Refrigerant gas cooling of motor and magnetic bearings

What is claimed is: 1. A compressor, comprising: a volute housing; a motor housing; a metering device comprising: an inlet configured to receive a flow of refrigerant, the flow of refrigerant being a portion of flow provided directly from the volute housing; an orifice in direct fluid communication with an inside of the motor housing; an automated expansion valve; and a valve seat configured to receive the automated expansion valve, wherein the automated expansion valve and the valve seat control the flow of refrigerant through the orifice, wherein the automated expansion valve is electrically connected to a controller to receive position information for the automated expansion valve, wherein the controller receives compressor operational parameter data, and determines a position of the automated expansion valve; at least one bearing located within the motor housing; a shaft seal; and a compressor motor located within the motor housing; wherein the flow of refrigerant and leakage from the shaft seal are configured to form a cooling flow that travels in a direction of rotation of an internal component within the compressor motor housing when the compressor motor is in operation. 2. The compressor of claim 1 , wherein the metering device further comprises a fixed orifice configured to allow fluid communication between the cooling line and an inside of the motor housing. 3. The compressor of claim 1 , wherein the metering device comprises a fixed flow path formed in the valve seat. 4. The compressor of claim 1 , wherein the automated expansion valve is an electronic expansion valve. 5. The compressor of claim 1 , wherein the automated expansion valve is a thermal expansion valve. 6. The compressor of claim 1 , wherein the compressor is a multi-stage compressor. 7. The compressor of claim 1 , wherein the compressor operational parameter data comprises a gas density within the motor housing. 8. The compressor of claim 1 , wherein the compressor operational parameter comprises temperature data from within the motor housing. 9. A metering device comprising: an inlet configured to receive a flow of refrigerant, the flow of refrigerant being a portion of flow provided directly from a volute housing of a compressor, an orifice in direct fluid communication with an inside of a compressor motor housing, an automated expansion valve, a valve seat configured to receive the automated expansion valve, wherein the automated expansion valve and the valve seat control the flow of refrigerant through the orifice, wherein the automated expansion valve is electrically connected to a controller to receive position information for the automated expansion valve, wherein the controller receives compressor operational parameter data, and determines a position of the automated expansion valve. 10. The metering device of claim 9 , further comprising a second orifice having a fixed size. 11. The metering device of claim 9 , wherein the valve seat is configured to allow a flow of refrigerant through the orifice when the automated expansion valve is in a fully extended position. 12. A method of providing refrigerant to an inside of a compressor motor housing, comprising: providing a baseline flow of the refrigerant to the inside of the compressor motor housing, the baseline flow including a fixed flow at a metering device and shaft seal leakage, and providing a variable flow of the refrigerant from a volute housing of a compressor to the inside of the compressor motor housing, wherein the variable flow of the refrigerant is controlled via an automated expansion valve, wherein the automated expansion valve receives the refrigerant from a portion of flow provided directly from the volute housing of the compressor, combining the baseline flow and the variable flow into a cooling flow, and directing the cooling flow to travel in a direction of rotation of an internal component within the compressor motor housing. 13. The method of claim 12 , wherein the fixed flow at the metering device is provided via an orifice having a fixed size. 14. The method of claim 12 , wherein the automated expansion valve is an electronic expansion valve. 15. The method of claim 12 , wherein the automated expansion valve is a thermal expansion valve. 16. A compressor, comprising: a volute housing; a motor housing; a metering device comprising: an orifice in direct fluid communication with an inside of the motor housing; an automated expansion valve; and a valve seat configured to receive the automated expansion valve, wherein the automated expansion valve and the valve seat control the flow of refrigerant through the orifice, wherein the automated expansion valve is electrically connected to a controller to receive position information for the automated expansion valve, wherein the controller receives compressor operational parameter data, and determines a position of the automated expansion valve; at least one bearing located within the motor housing; a shaft seal; and a compressor motor located within the motor housing, wherein the metering device is located on a surface of the motor housing, and the flow of refrigerant and leakage from the shaft seal are configured to form a cooling flow that travels in a direction of rotation of an internal component within the compressor motor housing when the compressor motor is in operation. 17. The compressor of claim 16 , wherein the metering device further comprises a fixed orifice configured to allow fluid communication between a cooling line and an inside of the motor housing. 18. The compressor of claim 16 , wherein the metering device comprises a fixed flow path formed in the valve seat.