KR20210138955A - Injection nozzle structure - Google Patents

Abstract

Disclosed is an injection nozzle structure capable of sufficiently bringing cooling water into contact with the entire outer circumferential surface of a tube for transporting a thermal fluid. According to an embodiment of the present invention, an injection nozzle structure for spraying coolant to a tube for transporting a thermal fluid comprises: a body having a flow path through which the coolant moves and an injection port through which the coolant flowing through the flow path is injected toward the tube; and an injection guide which is provided around the injection port of the body and is formed to surround a part of an outer peripheral surface of the tube. A space is formed in which the coolant sprayed from the injection port moves between the inner surface of the injection guide and the outer peripheral surface of the tube.

Description

Spray nozzle structure {INJECTION NOZZLE STRUCTURE}

The present invention relates to a spray nozzle structure, and more particularly, to a spray nozzle structure for cooling a tube of a heat exchanger.

In general, in many cases of widely used air-conditioning equipment, a device including a heat exchanger is configured as a circulation cycle to move heat from one space (generally an indoor space) to another space (generally an outdoor space). In the case of the cooling cycle, it operates to take heat from the indoor space and throw it away in the outdoor space, and in the case of the heating cycle, it operates in the opposite direction. There are evaporators and condensers as heat exchangers widely used in these heating and cooling systems. In the case of the evaporator, it absorbs heat from the air outside the evaporator and uses it as evaporation heat to evaporate the heat exchange medium inside the evaporator. do. Conversely, in the case of a condenser, the heat emitted as the heat exchange medium inside the condenser is condensed is transferred to the air outside the condenser, and serves to heat the outside air. As described above, the basic configuration of most heat exchangers is to form heat exchange between the external air and the internal heat exchange medium.

On the other hand, in the case of nuclear power generation, a large amount of thermal energy is generated in a nuclear reactor, and if an accident occurs in the nuclear reactor and does not operate normally, there is a risk of a large-scale accident in which the reactor facility itself is destroyed by this thermal energy. Therefore, various safety systems for rapidly cooling the nuclear reactor in case of damage to the nuclear reactor are essential. These safety systems are made in the form of supplementing and supplying coolant to each part of the nuclear reactor, circulating the coolant along an appropriate flow path, absorbing heat from each part of the nuclear reactor, and finally disposing of it to an external heat sink. At this time, since the coolant that has been in direct contact with each part of the nuclear reactor contains radioactive materials dangerous to the environment, the coolant itself should not be directly discharged to the outside, and only heat should be disposed of to the outside. As such, a heat exchanger for dissipating heat to an external heat sink in the nuclear reactor safety system is commonly referred to as a heat exchanger for removing residual heat in the field of nuclear reactor technology. Such a configuration of a heat exchanger for removing residual heat is widely disclosed in various technologies such as Korean Patent Publication No. 2009-0021722.

As one type of such a heat exchanger for removing residual heat, a method of cooling the tube by injecting a heat exchange medium around a tube for transporting a heat fluid to induce evaporation of the heat exchange medium is also used. However, at this time, when the injection hole for spraying the heat exchange medium is injected only toward one side of the outer peripheral surface of the tube, the portion adjacent to the injection hole among the outer peripheral surface of the tube may be sufficiently cooled, but the outer peripheral surface located in the region opposite to the direction in which the injection hole is directed Since silver cannot sufficiently contact the heat exchange medium, cooling efficiency may be reduced.

An embodiment of the present invention is to provide a spray nozzle structure capable of sufficiently contacting cooling water with respect to the entire outer circumferential surface of a tube for transporting a thermal fluid.

According to one aspect of the present invention, there is provided a spray nozzle structure for spraying cooling water to a tube for transferring a thermal fluid, and having a flow path through which the cooling water moves and an injection hole through which the cooling water flowing through the flow path is injected toward the tube. body to do; It is provided around the injection hole of the body and includes an injection guide formed to surround a part of the outer circumferential surface of the tube, and the coolant injected from the injection hole moves between the inner surface of the injection guide and the outer peripheral surface of the tube. An injection nozzle structure is provided, in which a space is formed.

In this case, the injection hole may be formed to have a circular cross-section.

In this case, the injection hole may be formed in the form of a slit having a cross section extending in an extension direction of the tube.

In this case, a plurality of the injection holes are formed along the extension direction of the tube, and may be disposed to be spaced apart from each other.

In this case, a plurality of flow paths of the body may be formed to correspond to the plurality of injection holes.

In this case, the injection guide may be formed so that a cross section perpendicular to the extension direction of the tube has an arc shape.

At this time, the cross-section of the injection guide may be formed to have a semicircular shape.

At this time, the injection guide may be formed to be symmetrical with respect to the injection hole.

In this case, the tube may be formed to extend in a cylindrical shape.

At this time, the tube may be formed to extend in a spiral shape.

The spray nozzle structure according to an embodiment of the present invention introduces a spray guide formed to surround a portion of the outer circumferential surface of the tube, so that the cooling water can be sufficiently brought into contact with the entire outer circumferential surface of the tube by using both the gap cooling effect and the Coanda effect. .

1 is a perspective view showing a spray nozzle structure according to an embodiment of the present invention and a tube cooled thereby.
Figure 2 is a side view of the spray nozzle structure and the tube cooled thereby according to an embodiment of the present invention viewed from the side.
3 is a perspective view showing that the injection hole of the injection nozzle structure according to an embodiment of the present invention is formed to have a circular cross-section.
4 is a perspective view showing that the injection hole of the injection nozzle structure according to an embodiment of the present invention is formed in a slit shape.
5 is a conceptual diagram for explaining the Coanda effect.
6 is a perspective view showing a spray nozzle structure according to an embodiment of the present invention and a spiral tube cooled thereby.
7 is a side view of the spray nozzle structure and the spiral tube cooled thereby according to an embodiment of the present invention as viewed from the side.
8 is a view showing a passive infinite cooling structure of a nuclear reactor to which the injection nozzle structure according to an embodiment of the present invention is applied.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In this specification, terms such as "comprise" or "have" are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the possibility of addition or existence of numbers, steps, operations, components, parts, or combinations thereof.

1 is a perspective view showing a spray nozzle structure according to an embodiment of the present invention and a tube cooled thereby. Figure 2 is a side view of the spray nozzle structure and the tube cooled thereby according to an embodiment of the present invention viewed from the side. 3 is a perspective view showing that the injection hole of the injection nozzle structure according to an embodiment of the present invention is formed in the form of a nozzle. 4 is a perspective view showing that the injection hole of the injection nozzle structure according to an embodiment of the present invention is formed in a slit shape.

The injection nozzle structure 10 according to an embodiment of the present invention injects low-temperature cooling water 22 on the outer peripheral surface of the tube 40 for transferring the high-temperature thermal fluid, thereby forming the tube 40 and the inside of the tube 40 . It is a cooling device that cools the thermal fluid present in the At this time, the spray nozzle structure 10 according to an embodiment of the present invention is provided with a spray guide 30 formed to surround the outer periphery of the tube 40 as shown in FIG. 1 to provide a Coanda effect (Coanda effect). ), the cooling water 22 can be brought into contact with the entire circumferential direction of the outer peripheral surfaces 46 and 48 of the tube. Through this, the spray nozzle structure 10 according to an embodiment of the present invention can improve the cooling efficiency of the tube 40 .

Hereinafter, the main configuration and effects of the spray nozzle structure 10 according to an embodiment of the present invention will be described in more detail.

The spray nozzle structure 10 according to an embodiment of the present invention includes a body 20 in which a flow path 21 through which the coolant 22 moves is formed.

In one embodiment of the present invention, the body 20 is a member having one end connected to a cooling water supply source (not shown) and the other end connected to the spray guide 30 . That is, the body 20 may function as a passage through which the cooling water 22 supplied from the cooling water supply source moves in one direction with a constant pressure until it is sprayed toward the tube 40 . At this time, a passage 21 that is a space through which the cooling water can move may be formed inside the body 20 .

Meanwhile, referring to FIG. 2 , the body 20 of the spray nozzle structure 10 according to an embodiment of the present invention may have a spray hole 50 on one side. Here, the injection hole 50 is an opening formed at one end of the flow path 21 , and the coolant 22 flowing through the flow path 21 inside the body 20 may be injected toward the tube 40 through this.

In one embodiment of the present invention, the injection hole 50 may be formed in various shapes. For example, referring to FIG. 3 , the injection hole 50 may be formed in a conventional nozzle shape 52 having a circular cross-section. At this time, by forming a plurality of nozzle-shaped injection holes 52 having a circular cross section along the extension direction of the tube 40 , the area in which the coolant 22 comes into contact with the tube 40 can be enlarged. In addition, when the nozzle-shaped injection hole 52 having a circular cross section is formed in this way, it may be suitable for spraying the cooling water 22 with a strong water pressure.

Alternatively, referring to FIG. 4 , the injection hole 50 may be formed in the form of a slit 54 elongated in the extension direction of the tube 40 . In this case, the flow path 21 of the body 20 may also be formed to have a width to correspond to the slit-shaped injection hole 54 . At this time, it goes without saying that a plurality of slit-shaped injection holes 54 may also be formed along the extension direction of the tube, like the nozzle-shaped injection holes 52 .

In one embodiment of the present invention, as already described above, a plurality of flow paths 21 may be formed. At this time, as shown in FIG. 1 , the plurality of flow paths may be disposed to be spaced apart from each other along the extension direction of the tube 40 . However, unlike this, a single flow path may be formed in the body 20 . That is, one huge flow path having a width corresponding to the entire extension direction of the tube 40 is formed, and only a plurality of injection holes 50 may be disposed.

The spray nozzle structure 10 according to an embodiment of the present invention includes a spray guide 30 connected to the body 20 .

1 to 3 , the injection guide 30 may be disposed at an end adjacent to the tube 40 among the ends of the body 20 to surround the tube 40 . That is, the injection guide 30 is formed to be curved in a shape corresponding to the circumference of the outer circumferential surface 46 of the tube 40 , so that a cross section perpendicular to the extension direction of the tube 40 may have an arc shape. For example, the cross-section of the injection guide 30 may have a semicircular shape, as shown in FIG. 2 . However, in one embodiment of the present invention, the shape of the injection guide 30 is not limited to a semicircular shape, and may be formed in an arc shape having various central angles in addition to a semicircular shape having a central angle of 180 degrees.

At this time, the injection guide 30 is disposed to surround the tube 40, spaced apart from the outer peripheral surface 46 of the tube by a predetermined thickness. Therefore, between the outer peripheral surface 46 of the tube 40 and the inner surface 32 of the injection guide 30 surrounding it, the cooling water 22 injected from the injection hole 50 follows the outer peripheral surface 46 of the tube 40 . A gap cooling space G may be formed to move. Since the cooling water 22 moves while surrounding the tube 40 by the gap cooling space G, the spray nozzle structure 10 according to an embodiment of the present invention can effectively cool the tube 40 .

More specifically, in one embodiment of the present invention, the injection guide 30 may include an inner surface 32 surrounding the tube 40 and an outer surface 34 exposed to the outside. In this case, the injection hole 50 through which the coolant 22 moved along the flow path 21 of the body 20 is sprayed toward the tube 40 may be disposed on a part of the inner surface 32 . The cooling water 22 injected through the injection hole 50 does not scatter sporadically after hitting the outer peripheral surface 46 of the tube, but along the gap cooling space G formed by the injection guide 30 (Fig. 2). in the direction of the arrow). As a result, the contact area between the coolant 22 and the outer peripheral surface 46 of the tube is increased, so that heat exchange between the tube 40 and the coolant 22 can be effectively performed.

In one embodiment of the present invention, referring back to FIG. 2 , the injection guide 30 is formed to surround only a portion 46 of the tube outer peripheral surfaces 46 and 48 . In detail, the outer peripheral surfaces 46 and 48 of the tube 40 are not surrounded by the injection guide 30 unlike the first surface 46 and the first surface 46 surrounded by the injection guide 30 . It can be divided into a second surface 48 exposed to the outside. At this time, the first surface 46 can be effectively cooled by the gap cooling space (G) formed between the injection guide 30 as has already been described.

5 is a conceptual diagram for explaining the Coanda effect. 6 is a perspective view showing a spray nozzle structure according to an embodiment of the present invention and a spiral tube cooled thereby. 7 is a side view of the spray nozzle structure and the spiral tube cooled thereby according to an embodiment of the present invention as viewed from the side.

On the other hand, the spray nozzle structure 10 according to an embodiment of the present invention uses the Coanda effect, so that the cooling water 22 is also on the second surface 48 of the tube 40 in which the gap cooling space G is not formed. can be effectively contacted. The Coanda effect refers to a phenomenon in which a fluid flows along the curvature of a curved surface instead of flowing in a straight line when it flows in contact with a curved surface. That is, as shown in FIG. 5 , when the fluid is sprayed on the outer wall of the circular tube, it may mean a phenomenon in which the scent of the fluid is bent along the surface of the circular tube.

Specifically, the spray nozzle structure 10 according to an embodiment of the present invention is a circular tube 42, that is, a tube extending in a cylindrical shape and having a cross section perpendicular to the extending direction as shown in FIG. 1 in a circular shape. (42) can be applied. Accordingly, the second surface 48 not surrounded by the injection guide 30 may form a circular curved surface. As a result, the cooling water 22 flows in contact with the curved first surface 46 by the gap cooling space G, and the above-described Coanda effect also occurs on the second surface 48 where the injection guide 30 does not exist. can continuously flow along the second surface 48 of the curved shape. Through this, the spray nozzle structure 10 according to an embodiment of the present invention can maximize cooling efficiency by effectively supplying the coolant 22 to the second surface 48 that is not adjacent to the spray guide 30 .

Alternatively, the spray nozzle structure 10 according to an embodiment of the present invention may be applied to a spiral tube 44 extending in a spiral shape while drawing a circle, as shown in FIG. 6 . That is, the spiral tube 44 is also not adjacent to the injection guide 30 and includes the second surface 48 having a curved shape, as a result, the cooling water 22 passing through the gap cooling space G has a Coanda effect. This is because it can flow along the curved second surface 48 by the

Hereinafter, as a specific example to which the injection nozzle structure 10 according to an embodiment of the present invention can be applied, a passive infinite cooling structure of a nuclear reactor will be described.

8 is a view showing a passive infinite cooling structure of a nuclear reactor to which the injection nozzle structure 10 according to an embodiment of the present invention is applied.

8, the passive cooling structure of the nuclear reactor to which the injection nozzle structure 10 according to an embodiment of the present invention is applied is a first containment vessel 100, a second containment vessel 200, a first partition wall ( 201 ), a pressure equalization pipe 214 , an injection pipe 228 , an injection pipe 242 , and a valve opening/closing unit 300 .

The first containment vessel 100 has an energy release space 110 (ERS; Energy Release Space) in which the reactor vessel 122 is accommodated. The first containment vessel 100 is manufactured to withstand high temperature and pressure in order to prevent high temperature and high pressure steam or non-condensed gas discharged from the reactor vessel 122 from going out. Accordingly, the first containment container 100 may be made of a concrete or metal material. However, the first containment container 100 is not limited thereto, and may be made of various materials having explosion resistance.

On the other hand, the first containment vessel 100 is sufficient as long as it has a size and shape capable of accommodating the nuclear reactor vessel 122 regardless of a specific shape, but is generally formed in a cylindrical shape.

And, the first storage container 100 is installed is not limited by the ground or underground. However, preferably buried underground or surrounded by soil (L).

A nuclear reactor core 124 may be accommodated in the nuclear reactor vessel 122 accommodated in the first containment vessel 100 . 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 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 . The second containment vessel 200 is a second containment vessel ( 200) may have an energy transfer space 220 (ETS; Energy Transfer Space) emitting to the outside. The second containment vessel 200 is manufactured to withstand high temperature and pressure in order to prevent the high temperature and high pressure steam or non-condensed gas transmitted from the energy release space 110 from going out.

Accordingly, the second containment container 200 may be made of concrete or a metal material like the first containment container 100 . In addition, the second containment container 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.

On the other hand, the second containment vessel 200 is sufficient as long as it has a size and shape capable of accommodating a sufficient amount of heat medium to cool the vapor emitted from the reactor vessel 122 regardless of a specific shape, but generally has a cylindrical shape. formed in the form Also, the first containment vessel 100 and the second containment vessel 200 may have a cylindrical shape as a whole, and may be formed in a form partitioned by partition walls.

And, the second containment container 200 is installed on the ground, underground, or in the water regardless of the place. However, it is preferably surrounded by water (S) or disposed in water, and is installed near the first containment vessel (100). In this case, the water may be seawater.

The energy absorbing space 210 provided in the second containment 200 may be partitioned from the energy emitting space 110 to accommodate the heating medium. In this case, 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 absorbing space 210 receives the pressure of the energy emitting space 110 and moves the heating medium accommodated in the energy absorbing space 210 to the energy emitting space 220 using the siphon effect, while the energy emitting space 110 . Relieves rapid internal pressure rise.

The energy transfer space 220 provided above the energy absorbing space 210 is partitioned from the energy emitting space 110 while being partitioned from the energy absorbing space 210 . At this time, it is partitioned from the energy absorption space 210 through the first partition wall 201 . The pressure of the energy transfer space 220 may change according to the pressure of the energy release space 110 . In addition, by connecting the energy emitting space 110 and the energy absorbing space 210 through the pressure equalization tube 214 , the energy emitting space 110 and the energy absorbing space 210 are well transferred to each other.

On the other hand, the first partition wall 201 is disposed between the energy transfer space 220 and the energy absorption space 210, and like the second containment container 200, to prevent high-temperature and high-pressure steam or non-condensed gas from going out. It is manufactured to withstand high temperature and high pressure.

On the other hand, the pressure equalization tube 214 is formed in an inverted U-shape, so that the heat medium of the energy absorption space 210 may be prevented from flowing into the energy discharge space 110 through the pressure equalization tube 214 .

In addition, the upper side of the pressure equalization tube 214 may be positioned higher than the upper side of the energy transfer space 210 . When the pressure of the energy emitting space 110 is increased, 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 emitting space 110 increases, the pressure increases due to the increased temperature, and the increased pressure is transferred to the energy absorption space 210 through the pressure equalization tube 214 . can be transmitted. 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 flow the heating medium of the energy absorption space 210 pressurized by the pressure equalization tube 214 to the energy transfer space 220 . In addition, the injection tube 228 may flow the heating medium in a manner to inject the energy transfer space 220, and one end of the injection tube 228 on the energy transfer space 220 side has a nozzle shape, or a nozzle is installed. can be

The heat medium injection pipe 242 may connect the energy delivery space 220 and the energy discharge space 110 to introduce the heat medium of the energy delivery space 220 into the energy discharge space 110 .

On the other hand, the passive cooling structure of the nuclear reactor to which the injection nozzle structure 10 according to an embodiment of the present invention is applied includes a first cooling passage 130 .

The first cooling passage 130 may transfer heat from 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 absorbing 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 radiate heat from the second heat exchanger 134 . In addition, according to an embodiment of the present invention, the first heat exchanger 132 may be a steam generator of the above-described reactor driving system. When the first heat exchanger 132 is a steam generator of the reactor driving system, the first cooling flow path 130 may branch or join at any point in the flow path pipe of the reactor driving system. In addition, according to an embodiment of the present invention, the first heat exchanger 32 may be a separate configuration different from the steam generator.

Referring back to FIG. 8 , the passive cooling structure of the nuclear reactor to which the injection nozzle structure 10 according to an embodiment of the present invention is applied is a saturated vapor pressure cooling chamber 226 and a reference pressure chamber disposed in the energy transfer space 220 . (227) may be provided.

At this time, the saturated vapor pressure cooling chamber 226 may have a spherical shape, and a heating medium may be accommodated in the interior 222 . In addition, the saturated vapor pressure cooling chamber 226 may be connected to the injection pipe 228 . The saturated vapor pressure cooling chamber 226 may receive a 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 a heating medium. The reference atmospheric pressure chamber 227 may communicate with the 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 heating medium of the saturated vapor pressure cooling chamber 226 while receiving the pressure of the energy transfer space 220 . 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 .

In addition, the passive cooling structure of the nuclear reactor to which the injection nozzle structure 10 according to an embodiment of the present invention is applied may further include a second cooling passage 231 .

The second cooling passage 231 is provided in the energy transfer space 220 , and may discharge heat in the energy transfer space 220 to the outside of the second containment container 200 . One end 236 of the second cooling passage 231 may pass through the 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 and 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 formed in the energy transfer space 220 . ) can be cooled.

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

On the other hand, when the pressure of the energy absorbing space 210 increases in the passive cooling structure of the nuclear reactor, the heat medium of the energy absorbing space 210 is moved to the saturated vapor pressure cooling chamber 226 through the injection pipe 228 and the water level is lowered. . Then, the heating medium moved to the saturated vapor pressure cooling chamber 226 is moved to the energy transfer space 220 through the reference atmospheric pressure chamber 227 .

Specifically, the injection pipe 228 may inject the heating medium toward the second heat exchanger 134 in the saturated vapor pressure cooling chamber 226 . Here, as an example of the injection pipe 228, the injection nozzle structure 10 according to an embodiment of the present invention may be applied. That is, the injection nozzle structure 10 having the injection guide may be disposed to surround the periphery of the second heat exchanger 134 that may be formed in a spiral tube shape. Through this, the spray nozzle structure 10 according to an embodiment of the present invention is sprayed on the entire outer side of the second heat exchanger 134 by the Coanda effect even if it is sprayed toward one of the outer sides of the second heat exchanger 134 . The heating medium can be sufficiently brought into contact with each other. As a result, the injection nozzle structure 10 according to an embodiment of the present invention can improve the heat dissipation performance of the second heat exchanger 134 provided in the passive infinite cooling structure of the nuclear reactor. However, the application of the injection nozzle structure 10 according to an embodiment of the present invention is not limited to the second heat exchanger 134, and may be installed adjacent to various heat exchangers included in the passive infinite cooling structure of the nuclear reactor. reveal the

As can be seen, the spray nozzle structure 10 according to an embodiment of the present invention is a surface adjacent to the injection hole 50 on the outer circumferential surface of a tube (eg, a circular tube or a spiral tube) cooled by the spray nozzle structure 10 . Regarding (46), by forming the gap cooling space (G) by the injection guide (30), it is possible to sufficiently contact the cooling water. In addition, cooling water can be effectively supplied to the outer peripheral surface 48 that is not adjacent to the injection port 50 side by using the Coanda effect. Therefore, the spray nozzle structure 10 according to an embodiment of the present invention has an advantage in that the cooling water can be sufficiently brought into contact with the entire outer circumferential surface of the tube constituting the heat exchanger.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same spirit. , changes, deletions, additions, etc. may easily suggest other embodiments, but this will also fall within the scope of the present invention.

10 Spray nozzle structure 20 Body
21 Euro 22 coolant
30 Spray guide 32 Inner side of spray guide
34 Outer side of dispensing guide 40 Tube
42 round tube 44 spiral tube
46 first side of tube 48 second side of tube
50 Nozzle 52 Nozzle Type Nozzle
54 Slit-shaped nozzle G gap cooling space
100 First containment vessel 200 Second containment vessel
210 Energy absorption space 220 Energy transmission space

Claims (10)

As a spray nozzle structure for spraying cooling water to a tube that transports a thermal fluid,
a body having a flow path through which the cooling water moves and an injection hole through which the cooling water flowing through the flow path is injected toward the tube;
It is provided around the injection port of the body, and includes a injection guide formed to surround a portion of the outer peripheral surface of the tube,
A space in which the coolant sprayed from the injection hole moves is formed between the inner surface of the spray guide and the outer peripheral surface of the tube. The method of claim 1,
The injection hole is formed to have a circular cross-section, the injection nozzle structure. The method of claim 1,
The injection hole is formed in the form of a slit having a cross section extending in the extension direction of the tube, the injection nozzle structure. The method of claim 1,
A plurality of the injection holes are formed along the extension direction of the tube, and are disposed to be spaced apart from each other. 5. The method of claim 4,
A plurality of flow passages of the body are formed to correspond to the plurality of injection holes, and a spray nozzle structure. The method of claim 1,
The injection guide is formed so that a cross section perpendicular to the extension direction of the tube has an arc shape, the injection nozzle structure. 7. The method of claim 6,
A cross section of the spray guide is formed to have a semicircular shape, the spray nozzle structure. The method of claim 1,
The injection guide is formed to be symmetrical with respect to the injection hole, the injection nozzle structure. The method of claim 1,
The tube is formed to extend in a cylindrical shape, the spray nozzle structure. The method of claim 1,
The tube is formed to extend in a spiral shape, the spray nozzle structure.

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