<trans-title>Review on Design of Solenoid Pressurizer Spray Valve for Nuclear Power Plants

Yueqiu CAO; Xiaoning CAO; Xiaohong JIANG; Song WU

doi:10.16516/j.gedi.issn2095-8676.2022.01.011

Volume 9 Issue 1

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CAO Yueqiu,CAO Xiaoning,JIANG Xiaohong,et al.Review on Design of Solenoid Pressurizer Spray Valve for Nuclear Power Plants[J].Southern Energy Construction,2022,09(01):71-75. doi: 10.16516/j.gedi.issn2095-8676.2022.01.011

Citation:

Review on Design of Solenoid Pressurizer Spray Valve for Nuclear Power Plants

doi: 10.16516/j.gedi.issn2095-8676.2022.01.011

1.
Anshan Solenoid Valve Co., Ltd., Anshan 114300, Liaoning, China
2.
China Nuclear Power Engineering Co., Ltd., Shenzhen 518124, Guangdong, China

Received Date: 2021-11-08
Rev Recd Date: 2021-12-08
Publish Date: 2022-03-25

Abstract

Introduction The solenoid pressurizer spray valve is one of the key valves for PWR nuclear power plant, and it is of great significance for nuclear power construction to realize the independent research and development of the valve. Method In this paper, Starting from the system functional requirements and technical parameter requirements of the solenoid pressurizer spray valve, the overall structure, proportional solenoid, middle thermal protection device, valve position detect and output device, control system with pilot disc of the independently-developed solenoid pressurizer spray valve were briefly introduced in this paper. Result Through this independent research and development, the design technology of the solenoid pressurizer spray valve is mastered, the technical difficulties of the electromagnetic drive structure and the adaptability of the valve working under high temperature and high pressure medium conditions are solved, the system functional requirement for pressurizer spray valve is realized. Conclusion The independently-developed solenoid pressurizer spray valve meets the development needs for third generation nuclear power plant, and can be popularized and applied.

References

[1]	广东核电培训中心. 900 MW压水堆核电站系统与设备(上、下册) [M]. 北京: 原子能出版社, 2005. Guangdong Nuclear Power Training Center. 900 MW PWR nuclear power plant system and equipment (part I and part II) [M]. Beijing: Atomic Energy Press, 2005.
[2]	法国核岛设备设计、建造及在役检查规则协会. 压水堆核岛机械设备设计和建造规则: RCC-M-2007 [M]. 北京: 中国核电工程有限公司, 2007. AFCEN. Design and conception rules for mechanical components of PWR nuclear islands: RCC-M-2007 [M]. Beijing: China Nuclear Power Engineering Co., Ltd., 2007.
[3]	法国核岛设备设计、建造及在役检查规则协会.压水堆核电站核岛电气设备设计和建造规则: RCC-E-2005 [M]. 深圳: 深圳中广核工程设计有限公司, 2005. AFCEN. Rules for design and construction of electrical equipment for PWR nuclear island: RCC-E-2005[M]. Shenzhen: China Nuclear Power Design Co., Ltd., 2005.
[4]	Fluid Controls Institute, Inc. Control valve seat leakage: ANSI FCI 70-2-2006 [S]. Ohio: Fluid Controls Institute, Inc., 2006.
[5]	陈刚, 王志敏, 张宗列. 比例喷雾阀的研制 [J]. 阀门, 2011(4): 14-15+24. DOI: 10.16630/j.cnki.1002-5855.2011.04.014. CHENG, WANGZ M, ZHANGZ L. Development of pressurizer spray control valve [J]. Valves, 2011(4): 14-15+24. DOI: 10.16630/j.cnki.1002-5855.2011.04.014.
[6]	祁崇可. 核电厂稳压器喷雾阀阀芯结构和等百分比流量特性补偿研究 [D]. 兰州: 兰州理工大学, 2016. QIC K. The disc structure and equal percentage flow characteristic analysis of pressurize spray valve of nuclear power plants [D]. Lanzhou: Lanzhou University of Technology, 2016.
[7]	施宝新. 核一级稳压器喷雾阀特性分析与结构设计 [J]. 阀门, 2019(6): 10-12+15. DOI: 10.16630/j.cnki.1002-5855.2019.06.003. SHIB X. Characteristic analysis and structure design of nuclear class1 pressure regulator spray valve [J]. Valves, 2019(6): 10-12+15. DOI: 10.16630/j.cnki.1002-5855.2019.06.003.
[8]	陆培文. 控制阀实用技术 [M]. 北京: 机械工业出版社, 2007. LUP W. Practical valve design manual [M]. Beijing: China Machine Press, 2007.
[9]	杨源泉. 阀门设计手册 [M]. 北京: 机械工业出版社, 1992. YANGY Q. Valve design manual [M]. Beijing: China Machine Press, 1992.
[10]	杨化飙. 稳压器喷雾阀流动规律与安全分析 [D]. 上海: 上海交通大学, 2013. YANGH B. Flow law and safety analysis of spray valve of pressurizer [D]. Shanghai: Shanghai Jiao Tong University, 2013.
[11]	薛阳, 林静, 李媛, 等. 基于自抗扰的核电站稳压器压力控制研究 [J]. 计算机仿真, 2014, 1(1): 127-131. DOI: 10.3969/j.issn.1006-9348.2014.01.029. XUEY, LINJ, LIY, et al. Research on pressure control of pressurizer at nuclear power plant based on active disturbances rejection controller [J]. Computer Simulation, 2014, 31(1): 127-131. DOI: 10.3969/j.issn.1006-9348.2014.01.029.
[12]	张国铎, 杨旭红, 卢栋青, 等. 核反应堆稳压器水位和压力控制系统研究 [J]. 化工自动化及仪表, 2013, 40(1): 35-38+42. DOI: 10.3969/j.issn.1000-3932.2013.01.011. ZHANGG D, YANGX H, LUD Q, et al. Research on water level and pressure control system of nuclear reactor regulator [J]. Control and Instruments in Chemical Industry, 2013, 40(1): 35-38+42.DOI: 10.3969/j.issn.1000-3932.2013.01.011.
[13]	上海发电设备成套设计研院. 核电厂用能动机械设备的鉴定 [M]. 上海: 上海科学技术文献出版社, 2007. Shanghai Power Equipment Reserch Institute. Qualification of active mechanical equipment used in nuclear power plants [M]. Shanghai: Shanghai Scientific & Technological Literature Press, 2007.
[14]	IEEE Standard for Qualification of Safety-Related Actuators for Nuclear Power Generating Stations and Other Nuclear Facilities: IEEE 382-2019 [S]. New York: IEEE, 2019.
[15]	中华人民共和国工业和信息化部. 工业过程控制系统用电动控制阀: JB/T 7387—2014 [S]. 北京: 机械工业出版社, 2014. Ministry of Industry Information Technology of the People's Republic of China. Electrical control valves for industrial-process control systems: JB/T 7387—2014 [S]. Beijing: China Machine Press, 2014.
[16]	ASME. Qualification of Active Mechanical Equipment Used in Nuclear Facilities: QME-1-2017 [S]. New York: ASME, 2017.

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

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0 引　言

电磁驱动型稳压器喷淋阀是三代压水堆核电机组的重要设备之一，是核电站唯一的一台核安全一级的控制阀。该阀门位于稳压器系统主喷淋管线上，主要功能是参与一回路的压力控制。在DBC-1类工况（包括电厂启动和停运工况）时，稳压器通过喷淋阀和电加热器实现将一回路压力控制在允许的变化范围内，避免反应堆紧急停堆和稳压器安全阀动作；在DBC-2类工况（例如二次侧排热减少事故）中，操纵员手动开关稳压器喷淋阀对一回路进行降压，以便达到安全注入系统余热排出模式（RIS/RHR）接入的安全停堆状态^［1］。

1 主要技术参数

三代核电华龙一号技术路线引入了全新设计理念，安全壳内减少气源，稳压器比例喷雾阀由二代机组的气动控制阀改为电磁驱动型控制阀。

电磁驱动型稳压器喷淋阀的主要设计参数指标如表1所示。阀门在满足RCC-M^［2］机械设备规范1级要求的同时，还需满足RCC-E^［3］电气设备鉴定等级K2的要求，并确保阀门整机满足一定地震工况下的可运行性和60年内12万次的循环寿命要求。阀门控制部分由外接在安全壳外的控制柜完成，控制柜和阀门本体之间应能保证至少150 m的信号传输与控制能力。阀门电磁驱动执行器需满足RCC-E等级K2的鉴定要求，控制柜需满足RCC-E电气设备鉴定等级K3的要求。

技术参数	电磁驱动型稳压器喷淋阀
驱动机构型式	电磁驱动
核安全等级	1级
RCC-M等级	1级
RCC-E等级	喷淋阀K2/控制柜K3
抗震等级	SSE1（可运行性）
设计压力/ （MPa.g·℃^-1）	17.13/360
公称直径/DN	100
最大压差/MPa	0.5
开启/关闭时间	≤2 s/5 s
调节特性	线性
允许阀座泄漏率	Ⅳ级 ANSI FCI 70—2^［4］
循环寿命次数	120 000

Table 1. Main technical parameters of solenoid pressurizer spray valve

3 试验验证

稳压器喷淋阀是核电站一回路系统的重要设备，为确保研制产品满足电厂的设计要求并成功落地应用，根据阀门在电厂中的安装位置及所在环境条件、运行老化等要求，确定了样机的鉴定试验项目^［13-15］如表2所示。其中阀门本体承压机械组件的鉴定参照ASME QME-1^［16］确定，阀门电磁驱动执行器按照RCC-E K2级的要求确定，阀门配套控制器按照RCC-E K3级的要求确定。

基准试验	型式试验	极限条件下的可运行性试验	设备性能随时间变化试验	事故模拟试验
承压性能试验	流量系数及固有流量特性试验	过电流试验	循环老化试验	阀门抗震试验
密封性能试验	开孔流量试验	加压循环试验	低温试验	控制器抗震试验
绝缘电阻试验	噪声试验	冷态可运行性试验	交变湿热试验	DBA辐照老化试验
绝缘强度试验	线圈允许温度试验	热态可运行性试验	热老化试验	LOCA试验
控制优先级试验		电磁兼容试验	辐照老化试验	/
动作性能试验	/	端部加载试验	振动老化试验	/
调节性能试验	/	/	循环老化试验	/
控制优先级试验	/	/	低温试验	/

Table 2. qualification test item for solenoid pressurizer spray valve

样机成功通过了表2所列的全套鉴定试验，证明本次研发的稳压器喷淋阀样机可满足机组一回路稳压器喷淋阀的正常运行老化及事故环境条件要求。

Reference (16)

[1]	广东核电培训中心. 900 MW压水堆核电站系统与设备(上、下册) [M]. 北京: 原子能出版社, 2005.	Guangdong Nuclear Power Training Center. 900 MW PWR nuclear power plant system and equipment (part I and part II) [M]. Beijing: Atomic Energy Press, 2005.
[2]	法国核岛设备设计、建造及在役检查规则协会. 压水堆核岛机械设备设计和建造规则: RCC-M-2007 [M]. 北京: 中国核电工程有限公司, 2007.	AFCEN. Design and conception rules for mechanical components of PWR nuclear islands: RCC-M-2007 [M]. Beijing: China Nuclear Power Engineering Co., Ltd., 2007.
[3]	法国核岛设备设计、建造及在役检查规则协会.压水堆核电站核岛电气设备设计和建造规则: RCC-E-2005 [M]. 深圳: 深圳中广核工程设计有限公司, 2005.	AFCEN. Rules for design and construction of electrical equipment for PWR nuclear island: RCC-E-2005[M]. Shenzhen: China Nuclear Power Design Co., Ltd., 2005.
[4]	Fluid Controls Institute, Inc. Control valve seat leakage: ANSI FCI 70-2-2006 [S]. Ohio: Fluid Controls Institute, Inc., 2006.
[5]	陈刚, 王志敏, 张宗列. 比例喷雾阀的研制 [J]. 阀门, 2011(4): 14-15+24. DOI:10.16630/j.cnki.1002-5855.2011.04.014.	CHEN G, WANG Z M, ZHANG Z L, : Development of pressurizer spray control valve[J]. Valves, 2011, 14-15+24.
[6]	祁崇可. 核电厂稳压器喷雾阀阀芯结构和等百分比流量特性补偿研究 [D]. 兰州: 兰州理工大学, 2016.	QI C K, 2016: The disc structure and equal percentage flow characteristic analysis of pressurize spray valve of nuclear power plants[J]. , , -.
[7]	施宝新. 核一级稳压器喷雾阀特性分析与结构设计 [J]. 阀门, 2019(6): 10-12+15. DOI:10.16630/j.cnki.1002-5855.2019.06.003.	SHI B X, : Characteristic analysis and structure design of nuclear class1 pressure regulator spray valve[J]. Valves, 2019, 10-12+15.
[8]	陆培文. 控制阀实用技术 [M]. 北京: 机械工业出版社, 2007.	LUP W. Practical valve design manual [M]. Beijing: China Machine Press, 2007.
[9]	杨源泉. 阀门设计手册 [M]. 北京: 机械工业出版社, 1992.	YANGY Q. Valve design manual [M]. Beijing: China Machine Press, 1992.
[10]	杨化飙. 稳压器喷雾阀流动规律与安全分析 [D]. 上海: 上海交通大学, 2013.	YANG H B, 2013: Flow law and safety analysis of spray valve of pressurizer[J]. , , -.
[11]	薛阳, 林静, 李媛, 等. 基于自抗扰的核电站稳压器压力控制研究 [J]. 计算机仿真, 2014, 1(1): 127-131. DOI: 10.3969/j.issn.1006-9348.2014.01.029.	XUE Y, LIN J, LI Y, 2014: Research on pressure control of pressurizer at nuclear power plant based on active disturbances rejection controller[J]. Computer Simulation, 31, 127-131.
[12]	张国铎, 杨旭红, 卢栋青, 等. 核反应堆稳压器水位和压力控制系统研究 [J]. 化工自动化及仪表, 2013, 40(1): 35-38+42. DOI: 10.3969/j.issn.1000-3932.2013.01.011.	ZHANG G D, YANG X H, LU D Q, 2013: Research on water level and pressure control system of nuclear reactor regulator[J]. Control and Instruments in Chemical Industry, 40, 35-38+42.
[13]	上海发电设备成套设计研院. 核电厂用能动机械设备的鉴定 [M]. 上海: 上海科学技术文献出版社, 2007.	Shanghai Power Equipment Reserch Institute. Qualification of active mechanical equipment used in nuclear power plants [M]. Shanghai: Shanghai Scientific & Technological Literature Press, 2007.
[14]	IEEE Standard for Qualification of Safety-Related Actuators for Nuclear Power Generating Stations and Other Nuclear Facilities: IEEE 382-2019 [S]. New York: IEEE, 2019.
[15]	中华人民共和国工业和信息化部. 工业过程控制系统用电动控制阀: JB/T 7387—2014 [S]. 北京: 机械工业出版社, 2014.	Ministry of Industry Information Technology of the People's Republic of China. Electrical control valves for industrial-process control systems: JB/T 7387—2014 [S]. Beijing: China Machine Press, 2014.
[16]	ASME. Qualification of Active Mechanical Equipment Used in Nuclear Facilities: QME-1-2017 [S]. New York: ASME, 2017.

Review on Design of Solenoid Pressurizer Spray Valve for Nuclear Power Plants

doi: 10.16516/j.gedi.issn2095-8676.2022.01.011

Abstract

References

通讯作者: 陈斌, bchen63@163.com

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Review on Design of Solenoid Pressurizer Spray Valve for Nuclear Power Plants

doi: 10.16516/j.gedi.issn2095-8676.2022.01.011

1. Anshan Solenoid Valve Co., Ltd., Anshan 114300, Liaoning, China

2. China Nuclear Power Engineering Co., Ltd., Shenzhen 518124, Guangdong, China

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2.1　整机结构设计

2.2　比例电磁铁结构设计

2.3　热防护装置结构设计

2.4　阀位信号检测与输出装置设计

2.5　先导式阀芯结构设计

Catalog

Review on Design of Solenoid Pressurizer Spray Valve for Nuclear Power Plants

doi: 10.16516/j.gedi.issn2095-8676.2022.01.011

Abstract

References

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Related

Review on Design of Solenoid Pressurizer Spray Valve for Nuclear Power Plants

doi: 10.16516/j.gedi.issn2095-8676.2022.01.011

1. Anshan Solenoid Valve Co., Ltd., Anshan 114300, Liaoning, China 2. China Nuclear Power Engineering Co., Ltd., Shenzhen 518124, Guangdong, China

HTML

2.1 整机结构设计

2.2 比例电磁铁结构设计

2.3 热防护装置结构设计

2.4 阀位信号检测与输出装置设计

2.5 先导式阀芯结构设计

Catalog

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1. Anshan Solenoid Valve Co., Ltd., Anshan 114300, Liaoning, China

2. China Nuclear Power Engineering Co., Ltd., Shenzhen 518124, Guangdong, China

2.1　整机结构设计

2.2　比例电磁铁结构设计

2.3　热防护装置结构设计

2.4　阀位信号检测与输出装置设计

2.5　先导式阀芯结构设计