[1]柴伟东,赵清森. CPR1000机组蒸汽发生器裕度问题分析[J].热力发电,2019,(预出版):1-7.[doi:10.19666/j.rlfd.201807150]
 CHAI Weidong,ZHAO Qingsen. Research on design margin of steam generator in CPR1000 units[J].Thermal Power Generation,2019,(预出版):1-7.[doi:10.19666/j.rlfd.201807150]
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CPR1000机组蒸汽发生器裕度问题分析

参考文献/References:

 [1] Guangdong Nuclear Power Joint Venture. 55/19 steam generator thermal hydraulic design studies[R]. 1986.

[2] 岭澳核电站二期调试启动试验报告: 蒸汽发生器裕度试验[R]. 深圳: 中广核工程有限公司, 2012.

BU Yubing. Ling’ao II Nuclear Power Plant steam generator margin test report[R]. Shenzhen: CGN Engineering Company, 2012.

[3] 大亚湾核电站蒸汽发生器裕度试验报告[R]. 深圳: 法玛通公司, 1993.

Daya Bay Nuclear Power Plant steam generator margin test report[R]. Shenzhen: Framatome Corporation, 1993.

[4] 丁训慎, 巴长喜. 立式自然循环蒸汽发生器的传热特性及其计算[J]. 核动力工程, 1982(6): 37-46.

DING Xunshen, BA Changxi. Heat transfer characteristics and calculation of vertical natural circulation steam generator[J]. Nuclear Power Engineering, 1982(6): 37-46.

[5] GIBSON M W. Mode 60F steam generator thermal and hydraulic design data report for Qinshan II Nuclear Power Project Units 1 and 2[R]. Qinshan: Westinghouse Electric Company, 1997.

[6] 王巍. AP1000蒸汽发生器换热面积计算探讨[J]. 东方电气评论, 2013, 27(4): 53-55.

WANG Wei. Calculation of heat transfer area for AP1000 steam generator[J]. Dongfang Electric Review, 2013, 27(4): 53-55.

[7] AP1000 steam generator analysis: thermal-hydraulic design data[R]. Madison: Westinghouse Electric Company, 2007.

[8] 丁训慎. 核电站蒸汽发生器的化学清洗与传热性能[J]. 清洗世界, 2007(6): 17-22.

DING Xunshen. Chemical cleaning and heat transfer performance of steam generator in nuclear power station[J]. Cleaning World, 2007(6): 17-22.

[9] 《蒸汽发生器》编写组. 蒸汽发生器[M]. 北京: 原子能出版社, 1982: 26.

“Steam Generator” author group. Steam generator[M]. Beijing: Atomic Energy Press, 1982: 26.

[10] 赵清森. CPR1000机组蒸汽发生器压力降低调研分析报告[R]. 苏州: 苏州热工研究院, 2016.

ZHAO Qingsen. Research and analysis report on pressure decline of steam generators in CPR1000 units[R]. Suzhou: Suzhou Nuclear Power Institute, 2016.

[11] STAEHLE R W, GORMAN J A, MCLLREE A R, et al. Status and future of corrosion in PWR steam generators[C]//Proceedings of the International Sympo-sium Fontevraud 6, Fontevraud Royal Abbey, Chinon, 2006.

[12] KREIDER M A , WHITE G A , VARRIN R D J . A global fouling factor methodology for analyzing steam generator thermal performance degradation[J]. Office of Scientific & Technical Information Technical Reports, 1998.

[13] HU M H. A new perspective of tube fouling and its effect on steam pressure[C]. EPRI sludge management workshop. Myrtle beach, South Carolina, 1996.

[14] HU M H. A strategic thinking to draw benefit from tube scale for boiling enhancement[C]. EPRI 2003 steam generator secondary side management conference. Savanah, Georgia, 2003.

[15] KREIDER M A, MORONEY V D, WHITE G A, et al. Industry SG heat-transfer fouling trends and probabilistic fouling predictions[C]. The 6th CNS international steam generator conference. Toronto, Canada, 2009.

[16] KREIDER M A, WHITE G A, VARRIN R D, et al. Heat transfer characteristics of porous sludge deposits and their impact on the performance of commercial steam generators[R]. Dominion Engineering, 1998.

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备注/Memo

 柴伟东(1967—),男,工学硕士,高级工程师,主要研究方向为核电厂性能试验及热效率分析诊断,chaiweidong@cgnpc.com.cn。

更新日期/Last Update: 2019-01-07