Patent Number: 
Section: claims

1. A facility for reducing radioactive material, the facility comprising:a cooling water storage unit installed inside a containment building and formed to store cooling water, the cooling water storage unit formed by a structure distinguished from a structure forming the containment building;an opening portion formed at an upper wall of the cooling water storage unit to allow an evaporation of the cooling water therethrough;a boundary unit configured to surround a reactor coolant system installed inside the containment building to form a boundary of radioactive material, the boundary unit configured to suppress spreading of the radioactive material released from the reactor coolant system or a pipe connected with the reactor coolant system to an outside of the boundary;a connecting pipe connected with an inner space of the boundary unit and the cooling water storage unit to guide a flow of a fluid caused by a pressure difference between the boundary unit and the cooling water storage unit from the boundary unit to the cooling water storage unit;a sparging unit disposed to be submerged in the cooling water stored in the cooling water storage unit and connected with the connecting pipe to sparge the fluid that has passed through the connecting pipe and the radioactive material contained in the fluid to the cooling water storage unit;wherein an inside of the containment building comprises:a first area corresponding to the inside of the boundary unit; anda second area formed between (1) an inner wall of the containment building and (2) outer walls of the cooling water storage unit and the boundary unit for accommodating fluid that evaporates through the opening portion, and maintaining a pressure balance with the inside of the cooling water storage unit by the opening portion;a cooling water recollecting portion formed at the upper wall of the cooling water storage unit to recollect fluid condensed in the second area to the cooling water storage unit,wherein the first area is isolated from other spaces inside the containment building excluding an inlet of the connecting pipe,wherein the boundary unit, the connecting pipe and the sparging unit collect the radioactive material in the cooling water storage unit before the radioactive material contacts the inner wall of the containment building, andwherein at least a part of the second area is formed above a top of the first area and a top of the cooling water storage unit, the size of the at least a part of the second area is larger than that of the first area so that the flow of the fluid from the first area to the cooling water storage unit is continued by maintaining a pressure difference between the first area and the second area when a loss-of-coolant accident occurs. 2. The facility of claim 1, wherein the cooling water storage unit includes an inlet through which the connecting pipe passes, and wherein the highest part of the connecting pipe is formed at a predetermined height from a bottom of the cooling water storage unit to prevent the cooling water stored in the cooling water storage unit from flowing back to an inside of the boundary unit. 3. The facility of claim 1, further comprising a check valve formed to allow for a flow only in one direction and installed at the connecting pipe to prevent the cooling water in the cooling water storage unit from flowing back to the boundary unit through the connecting pipe. 4. The facility of claim 1, further comprising:a discharging unit installed at the boundary of the radioactive material to form a fluid path that runs from the boundary unit to the containment building and configured to guide a flow of a fluid caused by a pressure difference between the containment building and the boundary unit from the containment building to the boundary unit through the fluid path; anda filter facility installed in the fluid path of the discharging unit to capture the radioactive material contained in the fluid passing through the discharging unit in the boundary unit. 5. The facility of claim 1, wherein at least a portion of the boundary unit is expanded to a region adjacent to the containment building while surrounding a penetration pipe penetrating the containment building to prevent the loss-of-coolant accident from occurring due to breakage of the penetration pipe in a region between the containment building and the boundary unit. 6. The facility of claim 1, wherein the boundary unit forms a sealing structure around the reactor coolant system to prevent release of the radioactive material. 7. The facility of claim 1, wherein at least a portion of the boundary unit is formed by a concrete structure inside the containment building or a coating member installed on the concrete structure. 8. The facility of claim 1, wherein the boundary unit comprises:a barrier formed to surround the reactor coolant system; anda cover formed to cover an upper part of the reactor coolant system and coupled with the barrier. 9. The facility of claim 4, wherein the filter facility comprises at least one of:a filter configured to form iodic silver by reacting silver nitrate with iodine contained in the fluid and formed to remove the iodic silver from the fluid; andan absorbent configured to remove the iodine contained in the fluid through chemisorption that is performed by charcoal. 10. The facility of claim 4, further comprising a cooling water storage unit installed inside the containment building, the cooling water storage unit formed to store cooling water for dissolving the radioactive material. 11. The facility of claim 10, wherein the discharging unit is extended from the boundary unit to an inside of the cooling water storage unit to discharge the fluid into the cooling water storage unit. 12. The facility of claim 1, wherein the cooling water storage unit is connected with a pipe forming a fluid path that runs to a safety injection line of a safety injection system to inject the cooling water stored in the cooling water storage unit to the inside of the reactor coolant system. 13. The facility of claim 1, further comprising an additive injection unit supplying an additive for maintaining a pH of cooling water to a predetermined value or more to prevent volatilization of the radioactive material dissolved in the cooling water storage unit. 14. The facility of claim 13, wherein the additive injection unit is installed at a predetermined height inside the cooling water storage unit to be submerged in the cooling water as a water level of the cooling water storage unit increases, and wherein as the additive injection unit is submerged in the cooling water, the additive is dissolved in the cooling water. 15. The facility of claim 13, wherein the additive injection unit is installed on a fluid path of the cooling water recollecting portion to dissolve the additive in the cooling water recollected to the cooling water recollecting portion. 16. The facility of claim 1, further comprising a sparging unit installed at an end of a discharging unit to be submerged in the cooling water of the cooling water storage unit and configured to sparge a fluid that has passed through the discharging unit, to condense steam and to dissolve soluble radioactive materials in the discharged air contained in the fluid. 17. The facility of claim 1, wherein the sparging unit comprises:a plurality of sparging holes formed to sparge fluid that has passed through the connecting pipe and the radioactive material contained in the fluid; anda plurality of sub fluid paths that run the plurality of sparging holes from the connecting pipe,wherein the sparging unit has a flow resistance therein to induce an even distribution of the fluid into a plurality of sub fluid paths. 18. The facility of claim 1, further comprising a pressure balance line passing through at least a portion of the boundary unit and extended to an inside of the containment building to form a fluid path of atmosphere passing through the boundary of the radioactive material, wherein the pressure balance line, when a pressure inside the containment building is higher than a pressure inside the boundary unit, introduces atmosphere inside the containment building to the inside of the boundary unit to prevent the cooling water in the cooling water storage unit from flowing back to the inside of the boundary unit. 19. The facility of claim 18, further comprising a check valve formed to allow for a flow only in one direction and installed at the pressure balance line to prevent the atmosphere inside the boundary unit from being discharged to the inside of the containment building through the pressure balance line. 20. The facility of claim 1, wherein the cooling water storage unit is connected with a pipe forming a fluid path that runs to a safety injection line of a safety injection system to inject the cooling water stored in the cooling water storage unit to the inside of the reactor coolant system. 21. The facility of claim 4, wherein at least a portion of the boundary unit is expanded to a region adjacent to the containment building while surrounding a penetration pipe penetrating the containment building to prevent the loss-of-coolant accident from occurring due to breakage of the penetration pipe in a region between the containment building and the boundary unit. 22. The facility of claim 4, wherein the boundary unit forms a sealing structure around the reactor coolant system to prevent release of the radioactive material. 23. The facility of claim 4, wherein at least a portion of the boundary unit is formed by a concrete structure inside the containment building or a coating member installed on the concrete structure. 24. The facility of claim 4, wherein the boundary unit comprises:a barrier formed to surround the reactor coolant system; anda cover formed to cover an upper part of the reactor coolant system and coupled with the barrier. 25. The facility of claim 16, wherein the sparging unit has a flow resistance therein to induce an even distribution of the fluid into a plurality of sub fluid paths. 26. The facility of claim 10, further comprising a pressure balance line passing through at least a portion of the boundary unit and extended to an inside of the containment building to form a fluid path of atmosphere passing through the boundary of the radioactive material, wherein the pressure balance line, when a pressure inside the containment building is higher than a pressure inside the boundary unit, introduces atmosphere inside the containment building to the inside of the boundary unit to prevent the cooling water in the cooling water storage unit from flowing back to the inside of the boundary unit.