共查询到18条相似文献,搜索用时 93 毫秒
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采用温压工艺制备了钕铁硼粘结磁体,研究了温压压力、温压温度、粘结剂种类及含量对磁体磁性能的影响,以及温压工艺对钕铁硼粘结磁体氧含量的影响.利用Nd2Fe14B/a-Fe系双相纳米晶磁粉为原料,在200℃下,采用12MPa的压力,获得性能最佳的磁体,其密度为6.43 g/cm3,磁性能为:Br=0.808 T,Hcb=461 kA/m,Hci=623 kA/m,(BH)max=101 kJ/m3. 相似文献
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通过磁粉表面处理及在NdFeB磁粉中添加不同比例的粘结剂,制备了金属基和塑料基两种粘结磁体,研究了不同基体磁体的稳定性和磁性能,从断口SEM照片及结合理论分析可得出结论磁粉的表面处理可以改善磁体的稳定性及磁性能,通过磁性能测试及对比和退磁率的测量可以看出塑料基磁体的磁性能低于金属基磁体,但其稳定性却显著提高,塑料基磁体的使用温度可达150~180 ℃. 相似文献
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NdFeB粘结磁体的使用温度及磁性能 总被引:3,自引:0,他引:3
对磁粉进行表面处理,利用冷、热模压法制备了金属基及塑料基两种粘结NdFeB磁体,研究了表面处理前后及不同基体磁体的使用温度和磁性能.研究结果表明磁粉的表面处理可以提高磁体的磁性能及使用温度,塑料基磁体的磁性能低于金属基磁体的,但其使用温度却较高,可达180 ℃左右. 相似文献
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各向异性粘结NdFe12Nx磁体工艺探讨 总被引:1,自引:0,他引:1
用不同的工艺制备了各向异性粘结NdFe12Nx磁体,并对影响其各向取向度的各个因素进行了分析。结果表明,在制备各向异性粘结NdFe12Nx磁体过程中对磁粉进行强磁场处理、湿法处理,可以较大程度提高粘结磁体的取向程度,从而制得性能优异的各向异性粘结磁体。 相似文献
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粘结剂作为粘结NdFeB磁体制备过程中的重要组成部分,其作用是提高磁粉颗粒的流动性和粘结强度,保证产品的力学性能和磁性能的稳定。采用理论与实验相结合的方法,研究了粘结剂含量对粘结NdFeB磁体力学性能和磁性能的影响。在此基础上,制备了高性能粘结NdFeB磁体。利用扫描电子显微镜(SEM)对磁体的结构和形貌进行了表征。在NIM-200C磁滞回线仪和电子万能试验机(AG-X plus)上分别测定了环形粘结NdFeB磁体(RSM)的磁性能和力学性能。结果表明,当粘结剂含量为3%(质量分数)时,粘结NdFeB磁体密度最高(5.59 g/cm3),抗压强度最高(159 MPa),磁性能最佳。 相似文献
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Nanocrystalline Nd2Fe14B/α—Fe permanent magnet 总被引:2,自引:0,他引:2
Nd8.5Fe75Co5Cu1Zr3Nb1B6.5bonded magnet was prepared by melt-spinning(vs=18m/s)and subsequent heat treatment(670℃,4min).Excellent magnetic properties of the bonded magnet were achieved:Br=0.68T,iHc=620.3kA/m,(BH)max=74kJ/m^3.The addition of Cu and Zr elements shows to be advantageous in improving an intrinsic coercivity and squareness of hysteresis loop,as well as energy product.In has a remarkable remanence enhancement and the isotropic saturation remanence ratio Mr/Ms is 0.83. 相似文献
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Warm compaction and room temperature compaction were applied to prepare bonded Nd-Fe-B magnets. The results indicated that the density of magnet was determined by the compaction pressure and warm compaction temperature, whereas, the thermosetting temperature could hardly affect the density of magnet. The mechanical properties of magnets were the best when the thermosetting temperature was 200 ℃. The Br, Hcb, and (BH)max of warm compaction magnet were higher than those of room compaction. When the warm compa... 相似文献
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V. Panchanathan 《Journal of Materials Engineering and Performance》1995,4(4):423-429
The advent of neodymium-iron-boron materials having excellent magnetic properties and potential economic advantages has initiated
a new era in permanent magnet technology. One method of making these magnets is by the rapid solidification process. It is
typically carried out by melt spinning, which produces a highly stable, dmagnetically hard microstructure powder, directly
from the melt. This can be used for bonded magnet applications. Alternatively, this powder can be hot pressed to produce fully
dense isotropic magnets with energy products up to 15 MGOe. Anisotropic magnets with energy products ranging up to 50 MGOe
can be produced by thermomechanical orientation or hot deformation process. Current processing and properties of Magnequench
(General Motors) materials are reviewed, das well as the applications and advances of these materials. The advances include
high-temperature bonded magnet and high-energy product anisotropic bonded and fully dense magnets. 相似文献
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Dong-Tao Zhang Peng-Fan Wang Ming Yue Wei-Qiang Liu Jiu-Xing Zhang Jennifer Anand Sundararajan You Qiang 《稀有金属(英文版)》2016,35(6):471-474
Anisotropic Mn Bi/Nd Fe B(Mn Bi contents of0 wt%, 20 wt%, 40 wt%, 60 wt%, 80 wt%, and 100 wt%)hybrid bonded magnets were prepared by molding compression using Mn Bi powders and commercial hydrogenation disproportionation desorption and recombination(HDDR) Nd Fe B powders. Magnetic measurements at room temperature show that with Mn Bi content increasing, the magnetic properties of the Mn Bi/Nd Fe B hybrid bonded magnets all decrease gradually, while the density of the hybrid magnets improves almost linearly. In a temperature range of 293–398 K, the coercivity temperature coefficient of the hybrid magnets improves gradually from-0.59 %áK~(-1)for the pure Nd Fe B bonded magnet to-0.32 %áK~(-1)for the hybrid bonded magnet with 80 wt%Mn Bi, and the pure Mn Bi bonded magnet exhibits a positive coercivity temperature coefficient of 0.61 %áK~(-1). 相似文献
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采用快淬法制备了镨基(Nd,Pr)10.5-x Dyx Fe83.5B6(x=0.0,0.5,1.0,1.5,2.0,2.5)系列粘结磁体,研究了Dy元素添加对快淬合金显微组织结构、磁性能及快淬薄带热稳定性的影响。与Nd2Fe14B相比,硬磁相Dy2Fe14B具有较高的磁晶各向异性场HA和较低的饱和磁极化强度Js,因此,Dy元素添加能显著提高合金的内禀矫顽力Hcj,但会降低合金的剩磁Br。Dy元素替代Nd/Pr元素,增强了快淬薄带的热稳定性,提高了晶化退火温度。较高的晶化退火温度,使快淬薄带中已经形成的微晶更容易长大,形成一些粗大晶粒,降低了粘结磁体的磁性能。1.0%是较佳的Dy元素添加量,(Nd,Pr)9.5Dy1Fe83.5B6合金快淬粘结磁体的最大磁能积(BH)max为71.6 k J/m3,剩磁Br为0.638 T,内禀矫顽力Hcj为611 k A/m。 相似文献