基本信息科学研究教育教学研究成果新页签
基本信息


赵猛，男，汉族，1974年生。副教授；哈尔滨工业大学电气工程及自动化学院。

先后主持承担国家自然科学基金项目、黑龙江省自然科学基金项目等。

荣誉称号
2008年 获哈尔滨工业大学优秀共产党员荣誉称号

2008年 获哈尔滨工业大学电气工程及自动化学院优秀共产党员荣誉称号

2012年 获哈尔滨工业大学保密工作先进个人荣誉称号

2012年 获哈尔滨工业大学优秀学生专兼职学生工作者荣誉称号

2013年 获哈尔滨工业大学优秀学生专兼职学生工作者荣誉称号

2016年 哈尔滨工业大学保密先进个人

2019年 哈尔滨工业大学保密先进个人


工作经历
时间工作经历
1997年-2002年 哈尔滨工业大学电气工程系助教
2002年-2007年 哈尔滨工业大学电气工程系讲师
2007年-至今 哈尔滨工业大学电气工程系副教授
2005年-2007年 哈尔滨工业大学机械工程博士后流动站博士后


教育经历
1993年-1997年, 就读于哈尔滨工业大学电气工程系, 工学学士2000年-2002年, 就读于哈尔滨工业大学电气工程系, 工学硕士2002年-2005年, 就读于哈尔滨工业大学电气工程系, 工学博士


主要任职
2000年-2002年任哈尔滨工业大学电气工程及自动化学院团委书记

2002年-2004年任哈尔滨工业大学电气工程及自动化学院学生工作办公室副主任

2004年-2010年任哈尔滨工业大学电气工程及自动化学院 办公室主任/院工会副主席


科研项目

项目名称行波作用下磁性流体运动机理的研究

项目来源国家自然基金青年基金项目

开始时间2008-01-01

结束时间2010-12-01

项目经费22

担任角色负责

项目类别纵向项目

项目状态完成



项目名称交变磁场作用下磁性流体运动特性的研究

项目来源黑龙江省自然科学基金项目

开始时间2012-01-01

结束时间2015-04-01

项目经费5

担任角色负责

项目类别纵向项目

项目状态完成



项目名称大功率多单元永磁同步电机的无机械负载测试方法研究

项目来源国家自然基金面上项目

开始时间2013-01-01

结束时间2016-12-01

项目经费84

担任角色参与

项目类别横向项目

项目状态完成



项目名称防爆屏蔽电机电磁设计程序开发

项目来源企业课题

开始时间2013-06-01

结束时间2014-06-01

担任角色负责

项目类别横向项目

项目状态进行中



项目名称大扭矩力矩电机可靠性测试台的研制

项目来源重大专项子课题

开始时间2012-01-01

结束时间2015-06-01

项目经费50

担任角色负责

项目类别横向项目

项目状态完成



项目名称高温直流无刷电机开发

项目来源企业课题

开始时间2012-11-01

结束时间2013-03-01

项目经费24

担任角色负责

项目类别纵向项目

项目状态进行中



项目名称仿真转台用力矩电机研制

项目来源校内合作课题

开始时间2014-01-01

结束时间2015-06-01

项目经费210

担任角色负责

项目类别横向项目

项目状态进行中



项目名称****无刷力矩电机

项目来源国防科工委

开始时间2013-01-01

结束时间2015-06-01

项目经费117

担任角色参与

项目类别横向项目

项目状态进行中



项目名称高温测井无刷直流电机

项目来源企业课题

开始时间2013-01-01

结束时间2013-12-01

项目经费56

担任角色负责

项目类别横向项目

项目状态进行中



研究领域
一体化机电能量转换装置的研究

电机电磁场设计与分析

特种电机本体设计

电机工艺学

磁性流体密封

磁场作用下磁性流体力学研究



团队成员
暂无填写


专利

专利名称外转子旋转型磁性流体行波泵

专利号ZL**0.8

发明人赵猛、邹继斌、 胡建辉、 徐永向、 尚静、 赵博.

申请时间,完成时间2012-06-06

专利类别 发明



专利

专利名称带有螺线管的磁性流体行波泵

专利号ZL**7.0

发明人赵猛、邹继明、邹继斌

申请时间,完成时间2012-09-05

专利类别 发明


讲授课程
单相串激电动机课程设计

MATLAB 电机学计算机辅助分析和仿真

电机新原理、新技术与新型电磁机构

微电机结构工艺学
科技写作

工程技术基础

生产实习


招生信息
暂无填写


论文期刊

论文标题The out-rotator of Spin Traveling Wave Pump on Magnetic Fluid

作者Meng Zhao, Jibin Zou, Jing Shang

期刊名称Key Engineering Materials

期卷503

简单介绍According to researching the spin traveling wave pump, the relationship of the characteristics of magnetic fluid and the press is investigated under the spin magnetic field by the theory method. The relationship of moving, magnetic field and press is investigated by the decoupled computation between the magnetic field and force. The method is scientificity and rationality by the testing. The distributing shape of magnetic fluid in the pump is affected by the adding magnetic field under the spin magnetic field when the magnetic fluid is filled in the pump. At the same time, the adding magnetic field is affected by magnetic particles of magnetic fluid. The magnetic fluid can be moved by the effect of the adding magnetic field in the pump. The flux of magnetic fluid increases with the magnetic field.


论文标题Experimental facility of line magnetic fluid traveling wave pump

作者Zhao Meng, Zou Jibin, Shang Jing, Qi Ming

期刊名称Optics and Precision Engineering

期卷17

简单介绍The magnetic fluid traveling wave pump as the representative application of magnetic fluid produces the phenomenon of flowing. The key techniques of the research on the magnetic fluid traveling wave pump are the production of traveling wave magnetic field, the design of pump structure, and the dynamics characteristics of magnetic fluid, and so on. According to the form of the production of traveling wave magnetic field, the line magnetic fluid traveling wave pump has been designed. Under the effect of traveling wave magnetic field, the magnetic fluid flux has a direct relationship with the magnetic field. The bigger is the magnetic field, the more is the flux. The flux rate of the magnetic fluid will reduce with the increase of the magnetic field because of the increase of the viscosity of the magnetic fluid. The bigger is the saturation magnetization of the magnetic fluid, the more is the flux.


论文标题磁性流体行波泵实验装置

作者赵猛, 邹继斌, 尚静, 齐明.

期刊名称哈尔滨工业大学学报

期卷41(7)

简单介绍行波磁场作用下的磁性流体流量与产生行波磁场的永磁转子的磁极旋转的角度有直接关系，永磁转子磁极旋转过的角度越大，其流量也越多；行波磁场的强弱对磁性流体流量也会产生影响，当永磁转子磁极旋转相同角度时，磁场越强，其流量越大；在永磁转子旋转相同角度时，行波磁场的频率只能影响磁性流体的流速，对流量不直接产生影响。


论文标题异步起动永磁同步电动机起动特性研究

作者赵猛, 邹继斌, 胡建辉, 徐永向.

期刊名称电工技术学报

期卷22

简单介绍异步起动永磁同步电动机既具有较高的功率因数和效率，又具有异步起动的能力。异步起动永磁同步电动机在起动过程中受到诸如异步转矩、发电机制动转矩、磁阻负序转矩等多个转矩的合成作用，使得异步起动永磁同步电动机的起动过程同感应电机相比更为复杂。本文在感应电机的基础上，通过改进其转子设计异步起动永磁同步电动机，并采用有限元法计算和分析其起动过程，并通过实验对感应电机和异步起动永磁同步电动机进行了比较。


论文标题Research on computation method of magnetic fluid in the strong magnetic field

作者Meng Zhao, Cheng-jun Liu, Shang-Lin Jiang, Jian-Hui Hu, Ji-Bin Zou

发表时间，完成时间2014.06

期刊名称Rare Metals

期卷6(33)



论文标题Investigation of spin traveling wave pump on magnetic fluid

作者Meng Zhao, Jibin Zou, Yongxiang Xu, Yong Li

发表时间，完成时间2015.06

期刊名称Materials Research Innovations

期卷19 S5

简单介绍Under the effect of the traveling wave magnetic field, the magnetic fluid flux has a direct relationship with the magnetic flux density of the magnetic field according to theory analysis and experiment. The stronger the magnetic flux density of the magnetic field, the more the flux of magnetic fluid. The velocity of magnetic fluid is proportional to the square root of the magnetic flux density. The radial length of permanent magnet, the diameter of rotor, and the number of permanent magnet and saturation magnetization of magnetic fluid affect distribution of magnetic intensity in the region of magnetic fluid. The larger the velocity of magnetic fluid, the larger the saturation of magnetic intensity of magnetic fluid, radial length of the permanent magnet and the number of permanent magnets. When the saturation magnetization of magnetic fluid and the stator are same, velocity of magnetic fluid and rotor diameter are smaller.


论文标题Loss of Torque on Magnetic Fluid Seals with Rotating-Shafts

作者Hu,Jianhui; Zhao,Meng; Wang, Lu; Zou, Jibin; Li,Yong

发表时间，完成时间2017.01

期刊名称Journal of Magnetics

期卷22(2):286-290

简单介绍 The effects of loss of torque on magnetic fluid seals with rotating-shafts and the general difficulty of studying magnetic fluid seals are the focus of this work. The mechanism underlying loss of torque on such seals is analyzed using theoretical methods that show that loss of torque can be affected by several factors, including the velocity of the rotating-shaft, the structure of the sealing device, the characteristics of the magnetic field, and the characteristics of the magnetic fluid. In this paper, a model of the loss of torque is established, and the results of finite element analysis and testing and simulations are analyzed. It is concluded that (i) the viscosity of the magnetic fluid increased with the intensity of the magnetic field within a certain range; (ii) when the magnetic fluid was saturated, the increase in loss of torque tended to gradually slow down; and (iii) although the axial active length of the magnetic fluid may decrease with increasing speed of the rotating-shaft, the loss of torque increased because of increasing friction.


论文标题Comparative Study of Sator Configurations of a Parmanent Magnet Linear Oscillating Actuator for Orbital Friction Vibration Actuator

作者Hu, Jianhui; Zhao, Meng; Zou, Jibin, Li, Yong

发表时间，完成时间2017.01

期刊名称Applied Sciences-Basel

期卷7(6)

简单介绍 A PM orbital friction vibration actuator (OFVA) which composes four linear oscillating actuators (LOA) is proposed in this paper. This paper presents the design, analysis, and experimental validation of stator configuration of a permanent magnet LOA to improve its thrust force characteristics. First, the magnetized topology and the coil configuration are interpreted. The optimization design goal of the LOA was established and the end effects of the actuator are illustrated. The influences of stator design parameters on the performance of LOA were investigated and the optimal parameters have been identified with reference to the thrust force density and thrust force ripple. Results showed that a quasi-Halbach magnetized E-cored LOA with obtrapezoid teeth has the best electromagnetic performances of all the LOAs examined here. Finally, the predicted thrust force characteristics were validated by measurements on a prototype actuator.


论文期刊

论文标题Dynamic Analysis and Mechanical Structure Improvement of Submersible Rotor

作者Ran, XH; Zhao, M; Shang, J; He, C

发表时间，完成时间2019.05

期刊名称IEEE ACCESS

期卷7

简单介绍 In order to enhance interference immunity and reduce the breakage of rotating shafts (rotors) which happens frequently especially in submersible permanent magnet synchronous motor (PMSM) applications, first a typical rotor structure is established serving as the comparative object, and then two improved schemes with optimal mechanical structure are proposed. Rotor strength, rotor stiffness, and the influence of unilateral magnetic pull on the rotor deflection are calculated analytically. The modal simulation, stress field simulation, and unilateral magnetic pull simulation are analyzed using finite element method (FEM). Position deviation and bending deformation of the rotor caused by the unilateral magnetic pulling force is taken into account to improve the simulation accuracy. The simulation results illustrate that the submersible rotor improved by the proposed schemes presents more excellent stiffness and strength performance compared with the traditional scheme, which indicates that the proposed schemes have important reference values for the structural design of submersible rotor.


论文期刊

论文标题Characteristics of a magnetic fluid under an orthogonal alternating magnetic field

作者Zhao, M ; Hu, JH; Zou, JB; Zhao, B; Li, Y

发表时间，完成时间201606

期刊名称JOURNAL OF MAGNETISM AND MAGNETIC MATERIALS

期卷409

简单介绍 Nonlinearity is a primary characteristic of a magnetic fluid. Under an orthogonal alternating magnetic field, the magnetization characteristics change, which produce a variable magnetic field in the magnetic fluid region. A mathematical model of a magnetic fluid under an orthogonal alternating magnetic field is here proposed. The model is solved by an analytic method, and the validity of the solution is verified using the finite element method in addition to experimental results. It is shown that the frequency of the magnetic field in a magnetic fluid is twice that of the orthogonal alternating magnetic field. (C) 2016 Elsevier B.V. All rights reserved.