KR20210147508A - Device and method for cooling containment vessel - Google Patents

Abstract

According to an embodiment of the present invention, a cooling device of a containment vessel for cooling an outer wall of the containment vessel may comprise: a lower guide unit disposed to be spaced apart from the outer wall of the containment vessel and guiding seawater to the outer wall of the containment vessel; and an upper guide unit disposed to be spaced apart from the outer wall of the containment vessel, disposed on an upper side of the lower guide unit, and guiding the seawater guided by the lower guide unit to an upper direction.

Description

COOLING DEVICE AND METHOD FOR COOLING CONTAINMENT VESSEL

The present invention relates to a cooling apparatus and a cooling method for a containment vessel, and more particularly, to a cooling apparatus and a cooling method for a containment vessel for cooling a containment vessel of a nuclear power plant.

Nuclear power generation is a method of generating electrical energy by operating the turbine 52 using energy generated during nuclear fission. It does not generate carbon dioxide in the power generation process and can produce enormous electricity with little fuel, so it is adopted as one of the power generation methods in many countries. is being operated.

Such nuclear power generation requires cooling due to the generation of enormous heat. In general nuclear power generation, as shown in FIG. 1 , the enormous thermal energy generated by the nuclear fission of the reactor core 20 in the reactor vessel 10 is generated in the reactor vessel ( 10) is transferred to the coolant, and the coolant is circulated back into the reactor vessel 10 after exchanging heat in the heat exchanger 30 . In addition, the water in the drive system 50 is circulated as a path independent of the coolant, and the heat exchanger 30 generates steam in the drive system 50 as heat absorbed from the coolant, and through this, the turbine 52 After being turned into electric energy by the generator 54, it is condensed back into water and circulated to the heat exchanger 30.

These reactors generate enormous thermal energy, and if the heat of the reactor is not properly cooled due to an unexpected accident, a major accident may occur in which the reactor facility itself is destroyed, which causes radioactive contamination of the surrounding environment in addition to the loss of the facility. It can lead to very dangerous situations that can be done.

Registered Patent Publication No. 10-1433907 (Nuclear emergency cooling system using seawater)

An object of the present invention is to solve the above problems, and to provide a cooling apparatus and a cooling method for a containment vessel that can improve the safety of the containment vessel using seawater waves.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to solve the above problem, the cooling device for a containment vessel according to an embodiment of the present invention is a cooling device for a containment vessel that cools an outer wall of the containment vessel, and is disposed to be spaced apart from the outer wall of the containment vessel, a lower guide portion for guiding to the outer wall of the containment vessel; and an upper guide part disposed to be spaced apart from the outer wall of the containment vessel, disposed on an upper side of the lower guide part, and guiding the seawater guided by the lower guide part in an upward direction; may include

The lower guide portion, the lower surface supported on the seabed; an upper surface inclined at a predetermined angle with respect to the lower surface; And it may have a side spaced apart from the outer wall of the containment vessel to form a seawater passage.

The lower guide part may further include a guide protrusion formed to protrude from the upper surface.

The lower guide portion may include: a first lower guide portion disposed to be spaced apart from the upper guide portion; and a second lower guide part spaced apart from the first lower guide part, wherein a first guide space is formed between the upper guide part and the first lower guide part, and the first lower guide part and the first lower guide part A second guide space may be formed between the two lower guide parts.

The upper guide portion may include: a first upper guide portion disposed to be spaced apart from the outer wall of the containment vessel; and a second upper guide part extending from the first upper guide part and facing the lower guide part, and temporarily storing the guided seawater between the first upper guide part and the second upper guide part A temporary storage space may be formed.

The cooling device of the containment container may further include a support part supporting the lower guide part and the upper guide part.

In addition, a cooling method of a containment vessel according to an embodiment of the present invention is a method of cooling a containment vessel for cooling an outer wall of the containment vessel, the method comprising: a first seawater guide step of guiding seawater to the outer wall of the containment vessel; a second seawater guide step of guiding the guided seawater upward along the outer wall of the containment vessel; And it may include a temporary storage step of temporarily storing the "upward?"* guided seawater.

The cooling method of the containment vessel may further include a third seawater guide step of guiding the temporarily stored seawater downward along an outer wall of the containment vessel.

According to the embodiment of the present invention, since the containment vessel is cooled using seawater, the power supplied to the cooling drive system is minimized, and even if the power supplied to the cooling drive system is cut off, it can operate by itself, thereby improving safety. have.

1 is a diagram schematically showing a conventional nuclear reactor.
2 is a diagram schematically showing a containment vessel according to an embodiment of the present invention.
3 is a cross-sectional view schematically showing a cooling device for a containment vessel according to an embodiment of the present invention.
FIG. 4 is an enlarged view of part A shown in FIG. 3 .
5 is a plan view schematically illustrating a cooling apparatus for a containment vessel according to an embodiment of the present invention.
6 is a perspective view showing a cooling device for a containment vessel according to an embodiment of the present invention.
7 is a diagram schematically illustrating a state in which seawater is guided when the sea level is lowered.
8 is a plan view schematically showing a cooling apparatus for a containment vessel according to another embodiment of the present invention.
9 is a flowchart illustrating a method for cooling a containment vessel according to an embodiment of the present invention.

Hereinafter, various embodiments will be described in more detail with reference to the accompanying drawings. Embodiments according to the present invention can be variously modified. Certain embodiments may be depicted in the drawings and described in detail in the detailed description. However, the specific embodiments disclosed in the accompanying drawings are only provided to facilitate understanding of the various embodiments. Accordingly, the technical spirit is not limited by the specific embodiments disclosed in the accompanying drawings, and it should be understood to include all equivalents or substitutes included in the spirit and scope of the invention.

Terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various components, but these components are not limited by the above-mentioned terms. The above terminology is used only for the purpose of distinguishing one component from another component.

In the embodiments of the present invention, terms such as “comprises” or “have” are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the embodiments of the present invention exist, It should be understood that this does not preclude the possibility of addition or existence of one or more other features or numbers, steps, operations, components, parts, or combinations thereof. When an element is referred to as being “connected” or “connected” to another element, it is understood that it may be directly connected or connected to the other element, but other elements may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

Meanwhile, a “module” or “unit” for a component used in an embodiment of the present invention performs at least one function or operation. In addition, a “module” or “unit” may perform a function or operation by hardware, software, or a combination of hardware and software. In addition, a plurality of “modules” or a plurality of “units” other than a “module” or “unit” to be performed in specific hardware or to be executed in at least one processor may be integrated into at least one module. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be abbreviated or omitted.

2 is a diagram schematically showing a containment vessel according to an embodiment of the present invention.

Referring to FIG. 2 , the containment vessel cooling system according to an embodiment of the present invention includes a first containment vessel 100 , a second containment vessel 200 , a first cooling passage 130 , a pressure equalization tube 214 , and an injection tube. 228 , a saturated vapor pressure cooling chamber 226 , a reference atmospheric pressure chamber 227 , and a second cooling passage 231 .

The first containment vessel 100 may be made of a concrete or metal material. In addition, the first containment vessel 100 is not limited to being made of a concrete or metal material, and may be made of various materials having explosion resistance. The first containment vessel 100 may be buried underground or surrounded by soil L. The first containment vessel 100 may have an Energy Release Space (ERS) in which the nuclear reactor vessel 122 is accommodated.

A nuclear reactor core 124 may be accommodated in the reactor vessel 122 . In addition, steam may be generated in the energy emitting space 110 using heat generated from the nuclear reactor core 124 . In addition, the reactor vessel 122 may include a reactor driving system including a steam generator and a flow path for circulating the steam to an external turbine (not shown).

The second containment vessel 200 may be partitioned from the first containment vessel 100 while being connected to the first containment vessel 100 . In addition, the second containment vessel 200 is not limited to being made of a concrete or metal material, and may be made of various materials having explosion resistance and corrosion resistance. The second containment vessel 200 may be surrounded by water (S) or disposed in water. The water may be, for example, seawater. In addition, the second containment vessel 200 may be provided to form the exterior of the entire cooling system together with the first containment vessel 200 . In addition, the containment vessel may include the first containment vessel 100 and the second containment vessel 200 .

The second containment vessel 200 absorbs the heat transferred from the energy absorbing space 210 (EAS) that receives the pressure of the energy emitting space and the nuclear reactor vessel to receive the second containment vessel 200. It may have an energy transfer space 220 (ETS; Energy Transfer Space) radiating to the outside of the .

The energy absorbing space 210 may be partitioned from the energy emitting space 110 to accommodate a heating medium. The heating medium may be water. The water level of the heating medium of the energy absorbing space 210 may be increased or decreased according to the pressure of the energy emitting space 110 .

The energy transfer space 220 may be partitioned from the energy emitting space 110 while being partitioned from the energy absorbing space 210 . The energy transfer space 220 may be provided above the energy absorption space 210 . A partition wall 201 may be disposed between the energy transfer space 220 and the energy absorption space 210 . The pressure of the energy transfer space 220 may change according to the pressure of the energy release space 110 .

The first cooling passage 130 may transfer the heat of the reactor vessel 122 to the energy transfer space 220 . A heat absorbing medium may be moved in the first cooling passage 130 . The heat absorption medium may be water. A first heat exchanger 132 for absorbing heat from the reactor vessel 122 and a second heat exchanger 134 for dissipating the absorbed heat may be installed in the first cooling passage 130 . The heat absorbing medium may absorb heat from the first heat exchanger 132 and release heat from the second heat exchanger 134 . Also, according to an embodiment of the present invention, the first heat exchanger 132 may be a steam generator of the above-described nuclear reactor driving system. When the first heat exchanger 132 is a steam generator of a nuclear reactor driving system, the first cooling flow path 130 may branch or merge at any point in a flow path pipe of the nuclear reactor driving system. In addition, according to an embodiment of the present invention, the first heat exchanger 32 may have a different configuration from the steam generator.

The pressure equalization pipe 214 may connect the energy emitting space 110 and the energy absorbing space 210 . Accordingly, the energy emitting space 110 and the energy absorbing space 210 may communicate with each other so that pressure is transmitted to each other. In addition, the pressure equalization tube 214 may be formed in an inverted U-shape to prevent the heating medium of the energy absorption space 210 from flowing into the energy discharge space 110 through the pressure equalization tube 214 . have. In addition, an upper side of the pressure equalization pipe 214 may be positioned higher than an upper side of the energy transfer space 210 . When the pressure of the energy emitting space 110 increases, the increased pressure may be transferred to the energy absorbing space 210 through the pressure equalization tube 214 .

Accordingly, when the reactor vessel 122 is overheated and the temperature of the energy release space 110 increases, the pressure increases due to the increased temperature, and the increased pressure absorbs the energy through the pressure balance tube 214 . It may be transferred to the space 210 . When the pressure of the energy absorbing space 210 increases, the heating medium accommodated in the energy absorbing space 210 may be pressurized.

The injection tube 228 may inject the heating medium of the energy absorption space 210 pressurized by the pressure equalization tube 214 into the energy transfer space 220 . That is, the heating medium of the energy absorption space 210 may be moved to the energy transfer space 220 through the injection pipe 228 .

The saturated vapor pressure cooling chamber 226 may be disposed in the energy transfer space 220 . The saturated vapor pressure cooling chamber 226 may have an approximately spherical shape. The heating medium may be accommodated in the interior 222 of the saturated vapor pressure cooling chamber 226 . The saturated vapor pressure cooling chamber 226 may be connected to the injection pipe 228 . The saturated vapor pressure cooling chamber 226 may receive the heating medium through the injection pipe 228 .

The reference atmospheric pressure chamber 227 may be disposed below the saturated vapor pressure cooling chamber 226 . The reference atmospheric pressure chamber 227 may accommodate the heating medium. The reference atmospheric pressure chamber 227 may communicate with a lower side of the saturated vapor pressure cooling chamber 226 . The heating medium of the reference atmospheric pressure chamber 227 may receive the pressure of the energy transfer space 220 while simultaneously receiving the pressure of the heating medium of the saturated vapor pressure cooling chamber 226 . The water level of the heating medium of the reference atmospheric pressure chamber 227 may change according to the pressure of the energy transfer space 220 and the pressure of the heating medium of the saturated vapor pressure cooling chamber 226 . For example, when the pressure of the saturated vapor pressure cooling chamber 226 increases, the heating medium of the saturated vapor pressure cooling chamber 226 may flow into the reference atmospheric pressure chamber 227 . Conversely, when the pressure of the saturated vapor pressure cooling chamber 226 decreases, the heating medium of the reference atmospheric pressure chamber 227 may flow into the saturated vapor pressure cooling chamber 226 .

The second cooling passage 231 may be provided in the energy transfer space 220 , and may discharge heat in the energy transfer space 220 to the outside of the second containment vessel 200 . One end 236 of the second cooling passage 231 may pass through a side surface of the second containment vessel 200 to be connected to the outside of the second containment vessel 200 . The external cooling water of the second containment vessel 200 may be introduced into the second cooling passage 231 through one end 236 of the second cooling passage. The other end 238 of the second cooling passage 231 may be disposed at a higher position than the one end 236 of the second cooling passage. The other end 238 of the second cooling passage may pass through the upper side of the second containment vessel 200 to be connected to the outside of the second containment vessel 200 . The cooling water of the second cooling passage 231 may be discharged to the second containment vessel 200 through the other end 238 of the second cooling passage 231 .

A third heat exchanger 232 and a fourth heat exchanger 233 may be installed in the second cooling passage 231 .

The third heat exchanger 232 may be disposed in the energy transfer space 220 . The third heat exchanger 232 may transfer the heat of the energy transfer space 220 to the cooling water of the second cooling passage 231 .

The fourth heat exchanger 233 may be disposed in the interior 222 of the saturated vapor pressure cooling chamber 226 . The fourth heat exchanger 233 may transfer the heat of the saturated vapor pressure cooling chamber 226 to the cooling water of the second cooling passage 231 . And, as the cooling water of the second cooling passage 231 is discharged to the outside of the second containment vessel 200 through the other end 238 of the second cooling passage, the second cooling passage 231 is Heat of the energy transfer space 220 may be cooled.

In addition, the second containment vessel 200 may further include a heat medium injection pipe 242 and an injection pipe opening/closing valve 244 .

The heat medium injection tube 242 may connect the energy transfer space 220 and the energy release space 110 to introduce the heat medium of the energy transfer space 220 into the energy release space 110 .

The injection pipe opening/closing valve 244 may be installed in the heat medium injection pipe 242 to selectively open and close the heat medium injection pipe 242 .

The injection pipe opening/closing valve 244 may close the heat medium injection pipe 242 when the nuclear reactor is operating normally. The injection tube opening/closing valve 244 may open the heat medium injection tube 242 when the temperature or pressure of the reactor vessel 122 or the energy release space 110 is excessively increased. When the injection tube opening/closing valve 244 opens the heat medium injection tube 242 , the heat medium of the energy transfer space 220 may move to the energy discharge space 110 . The heating medium moved to the energy emitting space 110 may cool the reactor vessel 122 or the energy emitting space 110 .

In addition, a steam release valve 138 may be installed in the first cooling passage 130 . The vapor release valve 138 may release the heat absorption medium (eg, steam) flowing through the first cooling passage 130 into the energy release space 110 .

When the heat absorption medium (eg, steam) is discharged into the energy discharging space 110 by the steam discharging valve 138 , the pressure of the energy discharging space 110 may increase. When the pressure of the energy release space 110 increases, as in the above description, after the pressure of the energy transfer space 220 increases, the second containment vessel 200 is cooled by the cooling pipe 250 . can do it

3 is a cross-sectional view schematically showing a cooling device for a containment vessel according to an embodiment of the present invention, Fig. 4 is an enlarged view of part A shown in Fig. 3 , and Fig. 5 is a view of the containment vessel according to an embodiment of the present invention It is a plan view schematically showing a cooling device, and FIG. 6 is a perspective view showing a cooling device for a containment vessel according to an embodiment of the present invention.

3 to 6 , the cooling apparatus for the containment vessel according to an embodiment of the present invention may include a lower guide part 400 and an upper guide part 300 .

The lower guide part 400 may be disposed to be spaced apart from the outer wall of the second containment container 200 . The lower guide part 400 may be supported on the seabed. At least a portion of the lower guide part 400 may be submerged in seawater. The lower guide unit 400 may guide seawater to the outer wall of the second containment vessel 200 . In addition, the lower guide part 400 may be made of concrete, metal, or plastic, and in addition, may be made of various materials strong in rigidity and corrosion resistance. In addition, the overall size of the lower guide part 400 may be approximately half the size of the second containment container 200 . However, the overall size of the lower guide part 400 may be smaller or larger than half the size of the second containment container 200 . In addition, the lower guide part 400 may be disposed to be spaced apart at a first interval so that the seawater moves smoothly upward, the first interval is the size of the second containment vessel 200 , the lower guide part It may be determined in consideration of the size of 400 , the topography of the seabed, the topography around the location of the second containment vessel, and the like.

The lower guide part 400 may include a first lower guide part 410 , a second lower guide part 420 , and a third lower guide part 430 .

The first lower guide part 410 may have a first lower surface 411 , a first upper surface 412 , and a first side surface 413 . The first lower surface 411 may be supported on the seabed. The first upper surface 412 may be inclined at a predetermined angle with respect to the first lower surface 411 . The first side surface 413 may connect the first lower surface 411 and the first upper surface 412 . The first side surface 413 may be disposed to be spaced apart from the outer wall of the second containment vessel 200 . A seawater passage 410a may be formed between the first side surface 413 and the outer wall of the second containment vessel 200 .

The second lower guide part 420 may have a second lower surface 421 , a second upper surface 422 , and a second side surface 423 . The second lower surface 421 may be supported on the seabed together with the first lower surface 411 . The second upper surface 422 may be inclined at a predetermined angle with respect to the second lower surface 421 . Also, the second upper surface 422 may be inclined to correspond to the first upper surface 412 . The second side surface 423 may connect the second lower surface 421 and the second upper surface 422 . The second side surface 423 may be disposed to be spaced apart from the outer wall of the second containment vessel 200 . A seawater passage 410a may be formed between the second side surface 423 and the outer wall of the second containment vessel 200 .

The third lower guide part 430 may have a third lower surface 431 , a third upper surface 432 , and a third side surface 433 . The third lower surface 431 may be supported on the seabed together with the first lower surface 411 and the second lower surface 421 . The third upper surface 432 may be inclined at a predetermined angle with respect to the third lower surface 431 . The third side surface 433 may connect the third lower surface 431 and the third upper surface 432 . Also, the third upper surface 432 may be inclined to correspond to the second upper surface 422 . The third side surface 433 may be disposed to be spaced apart from the outer wall of the second containment vessel 200 . A seawater passage 410a may be formed between the third side surface 433 and the outer wall of the second containment vessel 200 .

In addition, a guide protrusion may be formed on the upper surface of the lower guide part 400 . The guide protrusion includes a first guide protrusion 415 formed on the first lower guide part 410 , a second guide protrusion formed on the second lower guide part 420 , and the third lower guide part 430 . It may be provided with a third guide projection formed on the.

As shown in FIG. 4 , the first guide protrusion 415 may be formed to protrude from the first upper surface 412 . The second guide protrusion may be formed to protrude from the second upper surface 422 . The third guide protrusion may be formed to protrude from the third upper surface 432 .

The upper guide part 300 may be disposed to be spaced apart from the outer wall of the second containment container 200 . The upper guide part 300 may be disposed above the lower guide part 400 . The upper guide part 300 may guide the seawater guided by the lower guide part upward. In addition, the upper guide part 300 may be made of concrete, metal, or plastic, and in addition, may be made of various materials strong in rigidity and corrosion resistance. In addition, the overall size of the upper guide part 300 may be approximately half the size of the second containment vessel 200 . However, the overall size of the upper guide part 300 may be smaller or larger than half the size of the second containment container 200 . In addition, the upper guide part 300 may be disposed to be spaced apart at a second interval so that the seawater moves smoothly upward, and the first interval may be the same as the second interval. The second interval may be determined in consideration of the size of the second containment vessel 200 , the size of the upper guide unit 400 , the topography of the seabed, the topography around the location of the second containment vessel 200 , etc. . The upper guide part 300 may include a first upper guide part 310 and a second upper guide part 320 .

The first upper guide part 310 may be disposed to be spaced apart from the outer wall of the second containment container 200 . The side surface 311 of the first upper guide part 310 may face the outer wall of the second containment container 200 .

The second upper guide part 320 may extend from the first upper guide part 310 and face the first lower guide part 410 .

A temporary storage space 330 for temporarily storing seawater may be formed between the side surface 311 of the first upper guide part 310 and the upper surface 321 of the second upper guide part 320 .

Also, a first guide space 412a may be formed between the second upper guide part 320 and the first lower guide part 410 . In addition, a second guide space 422a may be formed between the first lower guide part 410 and the second lower guide part 420 . In addition, a third guide space 432a may be formed between the second lower guide part 420 and the third guide part 430 .

In addition, the cooling device of the containment vessel may be provided with a support part 500 for supporting the lower guide part 400 and the upper guide part 300 from the seabed.

The support part 500 may be coupled to a side surface of the lower guide part 400 . The support part 500 may be coupled to the lower guide part 400 in various ways, such as a welding method or a bolt fastening method to the lower guide part 400 . In addition, the upper guide part 300 may be coupled while being seated on the upper end of the support part 500 . However, the upper guide part 300 is not limited to being seated and coupled to the upper end of the support part 500 , and may be coupled to the support part 500 in various ways. The support part 500 may include a first support part 510 coupled to one side of the lower guide part 400 and a second support part 520 coupled to the other side of the lower guide part 400 . .

The first support part 510 may be formed in a plate shape. However, the first support part 510 is not limited to being formed in a plate shape, and may be formed in various shapes capable of supporting the lower guide part 400 and the upper guide part 300 . The first support 510 may be fixed to the seabed. In addition, a portion of the first support 510 may be inserted into and fixed to the seabed, and may be fixed to the seabed in various other ways.

The second support part 520 may be formed in a plate shape. However, the second support part 520 is not limited to being formed in a plate shape, and may be formed in various shapes capable of supporting the lower guide part 400 and the upper guide part 300 . Also, the second support part 520 may be disposed on the opposite side of the first support part 520 with the lower guide part 400 interposed therebetween. Also, the second support part 520 may be formed in parallel with the first support part 510 . The second support 520 may be fixed to the seabed. In addition, a portion of the second support 520 may be inserted into and fixed to the seabed, and may be fixed to the seabed in various other ways.

Thereafter, a method of cooling the containment vessel using seawater will be described.

The height of the sea level S1 may vary with time due to a seawater wave. Such a seawater wave may refer to a periodic or non-periodic up-and-down movement of seawater generated as disturbances generated on the surface of the seawater spread in the form of waves.

The upper guide part 300 and the lower guide part 400 may be submerged in seawater according to sea conditions, unlike the one shown in FIG. 3 . In addition, the upper guide part 300 may be disposed higher than the sea level S1 , and a portion of the lower guide part 400 may be disposed equal to or lower than the sea level S1 . As shown in FIG. 3 , the second lower guide part 420 and the third lower guide part 430 are submerged in seawater, and a portion of the first lower guide part 410 is at the sea level ( S1 ). can be accessed in

Seawater is moved by seawater waves, and the moving seawater is guided by the first lower guide part 410 and moves to the outer wall of the second containment vessel 200 through the first guide space 412a. The first guide space 412a may be formed to narrow along a direction in which the guided seawater is guided and moved. As the first guide space 412a narrows, the speed of the guided seawater increases. Also, the first guide space 412a may be narrowed by the first guide protrusion 415 . In addition, as the first guide protrusion 415 changes the direction of movement of the guided seawater upward, the guided seawater prevents direct collision with the outer wall of the second containment vessel 200 and smoothly It can be guided to flow into the seawater passage (300a).

The guided seawater is introduced into the seawater passage 300a after passing through the first guide space 412a. Since the speed of the guided seawater increases while passing through the first guide space 412a, the seawater is guided upward through the seawater passage 300a.

The seawater may primarily cool the outer wall of the second containment vessel 200 while being guided to the seawater passage 300a.

The seawater that has passed through the seawater passage 300a may be temporarily stored in the temporary storage space 330 . The upper surface 321 of the second upper guide part 320 may be formed perpendicular to the direction of gravity. Accordingly, the seawater staying in the temporary storage space 330 does not stay permanently on the upper surface 321, but may be moved back to the seawater passage 300a by gravity. That is, the seawater may be moved from the temporary storage space 330 to the seawater passage 300a.

The seawater may secondarily cool the outer wall of the second containment vessel 200 while moving back to the seawater passage 300a.

As described above, since the surface area of the outer wall of the second containment vessel 200 exchanging heat with seawater increases as the cooling apparatus for the containment vessel according to the embodiment of the present invention guides the seawater upward, the second containment vessel The cooling efficiency of 200 is improved.

In addition, in the cooling apparatus of the containment vessel according to the embodiment of the present invention, after seawater is temporarily stored in the temporary storage space 330 , it is moved back to the seawater passage 300a, Since the residence time of the seawater exchanging heat with the outer wall is increased, the cooling efficiency of the second containment vessel 200 is improved.

7 is a diagram schematically illustrating a state in which seawater is guided when the sea level is lowered.

Referring to FIG. 7 , the sea level S2 may be lower than the sea level S1 illustrated in FIG. 3 . The moving seawater is guided to the outer wall of the second containment vessel 200 through the second guide space 422a while being guided by the second guide part 420 .

The guided seawater is introduced into the seawater passage 300a after passing through the second guide space 422a. Since the speed of the guided seawater increases while passing through the second guide space 422a, the seawater is guided upward through the seawater passage 300a.

The seawater may primarily cool the outer wall of the second containment vessel 200 while being guided to the seawater passage 300a.

The seawater that has passed through the seawater passage 300a may be temporarily stored in the temporary storage space 330 .

In addition, the seawater may secondarily cool the outer wall of the second containment vessel 200 while moving back to the seawater passage 300a.

In addition, when the height of the sea level is lower than the height of the sea level S2 shown in FIG. 7 , the sea water may be guided by the third lower guide part 430 .

In addition, according to a modified embodiment of the present invention, the lower guide part 400 is a first lower guide part 410 , a second lower guide part 420 , and a third lower guide part 430 . It is not limited to one, and may be four or more.

8 is a plan view schematically showing a cooling apparatus for a containment vessel according to another embodiment of the present invention.

Referring to FIG. 8 , a cooling apparatus for a containment container according to another embodiment of the present invention may include a lower guide part and an upper guide part 300 ′. The same or similar components to the above-described components will be replaced with the above description, and the upper guide unit 300' will be focused on.

The upper guide part 300 ′ may be formed to surround the outer wall of the second containment vessel 200 . For example, the upper guide part 300 ′ may be a semi-cylindrical shape. Also, the lower guide part may be formed in a shape corresponding to the upper guide part 300'. For example, when the upper guide part 300' has a semi-cylindrical shape, the lower guide part may also have a semi-cylindrical shape. As the upper guide part 300 ′ and the lower guide part are formed to surround the outer wall of the second containment vessel 200 , seawater follows the outer circumferential surface of the second containment vessel 200 to the second containment vessel ( 200) can cool the outer wall.

9 is a flowchart illustrating a method for cooling a containment vessel according to an embodiment of the present invention.

9, the cooling method of the containment vessel according to an embodiment of the present invention includes a first seawater guide step (S110), a second seawater guide step (S120), a temporary storage step (S130), and a third seawater guide step. may include

In the first seawater guide step S110, seawater may be guided to the outer wall of the second containment vessel 200 (refer to FIG. 3) by the lower guide part 400 (refer to FIG. 3).

In the second seawater guide step (S120), the seawater guided by the upper guide part 300 (see FIG. 3) can be guided upward along the outer wall of the second containment vessel (200, see FIG. 3). have. The guided seawater may cool the outer wall of the second containment vessel 200 (refer to FIG. 3 ).

In the temporary storage step ( S130 ), the “upward?”* guided seawater may be temporarily stored in the temporary storage space 330 (refer to FIG. 3 ).

The third seawater guide step may guide the temporarily stored seawater downward along the outer wall of the second containment vessel 200 . The downwardly guided seawater may cool the outer wall of the second containment vessel 200 (refer to FIG. 3 ).

As described above, preferred embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the present invention in addition to the above-described embodiments is one of ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description, but may be modified within the scope of the appended claims and their equivalents.

100: first containment vessel 200: second containment vessel
300: upper guide part 400: lower guide part

Claims (8)

A cooling device for a containment vessel that cools an outer wall of the containment vessel, the cooling device comprising:
a lower guide part disposed to be spaced apart from the outer wall of the containment vessel and guiding seawater to the outer wall of the containment vessel; and
an upper guide part disposed to be spaced apart from the outer wall of the containment vessel, disposed on an upper side of the lower guide part, and guiding the seawater guided by the lower guide part in an upward direction;
A cooling device for a containment vessel comprising a.
According to claim 1,
The lower guide part,
a lower surface supported on the seabed;
an upper surface inclined at a predetermined angle with respect to the lower surface; and
A cooling device for a containment vessel having a side surface spaced apart from the outer wall of the containment vessel to form a seawater passage.
3. The method of claim 2,
The lower guide part,
The cooling device of the containment vessel further comprising a guide projection formed to protrude from the upper surface.
According to claim 1,
The lower guide part,
a first lower guide part spaced apart from the upper guide part; and
and a second lower guide portion disposed to be spaced apart from the first lower guide portion,
A first guide space is formed between the upper guide part and the first lower guide part,
A cooling device for a containment container in which a second guide space is formed between the first lower guide part and the second lower guide part.
According to claim 1,
The upper guide part,
a first upper guide part disposed to be spaced apart from the outer wall of the containment container; and
and a second upper guide part extending from the first upper guide part and facing the lower guide part,
A temporary storage space for temporarily storing the guided seawater is formed between the first upper guide part and the second upper guide part.
According to claim 1,
The cooling apparatus of the containment container further comprising a support part for supporting the lower guide part and the upper guide part.
A method of cooling a containment vessel for cooling an outer wall of the containment vessel, the method comprising:
a first seawater guide step of guiding seawater to the outer wall of the containment vessel;
a second seawater guide step of guiding the guided seawater upward along the outer wall of the containment vessel; and
and a temporary storage step of temporarily storing the "upward?"* guided seawater.
8. The method of claim 7,
The cooling method of the containment vessel further comprising a third seawater guide step of guiding the temporarily stored seawater downward along the outer wall of the containment vessel.

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