DE4219761A1 - Vibration-insulating fixture mechanism - comprises elastic, acoustically absorbent rubber deformation body, pressure piece, further but divisible, elastic acoustically absorbent deformation body, and further pressure piece - Google Patents

Abstract

The fixture (1) has two deformation bodies which perform the function of a dowel, and the pressure pieces are screws or discs. The fixture mechanism is mounted in a hole, and an elastic, vibration-absorbing deformation body, supported by a pressure piece against the surface of the component to be fitted, is so forced into the hole that it exerts an equal surface pressure on the hole wall, preventing it being withdrawn. Two opposing holes can be involved, with the deformation bodies being supported against the surface of the component to be installed by two pressure pieces. One of the deformation bodies is effective on one side, and the other on both sides. USE/ADVANTAGE - For the installation of stairways, facades etc. to fix components so that they are vibration-damped.

Description

The invention relates to a vibration-isolated Fastening mechanism or corresponding mounting elements preferably for use in construction, which has a damping of vibrations, especially for use in the Assembly of components made of organic or mineral Materials on the substructure, preferably for Use in the assembly of stairs, facades or other elements with wood, concrete, or metal Substructure, for example stairs, the steps of which metallic or other support structures in the most cases made of steel or aluminum profile tubes are mounted.

The fastener according to the invention is also Can be used for vibration-isolated fastening of parts in sheet metal constructions, (vehicles, air conditioning, Aircraft), i.e. areas in which resonance vibrations occur that are perceived as disturbing or damage lead to the objects.

The invention includes a definition for a Insulating element that provides thermal and acoustic damping includes and acoustically damping measures for mitigation the transmission of vibrations to vibrators  Constructions. The use took place inside and Outdoor area.

The object of the invention is a standardized Define fastener that is simple, with high Reproducibility producible, the transfer of Dampens vibrations as a safe mounting element for Fastening components from different Materials, wood, plastic, glass, minerals, Composite materials etc. can be used.

Due to the possibility of the two sides of the Fastening mechanism with different, too Profiles adapted to metal or plastic profiles provided, the use results as vibration damping connector between Hollow profiles with each other or in connection with one any mounting base.

The possibility of elastic deformation of the Fastener compensates for thermal expansion differences the assembly of components with different Thermal expansion, for example when fastening Aluminum pipes between two walls made of mineral Materials.

Due to the special shape of the fastening mechanism is also a tight cover of the Cut surfaces in the, in many cases on the Profiles coated on the long sides.

The fastener is intended to be used in craft and DIY tools and processes as well can be processed and assembled, as in industrial Use when assembling components (e.g. windows or vehicles or similar  

The components associated with the element are also intended to in the event of damage (vehicles as a result of accident damage) or Components for renovations, with little effort from the occupied substructure be removable.

The assembly element is intended for the designer / designer and the User / processor due to its specific design sufficient design options with regard to the Selection of materials and the optical and technical Enable the function of the finished surfaces.

Stairs with metallic substructures are known, which are usually made of profile tubes where the stairs are screwed. Furthermore is known for vibration damping between the steps and the support structure rubber or other insulating washers to insert. Although these discs cause an elastic Compensation of manufacturing and assembly tolerances as well Level differences or the like of the mounting points.

A reduction in the acoustic transmission properties is only achieved to a very small extent. The Vibrations are caused by the screw connection and its metallic components directly from the step the stair substructure and from this to the as Mounting ceilings or walls of the building transfer.

The device according to the invention includes a through absorbent material from the elements to be connected decoupled fastening mechanism and is based described several advantageous embodiments and represented in sketches.

The transmission of building and impact sound vibrations between steps, substructure and building is achieved through the use of the invention Fastening mechanism significantly reduced.  

An advantageous embodiment of the invention Fastening mechanism is also that in Deformation body two or more through nozzles with each other connected liquid containers are located at a Load due to the displacement of the liquid over the Nozzle cross sections damping the impulses cause.

The solution according to the invention is based on several Exemplary embodiments shown and described.

Figs. 1 and 2 show the basic function of the attachment mechanism before and after installation in a concrete piece with cavities between the individual components of the concrete.

To prevent rotation when tightening the screw received, the fastening mechanism on the Small circumferential surface with any longitudinal profiles Provide cross-section, the insertion guarantee, but otherwise in the Replace displacement mechanism, so none Have fastening function.

If necessary, there is the possibility of this Longitudinal profiles with a sawtooth-like cross or To provide circumferential profiling that the insertion relieved and difficult to pull out, about Overhead mounting applications.

The bore is dimensioned so that the Fastening mechanism can be used in the same and with the easily deformable anti-rotation locks on the Circumferential surface of the bore rests.

Longitudinal profiling is particularly advantageous Tilting the profile and thus wedging in the  Direction of rotation when trying the fastening mechanism in twisting the hole causes the insertion or Pulling out the unstressed part is not essential with special needs. With this arrangement, the tolerance range the hole can be significantly enlarged.

After tightening the screw, the peripheral volume of the Rubber or elastomer portion in the peripheral structure of the Hole pressed. At the same time to increase the Tear resistance parts of the meander into the existing ones Cavities of the body inserted. There is a partial deformation of the meander structure. The meander remains, however, due to the flow characteristics of the Rubber or elastomer material as a coherent Whole preserve and increase the tear resistance of the Fastener.

FIGS. 3 to 9 show longitudinal sections through a fastener of simple design and its embodiments and applications of the stair assembly in conjunction with a staircase supporting structure 6 and a stair step. 8

The fastening mechanism consists of a deformation body 1 which fulfills the function of a dowel and is preferably made of rubber or another, elastically deformable material.

A pressure piece 3 , which is provided with a pressure edge, is embedded in the deformation body and is vulcanized, glued, or secured by a suitable profile in the through opening to prevent rotation during assembly.

In the pressure piece 3 , a screw 4 is inserted, which is provided with a washer 5 , with which the pressure piece 3 is pulled into the deformation element 1 during assembly of the step and displaces the volume thereof against the bore wall 8.1 in the step 8 . This results in the circumferential surface of the deformation body being braced against the bore wall 8.1 .

Due to the natural surface texture of the Hole wall is a secure fixation of the step against the deformation body, its screwing and given against the stair substructure. At the same time, the deformability of the Deformation body positional tolerances of the Mounting holes and level differences of the Support points balanced.

For higher load requirements, the deformation body is provided with a meandering retraction device 2 , referred to in the further description as a meander, in various embodiments, which has claws 2.1 or segmented cutting edges on the outer contour, which in the event of a corresponding deformation of the deformation body into the wall of the Penetrate hole and claw in the material of the step. The meander consists of a stamped or embossed part made of sheet metal, a correspondingly bent wire, or a plastic injection-molded part stabilized, preferably GRP, CFRP or another fiber. To increase the unidirectional effect, the claws are bent in the tightening direction of the screw or the retraction device is funnel-shaped, like a plate spring. Due to the deformation of the deformation body when the screw is tightened, the retraction device is pressed in the direction of the tightening torque and outwards into the bore wall, the claws wedging in the bore wall while the deformation body is solidified. The entire complex is additionally hardened towards the outside in the direction of the tightening torque. For applications in which the fastening element is to be secured in two directions, namely against pulling out and pushing in, the meander can be designed to act on two sides, as shown. Depending on the type of material of the bore wall, the meander is made flat or basket-shaped or claw-shaped.

For the assembly of so-called artificial stone steps, the Drilling expediently with the manufacture of the stage poured in or before delivery in a standardized Grid incorporated. The same applies analogously to Steps made of other, hard, brittle, mineral Materials such as granite, marble, glass. The Deformation body is used to attach these steps to Scope with a coating of a hard material, for example a rubber / silicon carbide mixture Mistake.

The layer containing the hard material is either after the production of the deformation body as a mixture Rubber solution and hard material applied as a prefabricated Vulcanized ring or as a sandwich component produced.

To make a different when tightening the clamping screw Deformation behavior between deformation body and A ring made of an abrasive carrier will be reached softer rubber or elastomer mixture with hard material filled or in the area of the outer contour with hard material coated and in the contour of the deformation body vulcanized.

As a result, the fastener is also concealed Assembly of granite and marble steps, if necessary as Composite material suitable.

In order to achieve a surface pressure of the displacer that is adapted to the strength values of the step and carrier profile material, the screws are tightened with a predetermined torque during assembly. This assembly technique is made possible by the fact that a washer 5 is mounted under the screw head, which enables reproducible friction values during assembly.

To the spread of vibrations in the Stair substructure, and / or Auxiliary support structures (railings, stair supports,  so-called harps), which usually consist of profile tubes are made to further reduce these Profile tubes for indoor and living applications a vibration absorbing filling consisting of preferably inert mineral substances, for example, Expanded clay, expanded glass, gravel, grit, or other substances sufficient absorption behavior and good Free flowing, for example cork granulate in one preferably filled up loose fill.

The filling is preferably carried out after the final assembly the staircase through appropriate filling openings at the top End of the stair substructure. These fill openings after filling with the surface of the stairs adapted sealing plug closed.

It is known to design and insulate floors, Cork walls and ceilings to cover a corresponding To achieve impact sound insulation and thermal insulation. The use of cork is also recommended by the natural resistance of the material to fungi and Pests.

To dampen the impact sound at the point of origin is the Top of the stair step optionally with an impact sound absorbent covering, for example cork.

The solution according to the invention further provides that Surfaces of stairs and if necessary Stair substructures as fully coated components to manufacture. This eliminates the above-mentioned the conventional coating, especially the Use of cork surface covering work the surface to be covered.

The elements of the invention can be used as commercially available profile components. The usual, applicable to the assembly of components  Tools, semi-finished products and assembly techniques are used. The use of special tools or other work aggravating facilities is not required. Thereby is an exact transition of the surfaces and Edge structures of the individual elements guaranteed. The use as a standardizable component is in Interior of buildings no restrictions subject and enabled by the modular structure of the Elements almost any combination of materials No processing of solvents or solvent-containing components. For applications in the The outdoor area exposed to weather conditions is the Use of appropriate surface coatings or Materials required.

The element meets high demands for sound insulation and Thermal insulation. In the described embodiment, that is Users or designers the basis for a large Variety of construction and design options given without handling during assembly and the later To complicate maintenance by the user.

The structure of the elements described is the same and differ mainly in the type of their Use as floor, wall or ceiling covering in the Dimensions and thickness of each layer.

Fig. 3 shows a longitudinal section through a simple embodiment of the fastening mechanism, consisting of a deformation body 1 made of a deformable, elastic material with high coefficients of friction, for example rubber, a retraction device 2 , with an annular meandering structure, as in a modified disc spring, the outer contour wedges into the surface of the hole when the screw is tightened; a pressure piece 3 , made of metal and provided with an internal thread, for deforming the deformation body when tightening a screw 4 , which is designed as an internal hexagon or hexagon screw. Under the head of this screw 4 , a washer 5 is provided, which consists of a material similar to the material of the screw, in order to obtain defined frictional resistances when tightening the screw and to define the assembly parameters of the fastening mechanism with a torque wrench. To support this function, the disk 5 is expediently provided with a corrugation on the side facing away from the screw head surface.

Fig. 4 shows a longitudinal section through a, on a support profile 6 , consisting of a profile tube, mounted step 8 made of wood in which a simple version of the fastening mechanism is installed. The deformation body 1 is compressed by tightening the screw 4 between the pressure surface of the pressure piece 3 and the surface of the stair profile 6 in the bore 8.1 and thereby lies against the wall of the bore. At the same time, the retraction safety device 2 is pressed outward in the direction of the tightening torque of the screw and is clawed in the bore wall. To further dampen vibrations, the profile of the stair substructure 6 is filled with an absorbent material 7 .

Fig. 4a shows a composite of several components, conformable deformation body. The individual parts are stacked on top of each other and used for assembly. The length of the screw only has to be adapted to the dimensions of the installation location.

FIG. 4b shows a deformation body which is occupied on the peripheral surface with a hard material mixture 1.41 Siliziumcarbidkörnung for example in rubber or another hard material mixture. Deformation bodies of this type are used in the assembly of mineral components in order to increase the pull-out strength of the fastening element.

Fig. 5 shows a longitudinal section through a, mounted on a staircase profile 9 wooden stair step 8 is also made of wood, with a double-acting version of the fixing mechanism. The deformation body 1.1.1 is pressed together by tightening the screw 4 between the pressure surface of the two pressure pieces in the bores 8.1 and 9.2 and thereby lies against the walls of the bores. At the same time, the retraction safeguards 2 are pressed against one another in the direction of the tightening torque of the screw and thereby cling to the wall of the bore.

Fig. 6 shows an assembled from several components adaptable, double-acting deformation body from a center piece 1.11 with collar and intermediate pieces 1.12 , which can be plugged onto each other as well as with an upper part 1.13 , in which a pressure piece is inserted. The intermediate piece 1.12 and the upper part 1.13 each contain a safety catch 2 or a receptacle corresponding to their dimensions. The individual parts are plugged together depending on the requirements for the strength of the connection and used for assembly. The length of the screw only has to be adapted to the dimensions of the installation location. The design allows the production of asymmetrical arrangements and thus the use over a wide range of applications.

Fig. 7 shows a double-acting deformation body 1.5, which is occupied at the located in the bore portions of the circumferential surface with a hard material mixture 1:41, for example Siliziumcarbidkörnung in rubber or another hard material mixture or consists of such a mixture. Deformation bodies of this type are used in the assembly of mineral components in order to increase the pull-out strength of the fastening element. To adapt to special geometric conditions, the deformation body is composed of individual components, as shown in FIG. 6.

Fig. 8 shows a cross section through a wooden staircase mounted on a support profile from a profile tube, the surface of which is coated with a covering 11 made of an absorbent material, for example cork, with a simple embodiment of the fastening mechanism being installed. The deformation body 1 is compressed by tightening the screw 4 between the pressure surface of the pressure piece 3 and the surface of the stair profile in the bore and thereby lies against the wall of the bore. In order to achieve reproducible values of the surface pressure within the bore, the screw 4 is mounted with a washer 5 , which is provided with radial corrugation for better fixation on the side facing the profile tube.

FIG. 9 shows a longitudinal section through a wooden step 10 , which is mounted on a carrier profile 6 from a profile tube, the surface of which is coated with a covering 11 made of an absorbent material, for example cork, again with a simple embodiment of the fastening mechanism being installed. In order to support overhangs or fastening points of the steps that are far apart, supports 8.11 are inserted into corresponding holes. To further dampen vibrations, the profile of the stair substructure 6 is filled with an absorbent material 7 .

The arrangements shown and described are with artisanal means can be processed. You can handicraft tolerances due to the high Deformation capacity of the deformation body while preserving a uniform surface pressure in the interior of the Holes can be easily compensated for what at the Assembly of components made of mineral materials is particularly important.  

The fact that the fastener in conical Mounting holes is mounted is a significant one Tear strength increased. Thanks to the hydrostatic displacement mechanism of rubber or elastomers is very uniform Pressure distribution on that occupied by the fastener Hole surface which is a risk of cracking reduced.

When used in sheet metal parts, the fastening element, as shown in FIGS. 10 to 15, is mounted in bores or, more advantageously, in a passage (a bore which is formed with the material of the bore cross section to the rear).

This makes the load-bearing surface in the sheet metal essential enlarged and by the trained on the edge of the hole Radius significantly reduces the risk of cracking. The The passage is introduced by a corresponding designed embossing or rolling tool.

After inserting the fastener Tighten the screw of the displacement area under the Bracket first because of the lower resistance displaced, flows outwards with or without a meander over the Edge of the swipe and is then inside the hole solidified.

The meander ( FIGS. 16 to 19) or a claw ( FIGS. 20, 21) which have the same function are incorporated into the elastomer and follow its displacement mechanism.

For securing against dismantling of use-related connecting elements, a dismantling lock in the form of a disc is placed on the end piece of the screw ( FIGS. 1 and 2) or the end piece of the screw is mushroomed.

For applications in stones that contain cavities, one or more cavities are incorporated in the displacer ( FIGS. 22 to 25), which are filled with a preferably mineral displacer and when tightening the screw with the compression, this displacer with the wall of the displacer displace into the cavities. This arrangement reduces flexing and the likelihood of damage to the rubber or elastomer displacement body.

For assembly in porous low-strength materials, in metal feedthroughs or in materials with large pores, one or more cavities are incorporated in the displacement body, which are provided with a displaceable sealing plug or a bursting membrane and are filled with an adhesive compound ( Fig. 26). When tightening the screw with the compression of the displacement body, the adhesive is displaced into the bore wall and its cavities. This arrangement also ensures an increase in the pull-out strength of the connection in a lower stability mounting base.

In addition, there is a fastening mechanism with a gag for detachable mounting in holes possible, for example Realization of temporary attachment points on or in Buildings and facilities for inspection or renovation purposes. Other applications for this are temporary fastening of scaffolding, ladders or monitoring devices.

In Fig. 27, a further embodiment is shown for the fastening mechanism in which a built-in hydraulic shock absorber is provided. For this purpose, two cavities connected to one another by nozzles are provided, in which a liquid, for example silicone oil, is vulcanized. When the inner region of the fastening mechanism is displaced against the mounting base, the liquid is displaced from one cavity into the other, with damping occurring through the nozzles as in the case of a hydraulic shock absorber.

Further advantageous embodiments are shown in FIGS. 28 to 33, wherein Figs. 28, 30 and 32, the non-installed state and Fig. 29, 31 and 33, the fixed state show in which a strain of the elastic member of the fixing mechanism at a Sheet metal part is effected.

Also very advantageous configurations and examples of use are shown in FIGS. 34 to 43.

Claims (7)

1. Vibration isolating fastening mechanism, characterized in that a fastening mechanism

• an elastic, acoustically absorbing deformation body that fulfills the function of a dowel, for example made of rubber,
• - A pressure piece, a screw, optionally a washer
• a divisible, elastic, acoustically absorbing deformation body that fulfills the function of a dowel, for example made of rubber,
• - A pressure piece, a screw, optionally a washer.

2. Vibration isolating fastening mechanism according to claim 1, characterized in that the mounting of the fastening mechanism in

• - A bore occurs in that an elastic, vibration-absorbing deformation body, supported by a pressure piece in the bore against the surface of the element to be assembled, is displaced in this bore so that the deformation body exerts a uniform surface pressure on the bore wall and thus pull it out prevents
• - Two mutually opposite bores in that an elastic, vibration-absorbing deformation body, supported by two thrust pieces in the bore against the surfaces of the elements to be assembled, is displaced in these bores so that the deformation body exerts a uniform surface pressure on the bore wall and thus pulling out prevents.

3. Vibration isolating fastening mechanism according to claim 1 or 2, characterized in that the fastening mechanism

• - from a
• - there is a one-way deformation body,
• - there is a bilateral deformation body,
• - which can be assembled from several parts and thus can be extended,
• - Optionally provided with a meandering or segmented retraction device, which is provided with claws on the sides facing the circumferential surface and claws into the surface of the bore in the direction of the tightening torque of the screw.

4. Vibration isolating fastening mechanism according to claim 1, 2 or 3, characterized in that the fastening mechanism

• consists of a one-sided or two-sided deformation body which is composed of several parts and can therefore be extended,
• - with a hard material coating
• - From a mixture of deformation body material and a hard material granulate or
• - A mixture of a coating material and a hard material granulate is provided, which increases the pull-out resistance when used for the assembly of parts made of mineral or metallic materials.

5. Vibration isolating fastening mechanism after one of the preceding claims, characterized characterized in that in the deformation body at least two connected by nozzles Liquid containers are located during a load by overflowing the liquid through the nozzles cause a damping of the force impulses. 6. Vibration isolating fastening mechanism after one of the preceding claims, characterized characterized in that in or on the deformation body at least one adhesive or potting compound container located, which is closed by a membrane, which bursts during assembly and the adhesive or the Potting compound spread over the mounting surface. 7. Fastening mechanism according to one of the preceding Claims, characterized in that the outer surface the deformation body is ventilated.