Patent Number: 042591520
Section: description

DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now to FIG. 1, there is shown a nuclear reactor vessel 10 including a sealed roof structure 12. Within the vessel 10 is a nuclear core comprised of a plurality of fuel assemblies 14 each having a plurality of sealed fuel rods 16 containing nuclear fuel and a gas plenum. The fuel assemblies 14 are supported upon core support structures including a perforated lower core plate 18 joined to other components such as a transition 20, a cone 22 and a core barrel 24 by welds 26. A liquid coolant, such as sodium, enters the vessel 10 through a plurality of inlet nozzles 28, flows upwardly about the fuel rods 16, absorbing heat energy, and is discharged from the vessel through outlet nozzles 30 to heat exchange apparatus, typically for the ultimate purpose of electric power generation. The coolant then returns to the inlet nozzles 28, completing a circuit through the substantially sealed reactor system. The level 32 of coolant within the vessel 10 is maintained so as to provide a cover gas space 34 within the reactor vessel. Cover gas samples are continuously or intermittently withdrawn from the gas space 34 by a monitoring system 36 through conduit 38 and directed to an analyzer 40 for determining the gas content. The samples can be returned to the reactor system or further treated. As well known, the fuel rods 16 can be provided with tag gases, typically non-radioactive isotopes, which, in the event of fuel rod failure, are released into the circulating coolant along with fission product gases and flow upwardly, ultimately entering the cover gas 34. The analyzer 40, upon monitoring of the cover gas, indicates the presence of a tag gas and accordingly a fuel rod failure. The analyzer 40 in presently proposed reactor systems can be activated by a trigger signal from activator 41 which reacts to the presence of a specified level of radioactive fission product gases released with the tag gases upon a fuel rod failure. A typical tag gas system utilizing especially blended krypton and xenon isotopes is discussed in an article entitled "Design and Manufacture of Gas Tags for FFTF Fuel and Control Assemblies", Nuclear Technology, Vol. 26, August 1975, incorporated herein by reference. In accordance with the invention, the monitoring system 36 can advantageously be utilized to similarly indicate weld failure or crack initiation. FIG. 2 is representative of the welds, for example, the weld 26' between the transition 20 and cone 22. Subsequent to making the weld, a hole or chamber 42 is drilled or otherwise made through selected portions of the component base metal 44, 46 and the weld deposit 48. In the embodiment shown, chamber 42 extends from the surface 50 of the base metal 44, through a portion of the base metal 44, preferably the heat affected zone, through the weld deposit 48, and into the base metal 46. A preselected tag gas 52, different than the fuel rod tag gases, is then injected into the chamber 42 and sealed therein by sealing means such as a plug 54. In order to avoid spurious weld failure indications such as through leakage passed the plug 54, the plug is preferably both threaded into position and additionally welded or otherwise sealed about its periphery. Plural plugs in series can also be utilized for added integrity. Thus, if a failure in the welded area is initiated, such as a crack or a separation along a fusion line 56 which communicates with the chamber 42 and the outer surface of the welded area, the tag gas 52 is released to the surrounding environment 58. In the nuclear reactor system, the surrounding environment is the reactor coolant through which the gas is directed to the cover gas 34 and the monitoring system 36. While fuel rod failures emit not only the selected tag gas but also radioactive fission product gases which trigger the actuator 41, no similar releases of fission product gases arise from weld failure. Accordingly, a specific trigger gas, such as long-lived radioactive krypton-85 can be incorporated in the tag gas to similarly activate the detection system 36. It will be evident that the trigger gas should be fast-acting in actuation of the detection system, since cover gas cleanup systems would otherwise remove the tag gases prior to their detection. The tag gas weld failure detection arrangement can equally be applied to welded structures in other nuclear and also non-nuclear applications, as exemplified in FIG. 3. A weld deposit 48 is disposed between two base metal components 44, 46. A portion of the environment about the welded area, illustrated by the dashed line 60, is directed by drive means such as a pump or fan 62 to an analyzer 40. Tag gas 52 released from the chamber 42 in the event of weld area failure is passed to the analyzer 40 and detected. A trigger gas can also be incorporated with the tag gas to actuate the analyzer 40. FIG. 3 also shows an alternative chamber 42 configuration, the chamber extending from a surface 50 of the base metal 44, through weld deposit 48 and base metal 46 to a surface 64. Two plugs 54 are accordingly utilized to seal the tag gas 52 within chamber 42. The chamber 42 can be of additional geometric configurations and can extend over additional selected areas. A plurality of tag gas filled chambers 42 can also be utilized in conjunction with a single weld deposit. For any application, the diameter of a hole of circular cross section or the size of any other configuration can be selected compatible with the size of the weld, the weld stress conditions and material sensitivity to stress concentration. The pressure of the tag gas placed within the chamber can also be selected in conjunction with the chamber volume to provide a sufficient quantity of tag gas for detection. The spacing of plural chambers along a weld should also be based upon the critical crack size for the specific application. It will be recognized that the presence of a chamber will necessarily create a stress concentration which can reduce the fatigue life of a welded connection. This affect can be reduced by minimizing the size of a chamber and by adjusting the configuration of the chamber in any number of manners. Where, as is often the case, loading or bending stresses are lower in the central area of welded components and higher at the outer surfaces, a configuration such as shown in FIG. 4 can be utilized, the chamber volume being greater in a central region 66 and smaller at outer extensions 68. The enlarged central region 66 is machined into one or both of the base metal members and sealed by plug 70 prior to final machining of the base metal member preparatory to welding. The plug 70 preferably extends beyond the melting zone of the weld. Subsequent to welding, the smaller diameter extensions 68 are drilled from an outer surface and into the region 66. The tag gas can either be sealed within region 66 prior to making of the extensions 68, or the extensions 68 can be utilized for tag gas charging. In a system having a plurality of welds, such as with the reactor vessel and internal components, two or more chambers located in close proximity to each other within a given weld, each filled with a different tag gas, can be utilized to enhance reliability of the system. Evidence of only one of these gases would tend to indicate a spurious signal, such as leakage passed a plug, as opposed to actual weld area failure. Simultaneous detection of the tag gases from separate chambers would tend to indicate a true failure. Where different tag gases are utilized within a single weld, detection of a given tag gas further evidences not only the existence of a weld failure, but also the location of the failure within a specific weld. Additionally, plural tag gas filled chambers can be, and in nuclear applications preferably are, positioned through a welded region at intervals such that a crack which eliminates all of the structural capability of the material between the chambers would still be of a size such that the structural integrity of the weld for its intended function will be maintained. This can be compatibly arranged particularly in liquid metal cooled reactors as major components are typically comprised of austenitic stainless steel which has a relatively long critical crack length. The critical crack length is here defined as the length at which the energy liberated as a result of an incremental crack growth is greater than the energy required to cause that incremental growth such that the crack extends in an unstable manner. Thus, an adequate crack detection system for particularly the lengthy welds in a liquid metal cooled reactor, up to several hundred inches, can be obtained using a relatively small number of tag gas chambers in a given weld. Sealing of the tag gas within the chamber can be accomplished by a number of well known techniques such as sealing of the tag gas while the weld area is disposed in an environment of the desired gas at the desired pressure, or as shown in FIG. 5, by utilization of a container 72, having a rupturable end cap 74 which is pierced by a penetrator 76. Piercing can be accomplished upon insertion of the plug 54 or, for example, by electromagnetically moving the container 72 into contact with the penetrator 76, among other known techniques. Since numerous changes may be made in the above-described apparatus without departing from the spirit and scope thereof, it is intended that all matter contained in the foregoing description and shown in the accompanying drawings shall be interpreted as illustrative and not in a limiting sense.