JP2016125503A - Falling prevention structure of snap ring and frictional engagement device including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a falling prevention structure of a snap ring capable of being easily assembled with a simple structure and surely preventing falling of a snap ring, and a frictional engagement device including the snap ring.SOLUTION: Since a falling prevention structure 40 of a snap ring of a frictional engagement device 10 is configured such that between an inside surface 23a of a projection part 23 of an end plate 22c and an outer peripheral surface 24a of a snap ring 24, an annular member 42 is provided separately from the end plate 22c, the falling prevention structure is easily assembled with a simple structure. When the snap ring 24 is opened by centrifugal force, the outer peripheral surface 24a of the snap ring 24 contacts with a snap ring contact part 42a, and the snap ring 24 can be prevented from further being opened.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a structure that prevents a snap ring for a shaft (hereinafter sometimes simply referred to as “snap ring”) from falling off, and a friction engagement device including the same.

  In a friction engagement device that inputs and outputs with respect to the rotating shaft, the friction plate for transmitting torque and the mating plate are arranged on the outer peripheral side of the inner axial direction surface where the friction plate is formed on the hub, and the mating plate is used for the drum. Although it is preferable in terms of structure to be disposed on the inner peripheral side of the outer axial direction surface that is configured, the friction plate is placed on the inner peripheral surface of the outer axial direction surface that is configured in the drum due to layout restrictions. In some cases, the hub must be disposed on the outer peripheral surface of the inner axial surface of the hub. At this time, a snap ring for the shaft is used to prevent the end plate located on the opposite side of the piston from being pulled out. The snap ring is fitted into a groove provided in a circumferential direction on the outer peripheral surface of the inner axial direction surface formed in the hub adjacent to the end plate so as to tighten the bottom surface of the groove by its elasticity. However, when the rotating shaft rotates, a centrifugal force acts on the snap ring, the snap ring expands, and the snap ring may come off from the groove and fall off from the inner axial surface.

  Therefore, various snap ring dropout prevention structures have been proposed in order to prevent the snap ring from spreading and to prevent the above problems from occurring. Examples include the following.

JP 2001-241467 A JP 2011-112172 A

  Patent Document 1 discloses a snap ring drop-off preventing structure in which a plurality of protrusions protruding in the axial direction are provided on the snap ring side of a cancel plate fitted on the outer peripheral side of the input shaft.

  According to Patent Literature 1, since the radially inner side surface of the protrusion provided on the cancel plate is in contact with the outer peripheral surface of the snap ring, the snap ring can be prevented from expanding, and thus the snap ring falls off the rotating shaft. It is said that this can be prevented. Therefore, it is conceivable to apply this technique to provide a similar protrusion on the end plate that is spline-fitted to the outer peripheral side of the inner axial surface of the hub.

  However, the protrusion as disclosed in Patent Document 1 cannot reliably provide a snap ring drop-off preventing function. This is because the end plate may move axially with the friction engagement device disengaged, and when the end plate is away from the snap ring, the expansion of the snap ring cannot be suppressed by the protrusion. Because there are cases.

  On the other hand, in order to prevent the above situation, it is conceivable to increase the axial dimension of the protrusion. However, when the axial dimension of the protrusion is increased, the snap ring is on the outer peripheral surface of the inner axial surface formed on the hub. When snapping into a groove provided in the circumferential direction, the snap ring and the protrusion interfere with each other, which may cause a problem that the snap ring is difficult to attach or cannot be attached.

  Patent Document 2 discloses a snap ring drop-off preventing mechanism that prevents the snap ring from spreading by attaching an annular part to the snap ring. According to this, it is possible to reliably prevent the snap ring from expanding regardless of the axial movement of the end plate.

  However, because the structure is such that the part is attached to the snap ring by the claw part inserted into the narrow part provided in the annular part, it is difficult to process depending on the part shape and required accuracy, and it is difficult to align and assemble There are also issues.

  Therefore, in view of the problems of the prior art described above, the present invention is a snap ring drop-off preventing structure that can be easily assembled with a simple structure and can surely prevent the snap ring from dropping, and a friction engagement including the same. The object is to provide a device.

The present invention includes a drum having an outer axial surface positioned on the radially outer side and an inner axial surface positioned on the radially inner side, which are provided on the respective rotary shafts arranged coaxially and face each other in the radial direction A hub,
From the side of the pressing means that is spline fitted to the outer peripheral side of the inner axial surface and rotates integrally with the hub, at least a counter plate having a pressure plate and an end plate,
A friction plate that is provided between the mating plates and is spline-fitted to the inner peripheral side of the outer axial surface;
A groove provided on the outer circumferential surface of the inner axial direction surface and provided in a circumferential direction on the opposite side of the friction plate of the end plate;
A snap ring fitted into the groove and retaining the end plate;
In the friction engagement device in which the radially outer side of the surface of the end plate on the snap ring side of the end plate protrudes in the axial direction from the portion in contact with the snap ring to form a protrusion.
An annular member having a snap ring abutting portion is provided on the end plate between the inner side surface of the protrusion and the outer peripheral surface of the snap ring, and a structure for preventing the snap ring from falling off. The above-mentioned problem has been solved by a frictional engagement device comprising:

  In the present invention, an annular member separate from the end plate is provided between the inner surface of the protrusion and the outer peripheral surface of the snap ring, and the annular member has a snap ring abutting portion. It is a simple structure and can be assembled easily. Specifically, after the end plate is fitted on the outer circumferential side of the inner axial surface, the snap ring is fitted in a groove provided on the outer circumferential surface of the inner axial surface, and then the annular member is placed at a predetermined position. It can be provided on the end plate. Thus, since the annular member that prevents the snap ring from expanding can be attached after the snap ring is attached, it is difficult to attach the snap ring as in the conventional case even if the axial dimension of the annular member is increased. The problem does not occur. Therefore, this structure can improve the reliability of the snap ring drop-off preventing function.

  Further, if the annular member is configured to be provided on the end plate by being prevented from being pulled out by a hole snap ring attached to the inner side surface of the protrusion, assembly can be easily performed.

  Furthermore, if the annular member that forms an L-shaped section in the axial direction is formed by the radial surface in contact with the end plate and the snap ring abutting portion, it is easy to attach the hole snap ring for retaining the annular member.

The axial sectional view of the radial direction half of the friction engagement device to which the snap ring drop-off preventing structure of the first embodiment of the present invention is applied. The principal part enlarged view of FIG. The figure which looked at a part of drop-off prevention structure of the snap ring of 1st embodiment of this invention from the axial direction. The principal part expansion axial sectional view of the snap ring drop-off prevention structure of the second embodiment of the present invention. The figure which looked at a part of drop-off prevention structure of the snap ring of 2nd embodiment of this invention from the axial direction.

  An embodiment of the present invention will be described with reference to FIGS. However, the present invention is not limited to this embodiment.

  FIG. 1 is an axial sectional view of a half of the radial direction of a friction engagement device 10 to which a snap ring drop-off preventing structure 40 according to a first embodiment of the present invention is applied. The friction engagement device 10 is vertically symmetric with respect to the axis X of the rotation shaft 12.

  A hub 20 and a pressing means 14 are attached to the rotating shaft 12, and the rotating shaft 12, the hub 20, and the pressing means 14 are configured to rotate integrally. On the other hand, the drum 30 is attached to another rotating shaft (not shown) coaxial with the rotating shaft 12. A mating plate 22 including a pressure plate 22a, an intermediate plate 22b, and an end plate 22c is spline-fitted on the outer peripheral side of the inner axial surface 20a formed in the hub 20. On the other hand, the friction plate 32 is spline-fitted on the inner peripheral side of the outer axial surface 30a of the drum 30 so as to be positioned between the mating plates 22.

  The piston of the pressing means 14 provided on the rotating shaft 12 moves in the axial direction by hydraulic pressure or the like, and presses the pressure plate 22a in the direction of the end plate 22c, whereby the mating plate 22 and the friction plate 32 are frictionally engaged, and the hub Torque is transmitted between the drum 20 and the drum 30. In addition, the friction material 32a (refer FIG. 2) is normally affixed on the friction plate 32 in the part friction-engaged with the other party plate 22. FIG.

  As shown in FIG. 2, a snap ring 24 is provided adjacent to the end plate 22c to prevent the end plate 22c from being pulled out. The snap ring 24 is fitted on a groove 26 provided on the outer circumferential surface of the inner axial surface 20a of the hub 20 on the opposite side to the friction plate 32 of the end plate 22c in the circumferential direction. Thereby, when the piston is operated and the end plate 22c is pushed by the pressure plate 22a, the end plate 22c is pushed by the snap ring 24, so that the friction plate 32 can be sandwiched by the mating plate 22.

  The end plate 22 c includes a protrusion 23 in the axial direction (right direction in the drawing) on the snap ring 24 side at a position radially outward from the snap ring 24. The protrusion 23 is provided integrally with the end plate 22c continuously over the entire circumferential direction thereof, but is continuous as long as an annular member 42 described later can be provided. Not necessarily.

  An annular member 42 is provided between the inner side surface 23 a of the protrusion 23 of the end plate 22 c and the outer peripheral surface 24 a of the snap ring 24. The annular member 42 is fitted with the groove portion 42b of the annular member 42 and the groove portion 23b of the projecting portion 23, and is secured by a hole snap ring 44 provided in close contact with the groove portion 23b of the projecting portion 23. It is provided on the plate 22c. Specifically, as shown in FIG. 3, a notch 23c is provided in a part of the protrusion 23 of the end plate 22c, and the plier hooking portion 46 of the hole snap ring 44 is located in the notch 23c. Yes.

  The annular member 42 has a snap ring contact portion 42 a that protrudes in the axial direction from the protrusion 23. When the snap ring 24 is expanded by centrifugal force, the outer peripheral surface 24a of the snap ring 24 is in contact with the snap ring abutting portion 42a, so that further expansion of the snap ring 24 can be prevented. Thereby, it can prevent that the snap ring 24 falls off from the outer peripheral surface of the inner side axial direction surface 20a (refer also FIG. 2). The axial dimension of the snap ring contact portion 42a may be set as appropriate in consideration of the axial movable range of the end plate 22c.

  In the snap ring drop-off prevention structure 40 shown in FIG. 2, after the end plate 22c is fitted to the outer peripheral side of the inner axial surface 20a, the snap ring 24 is fitted into the groove 26, and then the annular member 42 The annular member 42 is inserted between the inner surface 23a of the protrusion 23 and the outer peripheral surface 24a of the snap ring 24 with the hole snap ring 44 fitted in the groove 42b, and the hole snap ring 44 is inserted into the groove portion of the protrusion 23. It can be assembled by fitting into 23b.

  FIG. 4 is an enlarged view of a main part of the snap ring drop-off preventing structure 40a according to the second embodiment of the present invention. Since the basic configuration of the friction engagement device and the drop-off prevention structure is the same as that of the friction engagement device 10, the description thereof is omitted.

  The annular member 43 of the snap ring drop-off prevention structure 40a forms an axial cross-section L-shape with the radial surface 43b in contact with the end plate 22c and the snap ring contact portion 43a. The annular member 43 is provided between the inner side surface 25a of the protrusion 25 of the end plate 22c and the outer peripheral surface 24a of the snap ring 24 by the radial direction surface 43b being secured by the hole snap ring 44a. . Specifically, as shown in FIG. 5, the annular member 43 is prevented from being pulled out by a hole snap ring 44 a fitted into a groove portion 25 b provided on the inner side surface 25 a of the protrusion 25 of the end plate 22 c. As long as the annular member 43 has an L-shaped cross section in the axial direction, it is easy to apply one in which the plier hooking portion 46a of the hole snap ring 44a is located on the radially inner side. The snap ring contact portion 43a protrudes in the axial direction from the protrusion 25 (see FIG. 4).

  In the snap ring drop-off preventing structure 40a shown in FIG. 4, after the end plate 22c is fitted on the outer peripheral side of the inner axial surface 20a, the snap ring 24 is fitted into the groove 26, and then the annular member 43 is fitted. It can be assembled by inserting between the inner surface 25a of the protrusion 25 and the outer peripheral surface 24a of the snap ring 24 and fitting the hole snap ring 44a into the groove 25b of the protrusion 25.

  The annular member described above is not limited to a complete annular shape, and may have a notch in part, and can be attached to the end plate by a method other than the snap ring described above. Of course, the present invention can be applied to a mating plate of a type that does not have an intermediate plate.

  The configuration similar to the snap ring drop prevention structure of the present invention is applied not only to the snap ring for retaining the end plate, but also to prevent the snap ring for other shafts used in the friction engagement device from falling off. You can also

  As described above, according to the present invention, it is possible to provide a snap ring drop-off preventing structure that can be easily assembled with a simple structure and can reliably prevent the snap ring from dropping, and a friction engagement device including the same. Can do.

DESCRIPTION OF SYMBOLS 10 Friction engagement apparatus 12 Rotating shaft 14 Pressing means 20 Hub 20a Inner axial direction surface 22a Pressure plate (counter plate)
22c End plate (mating plate)
23,25 Projection 23a, 25a Projection inner surface 24 Snap ring 24a Snap ring outer peripheral surface 26 Groove 30 Drum 30a Outer axial direction surface 40, 40a Snap ring drop-off prevention structure 42, 43 Annular member 42a, 43a Snap ring Contact part 43b Radial surface 44, 44a Hole snap ring

Claims (4)

A drum having an outer axial surface positioned radially outward and a hub having an inner axial surface positioned radially inward, each of which is provided on a rotation shaft disposed on the same axis and faces each other in the radial direction;
From the side of the pressing means that is spline fitted to the outer peripheral side of the inner axial surface and rotates integrally with the hub, at least a counter plate having a pressure plate and an end plate,
A friction plate that is provided between the mating plates and is spline-fitted to the inner peripheral side of the outer axial surface;
A groove provided on the outer circumferential surface of the inner axial direction surface and provided in a circumferential direction on the opposite side of the friction plate of the end plate;
A snap ring fitted into the groove and retaining the end plate;
In the friction engagement device in which the radially outer side of the surface of the end plate on the snap ring side of the end plate protrudes in the axial direction from the portion in contact with the snap ring to form a protrusion.
An annular member having a snap ring contact portion is provided on the end plate between the inner surface of the protrusion and the outer peripheral surface of the snap ring.
Snap ring dropout prevention structure.   The snap ring drop-off prevention structure according to claim 1, wherein the annular member is provided on the end plate by being prevented from being pulled out by a hole snap ring attached to an inner surface of the protrusion.   The snap ring drop-off prevention structure according to claim 2, wherein the annular member forms an axial cross-section L-shape with a radial surface in contact with the end plate and the snap ring contact portion.   A friction engagement device comprising the snap ring drop-off preventing structure according to any one of claims 1 to 3.

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