Machine system having submersible pumping system, and method

What is claimed is: 1. A machine system comprising: a machine; a fluid storage vessel; an outlet conduit coupled with the fluid storage vessel and structured to convey a fluid stored within the fluid storage vessel to the machine; a pumping system positioned within the fluid storage vessel so as to be submerged within the stored fluid, the pumping system including a housing having formed therein a pumping chamber, and a pumping element movable within the pumping chamber to transition the stored fluid from the fluid storage vessel to the outlet conduit; the pumping system further including a drive mechanism for actuating the pumping element, the drive mechanism including an electromagnetic element having an electrical conducting state above a critical temperature and an electrical superconducting state at or below the critical temperature; the drive mechanism further including a temperature control jacket forming a heat exchange cavity about the electromagnetic element; and a cooler coupled with the temperature control jacket and structured to pump heat from the heat exchange cavity to maintain the electromagnetic element at or below the critical temperature, wherein the cooler includes a first heat exchange element within the heat exchange cavity, and a second heat exchange element outside the heat exchange cavity and structured to pump heat to a fluid storage volume of the fluid storage vessel, and the cooler is structured to pump heat from the first heat exchange element to the second heat exchange element. 2. The system of claim 1 wherein cooling fluid is resident within the heat exchange cavity. 3. The system of claim 2 wherein the cooling fluid includes liquid nitrogen, and wherein the stored fluid is resident within the fluid storage volume of the fluid storage vessel and includes a cryogenic fluid other than liquid nitrogen. 4. The system of claim 1 further comprising a pressure relief valve coupled with the temperature control jacket and adjustable between a first state where the heat exchange cavity is in fluid communication with the fluid storage volume of the fluid storage vessel, and a second state where the heat exchange cavity is blocked from fluid communication with the fluid storage volume. 5. The system of claim 1 wherein the electromagnetic element includes an electromagnetic coil within the heat exchange cavity. 6. The system of claim 5 wherein the drive mechanism includes a linear electric motor having a stator that includes the electromagnetic coil. 7. The system of claim 1 wherein the temperature control jacket is double walled and includes a vacuum space between an inner wall of the double wall and an outer wall of the double wall, and wherein the heat exchange cavity is fluidly sealed from the fluid storage volume of the fluid storage vessel. 8. The system of claim 1 wherein the machine includes a combustion engine, and the fluid storage vessel includes a cryogenic fuel storage vessel structured for containing a cryogenic fluid hydrocarbon fuel for fueling the engine, and further comprising a vaporizer positioned fluidly between the fluid storage vessel and the combustion engine. 9. A submersible pumping system comprising: a housing having a pumping chamber positioned fluidly between a pumping inlet and a pumping outlet; a pumping element movable within the pumping chamber to transition a fluid from the pumping inlet to the pumping outlet; a drive mechanism for actuating the pumping element, and including an electromagnetic element having an electrical conducting state above a critical temperature, and an electrical superconducting state at or below the critical temperature; the drive mechanism further including a temperature control jacket forming a heat exchange cavity about the electromagnetic element; and a cooler coupled with the temperature control jacket and structured to pump heat from the heat exchange cavity to maintain the electromagnetic element at or below the critical temperature, wherein the cooler includes a first heat exchange element within the heat exchange cavity, and a second heat exchange element outside the heat exchange cavity and structured to pump heat to a fluid storage volume of a fluid storage vessel, and the cooler is structured to pump heat from the first heat exchange element to the second heat exchange element. 10. The system of claim 9 wherein the drive mechanism includes a linear electric motor, and the electromagnetic element includes an electromagnetic coil of the linear electric motor positioned within the heat exchange cavity. 11. The system of claim 10 wherein the linear electric motor further includes a second electromagnetic element inductively coupled with the first electromagnetic element, and wherein the temperature control jacket envelops the first electromagnetic element but not the second electromagnetic element. 12. The system of claim 9 wherein the temperature control jacket is double walled and includes a vacuum space between an inner wall of the double wall and an outer wall of the double wall. 13. The system of claim 12 further comprising a pressure relief valve coupled with the temperature control jacket and adjustable between a first state where the heat exchange cavity is in fluid communication with an ambient environment external to the temperature control jacket, and a second state where the heat exchange cavity is blocked from the ambient environment. 14. A method of operating a fluid system comprising: pumping heat from a coolant in heat transference contact with a drive mechanism of a pumping system submerged in a stored fluid within a storage vessel in the fluid system; cooling an electromagnetic element of the drive mechanism by way of the pumping of the heat from an ambient temperature of the stored fluid to or below a critical temperature of a material forming the electromagnetic element; energizing the electromagnetic element while cooled to or below the critical temperature; and pumping the heat from the coolant into the stored fluid by way of a cooler having a first heat exchange element in heat transference contact with the coolant and a second heat exchange element in heat transference contact with the stored fluid. 15. The method of claim 14 wherein the coolant is within a temperature control jacket enveloping the electromagnetic element. 16. The method of claim 14 wherein the stored fluid includes cryogenic fluid hydrocarbon fuel. 17. The method of claim 16 further comprising moving a second electromagnetic element coupled with a pumping element in the pumping mechanism to pump the cryogenic fluid hydrocarbon fuel from the storage vessel to a fluid conduit coupled with an internal combustion engine.