Impeller shroud with slidable coupling for clearance control in a centrifugal compressor

What is claimed is: 1. A compressor shroud assembly in a turbine engine, the compressor shroud assembly comprising: a static compressor casing; an actuator mounted to said casing; and an impeller shroud for encasing a rotatable centrifugal compressor, said impeller shroud coupled at a forward end to said casing by a slidable coupling that maintains an air boundary during the full range of axial movement of said impeller shroud, said impeller shroud mounted proximate an aft end to said actuator, said impeller shroud moving relative to the rotatable centrifugal compressor in an axial direction while maintaining a radial alignment when said actuator is actuated. 2. The compressor shroud assembly of claim 1 , further comprising one or more sensors for measuring the clearance gap between said impeller shroud and the rotatable centrifugal compressor, said actuator being actuated or vented in response to the clearance gap measure by the one or more sensors. 3. The compressor shroud assembly of claim 1 , further comprising one or more sensors for measuring discharge pressure of the rotatable centrifugal compressor, said actuator being activated in response to the measured pressure. 4. The compressor shroud assembly of claim 1 , wherein said actuator is one of a pneumatic, hydraulic, electric, or thermal actuator. 5. The compressor shroud assembly of claim 1 , wherein the actuator is an air piston comprising a chamber adapted to receive actuating air and the actuator further comprises an aft extending mounting arm which moves axially while maintaining a radial alignment when said piston is actuated. 6. A compressor shroud assembly in a turbine engine, the compressor shroud assembly comprising: a static compressor casing; an actuator mounted to said casing; and an impeller shroud comprising a static inducer portion coupled to said casing and a dynamically moveable exducer portion coupled at a forward end to said inducer portion by a slidable coupling that maintains an air boundary during the full range of axial movement of said exducer portion, said exducer portion mounted proximate an aft end to said actuator and moving relative to the rotatable centrifugal compressor in an axial direction while maintaining a radial alignment when said actuator is actuated. 7. The compressor shroud assembly of claim 6 , further comprising one or more sensors for measuring the clearance gap between said impeller shroud and the rotatable centrifugal compressor, said actuator being actuated or vented in response to the clearance gap measure by the one or more sensors. 8. The compressor shroud assembly of claim 6 , further comprising one or more sensors for measuring discharge pressure of the rotatable centrifugal compressor, said actuator being activated in response to the measured pressure. 9. The compressor shroud assembly of claim 6 , wherein said actuator is one of a pneumatic, hydraulic, electric, or thermal actuator. 10. The compressor shroud assembly of claim 6 , wherein the actuator is an air piston comprising a chamber adapted to receive actuating air and the actuator further comprises an aft extending mounting arm which moves axially while maintaining a radial alignment when said piston is actuated. 11. A method of dynamically changing a clearance gap between a rotatable centrifugal compressor and a shroud encasing the rotatable centrifugal compressor, said method comprising: mounting an actuator to a static casing; mounting an impeller shroud to the actuator; coupling a forward end of said impeller shroud to the casing by a slidable coupling; and actuating the actuator to thereby move said impeller shroud relative to a rotatable centrifugal compressor, said impeller shroud moving relative to the rotatable centrifugal compressor in an axial direction while maintaining a radial alignment, wherein the slidable coupling between said impeller shroud and said casing maintains an air boundary during the full range of axial movement of said impeller shroud. 12. The method of claim 11 further comprising sensing the clearance gap between the rotatable centrifugal compressor and said impeller shroud and actuating the actuator in response to the sensed clearance gap. 13. The method of claim 11 further comprising sensing the discharge pressure of the rotatable centrifugal compressor and actuating the actuator in response to the sensed discharge pressure. 14. The method of claim 11 wherein the step of actuating the actuator comprises supplying or discharging high pressure air to an air piston to effect axial motion while maintaining a radial alignment of said impeller shroud.