Source of electricity derived from a spent fuel cask

What is claimed is: 1 . A spent nuclear fuel storage container comprising: a canister for storing irradiated nuclear fuel; and a heat engine in heat transfer relationship with the canister for converting a differential in heat between the latent heat of the stored nuclear fuel and an ambient environment into electrical or mechanical power. 2 . The spent nuclear fuel storage container of claim 1 including: an outer cask surrounding the canister with an annular space there-between; an air intake through a lower end of the cask extending from outside the cask to the annular space; an air outlet through an upper end of the cask extending from the annular space to the outside of the cask; and wherein the heat engine is in heat transfer relationship with the annular space. 3 . The spent nuclear fuel storage container of claim 2 wherein the heat transfer relationship is implemented through a heat transfer medium to transport heat from the annular space to an exterior of the outer cask. 4 . The spent nuclear fuel storage container of claim 3 wherein the heat transfer medium is a heat pipe. 5 . The spent nuclear fuel storage container of claim 2 wherein the heat engine is selected from a Rankine cycle engine, a Sterling cycle engine and a thermoelectric device. 6 . The spent nuclear fuel storage container of claim 5 wherein the thermoelectric device is supported within the annular space on an outer surface of the canister. 7 . The spent nuclear fuel storage container of claim 6 wherein the thermoelectric device is supported at an elevation substantially between the air inlet and the air outlet. 8 . The spent nuclear fuel storage container of claim 7 wherein the thermoelectric device is supported substantially midway between the air inlet and the air outlet. 9 . The spent nuclear fuel storage container of claim 1 wherein the heat engine has an electrical output that is connected to a coolant circulation system operable to cool a coolant. 10 . The spent nuclear fuel storage container of claim 9 including an outer cask surrounding the canister with an annular space there-between and a coolant flow path between the canister and cask and through the cask to the exterior thereof, with the coolant circulation system circulating a fluid coolant between an interior of the annular space and an exterior of the cask. 11 . The spent nuclear fuel storage container of claim 9 wherein the coolant circulation system cools the fluid within a spent fuel pool of a nuclear power plant. 12 . The spent nuclear fuel storage container of claim 1 wherein the electric power forms an emergency auxiliary power source for a nuclear power plant. 13 . The spent nuclear storage container of claim 1 including: a fluid circulation system for circulating a cooling fluid over at least a portion of a circumference of the canister, the fluid circulation system having a fluid inlet and a fluid outlet which extends through a shield cask that surrounds the canister; and a fluid baffle system in fluid communication with the fluid outlet which is supported on the shield cask, wherein the heat engine is supported, at least in part, in the fluid baffle system in heat exchange relationship with the fluid exhausted from the fluid outlet. 14 . The spent nuclear fuel storage container of claim 13 , wherein the fluid baffle system is a substantially annular passage that fits around or on the shield cask. 15 . The spent nuclear fuel storage container of claim 14 , wherein the fluid baffle system is supported from an upper portion of the shield cask. 16 . The spent nuclear fuel storage container of claim 14 wherein the fluid baffle system has an inlet that is substantially hermetically sealed to the fluid outlet. 17 . The spent nuclear fuel storage container of claim 13 wherein the fluid circulation system has a plurality of fluid outlets circumferentially spaced around the shield cask and the fluid baffle system is in fluid communication with at least several of the fluid outlets, including a perforated plate supported within the fluid baffle system, in fluid communication with the fluid outlet, the perforated plate extending at least partially through the fluid baffle system for distributing the fluid over a fluid path through the baffle system. 18 . The spent nuclear fuel storage container of claim 13 wherein the heat engine is a plurality of thermoelectric generators that are supported through a fluid path through the fluid baffle system. 19 . The spent nuclear fuel storage container of claim 18 wherein fins extend on the outside of fluid baffle system to promote heat transfer. 20 . The spent nuclear fuel storage container of claim 13 wherein the fluid baffle system has a fluid path that extends vertically in a serpentine course.