Compressor bearing cooling via purge unit

What is claimed is: 1. A vapor compression system comprising: a compressor comprising: a housing assembly ( 40 ) having a suction port ( 24 ) and a discharge port ( 26 ) and a motor compartment ( 60 ); an electric motor ( 42 ) having a stator ( 62 ) within the motor compartment and a rotor ( 64 ) within the stator, the rotor being mounted for rotation about a rotor axis ( 500 ); one or more working elements ( 44 ) coupled to the rotor to be driven by the rotor in at least a first condition so as to draw refrigerant in through the suction port and discharge said refrigerant out from the discharge port; one or more bearings ( 66 , 68 ) supporting the rotor and/or the one or more working elements; and one or more bearing feed passages coupled to the bearings to pass fluid along a first supply flowpath ( 100 ) to the bearings and a second supply flowpath ( 407 A, 407 B) to the bearings; a first heat exchanger ( 28 ) coupled to the dis charge port to receive the refrigerant driven in a downstream direction in the first operational condition of the compressor; an expansion device ( 32 ) downstream of the first heat exchanger; a second heat exchanger ( 30 ) downstream of the expansion device and coupled to the suction port to return the refrigerant in the first operating condition; and a purge unit ( 400 ) having: a vapor inlet line ( 410 ) for receiving a refrigerant flow; and a return line ( 414 , 417 A, 417 B) for returning a contaminant-depleted refrigerant flow, wherein the second supply flowpath ( 407 A, 407 B) extends from the purge unit, and the first supply flowpath ( 100 ) does not branch from the return line. 2. The vapor compression system of claim 1 wherein: the second supply flowpath comprises a first branch ( 407 A) extending to a first ( 66 ) of the bearings and a second branch ( 407 B) extending to a second ( 68 ) of the bearings. 3. The vapor compression system of claim 1 wherein: the second supply flowpath is formed by or branches from the return line ( 414 , 417 A, 417 B). 4. The vapor compression system of claim 1 wherein: the first supply flowpath and the second supply flowpath are non-overlapping. 5. The vapor compression system of claim 1 wherein: there is no pump along the first supply flowpath. 6. The vapor compression system of claim 1 further comprising: a pump ( 130 ) along the first supply flowpath. 7. The vapor compression system of claim 1 wherein the purge unit comprises: a purge unit compressor ( 472 ); a purge unit heat rejection heat exchanger ( 478 ) downstream of the purge unit compressor along a purge unit refrigerant flowpath; a purge unit expansion device ( 482 ) downstream of the purge unit heat rejection heat exchanger along the purge unit refrigerant flowpath; and a purge condensing unit ( 438 ) being a heat absorption heat exchanger downstream of the purge unit expansion device along the purge unit refrigerant flowpath and wherein the purge unit refrigerant flowpath is in heat exchange relation with the refrigerant from the refrigerant flow received from the vapor inlet line. 8. The vapor compression system of claim 7 wherein the purge unit comprises: a purge exhaust line ( 464 ) extending from the purge condensing unit; and a pump ( 466 ) along the purge exhaust line for exhausting contaminants from the purge unit. 9. The vapor compression system of claim 1 wherein: the system is a chiller. 10. The vapor compression system of claim 1 wherein one or more of: the refrigerant is selected from the group consisting of low pressure refrigerants and medium pressure refrigerants; the refrigerant is selected from the group consisting of HFC refrigerants and HFO refrigerants; or the refrigerant is selected from the group consisting of R1233zd, R1234yf, R1234ze, and R134a; or R134a. 11. The vapor compression system of claim 1 wherein: the compressor is a centrifugal compressor. 12. The vapor compression system of claim 1 further comprising: a controller ( 200 ) configured to operate ( 604 ) the purge unit to supply ( 630 ) refrigerant along the second supply flowpath in a start-up condition. 13. The vapor compression system of claim 6 wherein: the pump is a gear pump, a centrifugal pump, a regenerative pump, a screw pump, or a vane pump. 14. A vapor compression system comprising: a compressor comprising: a housing assembly ( 40 ) having a suction port ( 24 ) and a discharge port ( 26 ) and a motor compartment ( 60 ); an electric motor ( 42 ) having a stator ( 62 ) within the motor compartment and a rotor ( 64 ) within the stator, the rotor being mounted for rotation about a rotor axis ( 500 ); one or more working elements ( 44 ) coupled to the rotor to be driven by the rotor in at least a first condition so as to draw refrigerant in through the suction port and discharge said refrigerant out from the discharge port; one or more bearings ( 66 , 68 ) supporting the rotor and/or the one or more working elements; and one or more bearing feed passages coupled to the bearings to pass fluid along a supply flowpath to the bearings; a first heat exchanger ( 28 ) coupled to the discharge port to receive refrigerant driven in a downstream direction in the first operational condition of the compressor; an expansion device ( 32 ) downstream of the first heat exchanger; a second heat exchanger ( 30 ) downstream of the expansion device and coupled to the suction port to return the refrigerant in the first operating condition; and a purge unit ( 400 ) having: a vapor inlet line ( 410 ) for receiving a refrigerant flow; and a return line ( 414 , 417 A, 417 B) for returning a contaminant-depleted refrigerant flow, wherein: the supply flowpath ( 407 A, 407 B) extends from the purge unit; the supply flowpath comprises a first branch ( 407 A) extending to a first ( 66 ) of the bearings and a second branch ( 407 B) extending to a second ( 68 ) of the bearings; and a weir ( 496 ) in the purge unit divides flow between the supply flowpath first branch and second branch. 15. A vapor compression system comprising: a compressor comprising: a housing assembly ( 40 ) having a suction port ( 24 ) and a discharge port ( 26 ) and a motor compartment ( 60 ); an electric motor ( 42 ) having a stator ( 62 ) within the motor compartment and a rotor ( 64 ) within the stator, the rotor being mounted for rotation about a rotor axis ( 500 ); one or more working elements ( 44 ) coupled to the rotor to be driven by the rotor in at least a first condition so as to draw refrigerant in through the suction port and discharge said refrigerant out from the discharge port; one or more bearings ( 66 , 68 ) supporting the rotor and/or the one or more working elements; and one or more bearing feed passages coupled to the bearings to pass fluid along a first supply flowpath ( 100 ) to the bearings and a second supply flowpath ( 407 A, 407 B) to the bearings; a first heat exchanger ( 28 ) coupled to the discharge port to receive refrigerant driven in a downstream direction in the first operational condition of the compressor; an expansion device ( 32 ) downstream of the first heat exchanger; a second heat exchanger ( 30 ) downstream of the expansion device and coupled to the suction port to return the refrigerant in the first operating condition; a purge unit ( 400 ) having: a vapor inlet line ( 410 ) for receiving a refrigerant flow; and a return line ( 414 , 417 A, 417 B) for returning a contaminant-depleted refrigerant flow, wherein the second supply flowpath ( 407 A, 407 B) extends from the purge unit; and a contr