Author: Fan, M.
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WEPSB043
Status of a THz source based on a FEL  
 
  • Y.J. Pei, G. Feng, X.Y. He, Y. Hong, G. Huang, D. Jia, K. Jin, P. Lu, L. Shang, B.G. Sun, Zh. X. Tang, W. Wei, K. Xuan, Z. Zhao
    USTC/NSRL, Hefei, Anhui, People's Republic of China
  • Q.S. Chen, M. Fan, T. Hu, B. Qin, P. Tan, Y.Q. Xiong
    HUST, Wuhan, People's Republic of China
  • G. Feng
    DESY, Hamburg, Germany
  • L.G. Shen
    USTC/PMPI, Hefei, Anhui, People's Republic of China
  • Zh. X. Tang
    DICP, Dalian, People's Republic of China
 
  Abstract THz wave have many special performances so that it will be applied in many field. So far there were many kind of THz Source, one of them is based on a FEL that can produce high power (~kW). This paper will describe the design of a THz source based on a FEL which is consists of a LINAC of 14MeV, undulator and a optical resonance cavities. The LINAC was composed of a novel EC-ITC-RF gun, constant gradient travelling wave accelerator with a collinear absorbing load, focusing system, RF power system, beam diagnostic system, vacuum system, control system and so on. The LINAC was installed on November of 2014. Last year, we finished the install of the undulator and the optical resonance cavities. Now the LINAC has been testing and commissioning for THz radiation test. So far, the beam parameters tested of the LINAC are as the following: beam Energy is of 13.58MeV, macro pulse current is of 655mA,μpulse beam current is of 30A, beam macro pulse length is of 1-2's, beam bunch length(μpulse) is of 8ps, energy spread of 0.33% , normal beam emmitance is of 24.1mm.mrad.  
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THPSC003 The Design of Permenant Magnet Spread System for 0.5 MeV Irradiation Accelerator 541
 
  • J. Huang, Q.S. Chen, K. Fan, M. Fan, W. Qi, Y.Q. Xiong, J. Yang, L.G. Zhang
    HUST, Wuhan, People's Republic of China
  • T. Yu, C. Zuo
    Huazhong University of Science and Technology, State Key Laboratory of Advanced Electromagnetic Engineering and Technology,, Hubei, People's Republic of China
 
  Funding: Supported by Natural Science Foundation (11505068)
The traditional electron beam scanning magnet has many disadvantages, for example, the regulatory of excitation current is very complex and the irradiation uniformity as well as the irradiation area is very difficult to improve and expand. Thus the author of the paper proposes an innovative technology of a permanent magnet spread system for 10 MeV irradiation accelerator which uses a special configuration of the magnetic field to spread electron beam bunch directly and would remarkably improve the spread uniformity, simplify the accelerator and would be helpful to protect the titanium window and expand the irradiation area. Also, the technology could as well be used on the electron beam irradiation of those irregular structured objects of large size.
 
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THPSC038 A Novel Design of Insulated Core Transformer High Voltage Power Supply 623
 
  • M.K. Li, K. Fan, M. Fan, J. Huang, H. Liang, W. Qi, Y.Q. Xiong, J. Yang, L. Yang, L.G. Zhang, Y.F. Zhang, C. Zuo
    HUST, Wuhan, People's Republic of China
  • T. Yu
    Huazhong University of Science and Technology, State Key Laboratory of Advanced Electromagnetic Engineering and Technology,, Hubei, People's Republic of China
 
  Insulated core transformer (ICT) high voltage power supply is an ideal model for industrial radiation accelerator at energy below 1MeV. Compared to the traditional scheme, a novel ICT high voltage power supply was put forward. Conventional silicon steel sheets were replaced with manganese zinc ferrites, raising working frequency from 50Hz to thousand hertz. Magnetic structure was changed from three-phase structure to four-phase structure. Accordingly, excitation voltage was changed from three-phase sinusoidal wave to square wave. Polyimide was chosen as insulation material instead of teflon or mica. A prototype of 400kV/50mA was designed, simulated and verified with the aid of finite element analysis software. To optimize the voltage distribution, corresponding flux compensation methods were raised to solve the problem of flux leakages.  
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THPSC045
Localisation of RF Breakdown Point in a Coaxial Load Linac Structure  
 
  • Q.S. Chen, M. Fan, T. Hu, J. Huang, B. Qin, P. Tan, Y.Q. Xiong, J. Yang
    HUST, Wuhan, People's Republic of China
  • Y.J. Pei
    USTC/NSRL, Hefei, Anhui, People's Republic of China
  • T. Yu
    Huazhong University of Science and Technology, State Key Laboratory of Advanced Electromagnetic Engineering and Technology,, Hubei, People's Republic of China
 
  A compact terahertz free electron laser (THz-FEL) prototype has been built up in Huazhong University of Science and Technology (HUST). In the prototype, a 0.85m long linac was designed to deliver electron beams with maximum energy of 14MeV and coaxial absorbing load instead of output coupler was selected to achieve a compact structure. In this case, no transmitted power signal could be used to determine the RF breakdown point (RFBP) in the linac cavity. Here we reported how the RFBP can be localized with just the input and reflected power signals through two methods. One refers to the analysis of time delay of the two signals and the other refers to the calculation of amplitude of the two signals. Quantitative analysis showed the two methods were well consistent with each other and indicated the RFBP located at the end of the linac cavity.  
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