Patent Number: 048620076
Section: claims

1. A thermal protection shell for protecting the exterior walls of a container used for containing heat generating toxic materials, characterized by a shell of heat conductive material which circumscribes and engages the exterior container walls in heat-conducting contact under ambient temperature conditions, wherein the thermal coefficient of expansion of the shell is greater than the thermal coefficient of expansion of the outer container walls so that the heat-conducting contact between the shell and the outer walls is substantially broken when the shell is exposed to an exterior source of thermal radiation that raises the temperature of the shell above a selected temperature, and the material forming the shell is fusible near said selected temperature so that the ablation of the shell also serves to obstruct the transmission of heat from the source of thermal radiation to the container walls. 2. A thermal protection shell as defined in claim 1, wherein the thermal coefficient of expansion of the material forming the container walls is about half of the thermal coefficient of expansion of the material forming the shell. 3. A thermal protection shell as defined in claim 1, wherein the value of the thermal coefficient of expansion of the container walls and the shell is between about 5 to 7.times.10.sup.6 inches/degrees F. and 11 to 14.times.10.sup.6 inches/degrees F., respectively. 4. A thermal protection shell as defined in claim 1, wherein the outer walls of the container are formed from an alloy containing iron, and said shell is substantially formed from one metal of the group consisting of aluminum and magnesium. 5. A thermal protection shell as defined in claim 1, wherein the inner surface of the shell expands out of contact with the outer surface of the outer container walls an average of at least two mils when the shell is exposed to exterior thermal radiation above a selected limit. 6. A thermal protection shell as defined in claim 1, wherein said selected temperature is about 800 degrees F. 7. A thermal protection shell as defined in claim 1, wherein said container walls are approximately four inches thick, and said shell is approximately one-half inches thick. 8. A thermal protection shell as defined claim 1, wherein said container comprises means for transporting heat generating radioactive waste. 9. A thermal protection shell as defined in claim 1, wherein said shell is formed from a plurality of interconnectable sections. 10. A thermal protection shell for protecting a radioactive waste container of the type which conducts and dissipates heat generated by the decay of radioactive wastes through heat conductive walls, characterized by a shell of heat conductive metal which substantially covers and engages the exterior of the container walls in heat-conducting contact under ambient temperature conditions so as not to obstruct the dissipation of the decay heat, wherein the thermal coefficient of expansion of the metallic shell is greater than the coefficient of expansion of the outer walls waste container so that said heat-conducting contact between said shell and said outer walls is substantially broken when the shell is exposed to an external source of thermal radiation that raises its temperature above a selected temperature, and the material forming the shell is fusible near said selected temperature so that the ablation of the shell also serves to obstruct the transmission of heat from the source of thermal radiation to the container walls. 11. A thermal protection shell for protecting a radioactive waste container as defined in claim 10, wherein the outer container walls are formed from steel, and said shell is formed from an alloy of one of the group consisting of aluminum and magnesium. 12. A thermal protection shell for protecting a radioactive waste container as defined in claim 10, wherein the thermal coefficient of expansion of the material forming the outer container walls is about half of the thermal coefficient of expansion of the material forming the shell. 13. A thermal protection shell for protecting a radioactive waste container as defined in claim 10, wherein the inner surface of the shell expands away from the outer surface of the outer walls of the container an average of at least two mils when the shell is exposed to exterior thermal radiation above a selected limit. 14. A thermal protection shell for protecting a radioactive waste container as defined in claim 10, wherein said shell is formed from a plurality of mutually adjacent sections that are rigidly interconnected along their edges. 15. A thermal protection shell for protecting a radioactive waste container as defined in claim 14, further including connecting assemblies for rigidly interconnecting the edges of mutually adjacent shell sections. 16. A thermal protection shell for protecting a radioactive waste container as defined in claim 16, wherein said connecting assemblies include an adjustment means for adjusting the distance between said edges so that said shell can accommodate containers of different sizes. 17. A thermal protection shell for protecting a radioactive waste container as defined in claim 10, wherein said shield is approximately one-half of an inch thick, and further functions to protect said container from mechanical shock. 18. A thermal protection shell for protecting a radioactive waste container as defined in claim 10, wherein said selected temperature is 1000 degrees F. 19. A thermal protection shell for protecting a container for transporting radioactive waste of the type that conducts and dissipates heat generated by the decay of radioactive wastes through walls formed at least in part by stainless steel, characterized by a shell formed of an alloy from one of the group consisting of magnesium and aluminum which circumscribes and engages the exterior of the container walls in heat-conducting contact under ambient temperature conditions so as not to obstruct the dissipation of the decay heat into the ambient atmosphere, wherein the difference between the thermal coefficient of expansion between the stainless steel container walls and the shell causes the interior surface of the shell to disengage the exterior surface of the container when the shell is exposed to a source of thermal energy which heats it to a temperature of over 800 degrees F. so that a gap is created between the shell and the container that obstructs the transmission of thermal energy from the source to the container, wherein said shell is formed from a plurality of mutually adjacent sections that are rigidly interconnected along their edges, and further including connecting assemblies for rigidly interconnecting the edges of mutually adjacent shell sections, wherein each of said connecting assemblies include an adjustment means for adjusting the distance between said edges so that said shell can accommodate containers of different sizes. 20. A thermal protection shell for protecting a container for transporting radioactive waste as defined in claim 19, wherein each of said connecting assemblies includes a nut and bolt means for securing said mutually adjacent edges together, and a second and third nut threadedly engaged to the bolt means for adjusting and fixing the distance between said mutually adjacent edges. 21. A method for installing a thermal protection shell around a container for transporting radioactive waste of the type that conducts and dissipates heat generated by the wastes through external metallic walls wherein said shell has an interior that is substantially complementary in shape to the exterior of the container and is formed by a plurality of mutually adjacent sections which are rigidly interconnectable along their edges by connecting assemblies that include adjustment means for adjusting the distance between said edge of said sections, comprising the steps of: a. positioning said shell sections over the exterior walls of the container so that the edges of said sections are mutually adjacent to one another;  b. interconnecting said sections along their mutually adjacent edges with said connecting assemblies, and  c. adjusting the adjusting means of said connecting assemblies so that the distance between the mutually adjacent edges of the sections is short enough to draw the complementary interior of the shell formed by the sections into heat conducting contact with the exterior walls of the container, yet not so short as to create tensile forces between the edge which would substantially interfere with the thermal expansion of the shell interior out of heat-conducting contact with the exterior walls of the container upon the heating of the shell to a temperature above 800 degrees F.