JP6102815B2 - Cooler - Google Patents

Description

  The present invention relates to a cooler that cools a heating element using a refrigerant.

  Patent Document 1 discloses a steam engine having a heating unit that heats a fluid in a fluid container in which the fluid is sealed, and a cooling unit that cools vapor that is heated and vaporized by the heating unit. The steam engine disclosed in Patent Document 1 displaces a liquid by the expansion pressure of steam and outputs mechanical energy, and cools and liquefies the steam in a cooling unit to self-excited vibration in the fluid in the fluid container. Displace.

Japanese Patent No. 4411829

  Although the steam engine of patent document 1 outputs mechanical energy as mentioned above, it can be utilized for purposes other than obtaining mechanical energy. For example, the inventors have promoted the heat transfer from the heating unit to the cooling unit by the self-excited vibration displacement of the fluid in the fluid container, so if the heating unit is configured using a heating element to be cooled, It was considered that the fluid in the fluid container can be used as the refrigerant fluid for cooling the heating element. That is, it was thought that the steam engine of patent document 1 can be utilized as a cooler for cooling the heating element.

  However, in the cooler having the configuration like the steam engine of Patent Document 1, the refrigerant fluid (liquid) is displaced by self-excited vibration, so that the heating element accommodation space for accommodating the heating element in the heating unit is always filled with liquid. It is not. For this reason, there is a problem that the liquid supply to the surface of the heating element is insufficient and the cooling capacity of the cooler is lowered.

  Specifically, when the liquid in the heating element accommodation space is vaporized by heat from the heating element, and the gas-liquid interface is displaced from the heating element accommodation space to the cooling unit space, a liquid film is formed on the surface of the heating element. Further, the liquid film boils by heat from the heating element, and steam is generated. At this time, if the liquid remaining on the surface of the heating element is scattered by the generated steam (bubbles), a dry region where no liquid exists on the surface of the heating element is generated. When the dry region occurs, the heat transfer area on the surface of the heating element decreases, and the amount of heat exchange between the surface of the heating element and the liquid decreases. Once the dry region is generated, the liquid is not supplied to the surface of the heating element until the next period in which the gas-liquid interface is displaced from the cooling unit space to the heating element housing space, and the state in which the heat exchange amount is reduced continues. As described above, when the gas-liquid interface is displaced from the heating element housing space to the cooling unit space, the liquid is scattered from the surface of the heating element and the liquid supply state to the heating element surface cannot be maintained. The capacity is lower than the cooling capacity that can be demonstrated originally.

  In view of the above points, an object of the present invention is to provide a cooler that cools a heating element with self-excited vibration displacement of a refrigerant fluid and that can prevent a decrease in cooling capacity.

In order to achieve the above object, in the invention described in claim 1,
A heating element housing space (14a) for accommodating the heating element (12) is formed, and a heating unit (14) for heating and vaporizing the refrigerant fluid contained in the heating element housing space by heat from the heating element. When,
A cooling section (16a) communicating with the heating element housing space, and a cooling section (16) for cooling and liquefying the refrigerant fluid vaporized by the heating section and flowing into the cooling section space;
An absorption part space (28a) communicating with the cooling part space is formed, and an absorption part (28) for absorbing a volume change due to heating and cooling of the refrigerant fluid is provided.
The heating element housing space, the cooling part space, and the absorption part space as a whole constitute one space (32) in which the refrigerant fluid is enclosed,
The heating unit and the cooling unit are adapted to self-excited vibration of the refrigerant fluid in one space by repeating vaporization and liquefaction of the refrigerant fluid,
The heating unit has opposing surfaces (151, 142, 121) facing the heating element surface (121), and the liquid refrigerant fluid is bridged between the heating element surface and the opposing surface by the action of surface tension. In addition, the heating element and the facing surface are arranged.

  Note that “the liquid refrigerant fluid is bridged between the surface of the heating element and the opposing surface” means a state in which the liquid refrigerant fluid bridges the surface of the heating element and the opposing surface. It means a state in which the refrigerant fluid is connected from the surface of the heating element to the opposing surface and is held between the surface of the heating element and the opposing surface.

  In the present invention, when the gas-liquid interface is displaced from the heating element housing space to the cooling part space, the refrigerant fluid (liquid) is bridged between the heating element surface and the opposing surface, so that the heating element surface accompanying steam generation The liquid can be prevented from splashing from the surface, and the liquid can be kept on the surface of the heating element. For this reason, even when the liquid level is displaced from the heating element housing space to the cooling unit space, the liquid supply state to the heating element surface can be maintained for a long time, so that the cooling capacity of the cooler can be prevented from being lowered.

  In addition, the code | symbol in the bracket | parenthesis of each means described in this column and the claim is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

It is sectional drawing which shows the whole structure of the cooler in 1st Embodiment. It is sectional drawing for demonstrating the Laplace length. (A), (b) is an enlarged view of a heat generating body and a counter member in FIG. 1, (a) shows the state of the liquid refrigerant in the initial stage of the expansion stroke, and (b) is the liquid refrigerant after a certain time has elapsed. Shows the state. It is sectional drawing which shows the whole structure of the cooler in the comparative example 1. (A), (b) is an enlarged view of the heat generating body in FIG. 4, (a) shows the state of the liquid refrigerant in the initial stage of the expansion stroke, and (b) shows the state of the liquid refrigerant after a certain time has elapsed. Show. It is an enlarged view of the heat generating body and counter member in 2nd Embodiment. It is an enlarged view of the heat generating body and counter member in 3rd Embodiment. It is an enlarged view of the heat generating body and counter member in 4th Embodiment. It is an enlarged view of area | region A1 in FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, parts that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
FIG. 1 is a diagram showing the overall configuration of the cooler 10 of the present embodiment, and is shown in cross-section. The cooler 10 cools the heating element 12 using the refrigerant sealed in the cooler 10. As shown in FIG. 1, the cooler 10 includes a heating unit 14, a cooling unit 16, a drive assist device 18, and the like. The refrigerant of the cooler 10 is a fluid that is liquid at room temperature and boils when heated by the heating element 12. For example, the refrigerant is a fluorine-based inert liquid. In addition, arrow DR1 of FIG. 1 represents the up-down direction DR1 in the state in which the cooler 10 was installed, ie, the vertical direction DR1.

  The heating element 12 is a member cooled by the cooler 10 in order to generate heat, and specifically, is an electronic component such as a semiconductor element that needs to be cooled. An example is an inverter semiconductor element module. The electrical terminals 12a and 12b of the heating element 12 protrude from the heating unit 14, and the heating element 12 generates heat when the electrical terminals 12a and 12b are energized.

  A heating element accommodating space 14a in which the heating element 12 is accommodated is formed in the heating part 14, and the heating part 14 has the heating element 12 in the heating element accommodating space 14a. The heating unit 14 heats and evaporates the liquid refrigerant contained in the heating element housing space 14a, that is, the liquid refrigerant fluid, by the heat from the heating element 12.

  Specifically, the heating unit 14 includes a box-shaped heating element accommodation wall 141 that forms a heating element accommodation space 14a as a heating part space. And in the heat generating body accommodation wall 141, the heat generating body 12 is accommodated so that the surroundings of the heat generating body 12 may be filled with a gaseous or liquid refrigerant. For example, in the present embodiment, the entire heating element housing space 14a is filled with a gas or liquid refrigerant, and when the refrigerant is all liquid, the entire heating element 12 or a part thereof is immersed in the liquid refrigerant. It has become. One end on the cooling unit 16 side of the heating element accommodation space 14a communicates with a cooling part space 16a of the cooling unit 16 described later, but the other end of the heating element accommodation space 14a is closed.

  In the present embodiment, in the heating unit 14, two heating elements 12 are arranged in the heating element accommodation space 14 a, and an opposing member 15 is arranged between the adjacent heating elements 12. The facing member 15 is a member different from the heating element 12, and the facing member surface 151 faces the heating element surface 121. Therefore, the facing member surface 151 forms a facing surface that faces the heating element surface 121. The heating element surface 121 is the surface of the heating element 12 that is in contact with the liquid refrigerant, and is a surface that mainly exchanges heat with the liquid refrigerant.

  The facing member 15 is held by a portion (not shown) of the heating element housing wall 141. The facing member 15 is made of a conductive material, for example, a metal material.

  As shown in FIG. 3B described later, the heating element 12 and the opposing member 15 are arranged so that the liquid refrigerant is bridged between the heating element surface 121 and the opposing member surface 151 by the action of surface tension. ing. Specifically, the heating element 12 and the opposing member 15 are arranged so that the distance L1 between the heating element surface 121 and the opposing member surface 151 is shorter than the Laplace length l expressed by the following mathematical formula. ing.

σ：冷媒流体の表面張力
ｇ：重力加速度
ρ_ｌ：冷媒流体の飽和液密度
ρ_ｖ：冷媒流体の飽和蒸気密度
ここで、一般的に、ラプラス長さｌは、図２に示すように、管内部の液体と気泡プラグにおいて、浮力と表面張力のつりあいで、気泡プラグが管内部に保持される限界管径のことである。気泡プラグが管内部に保持される状態のとき、表面張力の作用によって管内部の液体が管内壁にブリッジされた状態となる。したがって、このラプラス長さｌを目安として、発熱体表面１２１と対向部材表面１５１との間の距離Ｌ１を設定すればよい。

σ: Surface tension of refrigerant fluid g: Gravitational acceleration ρ _l : Saturated liquid density of refrigerant fluid ρ _v : Saturated vapor density of refrigerant fluid Here, in general, Laplace length l is a tube as shown in FIG. In the internal liquid and the bubble plug, this is the limit tube diameter that allows the bubble plug to be held inside the tube due to a balance between buoyancy and surface tension. When the bubble plug is held inside the tube, the liquid inside the tube is bridged to the inner wall of the tube by the action of surface tension. Therefore, the distance L1 between the heating element surface 121 and the opposing member surface 151 may be set using the Laplace length l as a guide.

  Moreover, in this embodiment, the heating part 14 has the opposing surface 142 which opposes the heat generating body surface 121 among the heat generating body accommodation walls 141. FIG. And the heat generating body 12 is arrange | positioned so that the distance L2 between the heat generating body surface 121 and the opposing surface 142 may become the same as the above-mentioned distance L1.

  The cooling unit 16 forms a cooling unit space 16a communicating with the heating element housing space 14a, and cools and liquefies the gaseous refrigerant vaporized by the heating unit 14 and flowing into the cooling unit space 16a. Specifically, the cooling unit 16 includes a cooling unit wall 161 and a cooling device 162. The cooling unit 16 is arranged side by side in the horizontal direction with respect to the heating unit 14.

  The cooling part wall 161 has a tubular shape, and a cooling part space 16a is formed inside thereof. The cooling device 162 includes a large number of cooling fins 162 a provided around the cooling unit wall 161. The cooling device 162 cools the refrigerant in the cooling space 16a by exchanging heat with the outside air. That is, when the cooling unit 16 cools the refrigerant, the cooling unit 16 radiates heat from the refrigerant to the outside of the cooling unit 16, that is, to the external space 16 b around the cooling unit 16.

  The cooling wall 161 is made of, for example, a thin metal, preferably a thin aluminum alloy so that high heat dissipation performance can be obtained. Moreover, the cooling unit wall 161, the cooling device 162, and the heating element housing wall 141 are integrated to form one refrigerant container made of a metal such as an aluminum alloy and containing a refrigerant.

  The cooling section space 16a is a space formed in a tubular shape, and is constituted by a pipe line having a very small pipe cross-sectional area perpendicular to the longitudinal direction thereof. Therefore, when the refrigerant gas-liquid interface 26 exists in the cooling unit space 16a, the gas-liquid interface 26 faces the longitudinal direction of the cooling unit space 16a by the surface tension of the refrigerant regardless of the gravity direction. Maintained. That is, in the longitudinal direction of the cooling unit space 16a, the gas refrigerant exists on the heating unit 14 side with the gas-liquid interface 26 as a boundary, and the liquid refrigerant exists on the opposite side.

  For example, the gas-liquid interface 26 moves away from the heating element housing space 14a in the cooling unit space 16a, that is, the left of FIG. Move in the direction. Then, the cooling unit 16 also cools the liquid refrigerant, but also cools and condenses the gas refrigerant vaporized by the heating unit.

  The drive assisting device 18 includes an extendable portion 28 that expands and contracts in a uniaxial direction or a substantially uniaxial direction, and a weight 30. The expansion / contraction part 28 absorbs the volume change of the refrigerant | coolant which arises in the heat generating body accommodation space 14a and the cooling part space 16a by the heating and cooling of a refrigerant | coolant. That is, the expansion / contraction part 28 functions as an absorption part that absorbs the volume change of the refrigerant. And the expansion-contraction part 28 forms the expansion-contraction part space 28a as an absorption part space connected with the cooling part space 16a inside the expansion-contraction part 28. As shown in FIG.

  The expansion / contraction part 28 is comprised by the bellows etc., for example, and expands-contracts to the up-down direction DR1 in this embodiment. Since the drive assist device 18 is a part that performs a mechanical operation, it may be called a drive unit in the cooler 10. When the expansion / contraction part 28 expands / contracts vertically, the expansion / contraction part space 28a also expands / contracts vertically. The expansion / contraction space 28a is filled with a liquid refrigerant.

  Moreover, the lower end of the expansion-contraction part 28 is being fixed with respect to the cooling part wall 161, and the lower end of the expansion-contraction part space 28a is connected to the cooling part space 16a. On the other hand, a weight 30 is fixed to the upper end of the stretchable portion 28, and the upper end of the stretchable portion space 28a is closed. Therefore, the expansion / contraction portion space 28a, the above-described heating element accommodating space 14a, and the cooling portion space 16a constitute an airtight refrigerant enclosure space 32 as one space in which refrigerant is enclosed. When the refrigerant in the cooling unit space 16a flows into the expansion / contraction part space 28a, the expansion / contraction part space 28a extends and the upper end of the expansion / contraction part 28 and the weight 30 rise. On the contrary, when the expansion / contraction part space 28a contracts and the upper end of the expansion / contraction part 28 and the weight 30 descend, the refrigerant in the expansion / contraction part space 28a flows out into the cooling part space 16a. That is, the refrigerant functions as a working fluid that causes the expansion / contraction part 28 to expand and contract.

  The weight 30 is provided in order to increase the inertia when the expansion / contraction part 28 expands / contracts vertically. The weight 30 should just be a high-density member, for example, is comprised with iron.

  In the cooler 10 configured as described above, when the liquid refrigerant in the heating element housing space 14a is heated and boiled by the heating element 12, the gas portion of the refrigerant increases, and the volume of the whole refrigerant increases with the expansion and contraction part 28. The top of the ascends. When the gas part of the refrigerant increases to some extent, for example, when the gas-liquid interface 26 enters the cooling part space 16a as shown in FIG. 1, the cooling part 16 cools and condenses the gas part of the refrigerant.

  When the gas portion is reduced by condensing the gas portion of the refrigerant, the entire volume of the refrigerant is reduced at the same time, and the upper end of the expansion / contraction portion 28 is lowered. Then, part or all of the heating element 12 is immersed in the liquid refrigerant. When the heating element 12 is immersed in the liquid refrigerant, the liquid refrigerant in the heating element housing space 14a again boils and evaporates as described above.

  Thus, in the cooler 10, the heating unit 14 and the cooling unit 16 cause the gas-liquid interface 26 of the refrigerant to self-oscillate in the refrigerant enclosure space 32 by causing the refrigerant to repeat evaporation and condensation. In short, the self-excited vibration of the refrigerant is performed in the refrigerant enclosure space 32. And the expansion-contraction part 28 absorbs the volume change of the whole refrigerant | coolant accompanying the self-excited vibration of the refrigerant | coolant. Furthermore, since the expansion / contraction part 28 has a predetermined spring constant, a reaction force corresponding to the expansion / contraction amount is generated toward the balance point in the expansion / contraction direction of the expansion / contraction part 28 to assist self-excited vibration of the refrigerant. Fulfill.

  The refrigerant repeatedly evaporates and condenses with the self-excited vibration of the gas-liquid interface 26, that is, the self-excited vibration of the refrigerant, thereby cooling the heat of the heating element 12 through the refrigerant, the cooling wall 161 and the cooling device 162. The air can be discharged from the portion 16 to the outside air.

  Here, the comparative example 1 shown in FIG. 4 is demonstrated. In the cooler J10 of Comparative Example 1, the facing member 15 is omitted from the cooler 10 of the first embodiment, and the distance L3 between the adjacent heat generating bodies 12 is the same as that of the heat generating body surface 121 of the first embodiment. The distance L1 is greater than the distance L1 between the opposing member surface 151. Other configurations are the same as those of the first embodiment.

  In the cooler J10 of the comparative example 1, the liquid refrigerant in the heating element housing space 14a of the heating unit 14 is vaporized by the heat from the heating element 12, and the gas-liquid interface 26 is changed from 26a → 26b → as shown in FIG. It is displaced in the order of 26c. As described above, when the gas-liquid interface 26 is displaced from the heating element housing space 14a to the cooling unit space 16a, a film (liquid film 40) of the liquid refrigerant 40 is formed on the heating element surface 121 at the initial stage of the expansion stroke shown in FIG. ) Is formed. Thereafter, the liquid film 40 is boiled by heat from the heating element 12, and steam is generated. At this time, as shown in FIG. 5B, when the liquid refrigerant 40 remaining on the heating element surface 121 is scattered by the generated steam (bubbles), the liquid refrigerant exists on the heating element surface 121. A dry area is generated. When the dry region occurs, the heat transfer area of the heating element surface 121 decreases, and the amount of heat exchange between the heating element surface 121 and the liquid refrigerant decreases. Once the dry region is generated, the liquid refrigerant is not supplied to the heating element surface 121 until the gas-liquid interface 26 is displaced from the cooling unit space 16a to the heating element accommodating space 14a, and the heat exchange amount is reduced. Will continue.

  Thus, in the cooler J10 of Comparative Example 1, when the gas-liquid interface 26 is displaced from the heating element housing space 14a to the cooling part space 16a, the liquid refrigerant 40 is scattered from the heating element surface 121, and the heating element surface Since the liquid supply state to 121 cannot be maintained, the cooling capacity of the cooler is lower than the cooling capacity that can be originally exhibited. That is, since the liquid refrigerant 40 scatters from the heat generating body surface 121 without exchanging heat with the heat generating element 12, the cooling capacity of the cooler is lower than the cooling capacity that can be originally exhibited.

  In contrast, in the cooler 10 of the present embodiment, when the gas-liquid interface 26 is displaced from the heating element housing space 14a to the cooling part space 16a, the liquid refrigerant 40 faces the heating element surface 121 due to the action of surface tension. The heating element 12 and the opposing member 15 are arranged so as to be bridged between the member surface 151.

  For this reason, in the initial stage of the expansion stroke shown in FIG. 3A, a film (liquid film 40) of the liquid refrigerant 40 is formed on both the heating element surface 121 and the opposing member surface 151. Thereafter, when the liquid film 40 is boiled by the heat from the heating element 12 to generate steam, the liquid film 40 is generated from the heating element surface 121 by the generated bubbles as shown in FIG. The liquid refrigerant 40 is bridged between the heating element surface 121 and the opposing member surface 151 by being pushed out to the side. At this time, the liquid refrigerant 40 and the gas refrigerant 41 are mixed between the heating element surface 121 and the counter member surface 151, and the liquid refrigerant 40 is vaporized over time.

  Thereby, scattering of the liquid refrigerant 40 from the heating element surface 121 due to vapor generation can be prevented, and the liquid refrigerant 40 can be continuously held on the heating element surface 121. That is, the state where the heating element surface 121 is wet with the liquid refrigerant 40 can be maintained. Thus, even when the gas-liquid interface 26 is displaced from the heating element housing space 14a to the cooling part space 16a, the liquid supply state to the heating element surface 121 can be maintained for a long time, thereby preventing the cooling capacity of the cooler from being lowered. it can.

  In the present embodiment, as shown in FIG. 1, the distance L2 between the heating element surface 121 and the facing surface 142 of the heating element receiving wall 141 is the distance between the heating element surface 121 and the facing member surface 151. Since it is the same as L1, the same can be said between the heating element surface 121 and the facing surface 142 of the heating element housing wall 141.

(Second Embodiment)
In the present embodiment, the material of the facing member is changed with respect to the first embodiment, and other configurations are the same as those in the first embodiment.

  As shown in FIG. 6, in this embodiment, the opposing member 15 is comprised with the resin material which is an insulating material. For this reason, the opposing member 15 has insulation. Ceramics may be used as the insulating material.

  By the way, when the heating element 12 is an electrical component and the opposing member 15 has conductivity, when the distance between the heating element 12 and the opposing member 15 and the distance between the heating elements 12 are equal to or less than a certain distance, Dielectric breakdown will occur. For this reason, the distance L1 between the heating element 12 and the opposing member 15 and the distance L3 between the heating elements 12 cannot be made equal to or less than a certain distance.

  On the other hand, in this embodiment, since the whole opposing member 15 has insulation, compared with the case where the opposing member 15 has electroconductivity, it is between the heat generating body 12 and the opposing member 15. The distance L1 and the distance L3 between the heating elements 12 can be shortened.

  In the present embodiment, the entire facing member 15 is made of an insulating material, but the surface layer portion of the facing member 15 may be made of an insulating material, and the inside may be made of a conductive material. Also in this case, since the opposing member surface 151 has insulating properties, the same effects as those of the present embodiment can be obtained.

(Third embodiment)
As shown in FIG. 7, in the present embodiment, the heating element surface 121 is covered with a thin film 13 made of a resin material that is an insulating material. For this reason, the heat generating body surface 121 has insulation. The thin film 13 has a thickness that does not affect the cooling of the heating element 12. Other configurations are the same as those in the first embodiment.

  According to the present embodiment, even if the facing member 15 is made of a conductive material, since the heating element surface 121 has insulation, the facing member 15 has conductivity, and the heating element surface 121 Compared with the case where the thin film 13 is not provided, the distance L1 between the heating element 12 and the opposing member 15 and the distance L3 between the heating elements 12 can be shortened.

(Fourth embodiment)
In the present embodiment, the material of the facing member is changed with respect to the first embodiment, and other configurations are the same as those in the first embodiment.

As shown in FIGS. 8 and 9, in the present embodiment, the opposing member 15 is configured such that the contact angle θ <b> 1 of the liquid refrigerant 40 on the opposing member surface 151 is larger than the contact angle θ <b> 2 of the liquid refrigerant 40 on the heating element surface 121. Is configured. The contact angle is the angle formed by the free surface of the liquid and the solid surface with which it contacts. For example, when water is used as the coolant, the counter member 15 is entirely made of a hydrophobic material. Examples of the hydrophobic material include polytetrafluoroethylene (PTFE). A hydrophobic layer made of a hydrophobic material may be formed on the opposing member surface 151. In short, it is sufficient that the opposing member surface 151 has hydrophobicity.

  In the present embodiment, since the contact angle θ1 of the liquid refrigerant 40 on the opposing member surface 151 is larger than the contact angle θ2 of the liquid refrigerant 40 on the heating element surface 121, it is equivalent to the contact angle θ2 of the liquid refrigerant 40 on the heating element surface 121. Compared to the following case, more liquid refrigerant 40 is supplied to the heating element 12 side. In other words, the time during which the heating element surface 121 is wet can be extended. For this reason, according to this embodiment, the amount of heat exchange between the heating element 12 and the liquid refrigerant 40 can be further increased, and a decrease in the cooling capacity of the cooler can be further prevented.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be appropriately modified within the scope described in the claims as follows.

  (1) In each embodiment described above, the heating element 12 and the opposing member 15 are arranged so that the liquid refrigerant 40 is bridged between the heating element surface 121 and the opposing member surface 151 by the action of surface tension. Two adjacent heating elements 12 may be so arranged. That is, the two heating elements are formed such that the liquid refrigerant 40 is bridged between the heating element surface 121 of one heating element 12 and the heating element surface 121 of the other heating element 12 opposite to the heating element surface 121 by the action of surface tension. 12 may be arranged. In this case, the heating element surface 121 of the other heating element 12 constitutes a facing surface facing the one heating element surface 121. In this case, in order to prevent dielectric breakdown, it is preferable to provide the thin film 13 made of an insulating material on the heating element surface 121 as in the third embodiment.

  (2) In each embodiment described above, two heating elements 12 are arranged in the heating element accommodation space 14a of the heating unit 14, but the number of heating elements 12 arranged in the heating element accommodation space 14a is three. Multiple or one may be used. In the case of one heating element 12, heat generation is performed so that the liquid refrigerant is bridged between the heating element surface 121 and the facing surface 142 of the heating element housing wall 141 facing the heating element surface 121 by the action of surface tension. A distance L2 between the body surface 121 and the facing surface 142 is set.

  (3) In each of the embodiments described above, the heating element housing space 14a and the cooling unit space 16a are provided such that the longitudinal direction thereof is the horizontal direction. For example, the refrigerant sealing space 32 is described in Patent Document 1. It may be U-shaped like a fluid container.

  (4) In each of the embodiments described above, the cooler 10 is installed so that the longitudinal direction of the cooling unit space 16a faces the horizontal direction, but the direction of the gas-liquid interface 26 in the cooling unit space 16a is the refrigerant. Since it is maintained by surface tension, there is no limitation on the installation direction of the cooler 10.

  (5) In each of the above-described embodiments, when the heat generation from the heating element 12 stops, the entire heating element 12 is immersed in the liquid refrigerant, but a part of the heating element 12 may be immersed in the liquid refrigerant.

  (6) In each of the above-described embodiments, the cooling unit 16 cools the refrigerant in the cooling unit space 16a by exchanging heat with the outside air. The cooling water may be cooled by exchanging heat with the cooling water.

  (7) In each of the above-described embodiments, the drive assist device 18 includes the weight 30, but the weight 30 may be omitted. Alternatively, the weight 30 may be replaced with another component or device that applies an inertial force so as to promote vibration of the refrigerant.

  (8) In each of the embodiments described above, the expansion / contraction part 28 is configured by a bellows or the like and vertically expands / contracts. There is no problem.

  (9) In each of the embodiments described above, the heating element 12 is a semiconductor element or the like that needs to be cooled, but need not be an electrical component.

  (10) The above-described embodiments are not irrelevant to each other, and can be appropriately combined unless the combination is clearly impossible. In each of the above-described embodiments, it is needless to say that elements constituting the embodiment are not necessarily essential unless explicitly stated as essential and clearly considered essential in principle. Yes. Further, in each of the above embodiments, when numerical values such as the number, numerical value, quantity, range, etc. of the constituent elements of the embodiment are mentioned, it is clearly limited to a specific number when clearly indicated as essential and in principle. The number is not limited to the specific number except for the case. In each of the above embodiments, when referring to the material, shape, positional relationship, etc. of the constituent elements, etc., unless otherwise specified, or in principle limited to a specific material, shape, positional relationship, etc. The material, shape, positional relationship, etc. are not limited.

DESCRIPTION OF SYMBOLS 10 Cooling device 12 Heating body 121 Heating body surface 14 Heating part 14a Heating body accommodation space 15 Opposing member 151 Opposing member surface (opposing surface)
16 Cooling part 16a Cooling part space 28 Expansion / contraction part (absorption part)
28a Expansion / contraction space (absorption space)
32 Refrigerant enclosure space (one space)

Claims (5)

A heating part (14a) in which the heating element (12) is accommodated is formed, and a heating part (heater) that heats and vaporizes the refrigerant fluid contained in the heating element accommodation space by heat from the heating element 14)
A cooling part space (16a) communicating with the heating element housing space is formed, and a cooling part (16) for cooling and liquefying the refrigerant fluid that has been vaporized by the heating part and has flowed into the cooling part space. When,
An absorption part space (28a) communicating with the cooling part space, and an absorption part (28) for absorbing a volume change due to heating and cooling of the refrigerant fluid,
The heating element accommodation space, the cooling part space, and the absorption part space as a whole constitute one space (32) in which the refrigerant fluid is enclosed,
The heating unit and the cooling unit are configured to cause the refrigerant fluid to self-oscillate in the one space by causing the refrigerant fluid to repeat vaporization and liquefaction,
The heating unit has a facing surface (151, 142, 121) facing the heating element surface (121), and the liquid refrigerant fluid flows between the heating element surface and the facing surface by the action of surface tension. The cooler, wherein the heating element and the facing surface are arranged so as to be bridged. In the heating unit, a plurality of the heating elements are arranged in the heating element accommodation space, and an opposing member (15) is arranged between the adjacent heating elements,
The cooler according to claim 1, wherein the facing member surface (151) constitutes the facing surface.   The cooler according to claim 1 or 2, wherein at least one of the surface of the heating element and the facing surface has an insulating property.   4. The cooler according to claim 1, wherein the facing surface has a larger contact angle of the liquid refrigerant fluid than the surface of the heating element. 5. The distance (L1, L2) between the heating element surface and the facing surface is shorter than a Laplace length represented by the following mathematical formula, according to any one of claims 1 to 4. Cooler.

In the equation, l represents the Laplace length, σ represents the surface tension of the refrigerant fluid, g represents the gravitational acceleration, ρ _l represents the saturated liquid density of the refrigerant fluid, and ρ _v represents the saturation of the refrigerant fluid. Indicates the vapor density.

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