysteresis loop direction and area can to obtain type and amount of charges. From the result of measure, clockwise hysteresis loop is negative charges.

在磁滞方面，磁滞回路方向与面积可得知缺陷捕获电荷的形态与数量，由量测结果得知，磁滞回路为顺时钟代表捕获的电荷为负电荷。

Multiple experiments such as grain-sized separation , magnetic mineral analysis, magnetic parameters measurement were made on 110 surface samples and 64 samples of the 180 core sediment taken from the shelf of the East China Sea to abyssal plain of the Okinawa Trough .

本文选取东海陆架至冲绳海槽槽底平原的代表性沉积样品110个和已有研究基础的DH180岩心样品，通过颗粒分离、磁性矿物分析、趋磁细菌培养、浮游有孔虫δ~(18)O测定、AMS~(14)C测年、多种磁学参数测量(包括磁化率、等温剩磁、x-T热磁曲线、磁滞回线、非磁滞剩磁和饱和等温剩磁等)等试验手段，分析探讨了不同粒级沉积物对磁性的贡献、沉积物磁性与物质来源及环境的内在联系、短期古海洋事件的环境磁学表现等科学问题。

hysteresis error：磁滞误差

hysteresis cycle 磁滞循环 | hysteresis error 磁滞误差 | hysteresis loop 磁滞回线

magnetic hysteresis loop：磁滞回路,磁滞回线

磁滞 magnetic hysteresis | 磁滞回路,磁滞回线 magnetic hysteresis loop | 磁滞损耗 magnetic hysteresis loss

magnetic hysteresis loss：磁滞损耗

magnetic hysteresis loop 磁滞回线 | magnetic hysteresis loss 磁滞损耗 | magnetic hysteresis 磁滞

magnetic hysteresis loss：磁滞损耗,磁滞损失

magnetic hysteresis cycle 磁滞回线 | magnetic hysteresis loss 磁滞损耗,磁滞损失 | magnetic hysteretic angle 磁滞角

magnetic hysteresis cycle：磁滞循环

magnetic hysteresis angle 磁滞角 | magnetic hysteresis cycle 磁滞循环 | magnetic hysteresis loop 磁滞回线

magnetic hysteresis cycle：磁滞回线

magnetic hysteresis angle 磁滞角 | magnetic hysteresis cycle 磁滞回线 | magnetic hysteresis loss 磁滞损耗,磁滞损失

magnetic hysteresis angle：磁滞角

magnetic hysteresis 磁滞 | magnetic hysteresis angle 磁滞角 | magnetic hysteresis cycle 磁滞循环

hysteretic：磁滞的

1339. hysteresis synchronous motor 磁滞同步电机 | 1340. hysteretic 磁滞的 | 1341. hysteretic angle 磁滞角

hysteresis coefficient：磁滞系数,滞后系数

hysteresis characteristic || 磁滞特性(曲线) | hysteresis coefficient || 磁滞系数,滞后系数 | hysteresis curve || 磁滞回线,磁滞曲线

hysteresis synchronous motor：磁滞式同步电动机; 磁滞同步电动机

hysteresis motor 磁滞电动机; 磁滞式电动机 | hysteresis synchronous motor 磁滞式同步电动机; 磁滞同步电动机 | igniter motor 点火发动机