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Rapid Load-change Control of Condensate Throttling Considering Self-recovery

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ã€Authorã€‘ KONG De-an;LI Wei;HAN Hong-zhi;GAO Ning;LIU Jiang-shan;WANG Xiao-yu;KANG Yong-hao;WANG Wei;State Grid Xinjiang Company Limited Electric Power Research Institute;Xinjiang Electric Power Construction and Commissioning Co.,Ltd;State Key Laboratory of Alternate Electrical Power System with Renewable Energy Sources,North China Electric Power University;

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ã€Abstractã€‘ In order to improve the load change capability for the large-scale integration and safe operation of renewable energies,condensate throttling was combined with traditional boiler-turbine coordinated control by the rapid load control and self-recovery control of condensate throttling. The dynamic incremental power model of condensate throttling was set up based on mechanism analysis and data identification,and the unit nonlinear control model with 3 inputs and 2 outputs considering condensate throttling regulation was further developed. A novel load-change control strategy combining condensate throttling and boiler-turbine coordinated control was designed,which overcomed the influence of condensate throttling on water levels of deaerator and hot well,and meanwhile improved the load following capability. Finally,a test on a 300 MW power unit proved that our strategy improves the load-change performance,which is with great significance to the primary frequency control of power grid.æ›´å¤š è¿˜åŽŸ