Patent Number: 
Section: claims

1. A container device for the long-term storage of hazardous material, particularly for the ultimate disposal of nuclear fuel, comprisingat least one elongate, cylindrical first containment body having a casing wall and end walls, the casing wall and the end walls defining a first compartment for accommodating at least one hazardous-material body formed by the hazardous material or containing or supporting the hazardous material, the first compartment comprising support means for supporting the hazardous-material body centrally in the first compartment and spaced from the casing wall and the end walls,an elongate, cylindrical second containment body having a casing wall and end walls, the casing wall and the end walls defining a cylindrical second compartment, the second compartment comprising support means for supporting the first containment body centrally in the second containment body and spaced from the casing wall and the end walls of the second containment body, andpassages provided in at least one of the end walls of each of the first and second containment bodies for the introduction of wet concrete in the first and second compartments for filling the space between, as regards the first containment body, the hazardous-material body and the walls defining the first compartment, and, as regards the second containment body, the space between the first containment body and the walls defining the second compartment. 2. A container device according to claim 1, comprisingan elongate, cylindrical third containment body having a casing wall and end walls, the casing wall and the end walls defining a cylindrical third compartment, the third compartment comprising support means for supporting the second containment body centrally in the third containment body and spaced from the casing wall and the end walls of the third containment body, andpassages provided in at least one of the end walls of the third containment body for the introduction of wet concrete in the third compartment for filling the space between the second containment body and the walls defining the third compartment. 3. A container device according to claim 2, comprisingan elongate, cylindrical fourth containment body having a casing wall and end walls, the casing wall and the end walls defining a cylindrical fourth compartment, the fourth compartment comprising support means for supporting the third containment body centrally in the fourth containment body and spaced from the casing wall and the end walls of the fourth containment body, andpassages provided in at least one of the end walls of the fourth containment body for the introduction of wet concrete in the fourth containment body for filling the space between the third containment body and the walls defining the fourth compartment. 4. A method for manufacturing a container device for the ultimate disposal of nuclear fuel elements arranged in a fuel assembly, comprising the steps of:introducing and fixing the nuclear fuel elements in a defined position in an essentially cylindrical container, wherein a length of the cylindrical container is substantially larger than a length of the nuclear fuel elements, and wherein a space is provided between the nuclear fuel elements and between a side and end walls of the cylindrical container, andembedding the nuclear fuel elements throughout the length thereof and at ends thereof in a casting compound which casting compound fills completely the space between the nuclear fuel elements and the side and end walls of the cylindrical container and between the individual nuclear fuel elements, wherein the embedding step includes the steps of forcing the casting compound into the container under a pressure in the range of 10 to 50 bar through one of the end walls, and discharging excess casting compound through one of an opposite end wall or the same end wall. 5. A method according to claim 4, in which the container is in an underwater position during the introduction of the nuclear fuel elements in the container and during the embedding of the nuclear fuel elements in the casting compound. 6. A method for manufacturing a container device for the long-term storage of hazardous material included in an elongate hazardous-material body, comprising the steps of:placing the hazardous-material body in an elongate, cylindrical first containment body having a casing wall and end walls, and fixing the hazardous-material body in a defined central position in the containment body which is spaced from the casing walls and the end walls of the containment body,embedding the hazardous-material body in the first containment body throughout a length thereof and at ends thereof in concrete, including the steps of introducing the concrete through one of the end walls and causing the concrete to completely fill the space between the hazardous-material body and the inside of the first containment body,placing the first containment body with the embedded hazardous-material body embedded therein in an elongate, cylindrical second containment body having a casing wall and end walls, and fixing the first containment body in a defined central position in the second containment body which is spaced from the casing and the end walls of the second containment body, andembedding the first containment body throughout a length thereof and at ends thereof in concrete, including the steps of introducing the concrete through one of the end walls of the second containment body and causing the concrete to fill completely the space between the first containment body and the inside of the second containment body. 7. A method according to claim 6, comprising the further steps of:placing the second containment body with the embedded first containment body therein in an elongate, cylindrical third containment body having a casing wall and end walls, and fixing the second containment body in a defined central position in the third containment body which is spaced from the casing and the end walls of the third containment body, andembedding the second containment body in the third containment body throughout a length thereof and at ends thereof in concrete, including the steps of introducing the concrete through one of the end walls of the third containment body and causing the concrete to fill completely the space between the second containment body and the inside of the third containment body. 8. A method according to claim 6, in which the embedding takes place under water. 9. A method according to claim 6, wherein the introducing the concrete into the first containment body through one of the end walls thereof takes place at a pressure of the concrete in the range of 10 to 50 bar. 10. A method according to claim 6, wherein the introducing the concrete into the first containment body through one of the end walls thereof takes place at a pressure of the concrete in the range of 10 to 50 bar, and wherein the introducing the concrete into the second containment body through one of the end walls thereof takes place at a pressure of the concrete in the range of 10 to 50 bar. 11. A method according to claim 7, wherein the introducing the concrete into the first containment body through one of the end walls thereof takes place at a pressure of the concrete in the range of 10 to 50 bar, and wherein the introducing the concrete into the third containment body through one of the end walls thereof takes place at a pressure of the concrete in the range of 10 to 50 bar. 12. A method according to claim 4, in which the casting compound is concrete.