KR20090021474A - Spacer grid with protruding strap to insert into the flow hole for the debris filtering - Google Patents

Abstract

A spacer grid capable of filtering foreign material flowing through flow hole is provided to minimize pressure drop due to cooling water by increasing size of a flow hole. A spacer grid comprises a strip(2), a dimple(24), and an arch(23). A slot is formed in the strip. The strip partitions a plurality of grid cells. A cut-out part is formed from a bottom center of a grid surface of the grid cell toward a top. Two pair of dimples are formed on a top of the grid surface. The dimple supports a lower end cap(14) of a nuclear fuel rod. The arch is protruded in a right and a left of a cut-out surface of the grid surface, and partitions a space of a flow hole(12). A diameter of a foreign material passing the flow hole is minimized.

Description

Spacer grid with protruding strap to insert into the flow hole for the debris filtering}

The present invention relates to a foreign matter filtration device of a nuclear fuel assembly, and specifically, to filter foreign substances introduced through the lower stationary passage hole along with the cooling water on the lower stationary body of the nuclear fuel assembly, and at the same time, a minimum flow rate in the flow direction of the cooling water. It relates to a filtration device having a resistance cross section to minimize the pressure drop.

A nuclear reactor is a device made to be used for various purposes such as generating heat by producing artificial fission reaction of fissile material, producing radioisotopes and plutonium, or forming a radiation field.

In general, light water reactors use enriched uranium with an increased ratio of uranium-235 to 2-5%. In order to process the nuclear fuel used in nuclear reactors, uranium is molded into cylindrical pellets weighing about 5g. Hundreds of these pellets are bundled in bundles, charged in a vacuum in a zircaloy cladding tube, spring and helium gas are put therein, and the upper rod stopper is welded to make fuel rods. The fuel rods finally form a fuel assembly and are burned through a nuclear reaction in the reactor.

The fuel assembly and its components are shown in [FIG. 1], [FIG. 2] and [FIG. 3]. FIG. 1 is a schematic view showing a general fuel assembly, FIG. 2 is a plan view of a support grid from above, and FIG. 3 is a cutaway perspective view showing the support grid in detail.

Referring to FIG. 1, the fuel assembly includes a skeleton composed of an upper fixing body 4, a lower fixing body 5, a guide tube 3, a measuring tube 8, and a support grid 2. Supported by springs 6 (see [FIG. 2] and [FIG. 3]) and dimples 7 (see [FIG. 2] and [FIG. 3]) which are inserted into the support grid 2 and formed in the support grid 2 It consists of the fuel rod (1). In order to prevent scratches on the surface of the fuel rod (1) and to prevent damage to the spring (6) in the support grid, the locker is applied to the surface of the fuel rod, charged into the skeletal body, and then fixed by attaching the upper and lower fixing bodies. After the assembly of the nuclear fuel assembly is completed, the assembly manufacturing process is completed by removing the lockers of the completed assembly and inspecting the spacing, warpage, electrical length, and dimensions between the fuel rods.

Referring to FIG. 2 and FIG. 3, the support grid 2 includes slots each having a predetermined thickness of a strap to partition a space in which a plurality of fuel rods 1 can be charged. (26; see FIG. 6) are mutually bonded to form a lattice shape. The support grids are arranged about 10 to 13 up and down, and a guide tube (not shown) having a length of 4 m is welded to the sleeve 3 formed on the support grid. Springs 6 and dimples 7 are regularly formed in each space portion partitioned by the support grid 2, and the springs 6 and dimples 7 are fuel rods 1 (see Fig. 1). By keeping in contact with the fuel rods 1 (see FIG. 1), the fuel rods 1 are fixed by the elasticity of the springs 6 and arranged in a predetermined position.

The fuel assembly thus completed emits heat by nuclear fission in the reactor, and the heat generated from the fuel assembly is absorbed by the coolant. Cooling water circulates the reactor and reactor piping by a reactor cooling pump and promotes heat transfer from the nuclear fuel assembly to the cooling water.

On the other hand, foreign matter introduced into the reactor along with the cooling water during the circulation of the cooling water, including fragments and debris such as metal particles, chips, and shavings during the production, installation, and repair of piping and cooling facilities. Various kinds of foreign matters may be mixed in the cooling water, and these foreign matters pass through the passage holes of the lower fixing body, causing micro vibration between the fuel rods and the support lattice and damaging the cladding of the fuel rods.

In order to solve the above problems, as shown in [FIG. 4], the method of restricting the size of the passage hole 12 of the lower fixing body 5 and the foreign matter filtration support lattice dedicated to foreign matter filtration as shown in [FIG. 5] ( 13) or a combination of the bottom fixing channel hole and the support grid for filtering foreign substances are used.

The method of limiting the passage hole size of the lower fixing body of the foreign matter filtering device has an advantage that it is easy to apply in a relatively simple method, but there is a disadvantage that the pressure drop increases due to the reduction of the passage area compared to the improvement of the foreign matter filtering performance. When the pressure of the coolant drops, the hydraulic uplift force must be increased to increase the pressing force of the upper stationary spring, and the fretting wear can be increased by intensifying the vibration of the nuclear fuel rod or by causing the coolant's lateral flow. There are disadvantages to this, which do not absorb enough heat from the fuel rods.

In the case of using a support grid for filtering foreign substances with the lower fixing body, there is an advantage that the pressure drop is relatively small while increasing the foreign matter filtration performance, but the number of parts is increased.

An example of using the above-described support grid for filtering foreign substances is 'US Patent US4652425' `` Bottom grid mounted debris trap for a fuel assembly '' filed on August 8, 1985 (hereinafter referred to as prior art).

Referring to FIG. 5, the prior art has four lattice cells forming a unit lattice cell with dimples 15 supporting the lower end caps 14 of the nuclear fuel rods on the lower support lattice 13 of the support lattice. It is configured on each side to prevent foreign matter from entering the effective section in the fuel assembly with the support of the nuclear fuel rods 14.

In order to prevent the inflow of foreign matter, a more complicated dimple structure or a larger cross-sectional area can be used to reduce the cross-sectional area through which foreign matter can pass. However, since the pressure drop of the cooling water is proportional to the cross-sectional area of the grid as viewed in the axial direction, the structure of the dimple cannot be unconditionally complicated or the area of the cross-sectional area can be increased.

From the above problems or needs,

An object of the present invention is to provide a means for preventing the inflow of foreign substances while at the same time securing the bottom fixing body and the coupling strengthening means.

In addition, an object of the present invention is to provide a means for minimizing the maximum diameter of the foreign matter while minimizing the pressure drop caused by the cooling water by increasing the size of the passage hole.

In order to achieve the above technical problem,

Protruding foreign matter filtration support grid is inserted into the flow path hole according to the present invention is provided on the bottom fixing body 5 is formed with a plurality of flow path holes 12 to filter the foreign material consists of a strip and includes dimples and arches do.

The strip is formed in a plate shape having a predetermined length, slots 26 having a width equal to the plate thickness are formed at regular intervals, and the plurality of unit grid cells are divided by mutually combining the slots arranged at regular intervals in the horizontal and horizontal directions. In the case of partitioning the lattice cells, the thickness and the predetermined height of the minimum thickness from the inner circumferential surface of the flow path hole 12 to the inner circumferential surface of the neighboring flow path hole 12 are directed upward from the bottom center of each lattice plane constituting the unit grid cell. A cutout portion 22 having a shape is formed, and the cutout portion 22 accommodates a portion that forms the shortest thickness between the inner circumferential surface of the flow path hole 12 and the inner circumferential surface of the adjacent flow path hole.

Dimples are formed on each of the lattice planes forming the unit cell, and a total of two pairs are formed to face each other to support the lower end caps 14 of the nuclear fuel rods on the same plane perpendicular to the central axis in the axial direction.

The arches are projected one on each of the left and right sides of the cutouts 22 of the lattice plane constituting the unit grid cell, and are formed on the same plane perpendicular to the central axis in the axial direction, and pass through the space of the flow path hole 12. Space the passageway holes to minimize the diameter of any foreign material that may be present.

Furthermore, the arch can be formed into an arcuate thin plate.

From the structural features of the present invention described above,

The present invention can prevent the inflow of foreign substances at the same time to strengthen the bonding force with the lower fixing body.

In addition, the present invention can minimize the maximum diameter of the inflow of foreign matter by providing a strap protruding in the passage hole while minimizing the pressure drop by the cooling water by increasing the size of the passage hole.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Unless otherwise defined or mentioned, terms indicating directions such as 'up, down, left and right' used in the present description are based on the states indicated in the drawings.

On the other hand, each space part divided by the lattice structure of the support grid is called a unit lattice cell, and one surface inside the lattice cell is defined as a lattice plane. If one lattice plane is defined as the longitudinal direction, all lattice planes parallel to the lattice plane become longitudinal lattice planes, and the lattice plane perpendicular to the longitudinal lattice plane is referred to as a transverse lattice plane. The axial direction refers to the direction in which the nuclear fuel rod is charged as the longitudinal direction of the unit cell.

The support grid for foreign material filtration according to the present embodiment is composed of a plurality of straps 2, dimples 24, and arches 23.

The strap 2 is demonstrated with reference to FIG.

The strap 2 is formed of a thin plate of elongated plate shape. A plurality of such straps 2 are provided to form slots 26 at predetermined intervals, respectively. Then, the straps 2 are arranged to cross each other in the longitudinal direction, that is, at right angles, and then the slots 26 are inserted into each other. As a result, there is a lattice structure having an interval equal to the arrangement interval of the slots 26. Each rectangular space part constituting the lattice structure is referred to as a unit lattice cell as described above. A plan view of the unit grid cell as seen from above is shown in FIG. 7.

Meanwhile, as described above, the support grid formed by the strap 2 is provided with a portion to which the guide tube 3 and the measurement tube 8 are connected, which is the same as a known support grid, and thus detailed description thereof will be omitted.

An incision 22 is formed from the center of the lower end of each lattice plane constituting the unit lattice cell toward the top. The cutout 22 is a portion for inserting the shortest thickness portion between the flow path holes 12 as shown in FIGS. 8 to 9 later. Therefore, the cutout portion 22 has a thickness and a predetermined height that are the shortest from the inner circumferential surface of the flow path hole 12 to the inner circumferential surface of the neighboring flow path hole 12. In this case, the predetermined height means a depth into which the flow path hole 12 is inserted and can be determined as necessary.

The dimple 24 is demonstrated with reference to FIG. 6 and FIG.

The dimples 24 are formed on each of the lattice planes 2 constituting the unit lattice cells. Also, a total of two pairs of dimples 24 are formed to face each other on the same plane perpendicular to the central axis in the axial direction. Therefore, since the dimple 24 has a total of two pairs formed at right angles in one unit lattice cell as shown in [FIG. 7], when the lower end stopper 14 is inserted into the unit lattice cell, the lower end stopper 14 is stably. Will be supported.

On the other hand, since the detailed structure of the dimple 24 is the same as the well-known dimple 24, detailed description is abbreviate | omitted here.

The arch 23 will be described with reference to FIGS. 6 to 8.

The arch 23 is formed in a thin plate shape and an arc shape as shown in [FIG. 7]. In addition, the arch 23 is formed on the left and right for each incision 22, as shown in Figure 6, at this time is formed on the same plane perpendicular to the axial central axis space of the flow path hole 12 The space of the flow path hole is partitioned to minimize the diameter of foreign matter that can pass through. That is, the diameter of the foreign matter that can pass through the passage hole 12 varies depending on the degree of protrusion and radius of curvature of the arch 23.

Hereinafter, the operation by the present embodiment will be described.

As described above, the foreign material filtration support grid according to the present embodiment is supported by two pairs of dimples 24 when the lower end cap 14 of the nuclear fuel rod is inserted.

In addition, the support grid for foreign matter filtration according to the present embodiment is inserted into the passage hole 12 penetrating the lower fixing body 5 in the axial direction. At this time, one unit lattice cell spans four flow path holes 12 as shown in FIG. 7, and on the other hand, one flow hole 12 is shown in FIG. 9. Four unit grid cells are covered.

That is, as shown in FIG. 7, the flow path holes 12 are divided into four by the straps 2, and two arches 23 are provided in each of the four-divided unit grid cells, and the flow path holes are divided into four equal parts. Is partitioning again. Therefore, when the coolant is circulated by the operation of the reactor and passes through the flow path hole 12 from the lower portion of the lower fixture 5, the large diameter is formed by the strap 2 and the arch 23 that partition the flow path hole 12. Foreign matters that they have cannot pass.

As mentioned above, although the preferred embodiment of the present invention has been described, the technical idea of the present invention is not limited to the above-described preferred embodiment, and is inserted into various flow path holes without departing from the technical idea of the present invention specified in the claims. It can be implemented as a support grid for protruding foreign matter filtration.

1 is a schematic view showing a general fuel assembly.

2 is a plan view showing a general support grid.

3 is a cutaway perspective view showing a general support grid.

4 is a perspective view showing a general lower fixing body.

5 is a plan view showing a support grid for filtering foreign substances in the related art.

6 is a front view showing a part of a strap forming a support grid according to the present invention.

7 is a plan view showing a unit grid cell of the foreign material filter according to the present invention.

8 is a perspective view showing a state in which the unit grid cell of the foreign material filter body according to the present invention is inserted into the flow path hole.

Figure 9 is a bottom perspective view showing a part of the foreign body filter according to the present invention combined with the lower fixed body.

<Description of the symbols for the main parts of the drawings>

1 fuel rod 2 support grid

3: sleeve 4: top fixture

5: lower fixing body 6: support grid spring

7: support lattice dimple 8: measuring tube

12: Flow hole 14: Fuel rod lower end cap

23: arch 24: dimple

Claims (2)

In the support grid for filtering foreign matter is provided on the lower fixed body (5) having a plurality of flow path holes 12, It is formed in a plate shape having a predetermined length, a slot 26 having a width as much as the plate thickness at a predetermined interval is formed, and arranged in a certain interval vertically and horizontally to combine a plurality of unit grid cells by partitioning a plurality of unit grid cells, In the case of dividing the cell, the cell has a thickness and a predetermined height from the inner bottom surface of the flow path hole 12 to the inner peripheral surface of the neighboring flow path hole 12 from the bottom center of each lattice plane constituting the unit grid cell to the top. A strip (2) having a cutout (22) formed therein, the strip (2) accommodating a portion having a shortest thickness between the inner circumferential surface of the flow path hole (12) and the inner circumferential surface of a neighboring flow path hole;  Dimples 24 are formed on each of the lattice planes forming the unit lattice cells, and a total of two pairs are formed to face each other to support the lower end caps 14 of the nuclear fuel rods on the same plane perpendicular to the central axis in the axial direction. ; And One projecting part of each of the cutouts 22 of the lattice plane forming the unit grid cells is formed on the same plane perpendicular to the central axis in the axial direction, and can pass through the space of the flow path hole 12. Protruding foreign matter filtration support grid is inserted into the passage hole including an arch (23): partitioning the space of the passage hole to minimize the diameter of the foreign matter. The method of claim 1, The arch is a support grid for protruding foreign matter filtration is inserted into the passage hole formed of an arc-shaped thin plate.

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