Variable pressure inventory control of closed cycle system with a high pressure tank and an intermediate pressure tank

We claim: 1. A method comprising: in a closed cycle system operable in a charge mode and a power generation mode, circulating a working fluid through a closed cycle fluid path which includes, in sequence, a compressor, a hot side heat exchanger, a turbine, and a cold side heat exchanger, wherein the closed cycle fluid path comprises a high pressure leg and a low pressure leg, wherein in the generation mode stored heat is provided to the working fluid to drive the turbine, and in the charge mode the compressor is driven by electric power to compress the working fluid to provide heat for storage; responsive to determination to adjust the amount of working fluid within the closed cycle system, opening a fluid connection between the closed cycle fluid path and a pressure tank to communicate fluid therebetween via the fluid connection, and opening another fluid connection between the closed cycle fluid path and another pressure tank to communicate fluid therebetween via the other fluid connection, wherein working fluid communicated via the fluid connection passes in the same direction to or from the closed cycle system as working fluid communicated via the other fluid connection to correspondingly add or remove working fluid via each fluid connection; and closing at least one of the fluid connections in response to achieving a threshold pressure value within at least one of the high pressure leg, low pressure leg, the pressure tank, and the other tank. 2. The method of claim 1 , wherein the closed cycle system comprises a closed Brayton cycle system. 3. The method of claim 1 , wherein the threshold pressure value is defined as an equilibrium pressure between pressure of the working fluid in the closed cycle system and pressure of the working fluid in one of the pressure tanks. 4. The method of claim 1 , wherein the threshold pressure value is defined as a pressure less than an equilibrium pressure between pressure of the working fluid in the closed cycle system and pressure of the working fluid in one of the pressure tanks. 5. The method of claim 1 , further comprising: operating the closed cycle system in the power generation mode of a power generation system, wherein a generator coupled with the turbine produces electrical power; determining an operating condition of the power generation system; and defining the first threshold pressure value based on the determination of the operating condition of the power generation system. 6. The method of claim 1 , further comprising closing the other one of the fluid connections in response to achieving another threshold pressure value within at least one other of the high pressure leg, low pressure leg, the pressure tank, and the other tank. 7. The method of claim 6 , wherein the other threshold pressure value is defined as an equilibrium pressure between pressure of the working fluid in the closed cycle system and pressure of the working fluid in one of the pressure tanks. 8. The method of claim 6 , wherein the other threshold pressure value is defined as a pressure less than an equilibrium pressure between pressure of the working fluid in the closed cycle system and pressure of the working fluid in one of the pressure tanks. 9. The method of claim 6 , further comprising: operating the closed cycle system in the power generation mode of a power generation system, wherein a generator coupled with the turbine produces electrical power; determining an operating condition of the power generation system; and defining the other threshold pressure value based on the determination of the operating condition of the power generation system. 10. The method of claim 1 , wherein working fluid communicated via each of the fluid connection and the other fluid connection passes to the closed cycle system to add working fluid. 11. The method of claim 10 , further comprising responsive to another determination to adjust the amount of working fluid within the closed cycle system, opening the fluid connection between the closed cycle fluid path and the pressure tank to communicate other working fluid therebetween via the fluid connection, and opening the other fluid connection between the closed cycle fluid path and the another pressure tank to communicate other working fluid therebetween via the other fluid connection, wherein other working fluid communicated via each of the fluid connection and the other fluid connection passes to the closed cycle system to add working fluid. 12. The method of claim 1 , wherein working fluid communicated via each of the fluid connection and the other fluid connection passes from the closed cycle system to remove working fluid. 13. The method of claim 12 , further comprising responsive to another determination to adjust the amount of working fluid within the closed cycle system, opening the fluid connection between the closed cycle fluid path and the pressure tank to communicate other working fluid therebetween via the fluid connection, and opening the other fluid connection between the closed cycle fluid path and the another pressure tank to communicate other working fluid therebetween via the other fluid connection, wherein other working fluid communicated via each of the fluid connection and the other fluid connection passes from the closed cycle system to remove working fluid. 14. The method of claim 12 , further comprising responsive to another determination to adjust the amount of working fluid within the closed cycle system, opening still another fluid connection between the closed cycle fluid path and still another pressure tank to communicate working fluid therebetween via the still another fluid connection, and opening further still another fluid connection between the closed cycle fluid path and further still another pressure tank to communicate working fluid therebetween via the further still another fluid connection, wherein working fluid communicated via each of the still another fluid connection and the further still another fluid connection passes to the closed cycle system to add working fluid. 15. The method of claim 1 , wherein the pressure tank is a high pressure tank and the other pressure tank is an intermediate pressure tank. 16. The method of claim 15 , wherein the fluid connection is arranged between the high pressure leg of the closed cycle system and the high pressure tank, and the other fluid connection is arranged between the high pressure leg and the intermediate pressure tank. 17. The method of claim 15 , wherein the fluid connection is arranged between the low pressure leg of the closed cycle system and the high pressure tank, and the other fluid connection is arranged between the low pressure leg and the intermediate pressure tank. 18. An energy system comprising: at least two turbomachinery systems, wherein at least one of the at least two turbomachinery systems is operable as a compressor system and at least one of the at least two turbomachinery systems is operable as a turbine system; a closed cycle system, operable in a charge mode and a power generation mode, for circulating a working fluid through a closed cycle fluid path which includes, in sequence, the at least one turbomachinery system operable as a compressor, a hot side heat exchanger, the at least one turbomachinery system operable as a turbine, and a cold side heat exchanger, wherein the closed cycle fluid path comprises a high pressure leg and a low pressure leg, wherein in the generation mode stored heat is provided to the working fluid to drive the turbine, and in the charge mode the compressor is driven by e