Solar heat steam cycle system

The invention claimed is: 1. A solar heat steam cycle system comprising: a heat collector which collects solar thermal energy; a thermal storage device which stores the solar thermal energy collected by the heat collector; a feed water heater which heats feed water; an evaporator which evaporates the feed water supplied from the feed water heater; a steam turbine driven by steam generated by the evaporator; a control valve which controls allocations of heating medium supplied from said thermal storage device to said evaporator and said feed water heater; a temperature sensor which measures a temperature of the heating medium stored in the thermal storage device; and a controller which receives as input a stored heat amount of the thermal storage device calculated based on the temperature measured by the temperature sensor to determine opening of said control valve in such a manner that allocation of the heating medium supplied to said evaporator is relatively increased when the stored heat amount is larger than a predetermined criterion and that allocation of the heating medium supplied to said feed water heater is relatively increased when said stored heat amount is smaller than the predetermined criterion. 2. The solar heat steam cycle system according to claim 1 , wherein the controller determines opening of said control valve in such a manner that the allocation of the heating medium supplied to said evaporator is set to 100% when said stored heat amount is larger than a predetermined criterion and that the allocation of the heating medium supplied to said feed water heater is set to 100% when said stored heat amount is smaller than the predetermined criterion. 3. A solar heat steam cycle system comprising: a heat collector which collects solar thermal energy; a feed water heater which heats feed water; an evaporator which evaporates the feed water supplied from the feed water heater; a steam turbine driven by steam generated by the evaporator; a control valve which controls allocations of a heating medium supplied from said heat collector to said evaporator and said feed water heater; a temperature sensor which measures a temperature of the heating medium flowing through the heat collector; and a controller which receives as input a collected heat amount of the heat collector calculated based on the temperature measured by the temperature sensor to determine opening of said control valve in such a manner that allocation of the heating medium supplied to said evaporator is relatively increased when the collected heat amount is larger than a predetermined criterion and that allocation of the heating medium supplied to said feed water heater is relatively increased when said collected heat amount is smaller than the predetermined criterion. 4. The solar heat steam cycle system according to claim 3 , wherein the controller determines opening of said control valve in such a manner that the allocation of the heating medium supplied to said evaporator is set to 100% when the collected heat amount is larger than a predetermined criterion and that the allocation of the heating medium supplied to said feed water heater is set to 100% when said collected heat amount is smaller than the predetermined criterion. 5. A solar heat steam cycle system comprising: a heat collector which collects solar thermal energy; a thermal storage device which stores the solar thermal energy collected by the heat collector; a feed water heater which heats feed water; an evaporator which evaporates the feed water supplied from the feed water heater; a steam turbine driven by steam generated by the evaporator; a control valve which controls allocations of heating medium supply from said heat collector to said evaporator, said feed water heater, and said thermal storage device; a temperature sensor which measures a temperature of the heating medium flowing through the heat collector; and a controller which receives as input a collected heat amount of the heat collector calculated based on the temperature measured by the temperature sensor to determine opening of said control valve in such a manner that allocation of the heating medium supplied to said evaporator is relatively increased when collected heat amount is larger than a predetermined criterion and that allocation of the heating medium supplied to said feed water heater or said thermal storage device is relatively increased when said collected heat amount is smaller than the predetermined criterion. 6. The solar heat steam cycle system according to claim 5 , wherein the controller determines opening of said control valve in such a manner that the allocation of the heating medium supplied to said evaporator is set to 100% when the collected heat amount is larger than a predetermined criterion and that the allocation of the heating medium supplied to said evaporator is set to 0% when said collected heat amount is smaller than the predetermined criterion. 7. The solar heat steam cycle system according to claim 5 , further comprising: an auxiliary boiler supplied with the feed water heated by said feed water heater; a pressure sensor which measures steam pressure in said evaporator; and a flow rate sensor which measures steam flow rate; wherein the controller calculates flow rate of the feed water supplied to said auxiliary boiler based on the steam pressure and the steam flow rate measured by said pressure sensor and said flow rate sensor. 8. The solar heat steam cycle system according to claim 7 , wherein said controller: receives as input the steam pressure acquired by said pressure sensor to calculate a steam flow rate for maximizing the efficiency of the steam turbine; and calculates the flow rate of the feed water to said auxiliary boiler based on the steam flow rate acquired by said flow rate sensor and the steam flow rate output. 9. The solar heat steam cycle system according to claim 5 , further comprising: an auxiliary boiler supplied with the feed water heated by said feed water heater; wherein the controller receives a retrievable heating value regarding either heat collected by said heat collector or gross heating value stored in said thermal storage device; and wherein the controller calculates flow rate of the feed water supplied to said auxiliary boiler based on the retrievable heating value and on demand for electric power generated by driving said steam turbine. 10. The solar heat steam cycle system according to claim 9 , wherein said controller: receives said demand for electric power as input to calculate a steam pressure and a steam flow rate for maximizing the efficiency of the steam turbine; receives as input the steam pressure and the retrievable heating value to calculate a retrievable steam flow rate; and calculates the flow rate of the feed water to said auxiliary boiler based on the retrievable steam flow rate and the steam flow rate output. 11. The solar heat steam cycle system according to claim 5 , further comprising: an auxiliary boiler supplied with the feed water heated by said feed water heater; and a pressure sensor which measures steam pressure in said evaporator; wherein the controller receives a retrievable heating value regarding either heat collected by said heat collector or gross heating value stored in said thermal storage device; and wherein the controller calculates flow rate of the feed water supplied to said auxiliary boiler based on the retrievable heating value and on the steam pressure measured by said pressure sensor. 12. The solar heat steam cycle system according to claim 11 , wherein said controller: receives as input the heating value a