JP2015113921A - Interruption device and differential device using interruption device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an interruption device capable of improving lubricity to a movable member and improving operation responsiveness of the movable member due to excitation of an electromagnet, and a differential device using the interruption device.SOLUTION: An interruption device 1 includes: a first member 7 and a second member 9; an interruption member 13; an annular electromagnet 15 intermittently operating the interruption device 13; and a movable member 17 arranged on the inner diameter side of the electromagnet 15 in an axial movable manner and operating the interruption member 13 due to excitation of the electromagnet 15. In the interruption device 1, an annular regulation member 19 regulating axial movement of the electromagnet 15 and movable member 17 is provided, and a pore 21 communicating the side of the electromagnet 15 and movable member 17 with one side in an axial direction is provided.

Description

  The present invention relates to an intermittent device applied to a vehicle and a differential device using the intermittent device.

  Conventionally, as an interrupting device, a differential case and a side gear as first and second members arranged in a casing so as to be capable of relative rotation via a bearing, and a differential case and a rotation to interrupt power transmission between the differential case and the side gear. An intermittent member integrally connected to the direction and connected so as to be movable in the axial direction, an annular electromagnet for intermittently operating the intermittent member, and an axially movable intermittent member disposed on the inner diameter side of the electromagnet. A movable member that is moved and operated is known (for example, see Patent Document 1).

  In this intermittent device, the movable member is moved in the axial direction by the magnetic path formed by the excitation of the electromagnet, and the intermittent member is moved in the axial direction by the axial movement of the movable member. Becomes a connected state, and power transmission becomes possible.

JP 2013-130228 A

  However, in the intermittent device as described in Patent Document 1, the movable member is disposed on the inner diameter side of the electromagnet so as to be movable in the axial direction. However, the supply of lubricating oil to the movable member is insufficient, and the movable member is movable by excitation of the electromagnet. The response reactivity of the member may be reduced.

  Accordingly, an object of the present invention is to provide an intermittent device that can improve the lubricity with respect to the movable member and improve the response responsiveness of the movable member by excitation of an electromagnet, and a differential device using the intermittent device.

  The present invention includes a first member and a second member housed in a casing in which lubricating oil is sealed and disposed so as to be relatively rotatable, and the power transmission between the first member and the second member is interrupted. An intermittent member integrally connected to one of the first member and the second member in the rotational direction so as to be axially movable, an annular electromagnet for intermittently operating the intermittent member, and an inner diameter side or an outer diameter side of the electromagnet An intermittent device that is arranged to be movable in the axial direction and includes a movable member that moves the intermittent member in the axial direction by excitation of the electromagnet, wherein one of the first member and the second member includes the electromagnet and An annular restricting member that restricts movement of the movable member in the axial direction is provided, and the restricting member is provided with a hole that communicates the electromagnet and the movable member side in the axial direction. It is characterized by that.

  In this intermittent device, the annular restriction member that restricts the movement of the electromagnet and the movable member to the one side in the axial direction is provided with a hole portion that allows the electromagnet and the movable member side to communicate with the one side in the axial direction. Thus, the lubricating oil can be caused to flow into the movable member side through this, and the lubricity of the movable member can be improved.

  Therefore, in such an intermittent device, the restriction member restricts the movement of the movable member in the axial direction, improves the lubricity to the movable member by the hole of the restriction member, and improves the response responsiveness of the movable member by excitation of the electromagnet. can do.

  According to the present invention, it is possible to provide an intermittent device that can improve the lubricity with respect to the movable member and improve the operation responsiveness of the movable member due to the excitation of the electromagnet, and a differential device using the intermittent device. Play.

1 is a cross-sectional view of an intermittent device and a differential device according to an embodiment of the present invention. 1 is a cross-sectional view of an intermittent device and a differential device according to an embodiment of the present invention. It is a side view of the intermittence device concerning an embodiment of the invention. (A) is a figure which shows the magnetic force line in the electromagnet of a prior art example. (B) is a figure which shows the magnetic force line in the electromagnet of a comparative example. (C) is a figure which shows the magnetic force line in the electromagnet of the interruption apparatus which concerns on embodiment of this invention. It is a figure which shows the change of the drag torque with respect to the voltage of each electromagnet shown in FIG. It is sectional drawing which shows the other example of the electromagnet of the intermittent device which concerns on embodiment of this invention. It is sectional drawing which shows the other examples of the interruption apparatus and differential apparatus which concern on embodiment of this invention. It is a top view which shows the other example of the intermittent device and differential apparatus which concern on embodiment of this invention. (A), (b) is sectional drawing which shows the other example of the electromagnet of the intermittent device which concerns on embodiment of this invention. It is a figure which shows the change of the thrust of a movable member with respect to the axial stroke of the movable member of the electromagnet of the intermittent device which concerns on embodiment of this invention, and the electromagnet of a comparative example.

  First, a differential apparatus to which an interrupting apparatus according to an embodiment of the present invention is applied will be described with reference to FIGS.

  As shown in FIG. 1, the differential device 101 includes a differential mechanism 109 including a differential case 7, a pinion shaft 103, a pinion 105 as a differential gear, and side gears 107 and 9 as a pair of output gears. The apparatus 1 is provided.

  The differential case 7 is rotatably supported by the casing 3 as a stationary system member via bearings 113 and 5 on the outer circumferences of the boss portions 111 and 43 formed on both sides in the axial direction, and the cover body 115 and the case main body 117. Consists of. A predetermined amount of lubricating oil is sealed inside the casing 3, and the sliding portion is lubricated and cooled as each member rotates.

  Here, if one side in the axial direction and the other side are defined, in the description of the present embodiment, the right side is defined as one side in the axial direction and the left side in the rotational axis direction view of the differential case in FIGS. Is the other side in the axial direction.

  The differential case 7 is formed with a flange portion 121 to which the ring gear 119 is fixed, and an input-side transmission mechanism (for example, a propeller shaft (not shown) coupled to a transfer (not shown) or the like through which the ring gear 119 transmits a driving force. ) And the drive pinion 123 connected to each other, and the driving force is transmitted to drive the differential case 7 to rotate.

  Here, as shown in FIG. 2, the drive pinion 123 is formed to have a smaller diameter than the ring gear 119, constitutes a bevel gear set so as to be capable of variable speed driving with the large diameter ring gear 119, and is transmitted from the transmission mechanism on the input side. Change direction of driving force.

  The small-diameter drive pinion 123 constituting this gear set is formed as one member continuous with the input shaft 125 on one end side in the axial direction of the input shaft 125, and changes the direction of the driving force input from the input shaft 125 to the differential case 7. To communicate.

  The input shaft 125 is disposed in a direction perpendicular to the rotational axis of the differential case 7 and is rotatably supported by the casing 3 via two bearings 127 and 129 disposed in the axial direction. A spline-shaped connecting portion 131 is formed on the outer periphery of the other end side of the input shaft 125, and a connecting member 133 connected to the propeller shaft or the like side for transmitting driving force from the input side transmission mechanism side can be integrally rotated. It is connected.

  The connecting member 133 is fixed in position in the axial direction by screwing a nut 135 to the end of the input shaft 125, and preload is applied to the bearings 127 and 129 to position the axial position of the input shaft 125. Further, a seal member 137 that divides the inside and the outside of the casing 3 is disposed between the connecting member 133 and the casing 3 in the radial direction, and the outer periphery of the connecting member 133 slides with the lip portion of the seal member 137. A dust cover 139 is disposed.

  The driving force transmitted to the input shaft 125 via the connecting member 133 is transmitted to the differential case 7 via a gear set including the drive pinion 123 and the ring gear 119.

  The flange portion 121 of the differential case 7 is provided with a divided portion of the cover body 115 and the case main body 117, and the pinion 105, the pair of side gears 107 and 9, and the interrupting device 1 are inserted into the case main body 117 from the opening of the divided portion. After housing various members such as the intermittent member 13, the case main body 117 and the cover body 115 are fastened together by the bolt 141 that fixes the ring gear 119, and the opening of the case main body 117 is closed by the cover body 115.

  In such a differential case 7, a pinion shaft 103, a pinion 105, a pair of side gears 107 and 9, an intermittent member 13 of the intermittent device 1 and the like are accommodated.

  The pinion shaft 103 is composed of one long pinion shaft 103 and two short pinion shafts 103. The outer end of the short pinion shaft 103 is engaged with the differential case 7, and the pin 143 prevents the pinion shaft 103 from coming off and rotating. The inner end of the short pinion shaft 103 engages with a hole provided in the middle of the long pinion shaft 103 to prevent the long pinion shaft 103 from being detached and prevented from rotating, and is integrated with the differential case 7. Driven by rotation. A pinion 105 is supported on the pinion shaft 103.

  The pinion 105 is a four-pinion type in which four pinions 105 are arranged at equal intervals in the circumferential direction of the differential case 7, and are respectively supported on both ends of the long pinion shaft 103 and on the outer ends of the two short pinion shafts 103. Revolves as the differential case 7 rotates. In addition, a spherical washer 145 that receives radial movement that occurs when the pinion 105 revolves is disposed between the rear side of the pinion 105 and the differential case 7.

  The pinion 105 is rotatably supported by the pinion shaft 103 so as to transmit a driving force to the pair of side gears 107 and 9 and to be driven to rotate when a differential rotation occurs between the pair of side gears 107 and 9 engaged with each other. Yes.

  The pair of side gears 107, 9 are supported by the boss portions 147, 31 so as to be relatively rotatable with the differential case 7, and mesh with the pinion 105. In addition, thrust washers 149 and 151 that receive movement in the axial direction of the side gears 107 and 9 due to the meshing reaction force with the pinion 105 are arranged between the side gears 107 and 9 and the differential case 7 in the axial direction.

  The pair of side gears 107 and 9 has spline-shaped connecting portions 153 and 155 provided on the inner peripheral side, and a drive shaft (not shown) connected to an output side member (for example, left and right wheels not shown). It is connected to the side gears 107 and 9 so as to be able to rotate integrally, and the driving force input to the differential case 7 from the input side transmission mechanism is output to the output side member.

  The differential of the differential mechanism 109 in the differential device 101 is locked or interrupted by the intermittent portion 11 provided between the differential case 7 as the first member and the side gear 9 as the second member in the intermittent device 1. Unlocked.

  In the differential device 101 to which the intermittent device 1 is applied, when the intermittent device 1 is connected, the differential case 7 and the side gear 9 are connected, and the differential of the differential mechanism 109 is locked. In this state, the driving force input to the differential case 7 is evenly output to the pair of side gears 107 and 9.

  Such a differential apparatus 101 is a differential apparatus having a so-called differential lock function. Hereinafter, the interrupting device according to the embodiment of the present invention will be described with reference to FIGS.

  The interrupting device 1 according to the present embodiment includes a first member, a differential case 7 and a side gear 9 as a second member, which are disposed in a casing 3 via a bearing 5, and a differential case 7 and a side gear 9. In order to intermittently transmit power between the first member and the second member, an intermittent member 13 connected to the differential case 7 that is one of the first member and the second member so as to be movable in the axial direction, and the intermittent member 13 is intermittently operated. And a movable member 17 that is arranged on the inner diameter side of the electromagnet 15 so as to be movable in the axial direction and that moves the intermittent member 13 in the axial direction by excitation of the electromagnet 15.

  The electromagnet 15 is disposed adjacent to the bearing 5 that supports the differential case 7 in the axial direction.

  Further, the differential case 7, which is one of the differential case 7 and the side gear 9, is provided with an annular restricting member 19 that restricts the movement of the electromagnet 15 and the movable member 17 in one axial direction.

  The restricting member 19 is provided with a hole 21 that allows the electromagnet 15 and the movable member 17 to communicate with one side in the axial direction.

  Further, a bearing 5 for supporting the differential case 7 as a rotating member on the casing 3 is disposed adjacent to the hole 21.

  Furthermore, the regulating member 19 is made of a nonmagnetic material.

  Further, the restricting member 19 is arranged so that the outer diameter overlaps the bearing support portion 23 of the casing 3 that supports the bearing 5 in the axial direction.

  Furthermore, the inner diameter of the regulating member 19 is fixed to the differential case 7 by press fitting.

  The bearing 5 is formed of a taper roller bearing, and the restricting member 19 is provided with an avoiding portion 24 that avoids interference with the cage of the bearing 5.

  As shown in FIGS. 1 to 3, the intermittent member 13 includes a base portion 25, a convex portion 27, and meshing teeth 29. The inner peripheral surface of the base portion 25 is formed in an annular shape and is concentrically supported on the outer peripheral side of the boss portion 31 of the side gear 9, and is arranged between the rear side of the side gear 9 and the wall portion 33 of the differential case 7. In addition, the differential case 7 is connected and disposed so as to be integrally movable in the rotational direction and axially movable.

  An urging member 35 that urges the intermittent member 13 in the disconnecting direction of the intermittent portion 11 is disposed between the base portion 25 and the back surface of the side gear 9. On the wall 33 side of the differential case 7 of the base 25, a convex portion 27 is provided from the annularly formed base 25 toward one side in the axial direction.

  A plurality of convex portions 27 are provided on the side surface of the base portion 25 as a single member continuous with the base portion 25 at equal intervals in the circumferential direction. The convex portion 27 is connected to a plurality of axial holes 37 that are opened so as to communicate between the inside and the outside of the differential case 7 between the rotational directions of the wall portion 33 of the differential case 7 so as to be integrally movable in the rotational direction. Is engaged.

  Due to the engagement between the convex portion 27 and the axial hole 37, the intermittent member 13 is prevented from rotating around the differential case 7, and the intermittent member 13 and the differential case 7 can rotate integrally. Note that cam surfaces having the same inclination are formed on the circumferential facing surfaces of the convex portion 27 and the axial hole 37.

  For this reason, when the intermittent member 13 is moved in the connecting direction of the intermittent portion 11, the cam surface is engaged by the rotation of the differential case 7, so that the intermittent member 13 is further engaged with the intermittent direction of the intermittent portion 11 (on the other side in the axial direction). ) To strengthen the connection of the intermittent portion 11.

  A plurality of meshing teeth 29 are provided on the side surface of the base portion 25 opposite to the base portion 25 of the convex portion 27 in the axial direction, and on the back side of the side gear 9 facing the meshing teeth 29 in the axial direction. A plurality of meshing teeth 39 are provided, and the meshing teeth 29 and 39 constitute the intermittent portion 11.

  The intermittent portion 11 is meshed with a plurality of meshing teeth 29, 39 provided in the circumferential direction of the opposing surfaces facing the axial direction between the intermittent member 13 and the back side of the side gear 9. When the meshing teeth 29 and 39 mesh with each other, the intermittent member 13 is connected to the intermittent gear 13 and the side gear 9 so as to be integrally rotatable.

  Due to the connection between the intermittent member 13 and the side gear 9, in the differential device 101, the differential case 7 and the side gear 9 are connected so as to be integrally rotatable, the differential of the differential mechanism 109 is in a locked state, and the differential case is changed from the input side transmission mechanism to the differential case. 7 is equally output to the output side member via the pair of side gears 107 and 9.

  Such connection of the intermittent portion 11 is performed by moving the intermittent member 13 to the other side in the axial direction toward the connection direction of the intermittent portion 11, and the intermittent member 13 is operated to move in the axial direction by the actuator 41.

  The actuator 41 includes the electromagnet 15, the movable member 17, and the wall portion 33 of the differential case 7. The electromagnet 15 is disposed adjacent to the wall portion 33 of the differential case 7 in the axial direction on the outer peripheral side of the boss portion 43 of the differential case 7. The electromagnet 15 is prevented from rotating with respect to the casing 3 as a stationary member via a rotation stopper 45 that is integrally fixed by welding or the like, and includes an electromagnetic coil 47 and a core 49.

  The electromagnetic coil 47 is annularly wound with a predetermined number of turns and molded with resin. The electromagnetic coil 47 is connected to a lead wire 51 drawn to the outside, and is connected to a controller (not shown) for controlling energization via a connector 53 connected to the terminal of the lead wire 51. A core 49 is disposed around the electromagnetic coil 47.

  The core 49 is made of a magnetic material so that a magnetic field is formed by energization of the electromagnetic coil 47, and has a predetermined magnetic path cross-sectional area. Further, the core 49 annularly covers the inner and outer peripheral surfaces of the electromagnetic coil 47 and the end surface on one side in the axial direction located on the opposite side of the wall portion 33 of the differential case 7 of the electromagnetic coil 47.

  On the outer diameter side of the core 49, an extending portion 55 that extends in the axial direction from the wall portion 33 of the differential case 7 is disposed so as to cover a sliding contact surface that is set so that magnetic flux can be transmitted in the radial direction. The electromagnet 15 is supported in the radial direction so as to position the radial position of the electromagnet 15.

  The axial end surface of the extended portion 55 is set such that magnetic flux can be transmitted in the axial direction with respect to the axially opposed surface of the abutting portion 57 that protrudes radially outward from the outer diameter side of the core 49. The differential case 7 and the electromagnet 15 are supported in the axial direction so that the axial positions of the differential case 7 and the electromagnet 15 are unchanged.

  On the end surface in the axial direction of the extending portion 55, chamfered portions 59, 59 are provided by chamfering corner portions. In addition, the corner of the abutting portion 57 facing the axial end surface of the extending portion 55, more specifically, the base end-side corner extending from the core 49 of the abutting portion 57 is extended in the axial direction. A cutout portion 61 is provided that is cut away in a direction away from the installation portion 55.

  In this way, the chamfered portions 59, 59 are provided in the extended portion 55, and the notched portion 61 is provided in the contact portion 57, thereby reducing the sliding resistance between the extended portion 55 and the contact portion 57. And the friction of the apparatus can be reduced. A movable member 17 is disposed on the inner diameter side of the electromagnet 15.

  The movable member 17 is disposed on the inner diameter side of the electromagnet 15 so as to be axially movable on the outer periphery of the boss portion 43 of the differential case 7, and includes an annular plunger 63 and a ring member 65. The plunger 63 is made of a magnetic material, and is arranged on the inner diameter side of the electromagnet 15 with an air gap that is a minute gap set so as to allow magnetic flux to pass therethrough. A ring member 65 is integrally fixed to the inner periphery of the plunger 63.

  The ring member 65 is formed of a nonmagnetic material and prevents magnetic flux from leaking from the inner peripheral side of the plunger 63 to the differential case 7 side. The ring member 65 is provided with a pressing portion 67 that abuts against the axially facing surface of the intermittent member 13 with the convex portion 27 in the axial hole 37 of the wall portion 33 of the differential case 7.

  The pressing portion 67 transmits the axial movement operation force by the movable member 17 activated by the excitation of the electromagnet 15 to the intermittent member 13 and presses the intermittent member 13 in the connecting direction of the intermittent portion 11.

  Here, the end surface on the outer side in the axial direction (one side in the axial direction) of the core 49 and the end surface on the outer side in the axial direction (one side in the axial direction) of the ring member 65 are non-magnetically press-fitted to the outer periphery of the boss portion 43 of the differential case 7. Positioning to the outside in the axial direction (one side in the axial direction) is performed by a regulating member 19 formed in an annular shape from the material.

  By forming the regulating member 19 with a nonmagnetic material in this way, the magnetic path formation between the core 49 and the plunger 63 is not affected, and magnetic flux leakage from the core 49 can be prevented and efficiently performed. A magnetic path can be formed.

  Further, by pressing and fixing the regulating member 19 on the outer periphery of the boss portion 43 of the differential case 7, there is no need to provide a fixing structure such as a groove for fixing the regulating member 19 on the outer periphery of the boss portion 43 of the differential case 7, The structure of the differential case 7 can be simplified.

  Furthermore, since the regulating member 19 is annular, the electromagnet 15 can be easily held on the circumference, and the support stability with respect to the differential case 7 can be improved. In addition, by using a non-magnetic material, magnetic flux leakage to one side in the axial direction can be suppressed as much as possible.

  In addition, a plurality of holes 21 are equally formed on the circumference with respect to the regulating member 19. The regulating member 19 can maintain its own strength, and can improve the operation stability without applying a partial load to the operation of the annular plunger 63.

  On the other hand, in the intermittent device 1, the axial position between the differential case 7 and the electromagnet 15 is made unchanged by the axial contact between the extending portion 55 of the differential case 7 and the contact portion 57 of the core 49 of the electromagnet 15. The differential case 7 and the electromagnet 15 are supported in the axial direction.

  For this reason, in the conventional intermittent device, the sliding resistance between the extending portion 55 and the contact portion 57 due to the excitation of the electromagnet 15 is large, and the friction of the device is increased. Therefore, a small-diameter portion 69 set smaller than the outer diameter of the contact portion 57 is provided on the back side in the axial direction of the contact portion 57 with the extending portion 55.

  The small-diameter portion 69 is provided in the entire region from the back side of the abutting portion 57 opposite to the facing surface between the abutting portion 57 and the extending portion 55 of the core 49 toward the outside in the axial direction. The small diameter portion 69 is set so that the outer diameter is smaller than the outer diameter of the contact portion 57. Thus, by providing the small diameter part 69 in the whole area in the axial direction, the back side of the contact part 57 of the core 49 can be reduced in the radial direction, and the apparatus can be reduced in size.

  By providing such a small diameter portion 69, the magnetic flux transmission cross-sectional area on the back side of the contact portion 57 can be reduced. As shown in FIG. Permeation of magnetic flux between the axial direction with 57 can be suppressed. For this reason, the sliding resistance between the axial direction of the extension part 55 and the contact part 57 by excitation of the electromagnet 15 can be reduced, and the friction of an apparatus can be reduced.

  The electromagnet 15a shown in FIG. 4 (a) is a conventional electromagnet, and the electromagnet 15b shown in FIG. 4 (b) has a thick radial thickness of the core 49 that overlaps the extending portion 55 in the radial direction. The electromagnet 15 shown in FIG. 4C is the electromagnet of the present invention.

  Here, the change of the drag torque with respect to the voltage of the electromagnet 15a, the electromagnet 15b, and the electromagnet 15 shown in FIG. 4 is shown in FIG. As is apparent from FIG. 5, the electromagnet 15 is excited by providing a small diameter portion 69 smaller than the outer diameter of the contact portion 57 on the back side in the axial direction of the contact portion 57 with the extended portion 55. It can be seen that the sliding resistance between the extending portion 55 and the contact portion 57 can be reduced.

  The small-diameter portion 69 provided in the core 49 may not be provided in the entire axial direction on the back side of the contact portion 57 of the core 49. For example, as illustrated in FIG. It may be a small diameter portion 69 a formed by a groove portion set smaller than the outer diameter of the contact portion 57 on the back side in the axial direction with respect to 55.

  Even with such a small-diameter portion 69a, the magnetic flux transmission cross-sectional area on the back side of the contact portion 57 can be reduced, and the extension portion 55 and the contact portion 57 are excited by the electromagnet 15 between the axial directions. Transmission of magnetic flux can be suppressed.

  Here, as shown in FIGS. 7 and 8, the small diameter portion 69 may be provided with a rotation preventing portion 45 that engages with the casing 3 as a stationary member and prevents the electromagnet 15 from rotating. Specifically, a bearing cap 71 that holds a bearing 5 (see FIG. 1) that rotatably supports the differential case 7 is assembled to the casing 3.

  The bearing cap 71 is formed in a semicircular shape and is fixed to the casing 3 via a plurality of bolts 73. When the bearing cap 71 is assembled to the casing 3, the inner peripheral side is formed in an annular shape by the bearing cap 71 and the casing 3, and holds the bearing 5 that rotatably supports the differential case 7 in the radial direction.

  Note that a support member 79 (see FIG. 2) is assembled to the bearing cap 71 via a connecting member 77 fixed to the inner periphery of one axial end side with a bolt 75, and the support member 79 is a shaft of the bearing 5. The bearing 5 is held in the axial direction in contact with the direction end surface.

  In such a bearing cap 71, two engaging portions 81, which are convex portions respectively extending in the axial direction of the differential case 7, are provided symmetrically on the outer diameter side. The engaging portion 81 is engaged with the rotation preventing portion 45 to prevent the electromagnet 15 from rotating.

  The anti-rotation portion 45 is provided integrally with the electromagnet 15 via a welding portion 83 at two locations spaced in the circumferential direction from the small diameter portion 69 of the core 49 of the electromagnet 15. Further, each of the rotation preventing portions 45 includes a convex portion that protrudes in a direction orthogonal to the rotation axis of the differential case 7.

  The anti-rotation portion 45 is engaged in the rotation direction of the electromagnet 15 with the engagement portion 81 provided in the bearing cap 71 at two locations in the circumferential direction of the electromagnet 15, and rotates in both the forward and reverse directions of the rotation direction of the electromagnet 15. Stop. The anti-rotation portion 45 may be integrally formed with the core 49 in the small diameter portion 69 of the core 49 of the electromagnet 15.

  In this way, the anti-rotation portion 45 is provided in the small diameter portion 69 of the electromagnet 15, the engagement portion 81 is provided in the bearing cap 71 on the casing 3 side, and the anti-rotation portion 45 and the engagement portion 81 are connected to the electromagnet 15 and the casing 3. By engaging between the axial directions, it is not necessary to provide a detent structure for the electromagnet 15 in the dotted line frame portion located on the outer diameter side in the direction of the arrow 85 from the bolt 73 that fixes the bearing cap 71.

  For this reason, in order to prevent the electromagnet 15 from rotating, the rotation preventing portion 45 and the engaging portion 81 do not protrude from the outer diameter side of the casing 3 or the bearing cap 71, and the casing 3 is increased in size toward the outer diameter side. Can be suppressed.

  The engaging portion 81 that engages with the rotation preventing portion 45 is provided on the bearing cap 71, but is not limited thereto, and a convex portion that extends from the casing 3 toward the electromagnet 15 in the axial direction is provided. The engaging portion 81 may be used.

  On the other hand, as shown in FIG. 1, the wall portion 33 of the differential case 7 disposed adjacent to the electromagnet 15 in the axial direction is thicker in the axial direction in the portion where the movable member 17 side is located than in the portion located on the electromagnet 15 side. It is set thick. By setting the axial thickness of the wall portion 33 in this way, the rigidity on the inner diameter side of the wall portion 33 can be improved.

  For this reason, while ensuring the rigidity of the wall portion 33, the stress portion where the stress of the driving force input to the differential case 7 acts on the wall portion 33 and the bearing 5 that rotatably supports the differential case 7 are close to each other in the axial direction. The apparatus can be reduced in size.

  In addition, the meshing reaction force of the side gear 9 is set to be input to the thick wall portion 33 in the axial direction, and the meshing reaction force of the side gear 9 can be stably received.

  Further, a magnetic path forming portion 87 that forms a magnetic path together with the core 49 and the plunger 63 is provided at a boundary portion between the thick portion and the thin portion of the wall portion 33 in the axial direction. By providing the magnetic path forming portion 87 in this way, the electromagnet 15 can be disposed closer to the wall portion 33 in the axial direction in the portion where the wall portion 33 is thin in the axial direction, and the apparatus is downsized. can do.

  Here, the regulating member 19 side of the core 49 of the electromagnet 15 is set such that the axial thickness is thicker on the inner diameter side than on the outer diameter side. The core 49 is provided with a convex portion 89 on the outer side in the axial direction on the inner diameter side so that the axial thickness is set thicker on the inner diameter side than on the outer diameter side.

  The regulating member 19 is brought into contact with the end surface of the convex portion 89 where the axial thickness is the largest, and the electromagnet 15 is positioned in the axial direction. Thus, the axial positioning of the electromagnet 15 can be stably performed by bringing the thickest portion in the axial direction into contact with the regulating member 19.

  On the other hand, an anti-rotation portion 45 that prevents the electromagnet 15 from rotating relative to the casing 3 is provided on the outer diameter side where the axial thickness of the core 49 is set to be thinner than the inner diameter side. Thus, by providing the anti-rotation part 45 in the portion where the axial thickness becomes thin, it is not necessary to provide a special arrangement space for providing the anti-rotation part 45, and the enlargement of the apparatus can be suppressed.

  The shape of the electromagnet 15 on the side of the regulating member 19 of the core 49 is, for example, a step shape in which the axial thickness on the inner diameter side is thicker than the outer diameter side, as shown in FIG. As shown in (b), the axial thickness on the inner diameter side is larger than the axial thickness on the outer diameter side, such as an inclined shape so that the axial thickness gradually increases from the outer diameter side to the inner diameter side. Any shape may be used as long as it is thick.

  Thus, by setting the axial thickness of the core 49 of the electromagnet 15 so that the inner diameter side is thicker than the outer diameter side, the magnetic path cross-sectional area on the movable member 17 side arranged on the inner diameter side of the electromagnet 15 is increased. The thrust of the movable member 17 in the axial direction can be improved.

  Here, the shaft of the movable member 17 (plunger 63) of the electromagnet 15 in which the axial thickness of the core 49 is set to be thicker on the inner diameter side than the outer diameter side and the electromagnet 15A in which the axial thickness of the core 49 is set constant. FIG. 10 shows a change in thrust of the movable member 17 with respect to the directional stroke. As is apparent from FIG. 10, it is understood that the thrust of the movable member 17 can be improved by setting the axial thickness on the inner diameter side of the core 49 to be thick.

  In the intermittent device 1 configured as described above, the plunger 63 is effectively used by using the shortest magnetic flux loop formed by the magnetic flux that passes through the core 49, the plunger 63, and the wall portion 33 of the differential case 7 by the excitation of the electromagnet 15. Is moved to the intermittent member 13 side, and the ring member 65 presses the intermittent member 13 via the pressing portion 67.

  By the pressing operation of the intermittent member 13 by the movable member 17, the intermittent member 13 is moved in the connecting direction of the intermittent portion 11 against the urging force of the urging member 35, and the intermittent portion 11 is connected.

  With the connection of the intermittent portion 11, in the differential device 101, the side gear 9 and the intermittent member 13 are connected so as to be integrally rotatable, the side gear 9 and the differential case 7 are connected, and the differential mechanism 109 is locked.

  On the other hand, in the disconnection of the intermittent portion 11, by stopping energization to the electromagnet 15, the intermittent member 13 is moved in the disconnection direction of the intermittent portion 11 by the biasing force of the biasing member 35, and the connection of the intermittent portion 11 is disconnected. Canceled.

  By releasing the connection of the intermittent portion 11, in the differential device 101, the side gear 9 and the intermittent member 13 can be rotated relative to each other, and the side gear 9 and the differential case 7 can be rotated relative to each other to release the locked state of the differential mechanism 109. The

  Here, in the intermittent device 1, the state of the intermittent portion 11 can be detected by detecting the operating position of the intermittent member 13 that is moved by the actuator 41. Specifically, since the intermittent member 13 is axially moved between the connection position of the intermittent portion 11 and the connection release position of the intermittent portion 11 by the actuator 41, the intermittent member 13 is intermittently detected by detecting the operating position of the intermittent member 13. The state of the unit 11 can be detected, and the state of the differential device 101 can be detected.

  Therefore, the detection member 91 is fixed to the intermittent member 13 so as to move integrally with the intermittent member 13. The detection member 91 is formed in a disc shape, and a plurality of convex plate portions are continuously formed on the inner diameter side toward the intermittent member 13 side, and the convex plate portions are opened so as to communicate with the inside and outside of the differential case 7. It is fixed to the axial end surface of the convex portion 27 of the intermittent member 13 with a bolt through the provided radial hole 93.

  For this reason, the detection member 91 is axially moved integrally with the intermittent member 13. A position switch 95 is disposed on the outer diameter side of the detection member 91.

  The position switch 95 is fixed to the casing 3 and connected to the controller. Further, the position switch 95 is provided with a contact portion 97 that is brought into contact with the outer diameter side of the detection member 91 and is turned on and off by the axial movement of the detection member 91.

  The position switch 95 detects the operating position of the intermittent member 13 according to the state of the contact portion 97, and detects the state of the intermittent portion 11 in the intermittent device 1. By detecting the state of the intermittent portion 11 in this way, the locked state and unlocked state of the differential mechanism 109 in the differential device 101 can be detected.

  In the intermittent device 1 configured as described above, the movable member 17 is disposed on the outer periphery of the boss portion 43 of the differential case 7 so as to be movable in the axial direction with an air gap that is a minute gap between the electromagnet 15 and the electromagnet 15. Therefore, it is necessary to supply the lubricating oil to the movable member 17 and improve the response reactivity due to the excitation of the electromagnet 15 of the movable member 17. Therefore, the restriction member 19 disposed adjacent to the movable member 17 in the axial direction is provided with a hole 21 for supplying lubricating oil to the movable member 17 side.

  The regulating member 19 is disposed between the electromagnet 15 and the movable member 17 and the bearing 5 that rotatably supports the differential case 7, and has a plurality of holes that communicate the electromagnet 15 and the movable member 17 side with the bearing 5 side. The parts 21 are provided at equal intervals in the circumferential direction.

  Thus, by providing the hole 21 in the regulating member 19, the lubricating oil can be caused to flow into the movable member 17 side by the rotation of the bearing 5, the lubricity of the movable member 17 is improved, and the movable member 17 is movable by excitation of the electromagnet 15. The response reactivity of the member 17 can be improved.

  The bearing 5 is a bearing that rotatably supports the differential case 7 as one of the first member and the second member with respect to the casing 3. Lubricating oil can be supplied to the hole 21 provided in the regulating member 19. Such a bearing is not limited to a bearing that supports the first member or the second member, but may be a bearing provided to support another rotating member. Any bearing may be arranged in the casing 3 and arranged in an arrangement shape capable of supplying the lubricating oil to the hole 21 as the rotating member rotates.

  Further, as shown in FIG. 2, the outer diameter of the regulating member 19 is disposed so as to overlap the inner diameter of the bearing support portion 23 that supports the bearing 5 of the casing 3 in the axial direction.

  By arranging the regulating member 19 in this way, the lubricating oil due to the rotation of the bearing 5 can be efficiently guided to the hole 21 without flowing out from the outer diameter side of the regulating member 19, and further movable. The lubricity of the member 17 can be improved.

  Further, the bearing 5 is a tapered roller bearing having a cage, and the restricting member 19 is provided with a concave avoiding portion 24 that avoids interference with the cage of the bearing 5.

  By providing the avoiding portion 24 in the restricting member 19 in this manner, the restricting member 19 and the bearing 5 can be disposed close to each other in the axial direction, and the apparatus can be downsized.

  In such an interrupting device 1, the electromagnet 15 and the movable member 17 are arranged on the annular regulating member 19 that regulates the movement of the electromagnet 15 and the movable member 17 between the electromagnet 15 and the bearing 5 in the axial direction. Since the hole portion 21 that communicates the member 17 side with the one side in the axial direction is provided, the lubricating oil can flow into the movable member 17 side through the hole portion 21, and the lubricity of the movable member 17 is improved. be able to. If the hole 21 is arranged close to or adjacent to the end side of the bearing as shown in FIG. 2, the lubricating oil receives a discharging function by the bearing due to the rotation of the bearing 5 and is forced toward the hole 21. Can be allowed to flow into.

  Therefore, in such an interrupting device 1, while the axial movement of the movable member 17 is regulated by the regulating member 19, the lubricity with respect to the movable member 17 is improved by the hole 21 of the regulating member 19, and the movable by the excitation of the electromagnet 15 The response reactivity of the member 17 can be improved.

  Further, since the regulating member 19 is made of a non-magnetic material, it does not affect the magnetic path formation between the electromagnet 15 and the movable member 17 and can prevent magnetic flux leakage from the electromagnet 15 and the movable member 17. A magnetic path can be formed efficiently.

  Further, since the regulating member 19 is arranged so that the outer diameter of the regulating member 19 overlaps the bearing support portion 23 of the casing 3 that supports the bearing 5 in the axial direction, the lubricating oil generated by the rotation of the bearing 5 causes the outer diameter of the regulating member 19 to be reduced. Lubricating oil can be efficiently guided to the hole 21 without flowing out from the side, and the lubricity of the movable member 17 can be improved.

  Further, since the inner diameter of the regulating member 19 is fixed to the differential case 7 by press-fitting, it is not necessary to provide a fixing structure for fixing the regulating member 19 to the differential case 7, and the structure of the differential case 7 can be simplified. .

  Furthermore, since the restricting member 19 is provided with an avoidance portion 24 that avoids interference with the cage of the bearing 5, the restricting member 19 and the bearing 5 can be disposed close to each other in the axial direction, and the device Can be miniaturized.

  Further, in the differential device 101 to which the intermittent device 1 is applied, the lubricity with respect to the movable member 17 can be improved, and the response reactivity of the movable member 17 by the excitation of the electromagnet 15 can be improved. It is possible to improve the intermittent characteristics between the 109 locked state and the unlocked state.

  Note that the interrupting device according to the embodiment of the present invention is applied as a differential lock mechanism of a differential device, but is not limited thereto, for example, power transmission between an outer differential case and an inner differential case in a free running differential. A first intermittent mechanism that interrupts power transmission between an input member and an output member in a transfer, and a second intermittent mechanism that interrupts power transmission on one axle, such as an axle disconnect. Any structure can be applied as long as the power transmission between the second members is intermittent.

  Further, the intermittent mechanism of the present invention can be applied to a so-called brake device in which one of the first member and the second member is a stationary member and the other is a rotating member.

  Further, the intermittent portion is a meshing clutch of opposing teeth facing in the axial direction, but is not limited to this, and has a sleeve that can move in the axial direction, and the opposing teeth facing between the sleeves in the radial direction. As long as the power transmission between the first and second members can be interrupted, such as a meshing clutch or a friction clutch including a multi-plate clutch or a single-plate clutch, the form of the intermittent portion may be any. .

  In addition, the movable member is disposed on the inner diameter side of the electromagnet so as to be movable in the axial direction. If an equivalent function can be obtained, the present invention can be applied.

  Furthermore, the restricting member only needs to be fixed to one of the first and second members, and the fixing means is not limited to press-fitting, and other fixing means such as welding, screwing, adhesion, and welding are appropriately employed. Is possible.

  Further, the hole portion does not necessarily have the same shape and the same shape with respect to the annular side surface, and may be an opening in which a part of the periphery is notched. In addition, a shape may be used in which the lubricating oil has an axial directionality by providing an inclined surface in the hole itself.

DESCRIPTION OF SYMBOLS 1 ... Intermittent device 3 ... Casing 5 ... Bearing 7 ... Differential case (1st member)
9: Side gear (second member)
DESCRIPTION OF SYMBOLS 11 ... Intermittent part 13 ... Intermittent member 15 ... Electromagnet 17 ... Movable member 19 ... Restriction member 21 ... Hole 23 ... Bearing support part 24 ... Avoidance part 101 ... Differential apparatus 105 ... Pinion (differential gear)
107 ... side gear (output gear)

Claims (7)

A first member and a second member housed in a casing encapsulated with lubricating oil and disposed so as to be relatively rotatable, and the first member for interrupting power transmission between the first member and the second member; An intermittent member connected to one of the second members so as to be axially movable integrally with the rotation direction, an annular electromagnet for intermittently operating the intermittent member, and axially movable to the inner diameter side or outer diameter side of the electromagnet An intermittent device provided with a movable member arranged to be moved in the axial direction by the excitation of the electromagnet,
One of the first member and the second member is provided with an annular restricting member that restricts movement of the electromagnet and the movable member to one side in the axial direction.
The intermittent member is provided with a hole for communicating the electromagnet and the movable member on one side in the axial direction. The intermittent device according to claim 1,
The interrupting device is characterized in that a bearing for supporting the rotating member is arranged on one side in the axial direction of the regulating member, and the lubricating oil is circulated through the hole by the operation of the bearing. The intermittent device according to claim 1 or 2,
The interrupting device, wherein the restricting member is made of a nonmagnetic material. The intermittent device according to claim 2,
An outer diameter of the bearing is supported by the casing, and the regulating member is arranged so that the outer diameter overlaps with a bearing support portion of the casing that supports the bearing in the axial direction. . The intermittent device according to any one of claims 1 to 4,
The intermittent member is characterized in that an inner diameter of the regulating member is fixed to either the first member or the second member by press fitting. The intermittent device according to claim 2 or 4,
The bearing comprises a tapered roller bearing,
The interrupting device according to claim 1, wherein the restricting member is provided with an avoiding portion for avoiding interference with the cage of the bearing. A differential device comprising the interrupting device according to any one of claims 1 to 6,
A differential case to which driving force is input, a differential gear supported by the differential case and capable of rotating, and revolved by the rotation of the differential case, and a pair of output gears meshed with the differential gear and relatively rotatable. And
The differential device, wherein the first member is the differential case, and the second member is one of the pair of output gears.

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