Linear actuator for a variable-geometry member of a turbocharger, and a turbocharger incorporating same

What is claimed is: 1. A vacuum-operated linear actuator for a variable-geometry member of a turbocharger, comprising: an enclosure having a first end wall and an opposite second end wall spaced apart along an axial direction, and a flexible diaphragm within the enclosure, the enclosure and diaphragm cooperating to define an interior chamber for supporting a fluid pressure differential across the diaphragm; a piston that is metallic and has a cup-shaped configuration having a bottom wall connected to the diaphragm and a side wall extending from the bottom wall toward the first end wall of the enclosure; a spring engaged between the first end wall of the enclosure and the piston for biasing the piston and the diaphragm in a direction opposite the fluid pressure differential across the diaphragm; an actuator rod connected to the piston and the diaphragm and extending axially and penetrating through the second wall of the enclosure; a sensor assembly comprising a permanent magnet and a sensor each fixedly mounted with respect to the enclosure and proximate the first end wall of the enclosure, and a non-magnetized metallic flux modifier mounted on the piston, the flux modifier extending axially between a proximal end proximate the first end wall to a distal end proximate the piston, movement of the diaphragm and piston resulting in movement of the flux modifier, said movement of the flux modifier causing an alteration of the magnetic field of the magnet, said alteration of the magnetic field being sensed by the sensor, which produces an output signal indicative of the magnetic field; a slide-pivot bearing mounted at the first end wall of the enclosure and receiving the flux modifier, the slide-pivot bearing permitting the flux modifier to move axially and to pivot relative to the enclosure; and an articulated joint connecting the flux modifier to the bottom wall of the piston, the articulated joint permitting pivotal movement of the flux modifier relative to the piston. 2. The actuator of claim 1 , wherein the sensor comprises a Hall effects sensor. 3. The actuator of claim 1 , wherein the flux modifier is contained in a carrier, the carrier having a proximal end proximate the first end wall of the enclosure and an opposite distal end proximate the piston. 4. The actuator of claim 3 , wherein the articulated joint comprises a socket member affixed to the bottom wall of the piston and defining a socket, and an end portion of the carrier that is received in the socket. 5. The actuator of claim 4 , further comprising a crimping member affixed to the bottom wall of the piston, the socket member being crimped by the crimping member. 6. The actuator of claim 4 , wherein an end portion of the actuator rod extends into an interior of the socket, and further comprising a resilient biasing member disposed between the end portion of the actuator rod and a surface of the carrier, the biasing member exerting an axial pre-load on the carrier. 7. The actuator of claim 1 , wherein the flux modifier is connected to the piston by a flexible member that flexes to allow the flux modifier to pivot relative to the piston. 8. A turbocharger having a variable-geometry mechanism, the turbocharger comprising: a compressor wheel and a turbine wheel mounted on a common shaft, the compressor wheel being disposed in a compressor housing and the turbine wheel being disposed in a turbine housing, the turbine housing defining passages for receiving exhaust gas, directing the exhaust gas to the turbine wheel, and discharging the exhaust gas from the turbine housing; a variable-geometry member operable to regulate flow of exhaust gas through the turbine housing; and a vacuum-operated linear actuator coupled with the variable-geometry member and operable to cause movement of the variable-geometry member, the linear actuator comprising: an enclosure having a first end wall and an opposite second end wall spaced apart along an axial direction, and a flexible diaphragm within the enclosure, the enclosure and diaphragm cooperating to define an interior chamber for supporting a fluid pressure differential across the diaphragm; a piston that is metallic and has a cup-shaped configuration having a bottom wall connected to the diaphragm and a side wall extending from the bottom wall toward the first end wall of the enclosure; a spring engaged between the first end wall of the enclosure and the piston for biasing the piston and the diaphragm in a direction toward the second end wall of the enclosure; an actuator rod connected to the piston and the diaphragm and extending axially and penetrating through the second wall of the enclosure; a sensor assembly comprising a permanent magnet and a sensor each fixedly mounted with respect to the enclosure and proximate the first end wall of the enclosure, and a non-magnetized metallic flux modifier mounted on the piston, the flux modifier extending axially between a proximal end proximate the first end wall to a distal end proximate the piston, movement of the diaphragm and piston resulting in movement of the flux modifier, said movement of the flux modifier causing an alteration of the magnetic field of the magnet, said alteration of the magnetic field being sensed by the sensor, which produces an output signal indicative of the magnetic field; a slide-pivot bearing mounted at the first end wall of the enclosure and receiving the flux modifier, the slide-pivot bearing permitting the flux modifier to move axially and to pivot relative to the enclosure; and an articulated joint connecting the flux modifier to the bottom wall of the piston, the articulated joint permitting pivotal movement of the flux modifier relative to the piston. 9. The turbocharger of claim 8 , wherein the sensor comprises a Hall effects sensor. 10. The turbocharger of claim 8 , wherein the flux modifier is contained in a carrier, the carrier having a proximal end proximate the first end wall of the enclosure and an opposite distal end proximate the piston. 11. The turbocharger of claim 10 , wherein the articulated joint comprises a socket member affixed to the bottom wall of the piston and defining a socket, and an end portion of the carrier that is received in the socket. 12. The turbocharger of claim 11 , further comprising a crimping member affixed to the bottom wall of the piston, the socket member being crimped by the crimping member. 13. The turbocharger of claim 11 , wherein an end portion of the actuator rod extends into an interior of the socket, and further comprising a resilient biasing member disposed between the end portion of the actuator rod and a surface of the carrier, the biasing member exerting an axial pre-load on the carrier. 14. The turbocharger of claim 8 , wherein the flux modifier is connected to the piston by a flexible member that flexes to allow the flux modifier to pivot relative to the piston.