Underwater remote cooling apparatus

We claim: 1. A cooling apparatus for an underwater platform comprising: an evaporator block fabricated from a thermally conductive material and having a first surface that is shaped so as to releasably mate to an exterior surface contour of the underwater platform; a heat pipe having a working fluid sealed therein, wherein the heat pipe has a first end and a second end, and wherein the first end is in thermal communication with the evaporator block; a condenser block in thermal communication with the second end of the heat pipe, wherein the condenser block is held in ambient water away from the surface of the underwater platform by the heat pipe; and a plurality of spring clamps mounted to the evaporator block and configured to bias the first surface of the evaporator block against the exterior surface of the underwater platform such that heat from the exterior surface of the underwater platform is transferred to the ambient water via the evaporator block, heat pipe, and condenser block. 2. The cooling apparatus of claim 1 , further comprising heat sink fins connected to the condenser block and in physical contact with the ambient water. 3. The cooling apparatus of claim 2 , further comprising a thermal interface material disposed between the condenser block and the heat pipe and between the evaporator block and the heat pipe. 4. The cooling apparatus of claim 3 , further comprising an evaporator interface material being elastic and electrically-non-conductive and disposed between the evaporator block and the surface of the underwater platform. 5. The cooling apparatus of claim 4 , wherein the underwater platform is a remotely operated vehicle (ROV). 6. The cooling apparatus of claim 4 , wherein the underwater platform is stationary equipment located on a seafloor. 7. The cooling apparatus of claim 6 , wherein the data center is buried beneath the seafloor and the condenser block is disposed above the seafloor. 8. The cooling apparatus of claim 5 , wherein the ROV comprises a cylindrical pressure vessel to which the evaporator block is releasably mated, wherein the cylindrical pressure vessel shrinks as external pressure increases as the ROV descends through the ambient water, and wherein the plurality of spring clamps continues to bias the first surface of the evaporator block against the exterior surface of the underwater platform as the ROV moves through the water. 9. The cooling apparatus of claim 1 , wherein the underwater platform is a hydraulic cylinder. 10. The cooling apparatus of claim 1 , further comprising an insulating layer surrounding the underwater platform and the evaporator block. 11. The cooling apparatus of claim 4 , wherein the evaporator block comprises: a first half; a second half bolted to the first half; and a cylindrical bore formed at the interface of the first and second halves, in which the heat pipe, surrounded by a thermal interface material, is disposed such that as the first and second halves are being bolted together the heat pipe is clamped in the cylindrical bore and the thermal interface material surrounding the heat pipe is sandwiched between the first and second halves and the heat pipe. 12. A cooling apparatus for an underwater platform comprising: an evaporator block fabricated from a thermally conductive material and having a first surface that is shaped so as to releasably mate to an exterior surface contour of the underwater platform; a heat pipe having a working fluid sealed therein, wherein the heat pipe has a first end and a second end, and wherein the first end is in thermal communication with the evaporator block; a condenser block in thermal communication with the second end of the heat pipe, wherein the condenser block is held in ambient water away from the surface of the underwater platform by the heat pipe; a plurality of spring clamps mounted to the evaporator block and configured to bias the first surface of the evaporator block against the exterior surface of the underwater platform such that heat from the exterior surface of the underwater platform is transferred to the ambient water via the evaporator block, heat pipe, and condenser block; and wherein no part of the cooling apparatus extends into an interior space of the underwater platform. 13. The cooling apparatus of claim 12 , further comprising heat sink fins connected to the condenser block and in physical contact with the ambient water. 14. The cooling apparatus of claim 13 , further comprising a non-electrically-conductive, thermal interface material disposed between the condenser block and the heat pipe. 15. The cooling apparatus of claim 14 , further comprising a non-electrically-conductive, elastic evaporator interface material disposed between the evaporator block and the surface of the underwater platform so as to electrically isolate the evaporator block and the underwater platform to prevent galvanic corrosion. 16. The cooling apparatus of claim 15 , wherein the non-electrically-conductive, elastic evaporator interface material consists of an elastomer matrix, a conductive filler material, and a layer of reinforcing fiberglass skin. 17. The cooling apparatus of claim 16 , wherein the heat pipe is made of a copper-nickel alloy and the working fluid is selected from the group consisting of: water, methanol, ammonia, sodium, and mercury. 18. The cooling apparatus of claim 12 , wherein the heat pipe comprises two separate heat pipes joined together with a junction block. 19. The cooling apparatus of claim 13 , wherein the underwater platform is an autonomous underwater vehicle (AUV) and wherein the condenser block is disposed with respect to the AUV so as to trail behind the AUV.