JP7032915B2 - Nuclear plant and sleeve cooling mechanism - Google Patents

Description

The present invention relates to a nuclear plant and a sleeve cooling mechanism .

In a nuclear power plant that uses nuclear power to generate electricity, a pipe can be inserted through a through hole formed in the concrete wall of the reactor building to supply fluid from the outside to the inside or from the inside to the outside of the reactor building. It enables discharge.

In such a nuclear plant, in order to improve the adhesion between the wall and the piping, and to prevent the piping from being damaged when the reactor building vibrates due to a large earthquake or the like, the wall is used. A technique for connecting a through hole of a portion and a pipe via a sleeve is known (see, for example, Patent Document 1). The sleeve also has a function of absorbing the displacement of the pipe due to thermal expansion and contraction that occurs in the pipe each time the plant is repeatedly started and stopped.

Japanese Unexamined Patent Publication No. 8-220274

By the way, in a nuclear power plant, since the fluid flowing through the pipe becomes hot, the heat of the fluid is transferred to the concrete wall portion, and there is a problem that the concrete becomes an allowable temperature (for example, 90 ° C.) or higher.

It is an object of the present invention to provide a nuclear power plant capable of suppressing an increase in temperature of a wall portion , and a sleeve cooling mechanism .

According to the first aspect of the present invention, the nuclear power plant has a reactor building having a wall portion in which a hole portion is formed, a pipe penetrating the hole portion, and a tubular shape surrounding the pipe portion from the outer peripheral side. A sleeve that supports the pipe on the wall portion and a sleeve cooling mechanism that is provided on the outer periphery of the sleeve to cool the sleeve are provided , and the sleeve cooling mechanism is fixed to the sleeve and the sleeve is provided. It has a cylindrical surface that is in surface contact with the outer peripheral surface of the sleeve, and has a metal structure having a pair of clamp portions covering substantially half of the sleeve and fins joined to each of the pair of clamp portions. The pair of clamp portions are connected to the vicinity of the upper end of the sleeve and the vicinity of the lower end of the sleeve, and the fins form a plate having a main surface facing the axial direction of the sleeve, and the pair of clamp portions have a plate shape. The fins joined to each are divided into a plurality of fin pieces arranged in the circumferential direction, and a gap is provided between the adjacent fin pieces .

According to such a configuration, the heat transferred from the pipe to the wall portion through the sleeve can be reduced by cooling the sleeve by the sleeve cooling mechanism. This makes it easy to keep the temperature of the wall portion below the permissible value.
Further, according to such a configuration, the heat of the sleeve can be released through the structure.
Further, according to such a configuration, the air rising flow of natural convection is less likely to be obstructed, so that the cooling of the sleeve can be promoted.
Further, according to such a configuration, since the fins are divided, the development of the temperature boundary layer can be suppressed and the heat transfer efficiency can be improved.

In the nuclear plant, the sleeve cooling mechanism includes a tubular heat transfer tube extending along the outer peripheral surface of the sleeve, a water supply device for supplying cooling water to the heat transfer tube, and the heat transfer tube on the outer peripheral surface of the sleeve. A band member for fixing the heat transfer tube to the sleeve and a paste-like heat transfer medium filled between the heat transfer tube and the outer peripheral surface of the sleeve may be provided so as to be in contact with the heat transfer tube.

According to such a configuration, leakage of the cooling water can be prevented by supplying the cooling water to the tubular heat transfer tube. Further, by filling the paste-like heat transfer medium between the heat transfer tube and the sleeve, the heat transfer efficiency between the heat transfer tube and the sleeve can be improved, and the cooling of the heat source can be promoted. Further, since the heat transfer tube is fixed by the band member, the heat transfer tube can be easily removed.

In the nuclear power plant, a carbon sheet may be arranged between the heat transfer tube and the sleeve.

According to such a configuration, the heat transfer efficiency between the heat transfer tube and the sleeve can be improved, and the cooling of the sleeve can be promoted.

In the nuclear power plant, it may have a tubular duct which is arranged above the structure and whose axis is along the vertical direction.

According to such a configuration, the heat transfer between the fin and the air can be increased by promoting the ascending air flow by the draft effect.

In the nuclear plant, the sleeve cooling mechanism has a first pipe extending in the circumferential direction along the outer peripheral surface of the sleeve while contacting the outer peripheral surface, and one end thereof is connected to the upper end of the first pipe. A second pipe formed so that the end is above the one end, a third pipe whose upper end is connected to the upper end of the second pipe and extends in the vertical direction, and the lower end of the third pipe and the above. It may have a heat pipe having a fourth pipe connecting the lower end of the first pipe, and a refrigerant sealed in the heat pipe.

According to such a configuration, the sleeve which is a heat source can be cooled by circulating the refrigerant without using a device such as a pump. Further, even if there is no space around the sleeve, the sleeve cooling mechanism can be installed by extending the second pipe and arranging the third pipe in a place having a space.

The nuclear power plant may have a tubular heat pipe duct that surrounds a part of the third pipe from the outer circumference.

According to such a configuration, the heat transfer between the third pipe and the air can be increased by promoting the ascending air flow by the draft effect. As a result, ventilation of the third pipe, which is a cooling unit, is promoted, coagulation / cooling of the refrigerant is promoted, and cooling of the sleeve, which is a heat source, is promoted.

In the nuclear power plant, a part of the third pipe may have a metal fin for a first heat pipe joined to the outer peripheral surface of the third pipe and extending along the third pipe.

According to such a configuration, the heat transfer speed can be improved by installing the fin for the first pipe in the third pipe and expanding the heat transfer area.

In the nuclear power plant, the fifth pipe connected to the second pipe and the fourth pipe is joined to the outer peripheral surface of the fifth pipe so as to be parallel to the third pipe, and the fifth pipe It may have a plurality of second pipe fins having a main surface that intersects the extending direction.

According to such a configuration, heat transfer is promoted by installing the fins for the second pipe, aggregation and cooling of the refrigerant are promoted in combination with the fins for the first pipe, and cooling of the sleeve which is a heat source is promoted. Will be done.

In the nuclear plant, the sleeve cooling mechanism is a fifth pipe extending in the circumferential direction along the outer peripheral surface of the sleeve while contacting the outer peripheral surface, and the first pipe in the circumferential direction of the sleeve. Is a fifth pipe arranged in different ranges, a sixth pipe connected to the upper end of the fifth pipe and formed so that the other end is above the one end, and the upper end is the upper end of the sixth pipe. A second heat pipe having a seventh pipe connected to and extending in the vertical direction, an eighth pipe connecting the lower end of the seventh pipe and the lower end of the fifth pipe, and the second heat pipe. It may have a refrigerant enclosed in the pipe.

According to such a configuration, the entire circumference of the sleeve is cooled, so that the risk of deformation can be reduced.

According to such a configuration, the flange is cooled by the flange cooling mechanism, so that the heat transferred from the pipe to the wall portion via the flange can be reduced. This makes it easy to keep the temperature of the wall portion below the permissible value.
According to the second aspect of the present invention, the sleeve cooling mechanism is a sleeve cooling mechanism for cooling the sleeve supporting the pipe, and has a cylindrical surface fixed to the sleeve and in surface contact with the outer peripheral surface of the sleeve. Along with this, it has a metal structure having a pair of clamp portions covering substantially half of the sleeve and fins joined to each of the pair of clamp portions, and the pair of clamp portions is of the sleeve. The fins are connected near the upper end and near the lower end of the sleeve, the fins have a plate shape having a main surface facing the axial direction of the sleeve, and the fins joined to each of the pair of clamp portions are in the circumferential direction. It is divided into a plurality of fin pieces arranged side by side, and a gap is provided between the adjacent fin pieces.

According to the present invention, the heat transferred from the pipe to the wall portion via the sleeve can be reduced by cooling the sleeve by the sleeve cooling mechanism. This makes it easy to keep the temperature of the wall portion below the permissible value.

It is a schematic block diagram of the nuclear power plant of the 1st Embodiment of this invention. It is sectional drawing of the pipe support structure of 1st Embodiment of this invention. It is a development view of the sleeve cooling mechanism of the 1st Embodiment of this invention. It is sectional drawing of the sleeve cooling mechanism of 1st Embodiment of this invention. It is a perspective view of the structure of the sleeve cooling mechanism of the 2nd Embodiment of this invention. It is a figure which looked at the sleeve cooling mechanism of the 2nd Embodiment of this invention from the axis direction. It is sectional drawing of the sleeve cooling mechanism of the 2nd Embodiment of this invention. It is a figure which looked at the sleeve cooling mechanism of the 3rd Embodiment of this invention from the axis direction. It is a schematic block diagram of the sleeve cooling mechanism of the 4th Embodiment of this invention. It is a schematic block diagram of the sleeve cooling mechanism of the 5th Embodiment of this invention. It is a schematic block diagram of the sleeve cooling mechanism of the 6th Embodiment of this invention. It is a schematic block diagram of the sleeve cooling mechanism of the 7th Embodiment of this invention. It is a schematic block diagram of the sleeve cooling mechanism of 8th Embodiment of this invention. It is a schematic block diagram of the sleeve cooling mechanism of the 9th Embodiment of this invention. It is a schematic block diagram of the sleeve cooling mechanism of the tenth embodiment of this invention.

[First Embodiment]
Hereinafter, the first embodiment of the present invention will be described in detail with reference to the drawings. The nuclear power plant of the present embodiment is a plant that generates electricity using nuclear power.
As shown in FIG. 1, the nuclear power plant 100 of the present embodiment has, for example, a pressurized water reactor 101 as a nuclear reactor. The pressurized water reactor 101 uses light water as a reactor coolant and a neutron reducer to make high-temperature and high-pressure water, and sends the high-temperature and high-pressure water to the steam generator 103 to generate steam by heat exchange, which is a generator for a steam turbine. Send to 105 to generate electricity.

The nuclear power plant 100 of the present embodiment includes a pressurized water reactor 101, a pressurizer 102, and a steam generator 103 inside the reactor building 109 (reactor containment vessel). The pressurizer 102 pressurizes the primary cooling water in order to suppress boiling of the primary cooling water (light water) in the reactor pressure vessel 110 of the pressurized water reactor 101. The steam generator 103 steams the secondary cooling water by the heat of the primary cooling water.
The nuclear plant 100 includes a steam turbine 104 driven by steam generated by the steam generator 103, a steam turbine generator 105 generated by driving the steam turbine 104, and a water condensing device that returns steam from the steam turbine 104 to water. 106 and are provided outside the reactor building 109.

The steam generator 103 and the steam turbine 104 are connected by a steam pipe 2a, which is a pipe 2 extending inside and outside the reactor building 109. The condenser 106 and the steam turbine 104 are connected by a water supply pipe 2b. The steam pipe 2a and the water supply pipe 2b penetrate the concrete wall portion 10 of the reactor building 109.

As shown in FIG. 2, the pipe support structure 1 of the first embodiment is formed in the pipe 2 penetrating the wall portion 10 of the reactor building 109 and the wall portion 10 in the nuclear power plant 100 (see FIG. 1). It is a structure that intervenes between the formed hole portion 13 (through hole).
In the following description, the direction in which the axis O of the pipe 2 extends is referred to as the axis direction Da. Further, the direction orthogonal to the axis O is called the radial direction, the side away from the axis O in the radial direction is called the radial outside, and the side approaching the axis O in the radial direction is called the radial inside.
Further, in the axial direction Da, the inner side of the reactor building 109 with respect to the wall portion 10 is the axial one side Da1 (left side of the paper in FIG. 1), and the outer side of the reactor building 109 with respect to the wall portion 10 is set. Da2 on the other side in the axial direction (right side of the paper in FIG. 1).

The pipe support structure 1 has a sleeve 3 arranged in a space between a pipe 2 inserted into a hole 13 from one side Da1 in the axial direction to Da2 on the other side in the axial direction and a space between the hole 13 and the pipe 2. And a sleeve cooling mechanism 7A for cooling the sleeve 3.

The wall portion 10 has a front surface 11 extending along the vertical surface facing Da1 on one side in the axial direction, a back surface 12 extending along the vertical surface facing Da2 on the other side in the axial direction, and a back surface 12 extending from the front surface 11 to the back surface 12. It has a hole portion 13 which is a through hole formed so as to penetrate the wall portion 10 in a circular shape centered on the axis O.
The pipe 2 extends along the axis O so as to insert the hole 13 from the axial direction Da1 to the axial direction other side Da2. The pipe 2 has a cylindrical shape centered on the axis O.

The sleeve 3 has a cylindrical shape that surrounds the pipe 2 from the outer peripheral side, and supports the pipe 2 on the wall portion 10. The sleeve 3 has a tubular sleeve body 4, a plurality of ribs 5 connecting the outer peripheral surface of the sleeve body 4 and the sleeve body 4 and the inner peripheral surface of the hole 13, and the inner peripheral surface of the sleeve body 4 and piping. It has a plurality of sealing plates 6 for connecting to the outer peripheral surface of 2.

The sleeve body 4 is made of metal. The sleeve body 4 is formed coaxially with the pipe 2. The length of the axial Da of the sleeve body 4 is longer than the thickness of the wall portion 10. The end of the sleeve body 4 on the other side in the axial direction Da2 projects from the back surface 12 of the wall portion 10 to the other side Da2 in the axial direction.
The sealing plate 6 and the rib 5 are made of the same metal as the sleeve body 4.

The sealing plate 6 is a disk-shaped plate that airtightly seals the end portion of Da2 on the other side in the axial direction of the sleeve body 4. A through hole 6a is formed in the center of the sealing plate 6, and the pipe 2 inserts the through hole 6a through the through hole 6a. The pipe support structure 1 of the present embodiment has two sealing plates 6. The two sealing plates 6 are fixed at a predetermined interval in the axial direction Da. Both of the two sealing plates 6 are arranged on Da2 on the other side in the axial direction from the back surface 12 of the wall portion 10. The sealing plate 6 and the sleeve body 4 are joined by welding, for example. The sealing plate 6 and the pipe 2 are joined by welding, for example.

The rib 5 is a disk-shaped plate that airtightly seals between the sleeve body 4 and the hole 13. A through hole 5a is formed in the center of the rib 5, and the sleeve body 4 inserts the through hole 5a through the through hole 5a. The ribs 5 are provided at equal intervals in the axial direction Da, but the intervals between the ribs 5 adjacent to each other in the axial direction Da may be appropriately adjusted according to the required strength.

FIG. 2 is a developed view of the sleeve cooling mechanism 7A of the present embodiment. The sleeve cooling mechanism 7A of the present embodiment is attached to the outer peripheral surface of the sleeve 3 and extends in the circumferential direction of the sleeve 3. The vertical direction in FIG. 2 is the circumferential direction of the sleeve 3, and the dimension L is ½ of the circumferential length of the sleeve 3. Two sleeve cooling mechanisms 7A are attached to the sleeve 3 of the present embodiment at equal intervals in the circumferential direction. The entire circumference of the sleeve 3 in the circumferential direction is covered by the two sleeve cooling mechanisms 7A.

As shown in FIGS. 2 and 3, the sleeve cooling mechanism 7A of the present embodiment has a heat transfer tube 15 extending along the outer peripheral surface of the sleeve 3 and between the heat transfer tube 15 and the outer peripheral surface 3a of the sleeve 3. The carbon sheet 16 arranged, the band member 17 for fixing the heat transfer tube 15 to the sleeve 3, the paste-like heat transfer medium 18 filled between the heat transfer tube 15 and the carbon sheet 16, and the heat transfer tube 15 It has a water supply device 19 for supplying cooling water.
The cooling water supplied from the water supply device 19 is introduced into one end of the heat transfer tube 15. The drainage used for cooling is discharged from the other end of the heat transfer tube 15.

The heat transfer tube 15 is arranged so as to meander on the outer peripheral surface 3a of the sleeve 3. The heat transfer tube 15 of the present embodiment extends in the circumferential direction of the sleeve 3, and a plurality of heat transfer tubes 15 (three in the present embodiment) arranged at predetermined intervals in the axial direction Da are 180 °. The configuration is connected via the bend 15a. A plurality of heat transfer tubes 15 are fixed by band members 17.

FIG. 4 is a cross-sectional view of the sleeve cooling mechanism of the present embodiment. The band member 17 has an arc portion 20 along the outer peripheral surface of the heat transfer tube 15 and fastening portions 21 provided at both ends of the arc portion 20. The fastening portion 21 is fixed to the outer peripheral surface of the sleeve 3 by, for example, a bolt B. The band member 17 is formed so that the heat transfer tube 15 is in close contact with the sleeve 3 (carbon sheet 16) by tightening using the fastening portion 21.

The carbon sheet 16 (graphite sheet) is a sheet-like member formed of graphite (graphite) and having a high thermal conductivity. The thermal conductivity of the carbon sheet 16 is 700 to 1950 W (m · K). The thickness of the carbon sheet 16 is about 1 mm.

A paste-like heat transfer medium 18 is filled between the heat transfer tube 15 and the sleeve 3 (carbon sheet 16). The paste-like heat transfer medium 18 is made of a material having high thermal conductivity. The material of the heat transfer medium is arbitrary, but the paste-like heat transfer medium 18 is preferably, for example, heat transfer cement, heat transfer grease, metal paste, carbon paste, or the like, but is not limited thereto.

According to the sleeve cooling mechanism 7A of the present embodiment, when the cooling water is introduced into the heat transfer tube 15 by the water supply device 19, heat is transferred from the sleeve 3 to the cooling water, and the sleeve 3 is cooled.

According to the above embodiment, the sleeve 3 is cooled by the sleeve cooling mechanism 7A, so that the heat transferred to the concrete wall portion 10 through the sleeve 3 can be reduced. This makes it easy to keep the temperature of the wall portion 10 below the permissible value.

Further, by supplying the cooling water to the tubular heat transfer tube 15, it is possible to prevent the cooling water from leaking. That is, for example, when a so-called plate coil that introduces cooling water between a wavy plate-shaped member and a planar plate-shaped member is used as a cooling device, the cooling water may leak from the vicinity of the welded portion. However, this can be prevented.

Further, by filling the paste-like heat transfer medium 18 between the heat transfer tube 15 and the carbon sheet 16, the heat transfer efficiency between the heat transfer tube 15 and the sleeve 3 is improved, and the sleeve 3 which is a heat source is improved. Can promote cooling. Further, since the heat transfer tube 15 is fixed by the band member 17, the heat transfer tube 15 can be easily removed.

It is not always necessary to provide the carbon sheet 16 between the sleeve 3 and the pipe 2. When the carbon sheet 16 is omitted, the paste-like heat transfer medium 18 is filled between the heat transfer tube 15 and the outer peripheral surface of the sleeve 3.

[Second Embodiment]
Hereinafter, the nuclear power plant according to the second embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the first embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIGS. 5, 6 and 7, the sleeve cooling mechanism 7B of the nuclear power plant of the present embodiment includes a clamp portion 23 fixed to the sleeve 3 and a plurality of fins 24 joined to the clamp portion 23. It has a metal structure 22 having a. The structure 22 is used in pairs.
Further, a duct 28 is arranged above the structure 22. Further, a radiation guard 29 is arranged between the structure 22 and the back surface 12 of the wall portion 10.

The clamp portion 23 includes a clamp portion main body 25 having a cylindrical surface 23a that comes into surface contact with the outer peripheral surface 3a of the sleeve 3, and flange portions 26 provided at both ends of the clamp portion main body 25 in the circumferential direction. is doing. The clamp portion main body 25 has a shape in which the cylinder is divided into two by a dividing surface including the axis O of the cylinder. In other words, the clamp portion main body 25 is a half-split tubular member having a semicircular cross-sectional shape. The clamp portion 23 is formed so as to cover substantially half the circumference of the sleeve 3.
The flange portion 26 projects radially outward from both ends in the circumferential direction of the clamp portion main body 25.

The fin 24 is a plate-shaped member brazed to the outer peripheral surface of the clamp portion 23. The fin 24 has a plate shape having a main surface facing the axial direction Da. The thickness of the fin 24 is thinner than that of the clamp portion 23. The fins 24 are anodized. The fin 24 may be joined to the outer peripheral surface 23b of the clamp portion 23 by welding.

As the material for forming the structure 22, metals such as aluminum, iron, and copper having good heat transfer characteristics are preferable.

The pair of structures 22 are connected near the upper end of the sleeve 3 and near the lower end of the sleeve 3. That is, the center of each clamp portion 23 in the circumferential direction faces sideways.
The duct 28 is a tubular member whose axis O is along the vertical direction. The lower end of the duct 28 increases in diameter toward the bottom. The duct 28 is arranged at a position overlapping the structure 22 when viewed from above.

The radiation guard 29 is, for example, a plate-shaped member made of aluminum. The radiation guard 29 is formed so that the size seen from the axial direction Da is larger than that of the structure 22. The radiation guard 29 is fixed to the wall portion 10 by a bracket (not shown). The portion for fixing the radiation guard 29 is not limited to the wall portion 10, and may be the sleeve 3.

According to the above embodiment, the sleeve cooling mechanism 7B is a metal structure 22 having a clamp portion 23 and fins 24 joined to the clamp portion 23, whereby the heat of the sleeve 3 is transferred to the structure 22. Can be released via.

Further, since the pair of clamp portions 23 are connected near the upper end of the sleeve 3 and near the lower end of the sleeve 3, the air rising flow of natural convection is less likely to be obstructed, so that the cooling of the sleeve 3 is promoted. Can be done.

Further, by having the tubular duct 28 arranged above the structure 22 and having the axis O along the vertical direction, the air rising flow is promoted by the draft effect, and the heat transfer between the fins 24 and the air is increased. Can be done.
Further, by providing the radiant guard 29, it is possible to reduce the radiant heat emitted from the structure 22 and transmitted to the wall portion 10.

The duct 28 and the radiation guard 29 do not necessarily have to be provided, and may be omitted depending on the situation such as cost and installation space. Further, the structure 22 of the present embodiment is attached as a set of two, but the sleeve 3 is not limited to this, and the sleeve 3 is provided by using one structure 22 depending on the situation such as cost and installation space. It can also be configured to be cooled.

In the above embodiment, the pair of structures 22 are connected near the upper end of the sleeve 3 and near the lower end of the sleeve 3, but the present invention is not limited to this. The connection position of the structure 22 can be appropriately changed based on the air flow direction around the sleeve 3 and the like.

[Third Embodiment]
Hereinafter, the nuclear power plant according to the third embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the second embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIG. 8, the fins 24C of the structure 22 of the present embodiment are divided into a plurality of fins 24C in the circumferential direction.

The fin 24C is composed of a plurality of fin pieces 27. That is, a plurality of fin pieces 27 are brazed to the outer peripheral surface 23b of the clamp portion 23 of the structure 22. The base ends of the plurality of fin pieces 27 are connected to the outer peripheral surface 23b of the clamp portion 23 without a gap. A gap is provided between the adjacent fin pieces 27.

According to the above embodiment, since the fins 24C are divided, the development of the temperature boundary layer can be suppressed and the heat dissipation efficiency can be improved. Further, since the chance of air colliding with the fin 24C increases, the heat dissipation efficiency can be improved.

[Fourth Embodiment]
Hereinafter, the nuclear power plant according to the fourth embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the first embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIG. 9, the sleeve cooling mechanism 7D of the present embodiment has a heat pipe 30 and a refrigerant R enclosed in the heat pipe 30. Pure water or CFC substitutes can be used as the refrigerant R.

The heat pipe 30 has a first pipe 31 extending in contact with the outer peripheral surface 3a along the circumferential direction of the outer peripheral surface 3a of the sleeve 3, and a second pipe 32 extending upward from the upper end 31a of the first pipe 31. A third pipe 33 extending downward from the upper end of the second pipe 32, and a fourth pipe 34 connecting the lower end 33a of the third pipe 33 and the lower end 31b of the first pipe 31.

The first pipe 31 is a portion that comes into contact with the sleeve 3 which is the heating portion H. The first pipe 31 is in contact with substantially half of the outer peripheral surface 3a of the sleeve 3. The first pipe 31 extends from the vicinity of the upper end of the sleeve 3 to the vicinity of the lower end of the sleeve 3.
One end of the second pipe 32 is connected to the upper end 31a of the first pipe 31. The second pipe 32 is arranged so that the other end is higher than one end connected to the first pipe 31. The heat pipe 30 is formed so that no part of the second pipe 32 is lower than that of the first pipe 31.
One end of the third pipe 33 is connected to the other end of the second pipe 32. The third pipe 33 extends in the vertical direction.

Next, the operation of the sleeve cooling mechanism 7 of the present embodiment will be described.
First, the refrigerant R1 inside the first pipe 31 is heated and vaporized. The vaporized refrigerant R2 moves upward through the second pipe 32, is cooled by the third pipe 33 which is a cooling unit, and is liquefied. The liquefied refrigerant R3 returns to the first pipe 31 by gravity. The returned refrigerant R is vaporized again and circulates.

According to the above embodiment, the sleeve 3 which is a heat source can be cooled by circulating the refrigerant R without using a device such as a pump. Further, even if there is no space around the sleeve 3, the sleeve cooling mechanism 7D can be installed by extending the second pipe 32 and arranging the third pipe 33 in a place having a space.

[Fifth Embodiment]
Hereinafter, the nuclear power plant 100 according to the fifth embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the fourth embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIG. 10, the sleeve cooling mechanism 7E of the present embodiment has a tubular heat pipe duct 40 that surrounds a part of the third pipe 33 from the outer periphery. The heat pipe duct 40 is a tubular member whose axis is along the vertical direction. The lower end of the heat pipe duct 40 increases in diameter toward the bottom. A predetermined gap G1 is formed between the outer peripheral surface of the third pipe 33 and the inner peripheral surface of the heat pipe duct 40.

According to the above embodiment, by having the heat pipe duct 40 that surrounds the third pipe 33 from the outer periphery, the air rising flow is promoted by the draft effect, so that the heat transfer between the third pipe 33 and the air is greatly increased. can do. As a result, ventilation of the third pipe 33, which is a cooling unit, is promoted, coagulation / cooling of the refrigerant R is promoted, and cooling of the sleeve 3 which is a heat source is promoted.
Further, since the lower end of the heat pipe duct 40 has an enlarged diameter, it is possible to prevent a decrease in air flow due to pressure loss.

[Sixth Embodiment]
Hereinafter, the nuclear power plant according to the second embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the fifth embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIG. 11, a plurality of first heat pipe fins 41 are joined to the third pipe 33 of the present embodiment.

The fin 41 for the first heat pipe is joined to the outer peripheral surface of the third pipe 33 and extends along the third pipe 33. That is, the fin 41 for the first heat pipe is formed so that the main surface of the fin 41 for the first heat pipe is along the vertical direction. The fin 41 for the first heat pipe is made of a metal such as aluminum, iron, or copper having good heat transfer characteristics.
The fin 41 for the first heat pipe has a plate shape, and its base end is joined to the outer peripheral surface of the third pipe 33 so as to project in the radial direction of the third pipe 33. A predetermined gap G2 is provided between the radial tip of the first heat pipe fin 41 (the radial direction of the third pipe 33) and the inner peripheral surface of the heat pipe duct 40.

According to the above embodiment, the heat transfer speed can be improved by installing the fin 41 for the first heat pipe in the third pipe 33 which is the cooling unit and expanding the heat transfer area. Further, since the main surface of the fin 41 for the first heat pipe is formed along the vertical direction, the resistance of the air flow can be reduced. As a result, aggregation and cooling of the refrigerant R are promoted, and cooling of the sleeve 3 which is a heat source is promoted.

[Seventh Embodiment]
Hereinafter, the nuclear power plant according to the seventh embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the sixth embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIG. 12, the sleeve cooling mechanism 7G of the present embodiment has a parallel pipe 42 provided in parallel with the third pipe 33 and fins for a second heat pipe provided in the parallel pipe 42. It has 43 and a bell mouth 44.

The parallel pipe 42 extends in the vertical direction like the third pipe 33. The upper end 42a of the parallel pipe 42 is connected to the upper end 32a of the second pipe 32, and the lower end 42b of the parallel pipe 42 is connected to the fourth pipe 34.
A plurality of second heat pipe fins 43 having a main surface intersecting the extending direction of the parallel pipe 42 are joined to the outer peripheral surface of the parallel pipe 42. The second heat pipe fin 43 is a plate-shaped member joined to the outer peripheral surface of the parallel pipe 42. The fin 43 for the second heat pipe has a plate shape having a main surface facing the axial direction of the parallel pipe 42. A predetermined gap is formed between the fins 43 for the second heat pipes adjacent to each other in the vertical direction.

The bell mouth 44 is an annular member provided between the fin 43 for the second heat pipe and the existing ventilation fan 45.
The bell mouth 44 is installed so that one end of the bell mouth 44 in the axial direction faces the fin 43 for the second heat pipe and the other end of the bell mouth 44 faces the existing ventilation fan 45. That is, the bell mouth 44 is arranged so that an air flow is generated inside the bell mouth 44 by the ventilation fan 45, and the fin 43 for the second heat pipe is cooled by the air flow. The other end of the bell mouth 44 is formed so as to gradually increase in diameter toward the end.

According to the above embodiment, the heat transfer is promoted by installing the fin 43 for the second heat pipe, and the aggregation and cooling of the refrigerant R are promoted in combination with the fin 41 for the first heat pipe, and the sleeve is a heat source. Cooling of 3 is promoted.
Further, by combining the bell mouth 44 with the existing ventilation fan 45, the flow rate of air by the ventilation fan 45 can be increased, and the cooling efficiency of the second heat pipe fin 43 can be improved.

[Eighth Embodiment]
Hereinafter, the nuclear power plant according to the eighth embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the fourth embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIG. 13, the sleeve cooling mechanism 7H of the present embodiment has a second heat pipe 47 having the same shape as the heat pipe 30 of the fourth embodiment.

The second heat pipe 47 is a fifth pipe 35 extending in the circumferential direction along the outer peripheral surface 3a of the sleeve 3 while contacting the outer peripheral surface 3a, and is different from the first pipe 31 in the circumferential direction of the sleeve 3. The fifth pipe 35 arranged in the range, the sixth pipe 36 extending upward from the upper end 35a of the fifth pipe 35, the seventh pipe 37 extending downward from the upper end 36a of the sixth pipe 36, and the seventh pipe. It has an eighth pipe 38 connecting the lower end 37a of the seventh pipe 37 and the lower end 35b of the fifth pipe 35.

The operation of the second heat pipe 47 is the same as that of the heat pipe 30. That is, the fifth pipe 35 is a portion in contact with the sleeve 3 which is the heating portion H, and the seventh pipe 37 functions as a cooling portion.

According to the above embodiment, in the sleeve cooling mechanism 7 of the fourth embodiment, since only the circumferential half circumference of the sleeve 3 is cooled, there is a risk of deformation of the sleeve 3, but the sleeve cooling mechanism 7H of the present embodiment is used. Then, since the entire circumference of the sleeve 3 is cooled, the risk of deformation can be reduced.
Further, when the installation space is restricted, the pipes, which are cooling portions, can be arranged at the same position while cooling the entire circumference of the sleeve 3 by merging and branching the pipes.

[Ninth Embodiment]
Hereinafter, the nuclear power plant according to the ninth embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the eighth embodiment described above will be mainly described, and the description thereof will be omitted for the same parts.
As shown in FIG. 14, the sleeve cooling mechanism 7J of the present embodiment has the heat pipe 30 and the second heat pipe 47 of the eighth embodiment, and the fin 41 for the first heat pipe and the duct for the heat pipe of the sixth embodiment. It is a configuration provided with 40.

According to the above embodiment, the cooling amount of the sleeve 3 can be maximized. That is, the heat transfer speed can be improved by the first heat pipe fin 41 and the heat pipe duct 40 while cooling the entire circumference of the sleeve 3.

[10th Embodiment]
Hereinafter, the nuclear power plant according to the tenth embodiment of the present invention will be described in detail with reference to the drawings. In this embodiment, the differences from the first embodiment described above will be mainly described, and the description thereof will be omitted for the same parts. The pipe 2K of the present embodiment has a flange 42, and the pipe support structure 1 of the present embodiment has a flange cooling mechanism 7K for cooling the flange 42.

As shown in FIG. 15, the pipe 2K of the present embodiment protrudes radially outward from the pipe main body 41 and the outer peripheral surface of the pipe main body 41, and is fixed to the wall portion 10 via the fixing portion 50. And have. The outer diameter of the flange 42 is larger than the inner diameter of the hole 13.
One surface 42a facing the wall portion 10 of the flange portion 42 and the back surface 12 of the wall portion 10 are connected by a plurality of fixing portions 50.
The fixing portion 50 is a cylindrical member that airtightly seals between the flange 42 and the wall surface 10.

The other surface 42b of the flange 42 is provided with a flange cooling mechanism 7K having substantially the same configuration as the sleeve cooling mechanism 7A of the first embodiment. The flange cooling mechanism 7K has a heat transfer tube 15 extending in the circumferential direction on the other surface 42b of the flange 42, and a carbon sheet 16 arranged between the heat transfer tube 15 and the other surface 42b of the flange 42. ing.
Similar to the sleeve cooling mechanism 7A of the first embodiment, the heat transfer tube 15 is fixed to the flange 42 by a band member (not shown), and a paste-like form is formed between the heat transfer tube 15 and the carbon sheet 16. The heat transfer medium is filled.

According to the above embodiment, the flange 42 is cooled by the flange cooling mechanism 7K, so that the heat transferred from the piping main body 41 to the wall portion via the flange 42 and the fixing portion 50 can be reduced. This makes it easy to keep the temperature of the wall portion below the permissible value.

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment and includes design changes and the like within a range not deviating from the gist of the present invention. ..
For example, the configuration of the sleeve 3 is not limited to that described above, and the number of ribs 5, sealing plates 6, and the like can be appropriately changed.

1 Pipe support structure 2 Pipe 2a Steam pipe 2b Water supply pipe 3 Sleeve 4 Sleeve body 5 Rib 6 Sealing plate 7A, 7B, 7C, 7D, 7E, 7F, 7G, 7H, 7J Sleeve cooling mechanism 7K Flange cooling mechanism 10 Wall 11 Front surface 12 Back surface 13 Hole part 15 Heat transfer pipe 15a 180 ° bend 16 Carbon sheet 17 Band member 18 Paste-like heat transfer medium 19 Water supply device 20 Arc part 21 Fastening part 22 Structure 23 Clamp part 24 Fin 25 Clamp part body 26 Flange Part 27 Fin piece 28 Duct 29 Radiation guard 30 Heat pipe 31 1st pipe 32 2nd pipe 33 3rd pipe 34 4th pipe 35 5th pipe 36 6th pipe 37 7th pipe 38 8th pipe 40 Heat pipe duct 41 Fins for the first heat pipe 42 Parallel pipes 43 Fins for the second heat pipe 44 Bellmouth 45 Ventilation fan 47 Second heat pipe 50 Fixed part 100 Nuclear plant 101 Pressurized water reactor 102 Pressurizer 103 Steam generator 104 Steam turbine 105 Steam Generator for turbine 106 Water condenser 109 Reactor building 110 Reactor pressure vessel Da Axial direction Da1 Axial direction One side Da2 Axial direction other side H Heating part O Axial line R Refrigerator

Claims (10)

Reactor building with walls with holes,
The piping that penetrates the hole and
A sleeve that supports the pipe on the wall by forming a cylinder that surrounds the pipe from the outer peripheral side.
A sleeve cooling mechanism provided on the outer periphery of the sleeve to cool the sleeve is provided .
The sleeve cooling mechanism is
A pair of clamp portions fixed to the sleeve, having a cylindrical surface in surface contact with the outer peripheral surface of the sleeve, and covering approximately half the circumference of the sleeve.
It has a metal structure having fins joined to each of the pair of clamp portions.
The pair of clamp portions are connected near the upper end of the sleeve and near the lower end of the sleeve.
The fin has a plate shape having a main surface facing the axis of the sleeve.
The fins joined to each of the pair of clamp portions are divided into a plurality of fin pieces arranged in the circumferential direction.
A nuclear power plant in which a gap is provided between adjacent fin pieces . The sleeve cooling mechanism is
A tubular heat transfer tube extending along the outer peripheral surface of the sleeve,
A water supply device that supplies cooling water to the heat transfer tube,
A band member that fixes the heat transfer tube to the sleeve so that the heat transfer tube is in contact with the outer peripheral surface of the sleeve.
The nuclear power plant according to claim 1, further comprising a paste-like heat transfer medium filled between the heat transfer tube and the outer peripheral surface of the sleeve. The nuclear power plant according to claim 2, wherein a carbon sheet is arranged between the heat transfer tube and the sleeve. The nuclear power plant according to any one of claims 1 to 3, which is arranged above the structure and has a tubular duct whose axis is along the vertical direction. The sleeve cooling mechanism is
A first pipe extending along the outer peripheral surface of the sleeve in the circumferential direction while contacting the outer peripheral surface,
A second pipe formed so that one end is connected to the upper end of the first pipe and the other end is above the one end.
A third pipe whose upper end is connected to the upper end of the second pipe and extends in the vertical direction,
A heat pipe having a fourth pipe connecting the lower end of the third pipe and the lower end of the first pipe.
The nuclear power plant according to any one of claims 2 to 4 , further comprising a refrigerant sealed in the heat pipe. The nuclear power plant according to claim 5 , which has a tubular heat pipe duct that surrounds a part of the third pipe from the outer periphery. The fifth or sixth aspect of the third pipe, wherein a part of the third pipe is joined to an outer peripheral surface of the third pipe and has a metal fin for a first heat pipe extending along the third pipe. Nuclear power plant. The second pipe and the fifth pipe connected to the fourth pipe so as to be parallel to the third pipe,
The nuclear power plant according to claim 7 , further comprising a plurality of second heat pipe fins joined to an outer peripheral surface of the fifth pipe and having a main surface intersecting the extending direction of the fifth pipe. The sleeve cooling mechanism is
A fifth pipe extending along the outer peripheral surface of the sleeve along the circumferential direction while contacting the outer peripheral surface, and the fifth pipe arranged in a range different from that of the first pipe in the circumferential direction of the sleeve. ,
A sixth pipe connected to the upper end of the fifth pipe and formed so that the other end is above the one end.
A seventh pipe whose upper end is connected to the upper end of the sixth pipe and extends in the vertical direction,
A second heat pipe having an eighth pipe connecting the lower end of the seventh pipe and the lower end of the fifth pipe,
The nuclear power plant according to any one of claims 5 to 8 , further comprising a refrigerant sealed in the second heat pipe. A sleeve cooling mechanism that cools the sleeve that supports the piping.
A pair of clamp portions fixed to the sleeve, having a cylindrical surface in surface contact with the outer peripheral surface of the sleeve, and covering approximately half the circumference of the sleeve.
It has a metal structure having fins joined to each of the pair of clamp portions.
The pair of clamp portions are connected near the upper end of the sleeve and near the lower end of the sleeve.
The fin has a plate shape having a main surface facing the axis of the sleeve.
The fins joined to each of the pair of clamp portions are divided into a plurality of fin pieces arranged in the circumferential direction.
A sleeve cooling mechanism in which a gap is provided between adjacent fin pieces .

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