KR20060058474A - Permanent reactor cavity seal assembly - Google Patents

Abstract

The reactor cavity permanent watertight seal body according to the present invention is provided between the reactor structure in which the reactor vessel is accommodated, and the concrete structure having a reactor tank formed on top of the reactor cavity and a reloading tank containing the reloading water when the nuclear fuel is reloaded. A permanent joint sealing body for preventing the reactor cavity from being submerged in the reloading water, the permanent joint sealing body comprising: an annular upper sealing body disposed to block between the reactor vessel and the concrete structure over the entire circumference of the reactor vessel; The upper end is fixed to the upper seal body throughout the inner circumference of the upper seal body and the lower end is fixed to the reactor vessel over the circumference of the reactor vessel, the inner wall portion and the upper end of the inner wall portion A first inner flange portion extending radially inwardly of the inner wall portion and fixed to the upper sealing body, and a second inner flange portion extending radially inward of the inner wall portion from the lower end of the inner wall portion and fixed to the reactor vessel; Inner flexible plate having; An outer wall part of which an upper end is fixed to the upper sealing body throughout the outer circumference of the upper sealing body, and the lower end thereof is fixed to the concrete structure throughout the circumference of the concrete structure, and the outer wall part fixed to the upper sealing body; An outer flexible plate having an outer flange part fixed to the concrete structure by extending from the lower end of the outer wall part to the radially outer side of the outer wall part; And a support having an upper end coupled to the upper seal and a lower end coupled to any one of the reactor vessel and the concrete structure to support the upper seal. As a result, the load generated in accordance with the external environment such as thermal expansion of the reactor vessel, earthquake, and water pressure due to reloading is appropriately distributed and supported, thereby improving durability of the reactor joint permanent watertight seal body.

Reactor cavity, Reloading water tank, Inner flexible plate, Outer flexible plate, Reactor joint permanent water seal

Description

Permanent reactor cavity seal assembly

1 is a view showing a state in which the reactor vessel is installed in the concrete structure and the reloading water is filled.

FIG. 2 is a schematic enlarged view of portion A of FIG. 1 showing a state where a conventional reactor cavity permanent watertight seal is installed.

Figure 3 is a perspective view schematically showing a reactor joint permanent watertight seal according to an embodiment of the present invention.

FIG. 4 is a schematic enlarged view of portion A of FIG. 1 showing a state in which the reactor cavity permanent water seal body shown in FIG. 3 is installed.

FIG. 5 is a schematic enlarged view of portion A of FIG. 1 showing a state in which a permanent joint seal of a reactor cavity according to another embodiment of the present invention is installed.

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

30.Concrete structures 32.Material transfer

33.Reinforcement plate 41 ... Nuclear fuel

42.Reactor reactor 50.Upper seal

51.Top sealing plate 52 ... Ventilation cover

60 ... inner flexible plate 70, 71 ... outer flexible plate

80.Support 81.Inner vertical support

82 ... outer vertical support 83 ... horizontal support

1, 100, 200 ... Permanent joint watertight seal

301 ... reactor joint 302 ... refilling tank

421 Flange of reactor vessel 511 Ventilation

521 Bolt 601 Inner Wall

602 ... 1st inner flange part 603 ... 2nd inner flange part

701, 711.outer wall part 702.outer wall part

712 ... 1st outer flange part 713 ... 2nd inner flange part

The present invention relates to a permanent water-tight seal of a nuclear reactor, and more particularly, to improve the structure so that the load generated according to the external environment such as thermal expansion of the reactor vessel, earthquake, and hydraulic pressure due to reloading can be properly distributed and supported. The present invention relates to a reactor joint permanent watertight seal.

Nuclear power plants generate electricity using heat generated by nuclear fission of nuclear fuel. After a certain time, new nuclear fuel must be supplied to the reactor.

Figure 1 shows the reactor vessel is installed in the concrete structure and the reloading water is filled. As shown in FIG. 1, the concrete structure 30 generally includes a reactor cavity 301 in which the reactor vessel 42 is accommodated, and a reloading tank 302 provided on an upper portion of the reactor cavity 301. .

The reactor cavity water-tight seal 1 installed between the reactor vessel 42 and the concrete structure 30 before reloading the nuclear fuel 41 has boron in the reload tank 302 for cooling and shielding the nuclear fuel. When filling the added reload 32, the reactor cavity 301 is prevented from submerging in the reload 32. On the other hand, reference numeral 100 described in parentheses in Figure 1 is intended to indicate the reactor joint permanent watertight seal according to the present invention.

In the past, such a reactor joint watertight seal was temporarily installed only when nuclear fuel was reloaded, and then removed and stored again when the reloading was completed. In this case, it takes much time to install and remove the reactor watertight seal. Several problems have arisen, such as the need to store the removed reactor cavity watertight seal in a radioactive barrier. In order to solve this problem, a reactor joint permanent watertight seal was designed to be permanently fixed between the flange portion of the reactor vessel and the bottom of the reload tank, and this seal is disclosed in Korean Patent Publication No. 150,110.

As shown in FIG. 2, the reactor joint permanent watertight sealing body 1 includes an annular upper sealing plate 11, an inner annular watertight body 12, an outer annular watertight body 13, and a c-shaped inner side. The flexible plate 14, the vertical support 15, and the support arm 16 are provided.

The upper sealing plate 11 is formed with at least one ventilation hole 111 formed through the upper sealing plate 11, the cover 18 for opening and closing the ventilation hole 111 is the upper sealing. It is coupled to the plate 11 by bolts 17. The inner annular watertight body 12 and the outer annular watertight body 13 are coupled by bolts 15 to the flange portion 421 of the reactor vessel 42 and the reinforcement plate 33 of the concrete structure 30, respectively. do. The upper end of the N-shaped inner flexible plate 14 is fixed to the upper sealing plate 11 by welding, and the lower end thereof is coupled to the inner annular watertight body 12. An upper end of the vertical support 15 is fixed to the upper sealing plate 11 by welding, and a lower end thereof is coupled to the outer annular watertight body 13. The support arm 16 is a cantilever-shaped support structure installed between the lower surface of the upper sealing plate 11 and the concrete structure 30.

However, as described above, the permanently fixed nuclear reactor watertight seal body has a horizontal load generated by an external environment such as water pressure due to reloading, thermal expansion of the reactor vessel generated during operation of the reactor, and earthquake, etc. It is a weak structure that is supported only by the flexible plate has a problem that the durability is poor. In addition, in order to improve durability, the cross-sectional length of the N-shaped inner flexible plate may be increased, but in order to avoid interference between the reactor joint permanent watertight seal and the fuel reloader used to reload the fuel, the N-shaped inner flexible plate may be used. There is a limit that the height of the plate cannot be made higher than the predetermined height.

The present invention has been made to solve the above problems, an object of the present invention, so that the load generated according to the external environment, such as thermal expansion of the reactor vessel, earthquake, water pressure due to reloading water can be properly distributed and supported. It is to provide a reactor joint permanent watertight seal with improved structure.

In order to achieve the above object, the reactor cavity permanent watertight sealing body according to the present invention is a concrete structure having a reactor cavity in which a reactor vessel is accommodated and a reloading tank which is formed on top of the reactor cavity and contains a reloading water when reloading nuclear fuel. And a reactor joint permanent watertight seal provided between the reactor vessel and the reactor vessel to prevent the reactor cavity from being submerged in the reloading water, wherein the reactor cavity is disposed to cover the reactor vessel and the concrete structure over the entire circumference of the reactor vessel. An annular upper sealing body; The upper end is fixed to the upper seal body throughout the inner circumference of the upper seal body and the lower end is fixed to the reactor vessel over the circumference of the reactor vessel, the inner wall portion and the upper end of the inner wall portion A first inner flange portion extending radially inwardly of the inner wall portion and fixed to the upper sealing body, and a second inner flange portion extending radially inward of the inner wall portion from the lower end of the inner wall portion and fixed to the reactor vessel; Inner flexible plate having; An outer wall part of which an upper end is fixed to the upper sealing body throughout the outer circumference of the upper sealing body, and the lower end thereof is fixed to the concrete structure throughout the circumference of the concrete structure, and the outer wall part fixed to the upper sealing body; An outer flexible plate having an outer flange part fixed to the concrete structure by extending from the lower end of the outer wall part to the radially outer side of the outer wall part; And a support coupled to the upper seal and the lower end coupled to any one of the reactor vessel and the concrete structure so as to support the upper seal.

In addition, in order to achieve the above object, another type of reactor cavity permanent watertight sealing body according to the present invention is formed in the reactor cavity in which the reactor vessel is accommodated and the reloading tank in which the reloading water is accommodated when the nuclear fuel reload is accommodated A reactor joint permanent watertight seal installed between a concrete structure having a reactor and the reactor vessel to prevent the reactor cavity from submerging in the reloading water, the reactor vessel and the concrete structure over the entire circumference of the reactor vessel An annular upper sealing body disposed to close the gap; The upper end is fixed to the upper seal body throughout the inner circumference of the upper seal body and the lower end is fixed to the reactor vessel over the circumference of the reactor vessel, the inner wall portion and the upper end of the inner wall portion A first inner flange portion extending radially inwardly of the inner wall portion and fixed to the upper sealing body, and a second inner flange portion extending radially inward of the inner wall portion from the lower end of the inner wall portion and fixed to the reactor vessel; Inner flexible plate having; An upper end thereof is fixed to the upper seal body throughout the outer circumference of the upper seal body and the lower end thereof is fixed to the concrete structure throughout the circumference of the concrete structure, the outer wall portion and the outer wall at the upper end of the outer wall portion. A first outer flange part extending radially outwardly of the body part and fixed to the upper sealing body, and a second outer flange part extending radially outwardly of the outer wall part from the lower end of the outer wall part and fixed to the concrete structure Outer flexible plate having; And a support coupled to the upper seal and the lower end coupled to any one of the reactor vessel and the concrete structure so as to support the upper seal.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a state in which a reactor vessel is installed on the concrete structure and the reloading water is filled, Figure 3 is a perspective view schematically showing a reactor joint permanent watertight sealing body according to an embodiment of the present invention, Figure 4 3 is a schematic enlarged view of a portion A of FIG. 1 showing a state in which the reactor joint permanent watertight seal shown in FIG. 3 is installed.

1, 3 and 4, the reactor cavity permanent watertight seal 100 according to an embodiment of the present invention is installed between the concrete structure 30 and the reactor vessel 42, in this embodiment The reinforcing plate 33 of the metal material installed in the concrete structure 30 and the flange portion 421 of the reactor vessel 42 is installed. The concrete structure 30 is formed on top of the reactor cavity 301 in which the reactor vessel 42 is accommodated, the reactor cavity 301 is reloaded to accommodate the reloading water 32 when the nuclear fuel 41 is replaced A water tank 302 is provided. The reactor cavity permanent watertight seal 100 prevents the reactor cavity 301 from being submerged in the reloading water 32. The reactor cavity permanent watertight seal 100 includes an upper seal body 50, an inner flexible plate 60, an outer flexible plate 70, a support 80, and a horizontal support 83.

The upper sealing body 50 is to block between the reactor vessel 42 and the concrete structure 30 over the entire circumference of the reactor vessel 42. The upper sealing body 50 is annular. The upper sealing body 50 includes an upper sealing plate 51 and a vent cover 52.

The upper sealing plate 51 is an annular structure manufactured by welding several pieces of metal plates, for example, stainless steel. The upper sealing plate 51 is formed with a ventilation hole 511 penetrating the upper sealing plate 51. The ventilation hole 511 may have various shapes such as circular, elliptical, and square according to the size of the upper sealing plate 51. In the present embodiment, the ventilation holes 511 are formed in the upper sealing plate 51 at six intervals equal to each other. The ventilation hole 511 is a portion for allowing the reactor cavity 301 and the reloading water tank 302 to communicate with each other. When the reloading of the nuclear fuel 41 is completed, air in the reactor cavity 301 is circulated through the ventilation hole 511 during operation of the reactor.

The vent cover 512 is installed to open and close the vent hole 511. The vent cover 512 is detachably coupled to the upper sealing plate 51 by screwing. In the present embodiment, six ventilation cover 512 is provided, and each ventilation hole cover 512 is coupled to the upper sealing plate 51 by ten bolts 521 so that each ventilation hole ( 511 is closed. The vent cover 512 is installed to close the vent hole 511 when the nuclear fuel 41 is reloaded, and is removed to open the vent hole 511 during operation of the reactor.

The inner flexible plate 60 is made of a thin steel sheet such as a flexible material, for example, stainless steel, to absorb horizontal loads generated by thermal expansion of the reactor vessel 42, seismic load, hydraulic pressure of the reloading water 32, and the like. do. The upper end portion of the inner flexible plate 60 is fixed by welding to the upper seal body 50 over the entire inner circumference of the upper seal body 50, and the lower end portion of the inner flexible plate 60 covers the entire circumference of the reactor vessel 42. It is fixed to the reactor vessel 42 by welding. The inner flexible plate 60 includes an inner wall portion 601, a first inner flange portion 602, and a second inner flange portion 603. The first inner flange portion 602 extends from the upper end of the inner wall portion 601 to the radially inner side of the inner wall portion 601 and is fixed to the upper sealing body 50. The second inner flange portion 603 extends radially inward of the inner wall portion 601 from the lower end of the inner wall portion 601 and is fixed to the flange portion 421 of the reactor vessel 42. to be. As the sum of the lengths of the inner wall portion 601, the first inner flange portion 602, and the second inner flange portion 603 increases, the inner flexible plate 60 absorbs the horizontal load well. Can be.

 The outer flexible plate 70 is made of a thin steel plate such as a flexible material, such as stainless steel, to absorb horizontal loads generated by thermal expansion of the reactor vessel 42, earthquake load, hydraulic pressure of the reloading water 32, and the like. will be. The upper end of the outer flexible plate 70 is fixed by welding to the upper sealing body 50 over the entire outer circumference of the upper sealing body 50 and the lower end of the outer flexible plate 70 over the entire circumference of the concrete structure 30. The concrete structure 30 is fixed by welding. The outer flexible plate 70 includes an outer wall portion 701 and an outer flange portion 702. The outer wall part 701 is a part fixed to the upper sealing body 50 by welding. The outer flange portion 702 extends from the lower end of the outer wall portion 701 to the radially outer side of the outer wall portion 701 and is fixed to the reinforcing plate 33 of the concrete structure 30 by welding. . As the sum of the lengths of the outer wall portion 701 and the outer flange portion 702 increases, the outer flexible plate 70 may absorb the horizontal load well.

As described above, the upper sealing body 50, the inner flexible plate 60, and the outer flexible plate 70 are integrally formed by welding, and when the nuclear fuel 41 is reloaded, the reactor vessel 42 and Close between the concrete structure (30). Thus, the reactor cavity 301 is prevented from being submerged in the reload 32.

The support 80 is for supporting the upper sealing body (50). The support 80 supports the vertical load generated by thermal expansion of the reactor vessel 42, earthquake load, water pressure of the reloading water 32, and the like. The support 80 includes an inner vertical support 81 and an outer vertical support 82.

The upper end of the inner vertical support 81 is fixed to the inner side of the upper sealing body 50 by screwing or welding, and the lower end thereof is contacted and supported by the flange portion 421 of the reactor vessel 42. The upper end of the outer vertical support 82 is coupled to the outer side of the upper sealing body 50 by screwing or welding, and the lower end thereof is contacted and supported by the reinforcing plate 33 of the concrete structure 30. As described above, lower ends of the inner vertical support 81 and the outer vertical support 82 are in contact with the flange portion 421 of the reactor vessel 42 and the reinforcing plate 33 of the concrete structure 30, respectively. Therefore, when a load is applied to the reactor cavity permanent watertight seal 100 due to thermal expansion or earthquake of the reactor vessel 42, the vertical supports 81 and 82 are flanged portions of the reactor vessel 42. 421 and the reinforcement plate 33 of the concrete structure 30 can be relatively moved relative.

The horizontal support 83 is for preventing the upper sealing plate 51 from being deformed by the vertical load applied to the upper sealing plate 51. The horizontal support 83 is fixed to the lower portion of the upper sealing plate 51 by screwing or welding.

Hereinafter, the function of the reactor cavity permanent watertight seal 100 of the present embodiment configured as described above will be described.

As shown in FIG. 1 and FIG. 4, the reactor cavity permanent watertight seal 100 is installed in an annular shape so as to close between the reactor vessel 42 and the concrete structure 30. If the reloading water 32 is filled in the reloading tank 302 before reloading the nuclear fuel 41, the reloading water 32 does not flow into the reactor cavity 301 and the inside of the reactor vessel 42 and the reloading tank 302 is maintained to maintain the water level as shown in FIG. In this state, the nuclear fuel 41 is replaced, and after that, the outlet of the bottom of the reloading tank 302 is opened to discharge the reloading water 32. When the reloading of the nuclear fuel 41 is completed as described above, the ventilation hole cover 52 is removed to open the ventilation hole 511 to allow the reactor cavity 301 and the reloading water tank 302 to communicate with each other. Will be activated.

Therefore, the reactor joint permanent watertight seal according to the present invention is permanently installed unlike the conventional temporarily installed reactor reloading water tank seal, there is no need to remove the installed seal and store in the radiation blocking reservoir, once If you do not need to remove it is convenient.

In addition, the reactor joint permanent watertight sealing body 100 according to the present invention includes an inner flexible plate and an outer flexible plate, the flexible plate is a horizontal load generated by the thermal expansion of the reactor vessel, earthquake load, hydraulic pressure of the reloading water, etc. It can disperse | distribute and absorb suitably, and it is excellent in durability compared with the reactor refilling water tank seal body provided with only one conventional N-shaped inner side flexible plate. In addition, the welding portions of each of the inner flexible plate and the outer flexible plate are exposed to the outside to facilitate the welding operation and to easily inspect the welded state.

Meanwhile, in the present exemplary embodiment, the outer flexible plate 70 including the outer wall portion 701 and the outer flange portion 702 is provided. However, as illustrated in FIG. 5, the outer wall portion 711 and the first outer side are provided. A reactor cavity permanent watertight seal 200 having a flange portion 712 and an outer flexible plate 71 having a second outer flange portion 713 may be installed. The first outer flange portion 712 extends from the upper end of the outer wall portion 711 to the radially outer side of the outer wall portion 711 and is fixed by welding to the lower portion of the upper sealing plate 51. The second outer flange portion 713 extends from the lower end of the outer wall portion 711 to the radially outer side of the outer wall portion 711 and is fixed by welding to the reinforcing plate 33 of the concrete structure 30. Part. The sum of the lengths of the outer wall portion 711, the first outer flange portion 712, and the second outer flange portion 713 of the outer flexible plate 71 configured as described above is illustrated in FIG. 4. The outer flexible plate 71 shown in FIG. 5 is larger than the sum of the lengths of the outer wall portion 701 and the outer flange portion 702 of the same outer flexible plate 70, so that the outer flexible plate 71 shown in FIG. The plate 70 can absorb the horizontal load generated by the thermal expansion of the reactor vessel 42, the earthquake load, the hydraulic pressure of the reloading water 32, and the like.

In addition, in the present embodiment, the inner vertical support 81, the outer vertical support 82, and the horizontal support 83 are disposed independently of each other, but both ends of the horizontal support 83 are the inner vertical support. It is connected to the upper end of each of the 81 and the outer vertical support 82 by welding, the inner vertical support 81, the outer vertical support 82, and the horizontal support 83 may be integrally formed. have. As such, when the support 80 is integrally formed, the horizontal support 83 is supported by the lower portion of the upper sealing plate 51, and lower ends of the vertical supports 81 and 82 are respectively The flange portion 421 of the reactor vessel 42 and the reinforcement plate 33 of the concrete structure 30 are respectively fixed by welding. Therefore, when a load is applied to the reactor cavity permanent watertight seal 100 due to thermal expansion or earthquake of the reactor vessel 42, the integrated support 80 is the flange portion 421 of the reactor vessel 42. And relative to the reinforcement plate 33 of the concrete structure 30 can be relatively movable.

As mentioned above, the present invention has been described in detail with reference to preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications may be made by those skilled in the art within the technical idea of the present invention. It is obvious.

The reactor cavity permanent watertight seal body according to the present invention having the above-described configuration is permanently installed unlike the conventional temporarily installed reactor reloading tank seal, so there is no need to remove the installed seal and store it in the radiation blocking reservoir, Once installed, it does not need to be removed.                     

In addition, the reactor joint permanent watertight sealing body according to the present invention includes an inner flexible plate and an outer flexible plate, and the flexible plates are appropriately distributed horizontal load generated by thermal expansion of the reactor vessel, seismic load, hydraulic pressure of the reloading water, etc. Can be absorbed, and the durability is superior to that of the reactor reload tank seal provided with only one conventional N-shaped inner flexible plate. In addition, the welding portions of each of the inner flexible plate and the outer flexible plate are exposed to the outside to facilitate the welding operation and to easily inspect the welded state.

Claims (6)

The reactor cavity is accommodated between the reactor structure and a concrete structure having a reactor cavity for receiving the reactor vessel and a recharging tank that is formed on top of the reactor cavity and accommodates the reloading of the fuel when reloading the nuclear reactor vessel is submerged in the reloading water In the reactor joint permanent watertight seal that prevents An annular upper sealing body disposed to cover the reactor vessel and the concrete structure over the entire circumference of the reactor vessel; The upper end is fixed to the upper seal body throughout the inner circumference of the upper seal body and the lower end is fixed to the reactor vessel over the circumference of the reactor vessel, the inner wall portion and the upper end of the inner wall portion A first inner flange portion extending radially inwardly of the inner wall portion and fixed to the upper sealing body, and a second inner flange portion extending radially inward of the inner wall portion from the lower end of the inner wall portion and fixed to the reactor vessel; Inner flexible plate having; An outer wall part of which an upper end is fixed to the upper sealing body throughout the outer circumference of the upper sealing body, and the lower end thereof is fixed to the concrete structure throughout the circumference of the concrete structure, and the outer wall part fixed to the upper sealing body; An outer flexible plate having an outer flange part fixed to the concrete structure by extending from the lower end of the outer wall part to the radially outer side of the outer wall part; And And a supporter coupled to the upper sealant and the lower end coupled to any one of the reactor vessel and the concrete structure so as to support the upper sealant. The reactor cavity is accommodated between the reactor structure and a concrete structure having a reactor cavity for receiving the reactor vessel and a recharging tank that is formed on top of the reactor cavity and accommodates the reloading of the fuel when reloading the nuclear reactor vessel is submerged in the reloading water In the reactor joint permanent watertight seal that prevents An annular upper sealing body disposed to cover the reactor vessel and the concrete structure over the entire circumference of the reactor vessel; The upper end is fixed to the upper seal body throughout the inner circumference of the upper seal body and the lower end is fixed to the reactor vessel over the circumference of the reactor vessel, the inner wall portion and the upper end of the inner wall portion A first inner flange portion extending radially inwardly of the inner wall portion and fixed to the upper sealing body, and a second inner flange portion extending radially inward of the inner wall portion from the lower end of the inner wall portion and fixed to the reactor vessel; Inner flexible plate having; An upper end thereof is fixed to the upper seal body throughout the outer circumference of the upper seal body and the lower end thereof is fixed to the concrete structure throughout the circumference of the concrete structure, the outer wall portion and the outer wall at the upper end of the outer wall portion. A first outer flange part extending radially outwardly of the body part and fixed to the upper sealing body, and a second outer flange part extending radially outwardly of the outer wall part from the lower end of the outer wall part and fixed to the concrete structure Outer flexible plate having; And And a supporter coupled to the upper sealant and the lower end coupled to any one of the reactor vessel and the concrete structure so as to support the upper sealant. The method according to claim 1 or 2, The upper sealing body, An upper sealing plate having ventilation holes formed therethrough so that the reactor cavity and the reloading water tank communicate with each other; And And a ventilation hole cover detachably coupled to the upper sealing plate to open and close the ventilation hole. The method according to claim 1 or 2, The support, An inner vertical support whose upper end is fixed inside the upper sealing body and whose lower end is supported by the reactor vessel; And The upper end portion is fixed to the outer side of the upper sealing body and the lower end of the reactor vertical permanent watertight sealing body comprising a; vertical support which is supported by the concrete structure. The method of claim 4, wherein Reactor joint permanent watertight sealing body further comprises a horizontal support coupled to the lower portion of the upper sealing body. The method of claim 5, The horizontal support is a reactor joint permanent watertight seal, characterized in that coupled to the upper end of each of the inner vertical support and the outer vertical support.

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