KR101253339B1 - One way clutch - Google Patents

Abstract

A unidirectional clutch is disclosed. One-way clutch according to an embodiment of the present invention, the input housing is disposed on the input shaft side and the output shaft disposed on the output shaft side is inserted into the output housing coupled to the input housing, coupled with the input shaft to rotate; An output clutching means formed in a hollow tube shape and disposed in the output housing and having a portion of the input clutching means inserted therein and coupled with the output shaft to rotate; And a coil shape installed in close contact with the inner circumferential surface of the output housing, and formed in a coil shape surrounding the outer circumference of the output clutching means, and both ends are bent inward to one end of the input clutching means and the output clutching means. And the other end of the coil spring is caught on the other side of the input clutching means and the output clutching means, the diameter of the coil spring is reduced by the rotational force transmitted from the input shaft to offset the frictional force with the inner peripheral surface of the output housing The rotational force is transmitted to the output shaft, and the diameter of the coil spring is extended by the rotational force transmitted from the output shaft is in close contact with the inner peripheral surface of the output housing, characterized in that the transmission of the rotational force to the input shaft.

Description

One way clutch

The present invention relates to a clutch, and more particularly, relates to a unidirectional clutch in which the rotational force input from the input shaft is transmitted to the output shaft, but the rotational force input from the output shaft is not transmitted to the input shaft.

Conventional clutches have two or more wide friction surfaces that combine to transmit power and are separated to block transmission of power, or separately to allow rotation and to engage rotation to prevent rotation.

These clutches require a large friction surface for power transmission, and require energy such as control elements for controlling the operation of the clutch and hydraulic pressure required for operation. In addition, if unexpected reverse power is transmitted from the output shaft, the equipment installed on the input shaft by reverse driving may leave the set position or damage.

In order to solve the reverse driving problem, a clutch that can block a conventional reverse input has been disclosed.

However, the conventional unidirectional clutch has a problem that the slip occurs in the clutch when the abnormal rotation force is generated, the stopping force decreases as the wear increases.

Embodiments of the present invention, the diameter of the coil spring is reduced by the rotational force transmitted from the input shaft to offset the friction force with the output housing to transfer the rotational force to the output shaft, the coil spring diameter is expanded by the rotational force transmitted from the output shaft output housing In close contact with the inner circumferential surface to provide a one-way clutch that can block the transmission of the rotational force to the input shaft.

According to one aspect of the invention, the input housing disposed on the input shaft and the output shaft side is disposed in the output housing coupled to the input housing, the input clutching means coupled to the input shaft to rotate; An output clutching means formed in a hollow tube shape and disposed in the output housing and having a portion of the input clutching means inserted therein and coupled with the output shaft to rotate; And a coil shape installed in close contact with the inner circumferential surface of the output housing, and formed in a coil shape surrounding the outer circumference of the output clutching means, and both ends are bent inward to one end of the input clutching means and the output clutching means. And the other end of the coil spring is caught on the other side of the input clutching means and the output clutching means, the diameter of the coil spring is reduced by the rotational force transmitted from the input shaft to offset the frictional force with the inner peripheral surface of the output housing A unidirectional clutch may be provided that transmits a rotational force to an output shaft and closes an inner circumferential surface of the output housing while the diameter of the coil spring is extended by the rotational force transmitted from the output shaft to block transmission of the rotational force to the input shaft.

Here, the coil spring has a first catching jaw having one end of the coil bent inward at one end thereof, and a second catching jaw being bent inward with the other end of the coil at the same line as the first catching jaw. Can be formed.

And the input clutching means is made of a hollow tube shape and one side is coupled to the input shaft to rotate and the first cam is formed with a first locking groove to take the first locking jaw on the other side, the outer circumference and the spline of the input cam It may be composed of an input inner guide is coupled and the second locking groove is formed so that the second locking jaw can be caught on one side.

In addition, the output clutching means is formed with a hollow tube shape is formed on the one side of the incision that can be caught on the second locking jaw and is inserted into the output housing and the output inner guide is inserted into a portion of the input clutching means and And, coupled to the output shaft is accommodated in the output inner guide and provided with a protrusion protruding on one side, the protrusion may be configured as an output cam is inserted into the incision to be caught on the first locking jaw.

On the other hand, the coil cross section of the coil spring may be rectangular to increase the friction with the inner peripheral surface of the output housing.

The greater the torque, the greater the shrinkage or expansion of the coil spring, which increases the stopping force. This improves product reliability and competitiveness without increasing backlash due to wear.

1 is an exploded perspective view of a unidirectional clutch according to an embodiment of the present invention.
Figure 2 is an assembled perspective view of the present invention shown in FIG.
3 is a cross-sectional view of the present invention shown in FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. The following description and the accompanying drawings are presented for the overall understanding of the present invention, and thus the technical scope of the present invention is not limited thereto. And a detailed description of known configurations and functions that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 is an exploded perspective view of a unidirectional clutch according to a preferred embodiment of the present invention, Figure 2 is an assembled perspective view of the present invention shown in Figure 1, Figure 3 is a cross-sectional view of the present invention shown in FIG.

Referring to FIG. 5, the present invention is a hollow tube-shaped input housing 10 disposed on an input shaft (not shown) and an output housing coupled to the input housing 10 while being disposed on an output shaft (not shown). 20 is provided, it may be composed of the input clutching means 100, the output clutching means 200, the coil spring 70 installed in the input housing 10 and the output housing 20.

First, the input clutching means 100 is inserted and disposed in the input housing 10 and the output housing 20, one side of which is coupled to the input shaft to rotate.

In addition, the input clutching means 100 is properly coupled to both ends of the coil spring 70 to reduce the diameter of the coil spring 70 in accordance with the rotation direction to transfer the rotational force to the output shaft.

In more detail, the input clutching means 100 may be composed of an input cam 30 and an input internal guide 40 as shown.

The input cam 30 is formed in a substantially hollow tube shape and one side is coupled to the input shaft is rotated.

And the first locking groove 32 is formed on the other side. The first catching groove 32 is a structure that can be caught with one end of the coil spring 70, which will be described later, which may be any type of groove or simply a structure in which a part of the hollow tube is cut and caught only on one side. . It may also be a stepped form.

In addition, the input cam 30 may have a multi-stage structure along the longitudinal direction as shown. This is to allow each component to settle, touch or hang.

For reference, the input cam 30 may be rotatably coupled by the input housing 10 and the bearing 80.

Meanwhile, the input inner guide 40 may have an annular ring shape as shown by being splined to the outer circumference of the input cam 30 to rotate together.

A second catching groove 42 may be formed at one side of the input inner guide 40, and the second catching groove 42 may be caught with the other end of the coil spring 70. Or stepped.

However, the first catching groove 32 and the second catching groove 42 are formed to be spaced apart from each other, and this interval is preferably approximately corresponding to the length of both ends of the coil spring 70.

Thus, as shown, the input inner guide 40 may be coupled to a central portion of the input cam 30.

Next, the output clutching means 200 will be described.

The output clutching means 200 is inserted and disposed in the output housing 20, one side of which is coupled to the output shaft to rotate, and a part of the input clutching means 100 is inserted.

In addition, the output clutching means 200 is also properly coupled to both ends of the coil spring 70 to extend the diameter of the coil spring 70 according to the rotation direction to block the transmission of the rotational force to the input shaft.

In more detail, the output clutching means 200 may be composed of an output inner guide 50 and an output cam 60 as shown.

The output inner guide 50 is inserted into the output housing 20, and has a substantially hollow tube shape, so that a part of the input clutching means 100, that is, a part of the input cam 30 is inserted. Can be. In addition, a part of the input inner guide 40 may be combined with a part inserted as shown.

In addition, a cutout 52 having a cut shape may be formed at one side of the output inner guide 50, and the cutout 52 may be caught with the other end of the coil spring 70.

On the other hand, the output cam 60 is formed in a substantially annular ring shape is accommodated in the output inner guide 50 and coupled to the output shaft is rotated.

And a protrusion 62 is provided on one side, the protrusion 62 is inserted into the cutout 52, the output cam 60 is accommodated in the output inner guide (50). Therefore, when the output cam 60 rotates, the protrusion 62 is rotated by the output inner guide 50 by being caught by the cutout 52.

In addition, the protrusion 62 may be caught with one end of the coil spring 70.

Next, the coil spring 70 will be described.

The coil spring 70 is installed in the output housing 20 to be in close contact with the output inner guide 50 to transfer the rotational force coming from the input shaft to the output shaft or to be in close contact with the inner circumferential surface of the output housing 20 to enter from the output shaft. It does not transmit the rotational force to the input shaft, it may be made of a coil shape surrounding the outer circumference of the output clutching means 200, that is, the output inner guide 50.

Both ends of the coil spring 70 are each bent inward so that one end of the first catching jaw 72 and the other end of the coil spring 70 are formed. In this case, the first catching jaw 72 and the second catching jaw 74 are preferably formed on the same line.

The first catching jaw 72 is caught on one side of the input clutching means 100 and the output clutching means 200, and in detail, the first locking groove 32 and the output of the input cam 30. The projection 62 of the cam 60 may be caught.

In addition, the second catching jaw 74 is caught on the other side of the input clutching means 100 and the output clutching means 200. Specifically, the second locking groove 42 of the input inner guide 40 and It may be caught by the cutout 52 of the output inner guide 50.

However, the coil spring 70 is inserted to be in close contact with the inner peripheral surface of the output housing 20 when installed. Therefore, when the coil spring 70 is inserted by slightly reducing the diameter when the coil spring 70 is inserted into the output housing 20, the coil spring 70 is smeared into the inner circumferential surface of the output housing 20 so that the coil spring 70 is not rotated due to frictional force.

In addition, the inner circumferential surface of the coil spring 70 and the outer circumferential surface of the output inner guide 50 are not in contact with each other but are spaced at very fine intervals.

Preferably, the cross section of the coil of the coil spring 70 may be circular but preferably rectangular. This is because not only the outer circumferential surface of the coil spring 70 contacts the inner circumferential surface of the output housing 20 to maximize the frictional force, but also the inner circumferential surface of the coil spring 70 also outputs the inner guide 50. This is to secure the maximum friction area with the outer circumferential surface.

Hereinafter will be described the operating state of the present invention.

First, the case where the rotational force is transmitted from an input shaft is demonstrated.

If the input shaft rotates clockwise, the input cam 30 coupled to the input shaft rotates clockwise, and the input inner guide 40 splined to the input cam 30 also rotates clockwise. do.

In addition, since the second catching jaw 74 of the coil spring 70 is caught by the second catching groove 42 formed in the input inner guide 40, the input inner guide 40 may rotate clockwise. When the second catching jaw 74 is pressed downward when seen in FIG. 1, the diameter of the coil spring 70 is reduced. At this time, since the outer circumferential surface of the coil spring 70 is in close contact with the inner circumferential surface of the output housing 20, the coil spring 70 itself does not rotate.

Eventually, as the diameter of the coil spring 70 is reduced, the friction force is offset by being spaced apart from the output housing 20 so that the rotational force of the input inner guide 40 is the input cam 30, the coil spring 70, and the output cam. The output inner guide 50 is rotated clockwise because of the frictional force via 60.

As a result, the output cam 60 coupled to the output inner guide 50 also rotates, and the output shaft coupled to the output cam 60 also rotates clockwise so that the rotational force on the input shaft is transmitted to the output shaft.

On the contrary, when the input shaft rotates counterclockwise, the input cam 30 rotates counterclockwise.

Since the first catching jaw 72 of the coil spring 70 is caught in the first catching groove 32 formed in the input cam 30, when the input cam 30 rotates in a counterclockwise direction. Since the first catching jaw 72 is pressed upward, the diameter of the coil spring 70 is reduced. As described above, since the outer circumferential surface of the coil spring 70 is in close contact with the inner circumferential surface of the output housing 20, the coil spring 70 itself does not rotate.

Therefore, as the diameter of the coil spring 70 is reduced, frictional force with the output housing 20 is canceled, and the rotational force of the input cam 30 passes the output inner guide 50 via the output cam 60. It rotates counterclockwise, and the output cam 60 also rotates counterclockwise.

Next, the case where the rotational force is transmitted from the output shaft will be described.

First, when the output shaft rotates in the clockwise direction, the output cam 60 coupled with the output shaft rotates in the clockwise direction, and the output inner guide 50 that rotates together with the output cam 60 rotates.

At this time, since the second catching jaw 74 caught in the cutout 52 of the output inner guide 50 is pressed upward, the diameter of the coil spring 70 is about to be expanded while the output housing 20 It adheres to the inner circumferential surface. Therefore, the coil spring 70 does not rotate due to the friction force, and the output inner guide 50 and the output cam 60 which are caught on the coil spring 70 do not rotate but stop. As a result, the rotational force on the output shaft is not transmitted to the input shaft.

On the contrary, when the output shaft rotates counterclockwise, the output cam 60 also rotates counterclockwise.

At this time, since the first catching jaw 72 caught by the projection 62 of the output cam 60 is pressed downward, the diameter of the coil spring 70 is about to be expanded while being strongly on the inner circumferential surface of the output housing 20. Close contact. Therefore, the coil spring 70 does not rotate due to the friction force, and the output cam 60 caught on the coil spring 70 does not rotate and stops, so that the rotational force of the output shaft is not transmitted to the input shaft.

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art, various modifications of the present invention within the scope of the claims without departing from the spirit and scope of the present invention And can be changed.

10: input housing
20: output housing
30: input cam 32: first jamming groove
34: input shaft coupler
40: input inner guide 42: second locking groove
50: output inner guide 52: incision
60: output cam 62: projection
64: output shaft coupler
70: coil spring 72: first locking jaw
74: second catch jaw
80: Bearings
100: input clutching means 200: output clutching means

Claims (5)

delete An input clutching means (100) inserted into an input housing (10) disposed on an input shaft side and an output shaft (20) coupled to the input housing (10) and coupled to the input shaft to rotate;
An output clutching means (200) formed in the hollow tube shape and disposed in the output housing (20) and having a portion of the input clutching means (100) inserted therein and rotating in combination with the output shaft; And
It is installed in close contact with the inner peripheral surface of the output housing 20, made of a coil shape surrounding the outer circumference of the output clutching means 200, both ends are bent inward, respectively, one end of the input clutching means 100 And a coil spring 70 which is caught on one side of the output clutching means 200 and the other end is caught on the other side of the input clutching means 100 and the output clutching means 200.
As the diameter of the coil spring 70 is reduced by the rotational force transmitted from the input shaft, friction with the inner circumferential surface of the output housing is canceled to transmit the rotational force to the output shaft, and the diameter of the coil spring 70 by the rotational force transmitted from the output shaft. While the expansion is in close contact with the inner peripheral surface of the output housing 20 to block the transmission of the rotational force to the input shaft,
The coil spring 70,
At one end, a first catching jaw 72 is formed in which an end of the coil is bent inward, and at the other end, a second catching jaw bent inward and positioned on the same line as the first catching jaw 72. Unidirectional clutch, characterized in that 74) is formed. The method of claim 2,
The input clutching means 100,
The input cam 30 is formed in a hollow tube shape and one side is coupled to the input shaft to rotate and the first catching groove 32 is formed to take the first catching jaw 72 on the other side,
Unidirectional clutch, characterized in that composed of the input inner guide 40 is spline coupled to the outer circumference of the input cam 30 and the second locking groove 42 is formed so that the second locking jaw (74) can be caught on one side. . The method of claim 2,
The output clutching means 200,
A hollow tube shape is formed, but a cutout 52 is formed at one side to be caught by the second catching jaw 74, and is inserted into the output housing 20, and a part of the input clutching means 100 is moved into the inside. An output inner guide 50 to be inserted,
Coupled with the output shaft is provided in the output inner guide 50 and is provided with a projection 62 of the shape protruding on one side, the projection 62 is inserted into the cutout 52 is the first locking jaw 72 Unidirectional clutch, characterized in that consisting of an output cam (60) is caught. 5. The method according to any one of claims 2 to 4,
The coil cross section of the coil spring (70) is a one-way clutch, characterized in that the square so as to increase the friction with the inner peripheral surface of the output housing (20).

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