[1] |
LIU M,ZHANG X,YANG K,et al. Optimization and comparison on supercritical CO2 power cycles integrated within coal-fired power plants considering the hot and cold end characteristics [J].Energy Conversion and Management,2019(195):854-865. |
[2] |
郭嘉琪,王坤,朱含慧,等. 超临界CO2及其混合工质布雷顿循环热力学分析 [J]. 工程热物理学报,2017(4):19-26.
GUO J Q,WANG K,ZHU H H,et al. Thermodynamic analysis of brayton cycles using supercritical carbon dioxide and its mixture as working fluid [J]. Journal of Thermophysics,2017(4):19-26. |
[3] |
郑开云. 集成小型堆和可再生能源的超临界CO2循环发电系统 [J]. 南方能源建设,2019,6(2):29-33. |
[4] |
ROCHAU G E,PASCH J J,CARLSON M D,et al. Supercritical CO2 Brayton Cycles [R]. Albuquerque:Sandia National Lab.,2014. |
[5] |
郑开云. 燃气-超临界CO2联合循环发电系统 [J]. 南方能源建设,2019,6(3):87-91. |
[6] |
International Energy Agency. Renewables 2018 analysis and forecasts to 2023 [R]. Paris:International Energy Agency,2018. |
[7] |
BRACKEN N,MACKNICK J,TOVAR-HASTINGS A,et al.Concentrating solar power and water issues in the US Southwest [R].Golden:National Renewable Energy Lab.,2015. |
[8] |
WANG K,HE Y L,ZHU H H. Integration between supercritical CO2,Brayton cycles and molten salt solar power towers:A review and a comprehensive comparison of different cycle layouts [J]. Applied Energy,2017(195):819-836. |
[9] |
HO C K,IVERSON B D. Review of high-temperature central receiver designs for concentrating solar power [J]. Renewable and Sustainable Energy Reviews,2014(29):835-846. |
[10] |
郑开云. 超临界二氧化碳循环应用于火力发电的研究现状 [J].南方能源建设,2017,4(3):39-47. |
[11] |
IVERSON B D,CONBOYT M,PASCH J J,et al. Supercritical CO2 brayton cycles for solar-thermal energy [J]. Applied Energy,2013,111(4):957-970. |
[12] |
朱含慧,王坤,何雅玲. 直接式S-CO2塔式太阳能热发电系统光-热-功一体化热力学分析 [J]. 工程热物理学报,2017,38(10):2045-2053. |
[13] |
ROSENTHAL R. GAMS—a user’s guide [M]. Washington D.C.:GAMS Development Corp.,2017. |
[14] |
DRUD A. GAMS/CONOPT-a large-scale GRG code [M]. Bagsvaerd:ARKI Consulting and Development,1996. |
[15] |
吴毅,王佳莹,王明坤,等. 基于超临界CO2布雷顿循环的塔式太阳能集热发电系统 [J]. 西安交通大学学报,2016,50(5):108-113. |
[16] |
WILLIAMS D F. Assessment of candidate molten salt coolants for the NGNP/NHI heat-transfer loop:ORNL/TM-2006/69 [R]. Oak Ridge,Tennessee:Oak Ridge National Laboratory,2006. Doi: 10.2172 /1360677. |
[17] |
LI X,KONG W,WANG Z,et al. Thermal model and thermodynamic performance of molten salt receiver [J]. Renewable Energy,2010,35(5):981-988. |