磁场热处理

磁场热处理后多晶Ni2MnGa铁磁形状记忆合金组织的变化

Microstructural variation of a polycrystalline ni_2mnga alloy by magnetic heat treatment

纵向磁场热处理对50～55%Ni-Fe合金μ0和Br的影响

Effect of Longitudinally Magnetic Heat Treatment on μ _0 and B_r in 50 ~ 55 % Ni-Fe Alloy

采用X射线衍射，场发射电子显微镜，交流梯度样品磁强计等方法研究了在富稀土情况下，磁场热处理对薄膜结构特性，微观结构及磁性能的影响。

Structural characterization , magnetic measurement and microstructure observation were carried out by X-ray diffractometer , AC grads sample magnetometer , field emission scan electronic microscope , respectively .

真空磁场热处理对Tb（0.3）Dy（0.7）Fe（1.95）合金磁致伸缩性能的影响

Effect of magnetic field heat-treatment on vacuum magnetostriction property of Tb_ ( 0.3 ) Dy_ ( 0.7 ) Fe_ ( 1.95 ) alloy

Fe-Co软磁合金真空磁场热处理工艺研究

Study on Fe-Co magnetically soft alloy vacuum magnetic heat treatment process

真空与磁场热处理改善FeCo合金的软磁性能

Improvement of soft magnetic properties of FeCo core alloy by vacuum and field annealing

Fe-N软磁薄膜的性能及其磁场热处理后的各向异性模型

Excellent Soft Magnetic Properties of Fe-N Films and a Model to the Anisotropy after Magnetic Heat Treatment

利用自制的磁场热处理设备对中、高碳钢进行了施加磁场与不施加磁场的淬火处理，研究了奥氏体在NaCl溶液中冷却时的组织转变，观察了相变后的组织变化。

The medium and high carbon steels were quenched with and without magnetic field in the self-made quench tank , the austenite transformation in the NaCl solution was studied , and the microstructure change after phase transformation was observed .

纵向磁场热处理能有效消除非晶丝样品的磁各向异性，得到非对称巨磁阻抗（AGMI）效应。

Longitudinal heat treatment in magnetic field can eliminate magnetism anisotropy of the amorphous wires , and then asymmetry giant magneto impedance ( AGMI ) can be obtained .

磁场热处理及其应用和发展前景

Magnetic Heat Treatment and Its Prospects in Applications and Development

旋转磁场热处理对钴基非晶合金静磁性与磁稳定性的影响

Effect of Rotational Field Annealing on Static Magnetic Properties and Stability of Co-Based Amorphous Alloys

结果表明，磁场热处理可以大幅改善合金电极的倍率性能和气态吸氢速率。

The results show that magnetic annealing can improve the rate properties and hydrogen absorption rate largely .

临界区磁场热处理双相钢组织及性能的研究

A Study the Structure and Properties of Dual phase Steels Produced by Intercritical Heat treatment under a Magnetic Field

磁场热处理可细化晶粒，增强晶粒间磁交换耦合作用，提高磁性能；

Magnetic-field heat treatment can refine grains , enhance the exchange coupled interaction between the grains , and increase the magnetic properties .

研究结果表明：在磁场热处理铁素体钢或珠光体钢时，磁场能够显著地促进钢的传导传热、加速钢材的冷却、细化铁素体晶粒。

The effects of magnetic field on heat conduction of ferritic and pearlitic steels in the magnetic field heat treatment were studied .

钒元素还有细化晶粒的作用，并能改善脆性和磁场热处理效果。

In addition the brittleness and effect of heat treatment in magnetic field have been greatly improved and the grain size becomes smaller .

研究了磁场热处理对Tb0.3Dy0.7Fe1.95多晶合金磁致伸缩性能的影响。

Investigated the effect of magnetic field heat-treatment in vacuum on the magnetostriction property of the polycrystalline alloy Tb_ ( 0.3 ) Dy_ ( 0.7 ) Fe_ ( 1.95 ) .

对含碳量相对较低的钢而言，磁场热处理的实验参数可明显影响中温型相变产物贝氏体的形态。

For the steel with lower carbon content , the experimental parameters of heat treatment under the field can significantly affect the morphologies of bainite , which is the product of bainite phase transformation .

强磁场热处理，作为一种新型的热处理方法，主要是在材料的固态相变过程中，利用不同的组成相或溶质元素之间磁性能的差异，进而改变材料的热处理过程及效果。

High magnetic fields heat treatment , as a novel heat treatment method , mainly takes advantage of the differences of magnetization energy between different compositions or solute elements during the solid-state phase transformations , thereby changing the process and effectiveness .

本论文的第二部分主要通过磁控溅射法研究制备了Mg-Ti薄膜，为下一步Mg-Ti薄膜强磁场下热处理研究做了准备工作。

The second part of this paper mainly prepares films for the study of the effect of the high magnetic fields heat treatment on the texture of films . Mg-Ti films were prepared by magnetron sputtering method .

本文研究了弱磁场条件下热处理工艺对FeCrAl铁磁型减振合金内耗值的影响。

In this paper , under the conditions of weak magnetic field , the effect of heat treatment process on the internal friction Q ~ ( - 1 ) of ferromagnetic damping Fe Cr Al alloys has been studied and analysed .

较高的磁场强度也是实现热处理优化的重要条件之一。

Higher magnetic field intensity is also one of the conditions to optimize the heat treatment .