DE1614014B2 - METHOD AND DEVICE FOR DETERMINING THE CONTENT OF FISSIBLE MATERIAL IN FUEL ELEMENTS OR FUEL SAMPLES TAKEN FROM NUCLEAR REACTORS - Google Patents

Description

3 4

drive of the type mentioned according to the invention. Two embodiments of the device for

training following the irradiation of the activity implementation of the method according to the invention

waste of nuclear radiation from both the fuel assemblies and a system for burn-up measurement are in the

or fuel samples as well as the test specimen drawing. It shows

measured within a given time interval. 5 F i g. 1 a schematic representation of the device

It is sufficient for the sample or the furnace to be used for carrying out the method according to

element and also the invention used as a calibration element,

Element with known fissile material content for a short time, Fig. 2 another embodiment of the

d. H. a few seconds to a few minutes at most, direction for carrying out the method according to

be post-irradiated in a manner known per se. The io invention,

The calibration element and the element to be tested, or the structure of a system for the burn-off sample to be tested in FIG. 3, are irradiated in the same way. measurement of spherical fuel assemblies.
It is advantageous for carrying out the method as shown in FIG. 1 shows, this comes under according to the invention when the fuel element to be compared via the feed 1 in the elements have the same dimensions. A large 15 measuring position A in the lead chamber 2. Within the advantage of the method according to the invention over lead chamber 2, the scintillation counter 3 is arranged in the previously known method for burning off, in front of its measuring head an exchangeable collimation consists in that mator 4 is arranged in this way by forming the difference that the measuring point A is fully covered by the long-life fission product background of the. This can be done by a corresponding burned-out fuel element or the formation of the collimator bore to be examined. Instead of the sample being eliminated, regardless of whether the entire sensor, it is also possible without further ado to arrange gamma radiation if necessary or whether the measurement of the short-term fission product activity, which is not shown in the drawing, is to be arranged integrally over a certain direction, through which the sample is inappropriately However, large - energy intervals rotation is offset that takes place after a predetermined time. If the measurement does not extend over the entire sequence of each area of the test sample in front of the gamma radiation area, it is rotated in the collimator opening. The fuel element or the test specimen, which in too many cases seeks a particularly high measurement accuracy, can be achieved. A further advantage of the method according to the invention after a short measurement in the measuring point A is that, despite a measuring means of a transport device 5, a measuring sequence 30 within a lead chamber 6 is brought into the measuring point B with an accuracy greater than ± 3% . The trans of a sample is achieved in 5 seconds. This is primarily of importance in the port device between the two measuring points A and B is expediently designed so that the activity of fuel assemblies from power reactors and the samples on the transport between the measuring points provide a very high throughput of fuel assemblies A and B the measurement result in the measuring positions, z. B. in pebble bed reactors. 35 gene not affected. The shielding of the two

A preferred device for carrying out the measuring heads against one another and against the samples can be achieved, for example, by arranging two scintillation counters with a lead mass in the method according to the invention. It can also be achieved by downstream electronic speaking selection of the distance, which is known per se.
System for the integral measurement of Spaltproduktakti- 4 °, the measuring device within the lead chamber 6 tivity with a recording and data processing is constructed exactly like the inner measuring system for the automatic evaluation of the measuring results half of the chamber 2. In the measuring position B after Nit, wherein the scintillation counters are arranged in a known manner in a known manner in a precisely adjustable delay time, so that the second measurement is carried out. The difference in radiation does not affect the measurements. A 45 counting rate of the measurements in A and B is then a similar device in which two scintillation counters measure the mass of the fissile material. If it is compared with a downstream electronic system according to the invention with the measured values of a calibration element for the integral measurement of the fission product activity, which is arranged in a recording system for automatic evaluation intervals the same irradiation and measurement cycle of the measurement results in a large amount of time, and at which 50 the fissile material content of the printer sample for recording the measurement results is obtained.

is provided, is already from the British To carry out the measurement, the Szin patent specification 807 048 known. But the distillation counter was misunderstood by a high-voltage unit 7 Device so far mainly provides for display. The output pulses of the counter are in on and reproduction of the activity of gases in a known manner by means of linear exchangers for graphite-moderated nuclear reactors more 8 reinforced and then used in a dead time been. analyzer 9 and a single-channel discriminator 10

Another advantageous embodiment of the pre-fed. From the single channel discriminator 10 direction to carry out the method according to the long only pulses from a preselected energy invention consists in the arrangement of a scintilla 60 interval in the counter. The information from the tion counter with the two electronic counters 11 connected downstream is stored in a data processing system for integral measurement of the cleavage product and registration system 12 with correction of the activity, a printer being provided for registering the measurement results from the dead time analyzer 9. The use of the previous results of the measurement of the standard sample is compared with the designated embodiment for carrying out the known fissile material content.
The method according to the invention has the advantage that, in order to ensure a precise timing, the sample or the fuel assembly during the measurement are also a measurement time generator 13 and a solution remain in the same measurement position. Pause time generator 14 is provided. The measuring time in

the measuring position A is much shorter than the time required for the transport from A to B. This means that additional samples can be measured in A while they are being transported from A to B. The data processing system 12 must therefore be designed in such a way that the counting rates that correspond in each case are subtracted from one another when the difference is formed. In addition, the data processing system 12 serves to monitor and control the synchronization of the irradiation cycle and the measurement cycle.

In Fig. 2 is another embodiment of the device for carrying out the new method shown. The main difference compared to the embodiment shown in FIG. 1 is in that only one scintillation counter is used. It is easily possible, instead of a data processing and registration system, a control device 16 and a corresponding to the requirements Printer 17 to use. The difference can be calculated here from the values registered by the printer Values are made or by a counting device that counts up and down. This simplified design of the device leads to a reduction in the production required Expense. When the measurements are carried out, the sample remains in the same measuring position.

In Fig. 3 the structure of a combustion measuring system for a pebble bed reactor is shown schematically. According to the illustration, after leaving the reactor 18, the fuel element is introduced into a presorting device 19 following a short decay time. There the moderator elements are separated from the fuel elements in a manner known per se by roughly measuring the activity. From the presorting device 19, the moderator elements are fed back to the reactor via the transport device α. The fuel assemblies are first conveyed via the transport device b into the post-irradiation device 20, which is known per se. They are irradiated there for a predetermined short time and brought into the first measuring position A via the transport device c. After a precisely defined delay time, the sample in the second measuring point B is measured a second time. The difference in the counting rates from measurements A and B is then a measure of the fissile material content, taking into account the necessary corrections. Then - as explained above - they are compared with the measured values of a calibration element.

As can be seen from FIG. 3, after the two measurements the fuel elements are transported to the switch 21, from where the examined fuel element is transported into the reactor via d or via the transport device e, depending on the burnup state. The time course for the irradiation cycle and for the measuring cycle is controlled in a manner known per se by means of the central control unit 22.

1 sheet of drawings

Claims (3)

1 2 known. A total absorption measurement has been made, or else reactivity measurements or gamma spectrometric measurement methods are used. 1. Method for determining the content of From British patent specification 917 776 a fissile material in samples taken from nuclear reactors is 5 Method for determining the content of fissile fuel elements or fuel material in fuel elements of nuclear reactors Fuel samples or the like. Known, in which the combustion samples are irradiated and the elements caused by them or the test specimens are re-irradiated nuclear radiation measured and with the nuclear radiation and then a for the fissile material content development of a sample irradiated in the same way characteristic measured value as well the corresponding body with a known content of fissile measured value of a test body with known fission material is compared, as a result of which the characteristic content can be compared with one another. It is characterized by the fact that, following the known method of irradiation, a strong neutron decrease in the activity of the nuclear radiation is required from the source, which must deliver ^{a neutron flux of 10 7} to fuel elements or fuel samples as well as 15 10 ³ n / cm ^{2 s.} The operation of Neutrodes test specimen within a given nenquellen is, however, with high operating costs ver-time interval is measured. bound. In addition, there is the further 2. Device for the implementation of the procedure that the detection of neutrons and splits according to claim 1, characterized by the gamma quanta by primary neutrons and the Arrangement of two scintillation counters with 20 high gamma background of the irradiated focal points downstream elements known per se is significantly disturbed. ironic system for the integral measurement of According to another well-known proposal is for Fission product activity with a registration and burnup determination the change in reactivity of a Data processing system for the automatic multiplying system based on an in-valuation of the measurement results, the amount of scintillate fission material being measured. Here is the tion counter in a manner known per se so arranged arrangement of a special measuring reactor is required are that the scattered radiation borrowed the measurements, making and maintaining it with high not affected. Is associated with an expense. True, it is after this 3. Device for carrying out the proposed method possible, burn-off measurements by reacrens according to claim 1, characterized by the 30 activity change in quick sequence with behavioral arrangement of a scintillation counter with a moderately high accuracy, but downstream electronic system for inter- must be taken into account that the degree of reactivity Measurement of the cleavage product activity, with the change and thus the measurement accuracy also decreasing Registration of the measurement results a printer with the mass of the fissile material also decreasing, is provided. .; .. 35 Therefore, this method is fissile to small amounts Materials not applicable. For the application of gamma spectrometric driving is the use of high-resolution detectors or the like. Required. When using this Ge-40 rate, the necessary measuring time is a few minutes. The invention relates to a method and it is also disadvantageous that with these devices, in the case of a device for determining the content of burnup, only a relatively fissile material can be achieved with an accuracy that can be removed from nuclear reactors. Another noteworthy fuel assemblies or fuel samples, with Licher disadvantage is that these known devices irradiated to the fuel assemblies or fuel samples 45 are relatively expensive.
as well as the nuclear radiation caused thereby measured. The object of the invention is therefore to provide a method and with the nuclear radiation one in the same way and a device for determining the amount of irradiated test specimen with a known content of fissile material, in particular for determination fissile material is compared. of the burn-up in fuel samples or in combustion By determining the content of fissile 5 ° elements, it is intended to ensure, for example, that quantities can be determined through the use of any fissile material. In the case of a rapid measurement sequence, fuel elements used in a nuclear reactor should also achieve a high level of measurement accuracy, with a predetermined burnup in the reactor. Nevertheless, the burnup determination should remain economical. Once the predetermined limit of the borrowed manner be feasible. When the fire has been reached, the fuel assembly must be removed from the reactor required for the burn-up determination and must then have a high level of operational reliability.
be prepared. The most exact compliance possible to solve this problem, the invention is based on this limit is necessary because one has gone too far from the knowledge that in the case of re-irradiation one ongoing burn-up has a negative impact on the reactivity of the reactor or a fuel element, or damage to the products before the post-irradiation before the fuel element has the consequence. A premature recovery of fission products cannot be generated. the processing causes unnecessary costs. Difference between the two For this reason, especially in the case of measured quantities of a post-irradiated sample, fuel assemblies are continuously exchanged during the reaction, proportional to the mass of the still existing gate operation, and a fissile material.
Subject to combustion measurement. To get the content of fissile material in from Processes and facilities for non-destructive nuclear reactors or removed fuel elements Determination of the burn-up of fuel elements, fuel samples are to be determined.