FR2571546A1 - COOLING BLOCK FOR ELECTRONIC COMPONENTS AND / OR DEVICES - Google Patents

Abstract

A COOLING BLOCK 20 FOR COMPONENTS AND OR ELECTRONIC APPLIANCES IS CONSTITUTED BY BASE BODIES 22, 24 ARRANGED IN OPPOSITE AND OFFSET IN PAIRS WITH THE ONE FROM THE OTHERS AND INCLUDING COOLING FINS 26, 30 STARTING FROM THESE, SO THAT THE COOLING FINS 26 OF ONE OF THE BASE BODIES 22 PENET INTO THE INTERVALS 28 BETWEEN THE COOLING FINS 30 OF THE OTHER BASE BODY 24.

Description

Cooling block for components and / or

electronic appliances.

  The invention relates to a cooling block for electronic components and / or devices, comprising

  at least one base body provided with cooling fins

who leave.

  Since the performance capacity of electronic components and / or electronic devices is constantly increasing, and therefore also their heat generation despite the reduction of their external dimensions, cooling blocks are required having, for the same external dimensions, greater capacity

  cooling, or for the same cooling capacity

  smoothing, less bulk. But an increase

  cooling capacity is only possible if the surface of the cooling block can be

  increased for predetermined external dimensions

  born, which is only possible by increasing the number of fins and reducing their spacing. But, with the usual economical manufacturing methods of such cooling blocks, one cannot go

  beyond the currently known scale.

  If, for example, the cooling block is produced in the form of a cast iron profile, it is not possible to descend below a ratio between the spacing of the cooling fins and the height thereof determined by the construction of the molds casting technique used. If however we wanted to manufacture cooling blocks having a smaller ratio between the spacing of the cooling fins and

  their height, the spaces between the cooling fins

  dissement had to be milled from a block of parallelepiped cast iron. This method of manufacturing cooling blocks is very time consuming and very expensive and therefore not suitable for

mass production.

  For the cooling blocks made of sheet metal by stamping, the ratio between the spacing of the cooling fins and their height cannot either be reduced beyond the value currently used,

  because we can't reduce the tools of estam-

  page due to the efforts that occur during

the stamping operation.

  The object of the invention is to provide an economical means

  to significantly increase the cooling capacity

  cooling of a cooling block while keeping

  the external dimensions, or reduce significantly-

  the external dimensions of a cooling unit

  smoothing for the same cooling capacity.

  This object is achieved for a cooling block of the aforementioned type by the fact that the cooling block is formed of basic bodies facing each other, offset in pairs relative to each other, so that the cooling fins of one of the basic body

  enter the spaces between the cooling fins

other base body.

  Thanks to the invention, it is thus possible to increase

  ter the cooling capacity of a cooling unit

  expansion of predetermined external dimensions by notably reducing in a simple manner the average spacing of the cooling fins by the fact that the cooling fins of one of the basic bodies penetrate into the intervals between the cooling fins of the other basic body. This has the advantage that the basic bodies can continue to

  be manufactured using current economic processes-

  ment in use for the manufacture of cooling blocks

  dissement. To form a cooling block according to the invention, it suffices to assemble in pairs and to link together the basic bodies thus produced. The

  basic bodies can be bonded together

  ment, screwing, gluing or using a separate bracket that holds the basic bodies together. The invention thus enables mass production in an economical series.

  cooling blocks whose cooling capacity

  softening in relation to their external dimensions

  is significantly above the values currently achieved

  sands. The cooling block according to the invention can be constituted, for example, by two plates constituting the basic bodies and arranged parallel between

  they, on the sides, turned towards each other, des-

  what are the cooling fins arranged

  ment, the cooling fins of one of the plates entering the spaces between the fins

  the other plate.

  However, the cooling block according to the invention can also consist of two concentric cylinders serving as the basic body. In this case, the cooling fins arranged in the form of spokes on the peripheral surface of the smallest cylinder penetrate

  in the intervals between the cooling fins

  attached to the inner surface of the larger cylinder. In another development of the invention, the cooling block consists of two similar basic bodies. This results in the advantage that a single manufacturing tool is sufficient to manufacture the two basic bodies, for example a single casting mold or a single

stamping tool.

  In another development of the invention, all of the

  cooling fins have appreciable heights -

  In addition, there is in each base body, between the cooling fins, a groove parallel to them, the width of which corresponds

  substantially to the thickness of the cooling fins

  ment of the other basic body on their free edges.

  This has the advantage that in a cooling block

  dissement formed by basic bodies facing each other, offset in pairs relative to each other, the cooling fins of one of the basic bodies come to rest in the grooves of the other basic body, which ensures good heat transmission

  between a base body and the cooling fins

ment of the other basic body.

  If, in the above-described embodiment of the cooling block, the grooves narrow towards the bottom, the two basic bodies can be wedged together if the thickness of the cooling fins on their free edges is greater than the width of the grooves at their lowest point. This embodiment of the cooling block has the advantage of ensuring particularly good heat transmission to the

  stuck places between the cooling fins

  dissement and the side walls of the grooves. In addition, in this arrangement, since the basic bodies are jammed, it is possible to remove an additional connection

of the two basic bodies.

  When the grooves are arranged in the middle between the cooling fins, all the intervals between the fins of the assembly are of the same size so that all the cooling fins are

  uniformly supplied with cooling air.

  If there is no specific direction of supply of cooling air to the cooling block, for example if free cooling is used

  air movement, the cooling block must be

  This is done in such a way that the cooling air can circulate through the block in all directions. This object is achieved in another development of the invention by the fact that the cooling fins have openings, which allows the cooling air to circulate in the cooling block, not only in the longitudinal direction.

  fins, but also transversely thereto.

  The openings can in this case be placed trans-

  vertically to the cooling fins, one behind the other coinciding with each other, which ensures particularly air circulation

  efficient in the transverse cooling block

also with fins.

  If the neighboring fin openings are offset

  one compared to the other, we ensure a good vortex

  the cooling air inside the

cooling block.

  The invention will be clearly understood on reading the

  description below, given by way of example only,

  of two embodiments of a basic body for forming a cooling block and of three forms of

  production of a cooling block according to the invention

  tion, shown schematically in the drawing, in which: - Figure 1 shows a base body in the form of a plate with the cooling fins which depart therefrom; - Figure 2 shows the basic body of Figure 1, in which, unlike Figure 1, the cooling fins have recesses; - Figure 3 shows a cooling block formed by two base bodies shown in Figure 1; - Figure 4 is a cross section of a cooling block consisting of stamped sheet metal elements of similar construction; and - Figure 5 is a cross section of a cooling block consisting of two concentric cylinders

  fitted with cooling fins.

  FIG. 1 represents a base body 10 in the form of a plate, produced by casting and comprising fins

  cooling 12 which leave at a right angle.

  These are rectangular in shape and have an identical height. Between the cooling fins 12 are respectively arranged grooves 14, in the middle in the base body 10. These are parallel to the

  cooling fins 12 and slightly shrink

  rement towards the bottom. Their width corresponds substantially to the thickness of the cooling fins 12 on

their free edges 13.

  The base body 10 shown in FIG. 1 is particularly suitable for forming cooling blocks (FIG. 3), into which the cooling air arrives in a determined direction. It is then necessary that the base body 10 is arranged in the air stream so that the cooling fins 12 are oriented in the direction of air intake so that as much air as possible may

  circulate between the cooling fins 12.

  Aluminum is particularly suitable as a material.

  riau for the basic body, since it is a good conductor of heat and is easy to work in the form of cast iron. As a casting technique, the process can be used as well.

  injection than the extrusion process.

  Such basic bodies can also be cut from sheet metal as will be explained later in

referring to figure 4.

  The basic body 15 shown in Figure 2 differs from that shown in Figure i simply in that the cooling fins 16 are provided with recesses 18 starting from their free edges 17 and extending almost over the entire height of the fins 16. In this embodiment of the

  basic body, there is provision in each cooling fin

  distribution 12 three recesses 18 and here the recesses of the neighboring fins 16 are arranged one behind

the other and coincide with each other.

  The realization of the basic body 15 provided with recesses 18

  in the cooling fins 16 is suitable

  especially to form cooling blocks (not shown) in which the free movement of air is used for cooling. Since, in this case, there is no predominant air intake direction, air must be able to circulate in the cooling block in all directions. This object is achieved with a cooling block constructed with the basic bodies 15, at least partially,

  by the fact that the cooling air circulation

  ment in the cooling block can be carried out both in the longitudinal direction of the cooling fins and in the transverse direction to these

fins 16.

  Advantageously, the basic body shown on

  Figure 2 can be made of aluminum by injection

  tion in a single operation. If we use this technique

  as the extrusion process, it will be necessary to mill the recesses 18 in the cooling fins 16

in another operation.

  FIG. 3 represents a cooling block 20 which is constituted by a first base body 22 and a

  second base body 24. These are similarly constructed.

  tion as the base bodies 10 shown in Figure 1. The two base bodies 22 and 24 are offset from each other so that the fins

  cooling 26 of the first base body 22 penetrates

  trent in the gaps 28 between the cooling fins 30 of the second base body 24. Both the base body 22 and the base body 24 are provided with grooves 34, 36 which are arranged in the middle between the cooling fins 26 and 30. The grooves 34 in the base body 22 have a width which corresponds substantially to the thickness of the cooling fins 30 of the base body 24 on their free edges 38. Similarly, the width of the grooves 36 of the base body 24 corresponds substantially to the thickness of the cooling fins 26 of the base body 22 at their free edges 40. As can be seen in the drawing, the cooling fins 26 of the first body

  base 22 have the same height as the cooling fins

  dissement 30 of the second base body 24. This gives the cooling fins 26, 30 of a base body22,24, respectively penetrate into the grooves 36, 34 of the other base body 24, 22, so that by wedging the two base bodies 22 and 24, a stable cooling block construction is obtained. But, instead of being wedged together, the basic bodies 22 and 24 can, as a variant, be for example screwed together, glued or held together by a stirrup

(not shown).

  On its outer sides, the cooling block 20 can be provided with anchoring elements, for example fixing flanges or bores (not shown), for fixing the components or the devices.

electronics to be cooled.

  Figure 4 shows a cooling block 50, in cross section, which consists of two base bodies 52 and 54 in the form of elements cut from sheet metal

  and assembled. Analogously to the cooling block

  ment 20 of FIG. 3, this cooling block 50

  consists of two basic bodies 52 and 54 of construction

  similar, which face each other with offset relative to each other, so that the cooling fins 56 of the base body 52 penetrate into

  the intervals between the fins 58 of the cooling fins

  dissement 60 of the other base body 54. There is provided in the middle between the cooling fins 56 and 60 of the two base bodies 52 and 54 respectively a groove 62, 64 parallel to the cooling fins

  56 and 60, since all the cooling fins

  56 and 60 have the same height, the cooling fins 56 of the base body penetrate into the grooves 64 of the base body 54, and conversely, the cooling fins 60 of the base body 54 penetrate into the grooves 62 of the body of base 52, which ensures good heat exchange between the base bodies 52 and 54. The two base bodies 52 and 54 can, for example, be glued together, so that this results in a rigid construction on which one can attach the electronic component or device (not

shown) to cool.

  Thanks to the arrangement according to the invention of the basic bodies 52 and 54 relative to each other, it has been possible to reduce

  notably the average spacing of the cooling fins

  smoothing of the entire cooling block 50 relative to that of a single base body 52 or 54,

  which significantly increases the cooling capacity

  of the entire cooling block 50 relative to a single base body 52 or 54, for the

same exterior dimensions.

  FIG. 5 finally shows a cooling block 70 in cross section, which consists of two concentric cylinders 72 and 74 serving as a basic body. The smaller inner cylinder 72 is provided

  on its peripheral surface 75 cooling fins

  dissement 76 arranged in the form of rays, which penetrate

  in the intervals 78 between the cooling fins

  dissement 82 fixed on the inner surface 80 of the

  larger cylinder 74. Between the cooling fins

  Dissement 82 of the largest cylinder 74 is provided each time a groove 84 in which is housed the free edge 86 of a cooling fin 76 of the smallest cylinder 72. Similarly, there is each time between the cooling fins 76 to middle, a groove 88 in which the free edge 90 is housed

  a cooling fin 82.

  The two basic bodies in the form of cylinders 72 and 74

  can be produced in the form of cast profiles.

  It is then enough to assemble them to form the block of

cooling 70.

  An electronic component or a cooling device (not shown) can for example be arranged at

  the interior 92 of the smallest cylinder 72.

Claims (9)

Claims.   1. Cooling block for electronic components and / or devices, comprising at least one basic body provided with cooling fins which   leave, characterized in that the cooling block   ment (20; 50; 70) is constituted by basic bodies (22, 24; 52, 54; 72, 74) arranged opposite and offset in pairs relative to each other, and that the fins of cooling (26; 56; 76) of one   basic bodies (22; 52; 72) penetrate into the inter-   valles (28, 58; 78) between the cooling fins   ment (30; 60; 82) of the other base body (24; 54; 74). 2. Cooling block according to claim 1, characterized by two similar basic bodies (22, 24; 52, 54). ; 3. Cooling block according to claim 1 or   2, characterized in that all the cooling fins   dissement (26, 30; 56, 60; 76, 82) have a substantially equal height and that in each base body (22, 24; 52, 54; 72, 74), there is between the fins   cooling (26, 30; 56, 60; 76, 82) respectively   a groove parallel to these (34, 36; 62, 64; 84, 88) whose width corresponds substantially to the thickness of the cooling fins (26, 30; 56, 60; 76, 82) of the other basic body (22, 24; 52,   54; 72, 74) on their free edges (40, 38; 86, 90).   4. Cooling block according to claim 3,   characterized in that the grooves (34, 36) shrink cisse going towards their bottom. 7 1546   5. Cooling block according to claim 3 or 4, characterized in that the grooves (34, 36; 62, 64; 84, 88) are arranged in the middle between the fins of   cooling (26, 30; 56, 60; 76, 82).   6. Cooling block according to one of the claims   above, characterized in that the fins   cooling (16) have openings (18).   7. Cooling block according to claim 6, characterized in that the openings are formed by recesses (18) starting from the free edges (17) of cooling fins (16). -   8. Cooling block according to claim 6 or   7, characterized in that the openings (18) are provided   entered transversely to the cooling fins (16) one behind the other and in coincidence one with the other.   9. Cooling block according to claim 6 or 7, characterized in that the openings (18) of cooling fins (16) adjacent to each other are   arranged offset relative to each other.