Журнал Российского общества по неразрушающему контролю и технической диагностике
The journal of the Russian society for non-destructive testing and technical diagnostic
 
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10 | 11 | 2024
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2018, 07 июль (July)

DOI: 10.14489/td.2018.07.pp.050-055

Чжун Ян, Чахлов С. В.
СОСТОЯНИЕ И ПЕРСПЕКТИВЫ КИТАЙСКОЙ ВЫСОКОЭНЕРГЕТИЧЕСКОЙ КОМПЬЮТЕРНОЙ ТОМОГРАФИИ
(c. 50-55)

Аннотация. В последние годы в Китае быстро развиваются производства высокоскоростных железных дорог, автомобилей, самолетов, ракет-носителей и т.д. В соответствии с высокими требованиями к ответственным высокотехнологичным изделиям необходимо контролировать их качество до использования. Высокоэнергетическая компьютерная томография (ВКТ) характеризуется большой проникающей способностью, высокой чувствительностью обнаружения дефектов и позволяет качественно измерять и визуализировать сложные внутренние структуры при контроле толстостенных ответственных изделий. Представлен обзор развития и применения ВКТ в Китае. Рассмотрены области применения ВКТ и приведены конкретные примеры.

Ключевые слова:  неразрушающий контроль, высокоэнергетическая компьютерная томография, ответственные изделия, дефекты, области применения.

 

Zhong Yang, Chakhlov S. V.
THE STATE AND PROSPECTS OF CHINESE HIGH-ENERGY COMPUTED TOMOGRAPHY
(pp. 50-55)

Abstract. Computed tomography (CT) is an advanced method of non-destructive testing (NDT) not only to detect inhomogeneities, inclusions and defects of products, but also to obtain accurate information about the materials and structure of the test object. Currently, CT is widely used in almost all areas of industrial production and has become a necessary technical guarantee for quality control, technical research, innovation in processes, etc. As is well known, the production of high-speed railways, cars, aircraft, carrier rockets, etc. has been rapidly developing in China in recent years. According to the high requirements for responsible high-tech products, it is necessary to monitor their quality before using them. High-energy computed tomography (HECT) has a large penetrating ability, high sensitivity of defects and allows qualitatively measuring and visualizing complex internal structures when controlling responsible products with large thickness. This paper is an overview of the development and application of HECT in China. The fields of HECT application are considered and specific examples are given.

Keywords: non-destructive testing, high-energy computed tomography, responsible products, defects, fields of application.

Рус

Чжун Ян, С. В. Чахлов (Российско-китайская научная лаборатория радиационного контроля и досмотра, Национальный исследовательский Томский политехнический университет, Томск, Россия) E-mail: Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра. , Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.  

Eng

Zhong Yang, S. V. Chakhlov (Russian-Chinese Laboratory of Radiation Control and Inspection, National Research Tomsk Polytechnic University, Tomsk, Russia) E-mail: Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра. , Данный адрес e-mail защищен от спам-ботов, Вам необходимо включить Javascript для его просмотра.  

Рус

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Eng

1. 李炬, 线阵高能工业CT研制进展//中国工程物理研究院科技年报 (2009), pp. 71-73.
2. Chen Zhiqiang, Li Liang, Feng Jianchuan. (2005). New development of high energy industrial computed tomography (ICT). CT Theory and Applications, 14(4), pp. 1-4.
3. IPT Series of Industrial CT NDT System. Available at: http://www.granpect.com.cn/english/products/p1/27.html (2018).
4. Zhang Ping, Xu Wenzhi. (2000). Data collect system design and realize for CD-300BG type industry computerized tomography. CT Theory and Applications, 9(1), pp. 17-21.
5. Xia Yuzheng, Chen Guangjie, Wang Lan. (1997). The key technique for high x-ray ICT. CT Theory and Applications, 6(1), pp. 37-39.
6. Tang C. (2010). Present status of the accelerator industry in Asia. Proceedings of IPAC’10, (pp. 2447-51). Kyoto, Japan, May, 2010.
7. Tang C. (2004). The development of accelerator applications in China. Proceedings of APAC 2004, (pp. 528-532). Gyeongju, Korea.
8. Tang C., Chen H. B., Liu Y. H. (2009). Electron Linacs for cargo inspection and other industrial applications. Proceedings of International Topical Meeting on Nuclear Research Applications and Utilization of Accelerators, (pp.1-8). Vienna, 4 – 8 May 2009. Vienna.
9. Xiao Yongshun, Chen Zhiqiang, Li Yantao, Ye Liang. (2016). Development and applications of high energy industrial computed tomography in China. 19th World Conference on Non-Destructive Testing, (pp.1-8). Munich, 13 – 17 June 2016.
10. Wang Yuan, Xu Zhou, Chen Hao et al. (2006). Data acquiring system for high energy industrial CT based on flatpanel detector. CT Theory and Applications, 15(3), pp. 53-56.
11. Xiao Yongshun, Hu Haifeng, Chen Zhiqiang et al. (2009). Application of large industrial computed tomography in nondestructive testing of key components of railway vehicles. CT Theory and Applications, 18(3), pp. 72-78.
12. Jiang Baoyu, Tang Jian, Li Puming et al. (2013). High energy x-ray industrial CT technology and its application in automotive industry. Proceeding of the 10th Annual Meeting of Chinese Society for Non-destructive Testing, (pp. 913-917). Nanchang, China, Sep. 2013. Nanchang.
13. Xiao Yongshun, Li Yantao, Ye Qing. (2013). The application of high energy industrial CT system in large casting NDT. Proceeding of the 10th Annual Meeting of Chinese Society for Non-destructive Testing, (pp. 840-847). Nanchang, China, Sep. 2013.
14. Ding Guofu. (2005). Application of high energy industrial computed tomography in testing solid rocket engine. CT Theory and Applications, 14(3), pp. 35-39.
15. Xiao Yong shun, Chen Zhiqiang, Yu Daiweiand et al. (2016). The applications of industrial CT NDT technology in geological research. 19th World Conference on Non-Destructive Testing, (pp.1-7), Munich, 13 – 17 June 2016.
16. Salamon M., Boehnel M., Reims N. et al. (2013). Applications and methods with high energy CT systems. 5th International Symposium on NDT in Aerospace, (pp. 1-8). Singapore, 13-15 Nov. 2013.
17. Salamon M., Errmann G., Reims N., Uhlmann N. (2012). High energy x-ray imaging for application in aerospace industry. 4th International Symposium on NDT in Aerospace, (pp. 1-8). Augsburg, 13 – 15, Nov. 2012.
18. Uhlmann N., Voland V., Salamonand M. et al. (2014). Metrology, applications and methods with high energy CT systems, (pp. 1-8). January 2014. doi: 10.1063/1.4865039.
19. Stock S. R. (Ed.), Reims N., Schoen T., Boehneland M. et al. (2014). Strategies for efficient scanning and reconstruction methods on very large objects with high energy x-ray computed tomography. Developments in X-Ray Tomography IX Proc. of SPIE, 9212, 921209, pp. 1-9. doi: 10.1117/12.2062002.
20. Lechuga L., Weidlich G. A. (2016). Cone beam CT vs. fan beam CT: a comparison of image quality and dose delivered between two differing CT imaging modalities. Cureus, 9(8): e778, doi: 10.7759/cureus.778.
21. Kastner J., Plank B., Heinzl C. (2015). Advanced X-ray computed tomography methods: High resolution CT, quantitative CT, 4DCT and phase contrast CT. Digital Industrial Radiology and Computed Tomography (DIR 2015), (pp. 1-13), 22 – 25 June 2015.
22. Kastner J. (2016). Case studies in nondestructive testing and evaluation. Special Issue 6th conference on industrial CT 2016 (iCT2016), V. 6/B. (pp. 1-131). Wels, Austria, 2016. Wels, 2016.
23. Kastner J., Heinzl C., Plank B. et at. (2017). New X-ray computed tomography methods for research and industry. 7th Conference on Industrial Computed Tomography. (pp. 1-10). Leuven, Belgium (ICT 2017).
24. Wenjing Wu, Haitao Zhu, Ming Jin et at. (2013). Partial CT and structural analysis with 950 KeV/3.95 MeV X-Band Linac X-Ray sources. E-Journal of Advanced Maintenance, 5(2), pp. 121-127.
25. Bonse U. (Ed.), Kang Kejun, Zhao Ziran, Chen Zhiqiang, Zhang Li. (2004). Eliminating beam-hardening artifacts in high-energy industrial computed tomography(ICT). Developments in X-Ray Tomography IV. Proc. of SPIE. 2004. V. 5535 (SPIE, Bellingham, WA, 2004). 0277-786X/04/$15, doi: 10.1117/12.559289.
26. High energy industrial CT. (2018). Available at: http://www.scjjrd.com/products_list/pmcId=30.html
27. High energy CT. (2018). Available at: http://www. meansee.com/index.php?m=product&a=index&cid=11
28. Wang Jue. (2013). The latest development of high energy industrial CT/DR technology and its application in China. Proceeding of the 10th Annual Meeting of Chinese Society for Non-destructive Testing, (pp. 7-8). Sep., 2013. Nanchang, China.

Рус

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