Flexible coal-fired power generation system and operation method thereof

What is claimed is: 1. A flexible coal-fired power generation system, which comprises a thermal system for coal-fired power generating unit and a high-temperature heat storage system, wherein: the thermal system for coal-fired power generating unit comprises a boiler ( 1 ), a steam turbine high pressure cylinder ( 2 ), a steam turbine medium and low pressure cylinder ( 3 ), a condenser ( 4 ), a condensate pump ( 5 ), a low pressure heater ( 6 ), a deaerator ( 7 ), a feedwater pump ( 8 ), a first-stage high pressure heater ( 9 ), a second-stage high pressure heater ( 10 ), a third-stage high pressure heater ( 11 ), an inlet regulating valve ( 12 ) for the first-stage high pressure heater, an inlet regulating valve ( 13 ) for the second-stage high pressure heater, an inlet regulating valve ( 14 ) for the third-stage high pressure heater and an outlet regulating valve ( 15 ) for the third-stage high pressure heater; a heat storage medium heater ( 16 ) is located in the boiler ( 1 ); the high-temperature heat storage system comprises a heat storage medium pump ( 17 ), a cold heat storage medium tank ( 18 ), a hot heat storage medium tank ( 20 ), a connection valve ( 19 ) for connecting the cold heat storage medium tank ( 18 ) with the hot heat storage medium tank ( 20 ), a heat storage medium and feedwater heat exchanger ( 21 ) and an outlet regulating valve ( 22 ) for the hot heat storage medium tank ( 20 ), all of which are connected with each other in sequence; an inlet of the heat storage medium heater ( 16 ) is connected with a cold heat storage medium outlet of the cold heat storage medium tank ( 18 ) through the heat storage medium pump ( 17 ); an outlet of the heat storage medium heater ( 16 ) is connected with a hot heat storage medium inlet of the hot heat storage medium tank ( 20 ) through a pipeline; a heat storage medium outlet of the heat storage medium and feedwater heat exchanger ( 21 ) is connected with a cold heat storage medium inlet of the cold heat storage medium tank ( 18 ) through a pipeline, and a heat storage medium inlet of the heat storage medium and feedwater heat exchanger ( 21 ) is connected with a hot heat storage medium outlet of the hot heat storage medium tank ( 20 ) through the outlet regulating valve ( 22 ) for the hot heat storage medium tank; a feedwater inlet of the heat storage medium and feedwater heat exchanger ( 21 ) is connected with a feedwater inlet of the first-stage high pressure heater ( 9 ) through the inlet regulating valve ( 12 ) for the first-stage high pressure heater, is connected with a feedwater inlet of the second-stage high pressure heater ( 10 ) through the inlet regulating valve ( 13 ) for the second-stage high pressure heater, is connected with a feedwater inlet of the third-stage high pressure heater ( 11 ) through the inlet regulating valve ( 14 ) for the third-stage high pressure heater, and is connected with a feedwater outlet of the third-stage high pressure heater through the outlet regulating valve ( 15 ) for the third-stage high pressure heater; a feedwater outlet of the heat storage medium and feedwater heat exchanger ( 21 ) is connected with the feedwater outlet of the third-stage high pressure heater ( 11 ); the cold heat storage medium tank ( 18 ) is connected with the hot heat storage medium tank ( 20 ) through the connection valve ( 19 ) for connecting the cold heat storage medium tank with the hot heat storage medium tank; a superheated steam outlet of the boiler ( 1 ) is connected with an inlet of the steam turbine high pressure cylinder ( 2 ); a feedwater inlet of the boiler ( 1 ) is connected with the feedwater outlet of the third-stage high pressure heater ( 11 ); a steam outlet of the steam turbine high pressure cylinder ( 2 ) is connected with a steam inlet of the steam turbine medium and low pressure cylinder ( 3 ) through the boiler ( 1 ), and is connected with a superheated steam inlet of the second-stage high pressure heater ( 10 ) through a pipeline; a first-stage steam extraction outlet of the steam turbine high pressure cylinder ( 2 ) is connected with a steam inlet of the third-stage high pressure heater ( 11 ) through a pipeline; a first-stage steam extraction outlet of the steam turbine medium and low pressure cylinder ( 3 ) is connected with a steam inlet of the first-stage high pressure heater ( 9 ) through a pipeline, and a second-stage steam extraction outlet of the steam turbine medium and low pressure cylinder ( 3 ) is connected with a steam inlet of the deaerator ( 7 ) through a pipeline, and a third-stage steam extraction outlet of the steam turbine medium and low pressure cylinder ( 3 ) is connected with a steam inlet of the low pressure heater ( 6 ) through a pipeline; a steam outlet of the steam turbine medium and low pressure cylinder ( 3 ) is connected with a steam inlet of the condenser ( 4 ); a water outlet of the condenser ( 4 ) is connected with a water inlet of the low pressure heater ( 6 ) through the condensate pump ( 5 ); a water outlet of the low pressure heater ( 6 ) is connected with a water inlet of the deaerator ( 7 ); a water outlet of the deaerator ( 7 ) is connected with the feedwater inlet of the first-stage high pressure heater ( 9 ) and the feedwater inlet of the heat storage medium and feedwater heat exchanger ( 21 ) through the feedwater pump ( 8 ); a feedwater outlet of the first-stage high pressure heater ( 9 ) is connected with the feedwater inlet of the second-stage high pressure heater ( 10 ) through a pipeline; a feedwater outlet of the second-stage high pressure heater ( 10 ) is connected with the feedwater inlet of the third-stage high pressure heater ( 11 ) through a pipeline. 2. The flexible coal-fired power generation system according to claim 1 , wherein a heat storage medium adopted by the high-temperature heat storage system is heat transfer oil. 3. The flexible coal-fired power generation system according to claim 1 , wherein a flue gas temperature of the boiler ( 1 ) where the heat storage medium heater ( 16 ) is located is greater than 400° C. 4. An operation method of the flexible coal-fired power generation system according to claim 1 , the operation method comprising steps of: when a load of a coal-fired power generating unit needs to be reduced, closing the inlet regulating valve ( 12 ) for the first-stage high pressure heater, the inlet regulating valve ( 13 ) for the second-stage high pressure heater, the inlet regulating valve ( 14 ) for the third-stage high pressure heater and the outlet regulating valve ( 15 ) for the third-stage high pressure heater, opening the connection valve ( 19 ) for connecting the cold heat storage medium tank with the hot heat storage medium tank, staring the heat storage medium pump ( 17 ), adjusting a flow of cold heat storage medium that enters the heat storage medium heater ( 16 ) and exchanges heat with high-temperature flue gas through the heat storage medium pump ( 17 ), heat storage medium after heat exchange entering the hot heat storage medium tank ( 20 ), and adjusting quantity of heat storage medium in the cold heat storage medium tank and quantity of heat storage medium in the hot heat storage medium tank to a balance through the connection valve ( 19 ) for connecting the cold heat storage medium tank with the hot heat storage medium tank, wherein an adjustment goal is to reduce an output of a steam turbine when the boiler ( 1 ) is stably burning; when the load of the coal-fired power generating unit needs to be increased, stopping the heat storage medium pump ( 17 ), opening the outlet regulating valve ( 22 ) for the hot heat storage medium tank, adjusting a flow of hot heat storage medium that enters the heat storage medium and feedwater heat exchanger ( 21 ) through the outlet regulating valve ( 22 ), adjusting flow and temperature of feedwater that enters the heat storage medi