DE102020002585A1 - Elastic bearing - Google Patents

Abstract

The present invention relates to an elastic bearing, in particular for suspending a load, with: at least one elastic body, the at least one elastic body having at least one receiving opening for receiving at least one coupling element, the at least one elastic body having at least one first contact surface and at least having a second contact surface, wherein the at least one first contact surface and the at least one second contact surface are opposite one another, wherein at least one of the contact surfaces has at least one predetermined surface structure in at least one region.

Description

The present invention relates to an elastic mount for a load. The elastic mount can be used, for example, to attach an exhaust system to a body of a vehicle. However, the elastic bearing can also be used in other areas for storing or fastening loads to devices or assemblies. The elastic bearing can be coupled via coupling elements such as bolts or similar elements to the devices or assemblies to be connected via the bearing.

From the prior art, for example, the in DE 100 13 121 C1 disclosed suspension device is known. The suspension device has two sockets that can be inserted into bolts.

It is an object of the present invention to provide an elastic mount with which undesired noises can be prevented, for example when the mount is used on a vehicle.

This object is achieved with an elastic bearing with the features of claim 1.

Further embodiments emerge from the dependent claims.

The elastic bearing according to the invention comprises at least one elastic body, the at least one elastic body having at least one receiving opening for receiving at least one coupling element, the at least one elastic body having at least one first contact surface and at least one second contact surface, the at least one first The contact surface and the at least one second contact surface are opposite one another, at least one of the contact surfaces having at least one predetermined surface structure in at least one region.

When the elastic bearing is loaded, the opposing contact surfaces can come into contact with one another and adhere to one another for a short time. When the elastic bearing is relieved and the contact surfaces are subsequently separated, undesirable noises can then occur, which have a negative effect on the acoustics of a vehicle in particular. With the predetermined surface structure provided according to the invention on at least one of the contact surfaces, it is possible to prevent the contact surfaces from sticking to one another. As a result of the at least one surface structure, the contact surfaces remain in contact longer in some areas and / or at specific points, which prevents a sudden or sudden separation of the contact surfaces. The undesired noises often arise when the bearing is relieved and the contact surfaces are suddenly separated. With the surface structure according to the invention on at least one of the contact surfaces, undesired noise development can thus be avoided.

With the predetermined surface structure on at least one area of at least one of the contact surfaces, the distance between the two opposite contact surfaces can be varied or changed. This change in the distance between the opposing contact surfaces can take place selectively and / or in areas with the predetermined surface structure. In particular, the distance between the first contact surface and the second contact surface with the predetermined surface structure can be reduced.

The at least one surface structure can have at least one profile element. The at least one profile element can extend from one of the contact surfaces in the direction of the respective other contact surface. In other words, the profile element can protrude on one of the contact surfaces in the direction of the other contact surface. With the at least one profile element, the distance between the two opposite contact surfaces can be reduced.

The at least one profile element can have at least one edge. The at least one edge can form the transition between the contact surface on which the profile element is arranged and the at least one profile element. The at least one edge can be a circumferential edge which defines the circumference of the at least one profile element. The at least one edge can extend over the entire longitudinal or transverse extent of the contact surface. The at least one edge can also only extend over parts of the longitudinal or transverse extension of the respective contact surface.

The area of the at least one profile element can be smaller than the area of the contact surface on which the at least one profile element is arranged.

The at least one profile element can be formed by an elevation. Such an elevation can be designed, for example, in the shape of a lens. The at least one profile element can also be a projection. The at least one profile element can be designed as a web. The at least one web can extend over the entire longitudinal extent of the contact surface. The at least one web can extend over the entire transverse extent of the contact surface. At least that one a web can also only span parts of the longitudinal or transverse extension of the contact surface.

The at least one elastic body can have at least one buffer element on which at least one of the contact surfaces is arranged. The at least one buffer element can be formed in an opening of the elastic body. The at least one elastic body can also have two or more buffer elements. The opposing contact surfaces can be provided on the buffer elements. When the elastic bearing is loaded, the buffer elements can be moved towards one another and come into contact with one another with their contact surfaces. As a result of this contact, the buffer elements can be compressed when the elastic bearing is loaded.

The elastic bearing can have at least one reinforcement which is at least partially embedded in the at least one elastic body. The at least one reinforcement can be a thread reinforcement, textile reinforcement, sheet metal reinforcement or wire reinforcement. The reinforcement can be a strap, a ring or a film. The reinforcement can be a textile band or a textile ring. The reinforcement can be a woven tape. The woven tape may have gaps that allow the elastomer to flow as the elastomer is injected. The reinforcement can also be a scrim made of parallel single threads. The individual threads can be connected to one another via one or more transverse threads. The reinforcement can also have cross layers. The material of the elastic body can be an elastomer, rubber or even a silicone.

The elastic bearing can have at least one first receiving opening and at least one second receiving opening, around which the at least one reinforcement extends at least in sections. The predetermined surface structure can have a corrugation, an engraving or a pattern structuring the surface.

The elastic bearing can have at least two bending beams and at least two joint sections. The elastic bearing can have four bending beams, two of which are connected to one another via a joint section. In each case a receiving opening can be provided at the transition between two bending beams. The at least one reinforcement can extend in the bending beam, the joint sections and on the outside around the receiving openings. The elastic bearing can be constructed symmetrically in relation to a straight line extending through the at least two joint sections. Additionally or alternatively, the elastic bearing can also be constructed symmetrically in relation to a straight line extending through the receiving openings. The intersection of these two straight lines can define the component center of the elastic bearing. The elastic bearing can be constructed symmetrically in relation to the straight line extending through the at least two joint sections or in relation to the straight line extending through the receiving openings.

• 1 eine Ansicht eines elastischen Lagers gemäß einer ersten Ausführungsform;
• 2 eine Schnittansicht entlang der Schnittlinie II-II in 1;
• 3 eine Ansicht eines elastischen Lagers gemäß einer weiteren Ausführungsform;
• 4 eine Ansicht eines elastischen Lagers gemäß einer weiteren Ausführungsform;
• 5 eine Ansicht eines elastischen Lagers gemäß einer weiteren Ausführungsform; und;
• 6 bis 8 Ansichten verschiedener Ausführungsvarianten von Profilelementen an einer Berührflächen.

Exemplary embodiments of the present invention are described below with reference to the accompanying figures. They represent:

• 1 a view of an elastic bearing according to a first embodiment;
• 2 a sectional view along the section line II-II in 1 ;
• 3 a view of an elastic bearing according to a further embodiment;
• 4th a view of an elastic bearing according to a further embodiment;
• 5 a view of an elastic bearing according to a further embodiment; and;
• 6th until 8th Views of different design variants of profile elements on a contact surface.

1 shows a view of an elastic mount 10 according to a first embodiment. The elastic bearing 10 has an elastic body 12th on. The elastic body 12th has four bending beams 14th , 16 , 18th , 20th . The bending beam 14th and 16 are about a hinge section 22nd connected with each other. The bending beam 18th and 20th are about a hinge section 24 tied together. The elastic body 12th also has two receiving openings 26th and 28 on. The receiving openings 26th and 28 are designed to accommodate coupling elements such as bolts (not shown) that are attached to the elastic bearing 10 devices to be connected are provided. The coupling elements can be provided, for example, on a body of a vehicle and an exhaust system of the vehicle, via the elastic mount 10 to be attached to the vehicle body.

In the elastic body 12th a reinforcement, not shown, extends. The reinforcement extends along the bending beam 14th , 16 , 18th , 20th and the hinge sections 22nd and 24 . The reinforcement runs from the receiving opening 26th to the receiving opening 28 . The reinforcement runs around the receiving openings 26th and 28 outside to from one of the bending beams 14th , 16 , 18th , 20th into another bending beam 14th , 16 , 18th , 20th to pass over. The reinforcement can be a thread reinforcement, a textile reinforcement, sheet metal reinforcement or wire reinforcement. The reinforcement can be ring-shaped or be formed in a band shape. A textile reinforcement can be formed from at least one textile tape. The ends of such a textile tape can be connected to one another. For example, the ends can be sewn or woven together. A thread reinforcement can be formed from one thread or several threads. The thread or threads can form a scrim or a winding. It is also possible that the threads are connected to one another.

The elastic bearing 10 is related to the through the receiving openings 26th and 28 running straight line G constructed symmetrically. In addition, the elastic bearing 10 based on one through the joint sections 22nd and 24 The straight line is symmetrical, the one in 1 corresponds to the drawn section line II-II. The intersection of the two straight lines can be the center of the elastic bearing 10 define.

The elastic body 12th has an opening 30th with one wall 32 on. The opening 30th extends between the receiving openings 26th , 28 who have favourited bending beams 14th , 16 , 18th , 20th and the hinge sections 22nd and 24 . In the opening 30th are buffer elements 34 and 36 provided that is in the opening 30th to extend towards each other. The buffer elements 34 and 36 extend in sections along the straight line G. The buffer elements 34 , 36 extend from the area of the elastic body 12th with the receiving openings 26th , 28 into the opening 30th into it. The distance between the reinforcement and the wall 32 the opening 30th in the elastic body 12th can proceed from one of the receiving openings 26th , 28 in the direction of one of the hinge sections 22nd , 24 decrease. The distance between the reinforcement and an outer surface AF of the elastic body 12th can proceeding from the receiving openings 26th , 28 in the direction of one of the hinge sections 22nd , 24 gain weight.

The elastic body 12th has first contact 38 and a second touch surface 40 . The first point of contact 38 is located on the buffer element 34 . The second contact area 40 is on the buffer element 36 intended. The first point of contact 38 and the second contact surface 40 lie opposite each other. The two contact surfaces 38 , 40 each have an area with a predetermined surface structure 42 , 44 on. The surface structure 42 , 44 every contact surface 38 , 40 has profile elements 46 , 48 . The profile element 46 extends from the first contact surface 38 towards the second contact surface 40 . The profile element 48 extends from the second contact surface 40 towards the first contact surface 38 . The profile elements 46 , 48 are as protrusions on the contact surfaces 38 , 40 trained and stand by the contact surfaces 38 , 40 before. In the unloaded state of the camp 10 point the contact surfaces 38 , 40 a predetermined distance A from one another, which is determined by the predetermined surface structures 42 , 44 at the contact surfaces 38 , 40 can be reduced in areas, sections or selectively.

When the elastic bearing is loaded 10 the receiving openings 26th , 28 approach one another essentially along the straight line G. The contact surfaces also approach 38 , 40 to each other and can come into contact with each other. The buffer elements 34 and 36 are compressed, whereby the receiving openings 26th , 28 continue to approach each other. When the camp is relieved 10 remove the receiving openings 26th and 28 from each other and there is a separation of the contact surfaces 38 and 40 . With the predetermined surface structures 42 , 44 at the contact surfaces 38 , 40 can prevent the contact surfaces 38 and 40 stick to each other and when loosening the contact surfaces 38 , 40 develop undesirable noises from each other. The predetermined surface structure 42 , 44 According to this embodiment, the profile elements 46 and 48 includes, ensures that the separation of the contact surfaces 38 , 40 is stretched over a longer period of time and does not occur suddenly. Especially the sudden separation of the contact surfaces 38 , 40 from each other in relieving the camp 10 can lead to the unwanted noises.

At the joint sections 22nd , 24 are on the inside or the wall 32 Notches 50 and 52 in the elastic body 12th recognizable. Also in the receiving openings 26th and 28 are in the area in which the reinforcement has the receiving openings 26th , 28 running around, notches 54 , 56 in the elastic body 12th intended.

2 FIG. 11 shows a sectional view along the section line II-II in FIG 1 . The section line II-II runs through the joint sections 22nd , 24 and by the distance A between the contact surfaces 38 , 40 .

The interface 40 is on the buffer element 36 intended. The interface 40 has the predetermined surface structure 44 . The predetermined surface structure has two profile elements 48 and 58 on. The profile elements 48 and 58 are oval and stand from the contact surface 40 before. The profile elements 48 and 58 can also be formed by elevations or knobs. The buffer element 36 is central in the opening 30th between the joint sections 22nd and 24 intended.

In the sectional view according to 2 is on the joint sections 22nd , 24 the reinforcement 60 recognizable. The reinforcement 60 extends into the bending beam 14th , 16 , 18th , 20th , the joint sections 22nd , 24 and around the receiving openings 26th , 28 outside around. In other words, the reinforcement runs around 60 the opening 30th and the receiving openings 26th , 28 as well as the buffer elements 34 , 36 . The buffer elements 34 , 36 and the receiving openings 26th , 28 are located within the reinforcement 60 . The reinforcement 60 points in the area of the joint sections 22nd , 24 a relatively small distance to the wall 32 the opening 30th on.

3 Figure 3 shows a perspective view of an elastic mount 10 according to a further embodiment. This in 3 The elastic bearings shown can be referred to as fixed cage bearings. Other than that with regard to the 1 and 2 described bearing, which is a self-aligning bearing, becomes the bearing 10 according to 3 fixedly attached to a structural element (not shown) such as the body of a vehicle. In contrast, it can 1 and 2 shown self-aligning bearings 10 around one, for example, in the receiving opening 26th swing the captured bolt.

The warehouse 10 has a cage (not shown) formed by sheet metal or wire reinforcement, which is inserted into the elastic body 12th is embedded. The warehouse 10 has a fastening portion 62 on. The cage, not shown, extends essentially along the edge of the elastic body 12th . The fastening section 62 has two mounting holes 64 and 66 . Via the fastening openings 64 and 66 can the camp 10 for example, be connected to the structural element, not shown. The elastic body 12th is between the mounting holes 64 and 66 on the attachment portion 62 arranged.

The elastic body 12th has a receiving section 68 with a receiving opening 70 . The receiving section 68 is of two openings 72 and 74 surround. The receiving section 68 is about footbridges 76 and 78 with the edge R of the elastic body 12th or the area of the elastic body 12th connected to the cage. The bridges 76 and 78 and the receiving section 68 separate the two openings 72 and 74 from each other.

The receiving section 68 has two (first) contact surfaces 80 , 82 on. The contact surfaces 80 and 82 are opposite to each other on the receiving portion 68 educated. The contact surfaces 80 , 82 are arched. The interface 80 forms a section of the wall 84 the opening 72 . The interface 82 forms a section of the wall 86 the opening 74 . On the fastening section 62 is a second contact surface 88 formed that of the first contact surface 80 opposite. The contact surfaces 80 and 88 are thus facing each other. The interface 88 is arched and also forms a section of the wall 84 the opening 72 . The first contact area 82 is the second contact surface 90 opposite to. The interface 90 forms like the contact surface 82 a section of the wall 86 the opening 74 . The elastic body 12th thus has two first contact surfaces 80 , 82 and two second contact surfaces 88 and 90 that are opposite each other in pairs.

The interface 80 on the receiving portion 68 has a predetermined surface structure 92 that is a profile element 94 having. The interface 90 has a predetermined surface structure 96 with profile elements 98 and 100 . It can also be on the contact surfaces 82 and 88 predetermined surface structures may be formed, which, however, in 3 are not recognizable.

4th Figure 3 shows a perspective view of an elastic mount 10 according to a further embodiment. The elastic bearing 10 according to 4th can also be referred to as a cage self-aligning bearing. The warehouse 10 has a cage (not shown) formed by sheet metal or wire reinforcement, which is inserted into the elastic body 12th is embedded. The elastic body 12th has a receiving portion 68 with a receiving opening 70 on. The elastic body 12th has another opening 102 on. In the receiving opening 102 For example, a bolt-shaped coupling element can be added with which the bearing 10 can be attached to a structural element. The elastic bearing can be used around this coupling element 10 according to 4th commute.

The receiving section 68 is of two openings 72 and 74 surround. The receiving section 68 is about footbridges 76 and 78 with the edge R of the elastic body 12th tied together. The bridges 76 and 78 and the receiving section 68 separate the two openings 72 and 74 from each other. The receiving section 68 has two (first) contact surfaces 80 , 82 on. The first two contact surfaces 80 and 82 are opposite to each other on the receiving portion 68 educated. The contact surfaces 80 , 82 are arched. The interface 80 forms a section of the wall 84 the opening 72 . The interface 82 forms a section of the wall 86 the opening 74 .

The elastic body 12th has another bridge 104 on which a second contact surface 106 is trained. Between the jetty 104 and the receiving opening 102 is another opening 108 in the elastic body 12th educated.

The second contact area 106 is the first contact surface 80 opposite to. The contact surfaces 80 and 106 are thus facing each other. The interface 106 is arched. The second contact area 106 is opposite to the first contact surface 80 arched. The second contact area 106 forms also a section of the wall 84 the opening 72 . The first contact area 82 there is a second contact surface 90 opposite to. The second contact area 90 forms like the contact surface 82 a section of the wall 86 the opening 74 . The elastic body 12th has two first contact surfaces 80 , 82 and two second contact surfaces 90 , 106 facing each other in pairs.

The interface 80 on the receiving portion 68 has a predetermined surface structure 92 . Also the contact surface 90 has a predetermined surface structure 96 . The predetermined surface structures 92 , 96 can be formed from knobs, points or similar elements. It can also be on the contact surfaces 82 and 106 predetermined surface structures be formed.

5 Figure 3 shows a perspective view of an elastic mount 10 according to a further embodiment. The warehouse 10 is designed as a self-aligning bearing. The elastic bearing 10 has an elastic body 12th on. The elastic body 12th has openings 110 and 112 on. The elastic body 12th has an opening 114 with one wall 116 on.

In the opening 114 are buffer elements 118 and 120 provided that is in the opening 114 to extend towards each other. The first point of contact 122 is located on the buffer element 118 . The second contact area 124 is on the buffer element 120 intended. The first point of contact 122 and the second contact surface 124 lie opposite each other. The second contact area 124 has an area with a predetermined surface structure 126 on. The predetermined surface structure 126 can be formed from several knobs, points, corrugations or similar elements. It can also be applied to an area of the second contact surfaces 124 a predetermined surface structure can be formed.

the 6th , 7th and 8th each show schematic views of different design variants of profile elements on a contact surface 128 can be provided.

6th shows a contact surface 128 with two profile elements that act as lenticular elevations 130 , 132 are trained. Such profile elements are for example on the elastic bearing 10 according to the 1 and 2 intended. The profile elements 130 , 132 , which form a predetermined surface structure, have an oval cross section and protrude from the contact surface 128 before. An edge was the transition between the contact surface 128 and the rises 130 , 132 , The edge K forms a peripheral edge of the elevations 130 , 132 .

7th shows profile elements as transverse crossbars 134 , 136 are trained. The cross bars 134 , 136 run along the entire transverse extent of the contact surface 128 . The edges K also extend over the entire transverse extent of the contact surface 128 and form the transition to the bars 134 , 136 . The cross bars 134 , 136 can also be shorter than the transverse extension of the contact surface 128 be. Several shortened transverse webs can also be provided.

8th shows profile elements in the form of longitudinal webs 138 , 140 . The longitudinal bars 138 , 140 run along the entire length of the contact surface 128 . The edges K also form the transition from the contact surface in this embodiment variant 128 to the jetties 138 , 140 . The longitudinal bars 138 , 140 however, they can also be shorter than the longitudinal extension of the contact surface 128 be. Several shortened longitudinal webs can also be provided.

With the above-described surface structures on at least one of the contact surfaces of an elastic bearing, undesirable noise developments can be avoided, for example when using such an elastic bearing on a vehicle. When the elastic bearing is loaded, the mutually opposite contact surfaces can come into contact with one another and adhere to one another. Unwanted noises can occur when the elastic bearing is relieved and the contact surfaces are separated as a result. Such undesirable noises can be avoided with the surface structures on the contact surfaces. In addition, the contact surfaces can remain in contact with the surface structures of the contact surfaces for a longer period of time in regions and / or at certain points, thereby preventing a sudden or sudden separation of the contact surfaces. Often the undesired noises arise with such a sudden or sudden separation of the contact surfaces, which are prevented with the invention.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 10013121 C1 [0002]

Claims (10)

Elastic bearing (10), especially for suspending a load, with: at least one elastic body (12), the at least one elastic body (12) having at least one receiving opening (26, 28) for receiving at least one coupling element, the at least one elastic body (12) at least one first contact surface (38) and at least has a second contact surface (40), wherein the at least one first contact surface (38) and the at least one second contact surface (40) are opposite one another, wherein at least one of the contact surfaces (38, 40) in at least one area has at least one predetermined surface structure (42, 44). Elastic bearing (10) according to Claim 1 , wherein a distance (A) between the first contact surface (38) and the second contact surface (40) with the predetermined surface structure (42, 44) on at least one of the contact surfaces (38, 40) is reduced. Elastic bearing (10) according to Claim 1 or 2 wherein the at least one surface structure (42, 44) has at least one profile element (46, 48) which protrudes from one of the contact surfaces (38, 40) in the direction of the respective other contact surface (38, 40). Elastic bearing (10) according to Claim 3 , wherein the at least one profile element (46, 48) has at least one edge (K) which forms the transition between one of the contact surfaces (38, 40) and the at least one profile element (46, 48) on this contact surface (38, 40) . Elastic bearing (10) according to Claim 3 or 4th wherein the area of the at least one profile element (46, 48) is smaller than the area of the contact surface (38, 40) on which the at least one profile element (46, 48) is arranged. Elastic bearing (10) according to one of the Claims 3 until 5 , wherein the at least one profile element (46, 48) is formed by an elevation, a projection or a web (134, 136, 138, 140). Elastic bearing (10) according to one of the Claims 1 until 6th wherein the at least one elastic body (12) has at least one buffer element (34, 36) on which one of the contact surfaces (38, 40) is arranged. Elastic bearing (10) according to one of the Claims 1 until 7th wherein the elastic bearing (10) has at least one reinforcement (60) which is at least partially embedded in the at least one elastic body (12). Elastic bearing (10) according to one of the Claims 1 until 8th , wherein the elastic bearing (12) has at least one first receiving opening (26) and at least one second receiving opening (28) around which the at least one reinforcement (60) extends at least in sections. Elastic bearing (10) according to one of the Claims 1 until 9 , wherein the predetermined surface structure (42, 44) has a corrugation, an engraving or a pattern structuring the surface.

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