Patent Number: 
Section: claims

1. An induction heating stress improvement method in a nuclear power plant including a recirculation inlet nozzle having an annular clearance, the recirculation inlet nozzle including an inner surface of piping having a fluid therein, the method comprising:providing a header tank comprising at least one cooling nozzle and a thermometer;installing the at least one cooling nozzle of a header tank within a range in a clockwise direction from one of a point at −45° from a horizontal position at 9 o'clock to a point at +45° from a horizontal position at 9 o'clock or a point at −45° from a horizontal position at 3 o'clock to a point at +45° from a horizontal position at 3 o'clock within the annular clearance of the recirculation inlet nozzle,supplying cooling water by the cooling nozzle to the inner surface of piping of the recirculation inlet nozzle, andverifying a cooling effect with respect to the inner surface of the piping by measuring a temperature of the fluid in the piping that has been raised by external heating of the recirculation inlet nozzle when applying the induction heating stress improvement method to the piping, andwherein an installation position of the thermometer is deviated from that of the cooling nozzle of the header tank in the peripheral direction by installing the thermometer within a range in a clockwise direction from a point at −45° from a position at 12 o'clock to a point at +45° from a position at 12 o'clock within the annular clearance of the recirculation inlet nozzle. 2. An induction heating stress improvement method in a recirculation inlet nozzle of primary loop recirculation piping in a nuclear power plant, the recirculation inlet nozzle having an annular clearance and the piping having a fluid therein, the method comprising:providing a header tank comprising at least one cooling nozzle,installing the at least one cooling nozzle of a header tank within a range in a clockwise direction from one of a point at −45° from a horizontal position at 9 o'clock to a point at +45° from a horizontal position at 9 o'clock or a point at −45° from a horizontal position at 3 o'clock to a point at +45° from a horizontal position at 3 o'clock within an annular clearance of the recirculation inlet nozzle, about the center of the annular clearance in the horizontal direction, to thereby promote a cooling effect,supplying cooling water by the cooling nozzle to an inner surface of the piping,verifying a cooling effect with respect to the inner surface of the piping by measuring a fluid temperature of the fluid in the piping that has been raised by external heating of the piping when applying the induction heating stress improvement method to the piping, andinstalling a thermometer in the annular clearance of the recirculation inlet nozzle,the fluid temperature being measured by using the thermometer, andan installation position of the thermometer is deviated from that of the cooling nozzle of the header tank in the peripheral direction by installing the thermometer within a range in a clockwise direction from a point at −45° from a position at 12 o'clock to a point at +45° from a position at 12 o'clock within the annular clearance of the recirculation inlet nozzle. 3. An induction heating stress improvement method in a nozzle portion of a nuclear reactor pressure vessel for a nuclear power plant, the nozzle portion including an annular clearance and an inner surface of piping having a fluid therein, the method comprising:installing the least one cooling nozzle of a header tank within a range in a clockwise direction from one of a point at −45° from a horizontal position at 9 o'clock to a point at +45° from a horizontal position at 9 o'clock or a point at −45° from a horizontal position at 3 o'clock to a point at +45° from a horizontal position at 3 o'clock within an annular clearance of the nozzle portion;supplying cooling water by the cooling nozzle to the nozzle portion andverifying a cooling effect of the nozzle portion by measuring a fluid temperature of the fluid in the piping when applying the induction heating stress improvement method to the nozzle portion, or when performing preliminary heating, or before executing the induction heating stress improvement method, whereinthe fluid temperature is measured by using the thermometer, and whereinan installation position of the thermometer is deviated from that of the cooling nozzle of the header tank in the peripheral direction by installing the thermometer within a range in a clockwise direction from a point at −45° from a position at 12 o'clock to a point at +45° from a position at 12 o'clock within the annular clearance of the nozzle portion.