SE470114B - Method and arrangement for detecting leaks of nuclear fuel - Google Patents

Abstract

Method and arrangement for detecting leaks of nuclear fuel in a nuclear reactor with a reactor core in the form of at least one fuel cartridge 2 which is lowered in water and comprises a number of fuel rods. Gas and/or water samples are taken in the vicinity of the fuel cartridge while measures are taken in order to force fission products out of fuel rods. A sample which has been taken is pumped up and supplied to a gas separator 7 comprising a gas space 8 and a water reservoir 9 and in which the gas space is separated from the water reservoir by means of a water lock 10. The water is finely distributed for supply to the gas space, and gas released from the sample is mixed with gas present in the gas space and the gas circuit 12 connected to the gas space. The gas mixture obtained is pumped to a measuring chamber 13 and is analysed for the presence of gaseous fission products. Degassed water is conducted to the water reservoir and is analysed for the presence of water- soluble fission products. <IMAGE>

Description

While the external static pressure is usually lowered by lifting the fuel assembly to a higher level in the reactor water.

Samples are taken in connection with the examined fuel assembly, whereby water from the fuel assembly, containing any fission products, is aspirated and pumped up for analysis. Sucked water can contain both fission products dissolved in the water, solid fission products and gaseous fission products.

Upon detection, the most reliable result is obtained if water-soluble fission products and gaseous fission products are separated and analyzed separately in a known manner as described, for example in the Swedish patent specification SE-B-396 497. According to this document, the aspirated water is pumped to a gas separator Gases contained in the sample are released when their solubility in water decreases due to the pressure drop. Released gas is mixed with a working gas present in the gas separator and pumped to a measuring chamber for analysis for the presence of gaseous fission products by means of a detector for detecting radioactivity in gases while the water is analyzed separately. Degassing achieved in the gas separator becomes, especially in connection with large amounts of water sample taken, not sufficiently efficient and the large amount of water affects the gas volume in the gas separator.

An object of the present invention is to provide an efficient and substantially complete release of gases present in an inflated water sample.

Another object of the invention is to enable, for low activity in sampled quantities, the necessary enrichment of gaseous fission products in the detection system for detection by large quantities of samples being pumped through the gas separator and degassed therein. THE INVENTION In the case of leak detection of nuclear fuel in a nuclear reactor with a reactor core arranged in the form of at least one immersed fuel assembly, which comprises a plurality of fuel rods, gas and / or water samples are taken in connection with said fuel assembly. the aforementioned measures are taken to expel fission products, which are formed during the operation of the reactor, from the fuel rods. The sample is taken by sucking water and gas from the fuel assembly into the sampling equipment, which is preferably arranged in the form of a suction hood. The taken sample is pumped to a gas separator where it is degassed, whereby gases contained in the sample are released when the solubility of these in water decreases due to the pressure being lower in the gas separator than at the sampling point in the basin. Gas released from the samples is mixed with existing gas in the gas space and an existing gas circuit connected to the gas space. The gas mixture thus obtained is pumped to a measuring chamber arranged in the gas circuit and analyzed for gaseous fission products. The degassed water is led to said water reservoir where it is analyzed for water-soluble fission products and is detected by means of a device for detecting radioactivity in water.

Alternatively, water samples are taken to a separate laboratory for analysis.

According to the invention, the gases taken are supplied with a gas separator which comprises at least one gas space and a water reservoir. The gas space is arranged separately from the water reservoir by means of a water trap. In order to obtain an efficient and substantially complete degassing of the samples taken, they are atomized at the supply to the gas space.

The released gas is mixed with existing gas in the gas space and in a gas circuit connected to the gas space. The resulting gas mixture is pumped from the gas space to a measuring chamber arranged in said gas circuit comprising a detector for detecting radioactivity in gases where the gas mixture is analyzed with respect to the presence of gaseous fission products. 10 15 20 25 30 35 476114 4 Degassed water from the samples is led to the said water reservoir where it is analyzed for the presence of water-soluble fission products by means of a detector arranged in connection with the water reservoir for detecting the radioactivity in water. Alternatively, water samples are taken to a separate laboratory for analysis. In one embodiment of the invention, the accompanying moisture and water vapor are separated from the gases by passing the gases a moisture separator and a gas dryer, and further purifying the gases from solid fission products by passing them through an iodine trap while pumping said gases from the gas space in the gas separator to the detector for detecting radioactivity in gases.

In another embodiment of the invention, said water reservoir is arranged with a overflow drain through which excess water, when taking large quantities of samples, is removed.

In a preferred embodiment of the invention, detection is made possible even at low activity in taken samples by taking large quantities of samples in connection with the examined fuel assembly and pumping to the gas separator where the samples are degassed by supplying a gas space arranged in the gas separator by means of nozzles. the degassing. Gas present in the gas space and the gas circuit can then be enriched in gaseous fission products so that even small leaks can be detected. The degassed water is led to a water reservoir arranged in the gas separator. When the water reservoir is arranged separated from the gas space by a water trap and when excess water in the water reservoir is continuously removed by means of an overflow drain arranged in connection with a, the water reservoir, large quantities of samples can be taken and degassed without this affecting the gas volume. FIGURES The invention is explained in more detail below with reference to the accompanying figure, which schematically shows the present invention, according to a preferred embodiment, applied in leak detection of nuclear fuel in a nuclear reactor with a core in the form of a core. of at least one fuel assembly arranged immersed in water.

DESCRIPTION OF THE FIGURES In the figure, 1 denotes a water-filled basin in which nuclear fuel in the form of fuel rods arranged in a vertically arranged fuel assembly 2 is immersed. The water level in the pool is indicated by the triangle 3.

During leak detection on the nuclear fuel, the necessary samples are taken primarily in connection with fuel assemblies 2 and not on individual fuel rods. In order to obtain as high a degree of detection as possible, measures are taken to expel the fission products formed during operation of the nuclear reactor from the fuel rods in the examined fuel assembly 2. Which is achieved by raising the fuel temperature and / or by lowering the external static pressure around the fuel. A temperature increase is obtained by reducing or stopping the water circulation through the fuel assembly 2, while a lowering of the external static pressure is usually obtained by raising the fuel assembly 2 to a higher level in the water base bed 1. Both temperature increase and pressure decrease can be obtained by move the fuel assembly to a container with the option of heating and depressurizing. Samples are taken with a sampling equipment 4 arranged in connection with the examined fuel assembly 2, in case of leak detection where the fuel assembly is moved to a container, water and / or gas samples are taken from said container. Preferably, water and / or gas, containing any fission products, are sucked out by means of a suction hood 4 and pumped by means of a line 5 and a pump arranged in connection with the line 5 10 15 20 25 30 35 ÄÉ-7O 114 6 6 to detect the possible presence of radioactive fission products. The sample taken may contain both water-dissolved, solid and gaseous fission products.

Upon detection, the most reliable result is obtained if water-soluble fission products and gaseous fission products are separated and analyzed separately in a known manner, so that the sampled sample is pumped to a gas separator 7 where gases present in the sample are released from the water. of the pressure drop. The gas separator 7 contains at least one gas space 8 and a water reservoir 9. According to the invention, the gas space 8 and the water reservoir are arranged by means of a water trap 10. In order to achieve a more efficient release of gases in the sampled samples, the water is atomized in the gas space 8 arranged nozzles 11 in connection with the supply of the gas separator 7.

The gases thereby released from the water, containing any gaseous fission products, are mixed with a working gas present in the gas separator 7 and pumped in a gas circuit 12 to a measuring chamber 13 for analysis for the presence of gaseous fission products by means of a detector for detecting radioactivity in gases. while the degassed water is led to the water reservoir 9 in which any radioactivity in the water is detected separately with a detection equipment 14 arranged in connection with the water reservoir 9 for detecting radioactivity in water. Alternatively, water samples are taken to a separate laboratory for analysis.

A further object of the invention is to enable the detection of gaseous fission products in the detection system in the case of low activity in the water samples taken by means of which large amounts of water samples can be pumped through the gas separator 7 and degassed therein. This is achieved in a preferred embodiment of the invention where at low activity in sampled samples, large quantities of samples are taken in connection with the examined fuel assembly 2 and pumped up to the gas separator 7. In the gas separator 7 the samples are degassed by supplying a gas dispenser 7 gas space 8 by means of nozzles 11. The degassed water is led to a water reservoir arranged in the gas separator 7. The water reservoir 9 is separated from the gas space by means of a water trap 10 in the gas circuit 12 and the gas space 8, by means of an adjacent gas circuit. Pump 16, around the gas circuit 12 and the gas space 8, whereby it is enriched in any gaseous fission products while excess water in the water reservoir 9 is continuously removed from the gas separator 7 by means of an overflow drain 15 arranged in connection with the water reservoir 9.

To ensure that dry gas is supplied to the measuring chamber 13 for detecting radioactivity in gases, moisture separators 17, gas dryer 18 and iodine trap 19 are suitably arranged in the gas circuit 12 between the gas space 8 and the measuring chamber 13.

Claims (7)

10 15 20 25 30 35 4 7 0 1 'i 4 PATENT CLAIMS 1. l. In the case of leak detection of nuclear fuel in a nuclear reactor with a reactor core in the form of at least one immersed fuel assembly (2) comprising a plurality of fuel rods, gas and or water samples being taken in connection with said fuel assembly while taking measures for to expel fission products from said fuel rods, the sampled sample is pumped up to a gas separator (7) where gas present in the sample is separated and analyzed for the presence of gaseous fission products, while the water is analyzed for the presence of water-soluble fission products. and is supplied with a gas separator (7) comprising a gas space (8) and a water reservoir (9) and wherein said gas space is separated from said water reservoir by means of a water trap (10), that the water at the supply to the gas space is atomized, to be degassed efficiently and substantially completely, that gas released from the sample is mixed with, in said gas space and to gas space connected gas circuit (12), existing gas after which the gas mixture obtained is pumped to a measuring chamber (13) arranged in said gas circuit and analyzed for the presence of gaseous fission products, while the degassed water is led to said water reservoir and analyzed for the presence of water-soluble fission products. 2. A method according to claim 1, characterized in that the accompanying moisture, water vapor and solid fissio products are separated from said gas by being passed through a moisture separator (17), a gas dryer (18) and an iodine trap (19) while the gas pumped by means of a pump (16) arranged in connection with the gas circuit from said gas space (8) to the measuring chamber (13). 10 15 20 25 30 35 4? Û 'H4 9 3. A method according to claim 1 or claim 2, characterized in that excess water in said water reservoir (9) is removed by means of an arranged overflow (10). 4. A method according to claim 3, characterized in that at low activity in the sampling large amounts of water are pumped up into the gas separator (7) and degassed, whereby existing gas in the gas space (8) and the gas circuit (12) is enriched on gaseous fission products while the excess water continuously removed by means of the overflow drain (10). Device for performing leak detection of nuclear fuel in a nuclear reactor with a reactor core in the form of at least one fuel immersion cartridge (2) which comprises a plurality of fuel rods, by means of a sampling equipment (4), preferably in the form of a suction hood, arranged for taking gas and / or water samples in connection with said fuel assembly, a line (5) and pump (6) are arranged to carry the taken sample from the suction hood up to a gas separator (7), arranged for degassing the taken sample, A measuring chamber (13) having detectors for detecting gaseous fission products in separated gas and detectors (14) for detecting fission products in degassed water, characterized in that said gas separator (7) is arranged to comprise a gas space (8) and a water reservoir (9), where the gas space is separated from said water reservoir by means of a water trap (10), that nozzles (11) are arranged to atomize the sample water at the supply to the gas space, that a gas reservoir ts (12) comprising at least one measuring chamber (13) with detector for detecting radioactivity in gases is arranged connected to the gas space and that a detector (14) for detecting radioactivity in the water is arranged in connection with the water reservoir. 10 470 'H4 10 Device according to claim 5, characterized in that a gas circuit (12) connected to the gas separator (7) in addition to the measuring chamber (lä) for detecting radioactivity in gases comprises a moisture separator (17) for separating moisture, a gas drying equipment (18). for separating water vapor, an iodine trap (19) for separating solid fission fruits and a pump (16) arranged in connection with the gas circuit. Device according to claim 5 or claim 6, characterized in that the water reservoir (9) is provided with a overflow drain (10).