JP7416586B2 - differential device - Google Patents

Description

The present invention relates to a differential device applied to a vehicle.

Conventionally, a differential device includes an axle housing as a carrier, a pinion that is rotatably supported by the axle housing and into which driving force is input, and an input gear that is rotatably supported by the axle housing and is driven by meshing with the pinion. , a differential case as a differential case to which an input gear is fixed, a differential gear that is supported by this differential case and can rotate on its own axis and also revolves with the rotation of the differential case, and a differential gear that meshes with this differential gear and is A pair of output gears that are rotatable and each output a driving force, a solenoid and a sensor as electrical components housed in the axle housing, and a pair of output gears that are electrically connected to the solenoid and the sensor and arranged outside the axle housing. A device equipped with an electrical connection portion is known (see, for example, Patent Document 1).

This differential device is electrically connected to a controller mounted on a vehicle outside the axle housing via an electrical connection section located outside the axle housing.

Special Publication No. 2010-516983

By the way, in a differential device such as the one disclosed in Patent Document 1, the electrical connection portion, which is electrically connected to an electrical component and is arranged outside the carrier, is arranged in an exposed state on the outer circumferential surface of the carrier.

For this reason, there is a possibility that the electrical connection portion may be damaged by flying stones or the like caused by the running of the vehicle, and there is a fear that the reliability of the electrical connection may be reduced.

In addition, in order to protect the electrical connections, it is possible to attach a protective member made of a separate material to the carrier, but there is a concern that the number of parts such as the protective member and the fixing member for fixing the protective member will increase. there were.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a differential device that can maintain electrical connection reliability of electrical connection portions without increasing the number of parts.

The present invention provides a carrier, a pinion that is rotatably supported by the carrier and into which driving force is input, an input gear that is rotatably supported by the carrier and is driven by meshing with the pinion, and the input gear is fixed. a differential case supported by the differential case, which is rotatable on its own axis and which revolves around the rotation of the differential case; and a pair of differential gears that mesh with the differential gear and are rotatable relative to each other, each outputting a driving force. A differential device comprising an output gear, an electrical component housed in the carrier, and an electrical connection part electrically connected to the electrical component and disposed outside the carrier, wherein the outer surface of the carrier includes: , a protruding wall facing the lower side of the electrical connection part is provided , the electrical connection part has a first electrical connection part and a second electrical connection part, and the second electrical connection part is arranged in a vertical direction. The protruding wall corresponds to the first electrical connection, and is arranged inward of the carrier from the first electrical connection in a horizontal direction, and the protruding wall corresponds to the first electrical connection. A first protruding wall provided to correspond to the second electrical connection portion, and a second protruding wall provided corresponding to the second electrical connection portion .

In this differential device, a protruding wall facing the lower side of the electrical connection part is provided on the outer surface of the carrier, so that the protruding wall prevents stones thrown by the vehicle from colliding with the electrical connection part. can.

Further, since the protruding wall is integrally provided with the carrier, there is no need to attach a protective member separate from the carrier, and the number of parts can be reduced.

Therefore, in such a differential device, the electrical connection reliability of the electrical connection portion can be maintained without increasing the number of parts.

According to the present invention, it is possible to provide a differential device that can maintain the electrical connection reliability of the electrical connection portion without increasing the number of parts.

FIG. 1 is a perspective view of a differential device according to an embodiment of the present invention, viewed from above. FIG. 1 is a perspective view of a differential device according to an embodiment of the present invention, viewed from below. FIG. 1 is a side view of a differential device according to an embodiment of the present invention. FIG. 1 is a front view of a differential device according to an embodiment of the present invention. FIG. 1 is a sectional view of a differential device according to an embodiment of the present invention.

A differential device according to an embodiment of the present invention will be described using FIGS. 1 to 5.

The differential device 1 according to the present embodiment includes a carrier 3, a pinion 5 that is rotatably supported by the carrier 3 and to which driving force is input, and a pinion 5 that is rotatably supported by the carrier 3 and meshes with the pinion 5 to be driven. the input gear 7, the differential case 9 to which the input gear 7 is fixed, the differential gear 11 that is supported by the differential case 9 and can rotate on its axis and revolves with the rotation of the differential case 9; A pair of output gears 13 and 15 that are relatively rotatable and each output a driving force, an electromagnet 17 and a position switch 106 as electrical components housed in the carrier 3, and an electrical connection to the electromagnet 17 and the position switch 106. An electrical connection part 19 connected to the carrier 3 and arranged outside the carrier 3 is provided.

A protruding wall 21 is provided on the outer surface of the carrier 3 and faces the lower side of the electrical connection section 19 .

Further, the carrier 3 is made up of a plurality of divided members 23, and the plurality of divided members 23 are connected to each other via mounting portions 25 that protrude in a circumferential manner. It is formed by connecting with.

Furthermore, a cylindrical portion 27 is formed in the carrier 3 along the axial direction of the pinion 5, and the electrical connection portion 19 is provided with a connecting end portion 29 along the extending direction of the cylindrical portion 27.

Further, the protruding wall 21 is formed so that the connecting end portion 29 side extends along the direction in which the cylindrical portion 27 extends.

Further, the protruding wall 21 has a wall length that is opposite to the height from the base end side of the electrical connection section 19 to the connection end section 29 side.

Further, the base end of the electrical connection portion 19 (first electrical connection portion 19a) is fixed to the cylindrical portion 27 by a fixing portion 31.

Further, the base end of the electrical connection portion 19 (second electrical connection portion 19b) is fixed to the attachment portion 25 by a fixing portion 33.

Further, the electrical connection section 19 has a first electrical connection section 19a and a second electrical connection section 19b, and the second electrical connection section 19b is arranged above the first electrical connection section 19a in the vertical direction. The first electrical connection portion 19a is disposed inward of the carrier 3 in the horizontal direction.

The protruding wall 21 includes a first protruding wall 21a provided corresponding to the first electrical connection part 19a, and a second protruding wall 21b provided corresponding to the second electrical connection part 19b.

Further, the protruding wall 21 (second protruding wall 21b) is formed above the cylindrical portion 27.

As shown in FIGS. 1 to 5, the differential device 1 includes a carrier 3, a pinion 5, a differential mechanism 35, and an interrupting mechanism 37.

The carrier 3 includes a divided member 23 whose inside has a housing space where the pinion 5 is mainly housed, and a divided member (not shown) whose inside has a housing space where the differential mechanism 35 and the disconnection mechanism 37 are mainly housed. It consists of.

In this carrier 3, the pinion 5 is accommodated in the split member 23, the pinion 5 and the input gear 7 are engaged, and the bearing caps 39, 41 that support the bearings 53, 55 are assembled to the split member 23. A circumferentially formed mounting portion 25 is fitted to the dividing member 23 and fixed by a fixing means such as a bolt.

Such a carrier 3 accommodates a pinion 5, a differential mechanism 35, an interrupting mechanism 37, and the like.

The pinion 5 is arranged with its axis perpendicular to the rotational axis of the differential case 9, and is rotatably supported by the carrier 3 through a bearing (not shown) inside the cylindrical portion 27 of the carrier 3.

A connecting member 43 is connected to one end in the axial direction of the pinion 5 so as to be able to rotate integrally with the pinion 5, and this connecting member 43 is connected to an input side member such as a propeller shaft that transmits driving force from a driving source side. is rotatably connected to the .

A small-diameter gear portion is provided on the other end of the pinion 5 in the axial direction, and this small-diameter gear portion meshes with a large-diameter input gear 7 fixed to the differential case 9 to form a direction conversion gear set. For example, the drive force transmitted from a drive source such as an engine or an electric motor is direction-changed and transmitted to the differential mechanism 35 .

The differential device 1 in which driving force is transmitted from the pinion 5 to the differential mechanism 35 in this manner serves as a final reduction device.

The differential mechanism 35 includes a differential case 9, pinion shafts 45 and 47, a differential gear 11, and a pair of output gears 13 and 15.

The differential case 9 is rotatably supported by the carrier 3 via bearings 53 and 55 at the outer peripheries of boss portions 49 and 51 provided on both sides in the axial direction, respectively.

The bearings 53 and 55 are held in bearing caps 39 and 41 assembled to the divided member 23 of the carrier 3.

The differential case 9 is provided with a flange portion 57 to which the input gear 7 is fixed, the input gear 7 meshes with the pinion 5, and the driving force from the drive source is transmitted to the differential case 9.

Such a differential case 9 houses pinion shafts 45 and 47, a differential gear 11, and a pair of output gears 13 and 15, and the driving force input to the differential case 9 is transmitted.

The pinion shafts 45, 47 consist of two short pinion shafts 45 and one long pinion shaft 47.

The two short pinion shafts 45 have their outer ends engaged with the differential case 9, are prevented from coming off and rotated by pins 59, and are driven to rotate integrally with the differential case 9.

One long pinion shaft 47 is prevented from coming off and rotating by engaging the inner ends of two short pinion shafts 45 in a hole provided in the middle, and is driven to rotate integrally with the differential case 9. .

A plurality of differential gears 11 are supported on the outer end sides of each of the pinion shafts 45 and 47.

The plurality of differential gears 11 are arranged in four pieces at equal intervals in the circumferential direction of the differential case 9, and are supported on the outer ends of the two short pinion shafts 45 and on both ends of the long pinion shaft 47, respectively. It revolves by rotation.

A spherical washer is arranged between the rear side of the differential gear 11 and the differential case 9 in the radial direction to receive movement in the radial direction that occurs when the differential gear 11 revolves.

The differential gear 11 transmits driving force to the pair of output gears 13, 15, and also has a pinion shaft 45, which is driven to rotate when a differential rotation occurs between the pair of meshed output gears 13, 15. It is rotatably supported by 47.

The pair of output gears 13 and 15 are relatively rotatably supported by the differential case 9 at boss portions formed on each output gear, and mesh with the differential gear 11.

Thrust washers are arranged between the pair of output gears 13, 15 and the differential case 9 in the axial direction to receive movement of the pair of output gears 13, 15 in the axial direction due to the reaction force of meshing with the differential gear 11. ing.

Such a pair of output gears 13, 15 is provided with spline-shaped connecting portions 61, 63 on the inner circumferential side, respectively, and has, for example, a drive shaft that is integrally rotatably connected to output side members such as left and right wheels. They are connected to the output gears 13 and 15 so as to be able to rotate integrally with each other, and output the driving force input to the differential case 9 to the output side member.

The differential between the pair of output gears 13 and 15 in the differential mechanism 35 is locked by the connection of the disconnection mechanism 37, and the driving force transmitted to the pair of output gears 13 and 15 is transferred to the output side member. Output is uniform.

The differential device 1 having the disconnection mechanism 37 that connects and disconnects the differential motion of the differential mechanism 35 in this manner is a differential device having a so-called differential lock function.

The disconnection mechanism 37 includes a disconnection member 65, a disconnection portion 67, a movable member 69, and an electromagnet 17.

The interrupting member 65 is formed into an annular shape, and a base portion 71 formed of a single member continuous in the circumferential direction is disposed so as to be movable in the axial direction between the wall portion 73 of the differential case 9 and the rear side of the output gear 15. ing.

An engaging portion 75 is provided on the wall portion 73 side of the differential case 9 of the disconnecting member 65, and is provided to engage integrally with the differential case 9, and a disconnecting portion 67 is provided on the rear side of the output gear 15 of the disconnecting member 65. It is provided.

The engaging portion 75 includes a plurality of convex portions 77 provided on the base 71 of the interrupting member 65 at equal intervals in the circumferential direction, and a plurality of protrusions 77 provided on the wall portion 73 of the differential case 9 at equal intervals in the circumferential direction and penetrating in the axial direction. It consists of a hole 79.

When the protrusion 77 and the hole 79 engage in the rotational direction, the intermittent member 65 is prevented from rotating by the differential case 9, and the intermittent member 65 and the differential case 9 can rotate together.

This engaging portion 75 is provided with a cam that moves the interrupting member 65 in the connecting direction of the interrupting portion 67 . Specifically, cam surfaces having the same inclination are formed on opposing surfaces of the convex portion 77 and the hole portion 79 on both sides in the circumferential direction.

Therefore, when the interrupting member 65 is moved in the connecting direction of the interrupting portion 67 and a rotational engagement action occurs on the interrupting portion 67, the respective cam surfaces are engaged by the rotation of the differential case 9, so that the interrupting member 65 is further moved in the direction of engagement of the interrupting portion 67 to strengthen the connection of the interrupting portion 67.

The intermittent portion 67 is provided between the intermittent member 65 and the back side of the output gear 15 in the axial direction on the side surface axially opposite to the engagement portion 75 of the base portion 71 of the intermittent member 65. A plurality of meshing teeth are formed in the circumferential direction and mesh with each other.

The intermittent portion 67 connects the intermittent member 65 and the output gear 15 so that they can rotate together, that is, the differential case 9 and the output gear 15 are connected so that the differential mechanism 35 can rotate as a unit due to the engagement of their meshing teeth. The differential becomes locked.

On the other hand, a biasing member 81 is provided between the interrupting member 65 and the rear side of the output gear 15 in the radial direction inside the interrupting portion 67, and urges the interrupting member 65 in the disconnection direction of the interrupting portion 67. are doing.

The biasing member 81 moves the interrupting member 65 in the direction of disconnecting the interrupting portion 67, disconnecting the interrupting portion 67, and brings the differential of the differential mechanism 35 into an unlocked state.

The intermittent state of the intermittent portion 67 is controlled by an actuator consisting of a movable member 69 and an electromagnet 17.

The movable member 69 is disposed on the inner diameter side of the electromagnet 17 on the outer periphery of the boss portion 51 of the differential case 9 so as to be movable in the axial direction, and includes an annular plunger 83 and a ring member 85.

The plunger 83 is made of a magnetic material and is disposed on the inner diameter side of the electromagnet 17 with an air gap that is a minute gap configured to allow magnetic flux to pass therethrough.

The ring member 85 is made of a non-magnetic material and is integrally fixed to the inner circumferential side of the plunger 83 to prevent magnetic flux from leaking from the inner circumferential side of the plunger 83 to the differential case 9 side.

This ring member 85 is disposed movably in the axial direction on the outer periphery of the boss portion 51 of the differential case 9, and is axially movable to the outside by a regulating member 87 made of a non-magnetic material that is press-fitted and fixed to the outer periphery of the boss portion 51 of the differential case 9. Movement is restricted.

Such a ring member 85 is provided with a pressing portion 89 that can come into contact with the convex portion 77 of the interrupting member 65 on the end surface in the axial direction on the interrupting member 65 side.

This pressing part 89 transmits the axial movement operation force of the movable member 69 actuated by the electromagnet 17 to the interrupting member 65 via the pressing part 89, and presses the interrupting member 65 in the connection direction of the interrupting part 67. .

The electromagnet 17 is disposed adjacent to the wall portion 73 of the differential case 9 in the axial direction on the outer peripheral side of the boss portion 51 of the differential case 9 .

A plurality of (here, two) detent members 91 are integrally fixed to the electromagnet 17 at equal intervals in the circumferential direction, and the detent members 91 are engaged with a fixing portion to which the bearing cap 41 of the carrier 3 is fixed. As a result, rotation is prevented.

Such an electromagnet 17 includes an electromagnetic coil 93 and a core 95.

The electromagnetic coil 93 is annularly wound a predetermined number of times and molded with resin.

A lead wire 97 drawn out from the core 95 is electrically connected to the electromagnetic coil 93, and an end of the lead wire 97 drawn out from the core 95 is connected to a second electrical connection portion 19b as the electrical connection portion 19. electrically connected to.

The second electrical connection part 19b is arranged outside the carrier 3, and its base end is fixed to a fixing part 33 provided in the mounting part 25 via a bolt, and extends in the direction in which the cylinder part 27 extends from the fixing part 33 side. A connecting end 29 extends along the line.

A mating electrical connection part (not shown) electrically connected to a controller (not shown) is fitted into the connection end 29 of the second electrical connection part 19b, and the electromagnet 17 connects the second electrical connection part 19b. It is electrically connected to the controller via the electromagnet 17, and energization of the electromagnet 17 is controlled.

The core 95 is made of a magnetic material so that a magnetic field is generated when the electromagnetic coil 93 is energized, and has a predetermined magnetic path cross-sectional area.

This core 95 annularly covers the inner and outer peripheral surfaces of the electromagnetic coil 93 and the end surface of the electromagnetic coil 93 on one axial side located on the opposite side from the wall portion 73 of the differential case 9 .

An extension part 99 extending in the axial direction from the wall part 73 of the differential case 9 is disposed on the outer diameter side of the core 95 so as to cover it with a sliding contact surface set to allow magnetic flux to pass therethrough. At the same time, the electromagnet 17 is positioned inward in the axial direction by the axial end face of the extending portion 99.

On the other hand, the axially outer end surface of the core 95 is fixed in the axial direction of the electromagnet 17 along with the movable member 69 by a regulating member 87 that is press-fitted and fixed to the boss portion 51 of the differential case 9 that regulates the axially outward movement of the movable member 69. Positioning is done to the outside.

Note that the regulating member 87 comes into contact with the end surface of the inner race of the bearing 55 that is press-fitted and fixed to the boss portion 51 of the differential case 9 in order to ultimately rotationally support the differential case 9, and its movement outward in the axial direction is restricted. There is.

In the differential device 1 configured as described above, the shortest magnetic flux loop formed by the magnetic flux that passes through the core 95, the plunger 83, and the wall portion 73 of the differential case 9 by excitation of the electromagnet 17 is effectively used. is operated to move toward the interrupting member 65, and the ring member 85 presses the interrupting member 65 via the pressing portion 89.

By this pressing operation of the interrupting member 65 by the movable member 69, the interrupting member 65 is moved in the connection direction of the interrupting portion 67 against the urging force of the urging member 81, and the interrupting portion 67 is connected.

By this connection of the disconnecting portion 67, the output gear 15 and the disconnecting member 65 are connected to be rotatable together, the output gear 15 and the differential case 9 are connected, and the differential mechanism 35 is placed in a locked state.

On the other hand, when disconnecting the interrupting part 67, by stopping the power supply to the electromagnet 17, the interrupting member 65 is moved in the direction of disconnecting the interrupting part 67 by the urging force of the urging member 81, and the connection of the interrupting part 67 is disconnected. It will be canceled.

By disconnecting the interrupting portion 67, the output gear 15 and the interrupting member 65 can rotate relative to each other, the output gear 15 and the differential case 9 can rotate relative to each other, and the locked state of the differential mechanism 35 is released.

Here, an interlocking member 101 is fixed to the axial end surface of the convex portion 77 of the interrupting member 65 via a bolt so as to be movable together with the interrupting member 65 in the axial direction.

The interlocking member 101 is disposed in a radial hole 103 that radially penetrates through a hole 79 provided in a wall 73 of the differential case 9, and has a radial end that extends from the outer peripheral surface of the differential case 9. The operating section 105 is arranged so as to be exposed from the inside.

The operating section 105 of the interlocking member 101 is housed inside the carrier 3, and is closely opposed to the switch section of the position switch 106, which is an electrical component fixed to the carrier 3, and is operated by the axial movement of the interrupting member 65. An intermittent condition is detected.

In the present embodiment, the position switch 106 is a non-contact type detection sensor disposed close to the operation unit 105, but the position switch 106 can also be combined with a contact type.

The position switch 106 has an output end (not shown) electrically connected to a first electrical connection section 19a as the electrical connection section 19 through an opening formed in the carrier 3.

The first electrical connection part 19a is disposed outside the carrier 3, has a base end fixed to a fixing part 31 provided in the cylindrical part 27 via a bolt, and extends from the fixing part 31 side along the protruding direction of the mounting part 25. A connecting end 29 extends along the extending direction of the cylindrical portion 27 at the end of the extended portion.

A mating electrical connection part (not shown) electrically connected to a controller (not shown) is fitted into the connection end 29 of the first electrical connection part 19a, and the position switch 106 is connected to the first electrical connection part 19a. It is electrically connected to the controller via the position switch 106, and a signal from the position switch 106 is input to the controller.

By detecting the disconnection of the position switch 106 by the interlocking member 101 in this way, it is possible to detect the position of the disconnection member 65, that is, whether or not the disconnection mechanism 37 is in the connected state. It is possible to detect whether or not there is.

Further, as described above, the electromagnet 17 as an electric component is connected to the second electrical connection part 19 through the output end (not shown) of the electromagnet 17 through the opening formed in the carrier 3 via the connected lead wire. 19b.

In such a differential device 1, if the first electrical connection portion 19a and the second electrical connection portion 19b as the electrical connection portion 19 disposed outside the carrier 3 are exposed, it may cause damage due to running of the vehicle. There is a possibility that the first electrical connection portion 19a and the second electrical connection portion 19b may be damaged by flying stones or the like, and there is a fear that the reliability of the electrical connection may be reduced.

Furthermore, in order to protect the first electrical connection part 19a and the second electrical connection part 19b, it is possible to attach a protection member formed of a separate member from the carrier 3 to the carrier 3, but the protection member and the protection member are fixed. There was a concern that the number of parts, such as fixing members, would increase.

Therefore, a protruding wall 21 is provided on the outer surface of the carrier 3 so as to face the lower side of the electrical connection section 19 (located on the lower side in the vertical direction).

The protruding wall 21 includes a first protruding wall 21a disposed opposite to the lower side of the first electric connection part 19a, and a second protrusion wall 21b disposed opposite to the lower side of the second electric connection part 19b. have.

The first protruding wall 21a and the second protruding wall 21b are arranged outwardly from the outer peripheral surface of the dividing member 23 of the carrier 3 so as to be disposed below the first electrical connection part 19a and the second electrical connection part 19b, respectively. It is formed of a single member that is continuous with the dividing member 23 in the direction.

The first protruding wall 21a and the second protruding wall 21b are arranged in a cylindrical portion such that the connecting end 29 sides of the first electrical connecting portion 19a and the second electrical connecting portion 19b face the lower side of the connecting end 29. It extends along the extending direction of 27.

By providing the first protruding wall 21a and the second protruding wall 21b in this way, it is possible to prevent the connecting end 29 connected to the other electrical connection part from colliding with flying stones, etc., thereby improving the reliability of the electrical connection. can be retained.

Further, the first protruding wall 21a and the second protruding wall 21b have a wall length extending outward from the outer peripheral surface of the carrier 3 at least toward the proximal end side of the first electrical connection portion 19a and the second electrical connection portion 19b ( The height from the fixing portions 31, 33 side) to the connecting end portion 29 side is set to be opposite to the height.

By setting the wall lengths of the first protruding wall 21a and the second protruding wall 21b in this way, the first A protruding wall 21a and a second protruding wall 21b can be arranged.

Further, the base ends of the first protruding wall 21a and the second protruding wall 21b on the attachment part 25 side are formed of a single member continuous with the attachment part 25 so as to be connected to the attachment part 25.

By connecting the first protruding wall 21a and the second protruding wall 21b with the mounting part 25 in this way, the rigidity of the first protruding wall 21a and the second protruding wall 21b is increased, and the first protruding wall 21a and the second protruding wall 21b are connected to each other. By forming the protruding wall 21b continuously, it is possible to prevent collisions with flying stones from the direction of the mounting portion without any gaps.

Here, on the outer peripheral surface of the carrier 3, the second electrical connection part 19b is arranged above the first electrical connection part 19a in the vertical direction, and the second electrical connection part 19b is arranged higher in the carrier 3 than the first electrical connection part 19a in the horizontal direction. placed inward.

According to the arrangement of the second electrical connection portion 19b, the second protruding wall 21b is disposed higher than the first protruding wall 21a in the vertical direction, and the second protruding wall 21b is disposed higher than the first protruding wall 21a in the horizontal direction. placed inward.

By arranging the second electrical connection part 19b in this way, the second electrical connection part 19b can be prevented from colliding with flying stones etc. by the first protruding wall 21a and the second protruding wall 21b, and can be further electrically Connection reliability can be maintained.

In addition, on the outer peripheral surface of the carrier 3, the second protruding wall 21b located above the first protruding wall 21a is formed so as to be located above the cylindrical portion 27.

By forming the second protruding wall 21b in this manner, the second electrical connection portion 19b disposed above the second protruding wall 21b is protected from collisions with flying stones, etc., in addition to the second protruding wall 21b. This is also prevented by the portion 27, and electrical connection reliability can be further maintained.

Furthermore, by arranging the second electrical connection portion 19b inward of the carrier 3 in the horizontal direction from the first protruding wall 21a, it is possible to suppress the carrier structure from increasing in size. The ease of assembling the electrical wires on the other side is improved, and the routing of the electrical wires on the vehicle side becomes easier.

In such a differential device 1, the protruding wall 21 facing the lower side of the electrical connection part 19 is provided on the outer surface of the carrier 3, so that the protruding wall 21 prevents stones, etc., caused by the running of the vehicle from reaching the electrical connection part 19. Collision can be prevented.

Furthermore, since the protruding wall 21 is integrally provided with the carrier 3, there is no need to attach a protective member separate from the carrier 3, and the number of parts can be reduced.

Therefore, in such a differential device 1, the electrical connection reliability of the electrical connection portion 19 can be maintained without increasing the number of parts.

Furthermore, since the proximal end of the protruding wall 21 is connected to the mounting portion 25, the rigidity of the protruding wall 21 can be improved.

Furthermore, since the electrical connection portion 19 is provided with the connection end portion 29 along the extending direction of the cylindrical portion 27, the connection end portion 29 and the mating electrical connection portion are connected along the extending direction of the cylindrical portion 27. can be connected, and the ease of assembly can be improved.

Further, since the protruding wall 21 is formed so that the connecting end 29 side is along the extending direction of the cylindrical part 27, the protruding wall 21 can be disposed below the connecting end 29 to face the electrical connection reliability can be maintained.

Furthermore, since the protruding wall 21 has a wall length that is opposite to the height from the base end side of the electrical connection part 19 to the connection end part 29 side, the protrusion wall 21 is placed opposite to the lower side of the entire electrical connection part 19. Furthermore, electrical connection reliability can be maintained.

Further, since the base end of the electrical connection part 19 (first electrical connection part 19a) is fixed to the cylindrical part 27 by the fixing part 31, the electrical connection part 19 (first electrical connection part 19a) is The connecting portion 19a) can be arranged, and the degree of freedom in arrangement layout can be improved.

Furthermore, since the base end of the electrical connection part 19 (second electrical connection part 19b) is fixed to the mounting part 25 by the fixing part 33, the electrical connection part 19 (second electrical connection part 19b) is The connection portion 19b) can be arranged, and the degree of freedom in arrangement layout can be improved.

Further, the second electrical connection section 19b is arranged above the first electrical connection section 19a in the vertical direction, and arranged inside the carrier 3 from the first electrical connection section 19a in the horizontal direction, and is arranged on the protruding wall. 21 has a first protruding wall 21a provided corresponding to the first electrical connection part 19a, and a second protruding wall 21b provided corresponding to the second electrical connection part 19b.

Therefore, the second electrical connection portion 19b is prevented from colliding with a flying stone or the like by the first protruding wall 21a and the second protruding wall 21b, and further maintains electrical connection reliability.

Furthermore, since the protruding wall 21 (second protruding wall 21b) is formed above the cylindrical part 27, the electrical connection part 19 (second electrical connection part 19b) is connected to the protruding wall 21 (second protruding wall 21b). In addition, the cylindrical portion 27 also prevents collisions with flying stones and the like, and further maintains electrical connection reliability.

Note that in the differential device according to the embodiment of the present invention, the electrical components are an electromagnet and a position switch, but are not limited to these. The electrical component, such as a temperature sensor, can be any electrical component that is housed inside the carrier, with electrical connections located outside the carrier.

1 Differential device 3 Carrier 5 Pinion 7 Input gear 9 Differential case 11 Differential gear 13, 15 Output gear 17, 106 Electromagnet, position switch (electrical parts)
19 Electrical connection part 19a First electric connection part 19b Second electric connection part 21 Projecting wall 21a First projecting wall 21b Second projecting wall 23 Dividing member 25 Mounting part 27 Cylindrical part 29 Connection end parts 31, 33 Fixing part

Claims (8)

A carrier, a pinion that is rotatably supported by the carrier and into which a driving force is input, an input gear that is rotatably supported by the carrier and is driven by meshing with the pinion, and a differential case to which the input gear is fixed. a differential gear that is supported by the differential case and is rotatable and revolves around the rotation of the differential case; a pair of output gears that mesh with the differential gear and are relatively rotatable and each outputs a driving force; A differential device comprising an electrical component housed in the carrier, and an electrical connection part electrically connected to the electrical component and disposed outside the carrier,
The outer surface of the carrier is provided with a protruding wall facing the lower side of the electrical connection part ,
The electrical connection part has a first electrical connection part and a second electrical connection part,
The second electrical connection part is arranged above the first electrical connection part in the vertical direction, and arranged inward of the carrier than the first electrical connection part in the horizontal direction,
A differential characterized in that the protruding wall has a first protruding wall provided corresponding to the first electrical connection part and a second protruding wall provided corresponding to the second electrical connection part. Device. The differential device according to claim 1,
The carrier is made up of a plurality of divided members,
The plurality of divided members are connected via mutually protruding mounting portions in a circumferential manner,
A differential device characterized in that a base end of the protruding wall is connected to the mounting portion. The differential device according to claim 1 or 2,
A cylindrical portion is formed in the carrier along the axial direction of the pinion,
A differential device characterized in that the electrical connection portion has a connection end portion provided along an extending direction of the cylindrical portion. 4. The differential device according to claim 3,
The differential device is characterized in that the protruding wall is formed with the connecting end side extending along the extending direction of the cylindrical portion. The differential device according to claim 3 or 4,
The differential device is characterized in that the protruding wall has a wall length that is opposite to the height from the base end side of the electrical connection part to the connection end side. The differential device according to any one of claims 3 to 5,
A differential device characterized in that a base end of the electrical connection part is fixed to the cylindrical part by a fixing part. The differential device according to claim 2 ,
A differential device characterized in that a base end of the electrical connection part is fixed to the mounting part by a fixing part. The differential device according to any one of claims 3 to 5,
The differential device characterized in that the protruding wall is formed above the cylindrical portion .

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