JPH02125143A - Automatic tensioner for belt - Google Patents

Abstract

PURPOSE:To perform tension alignment by fixing the first cam piece to a tension arm and providing the second cam piece coupled with the first cam piece via inclined cross sections integrally with a tensioner shaft in the peripheral direction and movably in the axial direction. CONSTITUTION:The first cam piece C1 integrally formed with a tension arm 5 is concentrically provided with a tensioner shaft S1 on the inner periphery side of a torsion spring 8 provided in a cylindrical case 1, and the second cam piece C2 is provided with the shaft S1 in the peripheral direction and slidably in the axial direction via a key groove 14 and a sliding key 13 to face the first cam piece C1. When the tensile force of a belt is loosened, the torsion tensile force of the torsion spring 8 and the compression force of a dish spring 15 are converted into the rotary torque component to the first cam piece C1 by inclined faces H and H' of a cam mechanism 12, the first cam piece C1 is rotated together with the arm 5 while being slid on the face of the second cam piece C2, and an idler pulley 6 is pushed and moved to the tension direction. On the other hand, when the belt is tightened, they are reversely operated, and the belt tensile force is automatically maintained.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a belt autotensioner suitable for maintaining appropriate belt tension and preventing and damping belt tension fluctuations and resonance in a belt drive mechanism. It is something.

(Prior Art) Conventionally, an autotensioner has been used as a tensioning means in a belt transmission device in which a transmission belt is wound between a driving boot and a driven boot. Commonly used auto tensioners include hydraulic, pneumatic,
Tension is applied to the belt by means of compression, tension, bending, twisting, etc. using rubber, steel springs, resin springs, etc.

To give a specific example of this method, a tensioner shaft is inserted into a cylindrical case, which has an idler pulley at its tip, a ball bearing or bushing inserted into its inner surface, and a tension arm that also serves as a spring stopper. A torsion spring is inserted into the outer peripheral surface of the tensioner shaft between the cylindrical case and the tension arm, and the tension arm rotates around the shaft due to the torsional force of the spring, thereby applying belt tension.

Incidentally, in general, the tension to be applied to the belt by the tensioner should be applied more quickly when the belt tension decreases in order to prevent the belt from slipping. However, on the other hand, when the belt tension increases, it is preferable that the additional tension be reduced relatively gradually and not respond to a sudden increase in tension over a short period of time.

That is, the belt tensioner is required to have contradictory performance: to respond quickly when tension is applied, and to operate slowly when tension is decreased.

Another important function of the belt tensioner is to prevent belt resonance.

In other words, when a belt is used in a device that uses an engine as a drive source, especially when a single belt transmits power to many driven shafts and the circumference of the belt is relatively long, the engine has a top and bottom dead center, and the engine has a constant cycle. Because of the change in angular velocity, the belt resonates and violently vibrates up and down in a constant rotation speed range. As a result, abnormal noises may be generated from the belt or the proper torque may not be transmitted.

In addition, the belt resonance phenomenon causes the tensioner itself to vibrate violently due to the vibration of the belt, resulting in fluctuations in belt tension and additional fluctuations, which in turn causes undesirable phenomena such as belt falling off and uneven wear. Nevertheless, in the conventional tensioners as described above, little consideration is given to the provision of optimum tension and the function of preventing resonance, and in fact, there are almost no tensioners equipped with these preventive functions.

(Problems to be Solved by the Invention) It is an object of the present invention to deal with the above-mentioned actual situation and to improve the situation. The purpose of this is to prevent the resonance phenomenon of the belt and to enable excellent tension adjustment in belt transmission.

(Means for Solving the Problems) That is, the present invention is characterized in that one end of the tensioner shaft is inserted into a cylindrical case fixed to a bracket, and the other end of the tensioner shaft is inserted into a cylindrical case fixed to a bracket. The base end of a tension arm having an idler pulley at its tip is rotatably attached to the tensioner shaft, and a torsion spring is inserted between the tension arm and the cylindrical case, and both ends of the tension arm are connected to the tension arm and the cylindrical case. In a belt tensioner that is respectively locked to a cylindrical case, a first cam piece of a pair of cams that are fitted to each other through a diagonal cross section on the tensioner shaft on the inner peripheral side of the torsion spring is integrally formed with the tension arm. The second cam piece is provided so as to be integral with the tensioner shaft in the rotational direction and slidable in the axial direction, and a disc spring is installed between the second cam piece and the cylindrical case. This is an auto tensioner for a belt that is interposed in a surface contact state with a second cam piece.

(Function) As described above, in the auto tensioner of the present invention, the idler pulley attached to the tip of the tension arm is installed on the slack side of the power transmission belt wound between the driving pulley and the driven bobber so as to be in contact with the back surface of the belt. Ru. Then, when the idler pulley is pulled and rotated in the direction in which the torsion spring winds loosely, and is brought into contact with the belt, and the drive boob is rotated in the driving direction, the idler pulley acts in the direction in which the torsion spring winds and tightens, pressing the belt while Rotates to give the belt the desired tension.

Under these conditions, the next time the belt tension loosens,
Combined with the torsional tension of the torsion spring, the compressive force of the disc spring is replaced by a component of rotational torque applied to the first cam piece that is integrated with the arm by the inclined surface of the cam mechanism, and the first cam piece moves to the first cam piece. The two cams slide on one side and rotate together with the arm, and the resultant force of the rotational torque of the torsion spring and the rotational torque component of the cam piece quickly presses and moves the idler pulley in the belt tensioning direction to maintain belt tension. drive while doing so.

Next, when the ambient temperature rises and the belt becomes tense, the idler pulley receives a reaction force due to the belt tension, which is transmitted to the tensioner shaft as a rotational moment. This acts to weaken the pressure on the idler pulley, and the resultant force with the spring force from the torsion spring is applied from the idler pulley to the belt, automatically maintaining belt tension.

(Example) Hereinafter, specific examples of the present invention will be described further with reference to the accompanying drawings.

FIG. 1 shows an example of an auto tensioner according to the present invention. In the figure, (a) is an auto tensioner, (Sl)
(1) is a cylindrical case fixed to the bracket (2), and the flange part is attached to the bracket (2) with a bolt (Vl) (F2). ), and a tension arm (5) into which a ball bearing or bushing (4) is inserted is attached to the other end of the tensioner shaft (Sl) against the small diameter part of the shaft (S, ). At the tip of the tension arm (5), an idler pulley (6) is connected to the tip shaft (S2) of the tension arm via a ball bearing (7).
) and is fixed with a nut, and a torsion spring surrounding the tensioner shaft (Sl) is inserted between the contact surface of the bracket (2) of the cylindrical case (1) and the tension arm (5). (8), one end of the spring (8) is fitted and locked into a locking hole (10) of a stopper (9) provided integrally with the tension arm (5), while the other end is The torsion spring (8) is inserted and locked into the locking hole (11) provided in the cylindrical case (1).
) is configured to rotate the tension arm (5) in the axial direction and apply tension to the belt.

Therefore, in the above configuration, the present invention is characterized in that a cam mechanism (12) and a further spring (15) are provided inside the cylindrical case.

That is, the tension arm (5) is rested on the inner peripheral side of the torsion spring (8) and the first cam piece (C
1) is provided concentrically with the tensioner shaft (Sl), and in opposition to this, a second cam piece (C2) is provided concentrically with the shaft (S+) on the large diameter portion of the shaft (Sl). A sliding key (13) is provided in the provided keyway (14) so as to mesh with the first cam piece (C1).

A disc spring (15) is inserted between this second cam piece (C2) and the bracket contact surface of the cylindrical case (1), and moves the second cam piece (C2) only in the axial direction. There is pressure to do so.

In addition, the first cam piece (C1) and the second cam piece (C2)
) are made of a durable material that slides easily onto each other, as described above, and the most common combination is synthetic resin, for example, a nylon cam piece (C1) and a steel cam piece (C2), but synthetic resin Of course, it is also possible to use cam pieces made of steel or cam pieces made of steel.

Figures 2 and 3 show details of the first cam piece (C1) and the second cam piece (C2), and in the first cam piece (C process) shown in Figure 2, (Fl) (Flo) is a flat surface,
()l) (H") is the inclined surface, (f) (f') is the (F
l) A flat surface thinner than the flat surface of (F1'), while (P) (
P') indicates an inclined protrusion, and (F2) and (F2') indicate a flat part, and both of these first and second cam pieces (C1
) (C2) is the flat surface (Fl) of the first cam piece (C1).
) (Fl') and the protrusion (P) of the second cam piece (C2) (P
"), and when the belt tension fluctuates, the flat surface (Fl) of the first cam piece (C1) engages with the flat surface (F2) of the second cam piece (C2), and the second cam piece (
The protrusion (P') of C2) moves while sliding on the flat surface (f) and inclined surface (l()) of the first cam piece (C1).

Further, a disc spring (15) formed into a conical shape with a hole in the center and inserted between the second cam piece (C2) and the cylindrical case (1) is attached to the tension arm ( Since the rotational torque of the cam can be varied by changing the compression length due to the axial displacement in 5), it is effective to use a disc spring with a spring constant suitable for this.

The present invention has the above-described configuration.Next, the mode of use using the above-mentioned autotensioner will be explained with reference to FIG. 4.

In the figure, (Dr) is a driving pulley, (Dn) is a driven boolean, and an arbitrary belt (20) consisting of a ■ belt, a flat belt, a ribbed ■ belt, a timing belt, etc. is wound between these two boots. An idler pulley (6) attached to the tip of the tension arm (5) is installed on the slack side of the belt so as to be in contact with the back surface of the belt (20).

Therefore, the belt (20) is pulled and rotated by pulling the idler pulley (6) in the direction in which the torsion spring is unwound.
When the drive pulley (Dr) is rotated in the direction of the arrow, the idler pulley (6) acts in the direction of tightening the torsion spring, and rotates in the direction of the arrow while pressing the belt (20).

Then, when the tension of the belt (20) is loosened, the compressive force of the separately provided disc spring, together with the elasticity of the torsion spring, is applied to the arm (5) by the inclined surface of the cam piece. It is replaced by the component force of the rotational torque on the first cam piece, and the first
The cam piece rotates with the arm (5) while sliding on one side of the second cam, and the rotational force of the cam piece is added to the rotational torque of the torsion spring, resulting in a resultant force that causes the idler pulley (6) to tension the belt. The belt moves in the direction of the belt, prevents belt resonance, and maintains appropriate belt tension while driving.

On the other hand, when the ambient temperature rises and the belt becomes tense, the idler boot 1 bar 6) receives a reaction force due to the belt tension, which is transmitted to the tensioner shaft as a rotational moment.
The pressure on the idler pulley (6) is strengthened by the reaction force of the inclined surface of the cam piece and the disc spring, and the resultant force of the torsion spring is applied from the idler pulley (6) to the belt (20), automatically increasing the belt tension. will be maintained.

In this way, as an auto-tensioner in belt transmission, it provides excellent tension adjustment and contributes to resonance prevention.

(Effects) As described above, the present invention inserts a tensioner shaft into a cylindrical 4°-shaped case fixed with a bracket, attaches a tension arm having an idler pulley at the tip to the shaft, and provides a torsion spring between the cylindrical case and the tension arm. are inserted with their respective tips locked, a cam mechanism is provided on the inner peripheral surface, and a disc spring is further installed between the cam mechanism and the cylindrical case, so that rotational torque due to torsional coupling is prevented. The conversion reduces belt vibration and prevents the problematic belt resonance phenomenon during belt drive, allowing belt drive to be performed while always maintaining appropriate belt tension.Furthermore, the mechanism is simple. Appropriate selection of the spring constant of the disc spring makes it possible to support a wide range of belt specifications.Moreover, a large spring compression force can be obtained with a small deflection, making it possible to make the spring more compact. It is extremely practical as an auto-tensioner for belt transmission, and can exhibit excellent tension adjustment and resonance prevention functions.

[Brief explanation of the drawing]

Fig. 1 is a side cross-sectional view of essential parts showing an example of an auto tensioner for belts according to the present invention, Figs. These are detailed views of the cam pieces that make up the cam mechanism of the tensioner. Figure 2 (a), (b), and (c) relate to the first cam piece that is integrated with the tension arm, and (a) is a side view of a partial cross section. Figures, (B) is a front view, (C) is a cross-sectional developed view of (B) A-A, and Figure 3 (A)
(b) (c) relates to the second cam piece; 1 is a schematic side view showing an example of use of the auto tensioner of the present invention. (a) Auto tensioner (Sl) Tensioner shaft (S2) Tip shaft (1) Cylindrical case ( 2) Bracket (5) Tension arm (6) Idler pulley (8) Torsion spring (9) Stopper (10) (11) Locking hole ( 12)...Cam mechanism (C1)...First cam piece (C2)...Second cam piece (H) (H')...Slanted surface of cam piece (P) (P' Door: Protrusion of cam piece

Claims (1)

[Claims] 1. Insert one end of the tensioner shaft into a cylindrical case fixed to a bracket, and attach the base end of a tension arm having an idler pulley at the tip to the other end of the tensioner shaft so as to be rotatable on the tensioner shaft, and In a belt tensioner in which a torsion spring is inserted between a tension arm and the cylindrical case, and both ends of the torsion spring are respectively locked to the tension arm and the cylindrical case, the torsion spring is placed on the tensioner shaft on the inner circumference side, A first of a pair of cams that fit into each other through an oblique cross section.
A cam piece is integrally fixed to the tension arm, and the second cam piece is provided so as to be integral with the tensioner shaft in the rotational direction and slidable in the axial direction, and has a cylindrical shape with respect to the second cam piece. An auto tensioner for a belt, characterized in that a disc spring is interposed between the cases and in surface contact with the second cam piece.