WO2014049004A1 - Cooling device for cooling an electronic component, and electronic module - Google Patents

Abstract

The cooling device for cooling an electronic component comprises a heat sink attached to the electronic component, a piezoelectric bender transducer comprising a piezoelectric bending element, in addition to a flow section which is at least partially delimited by the heat sink and through which the flow that is generated by the component can pass. At least one flow body is situated in the flow section. The electronic module has an electronic power component in addition to a cooling device of this type, said device being designed and arranged to cool the power component.

Description

description

Cooling device for cooling an electronic component and electronic module

The invention relates to a cooling device for cooling an electronic component and an electronic module.

Cooling devices for cooling electronic components are known, which have a piezoelectric bending transducer with a piezoelectric bending element. These bending elements are excited to bending vibrations by applying a sinusoidal electrical voltage in the frequency range of the audible sound or the infrasound (about 10 Hz to 1 kHz), wherein the frequency of the bending vibrations usually ent ^¬ the lowest bending mode of the bending element. In particular with bending members in the form of bending bars ^¬ is due to the periodic movement of the bending element, a uniform air flow, approximately in the direction of the longitudinal extent of the cantilever is generated. This Luftströ ^¬ tion can be used in heatsinks in cooling devices of electronic modules to increase by flow of cooling fins, the cooling capacity of the heatsink. Compared to purely passive measures for cooling can be achieved by means of piezoelectric bending transducer, a reduction in the volume of electronic modules and an improvement in energy balance, such as by improving the regularly highly temperature-dependent efficiency of semiconductor devices.

In electronics-operated fanless modules, improvements have hitherto been achieved by optimizing the thermal or fluid dynamic design of the electronics module. However, conventional fans are limited in life and, for example, do not reach the lifetimes of

Electronic components such as LED lights high performance (regularly at least 30,000 hours). Furthermore, in the case of electronic modules, cooling by fans, wel typically cause a disturbing noise emission, not purposeful. By contrast, alternative solutions do not yet achieve the required cooling efficiency.

It is therefore an object of the invention to provide a cooling device for cooling an electronic component, which can be operated with sufficient cooling efficiency and low noise. It is another object of the invention to provide an electronic module in which a cooling of an electronic component of this electronic module is improved possible.

This object is achieved with a cooling device for cooling an electronic component having the features specified in claim 1 and with an electronic module having the features specified in claim 16. Preferred embodiments of the invention are set forth in the appended subclaims, the following description and the drawing.

The cooling device according to the invention for cooling a elekt ^¬ tronic component comprises a thermally anbindbaren the electronic component heat sink, a bending transducer comprising a piezoelectric bending element and a flow path which is at least partially delimited from the heat sink. The flow path can be flown with the flow which can be excited by the bending element. At least one flow body is located in the flow path.

In the case of the cooling device according to the invention, the at least one flow body provided in the flow path can effectively prevent the formation of air vortices in the region of the flow path. In this way, a flow in the flow path is significantly increased.

Consequently, due to the improved flow through the flow path, which is at least partially delimited by the heat sink, air flow-based heat transport away from the heat sink is continued clearly improved. Thus, the cooling capacity of the cooling device according to the invention is significantly increased.

Advantageously, in the cooling device according to the invention, the bending element is a bending beam.

Suitably, the cooling device according to the invention comprises a clamping, in which the bending element is at least partially clamped. In this case, the at least one flow body is arranged closer to a maximum deflectable part of the bending element than the clamping. In particular, the at least one flow body is arranged downstream of the maximum deflectable part of the bending element. Especially in the area of the ma ^¬ ximal deflectable portion of the bending element can alone already achieve effi ^¬ cient influencing the local flow directions of the fanned by bending element air flow and thus out.The ^¬ che improve cooling performance means arranged there flow body. The formation of vertebrae is effectively suppressed. A full ambient of the bending element with flow bodies is not necessary for ef ^¬ cient flow arousal.

Preferably, in the cooling device according to the invention, the bending element has a free end and forms the free end of the maximum deflectable part. Especially with a free end of a bending element there is a strong tendency to Ausbil ^¬ tion of air vortices, which can be effectively countered with the free end near flow bodies. It is advantageous in the cooling device according to the invention in all possible, especially in two opposite

set deflection directions each provided at least one flow body. For the purposes of this invention, a deflection direction is to be understood as that spatial direction in which a maximally deflectable part of the bending element, in particular the free end of a cantilevered cantilever, emerges begins to deflect out of his undeflected position. In particular, in a non-deflected state with its longitudinal extension along a longitudinal direction extending bending beam extending the deflection perpendicular to the longitudinal direction. For the purposes of this invention, the direction of deflection is not necessarily considered to be a signed quantity. For example, in the case of a ^cantilevered transducer which is clamped on one side and has a long and planar design, the deflection direction is regularly perpendicular to the bending direction

Flat sides of the bending transducer. In this case, the free end of the bending beam moves periodically in two opposite directions along an axis which is perpendicular to the flat sides. For the purposes of this invention, each of these opposite directions is understood as a deflection direction.

Conveniently, in the cooling device according to the invention, the at least one flow body or at least one or more of the flow bodies in a direction to a local bending axis of the flow body respectively near range, in ^¬ particular of the flow body next point, the Bie ^¬ geelements vertical plane completely flowed around. Alternatively and also expediently, a flow body projects from a boundary of the flow path into the flow path.

In the cooling device according to the invention, the at least one flow body or at least one of the flow bodies particularly preferably has a cylinder or is designed as a cylinder.

For the purposes of this invention, a cylinder is always to be understood as meaning a general cylinder, that is to say that the cylinder is expediently, but not necessarily, a cyclic cylinder.

It is advantageous in the cooling device according to the invention, a cylinder axis of the flow body parallel or nearly arranged parallel to the bending axis of the bending beam. Under an almost parallel axis of the cylinder is to be understood such a cylinder axis in the sense of this invention, wel ^¬ che in orientation from that of the local Biegeach- se of the bending element to the highest 20 degrees, particularly not more than 5 degrees, deviates.

In a preferred embodiment of the inventive cooling device, the flow body has a rectangular cross-sectional area, in particular a rectangular cylinder ^¬ base on.

Alternatively, and also advantageously has the Strömungskör ^¬ by a triangular cross-sectional area, in particular a triangular cylinder base surface, wherein the tip of the

Cross-sectional area preferably in a direction perpendicular to the deflection and perpendicular to the local bending axis and in particular in the direction of the clamping points. As an alternative to the two aforementioned further developments of the inventive cooling device, the flow body has a circular cross-sectional area, in particular a circular cylinder ^¬ shaped base face on. Ideally, in the case of the cooling device according to the invention, the at least one flow body has a cross-sectional area tapering in the direction perpendicular to the deflection direction and perpendicular to the local bending axis, in particular in the direction of the clamping, in particular a tapering cylinder base area. In the inventive

Cooling device is in an advantageous development, the bending element is a bending beam and the at least one Strö ^¬ tion body has greater dimension in the direction of the bending axis of the bending beam, as the bending beam or smaller dimensions than the bending beam or identical dimensions compared to the dimensions of the bending beam. In the cooling device according to the invention, the heat sink and the flow body are expediently connectable via a latching connection, in particular by means of latching lugs.

Preferably is formed with the inventive cooling device of the flow body and / or the cooling body, in particular as an integrally formed flow body heatsink composite, as a cast part or injection molded part, in particular with faserver ^¬ reinforced plastic and / or metal.

The electronic module according to the invention has an electronic component and a cooling device as described above, which is designed for cooling the power component and ordered to ^¬ .

The invention will be explained in more detail with reference to an embodiment shown in the drawing. It zei ^¬ gen 1 shows a known electronic module with a known

 Cooling device with a piezoelectric bending beam schematically in a schematic diagram,

FIG. 2 shows a bending beam of the cooling device of the electronic module according to FIG. 1 schematically in a plan view,

3 shows a bending beam of a cooling device according to the invention of an electronic module according to the invention in an arrangement with two flow bodies schematically in a plan view, the bending beam gem. 3 is a schematic plan view of a bending beam of a further embodiment of a cooling device according to the invention of the electronic module according to the invention in an arrangement. tion with two flow bodies schematically in a plan view,

FIG. 6 shows a bending beam of a further exemplary embodiment of a cooling device according to the invention of the electronic module according to the invention in an arrangement with two flow bodies schematically in a plan view, FIG. 7 shows a bending beam of a further embodiment of a cooling device according to the invention of the electronic module according to the invention in an arrangement with two flow bodies schematically in a top view,

8 shows a bending beam of a further embodiment of a cooling device according to the invention of the electronic module according to the invention in an arrangement with two flow bodies schematically in a plan view and

9 shows a heat sink of the cooling device according to the invention of the electronic module according to the invention in an arrangement with bending beams and two flow bodies gem. Fig. 5 schematically in cross section.

The known electronic module 1 shown in FIG. 1 has an electronic component 2, an LED component in the exemplary embodiment shown (in non-specifically illustrated exemplary embodiments, it is also possible for another electronic component, for example a power component, to be present). The electronics module further comprises a cooling device 3. The cooling device 3 comprises a heat sink 4, which is in the illustrated embodiment by direct thermal and spatial contact to the electronic component 2 is ^¬ prevented. The cooling body 4 defines part of a flow path (indicated by arrows S, which at the same time the flow direction ^¬ mark through the flow path), which is beströmbar with ambient air.

The air flow through the flow path is fanned by a piezoelectric bending beam 5, which forms a piezoelectric bending transducer in cooperation with an electrical circuit (not explicitly shown) for deflecting the bending beam 5. The bending transducer is designed for deflection at a frequency in the range of audible sound or infrasound.

The bending beam 5 in more detail illustrated in Fig. 2 is at a longitudinal end 10 in a restraint (not explicitly ge ^¬ shows) clamped. From this clamping, the bending beam 5 extends in its rest position, ie in its non-deflected state, in a longitudinal direction L. The longitudinal end of the bending beam 5, which is located outside the clamping, forms a free end F, which is bendable in a deflection direction A in relation to its longitudinal end 10 which is fixed in the clamping. Thus, in the operation of the cooling device 3, the free end F "waves" air in the direction symbolized by the arrows S through the flow path.

The electronic module according to the invention is constructed as the known electronic module 1 as described above. Deviating from the known electronic module 1, however, flow bodies are additionally present in the flow path of the cooling device, as described with reference to FIGS. 3 to 8.

Two Strö ^¬ mung body 40 are as shown in Fig. 3 and 4, the inventive electronic module downstream of the bending beam 5 is provided. The flow body 40 are in the rest position spaced from the longitudinal central axis of the bending beam 5 to geringfü ^¬ gig more than the maximum during operation of the bending beam 5 on ^¬ passing deflection in the deflection direction A and on both sides of the longitudinal center axis of the bending beam 5 zueinan- the mirror-symmetrically arranged with respect to the longitudinal center axis of the bending beam 5 in the rest position.

The flow body 40 shown in Fig. 3 and 4, as well as the flow body shown in FIGS. 5 to 8, the shape of a straight cylinder (not necessarily circular cylindrical ^¬) on. In this case, the cylinder axis of the flow body shown in Fig. 3 to 8 runs parallel to the bending axis of the bending beam 5, that is perpendicular to the plane.

In the plane lying directions the flow ^¬ body 40 are free-standing, ie, the flow body 40 are in directions of the plane, so perpendicular to the bending ^¬ axis of the bending beam 5 completely flowed around.

In the flow bodies 40 shown in FIGS. 3 and 4, the cylinder base area of the flow bodies 40 is rectangular.

In contrast, in the case of the flow bodies 50 shown in FIG. 5, the cylinder base area of the flow bodies 50 is circular.

Consequently, these flow bodies have a particularly aerodynamic profile. Aerodynamic profiles have also Strö ^¬ mung body 60 (Fig. 6) with a triangular basic cylinder surface, in which a tip of the triangular cylinder base surface in the longitudinal direction L to has the clamping. In this development, the cross-sectional area tapers in the longitudinal direction L to the clamping of the bending beam 5. A cross-sectional area to be tapered longitudinally to the clamping of the bending beam 5 also has the flow bodies 70 (FIG. 7), which have a drop-shaped cylinder base area tapering in the longitudinal direction L towards the clamping of the bending beam 5. As shown in FIG. 8, the cylinder base ^{surface of} the flow body 80 can also be L-shaped, for example with a leg pointing in the longitudinal direction onto the clamping, the respective remaining limbs of the flow body 80 facing one another. In this case, as shown by dashed lines in FIGS. 6 and 7 by way of example, Those directions in which the cylinder base surface of the flow body 60, 70 each tapers, not necessarily ^¬ gerweise exactly in the longitudinal direction L extend. For example, alignments with a smaller flow resistance of the flow body are conceivable and may, for example, by up to 30 degrees, deviate from this longitudinal direction.

In the illustrated embodiments, the flow body 40, 50, 60, 70, 80 in the direction of the bending axis of the bending beam 5, ie perpendicular to the plane, identical Ab ^¬ measurements on how the bending beam 5. In not specifically presented Darge ^¬ embodiments, which Incidentally, correspond to those shown, the flow body on larger or smaller dimensions compared with the bending beam 5 in the direction of the bending axis.

In the case of the cooling device according to the invention, the flow bodies 40, 50, 60, 70, 80 are connected to the heat sink via latching connections with latching lugs (in embodiments not shown separately, the flow bodies can also be connected to the heat sink in a different manner). For example, the heat sink ribs 100 in the longitudinal direction L, wherein as shown in Fig. 9, a plurality of bending bars 5 may be present between the ribs 100. The ribs 100 are covered in the direction of flow by a cover 110 which extends flat and perpendicular to the ribs 100 and to the direction of flow and through which the flow paths pass through flow openings 120. The flow body 50 are connected by webs to the lid 110.

The cover 110 with the flow bodies 50 has locking lugs 130, which can engage in corresponding with the locking lugs 130 recesses of the ribs. In this way, the lid 110 is connected to the flow bodies 50 with the ribs 100 of the heat sink.

Claims

Patent claims

1. Cooling device for cooling an electronic component (2), comprising a heat sink (4) that can be thermally connected to the electronic component (2), a bending transducer with a piezoelectric bending element (5) and a flow path (S), which is at least partially from the cooling ^¬ body (4) is limited and which can be flowed with the flow that can be excited by the bending ^element , and in which at least one flow body (40, 50, 60, 70, 80) is located in the flow path (S).

2. Cooling device according to the preceding claim

in which the bending element is a bending beam.

3. Cooling device according to one of the preceding claims, comprising a clamping in which the bending element (5) is at least partially clamped, in which the flow body (40, 50, 60, 70, 80) is a maximum deflectable part of the bending element (5 ) is arranged closer than the A ^¬ voltage, in particular downstream of the bending element (5).

4. Cooling device according to one of the preceding claims, in which the bending element (5) has a free end and the free end forms the maximum deflectable part.

5. Cooling device according to the preceding claim

which at least one flow body (40, 50, 60, 70, 80) is provided in several, in particular in two, mutually facing deflection directions.

6. Cooling device according to one of the preceding claims, in which the at least one flow body (40, 50,

60, 70, 80) in a region close to a local bending axis of a flow body (40, 50, 60, 70, 80), in particular an area close to the flow body (40, 50, 60, 70, 80) next point, the bending element (5) can be flowed around completely in the ^vertical plane.

7. Cooling device according to one of the preceding claims, in which the at least one or at least one of the flow bodies (40, 50, 60, 70, 80) has a cylinder or is a cylinder.

8. Cooling device according to one of the preceding claims, in which a cylinder axis of the flow body (40, 50, 60, 70, 80) is parallel to a, in particular local, bending axis of the bending beam (5).

9. Cooling device according to one of the preceding claims, in which the flow body (40) has a rectangular cross-sectional area, in particular a cylinder base area.

10. Cooling device according to one of the preceding claims, in which the flow body (60) has a triangular cross-sectional area, in particular a cylinder base area, in which a tip of the cross-sectional area is preferably in a direction perpendicular to the deflection ^direction (A) and perpendicular to the local bending axis and in particular ^¬ special in the direction of the clamping.

11. Cooling device according to one of the preceding claims, in which the flow body (50) has a circular cross-sectional area, in particular a cylinder base area.

12. Cooling device according to one of the preceding claims, in which the at least one flow body (60; 70; 80) has a cross-sectional area that tapers in the direction perpendicular to the deflection direction (A) and perpendicular to the local bending axis, in particular in the direction of the clamping Cylinder base, on ^¬ points.

Cooling device according to one of the preceding claims, in which the at least one flow body has larger dimensions in the direction of the local bending axis of the bending beam (5) than the bending beam (5) or smaller dimensions than the bending beam (5) or identical dimensions to the bending beam (5 ).

14. Cooling device according to one of the preceding claims, wherein the at least one flow body (50) can be connected to the heat sink (4) via a latching connection, in particular by means of latching lugs (130).

Cooling device according to one of the preceding claims, in particular according to claim 14, in which the flow ^¬ body (50) and / or the heat sink (4), in particular as a one-piece component that can be handled in one piece, as

Cast part or injection molded part, in particular with fiber ^- reinforced plastic and/or metal, is formed.

Electronic module with an electronic component (2), in particular a power component, and with a cooling device (3) according to one of the preceding claims, which is designed and arranged to cool the component (2).