Development of 200 kV multi-function pulsed radiation system

Lü Ze-Qi; Xie Yan-Zhao; Gou Ming-Yue; Chen Xiao-Yu; Zhou Jin-Shan; Li Mei; Zhou Yi

doi:10.7498/aps.70.20210583

Abstract

A multi-functional pulsed radiation system with a peak voltage of 200 kV, an impedance of 2 Ω, and a full width at half maximum (FWHM) of 30 ns is developed. The system can be switched flexibly in two states of generating pulsed electron beam and pulsed X-ray by changing the cathode and anode. It consists of a pulse power driving source, a vacuum diode, and an experimental cavity. A Marx generator, a high energy storage water transmission line, and two pulse compression switches are utilized to generate a high voltage on diode. An effector can be placed in the experimental cavity which has the same vacuum as diode. An insulation structure of transmission line and a diode are optimized to guide in system design. The system can provide a multi-functional experimental platform for investigating pulse power technology, system-generated electromagnetic pulse, biological radiation effect, etc. The Marx generator generates a high-voltage pulse with hundreds of nanoseconds in FWHM and hundreds of kilovolts in peak value. The pulse is compressed by the main switch and pulse forming switch and then loaded to the diode. Electrons are emitted from diode cathode under the high-voltage pulse and accelerated in the gap. The electrons are extracted directly or converted into X-ray through the anode. Aluminized polyethylene is used as an anode when pulsed electron beam is generated, and tantalum film is used when pulsed X-ray is generated. Working state can be switched by changing the cathode and anode of diode. The result shows that a current of 83 kA pulsed electron beam and an average energy of 67 keV X-ray are generated. Pulsed X-ray has good uniformity and low electron proportion (0.02%). In order to monitor the operation state and output parameter of the system comprehensively, a complete measurement system is established. Three capacitive voltage dividers are set at the beginning of transmission line, the end of pulse forming line, and the end of output line, while a B - dot current monitor is set at the diode. A Faraday cup is developed to measure the current intensity and the total energy of pulsed electron beam. For energy spectrum, dose and electron proportion, the measurement system composed of pulsed X-ray including spectrometric system, dose system and Rogowski Coil is build.

Keywords:

Authors and contacts

State Key Laboratory of Electrical Insulation and Power Equipment, School of Electrical Engineering, Xi’an Jiaotong University, Xi’an 710049, China

Corresponding author: Xie Yan-Zhao, yzxie@xjtu.edu.cn

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References

[1]	王晶晶 2016 硕士学位论文 (杭州: 浙江大学) Wang J J 2016 M. S. Thesis (Hangzhou: Zhejiang University) (in Chinese)
[2]	王波, 刘海浪, 祁正伟, 张国培, 王小宇 2018 热加工工艺 47 19 Google Scholar Wang B, Liu H L, Qi Z W, Zhang G P, Wang X Y 2018 Hot Working Technology 47 19 Google Scholar
[3]	Ribiere M, Dortan F D G D, Delaunay R, Aubert D, Dalmeida T 2020 IEEE Trans. Nucl. Sci. 67 1722 Google Scholar
[4]	Higgins D F, Lee K S H, Marin L 1978 IEEE Trans. Antennas Propag. 26 14 Google Scholar
[5]	Chen J, Wang J, Tao Y, Chen Z, Wang Y, Niu S 2019 IEEE Trans. Nucl. Sci. 66 820 Google Scholar
[6]	刘锡三 2007 高功率脉冲技术(北京: 国防工业出版社) 第178−183页 Liu X S 2007 High Pulsed Power Technology (Beijing: National Defense Industry Press) pp178−183 (in Chinese)
[7]	邱爱慈 2016 脉冲功率技术应用 (西安: 陕西科学出版社) 第39页 Qiu A C 2016 Pulsed Power Technology Application (Xi’an: Shaanxi Science and Technology Press) p39 (in Chinese)
[8]	吴治华 1997 原子核物理实验方法 (北京: 原子能出版社) 第49页 Wu Z H 1997 Experimental methods of nuclear physics (Beijing: Atomic Energy Press) p49 (in Chinese)
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[13]	苏兆锋, 杨海亮, 邱爱慈, 孙剑锋, 丛培天, 王亮平, 雷天时, 韩娟娟 2010 物理学报 59 7729 Google Scholar Su Z F, Yang H L, Qiu A C, Sun J F, Cong P T, Wang L P, Lei T S, Han J J 2010 Acta Phys. Sin. 59 7729 Google Scholar
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[17]	Meng C, Xu Z, Jiang Y, Zheng W, Dang Z 2017 IEEE Trans. Nucl. Sci. 10 2618 Google Scholar
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[19]	周开明, 王艳, 邓建红 2014 强激光与粒子束 26 073207 Google Scholar Zhou K M, Wang Y, Deng J H 2014 High Pow. Las. Part. Beam. 26 073207 Google Scholar
[20]	马良, 程引会, 吴伟, 李进玺, 朱梦, 李宝忠, 赵墨, 郭景海 2012 强激光与粒子束 24 2915 Google Scholar Ma L, Cheng Y H, Wu W, Li J X, Zhu M, Li B Z, Zhao M, Guo J H 2012 High Pow. Las. Part. Beam. 24 2915 Google Scholar
[21]	Summa W J, Gullickson R L, Hebert M P, Rowley J E, Leon J F, Vitkovitsky I 1995 Pulsed Power Conference (New Mexico: Albuquerque)
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Cited By

图 1 多功能脉冲辐射系统结构示意图

Figure 1. Schematic diagram of multi-function pulsed radiation system.

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图 2 传输线结构及电场分布　(a) 传输线结构图; (b) 电场分布

Figure 2. Structure and electric field distribution of transmission line: (a) Structure of transmission line; (b) distribution of the electric field.

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图 3 脉冲功率驱动源和二极管的等效电路

Figure 3. Equivalent circuit of pulse power source and diode.

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图 4 电路模拟结果

Figure 4. Circuit simulation results.

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图 5 二极管结构及电场　(a)二极管结构; (b)二极管间隙电场

Figure 5. Structure and electric field distribution of diode: (a) Structure of diode; (b) distribution of the electric field.

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图 6 二极管间隙电子图像　(a)电子初始发射; (b)电子大面积均匀发射

Figure 6. Electron image of diode gap: (a) Initial emission; (b) large-area uniform emission.

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图 7 两种阴极结构及两种结构产生X射线的均匀性　(a)用于产生电子束的圆盘阴极; (b)用于产生X射线的双环阴极; (c)阳极靶后10 cm处由圆盘和圆环阴极产生X射线的均匀性

Figure 7. Two kinds of cathode structure and the uniformity of X-ray: (a) Disk cathode for electron beam; (b) double-ring cathode for X-ray; (c) uniformity of X-ray generated by disk and ring cathode at 10 cm behind the anode.

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图 8 轫致辐射产生的光子总能量随钽靶厚度的变化

Figure 8. Curve of photon energy by bremsstrahlung with tantalum target thickness.

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图 9 电子束流和总能量测量原理示意图

Figure 9. Schematic diagram of electron beam current and total energy measurement.

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图 10 基于PIN的能谱测量系统

Figure 10. Spectrometric system based on PIN.

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图 11 系统总体结构和测量探头布局

Figure 11. Structure and probe layout of the system.

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图 12 脉冲电子束状态的电压、电流、束流波形

Figure 12. Voltage, current and beam of pulsed electron beam.

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图 13 吸收体温度变化

Figure 13. Absorber temperature.

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图 14 能谱仪测得波形

Figure 14. Waveform measured by spectrometric system.

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图 15 计算得到PIN探测器中平均能量沉积

Figure 15. Energy deposition averaged over PIN detector by calculated.

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图 16 解谱得到的X射线能谱

Figure 16. X-ray spectrum by spectrum unfolding.

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图 17 剂量随半径分布

Figure 17. Distribution of dose with radius.

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图 18 辐射场内电子电流波形

Figure 18. Current in radiation field.

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[1]	王晶晶 2016 硕士学位论文 (杭州: 浙江大学) Wang J J 2016 M. S. Thesis (Hangzhou: Zhejiang University) (in Chinese)
[2]	王波, 刘海浪, 祁正伟, 张国培, 王小宇 2018 热加工工艺 47 19 Google Scholar Wang B, Liu H L, Qi Z W, Zhang G P, Wang X Y 2018 Hot Working Technology 47 19 Google Scholar
[3]	Ribiere M, Dortan F D G D, Delaunay R, Aubert D, Dalmeida T 2020 IEEE Trans. Nucl. Sci. 67 1722 Google Scholar
[4]	Higgins D F, Lee K S H, Marin L 1978 IEEE Trans. Antennas Propag. 26 14 Google Scholar
[5]	Chen J, Wang J, Tao Y, Chen Z, Wang Y, Niu S 2019 IEEE Trans. Nucl. Sci. 66 820 Google Scholar
[6]	刘锡三 2007 高功率脉冲技术(北京: 国防工业出版社) 第178−183页 Liu X S 2007 High Pulsed Power Technology (Beijing: National Defense Industry Press) pp178−183 (in Chinese)
[7]	邱爱慈 2016 脉冲功率技术应用 (西安: 陕西科学出版社) 第39页 Qiu A C 2016 Pulsed Power Technology Application (Xi’an: Shaanxi Science and Technology Press) p39 (in Chinese)
[8]	吴治华 1997 原子核物理实验方法 (北京: 原子能出版社) 第49页 Wu Z H 1997 Experimental methods of nuclear physics (Beijing: Atomic Energy Press) p49 (in Chinese)
[9]	何辉, 禹海军, 王毅, 戴文华 2019 强激光与粒子束 31 125102 Google Scholar He H, Yu H J, Wang Y, Dai W H 2019 High Pow. Las. Part. Beam. 31 125102 Google Scholar
[10]	Manciu M, Manciu F S, Teodor V, Nes E, Waggener R G 2009 J. X-Ray Sci. Technol. 17 85 Google Scholar
[11]	欧阳晓平, 李真富, 张国光, 霍裕昆, 张前美, 张显鹏, 宋献才, 贾焕义, 雷建华, 孙远程 2002 物理学报 51 1502 Google Scholar Ouyang X P, Li Z F, Zhang G G, Huo Y K, Zhang Q M, Zhang X P, Song X C, Jia H Y, Lei J H, Sun Y C 2002 Acta Phys. Sin. 51 1502 Google Scholar
[12]	苏兆锋, 来定国, 邱孟通, 任书庆, 徐启福, 杨实 2020 强激光与粒子束 32 035005 Google Scholar Su Z F, Lai D G, Qiu M T, Ren S Q, Xu Q F, Yang S 2020 High Pow. Las. Part. Beam. 32 035005 Google Scholar
[13]	苏兆锋, 杨海亮, 邱爱慈, 孙剑锋, 丛培天, 王亮平, 雷天时, 韩娟娟 2010 物理学报 59 7729 Google Scholar Su Z F, Yang H L, Qiu A C, Sun J F, Cong P T, Wang L P, Lei T S, Han J J 2010 Acta Phys. Sin. 59 7729 Google Scholar
[14]	Baird L C 1981 Med. Phys. 8 319 Google Scholar
[15]	Waggener R G, Blough M M, Terry J A, Chen D, Lee N E, Zhang S, McDavid W D 1999 Med. Phys. (Lancaster) 26 1269 Google Scholar
[16]	来定国, 张永民, 李进玺, 苏兆峰, 张玉英, 任书庆, 杨莉, 杨实 2013 强激光与粒子束 25 1396 Google Scholar Lai D G, Zhang Y M, Li J X, Su Z F, Zhang Y Y, Ren S Q, Yang L, Yang S 2013 High Pow. Las. Part. Beam. 25 1396 Google Scholar
[17]	Meng C, Xu Z, Jiang Y, Zheng W, Dang Z 2017 IEEE Trans. Nucl. Sci. 10 2618 Google Scholar
[18]	Xu Z, Meng C, Jiang Y, Wu P 2020 IEEE Trans. Nucl. Sci. 67 425 Google Scholar
[19]	周开明, 王艳, 邓建红 2014 强激光与粒子束 26 073207 Google Scholar Zhou K M, Wang Y, Deng J H 2014 High Pow. Las. Part. Beam. 26 073207 Google Scholar
[20]	马良, 程引会, 吴伟, 李进玺, 朱梦, 李宝忠, 赵墨, 郭景海 2012 强激光与粒子束 24 2915 Google Scholar Ma L, Cheng Y H, Wu W, Li J X, Zhu M, Li B Z, Zhao M, Guo J H 2012 High Pow. Las. Part. Beam. 24 2915 Google Scholar
[21]	Summa W J, Gullickson R L, Hebert M P, Rowley J E, Leon J F, Vitkovitsky I 1995 Pulsed Power Conference (New Mexico: Albuquerque)
[22]	Ware K D, Bell D E, Gullickson R L, Vitkovitsky I 2002 IEEE Trans. Plasma Sci. 30 1733 Google Scholar

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