Turbocharger control linkage with reduced heat flow

Now that the invention has been described, I claim: 1. A turbocharger including an electric actuator unit connected internally within a turbocharger housing ( 1 ) connected to a variable turbine geometry mechanism via an axially extending control linkage, wherein the axially extending control linkage includes a shaft and a rod end, and wherein at least one of the shaft and the rod ends is provided with a plurality of cooling fins along at least one axial segment thereof cooling fins. 2. The turbocharger as in claim 1 , wherein said cooling fins are axially spaced radially outwardly projecting cooling fins extending generally perpendicular to the axis of the linkage. 3. The turbocharger as in claim 2 , wherein said cooling fins are generally annular cooling fins. 4. The turbocharger as in claim 1 , wherein said cooling fins are longitudinally extending fins extending parallel to the longitudinal axis of the control linkage. 5. The turbocharger as in claim 1 , wherein said control linkage comprises a center section having first and second ends and one rod end respectively connected to each center section end via a threaded connection, wherein said cooling fins are provided on both rod ends. 6. The turbocharger as in claim 1 , wherein said control linkage comprises a center section having first and second ends and one rod-end respectively connected to each center section end via a threaded connection, wherein said cooling fins are provided on said center section. 7. A turbocharger including an electric actuator unit connected internally within a turbocharger housing ( 1 ) connected to a variable turbine geometry mechanism via an axially extending control linkage, wherein the axially extending control linkage includes a shaft and a rod end, and wherein at least one of the shaft and the rod ends is provided with at least one hollow segment having a plurality of cooling fins. 8. The turbocharger of claim 7 , wherein said control linkage is formed of a material having a thermal conductivity of not more than 7.2 (W/(m*K)). 9. A turbocharger including: a turbocharger housing ( 1 ); an electric actuator unit ( 10 ) attached to the turbocharger housing ( 1 ), the electric actuator unit ( 10 ) including an actuator drive arm ( 12 ); at least one of a variable turbine-geometry mechanism; a control linkage including a drive-end rod end ( 15 ) and a driven-end rod end ( 7 ) connected directly to each other or connected via an intermediate center section, each rod end ( 15 , 7 ) including a cylindrical section ( 20 ) and a head section ( 3 ) divided by a transition plane ( 19 ), with a ball ( 8 ) constrained but free to rotate in the head ( 3 ), wherein each ball includes a bore ( 9 ); a drive pin ( 14 ) extending from the actuator shaft ( 11 ) into the bore ( 9 ) in the ball ( 8 ) in the drive-end rod end ( 15 ); a driven pin ( 6 ) extending from the bore ( 9 ) in the ball ( 8 ) in the driven-end rod end ( 7 ) and connected for driving the variable turbine geometry mechanism; wherein a surface area of the control linkage between the transition planes ( 19 ) is at least 1.4 times that of a baseline surface area; wherein the baseline surface area is calculated using a model control linkage; wherein the model control linkage comprises a drive-end rod end ( 15 ) and a driven-end rod end ( 7 ), the rod ends connected via a shaft ( 16 ), each rod end ( 15 , 7 ) including a cylindrical section ( 20 ) and the head section ( 3 ) divided by a transition plane ( 19 ), with a ball ( 8 ) constrained but free to rotate in the head section ( 3 ), wherein each ball includes a bore ( 9 ); wherein the model control linkage has the same centerline length as the control linkage, wherein the centerline length is the distance from the center of the ball ( 8 ) of the drive-end rod end ( 15 ) to the center of the ball ( 8 ) of the driven-end rod end ( 7 ); wherein a diameter of the shaft of the model control linkage is the same as a diameter of the bore ( 9 ) of the control linkage; wherein the lengths and diameter of the cylindrical sections ( 20 ) of the rod ends of the model control linkage are determined as follows: Calc. length Length from from Ball end to Transition Head Barrel bore centerline plane to end Diameter diameter Descriptor B A C D J Rod end 5 5 27 18 18 9 Rod end 6 6 30 20 20 11 Rod end 8 8 36 25 24 14 Rod end 10 10 43 30 28 17 Rod end 12 12 50 35 32 19 Rod end 14 14 57 40 36 22 Rod end 16 16 64 46 42 29 Rod end 20 20 77 54 50 32 and wherein the surface area of the model control linkage is measured between the transition planes ( 19 ). 10. The turbocharger as in claim 9 , wherein a flat or hexagonal wrench-receiving feature are is ignored in computing an effective heat radiating surface area of the control linkage and model control linkage. 11. The turbocharger as in claim 9 , wherein the surface area of the control linkage between the transition planes ( 19 ) is at least 1.40 times that of a baseline surface area. 12. The turbocharger as in c