[1]井芳波,袁永强,卫栋梁,等. 喷嘴+补汽新型调节技术的经济性分析[J].热力发电,2018,(预出版):1-6.[doi:10.19666/j.rlfd.201805144]
 JING Fangbo,YUAN Yongqiang,WEI Dongliang,et al. Economic analysis for nozzle governing with overload valve regulation technology[J].Thermal Power Generation,2018,(预出版):1-6.[doi:10.19666/j.rlfd.201805144]
点击复制

 喷嘴+补汽新型调节技术的经济性分析

参考文献/References:

[1] 中国电力企业联合会. 2017-2018年度全国电力供需形势分析预测报告[R]. 北京: 中国电力企业联合会, 2018.
China Electricity Council.2007-2018 National Power Supply and Demand Situation Analysis and Forecast Report [R].Beijing:China Electricity Council, 2018.
[2] 张晓鲁, 张勇, 李振中. 高效宽负荷率超超临界机组关键技术研发与工程方案[J]. 动力工程学报, 2017(3): 173-178.
ZHANG Xiaolu, ZHANG Yong, LI Zhenzhong. R & D of Key Technologies for a High-efficient Wide-load-range Ultra-supercritical Unit and the Engineering Schemes [J]. Journal Of Chinese Society Of Power Engineering, 2017(3): 173-178.
[3] 石淑莲, 余红兵. 百万等级超超临界汽轮机进汽调节方式分析[J]. 节能技术, 2011, 29(3): 107-108.
SHI Shulian, YU Hongbing. Admission governing method analysis for 1 000 MW level ultra-super critical steam turbine[J]. Energy Conservation Technology, 2011, 29(3): 107-108.
[4] 齐进, 何平, 胡丹梅. 某1 000 MW汽轮机的全周进汽-滑压调节与旁通调节方式[J]. 上海电力学院学报, 2013, 29(5): 451-454.
QI Jin, HE Ping, HU Danmei. Sliding-pressure operation with full admission and bypass system of some 1 000 MW steam turbines[J]. Journal of Shanghai University of Electric Power, 2013, 29(5): 451-454.
[5] 彭泽瑛, 顾德明. 补汽调节阀技术在百万千瓦全周进汽汽轮机中的应用[J]. 热力透平, 2004, 33(4): 223-227.
PEN Zeying, GU Deming. Overload valve technology in the 1 000 MW ultra-supercritical steam turbine[J]. Thermal Turbine, 2004, 33(4): 223-227.
[6] 包伟伟, 高敏, 庞浩城, 等. 1 000 MW超超临界机组补汽调节技术经济性分析[J]. 发电设备, 2016, 30(1): 11-15.
BAO Weiwei, GAO Ming, PANG Haocheng, et al. Economic analysis on additional steam control technology for a 1 000 MW ultra supercritical unit[J]. Power Equipment, 2016, 30(1): 11-15.
[7] 郭永奎, 郑文辉, 徐自强, 等. 330 MW机组运行优化调整分析与研究[C]. //全国火电300 MW级机组能效对标及竞赛第四十二届年会论文集. 北方联合电力海勃湾发电厂, 2013: 532-539.
GUO Yongkui, ZHENG Wenhui, XU Ziqiang, et al. Analysis and Research on operation optimization and adjustment of 330MW unit. [C].// Proceedings of the forty-second annual meeting of energy efficiency benchmarking and competition for thermal power 300MW units in China. Union power Haibowan power plant, 2013:532-539.
[8] 冯伟忠. 1 000 MW超超临界汽轮机蒸汽参数的优化及讨论[J]. 动力工程学报, 2007, 27(3): 305-309.
FENG Weizhong. Discussion and optimization of steam parameters of 1 000 MW ultra-supercritical steam turbines[J]. Journal of Power Engineering, 2007, 27(3): 305-309.
[9] 李斌, 潘富停, 姚大林, 等.基于特征通流面积的汽轮机调节级变工况计算[J]. 应用能源技术, 2107(7): 36-39.
LI Bin, PAN Futing, YAO Dalin, et al. Calculation of Variable Stage of Steam Turbine Regulating Stage Based on Characteristic Flow Passage Area [J]. Applied Energy Technology, 2107(7): 36-39.
[10]顾溢. 超超临界660 MW机组汽轮机的特点与性能[J].热力发电, 2011 (3): 9-13.
GU Yi. Features and performance of ultra-supercrcritical 660 MW steam turbines[J]. Thermal Power Generation, 2011(3): 9-13.
[11]蔡颐年. 蒸汽轮机[M]. 西安: 西安交通大学出版社, 1988: 1.
CAI Yinian. Steam turbine[M]. Xi’an: Xi’an Jiaotong University Press, 1988: 1.

相似文献/References:

[1]测试.测试[J].热力发电,2013,(03):1.
  测试[J].Thermal Power Generation,2013,(预出版):1.
[2]陈海平,谢 天,杨博然,等. 火电厂烟气水分及余热陶瓷膜法回收实验[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201803032]
 CHEN Haiping,XIE Tian,YANG Boran,et al. Ceramic membrane method for water and waste heat recovery from flue gas of thermal power plant[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201803032]
[3]肖俊峰,李晓丰,胡孟起,等. 燃气轮机污染物排放影响因素相关性分析[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201804088]
 XIAO Junfeng,LI Xiaofeng,HU Mengqi,et al. Research on the correlation between influencing factors and pollutant emission of a heavy-duty gas turbine[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201804088]
[4]汪淑军,姚 伟,张喜来,等. 准东煤一维炉燃烧结渣特性试验研究[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201804121]
 WANG Shujun,YAO Wei,ZHANG Xilai,et al. Experimental study on slagging characteristics of zhundong coal burning on a one dimensional furnace [J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201804121]
[5]张贵泉,刘永兵,文慧峰,等. Incoloy800H合金晶间腐蚀敏化条件研究[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201805112]
 ZHANG Guiquan,LIU Yongbing,WEN Huifeng,et al. Research on intergranular corrosion sensitization conditions for Incoloy800H alloy[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201805112]
[6]杨 琛,薛 铮,方彦军,等. 塔式太阳能镜场三轴支撑定日镜控制装置[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201803062]
 YANG Chen,XUE Zheng,FANG Yanjun,et al. Tower solar mirror field of the three-axis support heliostat control device[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201803062]
[7]张雪慧,魏 博,马 瑞,等. 准东地区粉煤灰改性做高碱煤缓焦剂的熔融性能评估[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201805097]
 Zhang Xuehui,Wei Bo,Ma Rui,et al. The Evaluation of Fusion Characteristics on the High Alkali Coal Slagging Inhibitor by Modified Fly Ash from Zhundong Area[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201805097]
[8]余兴刚,李 旭,蒋北华,等. 汽轮机变工况模型的简便建立方法及应用[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201806123]
 YU Xinggang,LI Xu,JIANG Beihua,et al. A simple method to construct variable condition model for steam turbine and its application[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201806123]
[9]邱振波,张立杰,胡伟,等.基于信息通信技术的燃气轮机远程预警技术研究及应用[J].热力发电,2018,(预出版):1.[doi:10.19666/j.rlfd.201804129]
 QIU Zhenbo,ZHAGN Lijie,HU Wei,et al. Research and application of gas turbine remote early warning technology based on ICT[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666/j.rlfd.201804129]
[10]王万召,铁 玮,谭 文.直接蒸汽发电槽式太阳能集热器蒸汽温度自抗扰控制[J].热力发电,2018,(预出版):1.[doi:10.19666j.rlfd.201806120]
 WANG Wanzhao,TIE Wei,TAN Wen.Active Disturbance Rejection Control System of Steam Temperature of Direct Steam Generation Trough Solar Collector[J].Thermal Power Generation,2018,(预出版):1.[doi:10.19666j.rlfd.201806120]

备注/Memo

井芳波(1982—),男,高级工程师,主要从事汽轮机热力设计和性能试验,jingfb@mail.dfstw.com。

更新日期/Last Update: 2018-09-17