KR19980031158A - Tensioner of Belt - Google Patents

Abstract

The present invention relates to a tensioner (Tensioner) for adjusting the tension of the belt for transmitting the power of the drive shaft to the driven shaft, the moving body 10 in contact with the belt (B) and moves in accordance with the tension of the belt (B), A guide member 20 for guiding the movable body 10 so that the movable body 10 rotates eccentrically and linearly moves, and the movable body to adjust a relative movement between the movable body 10 and the guide member 20. A damper 50 disposed between the 10 and the guide member 20 and a plurality of intermediate members coupled to the movable body 10 to bring the damper 50 into close contact with the friction surface of the guide member 20. And a resilient means 70 disposed on the guide member 20 to apply a restoring force to the damper 50, the belt being moved by the moving body which is eccentrically rotated in contact with the belt B. At the same time as adjusting the tension to control the speed of change of the tension of the belt by the friction force of the damper Characterized in, and it is configured in this manner, it is able to respond appropriately to changes in the tension of the belt and at the same time as increasing the life of the belt smooth power transmission, it is possible to simplify the structure.

Description

Tensioner of Belt

The present invention relates to a tensioner that provides a constant tension to a belt that transmits power from a drive shaft to a driven shaft.

The transmission system that transmits the power of the drive shaft to the driven shaft by a belt such as a general belt or a timing belt is widely adopted in power transmission units such as automobiles because the noise is small and the power transmission distance can be increased.

In the power transmission method by the belt, the belt part separated from the drive pulley coupled to the drive shaft is relaxed, and the belt part closely attached to the drive pulley is tensioned. Therefore, the belt is relaxed to the relaxed side by applying a constant tension to the tensioning device to facilitate power transmission.

Conventionally, such a tension device has been fixed to impart a constant tension to the belt during initial transmission. In addition, as another example of a conventional tension device, a tension device for detecting a tension change of a belt due to a change in driving force and changing a tension applied to the belt by hydraulic pressure has also been developed.

By the way, the fixed tension device that imparts a constant tension to the belt during the initial initial transmission has no ability to adjust the tension change of the belt, so if the belt tension changes due to the change of the driving force, the belt is easily worn and the drive source (engine There is a problem that decreases the efficiency of).

In addition, the tension device that can change the tension applied to the belt by the conventional hydraulic pressure has a problem that the number of parts, the structure is complicated, the weight is large, and occupy a lot of installation space.

Accordingly, the present invention has been made to solve the above problems, and an object of the present invention is to appropriately respond to the tension change of the belt to increase the service life of the belt and at the same time to facilitate power transmission as well as a compact and simple structure of the belt To provide a tension device.

1 is an installation state of the tension device according to the present invention,

2 is a plan view of the tensioning device of the belt according to the present invention;

3 is a longitudinal sectional view of the tensioning device of the belt according to the present invention;

Figure 4 is a bottom view of the concave space of the eccentric member shown in Figure 3,

5 is a cross-sectional view taken along the line A-A in FIG. 4;

6 is a plan view of the damper shown in FIG.

FIG. 7 is a cross-sectional view taken along the arrow line B-B in FIG. 6;

8 is an explanatory view of the operation of the belt tensioning device according to the present invention.

Explanation of symbols on the main parts of the drawings

10: movable body 20: guide member

50: damper 60: intermediate member

70: elastic means 80: washer

B: belt

The tensioning device of the belt according to the present invention includes a movable body that contacts the belt and moves according to the tension of the belt, and a guide member for guiding the movable body so that the movable body rotates eccentrically and simultaneously moves linearly, between the movable body and the guide member. A damper disposed between the movable body and the guide member to adjust the relative movement of the plurality of media members coupled to the movable body to bring the damper into close contact with the friction surface of the guide member, and to apply a restoring force to the damper. It is provided with an elastic means disposed in the guide member, characterized in that to adjust the tension of the belt by the friction force of the damper while controlling the tension of the belt by the moving body eccentrically rotating in contact with the belt, characterized in that .

The movable body may include an eccentric member eccentrically coupled to an outer side of the guide member, a bearing coupled to an outer circumferential surface of the eccentric member to contact the belt, and the eccentric member to restrain the eccentric member to impart tension to the belt. It is preferable to have a restraining member coupled to the outside and a bush press-fitted inside the eccentric member so as to slide easily with the guide member.

One surface of the damper has a shape in which a plurality of grooves are formed along the circumferential direction so that the plurality of intermediate members are inserted.

It is preferable to have the circular arc surface which gradually deepens the groove | channel formed in the said damper, and the vertical surface which rises vertically.

The intermediate member is press-fitted into one surface of the eccentric member to be inserted into the groove of the damper.

The upper intermediate member preferably has a curved surface and a vertical surface corresponding to the inclined surface and the vertical surface of the groove, respectively.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figure 3, the moving body 10 in contact with the belt (B) to move in accordance with the tension of the belt is coupled to the outside of the guide member 20 to be guided by the guide member 20, the guide The member 20 is coupled to the base 40 by the fastening means 30, and the relative movement between the movable body 10 and the guide member 20 between the movable body 10 and the guide member 20. The damper 50 is disposed to adjust, and the intermediate member 60 is coupled to the movable body 10 to bring the damper 50 into close contact with the friction surface of the guide member 20, and the damper 50. The elastic member 70 is disposed in the guide member 20 so as to apply a restoring force. The washer 80 is fitted to the upper end of the guide member 20 so that the eccentric member, which will be described later, of the movable body 10 is not separated.

The movable body 10 and the eccentric member 11 eccentrically coupled to the outside of the guide member 20, the bearing 13 is coupled to the outer peripheral surface of the eccentric member 11 and in contact with the belt (B); The restraining member 15 coupled to the outer side of the eccentric member 11 to restrain the eccentric member 11 to impart tension to the belt B and the sliding member and the guide member 20 so as to slide easily. A bush 17 press-fitted into the eccentric member 11 is provided.

The eccentric member 11 has an eccentric hole 11a formed therein so as to press the bush 17 therein and guide the upper portion of the guide member 20, and a lower portion of the eccentric member 11 at the bottom thereof. The concave convex space 11b is formed to accommodate the damper 50 at the same time as it is accommodated, and has an outer flange 11c formed on the outer surface thereof so that the bearing 13 can be easily seated. The inner flange 11d is formed in the eccentric hole 11a so that the bush 17 can be easily seated.

The bearing 13 has an inner ring 13a and an outer ring 13b relative to each other with a plurality of balls 13c interposed therebetween, and protects the plurality of balls 13c outside the ball 13c. At the same time, the retainer 13d is coupled to maintain at regular intervals, and the seal member 13e is coupled to the outside of the retainer 13d to prevent foreign matter from penetrating into the ball 13c side. The inner ring 13a is press-fitted on the upper outer peripheral surface of the eccentric member 11, and the outer ring 13b has a shape in which the flange extends in the width direction so as to increase the area of contact with the belt B.

As shown in FIG. 2, the restraining member 15 is coupled to the lower outer circumferential surface of the eccentric member 11 through a bracket 19 protrudingly formed. The restraining member 15 is a tension spring, one end of which is caught in a hole 19a formed in the protruding end of the bracket 19, and the other end thereof is caught in a fixing part (not shown).

The bush 17 is pressed into the eccentric hole 11a and seated on the inner flange 11d, and moves relative to the upper outer peripheral surface of the guide member 20.

The guide member 20 includes an upper portion 21 inserted into the bush 17 and a lower portion 23 inserted into the concave space 11b, and the fastening means 30 therein. The through-hole 20a is formed so that () may be inserted. The outer diameter of the lower portion 23 is larger than the outer diameter of the upper portion 21.

In the outer peripheral surface of the end portion of the upper portion 21, a recessed groove 21a is formed along the outer circumferential surface so that the washer 80 is fitted, and the elastic means 70 is provided at the side end surface 23a of the lower portion 23. A recess groove 23b having a constant depth in the axial direction is formed in the circumferential direction so as to receive the recess.

The damper 50 is a hollow disc shape in which the bottom surface is fitted to the lower outer surface of the upper portion 21 of the guide member 20 and is in close contact with the side end surface 23a of the lower portion 23. 6 and 7, the plurality of grooves 51 are formed along the circumferential direction so that the plurality of intermediate members 60 are inserted.

The groove 51 has a shape that gradually deepens along the inclined surface 51a and rises along the vertical surface 51c through the horizontal surface 51b.

As shown in FIG. 3, the intermediate member 60 is press-fitted into the bottom surface 11e of the concave space 11b of the eccentric member 11 and inserted into the groove 51 of the damper 50. It is. That is, as shown in Figs. 4 and 5, the intermediate member 60 is inserted into its root portion 61 firmly press-fitted into the eccentric member 11 and the groove 51 of the damper 50. Consists of a protrusion (63).

The protruding portion 63 has a curved surface 63a, a horizontal surface 63b and a vertical surface 63c corresponding to the inclined surface 51a, the horizontal surface 51b and the vertical surface 51c of the groove 51, respectively.

The groove 51 of the damper 51 and the protruding portion 63 of the intermediate member 60 are made of a low friction surface having a small coefficient of friction so as to slide easily with each other.

The elastic means (70) is inserted into the recessed groove (23b) of the guide member 20 is a coil spring for applying an elastic restoring force to the damper (50).

On the other hand, the surface (S1) in which the washer 80, the eccentric member (11) and the bush (17) contact each other, and the surface in which the lower portion (23) of the damper (50) and the guide member (20) contact each other ( S2) is a high friction surface with a large coefficient of friction so as to suppress the movement of the movable body 10.

The belt tensioning device according to an embodiment of the present invention configured as described above, as shown in Figure 1, the movable body 10 to the belt (B) for transmitting power from the driving pulley (1) to the driven pulley (3) The outer ring surface of the bearing 13 is mounted so that the restraining member 15 is hooked to a fixed part (not shown) to provide a constant initial tension to the belt B.

Hereinafter, the operation of the belt tensioning device according to an embodiment of the present invention.

If the tension applied to the belt suddenly increases due to abnormal operation of the driving source (engine, etc.) or changes in the external environment, the tension applied by the tension device to the belt gradually decreases to maintain a constant tension due to the following actions. .

That is, since the belt B shown in FIG. 1 pushes the bearing 13 of the movable body 10 and the outer ring of the bearing 13 rotates clockwise, the eccentric member of the movable body 10 shown in FIG. 11) try to rotate clockwise.

As the protrusion 63 of the intermediate member 60 fixed to the eccentric member 11 moves in the clockwise direction CW shown in FIG. 8, the curved surface 63a has a groove 51 formed in the damper 50. The inclined surface 51a is moved. At this time, since the groove 51 of the damper 50 and the protrusion 63 of the intermediate member 60 have a low friction surface with a small coefficient of friction, the curved surface 63a of the protrusion 63 is formed in the groove 51. It easily moves on the inclined surface 51a.

Accordingly, the damper 50 shown in FIG. 3 overcomes the elastic restoring force of the miter elastic means 70 downward and closely contacts the side end surface 23a of the guide member 20, and at the same time the The upper surface and the upper surface of the bush 17 are in close contact with the bottom surface of the washer 80. The surface S1 in which the washer 80, the eccentric member 11, and the bush 17 contact each other, and the surface S2 in which the lower part 23 of the damper 50 and the guide member 20 contact each other. Since the friction coefficient is a high friction surface, the movable body 10 is gradually rotated by the frictional force of the surfaces S1 and S2, and the tension applied to the belt is gradually decreased, and the belt is in a constant steady state. It will maintain the tension of.

On the other hand, when the driving force decreases due to abnormal operation of the driving source (engine, etc.) or changes in the external environment, and the tension on the belt suddenly decreases, and the belt becomes loose, the tension applied by the tension device to the belt increases rapidly by the following action. .

That is, when the belt B shown in FIG. 1 is loosened, as the protrusion 63 of the intermediate member 60 fixed to the eccentric member 11 moves in the counterclockwise direction CW shown in FIG. The curved surface 63a descends rapidly on the inclined surface 51a of the groove 51 formed in the damper 50, and the vertical surface 63c is caught by the vertical surface 51c of the groove 51. At this time, since the groove 51 of the damper 50 and the protrusion 63 of the intermediate member 60 are made of a low friction surface with a small coefficient of friction, the curved surface 63a of the protrusion 63 is formed in the groove 51. The inclined surface 51a moves down easily.

Therefore, the damper 50 shown in FIG. 3 is upwardly separated from the side end surface 23a of the guide member 20, and at the same time, the upper surface of the eccentric member 11 and the upper surface of the bush 17 are washers ( 80, the eccentric member 11 of the movable body 10 is free to rotate, and the eccentric member 11 is rotated counterclockwise by the restraining member 15 shown in FIG. Therefore, the outer ring of the bearing 13 pushes the belt B so that the tension applied to the belt by the tension device increases rapidly, and the belt is tensioned to maintain a constant tension.

According to the belt tensioning device according to the present invention configured as described above, when the driving source (engine, etc.) is abnormally operated or changes in the external environment, the tension applied to the belt is increased when the tension is applied to the belt due to an increase in driving force. When the belt is gradually reduced to maintain a constant steady state tension, and when the tension on the belt suddenly decreases and the belt is loosened, the tension applied to the belt by the tension device increases rapidly and the belt maintains a constant steady state tension. It is possible to prevent the slack of the belt, increase the efficiency of the driving source (engine), smooth power transmission, reduce wear of the belt and the power transmission, and simplify the structure of the tension device.

Claims (6)

The movable body 10 which contacts the belt B and moves according to the tension of the belt B, and the guide member 20 which guides the movable body 10 so that the movable body 10 may be eccentrically rotated and linearly moved. And a damper 50 disposed between the movable body 10 and the guide member 20 to adjust the relative movement between the movable body 10 and the guide member 20, and guide the damper 50 to the guide. A plurality of intermediate members 60 coupled to the movable body 10 to closely contact the friction surface of the member 20 and elastic means disposed on the guide member 20 to apply a restoring force to the damper 50 ( 70) of the belt, characterized in that the belt is adjusted by the moving body which rotates eccentrically in contact with the belt (B) and at the same time the speed of change of the tension of the belt is controlled by the frictional force of the damper. Tension device. According to claim 1, The movable body 10 is coupled to the eccentric member 11 eccentrically coupled to the outside of the guide member 20, the outer peripheral surface of the eccentric member 11 is in contact with the belt (B) The bearing 13 and the restraining member 15 coupled to the outside of the eccentric member 11 to constrain the eccentric member 11 to impart tension to the belt B, and the guide member 20. And a bush (17) press-fitted into the eccentric member (11) so as to slide easily. The belt tensioning device according to claim 1, wherein a plurality of grooves (51) are formed in one surface of the damper (50) in a circumferential direction such that the plurality of intermediate members (60) are inserted therein. 4. The belt tensioning device according to claim 3, wherein the groove (51) is provided with an inclined surface (51a) that gradually deepens and a vertical surface (53c) that rises vertically. The belt tensioning device according to claim 1, wherein the intermediate member (60) is pressed into one surface of the eccentric member (11) and inserted into the groove (51) of the damper (50). The belt according to claim 1, wherein the intermediate member (60) has a curved surface (63a) and a vertical surface (63c) corresponding to the inclined surface (51a) and the vertical surface (51c) of the groove (51), respectively. Tension device.