DE4439834A1 - Belt tensioner for belt or chain drive - Google Patents

Abstract

The tension device (1) adjoins the machine part (14) through a bearing flange (13a) which is connected integral with the adjustment eccentric (12). A spring is inserted between a spring support sleeve (16) and work eccentric and the spring support sleeve (16) is rotatable on the bearing flange. The bearing flange can be concentric with a bore set in the adjustment eccentric (12). A disc (22a) guided on the bearing flange can be rotationally fixed through a pin (24a) in a blind hole bore (25) on which the support sleeve is secured against rotation.

Description

The invention relates to a tensioning device for a belt or Chain drive in particular according to the generic features of Claim 1.

Clamping devices of this type, provided with a spring force beating, swiveling idler pulley are for example for belt drives provided in internal combustion engines to keep the belt tension constant nung. The tensioning pulley is adjusted to the belt depending on dynamic or quasi-static changes, such as B. Wear, elongation, temperature-dependent changes in tension or partial stretching of the belt under impulse loads.

From DE-A 40 33 777 is a tensioning device with an adjustment eccentric known on a mounting bolt for adjustment is rotatable. Coaxially around and on the eccentric there is a spring-loaded work eccentric on which one Tension roller is rotatably arranged. To fix the device in rotation is a pin in the base plate connected to the adjustment eccentric provided which engages in a recess of the machine part which the clamping device is attached.

When adjusting the setting eccentric, in which this is in the base plate rotates, there is disadvantageous relative displacement Exercise of the base plate on the machine part, for which a rotation fixation Elongated hole is required. In addition, the well-known instep device via a small one, which corresponds to the diameter of the setting eccentric appropriate contact surface, associated with the risk of tilting or  Tilting the device. The limited investment area can further increase an unstable, i.e. H. lead vibration-sensitive attachment.

The object of the invention is to plant the clamping device on Improve machine part and shift the spring support sleeve on the machine part during the adjustment of the adjustment eccentric to avoid.

In a device of the type mentioned, this task is performed by the characterizing part of claim 1 specified features.

Then the setting eccentric is on the side facing the machine part tied side via a contact flange, the radial dimensions of which Diameter of the setting eccentric clearly exceeded. The contact flange allows an advantageously large contact surface of the device where by itself a more stable, better against tilting or tilting secured and thus also vibration-resistant attachment results. It is advantageous to achieve effective external support diameter from the contact flange concentric to the mounting hole.

To prevent the spring support sleeve from contacting the machine part this advantageously guided on the contact flange, which does not lead to it an adverse displacement of the spring support sleeve on the machine part comes. The contact flange consequently provides an axial stop for the spring support sleeve. This design also allows an anti-rotation lock of the instep separated from the spring support sleeve device, which is advantageous via a pin in a mechanical engages easily manufactured hole, and thus on a previously The usual elongated hole is dispensed with.

According to claim 2 is the hole made in the adjustment eccentric to hold the screw with which the entire clamping device is to be screwed is introduced concentrically to the contact flange. So that results regardless of the position of the setting eccentric advantageously the same annular contact surface, without Relativver push against the contact surface when infeed by the setting eccentric.  

In one embodiment of the invention is a measure according to claim 3 me to increase the eccentricity. The generic Prior art shows one with a slight offset to the middle of the Adjustment eccentric mounting hole for the attachment screw of the clamping device. This presents a limited eccentric tricity and associated with it a disadvantageously small adjustment range a.

According to the invention is the hole for the screw with which the clamping device is attached to the outer surface of the working exzen ters offset, so as large a possible offset between the middle the eccentric and the hole for the screw. This results in a maximum eccentricity with distance between the center of the setting eccentric and the center of the hole for the Fixing screw is equivalent.

According to claim 4, a contact flange is provided, the only lies against the machine part via an outer annular surface, d. H. zen tric around the hole for the fastening screw of the tensioning device device is provided a circular recess. This design limits the required mechanical processing in the plant area on Machine part on a circular ring surface without the benefit of one having to do without a large contact area.

As stated in claim 5, serves as an anti-rotation device on the Flange guided washer, which has a pin that in a blind hole drilled in the machine part is rotationally fixed. The disc is in operative connection with the spring support sleeve. By concentric to the pivot point of the setting eccentric arranged disc is advantageous to prevent rotation in a Hole in the machine part protruding pin sufficient, in the difference to a previously required slot for one with the spring support sleeve-connected anti-rotation device to enable an actuating movement the spring support sleeve.

According to the invention, according to claim 6, the washer for securing against rotation provided with at least one stop on which a radially outward  directed arm of the spring support sleeve rests. Two are advantageous Stops are provided between which the arm during the adjustment the setting eccentric is effectively managed, d. H. the arm between the Attacks is postponed.

In one embodiment of the invention according to claim 7, the arm is the Provide the spring support sleeve at its free end with a pointer that with a pointer attached to a position ring an indicator for forms the spring preload. An optical one is therefore advantageous Control for the presetting of the setting eccentric created.

According to claim 8, the clamping device according to the invention with a Provide on the adjusting eccentrically arranged slide bearing on which the work eccentric is pivoted. In advantageous Design is the adjustment eccentric in the area of the attachment screw provided with a longitudinal groove, except for a free space for the mounting screw is filled with the plain bearing material. By this design creates a desired large distance between the center of the adjustment eccentric and the center of the screw determines the eccentricity.

To achieve a simple adjustment of the adjustment eccentric according to claim 9 at the opposite end of the contact flange Adjusted hexagon fixed in position. With the help of Adjusting tool an easily accessible and time-saving manual Adjustment of the setting eccentric ensured. It is advantageous the setting hexagon extends radially far beyond the setting eccentric and also covers one on the setting hexagon adjacent development of the plain bearing, which acts as a thrust bearing for the Serves eccentric.

By a pin attached to the work eccentric according to claim 10 a limitation of the pivoting movement of the working eccentric provides, wherein the pin extends into a recess of the hub with the base plate is connected.

To further explain the invention, reference is made to the drawing with the referenced figure descriptions, in which Ausführungsbei games further illustrate the invention. Show it:

Figure 1 is a sectional view of a tensioning device according to the invention in the installed state.

FIG. 2 is a partial top view of the tensioning device shown in FIG. 1 along the line AA;

Fig. 3 is an alternative to Figure 1 designed anti-rotation;

Fig. 4 is a rotation in a partial section according to the line CC of Fig. 3

Fig. 5 is a sectional view taken along line BB in Fig. 3.

The structure of a tensioning device 1 is first explained with reference to FIGS. 1 and 2. A tension roller 2 is then connected to a belt 3 via a belt drive (not shown in FIG. 1). The tension roller 2 is positively attached to an outer ring 4 of a rolling bearing 5 , the rolling elements 6 directly in a circulation groove, introduced into a lateral surface of a working eccentric 7 , leads. The designed as a hollow body eccentric 7 is pivotable on a slide bearing 8 and is with an end face 9 , be caused by a spring force application of a torsion spring 10 , at an angle 11 of the slide bearing 8 .

The sliding bearing 8 is fixed in a rotationally fixed positively locking or non-positively on an adjustment eccentric 12, which rests on a support flange 13 a on a machine part 14 and is fixed by means of an off-center immediately adjacent to the sleeve bearing 8 bolt 15 thereto. The contact flange 13 a is located centrally for fastening supply screw 15 . Between the support flange 13 a and the working eccentric 7 also a pivotable Federabstützhülse 16 in front is seen, the hub 17 is guided to the working eccentric 7, wherein a pin 19 projects of the working 7 in a recess 18 of the hub 17, to form a Verdrehbegrenzung for the work eccentric 7 .

The spring support sleeve 16 is used for the torsion spring 10 for further support, the ends of which are each positively attached to the work eccentric 7 and to the base plate 16 .

On the spring support sleeve 16 , a radially outward arm 20 is attached, which is guided between two stops 21 a, which together form an anti-rotation device between the components of the spring support sleeve 16 and the disc 22 a. For this purpose, the stops 21 a are integrally connected to the disc 22 a, which rests on the shoulder 23 between the spring support sleeve 16 and the contact flange 13 a. The disc 22 a is provided with a pin 24 a, which projects into a blind hole 25 of the machine part. The arm 20 of the spring support sleeve 16 is designed at the free end as a pointer 28 which, for example in connection with the pointer 29 , which is attached to the outer wall of the working eccentric 7 axially extending position ring 34 , illustrates the correct position of the setting eccentric 12 . At the opposite end of the contact flange 13 a of the adjusting eccentric 12 , the latter has an adjusting hexagon 26 or the like, which is connected to the adjusting eccentric 12 in a rotationally fixed manner by means of two members 27 offset from the screw 15 .

In Fig. 1 the difference between the previously usual contact surface and the contact surface according to the invention is illustrated. With "b" the contact surface of the tensioning device 1 according to the invention is marked net, which exceeds the previous contact surface "a" by a multiple and also lies centrally to the fastening screw.

Operation of the tensioning device

When tensioning the tensioning device 1 against the belt 3 , the screw 15 is loosened slightly. The tensioning device 1 is pivoted against the belt 3 with a gripping device on the adjusting hexagon 26 . The setting eccentric 12 rotates around the screw 15 and in the disk 22 and the spring support sleeve 16 . The adjustment range, the eccentricity results from the dimension "e" between the central axis (D) of the adjusting eccentric 12 and the central axis (E) of the screw 15 . Such rotation remains without influence on the Schei be 22 , which is arranged concentrically to the screw 15 , but which with the help of the stops 21 a and the arm 20 leads the Federab support sleeve 16 . The on the hub 17 directly on the A eccentric 12 arranged spring support sleeve 16 , however, performs a relative movement in which the angular position between the Federab support sleeve 16 and the torsion spring 10 and thus the working eccentric 7 remains unchanged. For presetting, the setting eccentric 12 is rotated so that the tensioning roller 2 is pressed against the belt 3 via the working eccentric 7 until the pointer 28 of the spring support sleeve 16 coincides with the pointer 29 of the positioning ring 34 connected in one piece with the working eccentric 7 . After pre-setting screw 15 is tightened. Belt expansions that occur are automatically compensated for by the work eccentric 7 with the aid of the torsion spring 10 , which ensures that the tensioning roller 2 abuts on the belt 3 under spring force.

From Fig. 3 and Fig. 4, a setting eccentric 12 can be seen men, which, in contrast to Fig. 1, a contact flange 13 b is provided with a central annular recess 30 directed towards the machine part. This results in an annular surface 33 , which serves as a contact surface for the clamping device 1 . In addition, the disk 22 b is radially guided on the contact flange 13 b captive rotatable, whereby the height of the clamping device 1 can advantageously be reduced ver.

FIG. 5 shows the up to the plain bearing 8 reaching bore 31 for the screw 15 to achieve a maximum distance to the central axis (D) of the adjustment eccentric (12) and the associated maximum eccentricity "e" (see Fig. 2). In the area of the bore 31 , the adjusting eccentric 12 is provided with a longitudinal groove 32 which, apart from the bore 31 , is filled with the material of the slide bearing 8 . This design ensures that the slide bearing 8 is effectively secured against rotation relative to the adjusting eccentric 12 .

Reference list

1 tensioning device
2 tension pulley
3 straps
4 outer ring
5 roller bearings
6 rolling elements
7 work centers
8 plain bearings
9 end face
10 torsion spring
11 angulation
12 eccentric
13 contact flange
14 machine part
15 screw
16 spring support sleeve
17 hub
18 recess
19 cones
20 arm
21 stop
22 disc
23 paragraph
24 pin
25 blind hole
26 eccentric
27 carriers
28 hands
29 hands
30 recess
31 hole
32 longitudinal groove
33 ring surface
34 position ring

Claims (10)

1.Tensioning device for a belt or chain drive with an adjustment eccentric, through which a screw is guided, with which the tensioning device attached to a machine part is fastened, and on a lateral surface of the adjustment eccentric, a pivotable spring-loaded working eccentric is arranged, which receives a roller bearing The roller is used, the spring being inserted between a spring support sleeve and the work eccentric, characterized in that the tensioning device ( 1 ) is connected to the machine part ( 14 ) via a contact flange ( 13 a, 13 b) connected in one piece with the adjustment eccentric ( 12 ). abuts and the spring support sleeve ( 16 ) on the on flange ( 13 a, 13 b) is rotatable. 2. Clamping device according to claim 1, characterized in that the contact flange ( 13 a, 13 b) is arranged concentrically with a bore ( 31 a, 31 b) introduced in the adjusting eccentric ( 12 ). 3. Clamping device according to claim 1, characterized in that a bore ( 31 ) in the adjusting eccentric ( 12 ) is offset up to the outer surface thereof, for receiving a screw ( 15 ). 4. Clamping device according to claim 1, characterized in that the contact flange ( 13 b) abuts an annular surface ( 33 ) on the machine part ( 14 ). 5. Clamping device according to claim 1, characterized in that on the contact flange ( 13 a, 13 b) a disc ( 22 a, 22 b) is guided, which via a pin ( 24 a, 24 b) in a blind hole ( 25 ) is rotationally fixed, on which the spring support sleeve ( 16 ) is secured against rotation. 6. Clamping device according to claim 5, characterized in that the disc ( 22 a, 22 b) is seen at least with a stop ( 21 a, 21 b) ver, on which a radially outward arm ( 20 ) of the spring support sleeve ( 16th ) is present. 7. Clamping device according to claim 6, characterized in that the arm ( 20 ) is provided at the end with a pointer ( 28 ) which forms a display for a spring preload with a pointer ( 29 ) attached to a position ring ( 34 ). 8. A clamping device according to claim 1, characterized in that the working eccentric (7) is pivotally mounted about a drehfixier on the adjustment eccentric (12) th plain bearings (8). 9. Clamping device according to claim 1, characterized in that the adjusting eccentric ( 12 ) at the opposite end of the contact flange ( 13 ) with an adjustment possibility, for. B. is provided an adjusting hexagon ( 26 ). 10. Clamping device according to claim 1, characterized in that to limit a pivoting movement of the working eccentric ( 7 ) it is provided with a pin ( 19 ) which projects in a recess ( 18 ) of a hub ( 17 ) of the spring support sleeve ( 16 ).