Patent Number: 054901880
Section: claims

1. For use in association with a vessel belonging to a nuclear steam supply system, the vessel having a first tubular member disposed therein surrounding a second tubular member, the first tubular member and the second tubular member defining a gap therebetween having moisture residing therein, a system for evaporating the moisture from the gap, comprising: (a) gas supply means in communication with the gap for supplying a gas to the gap; and  (b) dryer means in communication with said gas supply means for drying the gas supplied to the gap.  (a) a gas compressor in communication with the gap for supplying a gas to the gap at a predetermined volumetric flow rate; and  (b) a dryer in communication with said gas compressor for drying the gas.  (a) a first conduit having a first end portion in communication with the first open end of the tube and having a second end portion;  (b) an air compressor connected to the second end portion of said first conduit for supplying air through said first conduit, into the tube and to the gap at a predetermined volumetric flow rate;  (c) a dryer connected to said air compressor, said dryer having an adsorbent desiccant therein for drying the air supplied by said air compressor;  (d) a heater connected to said air compressor for heating the air supplied to the gap by said air compressor, so that the air is heated to a predetermined temperature and so that the moisture residing in the gap evaporates into the heated gas as the air is heated to the predetermined temperature, the moisture evaporated into the heated air having a dew point temperature;  (e) a second conduit having a first end portion connected to the second open end of the tube and having a second end portion; and  (f) a vacuum pump connected to the second end portion of said second conduit for reducing the pressure of the air in the gap to decrease the dew point temperature to a predetermined dew point temperature, so that substantially all the moisture residing in the gap evaporates into the heated air as the dew point temperature decreases to the predetermined dew point temperature.  (a) wherein said air compressor supplies the heated air to said first conduit at the predetermined volumetric flow rate of approximately 1,400 cubic feet per minute;  (b) wherein said heater heats the air in said first conduit to the predetermined temperature of approximately 300.degree. F.; and  (c) wherein said vacuum pump reduces the pressure in the gap to decrease the dew point temperature to the predetermined dew point temperature of approximately 0.degree. F., whereby substantially all the moisture in the gap evaporates as the air compressor supplies the air at the predetermined volumetric flow rate, as the heater heats the air to the predetermined temperature and as the vacuum pump decreases the dew point temperature to the predetermined dew point temperature.  (a) a pressure indicator in communication with the heated air for indicating the pressure of the heated air; and  (b) a dew point temperature indicator in communication with the heated air for indicating the dew point temperature of the heated air.  (a) supplying a gas to the gap by operating a gas compressor in communication with the gap; and  (b) drying the gas supplied to the gap by operating a dryer in communication with the gas compressor.  (a) connecting a first end portion of a first conduit to the first open end of the tube, the first conduit having a second end portion;  (b) supplying air through the first conduit, into the tube and to the gap at a predetermined volumetric flow rate by connecting the second end portion of the first conduit to an air compressor and operating the air compressor;  (c) drying the air supplied to the gap by operating a dryer connected to the air compressor, the dryer having an adsorbent desiccant therein for drying the air;  (d) heating the air supplied to the tube and to the gap, so that the air is heated to a predetermined temperature and so that the moisture residing in the gap evaporates into the heated air, the moisture evaporated into the heated air having a dew point temperature;  (e) connecting a first end portion of a second conduit to the second open end of the tube, the second conduit having a second end portion; and  (f) decreasing the dew point temperature to a predetermined dew point temperature by reducing the pressure of the heated air in the gap by operating a vacuum pump connected to the second end portion of the second conduit, so that substantially all the moisture residing in the gap evaporates into the heated gas.  (a) wherein said step of supplying the air to the first conduit at the predetermined volumetric flow rate comprises the step of supplying the air to the first conduit at the predetermined flow rate of approximately 1,400 cubic feet per minute;  (b) wherein said step of heating the air in the first conduit to the predetermined temperature comprises the step of heating the air to the predetermined temperature of approximately 300.degree. F.; and  (c) wherein said step of decreasing the dew point temperature comprises the step of decreasing the dew point temperature to the predetermined dew point temperature of approximately 0.degree. F., whereby substantially all the moisture in the gap evaporates as the air compressor supplies the air at the predetermined volumetric flow rate, as the heater heats the air to the predetermined temperature and as the vacuum pump decreases the dew point temperature to the predetermined dew point temperature.  (a) indicating the pressure of the heated air in the tube by operating a pressure indicator in communication with the heated air; and  (b) indicating the dew point temperature of the heated air in the tube by operating a temperature indicator in communication with the heated air. 2. The system of claim 1, further comprising heater means in communication with said gas supply means for heating the gas supplied to the gap, so that the moisture residing in the gap evaporates into the heated gas. 3. The system of claim 1, further comprising vacuum means in communication with the gap for decreasing the pressure of the heated gas in the gap, so that substantially all the moisture evaporates from the gap and into the heated gas. 4. For use in association with a heat exchanger vessel belonging to a nuclear steam supply system, the heat exchanger vessel having a heat transfer tube disposed therein surrounding a sleeve, the tube and the sleeve defining an annular gap therebetween having moisture residing therein, a system for evaporating the moisture from the gap, comprising: 5. The system of claim 4, further comprising a heater in communication with said gas compressor for heating the gas supplied to the gap, so that the gas is heated to a predetermined temperature and so that the moisture residing in the gap evaporates into the heated gas as the gas is heated to the predetermined temperature, the moisture evaporated into the heated gas having a dew point temperature. 6. The system of claim 4, further comprising a vacuum pump in communication with the gap for reducing the pressure of the heated gas in the gap to decrease the dew point temperature to a predetermined dew point temperature, so that substantially all the moisture residing in the gap evaporates into the heated gas as the dew point temperature decreases to the predetermined dew point temperature. 7. The system of claim 4, further comprising a pressure indicator in communication with the heated gas in the gap for indicating the pressure of the heated gas in the gap. 8. The system of claim 4, further comprising a temperature indicator in communication with the heated gas in the gap for indicating the temperature of the heated gas in the gap. 9. For use in association with a heat exchanger vessel belonging to a nuclear steam supply system, the heat exchanger vessel having a heat transfer tube disposed therein surrounding a repair sleeve engaging the tube, the tube and the sleeve defining an annular gap therebetween having moisture residing therein, the tube having a first open end and a second open end, a system for evaporating the moisture from the gap to prepare the sleeve for welding to the tube, the system comprising: 10. The system of claim 9, 11. The system of claim 9, further comprising: 12. For use in association with a vessel belonging to a nuclear steam supply system, the vessel having a first tubular member disposed therein surrounding a second tubular member, the first tubular member and the second tubular member defining a gap therebetween having moisture residing therein, a method of evaporating the moisture from the gap, comprising the steps of: 13. The method of claim 12, further comprising the step of heating the gas supplied to the gap by operating a heater in communication with the gas compressor, so that the moisture residing in the gap evaporates into the heated gas as the gas is heated. 14. The method of claim 12, further comprising the step of decreasing the pressure of the gas in the gap by operating a vacuum pump in communication with the gap, so that substantially all the moisture residing in the gap evaporates into the heated gas. 15. The method of claim 12, further comprising the step of indicating the pressure of the heated gas in the gap by operating a pressure indicator in communication with the heated gas in the gap; 16. The method of claim 12, further comprising the step of indicating the temperature of the heated gas in the gap by operating a temperature indicator in communication with the heated gas in the gap. 17. For use in association with a heat exchanger vessel belonging to a nuclear steam supply system, the heat exchanger vessel having a heat transfer tube disposed therein surrounding a repair sleeve engaging the tube, the tube and the sleeve defining an annular gap therebetween having moisture residing therein, the tube having a first open end and a second open end, a method of evaporating the moisture from the gap to prepare the sleeve for welding to the tube, the method comprising the steps of: 18. The method of claim 17, 19. The method of claim 17, further comprising the steps of: