DE4035211A1 - Electronic component module reception housing - has cooling air channel walls above and below inserted module - Google Patents

Abstract

The electronic component housing has an insertion space (6) within which the module is directly received, with flat mounting devices (10,10') above and/or below the insertion space (6) forming part of an air cooling channel for forced cooling of the inserted module, via incorporated air vents (20). Pref. each mounting device (10,10') is formed of sheet metal and has rear fixings (15), supporting the plug rail (8) cooperating with the inserted module. ADVANTAGE - Effective dissipation of generated heat.

Description

The invention relates to an assembly unit for subracks, Insert housing or similar housing, in particular 19 '' - Ge housing for accommodating electronic assemblies according to the Oberbe handle of claim 1.

Subracks and slide-in housings are widely used, for electronic devices with smaller series quantities or Build custom-made products. An essential problem be is that the individual modules on the one hand arranged relatively tightly packed, on the other hand the individual NEN assemblies give off different amounts of heat. The cooling of such assemblies is therefore relatively difficult. In most cases, heat-generating assemblies, e.g. B. power supplies, with a separate cooling device (blower) provided, while the other assemblies by convection ge be cooled. Both types of cooling are disadvantageous in that  an increased build volume for forced cooling or large area Flow cross sections required for convection cooling are so that the space utilization of the housing interior is unun stig.

The invention has for its object a mounting unit for subracks of the type mentioned to further develop that optimal cooling of the modules low volume is achievable.

This object is achieved in the characterizing part of claim 1 specified features solved.

An essential feature of the invention is that in any slide-in housing of the type mentioned at the outset anyway necessary facilities for holding the assemblies the same can be used in time to form a ventilation duct. From this ventilation duct, the individual buildings are then built groups or, if necessary, only parts thereof via the Ventilation openings ventilated so that an individual, the Suitable cooling can be done.

The assembly unit can be made from all materials those that have sufficient mechanical strength sen. Manufacturing becomes particularly easy when the Mon days unit is designed as a sheet metal part. At this Sheet metal part are preferably fastening devices for Attach connector strips provided so that otherwise usual separate holding rails for this purpose are omitted can. In particular, it is possible to attach the device formations for the connector strips by flanges, which consist of edge strips of the sheet metal assembly unit, which in the insertion space is bent so that it protrudes vertically.

The ventilation openings can be pre-punched as stripping parts be so that in the places where an assembly to be ventilated ten, the ventilation opening can be broken out. In the other preferred embodiment of the invention are at nor  mated points (according to the 19 ′ ′ standard) ventilation openings completely punched out, which - depending on requirements - either closed with a simple plastic molded part there where no ventilation is necessary. In the places where wel Chen should be ventilated, an air baffle, z. B. a nozzle. Such nozzles can be advantageous be made so that the one passing through the nozzle Air flow with respect to the air mass flow or the pressure con is kept constant. This can be done by measures known per se men happen, e.g. B. by a spring-loaded throttle valve, which is a kind of pressure reducing valve.

Guide rails for the slide-in modules can be firmly attached to the Mounting unit attached or formed by this. At an alternative embodiment of the invention are in the Assembly unit facilities, e.g. B. holes provided in which separate plastic guide rails can be attached are. These holes are then in the minimum standard distances attached so that the modules in any arrangement are settable.

The air circulation can either by convection or by means of forced ventilation. For this it is possible to use the ventilation openings. Advantageously however, a separate connection opening in the assembly unit provided with a cross section that is larger than the cross cut a ventilation opening. When using only one Assembly unit is used to form a compressed air duct the pressure side of a fan connected. If you use two Assembly units designed according to the invention, forms a one compressed air duct, the other a suction air duct.

The air circulation device can be designed as a slide-in unit be inserted into the housing like a slide-in module is slidable. In this case the connection opening is like that Ventilation openings are provided in the slot of the housing. At An alternative embodiment of the invention is air Circulation device installed outside the slot. Here  the back of the housing is particularly suitable for with a correspondingly deep housing behind space located in the connector strips to accommodate the air circulation furnishing serves. Of course, the air circulation can direction outside of the housing, for. B. from the back wall be protruding.

In any case, it is advantageous if the air circulation device tion comprises a heat exchanger, the heat from the circulated Absorbs air in the shelf and releases it to the environment. There by it is possible to hermetically seal the interior of the housing Complete the environment, which is necessary for both devices which are operated in a dusty environment, as well in such devices, which for reasons of electrical and magnetic shield must be completely closed all around have to. Of course it is also possible to get air out of the Aspirate the environment and into the compressed air ventilation duct to lead.

It is also possible to have the assembly unit with an outside wall, which enlarged a cooling rib-like Surface. This will remove heat from the airflow in the Ventilation duct discharged to the ambient air.

Preferred embodiments of the invention result from the dependent claims and the following description of Embodiments that explain with reference to figures be tert. Show here

Fig. 1 is a vertical section through a housing having a guide die from the mounting unit,

Fig. 2 shows a section along the line II-II of Fig. 1,

3 is a perspective partial sectional view of an air guiding device.,

Fig. 4 is a section similar to that of FIG. 1 by a preferred oth er embodiment of the invention,

Fig. 5 is a section along the line VV of Fig. 4,

Fig. 6 is a section similar to that of FIG. 5, but with another preferred embodiment of the invention

Fig. 7 is a section similar to that of FIG. 1 by a preferred embodiment of the invention re-wide,

Fig. 8 is a section along the line VIII-VIII of Fig. 7 and

Fig. 9 shows a section similar to that of FIG. 1 by a wide re embodiment of the invention.

In the drawings, identical or similar components or Identify elements with the same reference numbers.

Fig. 1 shows a vertical section through an assembly ger ger in a plane parallel to a circuit board 7th The hous se 1 comprises a divided into separate sections Frontplat te 2 , a rear wall 4 and side plates 3 , which are interconnected via aluminum extrusions 5 .

Between a front and a rear extrusion profile 5 , which are used as mounting strips, an upper mounting unit 10 and a lower mounting unit 10 'are fixed. Each of the mounting units 10 , 10 'has an, an insertion space 6 within the housing 1 facing inner wall 11 , 11 ', an outer wall 12 , 12 'and a front and a rear wall 13 , 13 ' and 14 , 14 ', which connect the inner wall and the outer wall. The box-shaped body thus formed delimits a ventilation duct 16 , 16 '.

The assembly unit 10 , 10 'is bent from sheet metal, the end edges of the sheet being bent vertically inwards to form a flange 15 , 15 '.

The flanges 15 , 15 'are provided with holes through which connector strips 8 can be fastened by means of fastening screws 35 .

The inner walls 11 , 11 'of the mounting unit 10 , 10 ' are provided at regular intervals with recesses 18 , 18 ', which serve to receive retaining hooks 34 , which are attached to receiving devices 17 , 17 ', which are used as guide rails for inserting Plug-in modules 7 serve. The area, which cher from such a guide rail 17 , 17 'on an inner wall 11 , 11 ' is covered, is designated in Fig. 2 with the reference number 19 .

Furthermore, in the inner wall 11 , 11 'ventilation openings 20 are provided at regular intervals, which cut the areas 19 and the recesses 18 , 18 ' are assigned.

At an edge area of the inner wall 11 , 11 ', a connection opening 26 , 26 ' is provided which has a larger cross section than the ventilation openings 20th

In the example just described with reference to FIGS . 1 and 2, the lower channel 16 'is struck with compressed air, which can flow through the ventilation openings 20 upwards along the plug-in module 7 , in order to absorb heat from the components of the plug-in module. The heated air passes through the ventilation opening 20 of the upper assembly unit 10 in the upper ventilation duct 16 and is guided from there. This can be done in that the upper channel 16 opens into the outside environment, while fresh air is introduced from the outside into the lower channel 16 '. The air flow can be generated by convection or by a fan.

Those ventilation openings 20 that are not required are preferably closed, for. B. by correspondingly shaped plastic parts. If one wants to produce a particularly strong court ended air flow, which increases the cooling effect, so eig net to an air guiding device 21, shown half in perspective in Fig. 3. Such Luftleiteinrich device 21 comprises a nozzle body 22 , the unit 10 is held in a snap fit via a holding piece 25 in a ventilation opening 20 of an inner wall 11 of a Monta. The holding piece 25 has a metering flap 23 which is articulated via a film hinge 24 , so that when there is an overpressure in the associated ventilation duct 16 , 16 '(in Fig. 3 below the inner wall 11 ) the flap 23 is pivoted upwards until the Ela tical restoring force of the film hinge 24 corresponds to the force generated by the pressure on the metering flap 23 . Since the air flow flowing over the plug-in module is set to a value which is essentially determined by the dimensioning of the metering flap 23 and its film hinge 24 . This means that when the space between two plug-in modules, in which the air guiding device 21 opens, opposes the air flow with a high resistance, the associated metering flap 23 opens further than where there is a lower resistance to the air flow. This enables a uniform cooling effect regardless of the individual construction of a slide-in module.

In the embodiment of the invention shown in FIGS . 4 and 5, the housing 1 comprises, in addition to the aforementioned components, an upper and a lower cover 9 , 9 'as well as additional mounting strips 5 , 5 '. The assembly units 10 are formed in this embodiment of the invention by Z-shaped sheets, which thus have only an inner wall 11 , 11 ', a front wall 13 , 13 ' and a (rear) flange 15 , 15 '. The flanges 15 , 15 'are at the same time with the connector strips 8 by means of the fastening screws 35 on strips holder 28 which are attached to the mounting strips 5 '. The ventilation ducts 16 , 16 'are thus delimited by the assembly units 10 , 10 ' and the covers 9 , 9 '.

The connection openings 26 , 26 'of the mounting units 10 , 10 ' stand hen with the suction or the pressure opening of a Luftumwälzein device 27 in connection, which group 7 is inserted into the housing 1 similar to a slide-in module. The Luftumwälzein device 27 has a blower 30 which sucks air from the upper ventilation duct 16 and presses into the lower ventilation duct 16 '. The air flow is illustrated by arrows in Fig. 5.

The heat is released in this embodiment of the inven tion on the cover 9 , 9 'to the environment, so that the whole system is closed. Of course, it is possible to design the air circulation device 27 such that the air flowing out of the channel 16 reaches the outside (into the environment) and fresh air from the environment is blown through the fan 30 into the ventilation channel 16 '.

In another embodiment of the invention shown in FIG. 6, the air circulation device 27 is equipped with such a heat exchanger 29 . In the exemplary embodiment shown in FIG. 6, air guiding devices 21 are also provided.

In a further embodiment of the invention, which is shown in FIGS. 7 and 8, the Anschlussöff openings 26 , 26 'are not within the slot 6 but behind the power strips 8 or a mut terplanatine provided there. The air circulation device 27 is consequently arranged in the rear housing part. In the embodiment of the invention shown in FIGS . 7 and 8, the air circulation device 27 operates according to the convection principle and comprises inner cooling fins 31 , which are separated by a cooling channel 33 from outer cooling fins 32 . Outside air is conveyed through the cooling duct 33 by means of a fan 30 . Characterized in that the inner fins 31 are kept essentially at the ambient temperature, that is, cooler than the air in the upper cooling channel 16 (this has already absorbed heat from the modules), the air and heat output to the cooling fins 31 drops down and passes into the lower cooling channel 16 'and from there up again, past the slide-in modules 7 , into the upper cooling channel 16 . The construction of the heat exchanger 29 thus formed enables the heat exchanger to be manufactured as an extruded profile. Of course, a blower for conveying the air from the ventilation duct 16 into the ventilation duct 16 'can also be provided here. In any case, the housing 1 is hermetically sealed so that neither interference (pollution, Störsigna le) from the outside to the inside nor those from the inside to the outside can last long.

The further embodiment of the invention shown in FIG. 9 differs from that according to FIGS. 7 and 8 essentially in that, on the one hand, a blower 30 for conveying the air between the ventilation ducts 16 , 16 'is provided, on the other hand, that the outer wall 12 of the upper Montageein unit 10 is corrugated so that it has an enlarged surface. Warm air, which flows through the upper ventilation duct 16 , can thus very effectively give off heat to the surrounding area through the outer wall 12 with its enlarged surface, so that the effect of the heat exchanger 29 (shown only schematically in FIG. 9) of the air circulation device 27 is amplified or the heat exchanger 29 may be omitted entirely. Of course, it is possible to apply this design principle of direct heat emission from a cooling channel by forming its outer wall 12 with a ver enlarged surface even in the previously shown embodiments of the invention.

Reference symbol list

1 housing
2 front panels
3 side plate
4 rear wall
5 mounting rails
6 slot
7 slide-in module
8 power strip
9, 9 ′ cover
10, 10 ' assembly unit
11, 11 ' inner wall
12, 12 ′ outer wall
13, 13 ′ front wall
14, 14 ' rear wall
15, 15 ' flange
16, 16 ′ ventilation duct
17, 17 ′ receiving device (guide rail)
18, 18 ' recess
19 surface section
20 ventilation opening
21 air guiding device
22 nozzle body
23 dosing cap
24 film hinge
25 holding piece
26, 26 ' connection opening
27 Air circulation device
28 last holder
29 heat exchangers
30 blowers
31 inner cooling fin
32 outer cooling fin
33 cooling channel
34 holding hooks
35 fastening screw

Claims (12)

1. Mounting unit for subracks, slide-in housings or similar housings, in particular for 19 '' housings, for accommodating electronic assemblies, including circuit boards, cassettes or similar plug-in assemblies, with holding devices for direct or indirect guidance and holding of the plug-in assemblies which are in a plug-in space in The housing can be inserted, characterized in that the assembly unit ( 10 , 10 ′) is flat and is arranged so as to extend above and / or below the insertion space ( 6 ) in such a way that the assembly unit ( 10 , 10 ′) has at least one wall ( 11- 14 ; 11 '- 14 ') of a ventilation duct ( 16 , 16 ') bil det, and that in the mounting unit ( 10 , 10 ') outside the sections ( 19 ) of the receiving devices ( 17 , 17 ') which can be covered ( 19 ) ventilation openings ( 20 ) are provided, which connect the ventilation duct ( 16 , 16 ') with the slide-in space ( 6 ) in areas which the slide-in size ppen ( 7 ) are assigned to their ventilation. 2. Assembly unit according to claim 1, characterized in that the assembly unit ( 10 , 10 ') is designed as a sheet metal part. 3. Mounting unit according to one of the preceding claims, characterized in that the mounting unit ( 10 , 10 ') fastening devices ( 15 , 15 ') for fastening connector strips ( 8 ). 4. Assembly unit according to claim 3, characterized in that the fastening devices are formed as flanges ( 15 , 15 '), which project into the insertion space ( 6 ) projecting ge curved edge regions of the sheet metal part. 5. Mounting unit according to one of the preceding claims, characterized in that in the ventilation openings ( 20 ) sealing devices for closing the ventilation openings ( 20 ) or Luftleiteinrich lines ( 21 ) can be used. 6. Mounting unit according to claim 5, characterized in that the air guiding devices ( 21 ) have means ( 23 , 24 ) for maintaining constant or equalizing the ventilation flow or pressure. 7. Mounting unit according to one of the preceding claims, characterized in that the mounting unit ( 10 , 10 ') has a plurality of Einrichtun gene (recesses 18, 18' ) at standardized intervals, via which guide rails ( 17 , 17 ') as a recording device gene with the mounting unit ( 10 , 10 ') can be connected. 8. Mounting unit according to one of the preceding claims, characterized in that the mounting unit ( 10 , 10 ') has a connection opening ( 26 ) for the suction or pressure-side connection of an air circulation device ( 27 ). 9. Mounting unit according to claim 8, characterized in that the connection opening ( 26 ) is designed and arranged such that the air circulation device ( 27 ) can be formed as a plug-in unit which, like a plug-in module ( 6 ), can be inserted into the housing ( 1 ) ( Fig. 5). 10. Mounting unit according to claim 8, characterized in that the connection opening ( 26 ) is designed and arranged such that the air circulation device ( 27 ) at least partially inside the housing ( 1 ) but outside the insertion space ( 6 ) can be installed ( Fig. 7, 8th). 11. Mounting unit according to one of claims 8 to 10, characterized in that the air circulation device ( 27 ) comprises a heat exchanger ( 29 ) which receives heat from the circulated air in the insertion space ( 6 ) and releases it to the environment. 12. Mounting unit according to one of the preceding claims, characterized in that the mounting unit ( 10 , 10 ') has an outer wall ( 12 ) with a cool rib-like enlarged surface such that heat from an air flow in the ventilation duct ( 16 ) can be dissipated to the ambient air ( Fig. 9).