DE2653411A1 - CORE REACTOR AND PROCEDURE FOR DETERMINING THE POWER DISTRIBUTION IN THE REACTOR CORE - Google Patents

Description

KRAFTWERK UNION AKTIENGESELLSCHAFT Our mark

₂ VPA 76P 9 391 BRD

Nuclear reactor and method for determining the power distribution in the reactor core

The invention is concerned with a method of determination the power distribution in a nuclear reactor with a reactor core composed of elongated fuel elements, which is traversed by a coolant in the longitudinal direction of the fuel assemblies, which is heated with temperature measuring devices is determined and used to correct the signal from neutron flux probes that are in a fuel assembly above it Length are arranged distributed. The measuring signals of the temperature measuring devices are intended to provide information on the azimuthal and radial Give power distribution.

The correction is based on a suggestion from the older patent application P 25 15 712.4 made with the help of thermocouples in the upper and lower area of the reactor core are evenly distributed over its cross-section. The neutron flux probes, on the other hand, are particularly reliable with regard to a Design only in a few places, especially outside the reactor core, where there is enough space available. In contrast, the invention seeks a way of determining the power distribution even more precisely than before, without that for the neutron flux measurement a high expenditure in terms of the number and / or the susceptibility of the neutron flux probes to interference must be driven. Rather, the reliability of the measurement should be guaranteed by failing measuring probes,

Sm 21 Hgr / 11/19/1976

809822/0092

"ξ" 76Ρ 939 1 FRG

which deliver a faulty signal can be made ineffective.

In the new method for determining the power distribution, one proceeds in such a way that the heating is carried out on one of the neutron flux probes immediately assigned point is determined redundantly and then evaluated that an integral of the measured values of the Neutron flux probes formed over the length of the fuel assembly that the assessed warming is compared with the integral and that the difference between the integral and the warming is used to suppress a signal from a neutron flux probe when a threshold value is exceeded.

The redundant temperature measurement thus forms a basis for the reliable monitoring of the neutron flux probes, the in turn are spatially so closely related to the temperature measuring devices that a direct assignment is possible is. The accuracy of the measurement of the power distribution is therefore not based on a multiplication of the neutron flux probes but the additional use of the temperature measuring devices and a corresponding computing effort.

Based on the temperature measurements, the signals from all neutron flux probes distributed in a fuel assembly can be used for the In case of incorrect measurement results are suppressed. Under certain circumstances, however, one can also use the axial extension of the reactor core distributed probes sort out individual faulty probes, so that the measurement of the power distribution in the reactor core is particularly little affected by the failure of individual probes.

The method according to the invention can advantageously be carried out in such a way that for difference values below the threshold value a correction of the signal of a neutron flux probe, which is dependent on the size of the difference, is carried out. The correction of the signal can be connected in the same way to all axially distributed probes of a fuel assembly or in different

809022/0092

"e?" 76P 939 1 FRG

different sizes, the gradation according to empirical values can be made or is determined from the values of the warm-up.

For a nuclear reactor for carrying out the method according to the invention one can advantageously start from a reactor core, which is composed of elongated fuel elements and a whose length has a corresponding axial extent and an approximately circular cross-section, and with a measuring device for the local distribution of the reactor power, which in a fuel element axially distributed neutron flux probes and additional temperature measuring devices, preferably thermocouples, to determine the heating of the reactor core in the longitudinal direction comprising coolant flowing through fuel assemblies.

According to the further invention, this reactor core is designed so that several temperature measuring devices at the outlet of a fuel assembly are arranged redundantly and connected to an evaluation circuit that the neutron flux probes with a Integrating circuit are connected, that integrating circuit and Evaluation circuit are connected to a summing element that is also one associated with the inlet temperature of the coolant Temperature measuring device is connected, and that the summing element with one of the outputs of the neutron flux probes associated correction element is connected firstly directly and secondly via a threshold value-dependent switching element.

The switching element can be connected to a signaling device with which the reaching of a threshold value is reported. In addition or instead of this, the switching element can also be the output of individual or all of the neutron flux probes block in the correction link.

For a more detailed explanation of the invention is based on the enclosed Drawing a highly schematic embodiment described.

The reactor core of a known pressurized water nuclear reactor

809822/0092

tor for example 1300 MWe is through a single fuel assembly 1 indicated, which has a square cross-section with 23 cm edge length and a total length of approx. 4.5 m and in the direction of arrow 2 from bottom to top of the pressurized water used for cooling, normally with a constant throughput is flowed through. The fuel assembly 1 contains a plurality of neutron flux probes distributed uniformly over its length 3 »for example 6 pieces, the output lines of which are marked 4. Η, β detectors can advantageously be known Construction are used.

In the head 5 of the fuel assembly there are three thermocouples 6 as temperature measuring devices in a redundant arrangement, i.e. that local irregularities that are conceivable within the cross section of the fuel assembly are not covered by them will.

The outputs of the thermocouples 6 are connected to an evaluation circuit 7. You can for the three depicted Thermocouples 6 a 2-v-3 evaluation circuit of a known type be. In this way, a reliable temperature value is obtained, which is sent to a summing element 9 via a line 8. The summing element 9 is simultaneously not shown by thermocouples via a line 10 with the inlet temperature of the coolant applied to the lower end of the fuel assembly. Instead of this inlet temperature, a Lower coolant temperature value outside the reactor core, for example in the cooling circuit loops as a reference value to be used. The formation of the difference indicated by the sign thus becomes the one for the thermal output of the fuel assembly characteristic warm-up span for the part of the primary coolant flowing through the fuel assembly 1. The summing element 9 can be designed as an integrated semiconductor circuit.

At the output positions 4 of the neutron detectors 3 is a from electronic components in a known manner, for

809822/0092

% 76 P 9 3 9 1 FRG

game in an integrated design integrating circuit 12 connected. It forms from the measured values of the neutron flux probes 3, which are characteristic of the local power, the integral of the power development over the fuel assembly 1, which must correspond to the power supply to the coolant expressed by the heating. Therefore this can Power with that determined in the summing element 9 can be used for a comparison with which the integrating circuit is connected via a line 13.

The difference between the power value determined with the thermocouples 6 and the power value of the neutron detectors 3 is available on the output line 14 of the summing element 9. It acts once on a switching element 15 with the indicated threshold value characteristic, which corresponds , for example, to deviations of ί 2-5%.

Correction elements 16 are connected to the switching element 15 and at the same time via the output lines 4 of the power distribution detectors 3 are fed directly. Furthermore, the correction elements are directly connected to the via a line 18 Output line 14 of the summing element 9 connected. The correction links 16 for their part provide the desired useful signals of the power density, i.e. the power distribution, via output lines 19 over the fuel assembly 1.

During the operation of the reactor, the difference between the power values, which is determined in the summing element 9, is in the normal case Correction of the signals of the individual neutron flux probes 3 over the length of the fuel assembly 1 used, provided the difference lies below a limit value established with the switching element 15. The embodiment is an equal limit value for all correction terms 16. However, if the power deviation is, for example, 10% exceed the neutron flux measurement by a Blocking of the measuring lines in the correction elements 16 switched off altogether. Hence, no wrong measurements can be made

809822/0092

Protective systems and monitoring devices connected to the output lines 19 or suggest the like incorrectly.

A signaling device is attached to the switching element 15 in the exemplary embodiment 20 connected. It notifies the personnel in a control room provided for the reactor that at There are discrepancies in the performance measurement so that repair options can be searched for as quickly as possible.

6 claims
1 figure

809822/0092

Claims (6)

76P 9 39 1 FRG Claims Iy procedure for determining the power distribution in a Nuclear reactor with a reactor core composed of elongated fuel elements, which extends in the longitudinal direction of the fuel elements is flowed through by a coolant, its heating determined with temperature measuring devices and used to correct the signal from neutron flux probes is distributed in a fuel assembly over its length are arranged, characterized in that the heating is directly assigned to one of the neutron flux probes Place redundantly determined and then it is assessed that a Integral of the measured values of the neutron flux probes over the length of the fuel assembly is formed that the rated heating is compared with the integral and that the difference between the integral and the heating when a threshold value is exceeded to suppress a signal from a neutron flux probe is used. 2. The method according to claim 1, characterized in that the signals of all neutron flux probes distributed in a fuel assembly be suppressed. 3. The method according to claim 1 or 2, characterized in that for difference values below the threshold value one of Correction of the signal depending on the size of the difference Neutron flux probe is made. 4. Nuclear reactor, especially pressurized water reactor, for exercise of the method according to one of claims 1 to 3 with a reactor core which is composed of elongated fuel elements and has an axial extent corresponding to its length and an approximately circular cross-section, and with a measuring device for the local distribution of the reactor power in a fuel assembly axially distributed neutron flux probes and additional temperature measuring devices, preferably thermocouples, to determine the heating of the reactor core in the longitudinal direction of the Includes fuel elements flowing through coolant, thereby SÖ9822 / 0Ö92
-'-- - - ORiGiMAL JNSPfKTfED 76Ρ 9 39 1 FRG oil characterized in that several temperature measuring devices (6) at the output a fuel assembly (1) are arranged redundantly and connected to an evaluation circuit (7) that the Neutron flux probes (3) with an integrating circuit (12) are connected that integrating circuit (12) and evaluation circuit (7) are connected to a summing element (9), to which a temperature measuring device (10) assigned to the inlet temperature of the coolant is also connected, and that the summing element (9) with a correction element (16) assigned to the outputs (4) of the neutron flux probes (3) firstly directly and secondly via a threshold value-dependent Switching element (15) is connected. 5. Nuclear reactor according to claim 4, characterized in that the switching element (15) is connected to a signaling device (20) is. 6. Nuclear reactor according to claim 4 or 5, characterized in that the output (4) of individual or all of the neutron flux probes (3) can be blocked in the correction element (16) by the switching element (15). 809812/0092