Compressor clearance control

What is claimed is: 1. A vapor compression system comprising: a compressor ( 22 ) comprising: a housing assembly ( 50 ) having a suction port ( 24 ) and a discharge port ( 26 ); an impeller ( 54 ), the impeller being an open-type impeller; a shaft ( 70 ) supporting the impeller to be driven in at least a first operating condition so as to draw fluid in through the suction port and discharge said fluid out from the discharge port; a magnetic bearing system ( 66 , 67 , 68 ) supporting the shaft; an axial position sensor ( 80 ); and a controller ( 84 ) coupled to the axial position sensor and configured to control impeller axial position to vary with at least one of system capacity and lift; wherein the fluid is refrigerant; a first heat exchanger ( 28 ) coupled to the discharge port to receive the refrigerant driven in a downstream direction in the first operating condition of the compressor; an expansion device ( 32 ) downstream of the first heat exchanger; and 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. 2. The vapor compression system of claim 1 wherein: the housing assembly further comprises a motor compartment ( 60 ); an electric motor ( 52 ) has a stator ( 62 ) within the motor compartment and a rotor ( 64 ) within the stator, the rotor being mounted fur rotation about a rotor axis ( 500 ); and the shaft couples the impeller ( 54 ) to the rotor. 3. The vapor compression system of claim 1 wherein the magnetic bearing system comprises: a first radial bearing ( 66 ); a second radial bearing ( 67 ); and a thrust bearing ( 68 ). 4. The vapor compression system of claim 3 wherein: the thrust bearing is a thrust/counterthrust bearing. 5. The compressor of claim 1 wherein the controller is also programmed to: control the magnetic bearing system to limit synchronous vibration. 6. The vapor compression system of claim 1 wherein the controller is programmed to control the impeller axial position to vary with the system capacity so as to improve efficiency. 7. The vapor compression system of claim 1 wherein: the compressor is a single-impeller compressor; and the impeller is a single-stage impeller. 8. A vapor compression system comprising: a compressor ( 22 ) comprising: a housing assembly ( 50 ) having a suction port ( 24 ) and a discharge port ( 26 ); an impeller ( 54 ), the impeller being an open-type impeller; a shaft ( 70 ) supporting the impeller to be driven in at least a first operating condition so as to draw fluid in through the suction port and discharge said fluid out from the discharge port; a magnetic bearing system ( 66 , 67 , 68 ) supporting the shaft; an axial position sensor ( 80 ); and a controller ( 84 ) coupled to the axial position sensor and to the magnetic bearing system and configured control the magnetic bearing system so as to control impeller axial position to vary with at least one of system capacity and lift; wherein the fluid is refrigerant; a first heat exchanger ( 28 ) coupled to the discharge port to receive the refrigerant driven in a downstream direction in the first operating condition of the compressor; an expansion device ( 32 ) downstream of the first heat exchanger; and 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. 9. The system of claim 8 wherein: the axial position sensor is positioned to measure an axial position of a thrust collar of the magnetic bearing system; and the controller is configured so as to control the impeller axial position to vary with said at least one of system capacity and lift by controlling said axial position of said thrust collar of the magnetic bearing system to vary with said at least one of system capacity and lift based on a target varying with said at least one of system capacity and lift.