JP2021191962A - Interrupter - Google Patents

Abstract

To provide an interrupter capable of improving responsiveness of connection release of an interrupting part.SOLUTION: An interrupter 1 includes: a pair of rotating members 3, 5 disposed to be relatively rotatable; an annular interrupting member 7 disposed to be integrally rotatable with the one rotating member 3 and to be movable in an axial direction; an interrupting part 9 provided between the interrupting member 7 and the other rotating member 5 and interrupting power transmission between the pair of rotating members 3, 5 by axial movement of the interrupting member 7; and an energizing member 11 for energizing the interrupting member 7 to a connection release direction of the interrupting part 9. The interrupting part 9 is constituted by meshing teeth formed on an inner case 5 and the interrupting member 7 in the circumferential direction respectively, and radial positions of a central axis O1 of axial movement of the interrupting member 7 and a load center of the energizing force applied to the interrupting member 7 by the energizing member 11 are different from each other.SELECTED DRAWING: Figure 1

Description

The present invention relates to an intermittent device.

Conventionally, as an intermittent device, a differential case and a side gear as a pair of rotating members arranged so as to be relatively rotatable, a cam ring as an annular intermittent member arranged so as to be rotatable integrally with the differential case and movable in the axial direction, and a cam ring. A dog clutch provided between the door and the side gear as an intermittent part that interrupts and interrupts power transmission between the differential case and the side gear by axial movement of the cam ring, and a return as an urging member that urges the cam ring in the direction of disconnection of the dog clutch. Those equipped with a spring are known (see Patent Document 1).

In this intermittent device, when the cam ring is moved in the connecting direction of the dog clutch against the urging force of the return spring, the dog clutch is engaged and connected, and the differential case and the side gear can rotate integrally.

On the other hand, in such an intermittent device, when the cam ring is moved in the direction of disconnection of the dog clutch by the urging force of the return spring, the dog clutch is disengaged and the connection is released, and the differential case and the side gear can rotate relative to each other. ..

Japanese Unexamined Patent Publication No. 2008-281194

By the way, in the intermittent device as in Patent Document 1, a plurality of urging members are provided at equal intervals in the circumferential direction around the central axis of the axial movement of the intermittent member between the intermittent member and the other rotating member in the axial direction. Have been placed.

By arranging the plurality of urging members in this way, the radial position of the central axis of the axial movement of the intermittent member and the radial position of the load center of the urging force applied to the intermittent member by the plurality of urging members can be set. , Will match.

Therefore, when the intermittent member moves in the axial direction due to the urging force of the urging member, the intermittent member is moved in the axial direction without tilting, and the meshing in the intermittent portion is released.

However, in a state where the meshing teeth of the intermittent portion are in mesh with each other, lubricating oil may intervene between the meshing teeth. The responsiveness of disconnection is reduced.

Therefore, an object of the present invention is to provide an intermittent device capable of improving the responsiveness of disconnection of the intermittent portion.

The present invention includes a pair of rotating members arranged so as to be relatively rotatable, an annular interrupting member arranged so as to be integrally rotatable with one of the rotating members and movable in the axial direction, and the intermittent member. An intermittent portion provided between the member and the other rotating member that interrupts power transmission between the pair of rotating members by axial movement of the intermittent member, and the intermittent member is urged in the disconnection direction of the intermittent portion. It is an intermittent device provided with an urging member, and the intermittent portion is composed of a plurality of meshing teeth formed in the circumferential direction of each of the other rotating member and the intermittent member, and is in the axial direction of the intermittent member. The central axis of movement and the load center of the urging force applied to the intermittent member by the urging member are characterized in that their respective radial positions are different.

In this intermittent device, the central axis of the axial movement of the intermittent member and the load center of the urging force applied to the intermittent member by the urging member are different in radial positions.

Therefore, when the intermittent member moves in the axial direction due to the urging force of the urging member, the urging force of the urging member is applied to the intermittent member so that the intermittent member is tilted with respect to the axial direction.

At this time, in a part of the circumferential direction of the intermittent portion, the sticking of the meshing teeth is peeled off due to the inclination of the intermittent member, and the surface tension between the meshing teeth disappears in the entire circumferential direction of the intermittent portion, so that the intermittent portion is easily Can be disengaged.

Therefore, in such an intermittent device, the sticking of the meshing teeth at the intermittent portion can be quickly released, and the responsiveness of disconnection of the intermittent portion can be improved.

According to the present invention, it is possible to provide an intermittent device capable of improving the responsiveness of disconnection of the intermittent portion.

It is sectional drawing of the differential device to which the intermittent device which concerns on 1st Embodiment is applied. It is a side view of the outer case of the differential device in which the urging member of the intermittent device which concerns on 1st Embodiment is arranged. It is a schematic diagram which shows the connection part of the electromagnetic coil and the lead wire in the electromagnet of the interrupting apparatus which concerns on this embodiment. It is sectional drawing of the differential device to which the intermittent device which concerns on 2nd Embodiment is applied.

The intermittent device according to the present embodiment will be described with reference to FIGS. 1 to 4.

(First Embodiment)
The first embodiment will be described with reference to FIGS. 1 to 3.

The intermittent device 1 according to the present embodiment has an outer case 3 and an inner case 5 as a pair of rotating members arranged so as to be relatively rotatable, and an annular shape which is integrally rotatable with the outer case 3 and is arranged so as to be movable in the axial direction. The intermittent member 7 and the intermittent portion 9 provided between the intermittent member 7 and the inner case 5 to interrupt the power transmission between the outer case 3 and the inner case 5 by the axial movement of the intermittent member 7. 7 is provided with an urging member 11 that urges the intermittent portion 9 in the disconnection direction.

Further, the intermittent portion 9 is composed of a plurality of meshing teeth formed in the circumferential direction of each of the inner case 5 and the intermittent member 7.

The radial positions of the central axis O1 of the axial movement of the intermittent member 7 and the load center of the urging force applied to the intermittent member 7 by the urging member 11 are different from each other.

Further, the urging members 11 are arranged at a plurality of locations in the circumferential direction located outside the central axis O1 in the radial direction.

Further, the plurality of urging members 11 are arranged at equal intervals in the circumferential direction, and at least one of the plurality of urging members 11 has a different urging force from the other urging members 11.

First, a differential device to which the intermittent device 1 according to the first embodiment is applied will be described with reference to FIGS. 1 and 2.

As shown in FIGS. 1 and 2, the differential device 201 includes an outer case 3, a differential mechanism 203, and an intermittent device 1.

The outer case 3 is rotatably supported by a stationary member (not shown) such as a carrier via bearings (not shown) on the outer circumferences of boss portions 205 and 207 provided on both sides in the axial direction.

The outer case 3 is provided with a flange portion 209 to which an input gear (not shown) is fixed, and the input gear meshes with a power transmission gear that inputs a driving force from a mechanism on the input side such as a drive source. , The driving force from the mechanism on the input side is transmitted to the outer case 3.

In such an outer case 3, the inner case 5 of the differential mechanism 203 is housed so as to be relatively rotatable, and when the intermittent portion 9 described later is in a connected state, the driving force input to the input gear causes the inner case 5. It is transmitted to the differential mechanism 203 via.

The differential mechanism 203 includes an inner case 5, a pinion shaft 211, a pinion 213, and a pair of side gears 215 and 217.

The inner case 5 has a rotation axis arranged coaxially with the outer case 3 and is housed in the outer case 3 so as to be rotatable relative to the outer case 3.

The pinion shaft 211, the pinion 213, and a pair of side gears 215 and 217 are housed in the inner case 5, and the driving force input to the inner case 5 is transmitted.

The pinion shaft 211 is composed of one long pinion shaft, both ends of which are engaged with the inner case 5, one end of which is prevented from coming off and rotation by a pin, and is rotationally driven integrally with the inner case 5. ..

A plurality of pinions 213 are supported on both ends of the pinion shaft 211.

Two of the plurality of pinions 213 are arranged at equal intervals in the circumferential direction of the inner case 5, and each of them is supported on both ends of the pinion shaft 211 and revolves by the rotation of the inner case 5.

The pinion 213 is rotatably supported by the pinion shaft 211 so that the driving force is transmitted to the pair of side gears 215 and 217 and the pair of side gears 215 and 217 that are engaged with each other are rotationally driven when a differential rotation occurs. There is.

The pair of side gears 215 and 217 are supported by the outer case 3 so as to be relatively rotatable by the boss portions formed therein, and mesh with the pinion 213.

The pair of side gears 215 and 217 are provided with spline-shaped connecting portions 219 and 221 on the inner peripheral side, respectively.

Drive shafts rotatably connected to output-side mechanisms such as left and right wheels are rotatably connected to the side gears 215 and 217, respectively, and input to the inner case 5 of the connecting portions 219 and 221. The driving force is output to the mechanism on the output side.

The driving force transmitted from the outer case 3 to the differential mechanism 203 is interrupted by operating the intermittent device 1 having the intermittent member 7 provided between the outer case 3 and the inner case 5.

As described above, the differential device 201 having the intermittent device 1 for interrupting the power transmission between the outer case 3 and the inner case 5 is a so-called free running differential.

Hereinafter, the details of the intermittent device 1 will be described with reference to FIGS. 1 to 3.

In addition to the outer case 3 and the inner case 5 described above, the intermittent device 1 includes an intermittent member 7, an intermittent portion 9, an urging member 11, a movable member 13, and an electromagnet 15.

The intermittent member 7 is formed in an annular shape, and a base portion 17 formed of one member continuous in the circumferential direction is arranged so as to be axially movable between the wall portion 19 of the outer case 3 and the inner case 5. ..

An engaging portion 21 that rotatably engages with the outer case 3 is provided on the wall portion 19 side of the outer case 3 of the intermittent member 7, and the intermittent portion 9 is provided on the inner case 5 side of the intermittent member 7. It is provided.

The engaging portions 21 are a plurality of (here, four) convex members 23 arranged at equal intervals in the circumferential direction on the base 17 of the intermittent member 7 and fixed to the base 17 via bolts, and a wall portion 19 of the outer case 3. It is composed of a plurality of (here, four) hole portions 25 provided so as to penetrate in the axial direction at equal intervals in the circumferential direction.

By engaging the convex member 23 and the hole portion 25 in the rotational direction, the intermittent member 7 is prevented from rotating by the outer case 3, and the intermittent member 7 and the outer case 3 can rotate integrally.

The engaging portion 21 is provided with a cam that moves the intermittent member 7 in the connecting direction of the intermittent portion 9. Specifically, cam surfaces having the same inclination are formed on the facing surfaces of the convex member 23 and the hole 25 on both sides in the circumferential direction.

Therefore, when the intermittent member 7 is moved in the connection direction of the intermittent portion 9 and the intermittent portion 9 between the outer case 3 and the inner case 5 is engaged in the rotational direction, the rotation of the outer case 3 causes each of the intermittent members 7. By engaging the cam surfaces of the above, the intermittent member 7 is further moved in the meshing direction of the intermittent portion 9, and the connection of the intermittent portion 9 is strengthened.

The intermittent portion 9 is provided between the engaging portion 21 of the base portion 17 of the intermittent member 7 and the side surface opposite to the axial direction between the intermittent member 7 and the inner case 5 in the axial direction, and is provided in the intermittent member 7 and the inner case 5, respectively. It is a meshing clutch composed of meshing teeth that are formed in plurality in the circumferential direction and mesh with each other.

In the intermittent portion 9, the intermittent member 7 and the inner case 5 are integrally rotatably connected by engaging the meshing teeth with each other, that is, the outer case 3 and the inner case 5 are integrally rotatably connected to the outer case 3 and the inner case 5. Power can be transmitted to and from the inner case 5.

On the other hand, the interlocking member 27 is fixed to each of the plurality of convex members 23 of the intermittent member 7 via bolts, and the urging member 11 is provided between the interlocking member 27 and the side surface of the outer case 3 in the axial direction. Have been placed.

The urging member 11 is composed of a coil spring or the like, and a plurality (four in this case) are arranged at equal intervals in the circumferential direction, and the intermittent member 7 is constantly urged in the disconnection direction of the intermittent portion 9 via the interlocking member 27. ing. The details of the urging member 11 will be described later.

By this urging member 11, the intermittent member 7 is moved in the disconnection direction of the intermittent portion 9, and the connection of the intermittent portion 9 is released.

By disconnecting the intermittent portion 9, the intermittent member 7 and the inner case 5 can rotate relative to each other, that is, the outer case 3 and the inner case 5 can rotate relative to each other, and power is transmitted between the outer case 3 and the inner case 5. Is blocked.

The intermittent state of the intermittent portion 9 is controlled by an actuator including a movable member 13 and an electromagnet 15.

The movable member 13 is arranged on the inner diameter side of the electromagnet 15 on the inner peripheral side of the boss portion 207 of the outer case 3 so as to be movable in the axial direction, and includes an annular plunger 29 and a ring member 31.

The plunger 29 is formed of a magnetic material and is arranged on the inner diameter side of the electromagnet 15 with an air gap which is a minute gap set so that magnetic flux can pass through.

The ring member 31 is made of a non-magnetic material and is integrally fixed to the inner diameter side of the plunger 29 to prevent magnetic flux from leaking from the inner peripheral side of the plunger 29 to the outer case 3 side.

Further, the ring member 31 is arranged so as to be movable in the axial direction on the outer periphery of the boss portion 207 of the outer case 3, and is moved outward in the axial direction by the regulating member 33 fixed to the outer periphery of the boss portion 207 by a fixing means such as press fitting. Is regulated.

The ring member 31 is provided with a pressing portion 35 capable of contacting the axial end surface of the convex member 23 of the intermittent member 7 on the axial end surface on the intermittent member 7 side.

Such a ring member 31 transmits an axial movement operation force by the movable member 13 operated by the electromagnet 15 from the pressing portion 35 to the intermittent member 7 via the convex member 23, and transfers the intermittent member 7 to the intermittent portion 9. Press in the connection direction of.

The electromagnet 15 is arranged on the outer peripheral side of the boss portion 207 of the outer case 3, and is arranged adjacent to the wall portion 19 of the outer case 3 in the axial direction.

The inner diameter side of the core 39 of the electromagnet 15 is in contact with a restricting member 33 that restricts the movement of the movable member 13 outward in the axial direction, and the movement of the electromagnet 15 outward in the axial direction is restricted.

Further, on the outer diameter side of the core 39 of the electromagnet 15, an extension portion 41 extending toward the outer case 3 side is provided, and the extension portion 41 faces axially in the recess of the outer case 3. The movement of the electromagnet 15 inward in the axial direction is restricted by the arrangement.

The electromagnet 15 is integrally provided with a detent member 43 on the axial end surface of the core 39, and the electromagnet 15 is detented by engaging the detent member 43 with a stationary member such as a carrier.

Such an electromagnet 15 includes an electromagnetic coil 37 and a core 39.

The electromagnetic coil 37 is annularly wound a predetermined number of turns and molded with a resin, and a lead wire 45 drawn out to the outside of the core 39 is electrically connected.

The lead wire 45 drawn from the core 39 is electrically connected to a controller (not shown) that controls energization of the electromagnet 15.

Here, conventionally, the connection portion is insulated by arranging a heat-shrinkable tube or winding a tape around the connection portion between the electromagnetic coil 37 and the lead wire 45, and the epoxy resin having a sealing function is used for electromagnetic waves. The coil 37 is fixed to the resin to be molded.

However, when the epoxy resin is cracked, the insulating property at the connection portion between the electromagnetic coil 37 and the lead wire 45 is lowered, and there is a possibility that leakage may occur.

Therefore, as shown in FIG. 3, the connection portion 47 between the electromagnetic coil 37 and the lead wire 45 has a heat-shrinkable tube 49 with an adhesive having a sealing function, or heat coated with a sealing material or an adhesive inside. A shrink tube 49 is arranged.

By arranging the heat-shrinkable tube 49 having a sealing function in the connection portion 47 between the electromagnetic coil 37 and the lead wire 45 in this way, the insulation of the connection portion 47 can be stably maintained, and the leakage reliability can be improved. Can be improved.

The core 39 is formed of a magnetic material so that a magnetic field is formed by energizing the electromagnetic coil 37, and has a predetermined magnetic path cross-sectional area.

The core 39 covers the outer peripheral surface of the electromagnetic coil 37 in an annular shape so as to have a predetermined distance between the plunger 29 of the movable member 13 and the magnetic flux on the inner diameter side of the electromagnetic coil 37.

Such a core 39 forms a magnetic flux loop with a magnetic flux passing through the core 39, the plunger 29, and the wall portion 19 of the outer case 3 by energizing the electromagnetic coil 37, and directs the movable member 13 toward the intermittent member 7. To move.

In the intermittent device 1 configured in this way, the plunger 29 is on the intermittent member 7 side by using the shortest magnetic flux loop formed by the magnetic flux transmitted through the core 39, the plunger 29, and the wall portion 19 by the excitation of the electromagnet 15. The ring member 31 presses the convex member 23.

By the pressing operation of the convex member 23 by the movable member 13, the intermittent member 7 is moved in the connection direction of the intermittent portion 9 against the urging force of the urging member 11, and the intermittent portion 9 is connected.

By the connection of the intermittent portion 9, the inner case 5 and the intermittent member 7 are integrally rotatably connected, the inner case 5 and the outer case 3 are connected, and the power transmission between the outer case 3 and the inner case 5 is performed. Is possible.

On the other hand, when disconnecting the intermittent portion 9, by stopping the energization of the electromagnet 15, the intermittent member 7 is moved in the disconnection direction of the intermittent portion 9 by the urging force of the urging member 11, and the connection of the intermittent portion 9 is disconnected. It will be released.

By disconnecting the intermittent portion 9, the inner case 5 and the intermittent member 7 can rotate relative to each other, and the inner case 5 and the outer case 3 can rotate relative to each other. Power transmission is cut off.

In such an intermittent device 1, a plurality of (here, four) urging members 11 that urge the intermittent member 7 in the disconnection direction of the intermittent portion 9 are in the circumferential direction of the intermittent member 7, as shown in FIG. On the other hand, the urging members 11 and 11 adjacent to each other are arranged at equal intervals of 90 °.

Further, the plurality of urging members 11 are set to have the same distance from the central axis O1 of the axial movement of the intermittent member 7 toward the outside in the radial direction, and the respective radial positions with respect to the central axis O1 are the same. Has been done.

When the urging force of each of the plurality of urging members 11 arranged in this way is set to be the same, the load center of the urging force applied to the intermittent member 7 by the plurality of urging members 11 coincides with the central axis O1. do.

Therefore, when the intermittent member 7 moves in the axial direction (the connection disconnection direction of the intermittent portion 9) due to the urging force of the plurality of urging members 11, the intermittent member 7 does not tilt in the direction orthogonal to the axial direction. It is moved in the axial direction, and the meshing at the intermittent portion 9 is released.

Here, in a state where the meshing teeth of the intermittent portion 9 are in mesh with each other, the lubricating oil may intervene between the meshing teeth, and when the lubricating oil intervenes, the meshing teeth stick to each other due to surface tension. It is in a state of being.

If the intermittent member 7 is moved in the axial direction in the disconnection direction of the intermittent portion 9 without tilting in the state where the meshing teeth are attached to each other, the engaging teeth are uniformly peeled off in the entire circumferential direction.

Therefore, in the intermittent portion 9, it is difficult to release the sticking of the meshing teeth, and the responsiveness of disconnection of the intermittent portion 9 is lowered.

Further, it is conceivable to increase the urging force of the urging member 11, but the cost of the urging member 11 must be increased and the rigidity of the portion of the urging member 11 that receives the urging force must be increased. The cost of the member 7 also increases.

Therefore, at least one of the plurality of urging members is set to be larger or smaller than the urging force of the other urging member 11 so that the urging force is different from that of the other urging member 11. There is.

By setting the urging force of the plurality of urging members 11 in this way, the radial position of the load center of the urging force applied to the intermittent member 7 by the plurality of urging members 11 is the center of the axial movement of the intermittent member 7. It is arranged at a position different from the axis O1.

By offsetting the load center of the urging force and the central axis O1 in this way, when the intermittent member 7 moves in the disconnection direction of the intermittent portion 9 due to the urging force of the plurality of urging members 11, it is orthogonal to the axial direction. The intermittent member 7 is moved in the axial direction so as to be tilted with respect to the direction.

Therefore, in the intermittent portion 9, the meshing tooth is peeled off at a part of the peripheral direction of the meshing tooth that is stuck, and the meshing tooth can be easily peeled off in the entire circumferential direction of the meshing tooth from this portion as a starting point. It is possible to improve the responsiveness of disconnection of the unit 9.

Further, since the urging force of at least one of the plurality of urging members 11 may be different, it is possible to suppress the cost increase of the urging member 11 and the intermittent member 7.

In such an intermittent device 1, the central axis O1 of the axial movement of the intermittent member 7 and the load center of the urging force applied to the intermittent member 7 by the urging member 11 are different in radial positions.

Therefore, when the intermittent member 7 moves in the axial direction due to the urging force of the urging member 11, the urging force of the urging member 11 is applied to the intermittent member 7 so that the intermittent member 7 is tilted with respect to the axial direction.

At this time, in a part of the circumferential direction of the intermittent portion 9, the sticking of the meshing teeth is peeled off due to the inclination of the intermittent member 7, and the surface tension between the meshing teeth disappears in the entire circumferential direction of the intermittent portion 9, which is easy. The meshing of the intermittent portion 9 can be disengaged.

Therefore, in such an intermittent device 1, the sticking of the meshing teeth in the intermittent portion 9 can be quickly released, and the responsiveness of disconnection of the intermittent portion 9 can be improved.

Further, the urging members 11 are arranged at a plurality of locations in the circumferential direction located outside the central axis O1 in the radial direction.

Therefore, by changing the design of at least one of the plurality of urging members 11, the load center of the urging force applied to the intermittent member 7 by the plurality of urging members 11 is the central axis of the axial movement of the intermittent member 7. It can be different from O1.

Further, the plurality of urging members 11 are arranged at equal intervals in the circumferential direction, and at least one of the plurality of urging members 11 has a different urging force from the other urging members 11.

Therefore, the urging force of at least one of the plurality of urging members 11 may be different from the urging force of the other urging members 11, and the responsiveness of disconnection of the intermittent portion 9 may be achieved without complicating the structure. Can be improved.

(First modification of the first embodiment)
In the intermittent device according to the present embodiment, a plurality of urging members 11 (see FIG. 1) are arranged at uneven intervals in the circumferential direction.

In addition, the same symbol is described in the same configuration as the first embodiment, and the configuration and the function description are omitted with reference to the first embodiment. The effects are the same.

Although not shown, the plurality of urging members 11 (see FIG. 1) that urge the intermittent member 7 (see FIG. 1) in the disconnection direction of the intermittent portion 9 (see FIG. 1) are in the circumferential direction of the intermittent member 7. On the other hand, they are arranged at uneven intervals so that the intervals between the adjacent urging members 11 and 11 are different.

The plurality of urging members 11 are set to have the same distance from the central axis O1 (see FIG. 2) of the axial movement of the intermittent member 7 toward the outside in the radial direction, and the respective radial positions with respect to the central axis O1 are set. It is designed to be the same.

By arranging the plurality of urging members 11 in this way, the radial position of the load center of the urging force applied to the intermittent member 7 by the plurality of urging members 11 becomes the central axis O1 of the axial movement of the intermittent member 7. Placed in different positions.

Therefore, the load center of the urging force and the central axis O1 are offset, and when the intermittent member 7 moves in the disconnection direction of the intermittent portion 9 due to the urging force of the plurality of urging members 11, the direction is orthogonal to the axial direction. On the other hand, the intermittent member 7 is moved in the axial direction so as to be tilted.

Therefore, in the intermittent portion 9, the meshing tooth is peeled off at a part of the peripheral direction of the meshing tooth that is stuck, and the meshing tooth can be easily peeled off in the entire circumferential direction of the meshing tooth from this portion as a starting point. The responsiveness of disconnection of 9 can be improved.

In such an intermittent device, a plurality of urging members 11 are arranged at uneven intervals with respect to the circumferential direction.

Therefore, the plurality of urging members 11 may be arranged at uneven intervals with respect to the circumferential direction of the intermittent member 7, and the responsiveness of disconnection of the intermittent portion 9 can be improved without complicating the structure. Can be done.

(Second variant of the first embodiment)
In the intermittent device according to the present embodiment, at least one of the plurality of urging members 11 (see FIG. 1) is arranged at a position different in the radial direction from the other urging members 11.

In addition, the same symbol is described in the same configuration as the first embodiment, and the configuration and the function description are omitted with reference to the first embodiment. The effects are the same.

Although not shown, at least one of the plurality of urging members 11 (see FIG. 1) that urge the intermittent member 7 (see FIG. 1) in the disconnection direction of the intermittent portion 9 (see FIG. 1) is the other. It is arranged at a position different from that of the urging member 11 in the radial direction.

Specifically, at least one urging member 11 is set so that the distance from the central axis O1 (see FIG. 2) of the axial movement of the intermittent member 7 toward the outside in the radial direction is different from that of the other urging members 11. Has been done.

Therefore, at least one urging member 11 is set so that the radial position with respect to the central axis O1 is different from the radial position of the other urging member 11.

The plurality of urging members 11 may have equal or non-uniform spacing between the adjacent urging members 11 and 11 in the circumferential direction of the intermittent member 7.

By arranging the plurality of urging members 11 in this way, the radial position of the load center of the urging force applied to the intermittent member 7 by the plurality of urging members 11 becomes the central axis O1 of the axial movement of the intermittent member 7. Placed in different positions.

Therefore, the load center of the urging force and the central axis O1 are offset, and when the intermittent member 7 moves in the disconnection direction of the intermittent portion 9 due to the urging force of the plurality of urging members 11, the direction is orthogonal to the axial direction. On the other hand, the intermittent member 7 is moved in the axial direction so as to be tilted.

Therefore, in the intermittent portion 9, the meshing tooth is peeled off at a part of the peripheral direction of the meshing tooth that is stuck, and the meshing tooth can be easily peeled off in the entire circumferential direction of the meshing tooth from this portion as a starting point. The responsiveness of disconnection of 9 can be improved.

If the plurality of urging members 11 are arranged at uneven intervals with respect to the circumferential direction of the intermittent member 7, the offset between the load center of the urging force and the central axis O1 can be made larger, and the intermittent portion 9 can be arranged. The responsiveness of disconnection can be further improved.

In such an intermittent device, at least one of the plurality of urging members 11 is arranged at a position different in the radial direction from the other urging members 11.

Therefore, at least one of the plurality of urging members 11 may be arranged at a position different in the radial direction from the other urging members 11, and the response of disconnection of the intermittent portion 9 without complicating the structure. The sex can be improved.

(Second Embodiment)
The second embodiment will be described with reference to FIG.

The intermittent device 101 according to the present embodiment has an outer case 103 and an inner case 105 as a pair of rotating members arranged so as to be relatively rotatable, and an annular shape which is integrally rotatable with the outer case 103 and is movable in the axial direction. The intermittent member 109, the intermittent portion 109 provided between the intermittent member 107 and the inner case 105, and interrupting the power transmission between the outer case 103 and the inner case 105 by the axial movement of the intermittent member 107, and the intermittent member. It is provided with an urging member 111 that urges the 107 in the disconnection direction of the intermittent portion 109.

Further, the intermittent portion 109 is composed of a plurality of meshing teeth formed in the circumferential direction of each of the inner case 105 and the intermittent member 107.

The radial positions of the central axis O2 of the axial movement of the intermittent member 107 and the load center of the urging force applied to the intermittent member 107 by the urging member 111 are different from each other.

Further, the urging member 111 is formed in an annular shape.

Further, the center of the urging member 111 is arranged in a radial position different from that of the central axis O2.

In addition, the same symbol is described in the same configuration as the first embodiment, and the configuration and the function description are omitted with reference to the first embodiment. The effects are the same.

First, a differential device to which the intermittent device 101 according to the second embodiment is applied will be described with reference to FIG.

As shown in FIG. 4, the differential device 301 includes an outer case 103, a differential mechanism 303, and an intermittent device 101.

The outer case 103 is rotatably supported by a stationary member (not shown) such as a carrier via bearings (not shown) on the outer circumferences of boss portions 305 and 307 provided on both sides in the axial direction.

The outer case 103 is provided with a flange portion 309 to which an input gear (not shown) is fixed, and the input gear meshes with a power transmission gear that inputs a driving force from a mechanism on the input side such as a drive source. , The driving force from the mechanism on the input side is transmitted to the outer case 103.

In such an outer case 103, the inner case 105 of the differential mechanism 303 is housed so as to be relatively rotatable, and when the intermittent portion 109 described later is in a connected state, the driving force input to the input gear causes the inner case 105. It is transmitted to the differential mechanism 303 via.

The differential mechanism 303 includes an inner case 105, pinion shafts 311, 313, a pinion 315, and a pair of side gears 317, 319.

The inner case 105 has a rotation axis arranged coaxially with the outer case 103, and is housed in the outer case 103 so as to be rotatable relative to the outer case 103.

The pinion shafts 311, 313, the pinion 315, and the pair of side gears 317, 319 are housed in the inner case 105, and the driving force input to the inner case 105 is transmitted.

The pinion shafts 311, 313 are composed of two short pinion shafts 311 and one long pinion shaft 313.

The two short pinion shafts 311 are rotationally driven integrally with the inner case 105 by engaging the outer end portion with the inner case 105 to prevent it from coming off and rotating with a pin.

The one long pinion shaft 313 is rotationally driven integrally with the inner case 105 by engaging the inner ends of the two short pinion shafts 311 with the holes provided in the middle to prevent them from coming off and rotating. To.

A plurality of pinion 315s are supported on the outer end sides of each of the pinion shafts 311, 313.

Four pinions 315 are arranged at equal intervals in the circumferential direction of the inner case 105, and are supported on the outer end side of the two short pinion shafts 311 and both ends of the long pinion shaft 313, respectively, of the inner case 105. Revolves by rotation.

Such a pinion 315 can rotate to the pinion shafts 311, 313 so that the driving force is transmitted to the pair of side gears 317 and 319 and the pair of side gears 317 and 319 that are engaged with each other are rotationally driven when a differential rotation occurs. Is supported by.

The pair of side gears 317 and 319 are supported by the outer case 103 so as to be relatively rotatable by the boss portions formed therein, and mesh with the pinion 315.

The pair of side gears 317 and 319 are provided with spline-shaped connecting portions 321 and 323 on the inner peripheral side, respectively.

Drive shafts rotatably connected to output-side mechanisms such as left and right wheels are rotatably connected to the side gears 317 and 319, respectively, and input to the inner case 105. The driving force is output to the mechanism on the output side.

The driving force transmitted from the outer case 103 to the differential mechanism 303 is interrupted by operating the intermittent device 101 having the intermittent member 107 provided between the outer case 103 and the inner case 105.

As described above, the differential device 301 having the intermittent device 101 that interrupts the power transmission between the outer case 103 and the inner case 105 is a so-called free running differential.

Hereinafter, the details of the intermittent device 101 will be described with reference to FIG.

In addition to the outer case 103 and the inner case 105 described above, the intermittent device 101 includes an intermittent member 107, an intermittent portion 109, an urging member 111, a movable member 113, and an electromagnet 115.

The intermittent member 107 is formed in an annular shape, and a base portion 117 formed of one member continuous in the circumferential direction is arranged so as to be axially movable between the wall portion 119 of the outer case 103 and the inner case 105 in the axial direction. ..

An engaging portion 121 that rotatably engages with the outer case 103 is provided on the wall portion 119 side of the outer case 103 of the intermittent member 107, and the intermittent portion 109 is provided on the inner case 105 side of the intermittent member 107. It is provided.

The engaging portions 121 are provided through a plurality of convex portions 123 provided at equal intervals in the circumferential direction on the base 117 of the intermittent member 107 and axially through the wall portions 119 of the outer case 103 at equal intervals in the circumferential direction. It is composed of a plurality of holes 125.

By engaging the convex portion 123 and the hole portion 125 in the rotational direction, the intermittent member 107 is prevented from rotating by the outer case 103, and the intermittent member 107 and the outer case 103 can rotate integrally.

The engaging portion 121 is provided with a cam that moves the intermittent member 107 in the connecting direction of the intermittent portion 109. Specifically, cam surfaces having the same inclination are formed on the facing surfaces of the convex portion 123 and the hole portion 125 on both sides in the circumferential direction.

Therefore, when the intermittent member 107 is moved in the connection direction of the intermittent portion 109 and the intermittent portion 109 between the outer case 103 and the inner case 105 is engaged in the rotational direction, the rotation of the outer case 103 causes each of the intermittent members 107 to engage with each other. By engaging the cam surfaces of the above, the intermittent member 107 is further moved in the meshing direction of the intermittent portion 109, and the connection of the intermittent portion 109 is strengthened.

The intermittent portion 109 is provided between the engaging portion 121 of the base portion 117 of the intermittent member 107 and the side surface opposite to the axial direction between the intermittent member 107 and the inner case 105 side in the axial direction, and is provided between the intermittent member 107 and the inner case 105. A plurality of meshing clutches are formed in the circumferential direction and are composed of meshing teeth that mesh with each other.

In the intermittent portion 109, the intermittent member 107 and the inner case 105 are integrally rotatably connected by engaging the meshing teeth with each other, that is, the outer case 103 and the inner case 105 are integrally rotatably connected to the outer case 103. Power can be transmitted to and from the inner case 105.

On the other hand, the interlocking member 127 is fixed to each of the plurality of convex portions 123 of the intermittent member 107 via bolts, and the urging member 111 is provided between the interlocking member 127 and the side surface of the outer case 103 in the axial direction. Have been placed.

The urging member 111 is formed in an annular shape and includes a wave spring or the like that presses at a plurality of locations, and the intermittent member 107 is constantly urged in the disconnection direction of the intermittent portion 109 via the interlocking member 127. The details of the urging member 111 will be described later.

The urging member 111 moves the intermittent member 107 in the disconnection direction of the intermittent portion 109, and disconnects the intermittent portion 109.

By disconnecting the intermittent portion 109, the intermittent member 107 and the inner case 105 can rotate relative to each other, that is, the outer case 103 and the inner case 105 can rotate relative to each other, and power is transmitted between the outer case 103 and the inner case 105. Is blocked.

The intermittent state of the intermittent portion 109 is controlled by an actuator including a movable member 113 and an electromagnet 115.

The movable member 113 is arranged on the inner diameter side of the electromagnet 115 on the outer periphery of the boss portion 307 of the outer case 103 so as to be movable in the axial direction via the support portion 133 of the electromagnet 115, and includes an annular plunger 129 and a ring member 131. ing.

The plunger 129 is formed of a magnetic material and is arranged on the inner diameter side of the electromagnet 115 with an air gap which is a minute gap set so that magnetic flux can pass through.

The ring member 131 is made of a non-magnetic material and is integrally fixed to the inner diameter side of the plunger 129 to prevent magnetic flux from leaking from the inner peripheral side of the plunger 129 to the outer case 103 side.

In this ring member 131, the end face in the axial direction on the intermittent member 107 side can come into contact with the interlocking member 127.

Such a ring member 131 transmits an axial movement operation force by the movable member 113 operated by the electromagnet 115 to the intermittent member 107 via the interlocking member 127, and transmits the intermittent member 107 in the connection direction of the intermittent portion 109. Press operation.

The electromagnet 115 is arranged on the outer peripheral side of the boss portion 307 of the outer case 103 via a support portion 133 provided integrally with the core 141, and is arranged adjacent to the wall portion 119 of the outer case 103 in the axial direction. ..

On the inner diameter side of the support portion 133, the movement of the electromagnet 115 outward in the axial direction is restricted by a regulating member 135 such as a C-shaped clip engaged with the outer circumference of the boss portion 307 of the outer case 103.

Further, on the inner diameter side of the support portion 133, the movement of the electromagnet 115 inward in the axial direction is restricted by the step portion 137 formed on the outer periphery of the boss portion 307 of the outer case 103.

The electromagnet 115 is provided with a detent member (not shown) integrally with the core 141, and is detented by engaging the detent member with a stationary member such as a carrier.

Such an electromagnet 115 includes an electromagnetic coil 139 and a core 141.

The electromagnetic coil 139 is annularly wound a predetermined number of turns, molded with a resin, drawn out of the core 141, and electrically connected to a controller (not shown) that controls energization of the electromagnet 115. 45 (see FIG. 3) is electrically connected.

The core 141 is formed of a magnetic material so that a magnetic field is formed by energizing the electromagnetic coil 139, and has a predetermined magnetic path cross-sectional area.

The core 141 covers the outer peripheral surface of the electromagnetic coil 139 in an annular shape so as to have a predetermined distance from the plunger 129 of the movable member 113 on the inner diameter side of the electromagnetic coil 139.

Such a core 141 forms a self-contained magnetic flux loop with the magnetic flux transmitted through the core 141 and the plunger 129 by energizing the electromagnetic coil 139, and moves the movable member 113 toward the intermittent member 107 side.

In the intermittent device 101 configured in this way, the plunger 129 moves to the intermittent member 107 side by using a self-contained magnetic flux loop formed by the magnetic flux transmitted through the core 141 and the plunger 129 by the excitation of the electromagnet 115. Operated, the ring member 131 presses the interlocking member 127.

By the pressing operation of the interlocking member 127 by the movable member 113, the intermittent member 107 is moved in the connection direction of the intermittent portion 109 against the urging force of the urging member 111, and the intermittent portion 109 is connected.

By the connection of the intermittent portion 109, the inner case 105 and the intermittent member 107 are integrally rotatably connected, the inner case 105 and the outer case 103 are connected, and the power transmission between the outer case 103 and the inner case 105 is performed. Is possible.

On the other hand, when disconnecting the intermittent portion 109, by stopping the energization of the electromagnet 115, the intermittent member 107 is moved in the disconnection direction of the intermittent portion 109 by the urging force of the urging member 111, and the connection of the intermittent portion 109 is disconnected. It will be released.

By disconnecting the intermittent portion 109, the inner case 105 and the intermittent member 107 can rotate relative to each other, and the inner case 105 and the outer case 103 can rotate relative to each other. Power transmission is cut off.

In such an intermittent device 101, the annular urging member 111 is provided with a plurality of pressing portions for urging the intermittent member 107 in the circumferential direction.

When the center of such an annular urging member 111 coincides with the central axis O2 of the axial movement of the intermittent member 107, the load center of the urging force applied to the intermittent member 107 by the urging member 111 is the center. It coincides with the axis O2.

Therefore, the center of the annular urging member 111 is arranged in a radial position different from that of the central axis O2 of the axial movement of the intermittent member 107.

By making the radial positions of the center of the urging member 111 and the central axis O2 of the axial movement of the intermittent member 107 different in this way, the radial direction of the load center of the urging force applied to the intermittent member 107 by the urging member 111. The position is arranged at a position different from the central axis O2.

By offsetting the load center of the urging force and the central axis O2 in this way, when the intermittent member 107 moves in the disconnection direction of the intermittent portion 109 due to the urging force of the urging member 111, the direction is orthogonal to the axial direction. On the other hand, the intermittent member 107 is moved in the axial direction so as to be tilted.

Therefore, in the intermittent portion 109, the meshing tooth is peeled off at a part of the peripheral direction of the meshing tooth that is stuck, and the meshing tooth can be easily peeled off in the entire circumferential direction of the meshing tooth from this portion as a starting point. It is possible to improve the responsiveness of disconnection of the unit 109.

In such an intermittent device 101, the radial positions of the central axis O2 of the axial movement of the intermittent member 107 and the load center of the urging force applied to the intermittent member 107 by the urging member 111 are different from each other.

Therefore, when the intermittent member 107 is moved in the axial direction by the urging force of the urging member 111, the urging force of the urging member 111 is applied to the intermittent member 107 so that the intermittent member 107 is tilted with respect to the axial direction.

At this time, in a part of the circumferential direction of the intermittent portion 109, the sticking of the meshing teeth is peeled off due to the inclination of the intermittent member 107, and the surface tension between the meshing teeth disappears in the entire circumferential direction of the intermittent portion 109, which is easy. The meshing of the intermittent portion 109 can be disengaged.

Therefore, in such an intermittent device 101, the sticking of the meshing teeth in the intermittent portion 109 can be quickly released, and the responsiveness of disconnection of the intermittent portion 109 can be improved.

Further, since the urging member 111 is formed in an annular shape, the load center of the urging force applied to the intermittent member 107 by the urging member 111 by changing the arrangement thereof and the urging force of the portion pressing the intermittent member 107. Can be different from the central axis O2 of the axial movement of the intermittent member 107.

Further, since the center of the urging member 111 is arranged in a radial position different from that of the central axis O2, it is not necessary to change the shape of the urging member 111.

Therefore, it is possible to improve the responsiveness of disconnection of the intermittent portion 109 without complicating the structure.

(Modified example of the second embodiment)
In the intermittent device according to the present embodiment, the center of the urging member 111 (see FIG. 4) is arranged in the same radial position as the central axis O2 (see FIG. 4), and at least one in the circumferential direction of the urging member 111. The location is different from the other locations.

In addition, the same symbol is described in the same configuration as the second embodiment, and the configuration and the function description are omitted with reference to the second embodiment. The effects are the same.

Although not shown, the center of the urging member 111 (see FIG. 4) that urges the intermittent member 107 (see FIG. 4) in the disconnection direction of the intermittent portion 109 (see FIG. 4) is in the axial direction of the intermittent member 107. They are arranged concentrically so as to coincide with the central axis O2 (see FIG. 4) of movement.

At least one of the plurality of pressing portions for urging the intermittent member 107 of the urging member 111 has a larger urging force than the urging force of the other pressing portion so that the urging force is different from that of the other pressing portion. Or is set small.

By setting the plurality of pressing portions of the urging member 111 in this way, the radial position of the load center of the urging force applied to the intermittent member 107 by the urging member 111 is set to the central axis O2 of the axial movement of the intermittent member 107. It is placed in a different position from.

Therefore, when the load center of the urging force and the central axis O2 are offset and the intermittent member 107 moves in the disconnection direction of the intermittent portion 109 due to the urging force of the urging member 111, the direction is orthogonal to the axial direction. The intermittent member 107 is moved in the axial direction so as to be tilted.

Therefore, in the intermittent portion 109, the meshing tooth is peeled off at a part of the peripheral direction of the meshing tooth that is stuck, and the meshing tooth can be easily peeled off in the entire circumferential direction of the meshing tooth from this portion as a starting point. The responsiveness of disconnection of 109 can be improved.

In such an intermittent device, the center of the urging member 111 is arranged at the same radial position as the central axis O2, and at least one position in the circumferential direction of the urging member 111 has a different urging force from the other points.

Therefore, it is sufficient to make the urging force of the urging member 111 different from that of the other portions in the circumferential direction, and it is possible to improve the responsiveness of disconnection of the intermittent portion 109 without complicating the structure. can.

The intermittent device according to the present embodiment is applied to a free running differential having an outer case and an inner case, but is not limited to this, and is a differential device having a differential lock function capable of locking the differential of the differential mechanism. Can also be applied to.

Further, the intermittent device according to the present embodiment can be applied not only to a differential device but also to a power transmission device for interrupting power transmission between a pair of relatively rotatable rotating members.

Further, the actuator for moving and operating the intermittent member is not limited to the electromagnetic actuator, but is not limited to this, and various types such as a motor / gear / cam mechanism, a hydraulic cylinder / piston mechanism, a motor / shift rod mechanism, and an air diaphragm are used. Actuators are available.

1,101 Intermittent device 3,103 Outer case (one rotating member)
5,105 Inner case (the other rotating member)
7,107 Intermittent member 9,109 Intermittent part 11,111 Biasing member O1, O2 Central axis

Claims (8)

A pair of rotating members arranged so as to be relatively rotatable, an annular intermittent member arranged so as to be integrally rotatable with one of the rotating members and movable in the axial direction, and the intermittent member and the other. An intermittent portion provided between the rotating member and interrupting power transmission between the pair of rotating members by axial movement of the intermittent member, and an urging member that urges the intermittent member in the disconnection direction of the intermittent portion. It is an intermittent device equipped with
The intermittent portion is composed of a plurality of meshing teeth formed in the circumferential direction of each of the other rotating member and the intermittent member.
An intermittent device characterized in that the central axis of axial movement of the intermittent member and the load center of the urging force applied to the intermittent member by the urging member are different in radial positions. The intermittent device according to claim 1, wherein the device is
The urging member is an intermittent device characterized by being arranged at a plurality of locations in the circumferential direction located outside the radial direction of the central axis. The intermittent device according to claim 2, wherein the device is
The interrupting device, wherein the plurality of urging members are arranged at uneven intervals in the circumferential direction. The intermittent device according to claim 2, wherein the device is
The plurality of urging members are arranged at equal intervals in the circumferential direction.
At least one of the plurality of urging members is an intermittent device characterized in that the urging force is different from that of the other urging members. The intermittent device according to any one of claims 2 to 4.
An intermittent device, wherein at least one of the plurality of urging members is arranged at a position different in the radial direction from the other urging members. The intermittent device according to claim 1, wherein the device is
The urging member is an intermittent device characterized in that it is formed in an annular shape. The intermittent device according to claim 6, wherein the device is
The center of the urging member is an intermittent device characterized in that the radial position is arranged differently from the central axis. The intermittent device according to claim 6, wherein the device is
The center of the urging member is arranged so that the radial position is the same as that of the central axis.
An intermittent device characterized in that at least one position in the circumferential direction of the urging member has a different urging force from the other points.

Images