Flowmeter for two-phase fluid with simultaneous or alternating measurement of the gas phase and the liquid phase

What is claimed is: 1. A method for measuring the flow rate of two-phase liquid/gas cryogenic fluids using a flowmeter, comprising the steps of: introducing the cryogenic fluid into an upper portion of a liquid/gas phase separator; measuring a level of liquid phase cryogenic fluid in the liquid/gas phase separator; measuring a flow rate of liquid phase cryogenic fluid flowing in a liquid line that is in fluid communication with a bottom portion of the separator using a liquid flow rate sensor that is located in said liquid, the separator being placed in an elevated position in space relative to the liquid flow rate sensor; measuring a flow rate of gas phase cryogenic fluid flowing in a gas line that is in fluid communication with the upper portion of the liquid/gas phase separator using a gas flow rate sensor; providing a three-way valve having first, second, and third ports, said first port receiving a flow of gas phase cryogenic fluid from a downstream end of said gas line, said second port receiving a flow of liquid phase cryogenic fluid from a downstream end of said liquid line, said third port receiving said flows of gas phase and liquid phase cryogenic fluid from said first and second ports, respectively, said three-way valve being adapted and configured to allow or disallow a flow of the gas phase cryogenic fluid via said first port and/or allow or disallow a flow of the liquid phase cryogenic fluid via said second port; directing, from said third port, a two-phase liquid/gas cryogenic fluid comprising said flows of gas phase and liquid phase cryogenic fluid from said first and second ports, respectively, to a downstream station that uses said two-phase liquid/gas cryogenic fluid; comparing the measured level of liquid phase cryogenic fluid in the separator to at least one setpoint value for a level of liquid phase cryogenic fluid in the separator; depending upon a result of said comparison, controlling operation of said three-way valve to allow or disallow the flow of gas phase cryogenic fluid into the first port and/or allow or disallow the flow of liquid phase cryogenic fluid into the second port, thus dictating a composition of the two-phase liquid/gas cryogenic fluid leaving the third port for the downstream station; determining a mass flow rate of the two-phase liquid/gas cryogenic fluid by summing the measured flow rates of the gas and liquid phase cryogenic fluids flowing in the gas and liquid lines, respectively; during a storage phase operating said three-way valve to allow a portion of the liquid phase cryogenic fluid flow in the liquid line to rise into the gas line and to allow a remaining portion of the liquid phase cryogenic fluid flow in the liquid line to exit the three-way valve through the third port; and during a withdrawal phase operating the three-way valve to disallow a flow of the liquid phase cryogenic fluid therethrough and to allow any of the liquid phase cryogenic fluid, that was previously allowed to rise into the gas line, to drop back down to the three-way valve to exit through the third port. 2. The measurement method of claim 1 , wherein: said step of comparing comprises comparing the measured level of liquid phase cryogenic fluid in the separator to high and low setpoint values for a level of liquid phase cryogenic fluid in the separator; and following said withdrawal phase, when the level of liquid phase cryogenic fluid in the separator rises until the level of liquid phase cryogenic fluid in the separator passes back between the high and low level setpoint values, the first and second ports are reopened in order to allow the flows of gas and liquid phase cryogenic fluid from the gas and liquid lines, respectively. 3. The measurement method of claim 1 , wherein the liquid/gas phase separator is a tank. 4. The measurement method of claim 1 , wherein said step of measuring a level of liquid phase cryogenic fluid in the liquid/gas phase separator is performed using a bottom level sensor and a top level sensor.