The present invention concerns a method and an instrument, for monitoring the cooling conditions in the reactor core in Light Water Reactors. In the method at least one probe provided with power supply means is introduced into the reactor vessel.

The need for reliable core cooling monitors became evident during the Three Mile Island accident, and it has been proposed that perhaps the destruction of the reactor core could have been avoided if the reactor had been equipped with monitors, which could have given direct information about the cooling conditions inside the reactor core. In several countries the Reactor Inspectorates have now presecribed that core cooling monitors should be installed in LWR's.

Such instruments must be able to indicate rapidly and clearly when the cooling of the reactor core is lost, which would occur if the liquid level in the reactor vessel falls below the level, where the reactor core starts to uncover. Especially, it is of great importance that the response of the monitor is sufficiently large in order to avoid any misinterpretations, which could lead to undesirable operator actions.

Differenct concepts for monitoring the cooling of the reactor core have been reported. Systems based on pressure drop measurements have been proposed by Westinghouse and by Babock & Wilcox. The output signals obtained from this kind of instruments may be difficult to interprete during the rapid transient conditions, which may exist during an accident situation. Hence, computer programs must be used for the interpretation of the signals, preventing a direct and reliable observation of the coolant inventory in the reactor vessel.

Another method, which is used by Combustion Engineering, is based on a heated junction thermocouple probe. The probe contains a dual thermocouple, with one heated junction and one unheated junction. Thus, the output from the probe is directly related to the cooling capacity of the surrounding fluid. An output voltage from the thermoelement indicates that there exists a temperature difference between the heated and the unheated junction and that the cooling capacity of the surrounding coolant is insufficient to cool the heated junction. This would indicate that also the core is insufficiently cooled. This principle suffers from the disadvantage that the output signal is in the order of a few millivolts only. For that reason the output signal could easily be disturbed by other phenomena occurring in the reactor.

The increase of the temperature in the core when inadequate cooling occurs can not be followed neither with instruments based on the pressured drop method, not with the above described dual thermocouple instrument.

The object of the present invention is to provide a method and an instrument for monitoring the cooling of a core in a light water reactor providing an output signal, which clearly and unambigously indicates the occurrence of a disturbance of the cooling of the reactor core, and which has such a strength, that possible occurring interferences are negligible, and which also can be used to measure the temperature in the reactor core during the heat up period after the loss of coolability.

According to the invention this object is solved by a method for monitoring the cooling conditions in the reactor core of a light water reactor, in which a probe provided with power supply means is introduced into the reactor vessel, wherein the probe comprises at least one electric heating element containing a resistor, which is connected to said power supply means and whose resistance is dependent on the temperature of the resistor, and sensing means connected to the resistor and providing an output signal, which is dependent on the resistance of the resisitor, when curren ows through the resistor, the resistor being in heat transfer contact with a medium which surrounds the probe, and wherein, in a first mode of operation for the detection of a reduction of the cooling capacity around the probe, the resistor is supplied with a relatively high power, being such, that the heat, which is generated in the resisitor by this, is carried off by the coolant surrounding the probe, when the core is normally cooled, said heat bringing about a temperature rise in the resistor in the case of a reduction or loss of the cooling capacity around the probe, resulting in a changed resistance and changed output signal and by an instrument for monitoring the cooling conditions in a reactor vessel of a light water reactor, comprising a probe insertable into the reactor vessel and provided with power supply means, wherein the probe comprises a casing made from a water resistant material, a resistor imperviously encapsuled in the casing and connected to the power supply means, the resistance of the resistor being independent on the resistor temperature, a heat conducting medium arranged between the inner wall of the casing and the resistor, and sensing means providing an output signal, which is dependent on the resistance of the resistor, when current flows through the resistor.

The invention provides great advantages in comparison with prior art:

• 1. In a loss of coolant accident the response of the monitor would be up to 200 times larger or more compared with the signals attainable from monitors, which are based on the heated thermocouple junction method. Because of the large response the risk for misinterpretations of the signals can be regarded as negligible.
• 2. The instrument can be used, especially after a detected loss of coolant accident, for measuring of the temperature inside the reactor core as well as outside the reactor core.
• 3. The instrument takes very little space and is constructed from very few parts, which are reliable in operation, thus reducing the error possibility. Especially the probe can be designed to be contained within the instrumentation guide tubes already existing in the reactor.
• 4. If a probe is arranged within the reactor core the instrument may serve as a core cooling monitor, a liquid level indicator or as a thermometer, If, however, the probe is placed above, below or beside the resctor core the instrument functions as a liquid level indicator or as a thermometer.
• 5. During the heat up phase which occurs after a loss of coolant, the output signal from the monitor may be used to activate certain safety equipment.
• 6. The probe does not need any shielding, since the out put signal is so strong, that the influences from water droplets hitting the probe are negligible. Heated junction thermocouple probes are often shielded against such disturbances, especially against the splashing, which occurs just above the surface of a two phase steam water mixture.

Laboratory test in which a steam water loop operating in a pressure range between 1 - 160 bar was used, have shown that the anticipated effects of splashing liquid and droplet deposition had negligible influence on the response from the monitor, when the normal coolant level disappeared and the probes became uncovered.

Other adavantages and features of the invention will become more evident from the following description of an embodiment of the invention by reference to the accompanying drawings, in which

• Figure 1 shows a circuit diagram comprising three measuring instruments in accordance with the invention and
• Figure 2 in section shows a probe, which is a part of one of the measuring instruments shown in the diagram in Figure 2.

In the circuit diagram of Figure 1 three measuring instruments 1a, 1b, 1c, are provided, eachcomprising a probe 2a, 2b and 2c, repsectively, which is introduced into the reactor vessel on a suitable place. Each probe 2a, 2b, 2c includes a resistor 3a, 3b and 3c, respectively, whose resistance is dependent on the temperature of the resistor. Each resistor is by means of signal lines 6a, 6b and 6c, respectively, connected to a recorder 4, which in this case records the voltage over each resistor. The resistors 3a, 3b, 3c are connected to power supply lines 5a, 5b, 5c, which by means of switches 7a, 7b, 7c are connectable to either of two power sources 8a, 8b, 8c and 9a, 9b, 9c, respectively.

In a first mode of operation, the resistors 3a, 3b, 3c are connected to a first power source 8a, 8b and 8c, respectively, supplying relatively high power to the corresponding resistor, for example 4 A. At normal operation the heat, which is generated by the supplied power in the resistors 3a, 3b, 3c, will be carried off by the surrounding coolant in the reactor, with a very slight temperature rise in the resistors as a result. However, if a reduction of the cooling capacity of the surrounding medium occurs, for instance by loss of coolant, the corresponding resistor 3a, 3b, 3c will be insufficiently cooled, which will increase the temperature in the corresponding resistor. The temperature rise in the resistor, changes the resistance of the resistor. If the monitor is supplied with a constant current, the voltage output would increase rapidly in case the cooling of the reactor core is lost. At a predetermined output signal level, which can be in the order of some volts, an alarm is released indicating the loss of core cooling in the reactor, whereupon necessary safety steps are released or undertaken.

The switches 7a, 7b, 7c may then be switched over, thereby connecting the resistors 3a, 3b, 3c to the second power sources 9a, 9b and 9c, respectively. This second power source supplies a considerably lower current, for example in the order of 0, 1, A, to the corresponding resistor, In this second mode of operation with a very low power supply to the resistors 3a, 3b, 3c the instrument will function as a resistance thermometer. Thus, in this second mode of operation the instrument is used for monitoring the development of the temperature in the reactor core.

Figure 2 shows the probe 2 of the instrument in section. A resistance wire 11, made from a suitable material, for instance Kanthal, is wound around an insulator 10, consisting of a solid body made from A1₂O₃ or another body covered with an electrically nonconducting material. the resistance wire 11 is connected to a power source by means of the cables 5. The resistor coil 11 is hermetically encapsuled, by means of laser or electron welding, within the casing 12 which is made from a low neutronabsorbing and waterresistant material, for instance stainless steel or Inconel. The space between the resistor 11 and the casing 12 is filled with a heat conducting, electrically insulating and low neutron absorbing material, for example MgO-powder.