Cryogenic storage system

What is claimed is: 1. A storage system for storing a cryogenic medium, the storage system comprising: a storage container to receive a cryogenic medium; and a thermo-acoustic production system that includes: at least one thin pipe projecting from outside the storage container into the storage container for closure at an end thereof facing away from the storage container and opening at another end thereof in the storage container; and a shut-off valve on the at least one thin pipe to regulate pressure in the storage container by being moveable between an open operating state in which the at least one thin pipe is in fluidic communication with the cryogenic medium in the storage container to thereby generate pressure based on thermo-acoustic oscillations in the at least one thin pipe, and a closed operating state in which the at least one thin pipe is not in fluidic communication with the cryogenic medium in of the storage container to thereby prevent thermo-acoustic oscillations in the at least one thin pipe. 2. The storage system of claim 1 , wherein the storage container comprises double walls including an inner wall and an outer wall, and an insulating vacuum space between the inner wall and an outer wall. 3. The storage system of claim 2 , wherein the end of the at least one thin pipe facing away from the storage container is located outside the insulating vacuum space and the at least one thin pipe extends through the insulating vacuum space and opens in the storage container. 4. The storage system of claim 1 , wherein the end of the at least one thin pipe facing away from the storage container comprises at least one heat transfer area having a plurality of pipe ribs to transfer heat from the at least one thin pipe. 5. The storage system of claim 1 , wherein the end of the at least one thin pipe facing away from the storage container comprises a heat transmitter to transmit heat to the at least one thin pipe. 6. The storage system of claim 5 , wherein the heat transmitter is to transmit heat to the at least one thin pipe by passing air and/or a cooling fluid. 7. The storage system of claim 1 , wherein the at least one thin pipe has a maximum internal diameter of 6 mm. 8. The storage system of claim 1 , wherein a length of the at least one thin pipe outside the storage container is at least 200 mm. 9. The storage system of claim 8 , wherein a ratio of a total length to an internal diameter of the at least one thin pipe is at least 800:1. 10. The storage system of claim 1 , wherein the at least one thin pipe comprises a thermal insulation pipe portion arranged in the insulating vacuum space to provide thermally insulation. 11. The storage system of claim 1 , wherein a region of the at least one thin pipe arranged inside the storage container has an internal diameter that is less than a region of the at least one thin pipe arranged outside the storage container. 12. The storage system of claim 1 , wherein a region of the at least one thin pipe arranged inside the storage container has a diameter that tapers towards a region of the at least one thin pipe arranged outside the storage container. 13. A storage system for storing a cryogenic medium, the storage system comprising: a storage container to receive the cryogenic medium; and a thermo-acoustic production system that includes: a plurality of thin pipes projecting from outside the storage container into the storage container, each thin pipe in the plurality of thin pipes being closed at an end thereof facing away from the storage container and being open at another end thereof located in the storage container; and a common valve block having a plurality of shut-off valves to regulate pressure in the storage container, each thin pipe in the plurality of thin pipes being in fluidic communication with a corresponding shut-off valve in the plurality of shut-off valves, each corresponding shut-off valve being moveable between an open operating state in which a corresponding thin pipe is in fluidic communication with the cryogenic medium in the storage container to thereby generate pressure based on thermo-acoustic oscillations in the corresponding thin pipe, and a closed operating state in which the corresponding thin pipe is not in fluidic communication with the cryogenic medium in the storage container to thereby prevent thermo-acoustic oscillations in the corresponding thin pipe. 14. The storage system of claim 13 , wherein the storage container comprises double walls including an inner wall and an outer wall, and an insulating vacuum space between the inner wall and an outer wall. 15. The storage system of claim 14 , wherein the end of each thin pipe that faces away from the storage container is located outside the insulating vacuum space, and each thin pipe respectively extends through the insulating vacuum space and opens in the storage container. 16. The storage system of claim 13 , wherein the end of each thin pipe that faces away from the storage container comprises at least one heat transfer area having a plurality of pipe ribs to transfer heat therefrom. 17. The storage system of claim 13 , wherein the end of each thin pipe that faces away from the storage container comprises a heat transmitter to transmit heat thereto. 18. The storage system of claim 17 , wherein the heat transmitter is to transmit heat to the thin pipe by passing air and/or a cooling fluid. 19. The storage system of claim 13 , wherein each thin pipe comprises a thermal insulation pipe portion arranged in the insulating vacuum space to provide thermally insulation. 20. A storage system, comprising: a storage container to store a cryogenic medium; and a thermo-acoustic production system that includes: a plurality of thin pipes projecting from outside the storage container into the storage container; and a common valve block having a plurality of shut-off valves to regulate pressure in the storage container, each thin pipe in the plurality of pipes being in fluidic communication with a corresponding shut-off valve in the plurality of shut-off valves, each corresponding shut-off valve being moveable between an open operating state in which a corresponding thin pipe is in fluidic communication with the cryogenic medium in the storage container to thereby generate pressure based on thermo-acoustic oscillations in the corresponding thin pipe, and a closed operating state in which the corresponding thin pipe is not in fluidic communication with the cryogenic medium in the storage container to thereby prevent thermo-acoustic oscillations in the corresponding thin pipe.