Patent Number: 044180357
Section: claims

1. In a nuclear power reactor having a fuel core and a sensor positioned within a body of reactor coolant in thermal contact with an outer sheath of the sensor to establish a heat sink for a body of the sensor internally heated by gamma radiation and having thermal resistance regions formed therein within spaced measurement zones and a thermocouple device extending through said heated body having at least two spaced junctions in each of the measurement zones producing differential signal voltages of one polarity in response to uniform cooling of the outer sheath by the body of coolant in the reactor, the improvement residing in one of the junctions in each of the measurement zones being located vertically above the other of the junctions to produce a differential signal voltage opposite in polarity to said one polarity in response to depletion of the body of reactor coolant to a level below said one of the junctions, and voltage monitoring means connected to the spaced junctions in each of the measurement zones for indicating coolant condition in the reactor. 2. The combination as defined in claim 1 wherein said thermocouple device includes an electrically grounded cladding enclosing the spaced junctions, said voltage monitoring means including first voltage indicating means connected across said spaced junctions for measuring heat flow rate in the heated body and second voltage indicating means connected between ground and said one of the junctions for measuring sensor temperature. 3. The improvement as defined in claim 2 including alarm means connected to the spaced junctions for indicating loss of coolant in response to a polarity reversal of the voltage across said spaced junctions. 4. The improvement as defined in claim 3 wherein said one of the junctions is located in spaced adjacency above the thermal resistance region in each of the measurement zones. 5. The improvement as defined in claim 1 wherein said one of the junctions is located in spaced adjacency above the thermal resistance region in each of the measurement zones. 6. The improvement as defined in claim 1 including electrical heating means embedded within the body for selectively increasing the internal heating thereof. 7. In a nuclear power reactor having a fuel core and a gamma sensor positioned within a body of reactor coolant in thermal contact therewith, said sensor having a thermocouple device provided with spaced junctions and means connected thereto for registering a differential signal voltage, the improvement residing in location of the junctions relative to each other producing a reversal in polarity of the differential signal voltage in response to depletion of the body of coolant to a level below one of the junctions, and means connected to said spaced junctions for monitoring heat transfer conditions externally of the sensor. 8. The improvement as defined in claim 5 wherein said one of the junctions is faster responding than the other of the junctions and is positioned above the other of the junctions. 9. The improvement as defined in claim 8 wherein said sensor includes a thermal resistance region axially aligned with the other of the junctions below the faster responding junction. 10. The improvement as defined in claim 7 wherein said monitoring means includes indicator means for detecting loss of reactor coolant in response to said reversal in polarity of the differential signal voltage. 11. The improvement as defined in claim 7 including electrical heating means embedded in the sensor for selectively increasing the differential signal voltage. 12. In a combination with a nuclear power reactor having an elongated, coolant containing vessel provided with a dome at an upper end thereof, and a lower end through which an elongated sensor is inserted for monitoring power generated by a fuel core positioned within the vessel in spaced relation below the dome, the improvement comprising means projecting into the dome for protectively enclosing the sensor extended vertically into the dome from the fuel core, and means connected to the sensor for monitoring heat transfer conditions of coolant within the dome. 13. The improvement as defined in claim 12 wherein said sensor includes a gamma radiation heated body and a thermocouple device embedded therein, to which the monitoring means is connected for monitoring both the heat transfer conditions and power generated within the fuel core. 14. The improvement as defined in claim 13 wherein said protective enclosing means is provided with openings through which the sensor is externally exposed to coolant throughout within the dome. 15. The improvement as defined in claim 14 wherein said thermocouple device includes at least two spaced temperature measuring junctions connected to the monitoring means and located within the dome, one of said two junctions responding more rapidly to changes in heat flow through the heated body of the sensor than the other of the junctions, said faster responding one of the junctions being located vertically above the other of the junctions to produce a reversal in polarity of voltage across the junctions as measured by the monitorng means in response to depletion of the coolant to a level below said faster responding one of the junctions. 16. The improvement as defined in claim 12, wherein said sensor includes a gamma radiation heated body and a thermocouple device embedded therein having at least two spaced temperature measuring junctions connected to the monitoring means and located within the dome, one of said two junctions responding more rapidly to changes in heat flow through the heated body of the sensor than the other of the junctions, said faster responding one of the junctions being located vertically above the other of the junctions to produce a reversal in polarity of voltage across the junctions as measured by the monitoring means in response to depletion of the coolant to a level below said faster responding one of the junctions. 17. In a nuclear power reactor having a fuel core and sensor means positioned within a body of liquid coolant in thermal contact therewith, said sensor means including vertically spaced thermocouple junctions, the improvement residing in a liquid level monitor comprising means connected to said junctions for indicating a differential signal voltage therebetween in response to depletion of said body of liquid coolant below at least one of the junctions, heater means mounted adjacent to the sensor means for increasing said differential signal voltage to a triggering level, and alarm means connected to said indicating means for registering coolant loss in response to the differential signal voltage above said triggering level. 18. The combination of claim 18 wherein a differential voltage of opposite polarity is developed at said thermocouple junctions when the liquid coolant is in thermal contact with both of said junctions to monitor local power distribution. 19. In combination with a power distribution sensor for the fuel core of a nuclear power reactor having a body of coolant, the sensor including a gamma radiation heated body, in heat transfer relation to the coolant, within which a varying temperature distribution is established, thermoouple junctions mounted within the body at spaced locations, and monitoring means connected to said thermocouple junctions for measuring temperature differentials in the heated body reflecting localized power generation, the improvement comprising additional means connected to the thermocouple junctions for detecting changes in the temperature differentials caused by changes in relative coolant conditions at said spaced locations, and alarm means connected to the additional detecting means for indicating a drop in coolant level within the reactor.