Patent Number: 
Section: claims

1. A drying apparatus for drying a cavity of a canister loaded with a spent nuclear fuel, the drying apparatus comprising:the canister having the cavity provided with a gas inlet port and a gas outlet port;a non-reactive gas source configured to store a non-reactive gas to be supplied to the cavity of the canister;a first gas circulation pump which is mounted on a first gas circulation line which connects the canister and the non-reactive gas source to communicate with each other, to feed the non-reactive gas supplied from the non-reactive gas source to the canister;a valve member which is mounted on the first gas circulation line between the first gas circulation pump and the canister to open or close the first gas circulation line;a heater which is mounted on the first gas circulation line between the valve member and the canister to heat the non-reactive gas to be supplied to the canister;a gas cooling unit which is fluidly coupled to the canister through a second gas circulation line to cool the non-reactive gas discharged from the cavity of the canister;a dew point temperature measuring member which is mounted on a third gas circulation line, which connects the gas cooling unit and the reactive gas source to communicate each other, to repeatedly measure a dew point temperature of the non-reactive gas;a second gas circulation pump which is mounted on the third gas circulation line to feed the non-reactive gas, which passes through the gas cooling unit, to the non-reactive gas source;a controller which is electrically connected to the first and second gas circulation pumps and the dew point temperature measuring member to control an operating state of the first and second gas circulation pumps and the dew point temperature measuring member;a fourth gas circulation line which is branched from the second gas, to fluidly connect the gas cooling unit and the canister, separately from the second gas circulation line, so as to transfer a contaminated non-reactive gas, which is discharged from the canister, to the gas cooling unit;a branched valve member which is mounted on a branched point, from which the second and fourth gas circulation lines are branched, to selectively open or close the second or fourth gas circulation line;a fifth gas circulation line which is fluidly coupled to the fourth gas circulation line to fluidly connect the gas cooling unit and the non-reactive gas source;a particle filter which is mounted on the fifth gas circulation line to remove particles contained in the contaminated non-reactive gas which is transferred along the fifth gas circulation line after the non-reactive gas passing the fourth gas circulation line is cooled by the gas cooling unit;a third gas circulation pump which is mounted on the fifth gas circulation line to feed the non-reactive gas, which is cooled by the gas cooling unit, to the non-reactive gas source; anda radiation dosimeter which is installed outside the second gas circulation line between the canister and the branched valve member to measure a radiation dose rate of the non-reactive gas which is discharged from the canister and is transferred along the second gas circulation line, and to send a measured signal to the controller, whereinthe controller is electrically connected to the radiation dosimeter, the branched valve member, the dew point temperature measuring member, and the third gas circulation pump, respectively, to determine whether or not the non-reactive gas discharged from the canister is contaminated, according to the measured radiation dose rate received from the radiation dosimeter; if it is determined that the non-reactive gas is contaminated, the controller closes the second gas circulation line, and opens the fourth gas circulation line, so that the contaminated non-reactive gas discharged from the canister circulates along the fourth, fifth and first gas circulation lines; and if it is determined that the non-reactive gas is not contaminated, the controller closes the fourth gas circulation line, and opens the second gas circulation line, so that the non-contaminated non-reactive gas discharged from the canister circulates along the second, third and first gas circulation lines. 2. The drying apparatus for drying the canister loaded with the spent nuclear fuel according to claim 1, wherein the branched valve member is an electronic valve, andthe radiation dosimeter is electrically connected to the controller to send the signal to the controller, so that the controller controls the operation of the branched valve member and the first to third gas circulation pumps according to the received signal. 3. In a drying apparatus for drying a cavity of a canister loaded with a spent nuclear fuel, the drying apparatus includingthe canister having the cavity provided with a gas inlet port and a gas outlet port;a non-reactive gas source configured to store a non-reactive gas to be supplied to the cavity of the canister;a first gas circulation pump which is mounted on a first gas circulation line which connects the canister and the non-reactive gas source to communicate with each other, to feed the non-reactive gas supplied from the non-reactive gas source to the canister;a valve member which is mounted on the first gas circulation line between the first gas circulation pump and the canister to open or close the first gas circulation line;a heater which is mounted on the first gas circulation line between the valve member and the canister to heat the non-reactive gas to be supplied to the canister;a gas cooling unit which is fluidly coupled to the canister through a second gas circulation line to cool the non-reactive gas discharged from the cavity of the canister;a dew point temperature measuring member which is mounted on a third gas circulation line, which connects the gas cooling unit and the reactive gas source to communicate each other, to repeatedly measure a dew point temperature of the non-reactive gas;a second gas circulation pump which is mounted on the third gas circulation line to feed the non-reactive gas, which passes through the gas cooling unit, to the non-reactive gas source;a fourth gas circulation line which is branched from the second gas, to fluidly connect the gas cooling unit and the canister, separately from the second gas circulation line, so as to transfer a contaminated non-reactive gas, which is discharged from the canister, to the gas cooling unit;a branched valve member which is mounted on a branched point, from which the second and fourth gas circulation lines are branched, to selectively open or close the second or fourth gas circulation line;a fifth gas circulation line which is fluidly coupled to the fourth gas circulation line to fluidly connect the gas cooling unit and the non-reactive gas source;a particle filter which is mounted on the fifth gas circulation line to remove particles contained in the contaminated non-reactive gas which is transferred along the fifth gas circulation line after the non-reactive gas passing the fourth gas circulation line is cooled by the gas cooling unit;a third gas circulation pump which is mounted on the fifth gas circulation line to feed the non-reactive gas, which is cooled by the gas cooling unit, to the non-reactive gas source;a radiation dosimeter which is installed outside the second gas circulation line between the canister and the branched valve member to measure a radiation dose rate of the non-reactive gas which is discharged from the canister and is transferred along the second gas circulation line, and to send a measured signal to the controller; anda controller which is electrically connected to the first to third gas circulation pumps, the branched valve member, the dew point temperature measuring member, and the radiation dosimeter, respectively, to determine whether or not the non-reactive gas discharged from the canister is contaminated, according to the measured radiation dose rate received from the radiation dosimeter, and to control an operating state of the branched valve member and the first to third gas circulation pumps according to the determination result,a method for controlling the drying apparatus which dries the cavity of the canister by circulating the non-reactive gas discharged from the canister along a non-contaminated non-reactive gas circulation system or a contaminated non-reactive gas circulation system according to the contaminated or non-contaminated state of the non-reactive gas, the control method comprising:a reference radiation dose rate setting step of setting a reference radiation dose rate to determine whether the non-reactive gas is contaminated or not;a non-reactive gas feeding step of feeding the non-reactive gas to the cavity of the canister through the first gas circulation line;a radiation dose rate measuring step of measuring the radiation dose rate of the non-reactive gas transferred along the second gas circulation line at the non-reactive gas outlet port of the canister;a non-reactive gas contamination determining step of determining whether the non-reactive gas is contaminated or not, on the basis of that the radiation dose rate of the non-reactive gas measured at the radiation dose rate measuring step reaches the predetermined reference value;if it is determined at the non-reactive gas contamination determining step that the non-reactive gas is not contaminated, a non-contaminated non-reactive gas circulation step of opening the non-contaminated non-reactive gas circulation system, and closing the contaminated non-reactive gas circulation system, so that the non-contaminated non-reactive gas circulates along the non-contaminated non-reactive gas circulation system;if it is determined at the non-reactive gas contamination determining step that the non-reactive gas is contaminated, a contaminated non-reactive gas circulation step of opening the contaminated non-reactive gas circulation system, and closing the non-contaminated non-reactive gas circulation system, so that the contaminated non-reactive gas circulates along the contaminated non-reactive gas circulation system. 4. The method for controlling the drying apparatus of drying the cavity of the canister loaded with the spent nuclear fuel according to claim 3, wherein the non-contaminated non-reactive gas circulation system is a circulation line including the first to third gas circulation lines, andthe contaminated non-reactive gas circulation system is a circulation line including the first, second, fourth and fifth gas circulation lines. 5. In a drying apparatus for drying a cavity of a canister loaded with a spent nuclear fuel, the drying apparatus includingthe canister having the cavity provided with a gas inlet port and a gas outlet port;a non-reactive gas source configured to store a non-reactive gas to be supplied to the cavity of the canister;a first gas circulation pump which is mounted on a first gas circulation line which connects the canister and the non-reactive gas source to communicate with each other, to feed the non-reactive gas supplied from the non-reactive gas source to the canister;a valve member which is mounted on the first gas circulation line between the first gas circulation pump and the canister to open or close the first gas circulation line;a heater which is mounted on the first gas circulation line between the valve member and the canister to heat the non-reactive gas to be supplied to the canister;a gas cooling unit which is fluidly coupled to the canister through a second gas circulation line to cool the non-reactive gas discharged from the cavity of the canister;a dew point temperature measuring member which is mounted on a third gas circulation line, which connects the gas cooling unit and the reactive gas source to communicate each other, to repeatedly measure a dew point temperature of the non-reactive gas;a second gas circulation pump which is mounted on the third gas circulation line to feed the non-reactive gas, which passes through the gas cooling unit, to the non-reactive gas source;a fourth gas circulation line which is branched from the second gas, to fluidly connect the gas cooling unit and the canister, separately from the second gas circulation line, so as to transfer a contaminated non-reactive gas, which is discharged from the canister, to the gas cooling unit;a branched valve member which is mounted on a branched point, from which the second and fourth gas circulation lines are branched, to selectively open or close the second or fourth gas circulation line;a fifth gas circulation line which is fluidly coupled to the fourth gas circulation line to fluidly connect the gas cooling unit and the non-reactive gas source;a particle filter which is mounted on the fifth gas circulation line to remove particles contained in the contaminated non-reactive gas which is transferred along the fifth gas circulation line after the non-reactive gas passing the fourth gas circulation line is cooled by the gas cooling unit;a third gas circulation pump which is mounted on the fifth gas circulation line to feed the non-reactive gas, which is cooled by the gas cooling unit, to the non-reactive gas source;a radiation dosimeter which is installed outside the second gas circulation line between the canister and the branched valve member to measure a radiation dose rate of the non-reactive gas which is discharged from the canister and is transferred along the second gas circulation line, and to send a measured signal to the controller; anda controller which is electrically connected to the first to third gas circulation pumps, the branched valve member, the dew point temperature measuring member, and the radiation dosimeter, respectively, to determine whether or not the non-reactive gas discharged from the canister is contaminated, according to the measured radiation dose rate received from the radiation dosimeter, and to control an operating state of the branched valve member and the first to third gas circulation pumps according to the determination result, in which the cavity of the canister is dried by circulating the non-reactive gas through the first to third gas circulation lines or the first, second, fourth and fifth gas circulation lines which are connected to the canister, the gas cooling unit and the non-reactive gas source,a radiation shielding geometry which is configured to house the radiation dosimeter of the drying apparatus to accurately measure the radiation dose rate of a target object, without being influenced by peripheral environment of the radiation dosimeter, the radiation shielding geometry comprising:a body which is a block having a radiation dosimeter assembling hole which penetrates through front and rear surfaces, and is provided with symmetrical assembling grooves on top and bottom surfaces, left and right surfaces or all surfaces, respectively;a plurality of shield plate members, each being a flat plate, and having an assembling protrusion protruding from a top surface, and an assembling groove formed on a bottom surface to be recessed in parallel with the assembling protrusion, in which the assembling protrusion of the shield plate member is detachably assembled to the assembling groove of the body, so that the body is sequentially assembled to the shield plate member; anda support stand configured to support the radiation shielding geometry, and having an assembling rod at an upper end, of which the assembling rod has the same cross-sectional shape as the assembling protrusion of the shield plate member, on top and bottom surfaces thereof to be symmetrically. 6. The radiation shielding geometry for housing the radiation dosimeter of the drying apparatus according to claim 5, wherein the shield plate member is an L-shaped bent plate, and has an assembling protrusion protruding from a top surface, and an assembling groove formed on a bottom surface to be recessed in parallel with the assembling protrusion. 7. The radiation shielding geometry for housing the radiation dosimeter of the drying apparatus according to claim 5, wherein the assembling groove of the body and the assembling groove of the shield plate member are dovetail grooves, andthe assembling protrusion of the shield plate member is a dovetail protrusion. 8. The radiation shielding geometry for housing the radiation dosimeter of the drying apparatus according to claim 5, wherein the body, the shield plate member and the assembling rod of the support stand have through-holes which coaxially penetrate the components, anda fixing pin is fitted into the respective through-holes of the body, the shield plate member and the assembling rod of the support stand which are assembled to each other to arrange the through-holes in a straight line, to maintain the assembled state thereof. 9. The radiation shielding geometry for housing the radiation dosimeter of the drying apparatus according to claim 5, further comprising:a plurality of assembling holes formed on each corner of both end faces of the body; anda pipe shield block which is a rectangular block, and has a plurality of assembling pins protruding from each corner of the end face in parallel with each other and detachably fitted into the assembling holes, and a pipe receiving groove which is recessed on the end face having the assembling pins, so that the target pipe is detachably assembled to the body in a state in which the pipe is received in the pipe receiving groove.