System injecting gas into a storage tank

The invention claimed is: 1. A storage tank for a fluid, the liquefaction temperature of which is lower than −50° C. under atmospheric pressure, the storage tank has a cylindrical shape around an axis of revolution with a bottom wall, an upper wall and a cylindrical peripheral wall connecting the bottom wall to the upper wall, said storage tank comprising at least one thermal insulation barrier covered with a sealed and corrugated membrane and in such a way that the sealed and corrugated membrane delimits an inner volume of the storage tank; the sealed and corrugated membrane including a plurality of corrugations that are used to delimit a space between said corrugations and the at least one thermal insulation barrier, the storage tank including at least a gas injection system injecting gas into the space, wherein the gas injection system comprises at least one circular pipe spreading around the axis of revolution of the storage tank, said circular pipe being located in the space delimited by the corrugations of the sealed and corrugated membrane of the bottom wall and the thermal insulation barrier, the gas injection system comprising at least one nozzle linked, flow-wise, to the circular pipe and in such a way that the at least one nozzle injects gas beneath the corrugations of the sealed and corrugated membrane. 2. The storage tank as claimed in claim 1 , wherein the gas injection system includes at least one supply system supplying gas to the circular pipe, the supply system comprising at least one distribution ring spreading around the axis of revolution. 3. The storage tank as claimed in claim 2 , wherein the supply system comprises at least one supply pipe extending mainly in the space of the peripheral wall and in such a way that this supply pipe connects, flow-wise, the circular pipe to the distribution ring. 4. The storage tank as claimed in claim 3 , wherein the bottom wall includes a peripheral edge and a center aligned with the axis of revolution of the storage tank, the circular pipe being placed closer to the center of the bottom wall than to the peripheral edge. 5. The storage tank as claimed in claim 4 , wherein the at least one nozzle is injecting gas beneath the corrugations of the sealed and corrugated membrane of the bottom wall and in direction of the peripheral edge. 6. The storage tank as claimed in claim 2 , wherein the bottom wall includes a peripheral edge and a center aligned with the axis of revolution of the storage tank, the circular pipe being placed closer to the center of the bottom wall than to the peripheral edge. 7. The storage tank as claimed in claim 6 , wherein the at least one nozzle is injecting gas beneath the corrugations of the sealed and corrugated membrane of the bottom wall and in direction of the peripheral edge. 8. The storage tank as claimed in claim 6 , wherein the sealed and corrugated membrane is configured in such a way that its corrugations formed at the peripheral wall are in communication, flow-wise, with the corrugations formed at the bottom wall. 9. The storage tank as claimed in claim 7 , wherein the at least one nozzle is adapted to reduce gas pressure at the outlet of said nozzle with respect to gas pressure at the inlet of said nozzle. 10. The storage tank as claimed in claim 1 , wherein the at least one nozzle is placed away from the circular pipe, at a distance ranging from 200 mm to 5000 mm. 11. The storage tank as claimed in claim 1 , wherein the sealed and corrugated membrane, at least, placed on the bottom wall comprises circular corrugations spreading around the axis of revolution of the storage tank and radial corrugations crossing the circular corrugations, and extending in a radial direction of the storage tank, the circular pipe extending at least beneath one of the circular corrugations of the sealed and corrugated membrane. 12. The storage tank as claimed in claim 11 , wherein an injection axis of the at least one nozzle is aligned with a main axis of a radial corrugation of the sealed and corrugated membrane placed on the bottom wall. 13. The tank ( 1 ) as claimed in claim 11 , wherein the gas injection system includes at least one supply system supplying gas to the circular pipe, the supply system comprising at least one distribution ring spreading around the axis of revolution, wherein the supply system comprises at least one supply pipe extending mainly in the space of the peripheral wall and in such a way that this supply pipe connects, flow-wise, the circular pipe to the distribution ring, and wherein the at least one supply pipe is extending in the space beneath one of the radial corrugations of the sealed and corrugated membrane of the bottom wall. 14. The storage tank as claimed in claim 1 , wherein the gas injection system comprises at least one injection device extending within a perimeter delimited by the circular pipe. 15. The storage tank as claimed in claim 14 , wherein the at least injection device comprises at least one additional nozzle placed at one of its ends located inside the perimeter delimited by the circular pipe, said additional nozzle injecting gas at least into the perimeter delimited by the circular pipe. 16. The storage tank as claimed in claim 1 , including a plurality of nozzles placed around the circular pipe and in such a way that each nozzle is distant from one another with respect to an angle ranging between 25° to 70° around the axis of revolution of the storage tank. 17. The storage tank as claimed in claim 1 , comprising at least one extraction system provided with at least one circular extraction pipe which is extending around the axis of revolution of the storage tank, outside of its inner volume, the extraction system including at least one extraction pipe that passes through, at least partly, the peripheral wall of the storage tank up to the thermal insulation barrier, the extraction pipe being linked, flow-wise, to the circular extraction pipe. 18. A process for checking the tightness of a sealed and corrugated membrane of a storage tank as claimed in claim 1 , this process using at least the gas injection system. 19. A process for sweeping at least an insulation volume of a storage tank as described in claim 1 , the process using at least the gas injection system. 20. A process for injecting gas into a space of a storage tank, as described in claim 1 , and according to which gas is injected into the gas injection system in such a way that the gas flows at least inside the circular pipe at a pressure ranging between 170 mbar and 230 mbar and in such a way that gas goes out by at least one nozzle at a pressure ranging between 20 mbar and 30 mbar.