DE10300647B4 - decoupling element - Google Patents

Abstract

decoupling element for vibration-decoupled support two machine elements (1, 2) with a first (3) and a second annular spring body (4) made of rubber-elastic material adjacent in the axial direction are, and by a connecting web (16) or a coaxial to the spring bodies (3, 4) arranged, hollow-shaped Cylinder section (10), to form a preassembled unit (9) are connected to a fastening element (8), wherein the spring bodies (3, 4) and the connecting web (16) or the hollow cylindrical portion (10) one piece merge into each other are formed of the same material.

Description

The Invention concerned with a decoupling element for vibration-decoupling support two Machine elements, wherein the vibration decoupling with at least a spring body takes place by means of which the two machine elements fastened together are.

Out DE 100 35 633 A1 a vibration damper for vehicle windscreen wiper devices is known. Here, a rubber-elastic body is provided, which surrounds a wiper frame. The rubber-elastic body clamped between a disc and a fuselage frame by means of a fastening element in the form of a through-bolt. The screw passes through a spacer sleeve which predetermines and maintains the axial distance between the two components. The rubber-elastic body, the fastening element in the form of a screw and the spacer sleeve are independent items that must be built together during assembly of the windshield wiper assembly.

Out DE 101 15 032 A1 is a vibration isolation storage for a motor or a motor-driven unit known. With these elastic elements of the motor or a motor-driven assembly is suspended elastically, which have a band shape. Thus, there is provided a band-shaped spring body. There is no suggestion herein to keep two machine elements axially spaced apart in a predetermined manner.

Of the Invention is based on the object, a decoupling element for vibration-decoupled support To provide two machine elements, which is easy and inexpensive to produce is, an efficient vibration isolation allowed, as well a simplified storage and installation of the same.

To The invention is for this purpose a decoupling element for vibration decoupled support two machine elements according to the claim 1 provided.

The both adjacent in the axial direction, annular body are in the decoupling element according to the invention connected by the connecting web or the tubular cylinder section, so that you form a pre-assembled unit. With the help of the fastener the components of the decoupling element are captive with each other connected. Both the warehousing and the handling of the Assembly is thereby considerably simplified. Especially easy and cost-effective the production of the decoupling element is characterized in that the spring body and the connecting element in the form of a connecting web or a shaped hollow Cylinder section in one piece merge into each other and formed of the same material. As a material, for example, EPDM (Ethylene-propylene-diene copolymer) are used. at such a design is also the recycling following use especially easy. The decoupling element can then sorted be recycled. By integrally merging and uniform material training example of cylinder section and spring body the decoupling element is particularly simple and inexpensive to produce. By the one-piece Design of the decoupling element is also the assembly considerably simplified. Despite the one-piece design of the decoupling element can this vibration in both machine elements relative to each other decouple in both tension and compression direction. The connecting bridge not only holds the two spring bodies he is captive, but he also creates one Restoring moment when the two spring bodies are arranged substantially coaxially to each other. The connecting bridge is then elastically biased and formed substantially U-shaped. By the restoring moment of the connecting bar, this endeavors, in its production-related to return flat form. But if, for example, by the substantially coaxial with each other arranged spring body already a fastener, such as a screw inserted through it is, so can thereby the screw, based on the spring body, in their Position be kept captive. The restoring torque allows a captive clamping.

In a preferred embodiment, at least one of the spring body has at least one undercut, and the projection formed by the undercut can be brought into positive engagement with a fastening element which connects the two machine elements in a vibration-decoupled manner by means of the decoupling element. The fastener is thus unbound and set captive on the spring bodies. With regard to a sorted recycling such a configuration is particularly advantageous. In addition, such a connection is easy and inexpensive to install. The fastening element may be formed for example by a collar screw. In such a fastener is of advantages that, for example, the washer commonly used is an integral part of the screw. The handling during the Mon days is particularly simple due to the low-part structure of the decoupling element.

Preferably the projection can be divided by three evenly distributed in the circumferential direction, be formed in the radial direction resilient locking cams. A different number of locking cams, for example, only a locking cam, which extends in the circumferential direction and in itself is formed closed, can optionally be provided. The locking cams and the federal government, for example, reaching the application Bundle screw are then screwed into each other and then captive connected with each other.

Especially it is advantageous if the cylinder portion a height in the axial Direction, which is substantially the thickness of the first machine element equivalent.

Preferably is the connecting web in the axial direction U-shaped and connects the spring bodies each outer peripheral side together. The decoupling element includes two production reasons arranged in an imaginary plane at a distance next to each other, annular Spring body, wherein mutually facing peripheral regions of the spring body means of bridging the gap, level connecting web of rubber-elastic material connected are. The spring bodies are during the intended use the decoupling element with the interposition of the decoupled, first machine element arranged coaxially with each other, wherein the connecting web is elastically biased.

Prefers are the spring bodies circular ring educated. Especially with regard to the fastening elements, usually formed by screws and therefore rotationally symmetrical are configured, such a shape of the spring body is advantageous.

The relationship of diameter and height of spring body is preferably each substantially 1. By such a ratio on the one hand a sufficient stability of the spring body, and on the other hand a sufficient compliance in the direction of the initiated Given vibrations. For a variety of applications has such a relationship proved to be advantageous.

Preferably the spring bodies are consistent trained, so that makes assembly much easier, and the risk of assembly errors can be reduced to a minimum. When the spring bodies coincide are formed, then it is irrelevant which spring body above or below the first, to be supported Machine element is arranged. The assembly is further simplified then when the spring body symmetrical to be supported Machine element are formed, and the connecting web respectively in half the height the spring body is arranged. In such a case, plays for the utility property the decoupling element, the direction of the same and the connecting web not matter. The assembly is further simplified.

In Preferably, a collar screw is used as a connecting element used. The support of the upper spring body on its side facing away from the second machine element, This makes it possible in a simple manner. Separately manufactured and to be mounted washers, the Abutment for the first spring body Therefore, it is not necessary.

Preferably can the spring bodies the shank of the screw at least partially with a radial distance enclose. It is advantageous that also a vibration decoupling transverse to the axis of the screw can. After overcoming the radial distance put the spring body and the shank of the screw to each other and thereby limit extreme deflections radially to Axis of the screw.

Preferably are the spring bodies during her intended use provided in a functional parallel connection.

Hereinafter, preferred embodiments of a decoupling element with reference to FIGS 1 to 5 explained in more detail. The following applies:

1 shows a sectional view taken along the line AA in 2 to illustrate a first preferred embodiment of a decoupling element according to the invention,

2 is a plan view of the decoupling element according to 1 .

3 shows the decoupling after the 1 and 2 in its intended operating condition,

4 shows a second preferred embodiment of a decoupling element, and

5 shows the decoupling after 4 in the intended use condition.

In 1 is the first embodiment of the decoupling element shown in the manufacturing condition. The two spring bodies 3 . 4 are annular trained and in imaginary plane 26 arranged at a distance next to each other. The mutually facing peripheral areas 27 . 28 , the spring body 3 . 4 are due to the production-related level connecting web 16 connected with each other. The connecting bridge 16 consists of a rubber-elastic material, as well as the two spring body 3 . 4 , The spring bodies 3 . 4 and the connecting bridge 7 are integrally merging into each other and formed of the same material and consist of the elastomeric material, such as EPDM.

In the embodiment shown here, the first spring body 3 an undercut 6 on, wherein the projection formed by the undercut 7 with a fastening element, not shown here 8th that the two machine elements not shown here 1 . 2 connects vibration-decoupled by means of the decoupling element, can be brought into positive engagement. The lead 7 extends annularly radially inwards. This in 3 illustrated fastener 8th is in the undercut 6 snapped.

In 2 is the top view of the decoupling from 1 shown.

In 3 the decoupling element is shown during its intended use. The first machine element to be decoupled 1 is formed for example by a mounting plate of an accessory. The second machine element 2 is formed for example by the engine block of an internal combustion engine. The two spring bodies 3 . 4 are arranged coaxially with each other. The connecting element 5 is in the embodiment shown here by a connecting web 16 formed, which is U-shaped in the axial direction and the spring body 3 . 4 each outer peripheral side connects to each other.

Within the decoupling element are in both spring bodies 3 . 4 each one to the shape of the respective spring body 3 . 4 close-fitting, annular support body 19 . 20 arranged, the two support bodies 19 . 20 on the opposite end faces 11 . 12 the two spring body 3 . 4 are arranged.

In the embodiments shown here, the ratio is the diameter 17 and the height 18 the spring body 3 . 4 each about 1.

Both the spring bodies 3 . 4 as well as the recess 29 of the first machine element 1 is from the fastener 8th in the form of a screw 22 penetrated. De screw 22 forms the fastener 8th between the first machine element 1 and the second machine element 2 , these two machine elements 1 . 2 are connected by the decoupling element vibration decoupled with each other.

The first spring body 3 Is in the area of its front 11 positive fit with the fastener 8th connected. The second spring body 4 is with his front page 12 on the surface 30 of the second machine element 2 supported.

For good vibration isolation radially to the screw 22 introduced vibrations, enclose the spring body 3 . 4 the shaft 23 the screw 22 with radial distance 24 . 25 , To limit such vibrations and to avoid the limitation 31 the recess 29 on the shaft 23 the screw 22 strikes are the annular bump stopper in this embodiment 32 . 33 provided, the one-piece merging into each other and of the same material with the respective spring body 3 . 4 are formed.

The screw 22 is in this embodiment insoluble with the federal government 34 connected.

In 4 the second embodiment of the decoupling element is shown. The connecting element 5 is through a coaxial to the spring bodies 3 . 4 arranged hollow cylindrical section 10 formed, the facing front sides 11 . 12 the spring body 3 . 4 combines.

Also in the second embodiment, the first spring body 3 an undercut 6 on, passing through the undercut 6 educated edge 7 with the fastener 8th is positively engageable, as in 5 shown.

The cylinder section 10 has one, based on the two spring body 3 . 4 smaller outer diameter 13 and has a height 14 in the axial direction, which is substantially the thickness 14 of the first machine element 1 corresponds, as in 5 shown.

The cylinder section 10 and the spring bodies 3 . 4 are integrally merging into each other and formed of the same material.

In 5 is the decoupling element off 4 shown during its intended use. The two machine elements 1 . 2 are connected by the decoupling element vibration decoupled with each other. The fastener 8th can, as in 3 shown by a screw 22 with waistband 34 be formed or by a conventional screw 22 in a sleeve 35 with waistband 34 is used. In the embodiment shown here, the federal government 34 the sleeve 35 positive fit in the first spring body 3 held. In both embodiments ( 3 and 5 ) consists of the preassemblable unit 9 from the two spring bodies 3 . 4 , the connecting element 5 in the form of the connecting bridge 16 or the cylinder section 10 and the fastener 8th ,

The Use characteristics of the two embodiments differ not significantly different from each other.

Claims (11)

Decoupling element for the vibration-decoupled support of two machine elements ( 1 . 2 ) with a first ( 3 ) and a second annular spring body ( 4 ) made of rubber-elastic material, which are adjacent in the axial direction, and by a connecting web ( 16 ) or coaxial with the spring bodies ( 3 . 4 ), hollow cylindrical section ( 10 ), to form a pre-assembled unit ( 9 ), with a fastener ( 8th ), wherein the spring bodies ( 3 . 4 ) and the connecting bridge ( 16 ) or the hollow cylindrical portion ( 10 ) are integrally formed into one another in the same material. Decoupling element according to Claim 1, characterized in that at least one of the spring bodies ( 3 . 4 ) at least one undercut ( 6 ), and that by the undercut ( 6 ) formed advantage ( 7 ) with a fastening element ( 8th ), the two machine elements ( 1 . 2 ) connects by means of the decoupling element vibration-decoupled, can be brought into positive engagement. Decoupling element according to claim 2, characterized in that the projection ( 7 ) by three uniformly distributed in the circumferential direction, radially resilient locking cam ( 7.1 . 7.2 . 7.3 ) is formed. Decoupling element according to claim 1, characterized in that the cylinder section ( 10 ) one, based on both spring body ( 3 . 4 ), smaller outer diameter ( 13 ) having. Decoupling element according to one of claims 1 or 4, characterized in that the cylinder section ( 10 ) a height ( 14 ) in the axial direction, which is substantially the thickness ( 15 ) of the first machine element ( 1 ) corresponds. Decoupling element according to one of claims 1 to 5, characterized in that the connecting web ( 16 ) is formed in the axial direction U-shaped and the spring body ( 3 . 4 ) connects each other on the outer circumference side. Decoupling element according to one of Claims 1 to 6, characterized in that the spring bodies ( 3 . 4 ) are annular. Decoupling element according to Claim 7, characterized in that the ratio of diameters ( 17 ) and height ( 18 ) of the spring body ( 3 . 4 ) is substantially 1 in each case. Decoupling element according to one of Claims 1 to 8, characterized in that the spring bodies ( 3 . 4 ) are formed consistently. Decoupling element according to one of claims 1 to 9, characterized in that the connecting element ( 5 ) as collar screw ( 22 ) is trained. Decoupling element according to one of Claims 1 to 10, characterized in that the spring bodies ( 3 . 4 ) the shaft ( 23 ) of the screw ( 22 ) at least partially at a radial distance ( 24 . 25 ) umschleißen.