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, circulating a working fluid through a closed cycle fluid path including, 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 the closed cycle system comprises: (i) a first fluid connection between the high pressure leg and a high pressure tank and connected to the high pressure leg between an outlet of the hot side heat exchanger and an inlet of the turbine, (ii) a second fluid connection between the high pressure leg and an intermediate pressure tank and connected to the high pressure leg between the outlet of the hot side heat exchanger and the inlet of the turbine, (iii) a third fluid connection between the low pressure leg and the intermediate pressure tank and connected to the low pressure leg between an outlet of the cold side heat exchanger and an inlet of the compressor, and (iv) a fourth fluid connection between the low pressure leg and the high pressure tank and connected to the low pressure leg between the outlet of the cold side heat exchanger and the inlet of the compressor, and wherein the closed cycle system is configured to cycle between a charge mode and a discharge mode; operating the closed cycle system in the discharge mode, wherein a generator coupled to the turbine produces electrical power; determining an operating condition of the closed cycle system; defining a first threshold pressure value based on the determination of the operating condition of the closed cycle system; removing a first quantity of working fluid from the closed cycle fluid path by opening the first fluid connection, such that pressure of the working fluid in the high pressure leg decreases and pressure of the working fluid in the high pressure tank increases; closing the first fluid connection when pressure of the working fluid in the high pressure tank reaches the first threshold pressure value; and removing a second quantity of working fluid from the closed cycle fluid path by opening the second fluid connection, such that pressure of the working fluid in the high pressure leg decreases and pressure of the working fluid in the intermediate pressure tank increases. 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 first threshold pressure value is defined as an equilibrium pressure between pressure of the working fluid in the high pressure leg and pressure of the working fluid in the high pressure tank. 4. The method of claim 1 , wherein the first threshold pressure value is defined as a pressure less than an equilibrium pressure between pressure of the working fluid in the high pressure leg and pressure of the working fluid in the high pressure tank. 5. The method of claim 1 , further comprising closing the second fluid connection when pressure of the working fluid in the intermediate pressure tank reaches a second threshold pressure value. 6. The method of claim 5 , wherein the second threshold pressure value is defined as an equilibrium pressure between pressure of the working fluid in the high pressure leg and pressure of the working fluid in the intermediate pressure tank. 7. The method of claim 5 , wherein the second threshold pressure value is defined as a pressure less than an equilibrium pressure between pressure of the working fluid in the high pressure leg and pressure of the working fluid in the intermediate pressure tank. 8. The method of claim 5 , further comprising: determining a second operating condition of the closed cycle system; and defining the second threshold pressure value based on the determination of the second operating condition of the closed cycle system. 9. A method comprising: in a closed cycle system, circulating a working fluid through a closed cycle fluid path including, 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 the closed cycle system comprises: (i) a first fluid connection between the high pressure leg and a high pressure tank and connected to the high pressure leg between an outlet of the hot side heat exchanger and an inlet of the turbine, (ii) a second fluid connection between the high pressure leg and an intermediate pressure tank and connected to the high pressure leg between the outlet of the hot side heat exchanger and the inlet of the turbine, (iii) a third fluid connection between the low pressure leg and the high pressure tank and connected to the low pressure leg between an outlet of the cold side heat exchanger and an inlet of the compressor, and (iv) a fourth fluid connection between the low pressure leg and the intermediate pressure tank and connected to the low pressure leg between the outlet of the cold side heat exchanger and the inlet of the compressor, and wherein the closed cycle system is configured to cycle between a charge mode and a discharge mode; operating the closed cycle system in the discharge mode, wherein a generator coupled to the turbine produces electrical power; determining an operating condition of the closed cycle system; defining a first threshold pressure value based on the determination of the operating condition of the closed cycle system; removing a first quantity of working fluid from the closed cycle fluid path by opening the first fluid connection, such that pressure of the working fluid in the high pressure leg decreases and pressure of the working fluid in the high pressure tank increases; closing the first fluid connection when pressure of the working fluid reaches the first threshold pressure value; and removing a second quantity of working fluid from the closed cycle fluid path by opening the second fluid connection, such that pressure of the working fluid in the high pressure leg decreases and pressure of the working fluid in the intermediate pressure tank increases. 10. The method of claim 9 , wherein closing the first fluid connection comprises closing the first fluid connection when pressure of the working fluid in the high pressure leg reaches the first threshold pressure value. 11. The method of claim 9 , wherein closing the first fluid connection comprises closing the first fluid connection when pressure of the working fluid in the low pressure leg reaches the first threshold pressure value. 12. A method comprising: in a closed cycle system, circulating a working fluid through a closed cycle fluid path including, 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 the closed cycle system comprises: (i) a first fluid connection between the high pressure leg and a high pressure tank and connected to the high pressure leg between an outlet of the hot side heat exchanger and an inlet of the turbine, (ii) a second fluid connection between the high pressure leg and an intermediate pressure tank and connected to the high pressure leg between the outlet of the hot side heat exchanger and the inlet of the turbine, (iii) a third fluid connection between the low pressure leg and the intermediate pressure tank and connected to the low pressure leg between an outlet of the cold side heat exchanger and an inlet of the compressor, and (iv) a fourth fluid connection between the low pressure leg and the high pressure tank and connected to the low pressure leg between the outlet of the cold side heat exchanger and the inlet of the