Active clearance management in screw compressor

The invention claimed is: 1. A compressor comprising, a housing defining a working chamber, the housing including a first bore, and an endplate disposed toward a discharge end, a first rotor having helical threads, the first rotor being configured to be housed in the first bore, one or more first rotor clearances each defined by an outer dimension of the first rotor in relation to one of one or more static components in the compressor, a controllable bearing supporting the first rotor, a second bore in the housing; a second rotor disposed in the second bore, the second rotor has helical threads intermeshing with the helical threads of the first rotor; a rotor-to-rotor clearance is defined between the first rotor and the second rotor; and a controller to control the controllable bearing such that the controllable bearing moves the first rotor in a manner to reduce or enlarge at least one of the one or more first rotor clearances, and such that the controllable bearing moves the first rotor in a manner to reduce or enlarge the rotor-to-rotor clearance. 2. The compressor according to claim 1 , wherein the one or more first rotor clearances include one or more of a first rotor-to-bore clearance defined between the first rotor and an interior surface of the first bore, and a first rotor-to-endplate clearance defined between the first rotor and the endplate. 3. The compressor according to claim 1 , further including a fixed bearing supporting the second rotor. 4. The compressor according to claim 1 further including, a second controllable bearing supporting the second rotor, the second controllable bearing being configured to be able to move the second rotor in a manner to reduce or enlarge at least one of a second rotor-to-bore clearance defined between the second rotor and an interior surface of the second bore, a second rotor-to-endplate clearance defined between the second rotor and the endplate, or the rotor-to-rotor clearance. 5. The compressor according to claim 4 , wherein the second controllable bearing is a magnetic bearing. 6. The compressor according to claim 1 , wherein the housing includes an intake port disposed toward an opposite end from the discharge end, a discharge port disposed toward the discharge end, and a compression chamber defined by the helical threads of the first rotor and the second rotor and an interior surface of the housing, the compression chamber being configured to move from the intake port to the discharge port when the first rotor and second rotor rotate, the compression chamber being configured to gradually reduce its volume when moving from the intake port to the discharge port, the compression chamber being configured to change its volume when any of the clearances are changed. 7. The compressor according to claim 1 , further including, a temperature sensor configured to sense a temperature of the compressor, wherein the controller is configured to change the one or more first rotor clearances according to the temperature sensed by the temperature sensor. 8. The compressor according to claim 1 , further including, a position sensor configured to measure at least one of the one or more first rotor clearances, wherein the controller is configured to change any of the one or more first rotor clearances according to the at least one of the one or more first rotor clearances measured by the position sensor. 9. The compressor according to claim 1 , wherein the controllable bearing is a magnetic bearing. 10. A method to control the compressor according to claim 1 , comprising, determining an operation condition of the compressor, setting a clearance value, and controlling the controllable bearing to move the first rotor according to the set clearance value. 11. The method to control the compressor according to claim 10 , wherein the moveable bearing is a magnetic bearing. 12. The method to control the compressor according to claim 10 , wherein the step of determining an operation condition of the compressor further includes sampling a temperature of the compressor, and determining whether the temperature of the compressor is higher than a threshold temperature. 13. The method to control the compressor according to claim 12 , further including changing at least one the one or more first clearances by repositioning the first rotor, when the temperature is higher than the threshold temperature. 14. The method to control the compressor according to claim 10 , further including setting a rotation speed of the first rotor, and operating the first rotor at the set rotation speed. 15. The method to control the compressor according to claim 12 , further including calibrating at least one of the one or more first clearances of the compressor, setting the clearance value at a workable range for start-up, and positioning the at least one of the one or more first clearances at first rotor to the set clearance value. 16. The method to control the compressor according to claim 15 , wherein the step of calibrating the at least one of the one or more clearances of the compressor further includes at least one of: moving the first rotor of the compressor to touch the second rotor of the compressor to measure the rotor-to-rotor clearance, moving the first rotor of the compressor to touch an interior surface of the first bore of the compressor housing to measure a rotor-to-bore clearance, or moving the rotor of the compressor to touch the endplate of the compressor to measure a rotor-to-endplate clearance. 17. The method to control the compressor according to claim 10 , further including changing a rotation speed of the first rotor.