1 | 方圆, 张万益, 曹佳文. 我国能源资源现状与发展趋势[J]. 矿产保护与利用, 2018, (4): 34- 42, 47. | 2 | 马玉华, 邢长清, 徐君诏, 等. 深度调峰负荷时亚临界自然循环锅炉水循环安全计算与分析[J]. 热力发电, 2018, 47 (10): 108- 114. | 3 | 马世英, 王青. 大规模新能源集中外送系统源网协调风险及仿真评估[J]. 发电技术, 2018, 39 (2): 112- 117. | 4 | 史洁, 刘晓飞. 新能源功率预测算法优化研究[J]. 发电技术, 2019, 40 (1): 78- 82. | 5 | 张广才, 周科, 鲁芬, 等. 燃煤机组深度调峰技术探讨[J]. 热力发电, 2017, 46 (9): 17- 23. | 6 | 顾煜炯, 徐婧, 李倩倩, 等. 燃煤发电机组调峰能力模糊综合评估方法[J]. 热力发电, 2017, 46 (2): 15- 21. | 7 | 邹兰青.规模风电并网条件下火电机组深度调峰多角度经济性分析[D].北京:华北电力大学, 2017. | 8 | 谢冰瑶.1000 MW超超临界塔式褐煤锅炉炉内燃烧过程的数值研究[D].哈尔滨:哈尔滨工业大学, 2013. | 9 | 蔡晓辉.600 MW超临界锅炉炉内燃烧过程数值模拟[D].保定:华北电力大学, 2010. | 10 | 申春梅.1000 MW单炉膛双切圆锅炉炉内燃烧过程的数值模拟[D].哈尔滨工业大学, 2006. | 11 | 武进猛.1000 MW超超临界锅炉炉内燃烧过程数值模拟[D].北京:华北电力大学, 2011. | 12 | Maidanik M N , Verbovetskii E K , Dekterev A A , et al. Mathematical simulation of the furnace and turning gas conduit of a P-50R boiler during joint combustion of solid and gaseous fuel[J]. Thermal Engineering, 2011, 58 (6): 483- 488. | 13 | 方庆艳, 汪华剑, 陈刚, 等. 超超临界锅炉磨煤机组合运行方式优化数值模拟[J]. 中国电机工程学报, 2011, 31 (5): 1- 6. | 14 | 丘全科.1000 MW超临界塔式锅炉传热模拟[D].北京:清华大学, 2016. | 15 | Senior C L , Srinivasachar S . Viscosity of ash particles in combustion systems for prediction of particle sticking[J]. Energy and Fuels, 1995, 9 (2): 209. | 16 | Wies?aw Z , Marzena N O . A new 1D/3D model of conjugate heat transfer in water wall tubes of power boiler combustion chamber[J]. Procedia Engineering, 2016, (157): 200- 206. | 17 | Vuthaluru R , Vuthaluru H B . Modelling of a wall fired furnace for different operating conditions using FLUENT[J]. Fuel Processing Technology, 2006, 87 (7): 633- 639. | 18 | Wang S Y , Yang D , Liu D , et al. Experimental and theoretical analysis on the safety and efficiency of an ultra-supercritical pulverized coal-fired boiler with low mass flux vertical water wall[J]. Applied Thermal Energy, 2019, (146): 440- 449. | 19 | Wang S Y , Yang D , Zhao Y J , et al. Heat transfer characteristics of spiral water wall tube in a 1000 MW ultra-supercritical boiler with wide operating load mode[J]. Applied Thermal Energy, 2018, (130): 501- 514. | 20 | Schuhbauer C , Angerer M , Spliethoff H , et al. Coupled simulation of a tangentially hard coal fired 700℃ boiler[J]. Fuel, 2014, (122): 149- 163. | 21 | Drosatos P , Nikolopoulos N , Agraniotis M , et al. Decoupled CFD simulation of furnace and heat exchangers in a lignite utility boiler[J]. Fuel, 2014, 117 (Part A): 633- 648. | 22 | 国建刚, 孙宏, 孙冠男, 等. 超(超)临界锅炉与亚临界锅炉热控设计的区别[J]. 电站系统工程, 2012, 28 (5): 60- 62, 64. | 23 | 岑可法. 高等燃烧学[M]. 杭州: 浙江大学出版社, 2002. | 24 | Baum M M , Street P J . Predicting the combustion behaviour of coal particles[J]. Combustion Science and Technology, 1971, 3 (5): 231- 43. | 25 | Field M A . Rate of combustion of size-graded fractions of char from a low-rank coal between 1200K and 2000K[J]. Combust Flame, 1969, 13 (3): 237- 52. | 26 | Magnussen B F , Hjertager B H . On mathematical modeling of turbulent combustion with special emphasis on soot formation and combustion[J]. Symposium (International) on Combustion, 1977, 16 (1): 719- 729. | 27 | 叶新涛.浓淡旋流煤粉燃烧器的数值模拟与改进[D].郑州:郑州大学, 2009. | 28 | 卢欢, 杨冬, 周旭, 等. 超临界直流锅炉水冷壁压降及出口汽温计算[J]. 西安交通大学学报, 2011, 45 (1): 38- 42. | 29 | 王为术, 徐维晖, 李帅帅, 等. 1000 MW超超临界锅炉高热负荷区垂直水冷壁温度特性研究[J]. 电站系统工程, 2011, 27 (6): 9- 12. | 30 | 何洪浩, 李文军, 曾俊, 等. 超超临界直流锅炉垂直管屏水冷壁壁温分布特性[J]. 动力工程学报, 2017, 37 (4): 257- 260, 292. | 31 | Chu Y , Lou C , Cheng Q , et al. Distributed parameter modeling and simulation for the evaporation system of a controlled circulation boiler based on 3-D combustion monitoring[J]. Applied Thermal Engineering, 2008, 28 (2/3): 164- 177. |
|