DE19812479C1 - Personal computer housing - Google Patents

Abstract

The housing, to hold electronic component groups and motor-driven assemblies, has a strip (30) with a high oscillation damping action between the fixed plate (20) or component groups and the fixed plate cage (10) or mounting. Mounting units (10,13,15) grip in the fixed plate(s) (20) or holder system, and they are supported by oscillation dampers as hard rubber discs. The damping strip (30) has good thermal conductivity as an insulation treated with silicon rubber. The housing cover is cladded at least partially with acoustic damping materials using a layer of bitumen, a foam layer and a polyurethane layer.

Description

The invention relates to a housing for receiving electronic assemblies and motor-driven units gate with one or more holder (s) in which one or more Other hard drive (s) or other structure, each with a drive motor group (s) is or are and a Housing for accommodating electronic assemblies and motor-driven units gate with one or more holder (s) in which one or more Other hard drive (s) or other structure, each with a drive motor group (s) with the interposition of a vibration-damping intermediate layer is or are.

A so-called. Is usually used to operate a personal computer, for example named computer, in which a hard drive, an arithmetic unit, a floppy disk as well as other aggregates in a cuboid lying or standing Housing are housed. In such a housing there are usually fans built-in, which contained during the computer operation to cool the in the housing electronic and mechanical assemblies an air flow in the housing keep right.

From the computer end users, the noise level is such Computer often felt uncomfortable. As far as this is from the If there are noises coming from fans, they are in a medium frequency range rich and therefore subjectively appear to be less disruptive than the one set apart from the computer radiated high-frequency sound and the changing resulting from mixing Noises (beats). The high-frequency sound, the frequency of which varies up to 16 kHz can extend mainly from the drive motor for the built-in Hard disk from which at very high speed from the drive motor is driven. Although from the housing and through cooling air flow openings radiated high-frequency sound has only a relatively low amplitude, it disturbs because of its constant presence, and even more so when in a room  (e.g. open-plan office) several computers with corresponding sound radiation in one sentence are. There is a constant high whistle or trill in this room, which maintains the health and labor of those working in the room impaired.

From the perspective of computer manufacturers, however, a lot is developing more serious problem. PCs and workstations are caused by the star competition have fallen sharply in price and now belong to mass production cater. On the other hand, the warranty periods are due to the competition rose sharply. 36 months warranty is at least with the big ones Providers now common worldwide. Due to the rapid technical progress with regard to constantly increasing computer performance, the purchase price of a Com falls puters within a very short time, well before the warranty expires. This leads to manufacturers and suppliers still bearing the warranty risk, although the goods are now largely worthless. Main causes of a Ge warranty cases are usually the components in the computer, which are mechanical moving or driven parts included. As a rule, these are Disk drives, keyboards and mice etc., which by the most diverse Can wear loads more or less quickly. The failure of the masses memory, the hard disk, leads both the user and the manufacturer ler / suppliers on the greatest individual damage. Modern hard drives are sensitive against impact and partly - due to high absorption power - also against overheating. Even small impacts can lead to a plat collision. Such impacts on a common assembled computers are undetectable for the manufacturer or supplier in the event of such defects automatically lead to a warranty obligation.

The state of the art already offers a wealth of individual or even combined solutions for soundproofing computer housings, cooling vibrating assemblies and shock absorption for sensitive assemblies. The following publications are assumed to be known as the state of the art:
DE-GM 297 04 870, DE-OS 38 23 656, DE-GM 296 02 346, DE-OS 43 14 199, US-PS 5 192 143, US-PS 5 510 954, US-PS 5 596 483, US -PS 5,287,244, U.S. Patent 5,214,549, U.S. Patent 5,668,697, U.S. Patent 5,654,875.

DE-GM 297 04 870 is largely decoupled from structure-borne noise Suspension of a hard disk in O-rings made of rubber-elastic material and out clothing of the inside of the housing with cork / rubber mats. The disadvantage here with that, depending on the type of hard drive, complicated settings of the suspensions must be taken. It is also questionable whether the assembly is slipping can really be prevented in all cases during transport. This suspension contradicts the express manufacturer regulations for the stable installation of Hard drives. A hard drive held in a 5 1/2 inch mounting frame sits immediately telbar behind the computer front in standard housings. So there must always be a front flap must be closed in order to reduce the noise completely. One in a 5 1/2 Inch mounting bracket-mounted hard drive can only be used with a fan from below or be cooled from the side with a very small fan. A ventilation of below is in many cases not sufficient. The hard drive manufacturers write in the Rule before that for safe cooling, an air flow over both the top and the underside must also be maintained. As for the hard drive no more passive cooling is provided, a fan failure in many hard drives Cause overheating. This is particularly fatal if a computer is left unattended works and does not immediately respond to a system message about a fan failure  becomes. Even if a fan failure detection system automatically shuts down drives, this is synonymous with a system fault, which for another Operation must be remedied immediately. Furthermore, the use of Cork / rubber does not meet the UL regulations for fire protection in electrical devices.

In DE-OS 43 14 199 a device for heat dissipation of vibration damped assemblies described, which are in a closed housing are located. It is questionable whether the cooling method described there is sufficient to feast plates with a power loss of up to 20 W through exclusively conductive Sufficiently good heat dissipation. Calculator are with a Be drive temperature of 35 ° C for medium latitudes and 40 ° C for the warmer regions. The hard drives available in the mass market, however only offered with a maximum permissible surface temperature of 55-60 ° C The surface temperatures specified for maximum service life are however usually 10-15 ° C below the maximum permissible temperature. This be indicates that very effective cooling is provided for long life got to. The method described here is due to the assembly costs for the mass market unusable anyway. Furthermore, hard disks are allowed for reasons of Manufacturer's warranty cannot be changed mechanically. An effective warmth Transition using braided copper wire can only be done by soldering or welding to the hard disk.

Shock absorbers for hard drives are described in US Pat. No. 5,192,143. It is not recognizable whether these shock absorbers also effectively reduce noise. Furthermore, it is doubted whether these shock absorbers are sufficient, a hard disk in front of you Sufficient protection of 30 g shock on the housing during operation. 30 g puffs arise when a computer is started with a vacuum cleaner. about This publication does not reveal anything about cooling the hard disk.

The best known prior art to date is disclosed in U.S. Patents 5,510,945 and 5,596,483. The noise reduction achieved there remains unmatched. However, it is disadvantageous that the hard disk is hermetically encapsulated and therefore not one Offers the possibility of active or passive direct air cooling. Here is the The hard disk can only be cooled by heat dissipation. The requ The air discharge on the computer deck does not correspond to any housing standard. Of the guided airflow is too dependent on the modules used and already warmed up when it reaches the heat sink described there. There is none redundant cooling. Two or even more slowly rotating fans and one Air flow in the power pack caused by convection is only sufficient for one Calculator with poorly performing components. Encapsulating the hard drive restricts cooling in such a way that this method works for powerful hard drives is not applicable. The cool bag described there, filled with liquid, is by means of a wide flat metal clan on the upper and lower side of the festival plate pressed to achieve good heat transfer. The bottom of one Hard disk, no matter what type, usually contains a circuit board with sharp edges SMD components and connector pins. It cannot be ruled out here that the Effectiveness of this cooling by tearing the cool bag during manufacture or is at risk during transport or operation. Furthermore, the assembly and De appears mounting a hard drive here is complex.

From the current state of knowledge of technology, no concept is recognizable The following criteria were also satisfactorily met: 1) For the subjective Perception of adequate noise reduction. 2) For the narrow temperature spec of a hard disk, even with the most powerful hard disks, sufficient  Cooling for a long service life. 3) For the shock sensitivity of the hard disk adequate protection against the possible in a typical work environment chen bumps. 4) A solution to the needs described above lowest use of material and assembly costs. Most of all is from the previous one Based on the level of knowledge, no uniform concept can be identified, which applies to both Noise reduction as well as a modular gradual expansion for cooling tion for the large number of hard drives available on the market, each with different Chen noise and temperature developments.

The hard drive is considered the main cause of the emergence of the subjectively uncomfortable Considered noise development. At the current state of hard disk technology this is due to the fact that a hard disk is four independent of each other has common sources of noise. For the high frequencies there are the bearings responsible for the drive and the medium and secondly the drive generated alternating magnetic fields. The low and also high-energy vibrations due to the manufacturing-related unbalance tolerances of the medium on the one hand and the acceleration and braking forces of the read / write head on the other generated. Due to the worldwide regulated limits for HF radiation from electronic devices, the use of metal housings for computers remains un essential for effective EMC. With a conventional metal-on-metal assembly of the Hard drives in the housing inevitably lead to an increased radiation of Noise over the metal surfaces.

In addition, especially the high-energy low vibrations then cause according to the design of the housing uncontrolled different excitations of the sheets in the various harmonic resonances of the fundamental frequency.

The invention is therefore based on the object on housings of the above explained types of measures to provide the subjectively unpleasant sound Suppress radiation as much as possible and at the same time the hard disk Protect common bumps on the housing taking into account the manufacturer's installation to provide regulations for hard drives and at the same time effective cooling measures, which is a thermal self-destruction of the hard disk if the hard disk fails prevent ventilation without disrupting the ongoing operation of the computer. Furthermore should the measures to be taken are gradually modular with a uniform concept be designed to be expandable, so that depending on the different performance classes because only the appropriate measures have to be implemented. Furthermore The design of the housing should enable them to be mass-produced both with regard to the use of materials and the required assembly steps are inexpensive. In connection with the mo The modular concept is intended to optimize costs for a range of computers models can be achieved from one production.

The following solutions to this task and the special Aus Leading examples were constructive and thus geometrical for a tower com puter case developed. However, it is understood that use in Desktop cases or other alternative cases basically also is possible by the geometry and arrangement of the functional elements used elements can be adapted accordingly.

The basic principle according to the invention for reducing the sound emission is used, the decoupling of structure-borne noise is built into the computer ten, constantly motor-driven assemblies relevant for noise development  from the common chassis. This effectively cools the hard disk combined heat dissipation and active and passive air cooling are used.

According to the invention the object is achieved by the in the independent claims 1 and 23 described objects solved.

The hard disk is held according to claim 1 in a hard disk holder, which on the front ren side of the hard drive bracket has a rigid support plate, for example with rivets provided on the hard drive bracket is consolidated and thus forms a mechanical unit with the bracket. This unity is preferably in the configuration described below to the Front plate of the chassis mounted. However, it is also any other suitable holder conceivable in the housing. The front panel is preferably as rigid as possible or - for example by a reinforcement provided in the mounting area plate - additionally stiffened. The fastening engaging in the carrier plate elements such as fastening screws or the like are supported by a rigid fastening plate on the outside of the front panel. Between the carrier plate of the Hard drive bracket and the inside of the front panel is a carrier plate ten vibration damper made of a semi-elastic material and between the Be mounting plate and the outside of the front plate is made of the same mate rial a mounting plate vibration damper. The semi-elastic material is procure so that it is considerably more elastic than the front panel but still ge sufficient load capacity for the hard disk holder with the hard disk held in it having. Furthermore, the mounting edges of the hard drive bracket serve as an end blow for the fastening elements engaging in the carrier plate. So is an adjustment of the fasteners is not necessary. At the same time the Entire layer structure, consisting of carrier plate, stiffened front plate, fastening plate and the two vibration dampers with the fastening elements matched so that the two vibration dampers under slight bias are when the, engaging in the support plate, fasteners on blow. The fasteners apply due to the pre-tensioned dampers supply elements then conditionally connected to the mounting plate. Consequently within the framework of the vibrational forces occurring here, a permanent, relatively rigid connection between the carrier plate and the mounting plate. The stiff Design of the two disks causes that generated by the hard disk Vibrations are essentially only introduced vertically into the damper. Furthermore, the fastenings are always the carrying or Holding layer between the two dampers insulated and vertical to the damper level movable or spaced.

The above-mentioned stiffening of the front plate by means of a stiffening plate in the mounting area of the hard drive bracket, especially in the masses manufacturing can alternatively be achieved in that the mounting surface or  appropriate bracket in the housing by striving deep embossing in the sheet receives the required rigidity. The support and attachment discussed above alternatively, plates can take on any other geometric shape, which the task of an indirect flat contact to the damper surfaces fulfill. The surface contact is not necessarily plane-parallel. The dampers are too not necessarily to be designed with plane-parallel or regular surfaces.

With a symmetrical configuration of the damper layers explained above it is a low-pass filter with frequency-independent positive feedback at the front plate between the two dampers. Coupling is due to the fact that two am same-frequency, equal-frequency vibrations, phase-shifted by 180 ° hit the front panel in the opposite direction vector. At medium or Even high frequencies play a subordinate role because the Damping factor of this deep-feeding system is high. Due to the large area The damper is designed using a very soft damper material sufficient load capacity possible. The rigid design of the straps and fasteners plate cause a strong distribution of the vertical vibration energy over the area of the damper. Has such a damping system even at low frequencies, a sufficient damping factor even under Coupling condition. The deepest and most energetic frequencies in a festival plates are generated by the read / write head. Each type of hard drive has its own, characteristic head swing behavior. This can be extremely effective The above-described damper system dampens the head vibration when the Layer thickness of the carrier plate vibration damper and the layer thickness of the Mounting plate vibration damper in their relationship to each other are tuned that the damped at the typical head vibration frequency Vibrations of both dampers in phase with opposite Hit the direction vector on the bracket area of the front panel. Under these Conditions then find a negative feedback on the front panel Damper system instead. This frequency-dependent negative feedback condition causes according to the invention almost (the different dampers required layers cause an amplitude difference) complete self-extinction the vibration on the front panel. This means that two are in phase Vibrations in the opposite direction hit the front panel and thus the front panel almost stops moving. Another requirement for the negative feedback condition, the choice of a damper material is included extremely low speed of propagation of vibrations (considerably lower than in e.g. air) in order to use the dimensions of the Damper to be able to influence the phase in the region of a half wave. Due to the quasi rigid connection between the carrier plate and the mounting plate, it is ensured that the necessary phase condition is always maintained is retained (phase shift lock). Thus the vibration energy effectively dampened against the stiffened front panel and thus against the chassis. At the same time, the self-oscillation of the hard disk or the holder is too negligible minimum reduced, although the hard drive relative to the case is mounted softly. This complies with the installation instructions for hard drives. A The hard disk must be installed in such a way that natural vibration is avoided, to prevent correction positions of the read / write heads, which a Loss of hard drive performance mean.

In a further embodiment of the invention, what has been explained above is obtained Steamer system a device for quick and easy adjustment of the for the Negative feedback required push-pull condition. Between mounting plate and mounting plates vibration damper a tuning plate is inserted.  

The tuning plate is guided by means of the fastening elements. In the middle of the Outside of the mounting plate is e.g. B. a threaded approach with a Tapped hole for a screw. From the outside can now with an appropriate Screw regulates the distance between the tuning plate and mounting plate become. The preload of the two dampers can thus be increased and thus also their layer thicknesses can be varied to a limited extent. So if the damper These are roughly dimensioned to a correct ratio direction fine-tuning to optimize the phase condition. This knows tere design is only necessary for the highest demands. In practice it has proved to be a very good noise reduction even with rough settings is achievable.

It can be advantageous if the two dampers to further refine their Damping characteristics made of different materials or the Damper constructed from several layers with different properties become. In order to be frequency-independent with push-pull damping in the vertical direction to become gig, a construction can also be expedient, which carrier plate and connecting plate crosswise or force redirecting and thus from in the front, both plates always only perform opposite movements. Like this with a symmetrical design of the damper would be a Ge at any frequency gene coupling of the vertically acting vibrations. The necessary for this However, the construction is comparatively expensive to use. As part of the This invention has been shown that the simple variant of the above explained time completely sufficient and also very inexpensive in mass production is.

As part of a further embodiment of the invention, Vibration damper and ent in the mounting plate vibration damper holes or openings should be left out according to the load distribution. This Measure causes a different mass distribution of the damper mass such that even with non-adjustable fasteners the hard disk unit maintains a right-angled fit to the front panel after installation. Here is the Ela Stity of the damper and thus the load capacity to choose so that in the Rah Different payloads required by the inventions made no difference Compensations become necessary. Thus, in mass production for all assembly variants require only one design of the plate damper.

Due to the described embodiment of the invention is corresponding Di dimensioning of the damper layer thickness is now also an extremely effective one Dampening of the hard disk against impacts on the case. By already he refined type of suspension forms a pivot bearing for the front panel Hard drive bracket between the two push-pull dampers both in horizontal as well as in the vertical direction. Due to the design of the damper surfaces and the position of the suspension points of those engaging the support plate Fasteners the shock absorbing effect is controlled so that in vertical direction to the hard disk more degrees of freedom arise than in ho horizontal direction. This results in a stronger shock absorption in the vertical direction than in the horizontal direction. The shock sensitivity of a hard drive is always greatest in the vertical direction to the medium, since the read / write heads ex Move extremely close over the medium.

The inexpensive damper system according to the invention thus causes both a Ge Noise reduction in the computer as well as an extremely effective shock absorber to protect the hard drive that is sensitive to impact.  

The hard drive bracket can be designed differently depending on the requirements and can be used to hold additional compos in addition to a hard drive serve as described below. Depending on the design of the hard drive and according to the type and scope of additional ge on or in the hard drive bracket held components and depending on the nature of the hard drive bracket factory high-frequency vibrations emanating from the hard disk by resonating with the bracket or the other components or their Combinations lead to an amplification of the high-frequency noise. In sol Chen cases according to the invention by a further embodiment of the invention between the hard drive and the hard drive bracket an anti-vibration Intermediate layer, which is high for high-frequency vibrations Has damping, with fasteners engaging in the hard disk itself support the hard disk holder over vibration-isolating documents. There with one of the hard drive bracket and the other connected to it Components outgoing high-frequency sound so strongly attenuated that in operation the usual high-pitched whistle is hardly noticeable on the computer.

Again, it is advantageous if hard drive, vibration-damping intermediate layer and hard drive bracket are in extensive contact to the swin Distribution of energy well over the surfaces in order to achieve a maximum yield to achieve the cushioning effect. Hartgum is the main material Mixing discs into consideration, on which washers, for example made of metal are brought. For a better distribution of the contact pressure, into the hard disk gripping fastenings, on the side walls of the bracket, has been under the Invention a summary of the documents on a flat component as proven advantageous. The individual hard rubber discs now form for each Hard disk side a rectangular elongated rubber part with several, in particular Case z. B. three through openings and a correspondingly shaped metal piece with three through openings. This construction will follow referred to as the torque distributor bridge. The torque distributor bridge is procure such that they the respective tightening forces of the fasteners evenly distributed over the hard rubber pad on the bracket side wall. in the Within the scope of the invention, a 4 mm thick steel sheet has proven to be expedient sen. With other designs such as a U-profile made of thinner Sheet metal can have the same effect. This is the assembly almost completely isolated from the hard disk bracket with regard to structure-borne noise. Thus, on the one hand, the radiation surface for high-frequency vibrations on the Hard disk surface limited and on the other hand there is an additional damper fung. The fact that the contact surface is the fixed is particularly advantageous plate to the surrounding air medium on the minimum of the hard disk surface is induced.

With the measures explained above and the apparent from the drawings Chen arrangement of the modules, with the help of the support plate and the order Hard drive lying bay, which is represented by the hard drive bracket and the over lying cage is formed by the hard drive to the surrounding air emitted, high-frequency sound, away from the front of the housing towards the Ge back of the house reflected. If necessary, the inside of the housing cover and the bottom plate of the chassis at least partially with a flame retardant layered material to be further lined up with the noise to mitigate. With this third measure, the maximum in noise reduction tion achieved in the context of the invention.  

The housing according to claim 23 solves the problem by that the vibration damping liner additionally has good thermal conductivity that the intermediate layer from a is made of elastically deformable material that the intermediate layer at least ever because it has extensive contact with two side walls of the holder, that at least parts of the surfaces of the bracket prevailing in the housing Air circulation are exposed, and that the bracket (s) from a good heat tendency material is or are. The biggest heat sources in the festival are made by the drive for the hard disk medium and the servo Read / write heads formed. These are usually fixed with a die-cast part connected, which forms the hard disk body. The best possible heat tap takes place on the two long sides of the hard drive body, which is also for fastening serve and - to a limited extent - still on the back. Because the long sides However, the hard drives usually have bumps, it is fiction moderately required to design the attachment so that the bracket side walls with sufficient contact pressure, the vibration-damping heat conduction between presses against the long sides of the hard drive to ensure the best possible surface contact to manufacture hard disk. This fact is favored by the fact that the same Measure, in the high-frequency vibration damping explained above, is also required and therefore no constructive contradiction to the combination both measures exist. It has been found in the context of this invention that that a vibration damping liner with good thermal conductivity of a thickness of about 0.45 mm is sufficient to sufficiently dampen the Compensate for unevenness by appropriate contact pressure and a high one To produce heat dissipation to the hard drive bracket. Preferably comes in Within the scope of this invention, an aluminum material for the hard disk holder for use. The aluminum hard drive bracket forms with the good thermal Connection to the hard disk a significant increase in the hard disk surface. In if it has a hard drive bracket made of aluminum in addition to the bracket also function as a heat sink. Unless the hard drive stops tion is at least partially in the airflow of the case fan, is sufficient this passive cooling for small and medium performance hard drives in many Cases.

In the context of this invention, it is appropriate for the vibration damping Intermediate layer to use a tape material made of silicone rubberized insulating material the. However, other processing options are possible in mass production bar. However, it is also conceivable for the silicone material to be screen printed vulcanized directly onto the mounting plate (before folding). Further is a coating on the long sides of the hard disk is conceivable. In this respect, the Sili hereinafter also generally referred to as intermediate layer.

In the context of a further embodiment of the invention, the cooling capacity can be can now be gradually expanded as required. According to a preferred embodiment the invention are to increase the cooling capacity, cooling fins or heat sinks attached to an outer hard drive bracket wall. These cooling elements protrude expediently at least partially into, from or of the main housing fan (s) generated airflow. Preferably, in the context of this invention, the cooling ribs mounted on the bottom plate of the hard drive bracket. Thus, that of heat dissipated directly from the two bracket side walls be reached in the heat sink when reaching the bottom plate. Even hard drives are brackets made of copper or other heat-conducting materials conceivable here. In the context of this invention has proven to be advantageous  Heatsink in metallic system fixed with the hard drive bracket via Ver to connect screw connections. The fastening element engaging in the heat sink elements are supported by a torque compensation plate on the inside of the Bracket base. With the appropriate tightening torque, the torque compensation plate the bracket base firmly to the heat sink. So there is hardly any heat transfer resistance between the hard drive bracket and Heat sink. Other connection techniques with good thermal transition the effect between the heat sink and the bracket is conceivable here. Can also Heat sink and bracket can also be made as an integral die-cast part. It is ever but to assume that the flexibility of a quick, geometric adjustment in ongoing production is advantageous.

As part of a further embodiment of the invention, an alternative to the above standing heat sinks (or) additionally have an increased cooling capacity by means of a fan attached to the bracket side wall. For this are on the bracket side wall above and below the hard drive, respectively a group of through openings is provided, which are taken together form a passage for the air flow generated by the fan. To the, of Fan generated, air flow completely through the groups of through openings to lead is a seal as a base between the side wall and Fan made use of. This is the manufacturer's regulations for ventilation fulfilled by means of an air flow above and below the hard disk. The in the Bracket side wall engaging fasteners for the fan support directly on the fan and are guided through holes in the seal. Appropriately thread or self-tapping Ge winds driven in. If the fasteners of the hard drive over a Support torque distribution bridge, the seal must at least at one point have a passage for the bridge. The group of through openings between hard drive and base plate has a greater distance between the Through openings to at least part of the passage at this point wise to allow heat dissipation. So there is a sufficient airflow generated above and below the hard drive. In the maximum expansion stage of the Cooling described above, the invention enables that even if the Hard disk fans are currently the strongest 1 inch hard drives, even with one Ambient temperature of 40 ° C does not exceed its maximum permissible temperature However, the fact that even the strongest feasts seem much more important plates with the cooling system intact up to the most extreme ambient temperatures still close to the temperature specified by the manufacturer for maxi male lifespan can be maintained. In this respect, a whole at this point made a decisive contribution to the life of the hard drives. Of course This cooling method is not just limited to 1 inch hard drives. This method is also possible through correspondingly expanded geometric configurations applicable for the 1.6 inch height hard drives available on the market.

To retrofit housings, kits can be created that have a fixed plate holder made of aluminum, possibly a heat sink, a swin cushioning liner with high damping against high-frequency body sound, a mounting plate vibration damper and a mounting plate Vibration damper with high damping against low-frequency structure-borne noise Fastening plate and, if necessary, vibration-damping documents together with have suitable fastening screws. Further refinements of the Erfin are specified in the subclaims.

The invention is based on exemplary embodiments and the accompanying Drawing described in detail below. Show it:

Figure 1 is a perspective view of a housing designed in the manner according to the invention after removal of the housing cover.

Fig. 2 is a sectional view of the hard drive unit from behind, consisting of fan, seal, hard drive bracket, carrier plate, hard drive, vibration-damping thermal interface, fastening elements of the hard drive, heat sink, fasteners of the heat sink, each with a cutting plane through the fastening elements of the heat sink and a cutting plane the middle fasteners of the hard drive;

Fig. 3 is a side view of the hard drive bracket without a fan, which is attached to the front panel with suitable push-pull dampers for low frequencies, the carrier plate, the carrier plate vibration damper, the stiffening plate, the mounting plate vibration damper, the mounting plate and a fastening screw on average are shown;

Fig. 4 is an internal perspective view of a housing cover with acoustic insulation;

Figs. 5 and 6 are each a schematic illustration of a hard rubber sheet as a vibration decoupling of the disk fixtures in the longitudinal central section and plan view;

Figures 7 and 8 each show a schematic representation of a torque distributor bridge as a base for the hard disk fastenings in the longitudinal center section or plan view.

Fig. 9 and 10 carrier plate vibration damper or mounting plate vibration damper with compensation holes in plan view;

11 is a sectional view through a tunable damping system as compared to Fig 3 in an enlarged scale..; and

FIGS. 12 and 13 are a top view and a sectional view corresponding to the sectional view of FIG. 3 of an alternative assembly in the assembly shown in FIGS . 2 and 3.

The block-shaped housing made of conventional sheet metal, designated in its entirety by 1 , has a framework 2 , on the front of which a front plate 3 with operating elements (not shown) and a base plate 4 are fastened. A main fan 5 is installed in the rear upper part of the housing 1 and blows the inside air out of the housing 1 through a power supply unit 53 and further through slots 7 in the rear wall 6 . The auxiliary fan 9 , which is attached in the lower part of the front plate 3 , sucks the outside air through slots, not shown, in the front plate 3 and blows it into the interior of the housing 1 . The arrangement of the main fan 5 and the additional fan 9 guides the cooling air flow approximately diagonally through the interior of the housing 1 . The cage 29 contains a floppy disk holder with a built-in floppy disk 45.

A in the case illustrated cage-like disk holder 10 consisting of a side wall 12 with a fixing edge 71, one of the side wall 12 gegenüberlie constricting side wall 14 with a fixing edge 73, a bottom plate 16 with Fixed To supply ridge 72, by, engaging in the mounting edge 71, rivets 22, 24 , by the, engaging in the fastening edge 73 , rivets 26 , 28 and the, engaging in the fastening edge 72 , not shown rivets, plate 50 fastened to the carrier. A hard disk 20 is held between the two side walls 12 and 14 by means of screws 11 , 13 , 15 , 17 , 19 , 21 in the hard disk holder 10 . The hard disk 20 includes, among other things, a drive, not shown, which drives the storage medium at the usual high speeds and a servo, not shown, which drives the read / write head.

The unit explained above, consisting of a hard disk holder 10 with a carrier plate 50 and the hard disk 20 mounted therein, is - as can be seen in particular in FIG. 3 - with a stiffening plate 52 on the front plate 3 with BEFE that between the carrier plate 50 and the front plate 3 with stiffening plate 52, a carrier plate vibration damper 51 is arranged. The surface of the carrier plate vibration damper 51 extends substantially over the entire surface of the carrier plate 50 and separates this structure-borne noise from the front plate 3 with stiffening plate 52. The engaging in the carrier plate 50 , designed as screws fasteners 23 , 25 and 27 for mounting the unit he explained above, are supported by a mounting plate 55 and a mounting plate vibration damper 74 arranged between the mounting plate 55 and the front plate 3 on the outside of the front plate 3 . The surface of the mounting plate vibration damper 74 extends substantially over the entire surface of the mounting plate 55 and separates this structure-borne noise from the front plate 3. The fasteners 23 , 25 , 27 are isolated from the front plate 3 and stiffening plate 52 and well movable.

The carrier plate vibration damper 51 has a layer thickness of approximately 16 mm and the mounting plate vibration damper 74 has a layer thickness of approximately 8 mm. Both dampers 51 and 74 are made of an identical semi-elastic, soft material. Both dampers 51 and 74 thus have excellent damping properties in the lower frequency range. The, engage in the carrier plate, the fastening elements (fastening screws) 23 , 25 and 27 hold both dampers 51 and 74 under slight prestress if they have the position of the stop position. The mounting edges 71 , 72 and 73 of the hard disk bracket 10 bil the stop for the fasteners 23 , 25 and 27. Thus, there is a quasi-rigid connection between the carrier plate 50 and mounting plate 55 generated by the above-mentioned bias by means of the fasteners 23 , 25 and 27th . the dimensioning of the two dampers 51 and 74 are the front panel 3 attenuated with stiffening plate 52 now, vibrations generated by the hard disk 20, the low-gen well ge. On the front panel 3 only one of the damped vibration of the mounting plate vibration damper 74 and the carrier plate vibration damper 51 is formed residual vibration energy. Thus, the vibration energy passed on to the framework 2 and thus the entire housing 1 is reduced to a minimum. In particular, the natural vibrations of the hard disk 20 are thus reduced to a minimum.

In a further embodiment of the above-mentioned push-pull damping, the phase shift of the damper system, as shown in FIG. 11, is designed to be adjustable, which allows an optimization of the push-pull coupling explained above. A tuning plate 75 is inserted between mounting plate 55 and mounting plate vibration damper 74 . The tuning plate is guided through holes, not shown, on the shafts of the fastening elements 23 , 25 , 27 , not shown. In the geometric center of the mounting plate 55 be there is a hole, not shown in detail, with a threaded attachment 77. The engaging in the threaded attachment 77 , adjusting screw 76 passes through the mounting plate 55 and is supported on the tuning plate 75 . By turning the adjusting screw 76 , the tuning plate 75 can be pressed off the fastening plate 55 . This causes a change in the layer thickness of the mounting plate vibration damper 74 and the carrier plate vibration damper 51. Analogously, as shown in FIG. 12, the tuning plate 75 is arranged such that it can be adjusted outwards against the front plate 3 .

The above-described mounting arrangement of the hard disk holder 10 with the hard disk 20 held therein and further components to be explained below, consisting of carrier plate 50 , carrier plate vibration damper 51 , reinforcing plate 52 , front plate 3 , mounting plate vibration damper 74 and fasteners 23 , 25 and 27 , are conditional by the elasticity of the two dampers 51 and 74 , around the front plate 3 now also a pivot bearing with a small deflection angle in the vertical and horizontal directions to the housing 1. If the housing 1 is pushed from the outside, the two dampers 51 and 74 also act as shock absorbers to protect the hard disk 20 , since the hard disk holder 10 with the hard disk 20 held therein can perform a damped deflection movement both in the vertical and in the horizontal direction.

With a layer thickness of, for example, 16 mm for the mounting plate vibration damper 51 and a layer thickness of 8 mm for the mounting plate vibration damper 74, it has been shown that shocks in the vertical direction on the housing 1 are reduced by up to 90% or by a factor of 10 act on the hard disk 20 . Above all, the dangerous rising edges of braking acceleration are significantly reduced. This enables a total of somewhat more brake acceleration on the hard disk 20. A shock of 30 g on the housing 1 means a shock of about 3 g on the hard disk 20 with a greatly reduced rising edge of the brake acceleration. This measure is sufficient to effectively protect the hard disk 20 from typical bumps against the housing 1 that occur in everyday office life.

A rectangular seat, the hard disk unit described above, to permit relative to the front plate 3, the two damper compensation through-holes 31 are 51 and 74 according to Fig. 9 and Fig. 10 corresponding with the load distribution provided.

As can be seen in particular Fig. 2, between the hard disk 20 and the hard disk tenhalterung 10 is a wide vibration-damping intermediate layer 30 on all sides of the two hard drive long sides and back, not shown, ie along the two side walls 12 , 14 and along the carrier plate 50 , interposed. The width of the vibration-damping intermediate layer extends substantially over the entire height of the HDD 20 and causes in good surface contact with a damping of the disk 20 in the high frequency acoustic spectrum.

For structure-borne noise decoupling of the hard disk 20 from the hard disk holder 10 , the fastening screws 11 , 13 , 15 , 17 , 19 , 21 engaging in the hard disk are supported on the hard disk bracket 10 via the two torque distributor bridges 61 and 63 and between the torque distributor bridge 61 and the Side wall 12 attached vibration-isolating rubber pad 62 and between the torque distribution bridge 63 and the side wall 14 attached vibration-isolating rubber pad 64 . The surface of the two rubber pads 62 , 64 and the two torque distribution bridges 61 , 63 are each identical and are shown in detail in FIGS. 5, 6 and 7, 8. So the pad 62 is made of hard rubber. From the surface of the hard rubber pad 62, there are central projections 37 which wall 12, 14 protrude into bores, not shown, in the sides. The pad 62 is provided in the center of the lugs 37 with through holes 35 for the screws 11 , 13 , 15 , 17 , 19 and 21 . The mitti conditions approaches 37 prevent contact of the fastening screws 11 , 13 , 15 , 17 , 19 , 21 with the two side walls 12 , 14. If the fastening screws 11 , 13 , 15 , 17 , 19 , 21 are tightened, the two torque Distribution bridges 61 , 63 on the two hard rubber pads 62 , 64, the two side walls 12 , 14 and the vibration-damping intermediate layer 30 firmly and flatly on the two long sides, not shown, of the hard disk 20. Thus, the high-frequency acoustic vibrations of the hard disk 20 are damped with the intermediate layer 30 and decoupled from the hard disk holder 10 with the two hard rubber pads 62 , 64 . The damped high-frequency vibrations of the hard disk 20 can now only be emitted to the surrounding air medium in the housing 1 via the upper side 78 and the underside of the hard disk 20, not shown.

With the side walls 12 , 14 , the bottom plate 16 , the support plate 50 and the fig 29 with floppy drive 45 , a slot is formed around the hard disk with opening in the direction of the rear wall 6 of the housing 1. Thus, the remaining portion of the , High-frequency sound emitted to the air from the hard disk 20 is reflected away from the front plate 3 in the direction of the rear wall 6 . Now a further sound insulation can be achieved if the three-sided cover 8 of the housing 1 according to FIG. 4 is at least partially lined with sound-absorbing composite material panels 46 , 47 , 48 , 49 , each of which is composed of a layer of bitumen, a layer of foam and a polyurethane layer. Another Ver composite material plate 32 is applied to the base plate 4 according to FIG. 1.

Measurements in a low-reflection room with a sound-proof surface between the computer and the measuring microphone on the housing 1 including the cover 8 equipped according to the invention have shown that if the computer is equipped with 4 fans and a 1 inch height hard disk 20 of the Seagate Cheetah 5T34501W type (10,000 rpm ) at a distance of one meter in front of the not shown front panel of the closed housing 1, an operating noise without hard disk access of 36 dB (A) was recorded. When the hard disk 20 was permanently accessed, a level of 37 dB (A) was measured. Without additional fan 9 , an operating noise of only 32 dB (A) without hard disk access was recorded.

The above-mentioned, used as a vibration-damping intermediate layer 30 , 0.45 mm thick silicone rubberized insulating material also has good thermal conductivity properties, as is evident from its thermal conductivity of about 0.0021 cal / cm s ° C. Thus, the silicone rubberized insulating material causes not only excellent damping for high-frequency structure-borne noise, but also additional heat dissipation of the waste heat emanating from the hard disk 20 directly to the two side walls 12 , 14 of the hard disk holder 10 and also directly to the carrier plate 50. Thus, in addition to reduction the above-described acoustical surface of the hard disk 20 , at the same time the thermal surface of the hard disk 20 increases. If the hard disk holder 10 consists of an aluminum material and sits at least partially in the air flow of the case fans 5 and 9 , a hard disk 20 of lower power can already be effectively cooled passively. Thus, the hard disk holder 10 with its side walls 12 , 14 and its base plate 16 has the character of a heat sink.

To increase the measures for cooling a hard disk 20 , a heat sink 18 with several cooling fins is attached to the bottom plate 16 of the two mounting sides 12 , 14 with good heat-conducting properties. The, engaging in the heat sink 18 , fastening supply elements 56 , 57 and other, not shown, fasteners or a plurality of such fasteners, are supported by a torque distribution plate 70 on the inside of the base plate 16 and provide an effective contact force for effective Heat transfer between the bottom plate 16 and the heat sink 18. Thus, a main heat dissipation path is formed, the shortest route from the two, not shown, long sides of the hard plate 20 , via the thermal interface 30 , to the side walls 12 , 14 of the holding tion 10 and with the base plate 16 runs directly into the heat sink 18 . If necessary, a heat conductor 60 can be attached between the base plate 16 and the heat sink 18 . The heat conductor 60 can be made of any material suitable for this purpose. The cooling fins of the heat sink 18 are, as shown in particular in FIG. 1, at least partially in the diagonal cooling air flow of the case fans 5 and 9 with the mentioned inlet openings on the underside of the front plate 3 and the mentioned outlet slots 7 on the rear wall 6. The cooling body 18 carries significantly for heat dissipation and thus for cooling the hard disk 20 .

As an alternative to the heat sink 18 or in addition to further increasing the cooling power, a hard disk fan 40 is mounted on the side of the hard disk 20 on the side wall 12 . For this purpose, a corresponding passage is required on the side wall 12 in order to pass on the air drawn in by the fan 40 to the hard disk 20 . As shown in Fig. 3, there are a group of through openings 41 and 42 above and below the hard disk 20. Between the through openings of the group 42 are gaps 43 , which are still sufficient heat dissipation through the metal of the side wall 12 to the bottom plate Allow 16 at these points. Furthermore, drive threads 36 are provided on the side wall 12 for fastening the hard disk fan 40 . As can be seen in FIG. 2, the fan fastening elements 65 , 67 engaging in the driving thread 36 on the side wall 12 and further fastening elements (not shown) are supported directly on the fan. Between the fan 40 and the side wall 12 there is a seal 44 , which passes the air flow completely through the groups of holes 41 and 42 . The fastening elements 65 , 67 and further fastening elements, not shown, are guided through the seal 44 . If the hard disk 20 with torque distributing bridges 61 , 63 and corresponding documents 62 , 64 is attached, a corresponding passage, not shown, is required at least at one point on the seal 44 . In connection with the already mentioned slot around the hard disk 20 , an air flow is now maintained over the entire upper side 78 and underside of the hard disk 20, not shown. Since the fan 40 is the housing selüfter 9 and thus the air inlet, not shown, the hard disk 20 is effectively cooled with fresh air not preheated. On the Be tenwand 12 there is a thread 38 for receiving a possibly necessary, not shown, thermal sensor for controlling a temperature monitor or a vario fan.

An alternative possibility of vibration-damping mounting of the holder 10 in the housing 1 is illustrated in FIGS. 12 and 13.

As can be clearly seen in particular from FIG. 12, the hard disk holder 10 can also consist of a broad U-plate. The two legs of the U form the mounting side walls 12 and 14 and the web part of the U now forms a mounting plate 50 integrated in the mounting 10 with a sufficient distance from the rear side of the hard disk 20, not shown. The mounting plate 50 is here between the mounting plate vibration damper 51 and mounting plate vibration damper 74 supported. The mounting plate 55 now sits on the inside of the carrier plate 50 and is supported from there on the mounting plate vibration damper 74 on the back of the carrier plate 50 . The fastening elements 23 , 25 , 27 which now engage in the fastening plate 55 are supported either on the front plate 3 or on a tuning plate 75 which is still connected upstream. The carrier plate vibration damper 51 also sits here between the carrier plate 50 and the front plate 3. Such a construction variant is recommended, for. B. when there is little space between the front panel 3 and front panel, not shown. Accordingly, the hard disk unit protrudes deeper into the interior of the housing 1.

As shown in FIG. 13 in particular, the mounting side walls 12 , 14 are flanged directly to the side of a heat sink 18 that fits between them. Here, too, it is conceivable that the mounting side walls 12 , 14 each hold a fastening edge at the bottom, in order then to be fitted with a wider heat sink 18 again. In both cases, the heat sink back forms the mounting base 16.

The cooling capacity achievable for the hard disk 20 depends on the dimensioning of the heat sink 18 , the holder 10 and the configuration of the fans 9 and / or fans 40. Measurements on the dimensions carried out within the scope of the invention gave a maximum cooling capacity without fans 9 and 40 of 1.2 K / W and with the fans 9 and 40 a cooling capacity of 0.5 K / W. Since this cooling method still has reserves for higher cooling capacities, hard disks with a power consumption of 20 W to 25 W can be safely cooled under the same requirements.

A rough calculation for mass production resulted in additional production costs between 8 and 25 US $ depending on the expansion stage. In this calculation, the additional costs for material and assembly costs compared to conventional construction were taken into account. In certain borderline cases, in which the aluminum bracket 10 and the intermediate layer 30 can replace a fan 40 , no or only small additional costs are required for mass production.

From the point of view of lowering warranty costs and advantageous, harmful properties for the user (rest on the computer Workplace) must be strictly assumed that when using this invention both the costs on the manufacturer side and the costs on the user side, lower in the long run.  

Reference list

1

casing

2nd

Framework

3rd

Mounting surface

4th

Housing base plate

5

Main fan

6

Back wall

7

Outlet slots

8th

Housing cover

9

Additional fan

10th

Hard drive bracket

11

Fastening screw

12th

Side wall

13

Fastening screw

14

Side wall

15

Fastening screw

16

Base plate

17th

Fastening screw

18th

Heatsink

19th

Fastening screw

20th

hard disk

21

Fastening screw

22

rivet

23

Fastening screw

24th

rivet

25th

Fastening screw

26

rivet

27

Fastening screw

28

rivet

29

Cage

30th

Vibration damping liner

31

Compensation holes

32

Composite panel

34

drilling

35

drilling

36

Drift thread

37

Middle approach

38

thread

40

Hard drive fan

41

Fan through openings

42

Fan through openings

43

Space

44

poetry

45

Floppy drive

46

Composite panel

47

Composite panel

48

Composite panel

49

Composite panel

50

Carrier plate

51

Carrier plate vibration damper

52

Stiffening plate

53

power adapter

54

rivet

55

Mounting plate

56

Machine screw

57

Machine screw

60

Heat conductor

61

Torque distributor bridge

62

Anti-vibration pad

63

Torque distributor bridge

64

Anti-vibration pad

65

Fan attachment

67

Fan attachment

69

rivet

70

Torque compensation plate

71

Bracket mounting edge

72

Bracket mounting edge

73

Bracket mounting edge

74

Mounting plate vibration damper

75

Tuning plate

76

Set screw

77

Threaded attachment

78

Hard drive top

Claims (37)

1. Housing ( 1 ) for receiving electronic assemblies and motor-driven units with one or more holder (s) ( 10 ), in which one or more hard disk (s) ( 20 ) or other, each having a drive motor Assembly (s) is / are held,
characterized by
that the holder (s) ( 10 ) is or are rigidly connected to a carrier plate ( 50 ),
that an at least partially flat support plate vibration damper ( 51 ) is arranged between the respective support plate ( 50 ) and a suitable mounting surface ( 3 ) on the housing ( 1 ),
that the respective carrier plate ( 50 ) is connected via fastening elements ( 27 , 25 , 23 ) to a spaced fastening plate ( 55 ), and
that between the respective mounting plate ( 55 ) and the mounting surface ( 3 ) on the housing ( 1 ) or between the respective mounting plate ( 55 ) and the support plate ( 50 ) a mounting plate vibration damper ( 74 ) is arranged at least partially flat. 2. Housing according to claim 1, characterized in that the carrier plate vibration damper ( 51 ) and / or the mounting plate vibration damper ( 74 ) consists of semi-elastic material or consist. 3. Housing according to claim 1 or 2, characterized in that the carrier plate (s) ( 50 ) in the integral part of the respective holder ( 10 ) is or are. 4. Housing according to one of claims 1 to 3, characterized in that the carrier plate (s) ( 50 ) and the mounting plate (s) ( 55 ) each with the interposition of the carrier plates vibration damper ( 51 ) or the mounting plate vibration Damper ( 74 ) are provided on opposite sides of the mounting surface ( 3 ) on the housing ( 1 ). 5. Housing according to one of claims 1 to 3, characterized in that the carrier plate (s) ( 50 ) and the mounting plate (s) ( 55 ) are arranged on the same side of the mounting surface ( 3 ) on the housing ( 1 ), wherein the carrier plate vibration damper ( 51 ) between the carrier plate and the mounting surface ( 3 ) on the housing ( 1 ) and the fastening plate vibration damper ( 74 ) between the carrier plate ( 50 ) and the fastening plate ( 55 ) is arranged. 6. Housing according to one of claims 1 to 5, characterized in that the mounting surface ( 3 ) is the housing front plate. 7. Housing according to one of claims 1 to 6, characterized in that the front plate ( 3 ) in the area of the holder of the support plate vibration damper ( 51 ) by a stiffening plate ( 52 ) is stabilized areal. 8. Housing according to one of claims 1 to 7, characterized in that the carrier plate ( 50 ) and the mounting plate ( 55 ) are held by the fastening elements at such a distance that the carrier plate vibration damper ( 50 ) and the mounting plate ten vibration damper ( 74 ) are under pressure. 9. Housing according to one of claims 1 to 8, characterized in that the carrier plate ( 50 ), the carrier plate vibration damper ( 51 ), the front plate ( 3 ) with the optionally provided stiffening plate ( 52 ), the mounting plate vibration damper ( 74 ) and the fastening plate ( 55 ) connecting fastening elements are designed as fastening screws ( 27 , 25 , 23 ), the head of which is supported on the outside of one of the outer plates, while the threaded shaft is guided without thread through through holes in the other components and with the The free thread shaft end is screwed into a threaded hole in the outer plate opposite the outer plate provided on the screw head side. 10. Housing according to claim 9, characterized in that the shaft of each fastening screw ( 23 , 25 , 27 ) is insulated and longitudinally displaceable through the associated hole (s) in between the outer plates arranged metallic plate (s). 11. Housing according to claim 9 or 10, characterized in that the carrier plate ( 50 ) is rigidly connected to the holder ( 10 ), and that the threaded bores for the fastening screws ( 23 , 25 , 27 ) are provided in the carrier plate ( 50 ) are. 12. Housing according to claim 8 and 11, characterized in that the carrier plate ( 50 ) is rigidly connected to the front wall of the bracket ( 10 ), and that the length of the fastening screws ( 23 , 25 , 27 ) is dimensioned so that the mounting plate vibration damper ( 51 ) and the mounting plate vibration damper ( 74 ) after screwing the mounting screws ( 23 , 25 , 27 ) into the threaded holes in the mounting plate ( 50 ) until their free threaded ends on the bracket front wall under the preseeseed pressure preload. 13. Housing according to one of claims 1 to 12, characterized in that the strength and / or the material properties of the carrier plate vibration damper ( 51 ) and the mounting plate vibration damper ( 74 ) are selected so that the plate from the carrier ( 50 ) , The carrier plate vibration damper ( 51 ), the mounting plate vibration damper ( 74 ) and the mounting plate ( 55 ) formed damper system in the critical frequency range of the hard disk forms a deep-root system vibrating substantially under negative feedback conditions. 14. Housing according to claim 13, characterized in that the carrier plate ( 50 ) and the mounting plate ( 55 ) are mechanically connected in such a cross or force-deflecting manner that the two plates can only perform oppositely directed movements. 15. Housing according to one of claims 1 to 14, characterized in that in the carrier plate vibration damper ( 51 ) and in the mounting plate vibration damper ( 74 ) recesses or holes ( 31 ) are each provided in different areas such that that of the bracket ( 10 ) and the hard disk ( 20 ) formed hard disk unit is aligned at right angles to the front panel after its assembly in the housing. 16. Housing according to one of claims 12 to 15, characterized by means for changing the pressure bias of the carrier plate vibration damper ( 51 ) and the BEFE stigungsplatten vibration damper ( 74 ). 17. Housing according to claim 16, characterized in that between the support plate ( 50 ) and the support plate vibration damper ( 51 ) or the mounting plate ( 55 ) and the mounting plate vibration damper ( 74 ) provided a flat on the respective vibration damper adjoining tuning plate ( 75 ) is and that a on the carrier or mounting plate on the one hand and the tuning plate on the other hand attacking delivery device is provided, by means of which the tuning plate ( 75 ) from the associated carrier or mounting plate away in the direction of the vibration damper is adjustable bar. 18. Housing according to one of claims 1 to 17, characterized in that between the respective hard disk ( 20 ) or assembly and the associated holder ( 10 ) is made of egg nem high damping for high-frequency vibrating material is arranged vibration-damping intermediate layer. 19. Housing according to claim 18, characterized in that the vibration-damping inter mediate position is formed by a band ( 30 ). 20. Housing according to claim 18 or 19, characterized in that the hard disk is held by means of engaging fastening elements (screws 11 , 13 , 15 , 17 , 19 , 21 ), which che on the bracket ( 10 ) via vibration-damping elements (torque distributor bridges 61 , 62 ; 63 , 64 ) are supported. 21. Housing according to one of claims 1 to 20, characterized in that the housing cover ( 8 ) of the housing ( 1 ) is at least partially lined with a sound-absorbing material. 22. Housing according to claim 21, characterized in that the sound-absorbing material ( 46 ,..., 49 ) consists of a layer material which has a layer of bitumen, a layer of foam material and a polyurethane layer. 23. Housing ( 1 ) for receiving electronic assemblies and motor-driven units with one or more holder (s) ( 10 ), in which one or more hard disk (s) ( 20 ) or other, each having a drive motor Construction group (s) with the interposition of a vibration-damping intermediate layer ( 30 ) is or are
characterized,
that the vibration-damping intermediate layer ( 30 ) additionally has good thermal conductivity,
that the intermediate layer ( 30 ) is made of an elastically deformable material,
that the intermediate layer ( 30 ) has at least one large-area contact with two longitudinal sides of the hard disk ( 20 ) and one large-area contact with two side walls ( 12 , 14 ) of the holder ( 10 ),
that at least parts of the surfaces of the holder ( 10 ) are exposed to the air circulating in the housing and
that the holder (s) ( 10 ) is (are) made of a good heat-conducting material. 24. Housing according to one of claims 18 to 20, characterized in that the vibration-damping band ( 30 ) is a silicone rubberized insulating material which has a hardness of about 75 shore A. 25. Housing according to claim 24, characterized in that the vibration-damping band ( 30 ) has a thickness of about 0.45 mm. 26. Housing according to one of claims 23 to 25, characterized in that the vibration-damping band ( 30 ) has a thermal conductivity of about 0.0021 cal / cm s C. 27. Housing according to one of claims 1 to 26, characterized in that on one side wall ( 12 ) of the holder laterally next to the hard disk ( 20 ), a fan ( 40 ) is arranged. 28. Housing according to claim 27, characterized in that in the hard disk fan ( 40 ) holding side wall ( 12 ) of the holder ( 10 ) two groups of through openings ( 40 , 41 ) as passages for air sucked in by the fan ( 40 ) from the housing are provided in the holding interior, which are arranged such that the partial air flow entering through the first group of through openings ( 41 ) essentially over the upper side ( 78 ) of the hard disk ( 20 ) and over the second group of through openings ( 42 ) A partial stream of air flows over the underside of the hard disk. 29. Housing according to claim 28, characterized in that the through openings ( 42 ) of the second, the air over the underside of the hard disk ( 20 ) leading group have a larger ren distance from each other than the through openings ( 41 ) of the first group. 30. Housing according to one of claims 27 to 29, characterized in that a thermal sensor for temperature monitoring is attached to the hard disk holder ( 10 ). 31. Housing according to one of claims 1 to 30, characterized in that on the hard disk holder ( 10 ) at least one provided with cooling fins heat sink ( 18 ) is provided. 32. Housing according to claim 31, characterized in that the cooling body ( 18 ) with the bottom plate ( 16 ) of the holder ( 10 ) emerging cooling fins is arranged. 33. Housing according to one of claims 31 or 32, characterized in that the Kühlrip pen of the heat sink ( 18 ) at least partially in the cooling air flow of the main housing fan ( 5 ) and / or an additional housing fan ( 9 ) occur. 34. Housing according to claim 33, characterized in that the heat sink ( 18 ) is arranged with sufficient contact force for optimizing the heat transfer on the wall of the holder ( 10 ) holding it. 35. Housing according to claim 20 and 23, characterized in that the intermediate layer ( 30 ) with sufficient contact pressure to ensure the surface contact between the long sides of the hard disk ( 20 ) and the side walls ( 12 , 14 ) of the holder ( 10 ) is angeord net. 36. Housing according to claim 23 to 35, characterized in that the cooling body ( 18 ) is integral part of the holder ( 10 ). 37. Housing according to claim 23 to 36, characterized in that at least two heat transfers are provided between the hard disk ( 20 ) and holder ( 10 ) via the intermediate layer ( 30 ) on the respective mounting sides.