DE10235285A1 - Belt drive motion dampening mechanism has rolling body in contact on both sides with inner face of outer body and outer face of inner body - Google Patents

Abstract

A belt drive has a belt tensioning device with a housing containing a spring-action dampener acting in conjunction with a moving arm. the dampener esp. consists of cylindrical inner and outer parts which are separated by a rolling or sliding body (9). The inner face of the outer section and outer face of the inner section generate dampening forces (F1, F2) by their relative motion.

Description

field of use the invention

The invention relates to a clamping device for a Belt drive, with a device housing to accommodate spring and damping agents, with a tensioning arm rotatably mounted on it and with one on the free Pressure means arranged at the end of the tensioning arm.

background the invention

To prevent a drive belt from slipping on the drive sheaves of a belt drive, the drive belt is generally deflected from its uninfluenced wrap path by means of a tensioning device acting on the belt between the drive sheaves, thus generating the necessary pretensioning force which presses the belt onto the drive sheaves. Such tensioners essentially consist of a non-rotatably arranged housing on which a tension arm for a belt pressure roller is pivotally mounted. A spring damping device is located in the housing, the spring being supported on the one hand on the housing and acting on the tension arm with its other end. The damping mechanism ensures that the belt vibrations occurring in such a drive system are limited to a tolerable level. According to the prior art, such a damping device usually consists of brake bodies which are fastened either to the housing or to the tensioning arm and act with a certain contact force on a counter surface which is effective with respect to the rotational movement of the tensioning arm. Such belt tensioners are for example from the DE 3419 969 A1 and the DE 37 28 158 A1 are known in which annular rubber-elastic elements fulfill the braking or vibration damping function. A disadvantage of these damping devices is that they are subject to abrasive wear and in some cases, lubricants must also be used in order to achieve a desired damping effect.

CH 31 62 36 also shows the CH 32 49 87 roller bearings, which essentially consist of an outer part, an inner part and there are rubber-elastic rolling elements arranged in between. With these roller bearings is the distance between the relatively movable bearing parts smaller than the diameter of the rolling elements before they are inserted in the rolling bearing, so that on the rolling elements used radial bias acts. The rolling elements point before being inserted into the space between the inner part of the bearing and the outer part of the bearing an approximation round cross section. Depending on the preload given to the rolling elements perform as a result of molecular rearrangement within it, but without any further change in shape run, a twist of the two parts mentioned in relation to each other a larger or smaller resistance. Such bearings are also according to these publications Can be used as a movement damper to a certain extent.

Based on this prior art, the object of the invention is to provide a belt tensioning device according to the DE 34 19 969 A1 to be further developed in such a way that less expensive production and better operating behavior can be achieved.

Summary the invention

The solution to this problem results derive from the features of the main claim, while advantageous embodiments and developments of the invention can be found in the subclaims.

Accordingly, it is provided that the Clamping device for a belt drive with a device housing for receiving spring and damping agents, with a rotatably mounted tension arm and with one on the free end of the clamping arm arranged pressing means is designed so that the damping agent from a hollow cylindrical outer part and a cylindrical inner part, between which rolling or sliding are arranged, the inside of the outer part, the surface of the Inner part and / or the rolling or sliders are designed such that on these or on these components opposite area when applied with a force and with relative movement to each other the rolling or sliding resistance of the rolling or Sliding body increasing and dampening acting macroscopic surface deformation the components are created. The outer part can be used as an outer housing part and the inner part as the inner part of the housing be trained.

Provision can also be made for one or both of the opposite sides of the outer part and inner part of the damping device to be designed to be viscoelastic or automatically reversible and the rolling or sliding bodies are made of a metallic material. With a relative movement of the inner part and outer part to each other and when the rolling elements are subjected to a contact pressure, these rolling elements can penetrate into this elastic layer and constantly perform deformation work along their runway, which has a damping effect on the movement of the tensioning arm. This deformation behavior is achieved, for example, in that the outer part and / or the inner part of the damping device have surfaces that face one another and that are made of an elastomer or egg nem another, preferably a polymer material, which allow a reversible deformation of the surfaces.

In contrast, in another embodiment the ending should be provided that the inner part and the outer part rigid surfaces have and the rolling elements an elastomer or other elastic material. This ensures that these rolling elements when loaded with a preload or normal force in macroscopic dimensions are deformed such that when the outer part moves or the inner part relative to each other to dampen the deformation work the mobility of the clamping arm of the clamping device acts. at this damping device are also elastically non-deformable rolling elements between the inside of the outer part and the surface of the inner part arranged as a spacer for the elastic deformable rolling elements are used. there the diameter of the elastically deformable rolling elements is larger than the diameter of the elastically non-deformable rolling elements.

In a further variant of the invention there is the inside of the outer part, the surface of the Inner part and / or the surface the rolling or sliding made of a flexible or elastic material layer, which is a viscous material includes, the rolling elements in turn consist of a material that is not independently reversibly deformable is.

Another variant of the design principle according to the invention stipulates that the inside of the outer part or the surface of the A rigid surface on the inside with sliding bodies formed on it has while the opposite surface one comparatively soft surface a material with automatic has reversibly elastic deformation behavior.

Finally, it can be provided that the damping device is part of the swivel bearing for the tension arm and is included preferably as a tapered roller, angular contact ball or deep groove ball bearing is formed, the rolling or sliding body one spherical, can have cylindrical, conical or needle-shaped geometry.

Ultimately, it is considered useful if the pressure medium the tensioning device is designed as a roller or sliding shoe.

Short description of the drawings

The invention can be described on the basis of exemplary embodiments explain, that in the attached drawing are shown. In it show:

1 1 shows a schematic illustration of a belt tensioning device,

2 2 shows a schematic cross-sectional illustration of the damping device of the belt tensioning device,

3 another variant of the damping device and

4 a damping device without rolling elements.

Full Description of the drawings

The representation according to 1 shows a schematic side view of a belt tensioner 1 with a drive belt 2 is deflected into a prestressed position. The belt tensioner 1 consists essentially of a housing 5 that by means of a connector 6 non-rotatable on a component 16 a drive device is attached. At the free end of this connector 6 is an inner part 8th of the housing 5 fixed non-rotatably, the coaxially from an outer housing part 7 is surrounded. Between these two housing parts 7 . 8th are rolling elements 9 inserted so that the outer housing part 7 and the housing inner part 8th are rotatable against each other.

With the outer casing 7 is a tension arm 4 connected, a pressure roller at its free end 3 for the drive belt 2 wearing. The tension arm 4 is together with the pressure roller 3 of a Fe, not shown separately here, with a force F against the drive belt 2 pressed so that it is preloaded accordingly.

The belt tensioner 1 also has a damping mechanism that ensures that the tension arm 4 quiet on the drive belt 2 is applied and is not excited to torsional vibrations due to belt vibrations.

How 2 can be removed, the embodiment of the damping device according to the invention shown there, deviating from the previously customary damping systems, consists of macroscopically non-deformable rolling elements 9 between the macroscopically automatically reversibly deformable surfaces 18 . 19 of the outer part 7 and the inner part 8th of the housing 5 are arranged. These deformable surfaces 18 . 19 can be formed from an elastomer layer or another suitable polymer material layer, which is on the inside of the housing outer part 7 and / or on the outside of the inner part 8th are trained.

The between the housing inner part 8th and the housing outer part 7 arranged rolling elements 9 cause when these parts are loaded 7 . 8th with a force F1, F2 an elastic deformation of the surfaces 18 . 19 of the housing outer part 7 and the housing inner part 8th that occur after the rolling elements pass 9 due to the relative movement of these two parts 7 . 8th back to each other. The deformation energy applied expresses itself with regard to the rolling elements 9 in an increased rolling resistance compared to non-deformable rolling surfaces, which is used as a damping effect for the belt tensioning system. The on the rolling body 9 acting force F1, F2 is preferably by an axially on the housing outer part 7 or the inner part of the housing 8th acting axial spring, which is not shown separately here.

In another embodiment of the invention it can be provided that at least one of the surfaces of the housing outer part facing one another 7 and / or the housing inner part 8th consist of a flexible plastic film.

This flexible plastic film closes between itself and the metallic part of the inner and / or outer part of the housing 7 . 8th a viscoelastic liquid that is required for and on the rotational movement of the tension arm 4 damping elastic deformation of the plastic film when the rolling elements roll past 9 provides.

The rolling elements 9 themselves can be designed as steel balls and be part of the rolling bearing, with which the pivoting of the clamping arm 4 is achieved. This ball bearing can be designed as a tapered roller bearing, an angular contact ball bearing or as a deep groove ball bearing, the rolling elements 9 have a spherical, cylindrical, conical or needle-like geometry. This integration of the damping device in the ball bearing for the tension arm 4 allows a particularly compact and inexpensive manufacture of the belt tensioning device according to the invention.

In the in 3 shown variant of the belt tensioning device according to the invention have the inside of the housing outer part 10 and the outside of the housing inner part 11 a hard and macroscopically non-deformable surface. There are rolling elements between these housing parts 17 arranged, which are not elastically deformable and the distance between the inside of the housing outer part 10 and the surface of the housing inner part 11 determine under the action of a force F1, F2. There are also rolling elements in this space 12 arranged, which are reversibly elastically deformable, so that deformation work must be performed when they roll.

How 3 can be clearly seen is the distance between the inside of the housing outer part 10 and the surface of the housing inner part 11 chosen so that it is smaller than the diameter of an elastically not deformed and initially approximately circular rolling element 12 , These rolling elements 12 can consist of an elastomer or another self-reversibly deforming polymer material. It can also be provided that the rolling elements 12 consist of a spherical plastic film that is a viscoelastic liquid 16 includes in itself.

The elastically non-deformable rolling elements 17 In addition to their usual bearing tasks in a rolling bearing, they also perform the function of spacers for the elastic rolling elements, which are larger in diameter 12 so that this damping bearing for the tension arm 4 a belt tensioner 1 optionally also without an axial force on the elastic rolling elements 12 producing spring can be produced. In this embodiment of the invention, it acts solely by the positive joining of the two housing parts 7 . 8th with the interposition of the elastically non-deformable rolling elements 17 on the elastically deformable rolling elements 12 a normal force F1, F2, which in the static state is a flattening of the rolling elements 12 and with a relative movement of the housing outer part 10 and housing inner part 11 to each other a circumferential deformation of the elastic rolling elements 12 caused. In this way, a rolling resistance is generated, as a result of which a damping effect on the deflection movement of the tension arm 4 the belt tensioner 1 is effected.

4 shows, however, another embodiment of the design principle according to the invention, in which the damping device without rolling elements between the inside of the housing outer part 13 and the surface of the housing inner part 14 gets along. These are on the inside of the outer housing part 13 rigid sliding body 15 formed, the radially inwardly facing ends in the elastically reversibly deformable material 20 of the housing inner part 14 Push. With a relative movement of these two housing parts indicated by the horizontal arrow 13 . 14 to each other and the action of a force F1, F2 on at least one of these housing parts cause the sliding body 15 a deformation of the elastic material 20 of the housing inner part 14 , which automatically reversibly regresses when the respective sliding body 15 moving away from this place. The necessary deformation work causes the described damping behavior with regard to the mobility of the tension arm 4 , With this damping device, a lubricant will have to be used in individual cases between the surfaces that come into contact, with the aid of which, if necessary, adhesive forces between the sliding bodies 15 and the inner part surface 20 can be reduced.

1

Belt tensioner

2

drive belts

3

pressure means

4

clamping arm

5

casing

6

connector

7

outer part

8th

inner part

9

rolling elements

10

outer part

11

inner part

12

rolling elements

13

outer part

14

inner part

15

sliding

16

Viscous material

17

not Elastic rolling elements

18

Reversible elastic material

19

Reversible elastic material

20

Reversible elastic material

F1

force

F2

force

Claims (12)

Tensioning device for a belt drive, with a device housing ( 5 ) to accommodate spring and damping devices, with a clamping arm rotatably mounted on it ( 4 ) and with one at the free end of the tension arm ( 4 ) arranged pressing means ( 3 ), characterized in that the damping means consists of a hollow cylindrical outer part ( 7 . 10 . 13 ) and a cylindrical inner part ( 8th . 11 . 14 ) exists between which rolling or sliding bodies ( 9 . 12 . 15 ) are arranged, and that the inside of the outer part ( 7 . 10 . 13 ), the surface of the inner part ( 8th . 11 . 14 ) and / or the rolling or sliding bodies ( 9 . 12 . 15 ) are designed in such a way that the rolling or sliding resistance of the rolling or sliding bodies () on these or on the surface opposite these components when they are subjected to a force (F1, F2) and when they move relative to one another ( 9 . 12 . 15 ) increasing macroscopic surface deformation occurs. Tensioning device for a belt drive according to claim 1, characterized in that the with the rolling or sliding bodies ( 9 . 12 . 15 ) contacting side (18) of the outer part ( 7 ) and / or the side (19, 20) of the inner part ( 8th . 14 ) have an automatically reversible elastic deformation behavior. Tensioning device for a belt drive according to claim 2, characterized in that the outer part ( 7 ) and the inner part ( 8th . 14 ) facing surfaces ( 18 . 19 . 20 ) consists of an elastomer or of another automatically reversibly elastic material, preferably a polymer material. Tensioning device for a belt drive according to claim 1, characterized in that the rolling elements ( 12 ) consist of an elastomer or of another automatically reversibly elastic material, preferably a polymer material. Tensioning device for a belt drive according to claim 4, characterized in that elastically non-deformable rolling elements ( 17 ) between the elastically non-deformable inside of the housing outer part ( 10 ) and the elastically non-deformable surface of the housing inner part ( 11 ) are arranged. Tensioning device for a belt drive according to claim 4 and 5, characterized in that the diameter of the elastically deformable rolling elements ( 12 ) is larger than the diameter of the elastically non-deformable rolling elements ( 17 ). Tensioning device for a belt drive according to at least one of claims 1 to 3, characterized in that the inside of the outer part ( 7 . 10 . 13 ), the surface of the inner part ( 8th . 11 . 14 ) and / or the surface of the rolling or sliding bodies ( 9 . 12 . 15 ) consists of a flexible material layer that is a viscous material ( 16 ) includes. Tensioning device for a belt drive according to at least one of the preceding claims, characterized in that the rolling or sliding bodies ( 9 . 15 . 17 ) consist of a metallic material. Tensioning device for a belt drive according to at least one of the preceding claims, characterized in that the damping means are components of a roller bearing, preferably a tapered roller, angular ball or deep groove ball bearing, in particular for mounting the tensioning arm ( 4 ) are. Tensioning device for a belt drive according to claim 8, characterized in that the rolling or sliding body ( 9 . 12 . 15 . 17 ) have a spherical, cylindrical, conical or needle-shaped geometry. Tensioning device for a belt drive according to at least one of the preceding claims, characterized in that the inside of the outer part ( 13 ) or the surface of the inner part ( 14 ) over a rigid surface with sliding bodies formed on it ( 15 ), while the opposite surface is made of one material ( 20 ) with viscoelastic or automatically reversible elastic Deformation behavior exists. Tensioning device for a belt drive according to at least one of the preceding claims, characterized in that the pressing means ( 3 ) is designed as a roller or sliding shoe.