KR102704465B1 - Crossed Heat Pipe and associated Nuclear Device - Google Patents

Abstract

The present invention relates to a nuclear power plant equipped with a crossed heat pipe (CHP) and a passive cooling system using the CHP.
The cross-type heat pipe is a double-tube structure comprising an inner tube and an outer tube surrounding the inner tube, has a refrigerant for heat transfer inside, and is composed of a cross joint portion designed to allow the two flows in the ascending and descending directions to intersect without mixing or colliding with each other.
Cross-shaped heat pipes allow the design of a nuclear power plant that implements a fully passive cooling system by transferring heat generated in the lower reactor to the upper steam generator without the need for separate power.

Description

Crossed Heat Pipe and Associated Nuclear Device

The present invention relates to a nuclear power plant equipped with a crossed heat pipe (CHP) and a passive cooling system using the CHP.

Nuclear power is a cheap and stable energy source, but radiation leaks due to accidents (such as the Fukushima or Chernobyl accidents) are serious hazards. If an accident occurs in a nuclear reactor and internal power is cut off, the cooling pumps that circulate the cooling water stop. This causes the core of the reactor to overheat and melt, and a large amount of radiation leaks due to hydrogen explosions generated in the core.

If a passive cooling system is implemented that can transfer the heat of the reactor to the steam generator without using electricity and pumps and without external power, the above accidents can be prevented, and the safety of nuclear power plants can be greatly improved. For this purpose, there are attempts using heat pipes and thermosiphons, but these devices were originally used for cooling small systems, and have limitations in increasing the reactor capacity due to the structurally unavoidable low efficiency.

A thermosyphon (Fig. 9) operates vertically, with the refrigerant vaporized in the heating section at the bottom rising through the tube and condensing into a liquid in the cooling section at the top and descending. Although the thermosyphon shows good heat transfer efficiency compared to a simple structure, when the high-temperature fluid rises and the low-temperature fluid falls, they collide in opposite directions, causing turbulence and reducing the mobility of the fluids, which limits the ability to increase heat transfer efficiency.

In the case of a heat pipe (Fig. 10), heat transfer occurs through the evaporation of the refrigerant, the rapid flow of the vapor resulting therefrom, and the movement of the liquefied refrigerant in the opposite direction by the capillary phenomenon through the internal wick structure. Compared to general metal heat sinks that depend on heat conduction, a heat pipe exhibits a high heat transfer speed because it transfers heat through the rapid movement of vapor, and since the refrigerant moves by the capillary phenomenon instead of gravity, it has the advantage of being able to transfer heat horizontally rather than vertically or in the direction opposite to gravity, and has been used for cooling small electronic devices, etc. However, since it relies on the capillary phenomenon where the movement of the liquid in the opposite direction is relatively slow, unlike the rapid speed of the vapor, there is a limit to increasing the heat exchange capacity because the system becomes larger and the length of the heat pipe becomes longer, and the refrigerant movement time takes a long time.

Therefore, the passive cooling system using this cannot help but have low heat exchange capacity, so although there are cases where it has been applied to micro reactors, it is difficult to apply it to larger reactors.

The present invention has been designed to overcome the limitations of such prior art, and the purpose of the present invention is to provide an efficient and safe energy production means that reduces the risk of accidents by designing a nuclear power plant that implements a passive cooling system using a crossed heat pipe (CHP) capable of dissipating or transferring a large amount of heat at a high speed.

To achieve this purpose, the cross-type heat pipe has a double-tube structure of an inner tube and an outer tube surrounding the inner tube, the inner tube has a first opening that opens downward and a second opening that opens upward, and is configured with a cross joint portion designed so that the inner tube and the outer tube intersect each other at the center in the vertical direction. In addition, a certain amount of refrigerant flows inside the cross-type heat pipe for heat transfer.

Cross-type heat pipes use the enormous heat of vaporization generated and absorbed during the boiling and condensation process of refrigerant for heat transfer, and have a faster heat transfer speed and larger capacity than heat conduction using metal or convection of liquid.

In addition, by guiding the rising and falling refrigerants through a cross joint so that they do not mix or collide with each other, the movement speed of the refrigerant can be increased, and thus the heat transfer capacity can be increased.

The Crossed Heat Pipe Reactor (CHPR) is a reactor that applies this to heat exchange between the reactor and steam generator of a nuclear power plant.

According to the present invention, since the cross-type heat pipe is doubled into an inner and outer pipe, and a cross joint is arranged in the middle so that the inner and outer refrigerants can cross without collision, the direction of movement of the refrigerants during the heat transfer process can flow in only one direction without collision with each other, so that the flow speed of the refrigerant increases and heat transfer is performed at high speed.

If a cross-type heat pipe is installed, the heat generated in the lower reactor can be transferred to the upper steam generator without separate power. This is called a passive cooling system. Since the passive cooling system does not use pumps, it can fundamentally prevent serious nuclear power plant accidents such as core meltdown and radioactive leaks that may occur when the coolant pump stops due to internal power failure caused by a disaster.

Figure 1 is a schematic diagram of a cross-shaped heat pipe of the present invention.
Figure 2 is a three-dimensional perspective view of the cross joint portion of Figure 1.
Figure 3 is a comparison diagram between the cross heat pipe (CHP) of the present invention and a conventional heat pipe (HP).
Figure 4 is a schematic diagram of a bent inner tube according to the present invention.
Figure 5 is a schematic diagram of a heat transfer fin according to the present invention.
Figure 6 is a drawing showing the structure of a crossed heat pipe reactor (CHPR).
Figure 7 is a drawing showing the structure of a safety-enhanced crossed heat pipe reactor (CHPR).
Figure 8 is a cross-sectional view of a large-capacity steam generator.
Figure 9 is a schematic diagram of a conventional thermosyphon.
Figure 10 is a schematic diagram of a heat pipe utilizing a conventional capillary phenomenon.

FIG. 1 illustrates a cross-shaped heat pipe having a cross joint according to an embodiment of the present invention.

A Crossed Heat Pipe (CHP) is a heat transfer device with a double-pipe shape that has an inner tube and an outer tube surrounding it. The inner tube is open in the upper and lower directions, the outer tube is sealed in both the upper and lower directions, and the inside contains a refrigerant that participates in heat transfer like a conventional heat pipe. There is a cross joint designed to allow the refrigerant flowing in the inner and outer tubes to intersect in the middle of the upper and lower directions, and the upper and lower parts of the crossed heat pipe are divided based on this cross joint. Specifically, the inner tube is divided into an upper inner tube and a lower inner tube, and the outer tube is divided into an upper outer tube and a lower outer tube.

The lower end of the lower inner tube is connected to the lower outer tube through the first opening, and the upper end of the upper inner tube is connected to the upper outer tube through the second opening.

The refrigerant is designed to circulate inside the cross-shaped heat pipes by gravity, with the light vapor rising and the heavy liquid falling, without any separate power source.

Cross heat pipes (CHPs) are used in certain systems to transfer heat from the hot part of the bottom (heating section) to the cold part of the top (cooling section) when the bottom is hot and the top is cold.

The place where heat is applied from the outside is the lower outer shell, and the heat is transferred from the outer wall of the lower outer shell, boiling the refrigerant accumulated in the lower outer shell. The refrigerant that has boiled and become vapor rises along the inner wall of the lower outer shell. As it rises, it meets the cross joint in the middle, and as the vapor crosses over to the upper inner tube, it continues to rise. Through the second opening at the upper end of the upper inner tube, the vapor meets the upper outer shell, loses heat from the cold wall of the outer shell, condenses, and turns into liquid. The condensation heat generated at this time is released through the outer wall of the upper outer shell. The condensed liquid flows down by gravity and gathers in the lower inner tube while passing through the cross joint in the middle.

As the liquefied refrigerant continues to accumulate in the lower inner tube, the water level rises, creating a pressure difference as shown in Figure 1. This pressure difference acts as a force that causes the refrigerant to continue to circulate in the same direction.

The refrigerant flows out through the first opening at the lower end of the inner tube to the lower outer tube, and then receives heat through the wall of the lower outer tube, boiling, and the circulation of the refrigerant is repeated.

Figure 2 illustrates the three-dimensional structure of a cross joint, which can be said to be a core part of a cross-type heat pipe.

Cross Joint: In the present invention, it is a part designed so that the refrigerant flowing vertically through the inner and outer pipes can cross each other without mixing at the midpoint of the vertical directions of the cross-shaped heat pipes.

The cross joint has a first connecting passage in which the upper end of the lower outer tube and the lower end of the upper inner tube meet and are connected in an upward direction, and a second connecting passage in which the lower end of the upper outer tube and the upper end of the lower inner tube meet and are connected in a downward direction. The refrigerant that has boiled and become vapor moves upward from the lower outer tube to the upper inner tube through the first connecting passage. Then, the refrigerant that has cooled and become liquefied moves from the upper outer tube to the lower inner tube through the second connecting passage. The upper and lower flows are blocked by a blocking plate to prevent them from mixing or colliding with each other, and the blocking plate extends radially around the first connecting passage and the second connecting passage. The blocking plate is in contact with the inner surface of the outer tube and the outer surface of the inner tube. Therefore, the cross joint has a shape in which the path in the direction of the first connecting passage and the path in the direction of the second connecting passage are blocked by the blocking plate.

By configuring the inner tube, outer tube, and cross joint in this way, the rising gas and the descending liquid flow in a certain direction without colliding with each other, and the problem of the speed decreasing due to collision while the refrigerant is moving up and down, as in the existing thermosyphon, has been solved. In addition, the problem of the existing heat pipe taking a long time to move the liquid by the capillary phenomenon through the wick has also been solved.

If we organize the refrigerant's movement path,

Lower outer tube (boiling) -> 1st connection (cross joint) -> upper inner tube -> 2nd opening -> upper outer tube (condensing) -> 2nd connection (cross joint) -> lower inner tube -> 1st opening -> lower outer tube

In this order, the circulation is in one direction, and heat is transferred from the bottom to the top through repeated boiling and condensation.

Figure 3 briefly illustrates the problems that occur when the system becomes larger and the length of the existing heat pipe becomes longer, and the advantages of the cross-type heat pipe compared to this.

Conventional heat pipes show relatively good performance when they are short, but as the length increases, heat transfer tends to be concentrated at the boundary rather than over the entire section. The refrigerant evaporates before reaching the end of the heat pipe through the wick, so the parts far from the boundary do not contribute much to heat transfer. In addition, the refrigerant that has evaporated in the heating section is in a gaseous state and can move quickly, but when the vapor that has reached a long distance liquefies in the cooling section and returns to the heating section in the opposite direction, it takes a long time to move in a liquid state through the capillary phenomenon of the wick.

In contrast, in the case of the cross-type heat pipe, the vapor induced through the upper inner pipe reaches the end of the cooling section and then proceeds in the opposite direction through the second opening, so liquefaction occurs throughout the entire cooling section, and the liquefied refrigerant also reaches the end of the heating section through the lower inner pipe and returns to the lower outer pipe through the first opening before the refrigerant begins to boil, so boiling occurs over a wide section of the heating section. This means that the section that actually contributes to heat transfer is larger.

In addition, as the cross-type heat pipe becomes longer, the amount of refrigerant inside also increases, and the level of the liquefied refrigerant that condenses, descends, and accumulates in the lower inner pipe also increases, so the pressure difference acting in the direction of circulation by gravity increases, and the force that increases the movement speed of the refrigerant is applied.

Due to these characteristics, when applied to relatively large systems such as nuclear reactors, the heat exchange performance of the cross-type heat pipe is superior to that of existing heat pipes.

Figure 4 illustrates a bent inner tube. By bending the end portion of the inner tube that collides with the outer tube at the upper and/or lower end in the direction of travel, the collision resistance is reduced, thereby reducing the velocity reduction of the refrigerant due to the collision.

In Fig. 5, heat transfer fins are illustrated. If wing structures (heat transfer fins) for heat conduction are attached to the upper and lower outer walls of the exterior of the cross-shaped heat pipe, the heat conduction speed can be further increased.

Meanwhile, the inner tube has the function of inducing the movement of the refrigerant, and the actual part where heat transfer takes place between the cooling and heating parts is the wall surface of the outer tube. Therefore, if the inner tube is made of a material with low thermal conductivity and the outer tube is made of a material with relatively high thermal conductivity (such as copper or aluminum), unnecessary condensation can be prevented from occurring in the inner tube, and condensation and boiling can occur efficiently in the outer tube.

If hydrophobic materials are used on the inner and outer walls or a hydrophobic coating is applied, the circulation speed can be increased because the liquid rolls off the wall surface without sticking to it.

The refrigerant of the cross-type heat pipe can be used the same as that of the existing heat pipe. Water is the most commonly used refrigerant, but if the operating temperature is lower, acetone, ammonia, ethanol, etc. can be used, and if the operating temperature is higher than water, naphthalene, sulfur, mercury, etc. with a higher boiling point can be used, and if the operating temperature is high, such as 400 degrees or higher, cesium, calcium, sodium, etc. can be used.

If the heat exchange efficiency between the cooling and heating sections is important rather than simply for heat dissipation purposes, the boundary section can be wrapped with insulation to reduce heat loss along the path of movement.

It is common to use circular pipes as the material for the inner and outer tubes, but various shapes such as square or flat can be used depending on the heat exchange environment. In addition, the cross joint can also be modified to ensure smooth refrigerant flow between the first and second connections depending on the shape of the inner and outer tubes.

The internal facilities of a nuclear power plant consist of a nuclear reactor, a steam generator, other facilities (pressurizer, cooling pump, piping system, safety facilities, etc.) and a power generation system. A reactor that embeds core facilities such as the nuclear reactor and steam generator in a single pressure vessel is called an integral reactor.

A nuclear power plant in the form of an integral reactor that transfers the heat of the reactor to the steam generator using the crossed heat pipe (CHP) is called a crossed heat pipe reactor (CHPR).

Figure 6 illustrates the structure of a crossed heat pipe reactor (CHPR).

In order to simplify the system and increase safety, mainly in small or ultra-small reactors, an integral reactor method is selected, and heat exchange between the reactor and steam generator is implemented by utilizing the excellent heat transfer capacity of cross-type heat pipes.

In order to ensure the safety of the reactor, the reactor and related systems including the steam generator are enclosed in a single pressure vessel, and cross heat pipes are arranged vertically from the top to the bottom of the pressure vessel. In this way, the lower part of the heat pipe penetrates the reactor and the upper part of the heat pipe penetrates the steam generator, and the heating part illustrated in Fig. 1 corresponds to the reactor and the cooling part corresponds to the steam generator.

Looking at the cross-sectional view of the core in Fig. 6, the heat pipes are arranged in a cross-shaped manner to surround the fuel rods of the reactor, thereby transferring the heat generated in the reactor at the bottom to the steam generator at the top.

Heavy water reactors, light water reactors, sodium and lead-cooled fast reactors mainly use rod-shaped nuclear fuel, but high-temperature gas-cooled reactors use spherical coated particle nuclear fuel, and molten salt reactors use nuclear fuel melted in a liquid state, so the cross-section of the core may be different. However, since most commercial reactors use rod-shaped nuclear fuel, it is depicted as a rod for easy understanding.

The cross heat pipe must be welded so that there is no gap as it passes through the bulkhead between the reactor and the steam generator. The internal refrigerant of the cross heat pipe can be naphthalene, sulfur, mercury, etc., but since the reactor configuration is diverse and the temperature and pressure of the operating environment are different accordingly, a refrigerant suitable for the conditions must be used. For example, in the case of the sodium-cooled fast reactor (SFR), which is widely used in the design of an integral reactor, the reactor temperature is 500 to 550 degrees, the steam generator steam pressure is 50 to 70 atm, and the temperature is 260 to 350 degrees. In this case, mercury (boiling point 1 atm, 357 degrees) can be used as a suitable refrigerant.

In Fig. 7, a design with enhanced safety of the above-mentioned crossed heat pipe reactor (CHPR) is illustrated. The reactor is the same as in Fig. 6 and is therefore omitted, and the steam generator portion is illustrated.

For example, in the case of a sodium-cooled fast reactor (SFR) that uses sodium as the primary coolant, a design in which cross-type heat pipes penetrate the bulkhead between the reactor and the steam generator may pose a safety issue because sodium can cause a violent chemical reaction and even an explosion risk if it comes into contact with water in the steam generator. This is because even if thoroughly welded, cracks can form in the bulkhead due to fatigue caused by the high pressure and long-term operation of the steam generator.

In this case, the heat exchange efficiency may be lower than when the crossed heat pipes are in direct contact with the water of the steam generator, but if the steam generator vessel is designed as a double vessel as shown in the drawing, the water inside the double vessel and the primary coolant inside the reactor can be perfectly isolated. In addition, if the empty space surrounding the crossed heat pipes between the double vessel and the pressure vessel is filled with a metal with excellent heat transfer properties, such as aluminum, it will not only help heat transfer but also maintain the internal structure of the steam generator strong.

The interior of the double vessel is equipped with heat transfer fins for efficient heat transfer.

Normally, the size of a nuclear reactor is determined by the size of the nuclear fuel system according to the power generation capacity, but the steam generator can be lengthened upwards as needed. As a result, the length of the cross-type heat pipe for heat exchange also increases, which increases the heat exchange capacity.

And, if a larger capacity heat exchange is to be implemented, the number of the above-mentioned double vessels can be increased and each double vessel can be designed to be surrounded by a cross-shaped heat pipe to increase the heat exchange capacity. This is illustrated in the cross-sectional view of a large-capacity steam generator in Fig. 8. In this drawing, a total of seven double vessels are illustrated to be used, but the number can be implemented in various ways with two or more symmetrical shapes depending on the required heat exchange capacity.

Additionally, the empty space between the double vessel and the pressure vessel can be filled with a material such as aluminum that has excellent heat conductivity and is strong, thereby increasing heat transfer efficiency.

Claims (8)

A double-tube structure comprising an inner tube and an outer tube surrounding the inner tube,
The inner wall is open in both the vertical and horizontal directions, and the outer wall is sealed in both the vertical and horizontal directions.
There is a refrigerant inside for heat transfer,
A structure having a first connecting passage in which the upper end of the lower outer surface and the lower end of the upper inner tube meet and are connected in an upward direction in the middle of the vertical direction, and a second connecting passage in which the lower end of the upper outer surface and the upper end of the lower inner tube meet and are connected in a downward direction, and having a cross joint portion in the shape in which the path in the direction of the first connecting passage and the path in the direction of the second connecting passage are blocked by a blocking plate.
Heat pipe. In claim 1,
A heat pipe having a curved shape at the upper end and/or the lower end of the inner tube. In claim 1,
A heat pipe with heat transfer fins attached to the upper or lower outer wall of the above-mentioned exterior. In claim 1,
A heat pipe in which the inner tube is made of a material having relatively low thermal conductivity and the outer tube is made of a material having high thermal conductivity. In claim 1,
A heat pipe having a hydrophobic coating on the inner wall of the inner and outer tubes. Using a heat pipe as described in any one of claims 1 to 5,
The reactor and steam generator are housed in a single pressure vessel,
A nuclear power plant designed with heat pipes arranged vertically in a pressure vessel so that the lower part of the heat pipe penetrates the reactor and the upper part of the heat pipe penetrates the steam generator. In claim 6,
A nuclear power plant with double-layered pressure vessels for the steam generator to enhance safety. In claim 7,
A nuclear power plant that increases heat transfer capacity by installing two or more double-containers.