JPH06331786A - Fuel extractor and failed-fuel detection device - Google Patents

Abstract

PURPOSE: To miniaturize a coolant extracting pipe and its port in a liquid coolant extracting device. CONSTITUTION: A fuel extracting device for detecting failed fuel within a reactor has a cylinder 27 having bores parallel to the axis, in which a plurality of ducts 29 are provided on the wall inner part, the respective ducts have inlet ports on one-side end surfaces of the cylinders and discharge ports 33-43 on the surfaces of the bores, and the discharge ports are set around at least two bores 31 situated different distances from one end surface of the cylinder; and a selector valve 47 for successively connecting the respective discharge ports to a fuel discharging passage 63, which is rotatable within the bore 31, movable in the axial direction of the bore, and successively positions the respective discharge ports 33-43 to an extracting nozzle 57, whereby fuel is continuously extracted from the respective exhaust ports.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fuel extraction device and a damaged fuel element detection device cooled by liquid metal in a nuclear reactor.

[0002]

2. Description of the Related Art Conventionally, as fuel for nuclear reactors of fast breeder reactors, liquid metal cooling type fuel is enclosed in a fuel cladding, and a plurality of fuel pins are installed in parallel in an open type envelope. Is
It forms the fuel assembly. Then, a plurality of such fuel assembly parts are assembled to form a central part of the nuclear reactor. Liquid metal, such as sodium, passes upwards through the assembly to remove heat generated at the fuel pins.

It is necessary to be able to detect any damage to the fuel pin cladding of a particular assembly. As a result, it is possible to immediately remove and replace the assembly, prevent contamination of the coolant, and ensure the safety of the reactor.

Conventionally, the detection of a broken fuel pin in a metal-cooled reactor as described above is carried out by attaching a coolant extraction pipe to each of the central assembly parts. Also conventionally, such coolant extraction pipes terminate at corresponding ports in the upper central structure. Then, a plurality of consecutive samples are taken out from the coolant extraction pipe by a selector valve having a rotary selector that prevents the respective pipes from coming into contact with each other. Multiple coolant samples are sequentially sent to a monitoring device that inspects the sample for fissionable material. Thereby, damage to one or more fuel cladding within the particular fuel assembly at the selected port is indicated.

[0005]

In the conventional coolant extraction apparatus as described above, the ports for all the coolant extraction pipes are installed on a straight plane, so that all the extraction pipes and the related pipes are associated therewith. To house the port,
There is a problem that a large area is required and each port must be sequentially isolated by the selector valve. For example, this is the case of 218 pipes and ports.

It is an object of the present invention to provide a brewing device, in particular a liquid coolant brewing device, to reduce the area of a straight plane for installing the coolant brewing pipe and its ports.

[0007]

According to a first aspect of the present invention, in a fuel extraction apparatus, the apparatus is a cylinder having an inner diameter parallel to an axis, and a plurality of ducts are provided inside a wall, respectively. Of the cylinder has an inlet port on one end surface of the cylinder and an exhaust port on the surface of the inner diameter, the exhaust port being at least two different distances from the one end surface of the cylinder around the inner diameter. And a selector valve that sequentially connects the respective exhaust ports to the fuel exhaust passage, and is rotatable inside the inner diameter and movable in the axial direction of the inner diameter. It is characterized by having a selector valve for sequentially aligning the discharge port and the extraction nozzle.

According to another aspect of the present invention, in a broken fuel detecting device in a nuclear reactor cooled by a liquid metal, each of the devices is a cooling medium which has passed through a corresponding fuel or breeder reactor assembly. Multiple extraction pipes for extracting
Each duct has an inlet port on one end surface of the cylinder,
And a cylinder inside the wall such that a discharge port is provided on the surface of the inner diameter at at least two different distances from the one end surface of the cylinder, each extraction pipe, and the plurality of inlet ports. A selector valve for connecting the respective discharge ports and the coolant sample discharge path, which is rotatable inside the inner diameter and movable in the axial direction of the inner diameter. , A selector valve for aligning the extraction nozzle with each of the discharge paths and inspecting the level of the substance that has undergone fission in the path.

[0009]

Embodiments of the present invention will now be described with reference to the drawings.

Referring to FIG. 1, a central part 1 of a metal cooled fast reactor has a structure of a fuel assembly part 3. The two damaged fuel detection and location (FFDL) units 5 and 7 of the present invention are installed on top of the central structure,
Each unit is responsible for half the corresponding fuel assembly.

Referring to FIGS. 2, 3 and 4, the FF
Each of the DL units 5, 7 has a lower cylinder 9 with an annular flange 11 at the upper end. The annular flange 11 is provided with five rings of openings 13 (only three of which are shown in the cross-section in FIG. 2). Each of the openings of the annular flange 11 receives the mouth ring 15 welded to the upper portion of the corresponding extraction pipe 17 in a corresponding manner. As shown in FIG. 1, each extraction pipe extends downwardly and outwardly to accommodate a corresponding fuel assembly 3
It is terminated in the form directly adjacent to. In the assembly section, each mouth ring 15 is pushed upwards through the opening 13 and the snap ring or split ring tube 19 is installed in the groove 21 inside the wall of the mouth ring 15. Then, the split ring pipe 19 is installed in the groove 23 on the upper surface of the annular flange 11 by moving the muzzle 15 downward. Thereby, the muzzle 15 is held in the axial direction of the opening 13. Then, the annular holding plate 25 having holes is moved downward beyond the muzzle 15.

The annular cylinder 27 has a plurality of inner diameters inside.
It has 29 rings and forms the coolant sample duct. The inner diameter 29 is countersunk at the lower end,
Receive 15 contact tips. The annular cylinder 27 is provided with a plurality of muzzles so that the respective muzzles are installed in the corresponding bearings to prevent the liquid from leaking to the corresponding bearings and prevent the liquid from leaking to the corresponding inner diameters 29. It is moved downward beyond 15 and installed on the annular holding plate 25. The annular cylinder 27 is fixed to the annular flange 11 with bolts. The inner diameter 29 extends vertically to the height of the annular cylinder 27 and is inclined in the axial direction of the annular cylinder 27. Thereby, it joins with the inner diameter 31 of the annular cylinder 27 and terminates as a port. The inner diameter 29 in the outer ring terminates at the location of the inner diameter 31 of the annular cylinder 27 which is higher than the inner ring inner diameter. Thereby, in the illustrated embodiment, there are six levels of different ports (ports 33-4).
3) is at the height of the inner diameter 31. These six levels are shown in Figure 2 (a).

The selector valve 45 is installed inside the inner diameter 31. The selector valve 45 has a longitudinal shaft 47 with three radially projecting lugs 49, 51, 53.
The three radially projecting lugs are also installed at 120 ° intervals around the longitudinal shaft. It should be noted that the line 2-2 of the cross section of FIG. 4 is not a straight line, but for the sake of simplicity of the figure. The lug 49 is formed by a selector block 55 made of hard-faced steel and is mounted against the wall of the inner diameter 31. The selector block 55 has a vertical outer surface corresponding to the vertically extending recess 57.
Prepared within 59. The recess 57 comprises a tapered portion 61 connected to the inner diameter 63 in the lug 49 and extending to the shaft 47. The inner diameter 63, which will be described later, is a device 65 for monitoring fission-causing substances in the coolant sample.
Is combined with. Each of the lugs 51 and 53 comprises a spring loaded plunger 67 and 69 respectively. The spring loaded plungers 67 and 69 are mounted against the wall of the annular cylinder 27 around the inner diameter 31. This prevents the selector block 55 from being connected to the wall of the annular cylinder 27. The entire selector device is surrounded by a vertical cylinder 71 and is isolated from the annular flange 11.

Further, referring to FIG. 5, the shaft 47 is
A spiral annular linear induction pump (H) that pumps the sample from the inner diameter 63 of the shaft 47 and sends it to the fissile material monitoring unit 65.
It is firmly fixed to the lower end of the ALIP 73 hangar. The operation of the selector valve 45 is operated by the floor motor 75 that rotates the housing 73 of the spiral annular linear induction pump 73. Therefore, since the angle corresponding to the interval of the ports 33 to 43 around the inner diameter 31 increases, the shaft 47 and the shaft 47 are moved up and down to bring the selector block 55 to one of the three required levels. Requires a hydraulic application or other jacking device 77 to be installed. It will be understood from FIG. 2 (a) that the selector block 55 can be connected to two different levels of the discharge port at each of the height installation positions of the selector block 55.

In the operation of the damaged fuel detection / position determination (FFDL) unit, the selector valve 45 is installed at the corresponding lowermost portion by the jack device 77, and the floor motor 75 stairs from each position to the next position. Is rotated into a shape. The selector valve 45 is connected to the jack device 77.
Is moved upward by and the stepwise rotation is repeated. By the upward movement and the stepwise rotation again, each of the extraction pipes 17 is sequentially connected to the inner diameter 63, and from there, is also connected to the fissile material monitoring unit 65. In this way, the position and level can be omitted by the controller and the selected group of assemblies is scanned (eg high burnup assemblies). Fissile material monitoring unit 65
Will alert if the sample has a pre-determined level of fissionable material and will immediately indicate by the position of the selector valve 45 which sample is being monitored. Therefore, the assembly is equipped with damaged fuel pins.

When the selector block 55 is aligned with one port, the remaining ejection ports eject sample to the inner diameter 31. Thereby the inner diameter 31 will carry the sample from all of the remaining extraction pipes. This sample passes through the gap between lugs 49, 51 and 53,
It is fed to the inner diameter 79 of the lower cylinder 9. From there it is returned to a coolant store (not shown). The reference extraction pipe 81, which is one of the discharge ports, is not connected to the fuel assembly unit. However, it bends upwards towards the path of the coolant that passes through the inner diameter 79. Thereby, a sample of the mixture is generated, and the mixture is sequentially sent to the fissile material monitoring unit 65 via the port 33. Selector valve 45 is shown in FIG. 2 in a position to receive a sample of the mixture.

In the particular configuration of multiple inner diameters of the annular cylinder 27 shown in FIG. 3, the required number of inner diameters is provided even though each of the five inner diameter rings has 28 inner diameters. It Similarly, if the level of the port inside the wall around the inner diameter 31 is more or less than 6,
At least two levels are provided.

To provide a further miniaturized brewing device by providing an annular cylinder 27 having multiple ports of varying levels up to the height of the inner diameter 31 and a rotatable and movable selector valve at that level. You can

[0019]

According to the present invention, in a liquid coolant extraction apparatus, it is possible to reduce the area of a straight plane for installing the coolant extraction pipe and its port.

[Brief description of drawings]

FIG. 1 is a schematic plan view showing a central portion of a liquid metal cooled nuclear reactor.

FIG. 2 is a schematic longitudinal cross-sectional view showing the apparatus for extracting a coolant of the present invention, which is taken out along line 2-2 of FIG.

FIG. 3 is a lateral cross-sectional view taken along line 3-3 of FIG.

FIG. 4 is a transverse cross-sectional view showing a portion of the upper central structure of a nuclear reactor of the present invention.

FIG. 5 is a longitudinal cross-sectional view showing a portion of the lower central structure of a nuclear reactor of the present invention.

[Explanation of symbols]

 1 Central part 3 Fuel assembly part 5, 7 Damaged fuel detection / positioning unit 9 Lower cylinder 11 Annular flange 13 Opening 15 Mouth ring 17 Extraction pipe 19 Split annulus pipe 21, 23 Groove 25 Annular holding plate 27 Annular cylinder 29, 31, 63, 79 Inner diameter 33, 35, 37, 39, 41, 43 Port 45 Selector valve 47 Vertical shaft 49, 51, 53 Lug 55 Selector block 57 Recess 59 Vertical outer surface portion 61 Tapered portion 65 Fissionable material monitoring portion 67, 69 Spring-loaded plunger 71 Vertical cylinder 73 Pump compartment 75 Floor motor 77 Jack device 81 Reference extraction pipe

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Ronald Barr UK 8 PF, Lancacia, Berii, Answers, Alexander Drive 47

Claims (9)

[Claims] 1. A fuel extraction apparatus, wherein the apparatus is a cylinder having an inner diameter parallel to an axis, and a plurality of ducts are provided inside a wall, each duct having an inlet port at one end face of the cylinder, Further, a discharge port is provided on the surface of the inner diameter, the discharge port is provided around the inner diameter at least two different distances from the one end surface of the cylinder, and the respective discharge ports. Is sequentially connected to the fuel discharge path, is rotatable inside the inner diameter, is movable in the axial direction of the inner diameter, and sequentially aligns the respective discharge ports and the extraction nozzles. A fuel extraction device having a selector valve. 2. A broken fuel detection device for a reactor cooled by liquid metal, wherein the device comprises a plurality of extraction pipes for extracting the corresponding fuel or the coolant having passed through the breeder reactor assembly, respectively. Each duct has an inlet port on one end surface of the cylinder,
And a cylinder inside a wall such that a discharge port is provided on the surface of the inner diameter at at least the two different distances from one end face of the cylinder, each extraction pipe, and the plurality of inlet ports. A selector valve that connects the corresponding one of them and the discharge port and the coolant sample discharge path, and is rotatable inside the inner diameter and movable in the axial direction of the inner diameter. And a selector fuel valve for aligning the extraction nozzle and the respective discharge paths to inspect the level of the substance that has undergone nuclear fission in the path. 3. The broken fuel detection according to claim 2, wherein the selector valve has a shaft provided with a lug protruding radially and provided with the extraction nozzle. apparatus. 4. The device of claim 3, wherein the device further comprises two lugs projecting from the shaft, the two added lugs being provided on a surface of the inner diameter. A broken fuel detection device comprising a plunger having a spring for contacting the nozzle with the surface of the inner diameter. 5. The apparatus according to any one of claims 2 to 4, wherein the plurality of discharge ports feed the sample to the inner diameter except when aligned with the extraction nozzle. A broken fuel detecting device, wherein a coolant extraction pipe and a corresponding duct are added in the cylinder to extract the coolant inside the inner diameter. 6. The apparatus according to claim 2, wherein each of the inlet ports has a counterbore end portion of the corresponding duct, and the coolant extraction pipe. And the means for connecting the inlet port has a mouth ring corresponding to the end of each extraction pipe, the mouth ring having a contact tip stored in the countersunk area of the corresponding duct. Damaged fuel detection device characterized by being. 7. The broken fuel detection device according to claim 1, further comprising a stepping motor unit for rotating the selector valve inside the inner diameter. 8. The damaged fuel detecting device according to claim 1, further comprising a jack device for moving the selector valve in an axial direction of the inner diameter. 9. The damaged fuel detection device according to claim 8, wherein the jack device is changed by water pressure.