高温超导磁体在持续电流模式下工作时，由于磁通蠕动效应和接头电阻的存在，使得闭合超导回路中的电流产生衰减。应用传统外部电源为超导磁体充磁需要采用大电流供电设备，能量损耗大。本项目致力于研究一种新型无接触式充磁技术——基于行波磁场的高温超导磁通泵，它可以在没有电接触的情况下将直流电流注入超导闭环系统，以补偿电流衰减，避免传统电源电流引线造成的热损耗。利用这种技术可以制造具有高稳定性磁场的超导新能源器件，这将对公共交通、医疗设备及高能物理等工程应用领域的技术革新做出贡献。本项目基于第二代高温超导涂层导体线圈，利用直流驱动源产生行波磁场对超导线圈进行充磁，定量研究行波磁场特征参数与超导材料特征物理量之间的关系，利用有限元法对高温超导带材的磁化及交流损耗进行数值分析，并将磁通动力学方法引入涡旋簇运动的建模中，探索高温超导磁通泵效应与宏观磁通量子耦合效应的微观机制，从而为实现稳态强磁场提供理论支持。

High temperature superconducting magnets often operate in the persistent current mode, however, the current in the closed superconducting loop decays due to the magnetic flux creep effect and the presence of the joint resistance. Using conventional external power source to magnetize a superconducting magnet requires the use of a large current power supply device and leads to a huge associated heat losses. This research focus on the study of a novel contactless magnetization technology——a high temperature superconducting flux pumping technology based on traveling magnetic waves, which can inject DC current into the closed HTS system to compensate for the current decay without any electrical contact, and heat losses caused by traditional external power supply current leads can be avoided. Finally，with this technology, we can make superconducting power devices with high-stability magnetic fields , which will make a big contribution to the technical innovation of a variety of engineering applications, ranging from public transportation, through medical equipment, to high energy physics. Based on the second-generation high temperature superconducting Coated Conductor(CC) coils，this research utilize traveling magnetic fields generated by DC drive source to magnetize the superconducting coil. The relationship between the magnetizing efficiency and the frequency, wavelength, amplitude and direction of traveling magnetic field are investigated by systematically measuring and analyzing of the electromagnetic characteristics of the HTS CC coils. The finite element method(FEM) is used to numerically study the magnetization and AC loss of high temperature superconducting tape. The vortex dynamics method is also introduced into the modeling of vortex cluster motion. Upon comprehensively studying the experimental data and numerical simulations, this research also explores the physical mechanism of HTS flux pumping effect and the microscopic mechanism of macroscopic magnetic coupling phenomenon, revealing the physics underlying the flux pumping effect based on the traveling magnetic waves, finally providing the theoretical support and technical assurance to realize the steady-state strong magnetic fields for high temperature superconductors.