Actuation arrangement

We claim as our invention: 1. A cryostat comprising: a cryogen-cooled vessel contained inside of an OVC, with a thermal radiation shield also inside of the OVC that shields the cryogen-cooled vessel from radiant heat from the OVC, said cryogen-cooled vessel having an actuatable component attached thereto that requires application of a force thereto in order to actuate the actuatable component; an actuator device attached to said OVC; a first push rod that extends through said OVC so as to be movable toward and away from said thermal radiation shield; a second push rod mounted at said thermal radiation shield so as to be movable toward and away from said actuatable component, and having a bias in a direction away from said actuatable component; an actuator rod mounted to said actuatable component so as to protrude from said actuatable component into a space between said thermal radiation shield and said cryogen-cooled vessel; said actuator device being operable to move said first push rod into mechanical engagement with said second push rod, to thereby move said second push rod, against said bias, into mechanical engagement with said actuator rod in order to thereby apply said force and actuate said actuatable component; and said actuator device being operable, after said actuatable device is actuated, to move said first push rod away from said second push rod, thereby causing said bias to separate said second push rod from said actuator rod. 2. A cryostat according to claim 1 wherein the second push-rod traverses the thermal radiation shield through a hole in the radiation shield, and wherein said assembly comprises a thermally conductive path between the second push-rod and the thermal radiation shield. 3. A cryostat according to claim 2 wherein the cryogenically-cooled device is attached to an exterior surface of the cryogen cooled vessel, and so an entirety of said actuator rod is in said space between said thermal radiation shield and said cryogen-cooled vessel. 4. A cryostat according to claim 2 comprising a mount for the second push-rod in said hole that comprises a mechanical bias element that produces said bias. 5. A cryostat according to claim 4 wherein said mount comprises solid insulation between the OVC and the thermal radiation shield, the solid insulation surrounding the second push-rod in said hole. 6. A cryostat according to claim 1 comprising a mount adapted to attach the actuator device to an exterior surface of the OVC. 7. A cryostat according to claim 1 wherein the actuator device is adapted to be mounted onto an access hatch forming part of the OVC. 8. A cryostat according to claim 1 comprising a polymer seal adapted to seal the first push-rod to the OVC. 9. A cryostat according to claim 1 wherein the actuator device comprises an output tube adapted to proceed through the OVC, and a polymer seal adapted to said seal the output tube to the OVC, said first push rod being movable in said output tube toward and away from said second push rod. 10. A cryostat according to claim 1 wherein the actuator device comprises an output tube adapted to proceed through the OVC, and a bellows adapted to said seal the output tube to the OVC, said first push rod being movable in said output tube toward and away from said second push rod. 11. A cryostat according to claim 1 wherein the actuatable component is mounted inside the cryogen-cooled vessel, and so the actuator rod is adapted to protrude through a hole in the cryogen-cooled vessel. 12. A cryostat according to claim 11 comprising a bellows surrounding the actuator rod adapted to seal the actuator rod to the cryogen vessel. 13. A cryostat according to claim 1 wherein the first push-rod, the second push-rod and the actuator rod are constructed of resin-impregnated fiber glass.