Air conditioning apparatus and refrigerant quantity determination method

What is claimed is: 1. An air conditioning apparatus comprising: a refrigerant circuit having a compressor, a condenser arranged and configured to condense refrigerant, an expansion mechanism, an evaporator arranged and configured to evaporate refrigerant, an evaporator-side interconnection pipe arranged and configured to interconnect the expansion mechanism and the evaporator, a liquid refrigerant pipe arranged and configured to interconnect the expansion mechanism and the condenser, a gas refrigerant pipe arranged and configured to interconnect the evaporator and the suction side of the compressor, and a gas discharge pipe arranged and configured to interconnect the compressor and the condenser; a controller configured to control the refrigerant circuit to perform liquefaction control, which causes refrigerant present inside the refrigerant circuit to be present in a liquid state in a liquid reserving portion located between the expansion mechanism and an end of the condenser on a side opposite the expansion mechanism; a liquid bypass circuit arranged and configured to interconnect the liquid reserving portion and the gas refrigerant pipe, the liquid bypass circuit including a liquid bypass expansion valve; and a refrigerant quantity detection unit arranged and configured to detect at least one of either a volume of liquid refrigerant in the liquid reserving portion or a physical quantity equivalent to the volume, the controller and the liquid bypass circuit being arranged and configured to, in the following order perform the liquefaction control with the liquid bypass expansion valve of the liquid bypass circuit closed in the beginning of the liquefaction control while the compressor continues to compress the refrigerant present inside the refrigerant circuit prior to the beginning of the liquefaction control and throughout the liquefaction control, open the liquid bypass expansion valve to open the closed liquid bypass circuit after the controller judged that the volume of liquid refrigerant or the physical quantity equivalent to the volume has continued to be within a predetermined fluctuation range for a predetermined time duration or longer, prior to the refrigerant quantity detecting unit detecting at least one of the volume of liquid refrigerant in the liquid reserving portion or the physical quantity equivalent to the volume while the compressor continues to compress the refrigerant present inside the refrigerant circuit prior to the liquid bypass circuit being open and throughout the opening and maintaining open of the liquid bypass circuit, and regulate an amount of refrigerant passing through the liquid bypass circuit while the compressor continues to compress the refrigerant present inside the refrigerant circuit prior to and during the regulating of the amount of refrigerant passing through the liquid bypass circuit; such that the compressor continues to compress the refrigerant present inside the refrigerant circuit prior to the beginning of the liquefaction control and throughout completion of the regulating of the amount of refrigerant passing through the liquid bypass circuit. 2. The air conditioning apparatus according to claim 1 , wherein the controller is further configured to control the refrigerant circuit to perform temperature stabilization control, which stabilizes the temperature of refrigerant liquefied by the liquefaction control. 3. The air conditioning apparatus according to claim 2 , further comprising: a subcooling circuit branching from between the condenser and the expansion mechanism, and connected to the suction side of the compressor; a subcooling expansion mechanism provided in a path of the subcooling circuit; and a subcooling heat exchanger arranged and configured to perform heat exchange between refrigerant expanded by the subcooling expansion mechanism and refrigerant moving from the condenser toward the expansion mechanism, the controller being further configured to perform the temperature stabilization control by regulating a degree of expansion of the subcooling expansion mechanism. 4. The air conditioning apparatus according to claim 3 , further comprising: flow rate regulation structure arranged and configured directly or indirectly regulate a rate at which refrigerant flows through the liquid bypass circuit from the liquid reserving portion toward the gas refrigerant pipe. 5. The air conditioning apparatus according to claim 2 , further comprising: flow rate regulation structure arranged and configured directly or indirectly regulate a rate at which refrigerant flows through the liquid bypass circuit from the liquid reserving portion toward the gas refrigerant pipe. 6. The air conditioning apparatus according to claim 1 , further comprising: flow rate regulation structure arranged and configured directly or indirectly regulate a rate at which refrigerant flows through the liquid bypass circuit from the liquid reserving portion toward the gas refrigerant pipe. 7. The air conditioning apparatus according to claim 6 , wherein the flow rate regulation structure includes a liquid bypass valve which is provided in a path of the liquid bypass circuit and is capable of regulating quantity of refrigerant passing therethrough. 8. The air conditioning apparatus according to claim 7 , wherein the liquid bypass valve is a liquid bypass expansion mechanism arranged and configured to reduce pressure of refrigerant passing through; and the flow rate regulation structure further includes a liquid bypass heat exchanger arranged and configured to perform heat exchange between refrigerant moving from the liquid reserving portion toward the liquid bypass expansion mechanism and refrigerant passing through the liquid bypass expansion mechanism toward the gas refrigerant pipe. 9. The air conditioning apparatus according to claim 8 , wherein the controller is further configured to regulate a degree of depressurization of refrigerant in the liquid bypass expansion mechanism, thereby causing the heat exchange amount in the liquid bypass heat exchanger to fluctuate so as to regulate flow rate of a liquid single-phase refrigerant passing through the liquid bypass expansion mechanism while ensuring that refrigerant flowing into the liquid bypass expansion mechanism is in a liquid single phase. 10. The air conditioning apparatus according to claim 9 , wherein the flow rate regulation structure further includes a gas return circuit arranged and configured to interconnect the gas discharge pipe and the gas refrigerant pipe; and the controller is further configured to regulate flow rate of refrigerant passing through the liquid bypass valve, thereby regulating a ratio of a mixture of gas refrigerant fed to the gas refrigerant pipe via the gas return circuit and liquid refrigerant fed to the gas refrigerant pipe via the liquid bypass circuit. 11. The air conditioning apparatus according to claim 7 , wherein the flow rate regulation structure further includes a gas return circuit arranged and configured to interconnect the gas discharge pipe and the gas refrigerant pipe; and the controller is further configured to regulate flow rate of refrigerant passing through the liquid bypass valve, thereby regulating a ratio of a mixture of gas refrigerant fed to the gas refrigerant pipe via the gas return circuit and liquid refrigerant fed to the gas refrigerant pipe via the liquid bypass circuit. 12. The air conditioning apparatus according to claim 11 , further comprising: a discharged refrigerant temperature sensor arranged and configured to detect temperature of refrigerant discharged by the compressor, the contro