从而为锰锌铁氧体性能的改善提供了新的线索。
Hence, it offers a new clue to improve the properties of Manganese-Zinc ferrite.
烧结温度对锰锌铁氧体的起始磁导率有重要影响。
And sintering temperature has an important effect on the initial permeability of Mn-Zn ferrites.
提高反应温度和延长反应时间,均有利于锰锌铁氧体的晶化过程。
The crystallization process can be prompted by increasing the reaction time and temperature.
实验结果证明在相对低温的情况下,制备以锰锌铁氧体为填充物的磁性纸用纤维是可行的。
The test results show that the preparation of magnetized paper fiber filled by manganese zinc ferrite is feasible at relatively low temperature.
本文介绍了国内外现行锰锌铁氧体材料的制备方法及研究进展,包括传统的干法工艺和湿法工艺。
This paper is introduced the domestic and foreign current manganese zinc ferrite material preparation method and research progress, including the traditional one does the law craft and wet law craft.
采用水热合成方法制得了晶相单一的锰锌铁氧体,对样品进行了XRD、磁滞回线和温升曲线的测定。
MnZn ferrite was prepared by hydrothermal method, and its property was described by XRD, hysteresis loop and temperature rise curve.
采用化学共沉淀法,通过加入分散剂,制备了团聚程度低、结晶度完好、具有较好磁性能、不同组成的锰锌铁氧体粉末晶体。
The homogeneous low-agglomerated and well crystallined MnZn ferrite powder with good magnetic properties were prepared by coprecipitation method and adding dispersant.
而锰锌软磁铁氧体微粉的合成方法是目前改善和提高铁氧体性能的重要手段。
While the method on preparing soft magnetic ultrafine powders is the important measure to ameliorate and improve the quality of ferrite.
特别适用于锰锌高导软磁铁氧体和低功耗软磁铁氧体等高档铁氧体材料的气氛烧结。
It is especially applicable for sintering Mn-Zn soft ferrite material with high permeability and low power loss.
介绍了直接法制备锰锌软磁铁氧体材料的工艺流程、特点及原理。
In this paper, the technological process, characters and principle of preparation of Mn-Zn soft magnetic ferrite by direct-method were introduced.
以软锰矿、硫化锌精矿及铁屑等为原料,研究了直接法制备锰锌软磁铁氧体的工艺条件,重点研究了浸出液复盐沉淀深度净化的工艺条件。
A novel technology, which is on the preparation of Mn-Zn soft magnetic ferrite using Fe, Mn and Zn existing in waste battery as raw materials, was proposed.
以软锰矿、硫化锌精矿及铁屑等为原料,研究了直接法制备锰锌软磁铁氧体的工艺条件,重点研究了浸出液复盐沉淀深度净化的工艺条件。
A novel technology, which is on the preparation of Mn-Zn soft magnetic ferrite using Fe, Mn and Zn existing in waste battery as raw materials, was proposed.
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