WO2018127548A1 - Heat diffusion device - Google Patents

Abstract

The invention relates to a device for heat diffusion by the heat pipe effect, comprising a heat transfer fluid (1) and a housing (2), the housing (2) having a lower wall (21) forming a bottom, an upper wall (22) opposite the lower wall (21) and four side walls between the lower (21) and upper (22) walls, the side walls consisting of: - two transverse side walls, - two longitudinal side walls, a first longitudinal side wall being intended to receive a heat source, characterised in that: - the distance between the longitudinal side walls is between ½ and 2 times the capillary length of the heat transfer fluid (1), and - the quantity (Q_f) of heat transfer fluid (1) contained in the device is between 25 and 80% of the total volume (V_tot) of the housing (2).

Description

 THERMAL DIFFUSION DEVICE

FIELD OF THE INVENTION The present invention relates to the general technical field of heat exchangers, in particular for the purpose of removing heat from an element to be cooled, such as an electronic component.

More specifically, the present invention relates to the technical field of two-phase thermal diffusers heat pipe type. Such thermal diffusers can be used for many applications such as applications in aeronautics, railways, aerospace, power electronics, etc.

PRESENTATION OF THE PRIOR ART

The components of the electronic boards dissipate a significant amount of heat, causing a significant increase in their temperature and associated electronic circuits. However, an excessive increase in the temperature of these electronic components can lead to a decrease in their reliability and / or reduce their service life. This is why it is necessary to effectively evacuate the heat dissipated by the electronic components. Heat exchangers are systems that collect heat from one environment and redistribute it to another. There are different categories of heat exchangers for transporting heat from a hot source (electronic component, for example) to a cold source (water condenser, for example). When the surface of the cold source is significantly larger than the surface of the hot source, the heat transfer includes a heat diffusion component, and the heat exchanger is called a "heat diffuser". We know in particular:

 the flat solid diffuser, which generally consists of a block of material with a high thermal conductivity such as a metal; such a diffuser operates by simple conduction of heat in the block of material,

 - The capillary heat pipe which generally consists of a housing containing a liquid and a capillary structure in thermal contact with the inner walls of the housing, the liquid being located mainly in the capillary structure and flowing from the cold source to the hot source, the steam produced at the hot source occupying the entire vapor space and condensing at the cold source,

 - The diphasic thermosiphon which consists of a housing including a two-phase fluid flowing under the effect of gravity forces, the gravity being the engine of the return of the condensed liquid in the evaporation zone. Each type of existing heat diffuser has advantages and disadvantages. This is why the choice of a type of thermal diffuser depends on the intended application, and more specifically the constraints associated with this application.

In some applications, such as applications for the cooling of power electronics in the aeronautical field, it is necessary that the heat exchanger meets the following constraints:

good efficiency at high flux density (ie flow density greater than a few W / cm ² ), that is to say low thermal resistance,

 - low constraints on the positioning of hot springs,

 - low sensitivity to inclination (limited thermal performance degradation for inclination changes of ± 40 °),

 - good homogenization of temperatures,

 - low complication in case of frost,

 - low weight,

 - simplicity and low cost.

However, none of the aforementioned thermal diffusers can meet all of these constraints. Indeed :

 the flat solid diffuser is heavy and inefficient with high flux density,

the capillary heat pipe is complex, expensive, and sensitive to freezing (the capillary structure may degrade when the liquid it contains solidifies), and its thermal performance degrades at high flux densities,

 - The diphasic thermosiphon - by the use of gravity forces for the circulation of the fluid - is sensitive to inclinations and very strongly constrained vis-à-vis the positioning of hot and cold sources. WO 201 1/149216 describes an oscillating heat pipe composed of several loops interconnected to each other. The loops are of capillary dimensions. They are filled with a heat transfer fluid in the form of a succession of vapor bubbles and liquid plugs. When the oscillating heat pipe is heated at one end and cooled at the other, the resulting temperature differences generate both temporal and spatial pressure fluctuations, which are themselves associated with the generation and growth of vapor bubbles in the water. evaporator and their implosion in the condenser. These fluctuations act as a pumping system to transport the trapped liquid and vapor bubbles through a complex fluid motion. A disadvantage of the device described in WO 201 1/149216 is that its operating mode is difficult to reproduce because of complex fluid movements, particularly when low flux densities are applied to the system (non-start of the system). Furthermore, in such an oscillating heat pipe, the positioning of the hot springs is strongly constrained to ensure its proper operation.

JP H10 185468, US 6,679,316 and US 5,642,776 disclose other examples of oscillating heat pipes having the same disadvantages.

An object of the present invention is to provide a thermal diffuser to meet the aforementioned constraints, and more specifically a thermal diffuser:

having a good efficiency at high flux density (ie flux density greater than a few W / cm ² ),

in which the hot springs can be positioned in different zones, - not very sensitive to inclination,

 - not at risk of degradation in case of frost,

 - having a low weight,

 - simple and inexpensive.

SUMMARY OF THE INVENTION

For this purpose, the invention proposes a thermal diffusion device with heat pipe effect comprising a coolant and a housing, the housing having a bottom wall forming a bottom, an upper wall opposite the bottom wall and four side walls between the lower walls and upper side walls consisting of:

 - two transverse lateral walls,

 two longitudinal lateral walls, a first longitudinal lateral wall being intended to receive a hot source,

the walls of the housing (2) being interconnected so as to constitute a sealed reservoir for the coolant,

remarkable in that:

 the distance between the longitudinal side walls is between ½ and 2 times the capillary length of the coolant,

 the distance between the transverse lateral walls is greater than 10 times the capillary length of the coolant,

 - The amount of heat transfer fluid contained in the device is between 25 and 80% of the total volume of the housing.

The fact that :

 the distance between the longitudinal side walls is between ½ and 2 times the capillary length of the coolant, and

 the distance between the lateral transverse walls is greater than 10 times the capillary length of the coolant

allows to constrain the heat transfer fluid in a single dimension to take advantage of a boiling phenomenon confined to a dimension that will be described in more detail below. Even if a confined boiling phenomenon can occur in an oscillatory heat pipe, two-phase flows and heat transfer are very different. Indeed, the loops composed of a serpentine tube having a capillary dimension, the confinement of the fluid takes place in two dimensions.

In the context of the present invention, the fact of constraining the fluid to a single dimension (ie distance between the longitudinal side walls) makes it possible to establish a flow of the two-dimensional two-phase fluid in the enclosure, which forms two convection cells. around the hot source (s) (upward movement of the bubbles above the hot source and return of the descending fluid around the hot source, and in particular along the two transverse lateral walls).

Preferred but non-limiting aspects of the device according to the invention are the following:

 the device may be devoid of capillary structure;

 the first longitudinal side wall comprises an evaporation zone intended to receive at least one hot source, the area of the evaporation zone being less than 40% of the total area of the first longitudinal lateral wall;

 the evaporation zone intended to receive the hot source can be positioned on the first wall at a non-zero distance from the side walls to allow a two-dimensional circulation of the coolant around the hot source,

 the position of the evaporation zone on the first longitudinal lateral wall may be such that:

 The distance between the evaporation zone and each transverse lateral wall is greater than or equal to one fifth of the length of the first longitudinal lateral wall,

 · The distance between the evaporation zone and the upper wall is greater than or equal to one third of the height of the first longitudinal side wall, and

• the distance between the evaporation zone and the bottom wall is zero; the outer face of the first longitudinal lateral wall may comprise a positioning mark for defining the position of the evaporation zone;

- The device may comprise spacers between the inner faces of the longitudinal side walls of the housing, each spacer being intended to cooperate with respective fastening means;

 the internal faces of the longitudinal lateral walls may comprise surface texturing;

 - The surface texturing may consist of splines formed on the inner faces of the longitudinal side walls, the grooves extending between the lower and upper walls of the housing;

 the heat transfer fluid may be water.

BRIEF DESCRIPTION OF THE FIGURES Other advantages and characteristics of the thermal diffusion device will emerge more clearly from the following description of several variant embodiments, given by way of non-limiting examples, from the appended drawings in which:

 FIGS. 1 and 2 illustrate an embodiment of a thermal diffuser according to the invention,

 - Figures 3 and 5 are side views illustrating the principle of operation of the thermal diffuser

 - Figures 4 and 6 are front views illustrating the principle of operation of the thermal diffuser. DETAILED DESCRIPTION

The device according to the invention will now be described in more detail with reference to the figures. In these different figures, the equivalent elements are designated by the same reference numeral.

Referring to Figure 1, there is illustrated an embodiment of a thermal diffusion device. The device comprises a heat transfer fluid 1 and a housing 2 for containing the coolant 1.

1. Thermal diffusion device

1.1. Coolant

The heat transfer fluid 1 makes it possible to transport the heat produced by the element to be cooled (not shown). The heat transfer fluid 1 is contained in the housing 2, the internal volume of which constitutes a sealed enclosure for the coolant. The vacuum is carried out in the housing 2 prior to the introduction of the coolant 1. The heat transfer fluid is then in a liquid-vapor equilibrium state in the absence of heat transfer.

The amount of heat transfer fluid 1 contained in the housing 2 may be between 25% and 80% of the total volume of the housing 2. It depends on the intended application and the compromise adopted between the thermal performance of the system and the other constraints to be taken such as the desired inclination or degree of freedom on the placement of the hot springs. For example for certain applications, the amount of fluid can be between 30% and 70%, or between 40% and 60%, or between 45% and 55%, or even substantially equal to 50% of the total volume of the housing. As will become more clearly apparent in the rest of the text, the combination of this characteristic with specificities relating to the dimensioning of the housing 2 enables the thermal diffusion device to respond to the aforementioned constraints concerning the efficiency of the device with a high flux density, its sensitivity to the inclination, its simplicity, etc.

The material constituting the coolant 1 may vary depending on the desired operating temperature level. The heat transfer fluid 1 can be, for example, an oil, an alcohol (such as methanol, ethanol or glycol), a compound organic (such as acetone, ammonia), a mixture, a nanofluid, a liquid metal, or any type of coolant known to those skilled in the art.

In one embodiment, the coolant 1 is deionized water. The use of water as heat transfer fluid 1 has many advantages, and in particular:

 - a very low cost and

 - zero toxicity and

 - non-flammability and

 - excellent thermal performance.

1.2. Housing

The housing 2 comprises walls consisting for example of sheets of thermally conductive material such as metal (for example copper or aluminum). The choice of material used to make the walls of the housing 2 depends in particular on the constraints of manufacture and use, as well as the type of heat transfer fluid chosen, the fluid / material pair of the housing to be chemically compatible.

Accommodation 2 comprises:

 a bottom wall 21 forming a bottom,

 an upper wall 22 opposite to the lower wall 21,

 two transverse lateral walls 23, 24, and

 - two longitudinal side walls 25, 26.

The walls 21-26 of the housing 2 are connected to each other so as to constitute a sealed reservoir containing the coolant 1. Thus, the heat transfer fluid is naturally distributed in the volume constituted by the walls of the housing. This limits the risk of local overheating when using the device, unlike existing heat pipes comprising a serpentine tube (or channels) for containing the heat transfer fluid. In the remainder of the text, the terms "side wall", "top wall" and "bottom wall" will be used with reference to a rectangular parallelepiped.

The reader will appreciate that in the context of the present invention, the following is meant:

 · 'Lower wall' means a horizontal wall of a rectangular parallelepiped nearest the ground,

 • "upper wall" means a horizontal wall of a rectangular parallelepiped opposite to the lower wall,

 • "face / side wall" means a face / vertical wall of a rectangular parallelepiped extending in a plane perpendicular to the bottom wall,

• "faces / longitudinal walls" means the vertical faces / walls of a rectangular parallelepiped of which at least one dimension is greater than the dimensions of the other faces / side walls,

 • "faces / transverse walls" means vertical faces / walls extending perpendicular to the longitudinal faces / walls.

Advantageously, the housing 2 is devoid of capillary structure. This reduces the risk of degradation of the thermal diffusion device in case of freezing of the heat transfer fluid 1, for example during a prolonged deactivation of the device in a cold environment. The absence of a capillary structure also makes it possible to improve the thermal performance and to reduce the cost and the manufacturing constraints compared with the usual heat pipe.

12.1 Longitudinal side walls

The longitudinal side walls 25, 26 constitute the walls of larger dimensions of the thermal diffusion device. More specifically, the area of a longitudinal side wall is greater than the area of each of the other walls of the housing 2.

Accommodation 2 comprises:

A first longitudinal lateral wall 25, A second longitudinal lateral wall extending parallel to the first longitudinal lateral wall.

In the embodiment illustrated in Figures 1 to 3, the outer face of the first longitudinal side wall 25 is intended to be in thermal contact with one (or more) source (s) hot (s). The outer face of the second longitudinal side wall 26 is in turn intended to be in thermal contact with one (or more) source (s) cold (s). Alternatively, the hot and cold sources may be disposed on the same longitudinal sidewall, as long as certain rules, described below, are respected.

The distance "e" between the longitudinal side walls (25, 26) is advantageously between ½ and 2 times the capillary length of the coolant (1). "Capillary length" is a length scale characteristic of an interface (between two fluids) subjected to capillary forces and gravitational forces: for example, when gravitational effects dominate, a bubble or a drop is flattened by the gravity and its radius is large in front of the capillary length. This characteristic length is an intrinsic property and therefore depends on the coolant chosen for the thermal diffusion device as well as the operating temperature; in the case of water at 20 ° C, the capillary length is 2.7 millimeters.

The fact that the distance e between the longitudinal side walls 25, 26 is between ½ and 2 times the capillary length of the coolant 1 makes it possible to take advantage of the confined boiling phenomena. The main difference between a boil in a confined environment and in an unconfined environment is that for low thermal flows, the wall overheating is less important in a confined environment than in an unconfined environment. This reflects the fact that a better heat transfer coefficient is obtained. The more the space is confined, the greater the exchange coefficient becomes greater than that reached during boiling in an unconfined environment.

Those skilled in the art generally consider that the confinement of boiling is not suitable in the context of large heat fluxes. Indeed, he considers that case of large thermal flux in a confined environment, the rate of vapor produced becomes large and given the small characteristic dimensions of the system, this leads to a degradation of the thermal performance, in particular related to the pressure problems and up to a stoppage of operation of the system. diffuser.

The inventors have discovered that the combination:

 A quantity (Qf) of heat transfer fluid comprised between 25% and 80% of the total volume (Vtot) of the housing, and

· A distance e between ½ and 2 times the capillary length (L _c ) of the heat transfer fluid

provides an effective thermal diffusion device, even when the heat flow is important and increase the available surface for the placement of hot springs.

The distance L between the transverse lateral walls is in turn chosen to be much greater than the capillary length of the coolant (in particular 10, 100, 1000 times greater). This makes it possible not to confine the coolant between the transverse lateral walls. Thus, in the context of the present invention, the confinement of the coolant is made in one dimension, unlike the heat pipes of the oscillating type in which the heat transfer fluid is confined in two dimensions.

The combination of these characteristics (½xL _c <e _<c 2xL, L> 10XL _c and ³ / ioxVt ₀ t <Qf ^<7 / ioxVtot) allows:

 • improve the thermal performance of the device,

 • to limit the constraints on the positioning of the hot springs, and

• to reduce the sensitivity to the inclination of the thermal diffusion device.

1.2.1.1. Spacers and Means of attachment In one embodiment, the device comprises spacers 36 between the first and second longitudinal side walls 25, 26. These spacers 36 are fixed in different positions of the respective surfaces of the first and second longitudinal side walls 25, 26.

The spacers 36 may be attached to the first and second longitudinal side walls 25, 26 by welding, brazing or gluing.

The presence of spacers 36 stiffens the housing 2 so as to maintain constant the distance between the first and second longitudinal side walls 25, 26.

Advantageously, the device may also comprise fastening means 35 - such as bolts or screws - to allow the attachment of one (or more) system (s) outside (s) on the diffuser, such as fins or a electronic card.

One (or more) spacer (s) 36 may (advantageously) be arranged (s) so as to cooperate with a respective fastening means. For example in the embodiment illustrated in Figures 1 to 3, blind holes are formed in the spacers 36 through the first longitudinal side wall to form threaded barrels - four in number.

Each was intended to receive the thread of a respective fastening means to allow the attachment of a hot or cold source.

Advantageously, the spacers and fastening means 35, 36 of the first and second longitudinal side walls 25, 26 constitute thermal bridges which make it possible to heat up the coolant 1 more quickly, for example in the event of the latter being freezing (when the device thermal diffusion is deactivated and that the outside temperature is lower than the solidification temperature of the coolant). Thus, the presence of fixing means and spacers 35, 36 between the longitudinal side walls 25, 26 reduces the priming time of the device.

By "priming duration" is meant the time interval between the moment when the heat dissipated by the element to be cooled is applied to the thermal diffusion device, and the moment when the coolant 1 reaches a regime steady flow.

By reducing the duration of priming of the device through the fixing means and spacers, it limits the risk of damage to the element to be cooled, the priming time being short enough to ensure effective cooling of the element to be cooled.

1.2.1.2. Texturing In one embodiment, one of the two inner faces or the two inner faces of the longitudinal side walls 25, 26 are textured. In the case where the inner face of a single longitudinal side wall is textured, it will advantageously be the inner face of the first longitudinal side wall 25 intended to be in thermal contact with one (or more) hot source (s) (s).

This makes it possible to increase the exchange surface between the coolant and the hot (or cold) source (s). In particular, the texturing:

 The internal face of the second longitudinal sidewall 26 makes it possible to promote the condensation phenomenon of the coolant 1, the inner face of the first longitudinal lateral wall makes it possible to promote the phenomenon of evaporation of the coolant 1 by promoting nucleation effects.

In the embodiment illustrated in FIGS. 1 to 3, the surface texturing of the internal faces of the longitudinal lateral walls 25, 26 consists of a vertical grooving made on said inner faces, said grooves extending between the lower and upper walls 21, 22 of the device. 1.2.1.3. Hot source positioning area

As indicated above, the outer face of the first longitudinal side wall 25 is intended to be in thermal contact with one (or more) source (s) hot (s).

In the positioning zone 32 of the hot springs - the so-called "evaporation zone" - the coolant 1 is intended to be vaporized (i.e., from the liquid state to the vapor state) to allow the hot springs to cool.

In the embodiment illustrated in FIG. 1, the area of the evaporation zone is less than 40% of the total area of the first longitudinal lateral wall 25.

In the embodiment illustrated in FIG. 1, the distance between:

The evaporation zone 32 and each transverse lateral wall 23, 24 is equal to one fifth of the length (L) of the first longitudinal lateral wall ( ^L / 5), the distance between

The evaporation zone 32 and the upper wall 22 is equal to one third of the height (H) of the first longitudinal lateral wall ( ^H ), and the distance between

 The evaporation zone 32 and the bottom wall 21 are zero.

The distance between the evaporation zone 32 and each transverse side wall 23, 24 and the distance between the evaporation zone 32 and the upper wall 22 depend on the intended application: they are a function of the quantity of heat transfer fluid 1 chosen as well as surfaces necessary for condensation and recirculation of the fluid.

At least one hot source is in thermal contact with a region of the outer face of the first longitudinal side wall 25 for which the opposite inner face is covered with heat transfer fluid 1 (advantageously so that the distance between the lower part of the corresponding region on the outer face of the first longitudinal side wall 25 and the bottom wall 21 is zero). This makes it possible to ensure the proper operation of the thermal diffusion device, even for high flux densities, by preserving one or more hot source free surfaces on the outer face of the first longitudinal side wall 25 in order to allow condensation and return of the liquid to the evaporation zone 32.

Advantageously, the outer face of the first longitudinal side wall 25 may comprise a positioning mark to indicate the location of (and delimit) the evaporation zone. This facilitates the positioning of hot springs by the user. The positioning mark may consist, for example, of an imprint drawn or engraved on the external face of the first longitudinal lateral wall 25. 1.2.1.4. Cold source positioning zone

In the embodiment illustrated in Figures 1 to 3, the outer face of the second longitudinal side wall 26 is intended to be in thermal contact with one (or more) source (s) cold (s).

In the cold source positioning zone - the so-called "condensing zone" - the coolant is intended to be condensed (i.e. passage from the vapor state to the liquid state). The condensation zone may cover all or part of the surface of the external face of the second longitudinal lateral wall 26.

Alternatively, the condensation zone and the evaporation zone may extend on the same longitudinal sidewall. In this case, the condensation zone extends above the evaporation zone. More specifically, the condensation zone can be arranged so that the distance between:

The zone of condensation and each transverse lateral wall 23, 24 is zero, the distance between The condensation zone and the upper wall 22 are zero, and the distance between

• the condensation zone and the bottom wall 21 is equal to two thirds of the height (H) of the second longitudinal side wall 26 ( ^2H / 3).

The fact of being able to vary the position and the dimensions of the condensation zone makes it possible to limit the size of the device according to the intended application.

12.2. Lateral side walls

The transverse side walls 23, 24 extend perpendicular to the longitudinal side walls 25, 26. The length of each of these transverse lateral walls 23, 24 is equal to the height of the thermal diffusion device (which depends on the intended application) . The width of each of the transverse side walls is equal to the sum of the thicknesses of the longitudinal side walls added to the distance "e" between the longitudinal side walls 25, 26.

In other words, the width of each transverse lateral wall 23, 24 is between:

 · Twice the thickness of a longitudinal side wall plus ½ the capillary length of the heat transfer fluid 1, and

 • twice the thickness of a longitudinal side wall plus twice the capillary length of the coolant 1. 2. Principle of operation

The principle of operation of the thermal diffusion device will now be described in greater detail with reference to FIGS. 4 and 5. 2.1 Non-functioning

Referring to Figure 4, there is illustrated an embodiment of the device when the elements to be cooled do not generate heat. The housing comprises a quantity of heat transfer fluid substantially equal to 50% of its total volume, so that the lower half of the inner faces of the longitudinal and transverse side walls are immersed under the heat transfer fluid.

It is assumed in this embodiment that:

 The hot springs are disposed in the evaporation zone 32 of the first longitudinal lateral wall 25, at least one of the hot springs being in thermal contact with a region of the external face of the first longitudinal lateral wall for which the opposite internal face is covered with heat transfer fluid 1,

 The cold source is in thermal contact with the external face of the second longitudinal lateral wall 26 in the condensation zone. 2.2. Operating

When the elements to be cooled (i.e. hot springs) are activated, the heat generated at the hot springs is transmitted to the heat transfer fluid 1 via the first longitudinal side wall 25.

The texturing of the internal face of the first side wall 25 promotes the evaporation of the coolant 1 by promoting nucleation phenomena. Thus, vapor bubbles 4 are formed in the coolant (boiling) and back to the surface of said fluid (see Figure 5). The evaporation of the coolant 1 in the liquid state absorbs heat. This induces a cooling of the hot source.

The ascension of the vapor bubbles 4 confined (in one direction) towards the surface of the coolant 1 makes it possible to raise the heat transfer fluid in the liquid state ("pushed" by the bubbles below) so as to wet the zone of evaporation 32 over its entire surface.

The coolant vapor occupies the upper part of the housing 2. Once in the condensation zone, the heat transfer fluid in vapor form is transformed in liquid (condensation phenomenon), then falls via recirculation zones (corresponding to zones in the housing extending opposite regions of the outer face of the first longitudinal side wall 25 devoid of hot springs) to the lower wall 21 of housing 2 under the effect of gravity.

Thus, the recirculation of the coolant takes place in two dimensions. Convection cells are formed around the hot source (s): the heat transfer fluid moves over the hot source (s) during its evaporation and then falls around the (or) hot source (s) during condensation.

3. Conclusions

The proposed thermal diffusion device is capable of transferring heat from one or more flat heat sources - such as a card or electronic component - to a cold source - such as a radiator. Typical dimensions for electronic component cooling applications can be:

 A few centimeters (or tens of centimeters) for the length (L) and the height (H) of the longitudinal lateral walls, and

 · A few millimeters for the distance (e) between the longitudinal side walls.

The thermal diffusion device comprises:

 • one (or more) possible zone (s) for positioning the hot source (s), referred to as "evaporation zone (s)", and

• one (or more) possible zone (s) for positioning the cold source (s), called "condensation zone (s)".

 The evaporation and condensation zones may be placed on opposite walls (in particular the longitudinal side walls) or on the same wall.

The device can be used in a vertical or inclined position (even strongly). Great flexibility is allowed in the positioning of the sources. At least one of the hot springs is located below the filling level of the housing 2 in heat transfer fluid 1 to promote the evaporation thereof. Moreover, the hot springs are preferentially positioned so that:

 The distance between the hot springs and the upper wall 22 of the housing 2 is greater than or equal to one third of the height of the side walls 23-26 of the housing 2, and so that

 The distance between the hot springs and the transverse lateral walls 23, 24 of the housing 2 is greater than or equal to one fifth of the length of the longitudinal side walls 23, 24.

This maximizes the heat diffusion efficiency of the device.

The reader will have understood that many modifications can be made to the device described above without physically going out of the new teachings and advantages described herein.

Therefore, all such modifications are intended to be incorporated within the scope of the appended claims.

Claims

Thermal diffusion device with heat pipe effect comprising a heat transfer fluid (1) and a housing (2), the housing (2) comprising a bottom wall (21) forming a bottom, an upper wall (22) opposite to the bottom wall (21) and four side walls (23, 24, 25, 26) between the lower (21) and upper (22) walls, the side walls consisting of:

 two transverse lateral walls (23, 24),

 two longitudinal lateral walls (25, 26), a first longitudinal lateral wall (25) being intended to receive a hot source,

the walls of the housing (2) being interconnected so as to constitute a sealed reservoir for the coolant,

characterized in that

 the distance between the longitudinal lateral walls (25, 26) is between ½ and 2 times the capillary length of the coolant (1),

 the distance between the transverse lateral walls is greater than 10 times the capillary length of the coolant,

 - The amount (Qf) of heat transfer fluid (1) contained in the device is between 25 and 80% of the total volume (Vtot) of the housing (2).

Device according to claim 1, which is devoid of capillary structure.

Device according to any one of the preceding claims, wherein the first longitudinal side wall (25) comprises an evaporation zone (32) intended to receive at least one hot source, the area of the evaporation zone (32). being less than 40% of the total area of the first longitudinal side wall (25).

Device according to the preceding claim, wherein the evaporation zone for receiving the hot source is positioned on the first wall at a non-zero distance from the side walls to allow two-dimensional circulation of the coolant around the hot source.

5. Device according to any one of the two preceding claims, wherein the position of the evaporation zone on the first longitudinal side wall is such that:

 The distance between the evaporation zone (32) and each transverse lateral wall (23, 24) is greater than or equal to one fifth of the length (L) of the first longitudinal lateral wall (25),

The distance between the evaporation zone (32) and the upper wall (22) is greater than or equal to one third of the height (H) of the first longitudinal lateral wall (25), and

 The distance between the evaporation zone (32) and the bottom wall (21) is zero.

6. Device according to any one of the three preceding claims, wherein the outer face of the first longitudinal side wall (25) comprises a positioning mark for defining the position of the evaporation zone (32).

7. Device according to any one of the preceding claims, which comprises spacers (36) between the inner faces of the longitudinal side walls (25, 26) of the housing (2), each spacer (36) being intended to cooperate with means respective fasteners.

8. Device according to any one of the preceding claims, wherein the inner faces of the longitudinal side walls (25, 26) comprise surface texturing.

9. Device according to the preceding claim, wherein the surface texturing consists of splines formed on the inner faces of the longitudinal side walls (25, 26), the grooves extending between the lower and upper walls (21, 22) of the housing (2).

10. Device according to one of the preceding claims, wherein the coolant (1) is water.