1. Field of the Invention
The present invention relates to a cooler, a cooling apparatus using the same, and a method for cooling a heat generation element. In particular, the present invention relates to a boiling system cooler, a codling apparatus using the same, and a method for cooling a heat generation element.
2. Description of the Related Art
In recent years, a pressure vessel of a light-water reactor as shown in
Examples of the boil cooling system include a pool boiling system and a forced flow boiling system. Herein, a general pool boiling system cooling mechanism for a heat generation element will be described.
However, when a large heat flux is added to the contact part, the conventional pool boiling system cooler has a problem. The situation is shown in
The critical heat flux of the conventional pool boiling system cooler is about 1000 kW/m2 under a condition of atmospheric pressure in the presence of water in a saturation state (see S. G. Kandlikar, M. Shoji, and V. K. Dhir, “Handbook of Phase Change: Boiling and Condensation,” Taylor & Francis, 1999). Meanwhile, the cooler requires a critical heat flux of at least about 2000 kW/m2 or more in order to prevent the melt-through of the bottom part of the reactor pressure vessel of the light-water reactor.
On the other hand, the present inventors dramatically increase a conventional critical neat flux in a simple structure in Japanese Patent Laid-open No. 2009-139005. In the simple structure, a porous body is provided between a heat generation element and water in a cooling container. While water is supplied to the heat generation element by the capillary action of the porous body, vapor generated by supplying the water is discharged into the water in the container. However, in order to more safely prevent the melt-through of the bottom part of the reactor pressure vessel, it has been desired to develop a cooler exhibiting a further improved cooling effect.
It is an object of the present invention to provide a cooler which has a simple structure and stably exhibits a good cooling effect, a cooling apparatus using the same, and a method for cooling a heat generation element.
After intensive investigations, the present inventors found that a porous body disclosed in Japanese Patent Laid-Open No. 2009-139005 is provided as a first porous body on a heat generation element side, and a second porous body having a permeability higher than that of the first porous body is provided on a working fluid side so as to overlap with the first porous body, which can provide a cooler exhibiting a further improved cooling effect, although the detail of the investigations will be described later.
That is, one aspect of the present invention is a boiling system cooler for cooling a heat generation element. The boiling system cooler includes: a container accommodating a working fluid; and a cooling member provided in the container so as to be brought into contact with the working fluid and to face the heat generation element. The cooling member has a stacked structure including a first porous body provided on the heat generation element side and a second porous body provided on the working fluid side. The first porous body includes: a first working fluid supply part supplying the working fluid, by capillary action, to a contact part which is in contact with the heat generation element; and a first vapor discharge part discharging vapor generated in the contact part to the second porous body side. The second porous body includes: a second working fluid supply part supplying the working fluid to the first porous body; and a second vapor discharge part discharging the vapor discharged from the first porous body, into the working fluid. The second porous body has a higher permeability of the working fluid compared with the first porous body.
In the cooler according to one embodiment of the present invention, the second porous body has a pore radius greater than that of the first porous body and/or a void ratio greater than that of the first porous body, to set the permeability of the working fluid to be higher compared with the first porous body.
In the cooler according to another embodiment of the present invention, both the first and second porous bodies include an aggregate of porous particles.
In the cooler according to another embodiment of the present invention, both the first and second porous bodies include a porous layer.
In the cooler according to another embodiment of the present invention, one of the first and second porous bodies includes an aggregate of porous particles, and the other includes a porous layer.
In the cooler according to another embodiment of the present invention, the first porous body includes an aggregate of porous nanoparticles, and the second porous body includes a porous layer having a mesh structure.
In the cooler according to another embodiment of the present invention, the first porous body includes a porous layer, and the first vapor discharge part is a pore penetrating the porous layer.
In the cooler according to another embodiment of the present invention, a clearance region is formed between the first porous body and the contact part which is in contact with the heat generation element.
In the cooler according to another embodiment of the present invention, the second porous body is made of a metal.
In the cooler according to another embodiment of the present invention, the second porous body made of the metal has an end fixed to the heat generation element by welding.
The cooler according to another embodiment of the present invention further includes a heat release fin welded to the heat generation element, and the second porous body is fixed to the heat release fin by welding.
Another aspect of the present invention is a cooling apparatus including: the cooler of the present invention; and a condenser connected to a container included in the cooler and liquidizing a vaporized working fluid.
Another aspect of the present invention is a boiling system cooling method for at least partially immersing a heat generation element in a working fluid accommodated in a container to cool the heat generation element. The cooling method includes attaching a cooling member to a surface of a portion of the heat generation element immersed in the working fluid. The cooling member has a stacked structure including a first porous body provided on the heat generation element side and a second porous body provided on the working fluid side. The first porous body includes: a first working fluid supply part supplying the working fluid, by capillary action, to a contact part which is in contact with the heat generation element; and a first vapor discharge part discharging vapor generated in the contact part to the second porous body side. The second porous body includes: a second working fluid supply part supplying the working fluid to the first porous body; and a second vapor discharge part discharging the vapor discharged from the first porous body, into the working fluid. The second porous body has a higher permeability of the working fluid compared with the first porous body.
In the cooling method according to one embodiment of the present invention, nanoparticles are dispersed in the working fluid; and the second porous body including a porous layer having a mesh structure is provided on the surface of the portion of the heat generation element immersed in the working fluid. An aggregate of porous nanoparticles is constituted by depositing the nanoparticles in the working fluid boiled by heat from the heat generation element on a heating surface of the heat generation element, to form the first porous body between the heat generation element and the second porous body, which attaches the cooling member to the surface of the portion of the heat generation element immersed in the working fluid.
The cooler of the present invention, the cooling apparatus using the same, and the method for cooling the heat generation element exhibit at least the following effects.
(1) The critical heat flux can be achieved, which is about 2000 kW/m2 required in order to prevent the melt-through of the bottom part of the reactor pressure vessel, or about 2500 kW/m2 or more.
(2) Since the liquid is forcibly supplied to the contact part by capillary action when the vapor is generated in the working fluid supply part of the first porous body and the contact part, the container (water tank) accommodating the working fluid such as water can use a mere puddle without having the necessity of including a flow passage of water or a pump or the like in the case of the pool boiling cooling system. This can provide a simple structure, which provides a low installation cost and a low running cost.
(3) The porous body provided on the contact part which is in contact with the heat generation element is preferably thinner from the viewpoint of a capillary limit mechanism. When the porous body is too thin, dryout is apt to be produced in the porous body while a coalesced bubble is retained in the upper part of the porous body, which causes a decrease in the critical heat flux. In the present invention, the porous body provided on the contact part which is in contact with the heat generation element is the first porous body, and the second porous body having a higher permeability of the working fluid compared with the first porous body is provided on the first porous body (on the working fluid side). Such a constitution can suppress the occurrence of the dryout to prevent the decrease in the critical heat flux even if the thickness of the first porous body is decreased. This is because the second porous body plentifully supplying the working fluid toward the first porous body is present between the first porous body and vapor mass above the first porous body.
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
The second porous body has a pore radius greater than that of the first porous body to facilitate the passage of the working fluid, which can set the permeability of the working fluid to be higher compared with the first porous body. Herein, the pore radius of the porous body may be a radius of a pore originally included in each of the porous bodies, or a radius of a pore formed in each of the porous bodies. Herein, the pore of the porous body may have various shapes such as a polygonal shape, a circular shape, and an elliptical shape, and the “pore radius” of the present invention represents a radius of a circumscribed circle in the various pore shapes. Furthermore, the second porous body has a void ratio greater than that of the first porous body to facilitate the passage of the working fluid, which can set the permeability of the working fluid to be higher compared with the first porous body. The void ratio of the porous body can be increased by, for example, adjusting the particle size and amount or the like of a binder mixed with a metal powder in the manufacturing process of the porous body.
The working fluid may be a liquid having surface tension such as water, a low-temperature fluid, a refrigerant, or an organic solvent, for example.
Concerning the structure of the first porous body, since the contact area of the first porous body to the contact part is increased, the size of the pore for letting the vapor generated in the contact part out into water is preferably decreased, and may be 100 to 2000 μm, for example. Since pressure loss when the vapor passes through the bottom part of the porous body can be decreased, a distance between the pores for letting the vapor generated in the contact part out into water is preferably decreased, and may be 100 to 1000 μm, for example.
The porous substance constituting the first working fluid supply part in the first porous body may be ceramics such as cordierite or a sintering metal, for example. Particularly, the first working fluid supply part desirably includes a porous body having a good wettability such as an oxide, or a porous body subjected to processing such as plasma irradiation to improve a wettability.
The first porous body supplies the working fluid to the contact part according to capillary action if the liquid is vaporized in the first working fluid supply part. When the length of a capillary tube (that is, the thickness of the first porous body) is decreased considering a limit mechanism of liquid supply by a capillary force, the limit of the liquid supply, i.e., a “critical heat flux”, can be further increased. On the other hand,
Thus, the thickness of the porous body provided on the contact part which is in contact with the heat generation element is preferably decreased from the viewpoint of the capillary limit mechanism. When the porous body is thinner than the macro liquid film, the dryout is apt to occur in the porous body, which disadvantageously causes the decrease in the critical heat flux. In the present invention, the porous body provided on the contact part which is in contact with the heat generation element is the first porous body, and the second porous body having a higher permeability of the working fluid compared with the first porous body is provided on the first porous body (on the working fluid side). Such a constitution can suppress the occurrence of the dryout to prevent the decrease in the critical heat flux even if the thickness of the first porous body is decreased since the second porous body plentifully supplying the working fluid toward the first porous body is present between the first porous body and the vapor mass above the first porous body. Since the liquid supply amount of the second porous body is preferably increased, the thickness of the second porous body is also preferably increased. Specifically, when the thickness of the first porous body is decreased to about 100 μm, for example, the thickness of the second porous body is preferably about 1 to 2 mm or more.
The second porous body may be made of ceramics such as cordierite. The second porous body is particularly preferably made of a metal from the viewpoint of processability or strength. The second porous body particularly desirably includes a porous body having a good wettability such as an oxide, or a porous body subjected to processing such as plasma irradiation to improve a wettability.
The forms of the first and second porous bodies are not particularly limited, and both the first and second porous bodies may include an aggregate of porous particles, for example. Both the first and second porous bodies may include a porous layer. Furthermore, one of the first and second porous bodies may include an aggregate of porous particles, and the other may include a porous layer. When the first and second porous bodies include an aggregate of porous particles, a clearance between a plurality of porous particles may have a function as the vapor discharge part, for example, and the member around the clearance may function as the working fluid supply part.
The stacked structure of the cooling member is not limited to the stacked structure including the first and second porous bodies. The cooling member may have a stacked structure including three layers in total. The stacked structure includes the first and second porous bodies, and a third porous body provided on the working fluid side of the second porous body. In this case, the third porous body includes a working fluid supply part supplying the working fluid to the second porous body, and a vapor discharge part discharging the vapor discharged from the second porous body into the working fluid. Similarly, the cooling member may have a stacked structure including four layers or more in total. The stacked structure includes a plurality of porous bodies stacked on the working fluid side of the second porous body.
A clearance region is preferably formed between the first porous body of the cooling member and the contact part which is in contact with the heat generation element. The vapor generated on the bottom face of the first working fluid supply part of the first porous body advances along the bottom face of the first working fluid supply part, and enters into the first vapor discharge part. The vapor is discharged upward from the first vapor discharge part. Herein, when the clearance region is formed between the first porous body of the cooling member and the contact part which is in contact with the neat generation element, the clearance region serve as the passage of the vapor generated on the bottom face of the first porous body, and promotes the discharge of the vapor, which provides an improvement in the critical heat flux. Although the surface of the contact part may be daringly processed to a rough surface, the clearance region is slightly required for discharging the vapor. Therefore, by merely bringing the first porous body into contact with the contact part, the clearance region is sufficiently formed according to the original surface roughness of the contact part. When the clearance region is absent, the discharging property of the vapor is decreased. The first porous body may be fixed to the contact part with an adhesive.
As another aspect of the present invention, cooling can be performed by immersing the entire heat generation element into the working fluid, or immersing a part of the heat generation element into the liquid surface of the working fluid. In this case, the heat generation element possibly takes various forms such as a floating state and a state where it is placed on the bottom face of the container. In short, by attaching the cooling member having the stacked structure including the first and second porous bodies to the portion immersed into the working fluid, cooling can be performed as in the above example.
Since the liquid is forcibly supplied to the contact part by capillary action when the vapor is generated in the working fluid, supply part of the first porous body and the contact part according to the present invention, the container (water tank) accommodating the working fluid such as water can use a mere puddle without having the necessity of including a flow passage of water or the like in the case of a pool boiling cooling system. Furthermore, the container does not require a pump, which can provide a simple structure, thereby providing a low installation cost and a low running cost. In the present invention, the porous body provided on the contact part which is in contact with the heat generation element is the first porous body, and the second porous body having a higher permeability of the working fluid compared with the first porous body is provided on the first porous body (on the working fluid side). Such a constitution can suppress the occurrence of the dryout to prevent the decrease in the critical heat flux even if the thickness of the first porous body is decreased since the second porous body plentifully supplying the working fluid toward the first porous body is present between the first porous body and the vapor mass above the first porous body. The decrease in the critical heat flux can be prevented by the similar method even in a forced flow boiling cooling in which the flow passage is provided and the working fluid is circulated by the pump although the installation cost and the running cost in the forced flow boiling cooling are higher than those in the pool boiling cooling system.
The cooling member including the honeycomb-shaped first and second porous bodies so as to cover the bottom part of the reactor pressure vessel of the second embodiment may be supported without using the honeycomb-attached net. For example, as shown in
In the second embodiment, as shown in
In a cooling apparatus of the present invention, as a fourth embodiment, first porous bodies and second porous bodies which are included in a cooling member may be constituted so that the porous bodies having a gradually greater pore size are stacked in a stepwise fashion on the porous body having a small pore size. Preferably, the fine pore size of the porous body directly brought into contact with a bulk liquid at this time is different, and preferably largely different from the diameters of fine particles such as garbage which are largely present in a working fluid such as water. For example, preferably, the fine pore size of the porous body directly brought into contact with the bulk liquid is sufficiently greater, or sufficiently smaller than the diameters of the fine particles. Such a constitution can be expected to exhibit an effect of suppressing a clog phenomenon caused by the entering of the fine particles which are present in the working fluid into a deep part of the porous body, which provides an effect of maintaining a liquid supply effect to a heating surface by the porous body for a long time. In principle, for example, when the porous bodies having a gradually greater pore size are stacked in a stepwise fashion on the porous body having a small pore size, and the outermost fine pore size of the porous body is sufficiently greater or sufficiently smaller than the particle size of the garbage in the working fluid, the inflowing garbage particles do not infiltrate into the deep part of the porous body immediately. The garbage particles accumulate near the inlet port of the porous body under the influence of stagnation or the like formed in the shallow region of the porous body. Therefore, fine pores of 300 μm located in the outermost region of the porous body are first clogged, which sufficiently suppresses the formation of the clog in the porous body caused by the infiltration of the fine particles into the deep part of the porous body.
As a method for installing the cooling member according to the fifth embodiment, for example, an aqueous solution including diffused nanoparticles is provided on a heating surface as a position in which a first porous body is desired to be formed, by a predetermined means, and the aqueous solution is boiled on the heating surface by heating while the state is maintained. Thus, porous nanoparticles in the boiled aqueous solution are deposited on the heating surface to constitute an aggregate. This serves as the first porous body. Next, a second porous body including a porous layer having a mesh structure is provided on the aggregate of porous nanoparticles. Thereby, the cooling member including the first porous body including the aggregate of porous nanoparticles and the second porous body including the porous layer having the mesh structure can be provided. The cooling member may be provided by providing a second porous body on the surface of a heat generation element, and subsequently providing a first porous body between the surface of the heat generation element and the second porous body. As such a constitution, for example, the first porous body is formed between the heat generation element and a second porous body by dispersing nanoparticles in a working fluid, providing the second porous body including a porous layer having a mesh structure on the surface of a portion of the heat generation element immersed in the working fluid, and depositing the nanoparticles in the working fluid boiled by heat from the heat generation element on the heating surface of the heat generation element to constitute the aggregate of porous nanoparticles. Thereby the cooling member is attached to the surface of the portion of the heat generation element immersed in the working fluid. Specifically, for example, a honeycomb porous body (second porous body) is previously provided in a pressure vessel of a reactor. The nanoparticles are supplied to the working fluid upon occurrence of an accident, and dispersed. Subsequently, the working fluid including the nanoparticles is boiled on the working fluid side surface (heating surface) of the pressure vessel, and thereby the first porous body including the aggregate of porous nanoparticles is formed between the heating surface and the second porous body.
In the aggregate of nanoparticles included in the first porous body in the fifth embodiment, a number of fine pores between the particles or in the particles are included in a first working fluid supply part or a first vapor discharge part. Also in the present embodiment, the first porous body performs the supply of the working fluid and the discharge of the vapor in separate courses, and thereby the occurrence of a problem that the vapor covers the contact part, which causes the restriction of a critical heat flux, can be suppressed, as described with reference to
The present invention can be applied to various electronic devices and thermal instruments having a high-heat-generating density in addition to the cooling of the reactor pressure vessel. Examples thereof include diverter cooling of a fusion reactor, an improvement in performance of capillary pump loop, a semiconductor laser, cooling of a server of a data center, a chlorofluorocarbon cooling system chopper control device a power electronic device, or the like. The present invention can be applied to a water-cooling jacket for improving a high temperature work environment by reducing heat diffused to an ambient environment from the side part and bottom part of a glass or aluminum melting furnace. Furthermore, the present invention can be applied to a water-cooling jacket which cools a refractory wall for a large garbage incinerator or the like from the outside to reduce the damage and is installed in the side part and bottom part of the refractory wall.
Hereinafter, the present invention will be described in more detail with reference to Examples, but the present invention is not limited thereto.
A circular disk having a composition including a mixture of cellulose acetate and cellulose nitrate (brand name: MF-Millipore) was used as a first porous body of a cooling member. The circular disk of the first porous body had a diameter of 30 mm, a pore radius of 0.8 μm, a void ratio of 80%, and a board thickness of 0.15 mm. A circular disk including a porous body made of a SUS board (SUS316L) was used as a second porous body of the cooling member. The circular disk of the second porous body had a diameter of 30 mm, a pore radius of 10 μm, a void ratio of 70%, and a board thickness of 1 mm. The permeability of the second porous body was ten times or so as much as that of the first porous body.
The second porous body was mounted on the first porous body having such a constitution to provide the cooling member.
In an experiment, heating was performed while the voltage of a cartridge heater was raised by 5 V under atmospheric pressure (0.1 MPa). A sufficient steady state was confirmed, and the output voltages of the thermocouples were recorded. Herein, steady state was determined according to whether a temperature change for 20 minutes was 1 K or less. This operation was repeated until the steady state could not be maintained. A comparison experiment was performed for the case where the cooling member was not installed (naked surface), the case where only the first porous body was installed, and the case where only the second porous body was installed, in addition to the case where the above-mentioned cooling member was installed.
Subsequently, in order to consider the relation between the surface roughness of the surface of a contact part (heating surface) and a critical heat flux, the following test was performed using the experiment device, first porous body, and second porous body of the test example 1.
First, the surface of the contact part brought into contact with the working fluid of the experiment device of the test example 1 was ground with a sandpaper (#40), and a first porous body and a second porous body were provided in this order on the surface of the contact part to provide a cooling member. The surface of the contact part brought into contact with the working fluid of the experiment device of the test example 1 was ground with a sandpaper (#80), and a first porous body and a second porous body were provided in this order on the surface of the contact part to provide a cooling member. Furthermore, a first porous body was provided on the surface of the contact part brought into contact with the working fluid of the experiment device of the test example 1, with an adhesive sandwiched therebetween, without grinding the surface of the contact part, and a second porous body was further provided on the first porous body to provide a cooling member.
Regarding these cooling members, a boiling curve was obtained in the same procedure as that of the rest example 1.
The following test was performed in order to evaluate the critical heat flux according to the cooling member shown in the fifth embodiment using the same type device as the experiment device shown in
An aggregate of porous nanoparticles was produced as a first porous body of a cooling member as follows. That is, first, nanoparticles made of titanium dioxide (average particle size: 21 nm) weighed with an electronic balance were dispersed in a beaker in which distilled water prepared previously was placed. At this time, the concentration of the nanoparticles (titanium dioxide) was 0.04 g/L. Next, a heating surface shown in
Next, a circular disk including a porous body made of a SUS board (SUS316L) was used as a second porous body of the cooling member (porous layer having a mesh structure). A circular disk having a diameter of 30 mm and a circular disk having a diameter of 10 mm were prepared as the circular disk of the second porous body. The circular disks had a pore radius of 10 μm, a void ratio of 70%, and a board thickness of 1 mm.
The second porous body having such a constitution (porous layer having a mesh structure) was mounted on the first porous body (aggregate of porous nanoparticles) to provide the cooling member.
In an experiment, heating was performed while the voltage of a cartridge heater was raised by 5 V under atmospheric pressure (0.1 MPa). A sufficient steady state was confirmed, and the output voltages of the thermocouples were recorded. Herein, steady state was determined according to whether a temperature change for 20 minutes was 1 K or less. This operation was repeated until the steady state could not be maintained. A comparison experiment was performed for the case where the cooling member was not installed (naked surface), the case where only the first porous body (aggregate of porous nanoparticles) was installed, and the case where only the second porous body (porous layer having a mesh structure) was installed, in addition to the case where the above-mentioned cooling member was installed.
Number | Date | Country | Kind |
---|---|---|---|
2013-055533 | Mar 2013 | JP | national |
2013-262872 | Dec 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2014/052783 | 2/6/2014 | WO | 00 |