正电子发射成像回旋加速器磁铁设计与测试

魏涛; 杨国君; 何小中; 庞健; 赵良超; 张开志

doi:doi:10.3788/hplpb20122409.2193

强激光与粒子束, 2012, 24 (9): 2193, 网络出版: 2012-09-12

正电子发射成像回旋加速器磁铁设计与测试

Magnet design and test of positron emission tomography cyclotron

论文大纲

魏涛 ^*杨国君何小中庞健赵良超张开志

作者单位

中国工程物理研究院流体物理研究所，四川绵阳 621900

磁铁磁场等时性聚焦一次谐波 magnet magnetic field isochronism focus first harmonic

摘要

中国工程物理研究院流体物理研究所目前正在建造一台医用11 MeV回旋加速器，该加速器磁铁采用小气隙、深谷结构以提供更高的平均磁场和更强的聚焦能力。为实现5×10-4的测量精度，自行研发了一套磁场点测装置，该装置可实现二维极坐标下的精确测量。经过多次磁场垫补，束流的相位偏移控制在±9°，一次谐波幅值控制在0.001 T以内，满足了磁铁的设计需求。在束流调试过程中，成功实现了质子束的引出，表明回旋加速器磁铁建造成功。此外，还对磁铁研制过程中出现的磁场缺陷及磁测误差进行了讨论。

Abstract

An 11 MeV H－ compact cyclotron used for medical radioactive isotope production is under construction in Institute of Fluid Physics, CAEP. The cyclotron magnet adopts the design of small valley gaps and coulee structure which can provide high average magnetic field and strong focus ability. To achieve 5×10-4 measuring accuracy, a magnetic field mapping system has been developed. After iterative correction using field measurement data, the total phase excursion of the cyclotron is within ±9° and the first harmonic is less than 10-3 T, which are all acceptable. Furthermore, the beam testing declares the successful construction of the cyclotron magnet. Besides, some magnetic field influence factors were discussed, including the magnetic field distortion and measurement error.

参考文献

[1] Ollinger J M, Fessler J A. Positron emission tomography［J］. IEEE Signal Processing Magazine, 1997, 14(1):43-55.

[2] Thomas L H. The paths of ions in the cyclotron［J］. Phys Rev, 1938, 54(8):588-598.

[3] Park K H, Yoon Y D, Jung Y G, et al. Field mapping system for the KIRAMS-30 cyclotron magnet［J］. Journal of the Korean Physical Society, 2009, 54(4):1475-1480.

[4] Mandrillon P, Ostojic R. Mapping, magnetic field trimming and parameter optimization of the medicyc cyclotron［J］. Nucl Instrum Meth A, 1986, 243(2):237-243.

[5] 张天爵, 李振国, 储诚节,等. 强流回旋加速器综合试验装置的研制［J］. 科学通报, 2010, 55(35):3351-3357.(Zhang Tianjue, Li Zhenguo, Chu Chengjie, et al. Comprehensive test stand for high-intensity cyclotron development. Chinese Sci Bull, 2010, 55(35):3351-3357)

[6] 李振国, 吴隆成，葛涛,等. 10 MeV强流回旋加速器的束流调试［J］. 原子能科学技术, 2011, 45(5): 588-594.(Li Zhenguo, Wu Longcheng, Ge Tao, et al. Beam test of 10 MeV high intensity cyclotron. Atomic Energy Science and Technology, 2011, 45(5):588-594)

[7] Qin Bin, Yang Jun, Liu Kaifeng, et al. Main magnet and central region design for a 10 MeV PET cyclotron CYCHU-10［C］//Proceedings of the International Particle Accelerator Conference. 2009:184-186.

[8] Qin Bin, Liu Kaifeng, Feng Yizhang, et al. Central region design for a 10 MeV internal ion source cyclotron［J］. Chinese Physics C, 2009, 33(8):682-686.

[9] Fan Mingwu, Zhang Xingzhi, Zhang Tianjue, et al. Measurement and adjustment of CIAE medical cyclotron magnet［C］//15th IEEE Particle Accelerator Conference. 1993:2841-2843.

[10] Kramer P, Hagedoorn H L, Verster N F. The central region of the Philips AVF cyclotron［C］//Proceedings of the International Conference on Sector-Focused Cyclotrons and Meson Factories. 1963:214-221.

[11] Vector Fields Ltd. Opera-3D user guide［M］. England: Vector Fields Limited Press, 2008.

[12] Gulbekian G G, Ivanenko I A, Filatov O G, et al. A method of the magnetic field formation in cyclotron DC-72［J］. Nukleonika, 2003, 48(4):207-210.

[13] Group3 Technology Ltd. DTM-151 digital Teslameter with serial communications user’s manual［K］. 2007.

[14] 唐靖宇, 魏宝文. 回旋加速器理论与设计［M］.合肥: 中国科学技术大学出版社, 2008.(Tang Jingyu, Wei Baowen. Theory and design of cyclotron accelerator. Heifei: China Science and Technology University Press，2008)

魏涛, 杨国君, 何小中, 庞健, 赵良超, 张开志. 正电子发射成像回旋加速器磁铁设计与测试[J]. 强激光与粒子束, 2012, 24(9): 2193. Wei Tao, Yang Guojun, He Xiaozhong, Pang Jian, Zhao Liangchao, Zhang Kaizhi. Magnet design and test of positron emission tomography cyclotron[J]. High Power Laser and Particle Beams, 2012, 24(9): 2193.

正电子发射成像回旋加速器磁铁设计与测试

关于本站 Cookie 的使用提示

全站搜索

正电子发射成像回旋加速器磁铁设计与测试

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索