JP5759141B2 - Driving force distribution device - Google Patents

Description

  The present invention relates to a driving force distribution device that distributes and controls driving force between front and rear wheels of a vehicle or between left and right wheels of a vehicle.

  2. Description of the Related Art Conventionally, a driving force distribution device for a four-wheel drive vehicle that controls switching of an auxiliary transmission and clutch pressing force of a friction clutch with a single motor has been proposed (see, for example, Patent Document 1).

  In the driving force distribution device described in Patent Document 1, a shift fork for switching an auxiliary transmission mechanism and a spur gear for driving a ball cam are fixedly arranged coaxially on a drive shaft driven by a motor. The shift fork and the spur gear are driven by a cam follower provided on the motor drive shaft.

JP 2004-249974 A

  By the way, it is desired to move quickly to the clutch stroke amount to which the friction clutch is engaged. Therefore, when engaging the friction clutch, it is necessary to accelerate the motor to a high rotational speed.

  However, the driving force distribution device described in Patent Document 1 has a structure in which a shift fork (shift cam) for switching the sub-transmission mechanism and a spur gear for driving the ball cam (for friction clutch driving) are directly connected to rotate integrally. Therefore, the rotation angle of the shift cam is limited, and a sufficient motor rotation angle for driving the friction clutch cannot be secured. Therefore, if it is attempted to secure a clutch stroke in which the friction clutch is engaged at a small motor rotation angle, there is a problem that the motor current increases. If the reduction ratio of the motor is increased to avoid this, the transmission efficiency of the motor output is lowered, and thus the response is deteriorated.

  An object of the present invention is to provide a driving force distribution device having improved responsiveness to switching of a sub-transmission and clutch pressing force of a friction clutch.

[1] The present invention relates to a sub-transmission that transmits power to the input shaft to at least two stages, a high speed stage and a low speed stage, and transmits the power to the main output shaft, and friction that transmits the power of the main output shaft to the sub output shaft A clutch, a rotary drive member fixed to the output shaft of the actuator, a friction clutch drive cam that is coaxially disposed at one end of the rotary drive member so as to be relatively rotatable, and changes a pressing force of the friction clutch; A shift cam that is coaxially disposed at the other end of the rotational drive member so as to be relatively rotatable, converts the rotational motion of the actuator into a linear motion and shifts the sub-transmission, and the sub-transmission is operated by a shift operation of the shift cam. a mechanism for directly connected to the state near Rutoki said main output shaft releasing the pressing force of the low speed stage near I the friction clutch and said auxiliary output shaft, the direction normal to the axis of the outer surface of the rotary drive member Provided as the rolling center, said friction clutch driving cam and the interlocking position, and it and a ratchet lever which is switched by rotating around said axis in a position to work with the shift cam, the ratchet lever, the shift cam is When the sub-transmission is in a high speed position for switching to the high speed stage, and when the rotary drive member is rotationally driven to a predetermined position on one side from the control start position with the high speed stage position as a control origin, In order to increase the pressing force of the friction clutch in conjunction with the friction clutch drive cam, and the shift cam is in the high speed position, and the rotation drive member is in the control start position and when driven reciprocally rotated between a predetermined position of the other side, the high speed the shift cam said auxiliary transmission in conjunction with the shift cam The slow speed position switch to the low speed stage and the is configured to reciprocally rotate between the high gear position, said high speed stage from the low speed stage position after the shift cam is rotated to the low speed stage position from the high speed stage position from the In the driving force distribution device, the mechanism that is directly connected maintains the low speed stage of the auxiliary transmission until it returns to the position .

[2] In the invention described in [1], the ratchet lever is engaged with a ratchet groove formed in the shift cam to rotate the shift cam, and a drive provided in the friction clutch driving cam. An arm portion that rotates and retracts to the open position where the drive claw does not mesh with the ratchet groove by abutting on the pin is integrally formed.

  According to the present invention, excellent response to switching of the sub-transmission and the clutch pressing force of the friction clutch can be obtained.

It is sectional drawing which shows roughly the example of 1 structure of the transfer which is typical embodiment concerning this invention. (A)-(d) is explanatory drawing which shows typically the example of 1 action | operation of the shift fork for 4WD cancellation | release. It is a disassembled perspective view which shows the shift clutch control mechanism used suitably for the transfer of this invention. It is a perspective view of the rotation drive member used suitably for the shift clutch control mechanism of this invention. (A) is explanatory drawing which shows the assembly state of the shift clutch control mechanism of this invention, (b)-(d) is explanatory drawing of shift control. (A) is explanatory drawing which shows the assembly state of the shift clutch control mechanism of this invention, (b) is explanatory drawing of clutch control. It is. It is sectional drawing of the check mechanism used suitably for the shift clutch control mechanism of this invention.

  Preferred embodiments of the present invention will be specifically described below with reference to the accompanying drawings.

(Overall configuration of transfer)
In FIG. 1, reference numeral 1 indicating the whole schematically shows the overall configuration of a typical transfer according to this embodiment. The transfer 1 according to the illustrated example is applied to, for example, a four-wheel drive (4WD) vehicle based on an FR (front engine, rear drive) system.

  As shown in FIG. 1, the transfer 1 has a transfer case including a front case 2 and a rear case 3. An input shaft 4 for inputting rotation from an engine (not shown) via an automatic transmission or a manual transmission (not shown) is fixedly supported by a front portion of the front case 2 via a bearing 5 so as to be rotatable. Yes. A rear wheel output shaft 6, which is a main output shaft coaxially disposed in the rear case 3, is directly connected to the input shaft 4 via an auxiliary transmission 20 coaxially disposed in the front case 2. Yes.

  As shown in FIG. 1, a front wheel output shaft 7 serving as a sub output shaft with respect to the main output shaft is provided at a portion parallel to the rear wheel output shaft 6 of the transfer case. A drive sprocket gear 8 is provided on the same axis of the rear wheel output shaft 6. A driven sprocket gear 9 for the drive sprocket gear 8 is provided on the same axis of the one front wheel output shaft 7. An annular chain 10 is wound around the drive sprocket gear 8 and the driven sprocket gear 9.

  As shown in FIG. 1, the sub-transmission 20 switches a driving shift between the high speed stage H and the low speed stage L by using a shift mechanism 30 for the driving force of the engine input to the input shaft 4. The shift mechanism 30 includes an HL switching clutch sleeve 31 that is arranged coaxially with the planetary gear mechanism of the auxiliary transmission 20.

  As shown in FIG. 1, this planetary gear mechanism meshes with the high speed gear (sun gear) 21 formed on the outer periphery of the input shaft 4, the ring gear 22 fixed to the front case 2, and the outer periphery of the sun gear 21. , 23 are provided with a plurality of pinion gears (planetary gears) 23 that mesh with the inner periphery of the ring gear 22. The plurality of pinion gears 23 are fixedly supported so as to be capable of rotating on a circular carrier case 25 via a support shaft 24 arranged with the same phase difference. The carrier case 25 is fixedly supported around the input shaft 4 so as to be rotatable relative to the sun gear 21. A circular ring body 26 having an inner spline (tooth portion) 26 a is integrally fixed to the rear end portion of the carrier case 25, and both ends of the support shaft 24 are connected to the carrier case 25 and the circular ring body 26. The support is fixed.

  In the low speed state, the spline of the clutch sleeve 31 is disengaged from the high speed gear 21 so that the spline of the clutch sleeve 31 is spline engaged with the inner spline 26a of the ring body 26, and the rotational power transmitted from the pinion gear 23 is It is transmitted to the rear wheel output shaft 6 as a low-speed rotational driving force.

  On the other hand, in the high speed state shown in FIG. 1, the spline of the clutch sleeve 31 and the high speed gear 21 are meshed with each other, and the rotational driving force of the input shaft 4 is converted from the input shaft 4 as a high speed rotational driving force. It is transmitted to the rear wheel output shaft 6 via the drive sprocket gear 8, the front wheel drive chain 10, and the driven sprocket gear 9.

  On the same axis of the rear wheel output shaft 6, as shown in FIG. 1, a friction clutch device 40 that constitutes a part of a driving force distribution device that performs distribution control of front and rear wheel driving force in the 4WD mode is provided. . The transfer case is provided with an actuator 70 serving as a drive source for controlling the operation of the shift mechanism 30 of the auxiliary transmission 20 and the operation of the friction clutch device 40. The actuator 70 incorporates a speed reducer 71 that amplifies the torque of the motor. The rotational drive by the speed reducer 71 is transmitted to the shift mechanism 30 and the friction clutch device 40 via the actuator output shaft 72.

(Configuration of shift mechanism)
As shown in FIG. 1, the shift mechanism 30 is mainly configured by two members in which an HL fork main body 32 and a sliding holder 33 for HL switching are relatively movable via a coil spring 34. One side of the HL fork main body 32 is movably inserted and supported by the shift rod 35. A bifurcated fork engaged with the clutch sleeve 31 for HL switching is extended on the other side of the HL fork main body 32. A pair of elongate columnar spring load receiving portions 32a and 32a bulging inward are formed on both sides in the shift rod axial direction on the inner surface of the standing side wall facing both sides in the width direction of the HL fork main body 32, respectively. Yes.

  As shown in FIG. 1, one sliding holder 33 is provided so as to be movable relative to the HL fork main body 32 through a pair of sliding legs 33 a and 33 a that are inserted and supported coaxially with the shift rod 35. It has been. The sliding leg 33a is set to be smaller than the distance between the spring load receiving portions 32a of the HL fork main body 32, and the distance between the pair of sliding leg 33a is HL fork main body 32. Is substantially equal to the distance between the pair of spring load receiving portions 32a on both sides in the length direction.

  As shown in FIG. 1, a pair of circular washers 36, 36 are arranged coaxially with the shift rod 35 on the opposing inner surfaces of the pair of sliding legs 33 a. The washer 36 is formed to have a larger diameter than the distance between the pair of spring load receiving portions 33 a on both sides in the width direction of the HL fork main body 32. The pair of sliding legs 33 a and the washer 36 have a spring holding function for holding both ends of the coil spring 34 and a spring operating function for operating the coil spring 34. A waiting mechanism for accumulating the shift operation force is constituted by the compression force and the restoring force of the coil spring 34 generated by the relative movement between the spring load receiving portion 32a of the HL fork main body 32 and the sliding leg portion 33a of the sliding holder 33. .

  As shown in FIG. 1, an arm portion 33 b extending along the shift rod 35 is integrally formed at one end in the length direction of the sliding holder 33. A columnar shifter pin 33c protrudes and is supported at the tip of the arm portion 33b. The shifter pin 33c is loosely fitted with a predetermined gap in a slidable manner in a cam groove 37a that converts the rotational motion of the shift cam 37 into a linear motion of the shift mechanism 30. The shifter pin 33c is configured to be disposed closer to the shift cam 37 than the HL fork main body 32 via the arm portion 33b, so that a narrow installation space in the apparatus can be rationally used.

  As shown in FIGS. 5 and 6, the shift cam 37 is not formed with an endless cam groove, but is formed with a single cam groove 37 a that reciprocates between HL. The rotational movement of the shift cam 37 is transmitted to the sliding holder 33 via the shifter pin 33c moving along the inclined portion of the cam groove 37a, and is converted into a linear movement of the sliding holder 33. This linear motion causes the HL fork main body 32 to linearly move along the shift rod 35 via the coil spring 34.

  In the example shown in the figure, the shift cam 37 is moved 180 degrees in the left direction to move the shifter pin 33c by an axial shift amount necessary for switching between the high speed H position and the low speed L position of the sub-transmission 20. The linear movement of the HL fork main body 32 shifts the clutch sleeve 31 for connecting / disconnecting the driving force between the sun gear 21 and the pinion gear 23 of the auxiliary transmission 20 via the HL fork main body 32, Switching between high speed and low speed is performed.

(Configuration of friction clutch device)
As shown in FIG. 1, the friction clutch device 40 controls the connection / disconnection operation of an annular multi-plate friction clutch 41. The friction clutch 41 fixes an annular clutch hub 42 to the rear wheel output shaft 6 and is connected to a drive sprocket gear 8 that rotatably supports an annular clutch drum 43 on the rear wheel output shaft 6.

  During the two-wheel drive (2WD), the engagement of the friction clutch 41 is released, and the rotation of the input shaft 4 is transmitted to the rear wheel output shaft 6 via the auxiliary transmission 20. On the other hand, in the case of 4WD, the friction clutch 41 is in the engaged state, and the driving force from the input shaft 4 is the rear wheel output shaft 6, the friction clutch 41, the driving sprocket gear 8, the front wheel driving chain 10, and the driven sprocket gear 9. Is transmitted to the front wheel output shaft 7.

  As shown in FIG. 1, the friction clutch device 40 converts an annular clutch pressing member 44 that can move on the same axis as the rear wheel output shaft 6 and the rotational motion of the actuator 70 into a linear motion. 44 is provided with a ball cam mechanism 50 for applying an axial displacement.

  As shown in FIGS. 1 and 2, the ball cam mechanism 50 controls the clutch fastening force of the friction clutch 41 steplessly. The ball cam mechanism 50 includes a pair of ball cams configured by a reaction force side cam plate (reaction force cam plate) 51 and a drive side cam plate (drive cam plate) 52 on the same axis as the rear wheel output shaft 6. Is provided. The reaction force cam plate 51 is fixed to an annular fixing member 54 via a thrust bearing 53. One drive cam plate 52 is in contact with and connected to the clutch pressing member 44 via a thrust bearing 55.

  As shown in FIG. 2, the reaction force cam plate 51 is supported by the positioning rod 11 at a free end extending toward the actuator output shaft side. The positioning rod 11 also has a function as a stopper for preventing reverse rotation of the plate clutch 60 for driving the friction clutch, which is rotatably supported coaxially with the actuator output shaft 72. One drive cam plate 52 is integrally formed with a tapered arm portion 52 a extending toward the actuator output shaft side with a phase difference of a predetermined angle from the reaction force cam plate 51. A cam follower 56 is rotatably supported at the distal end portion of the arm portion 52a. The cam follower 56 is always in contact with the cam surface of the plate cam 60, and transmits the rotation of the actuator 70 to the ball cam mechanism 50.

  When the friction clutch 41 is engaged, the drive cam plate 52 rotates in a fixed direction with respect to the reaction cam plate 51 by rotating the plate cam 60 clockwise around the axis of the actuator output shaft 72 in the positive rotation direction. Driven. When the drive cam plate 52 is rotationally driven, the drive cam plate 52 moves in the axial direction of the rear wheel output shaft 6 while being pressed by the ball 57 in the ball cam groove. When the drive cam plate 52 moves, the clutch pressing member 44 is pressed in the axial direction of the rear wheel output shaft 6 to press the friction clutch 41, thereby increasing the clutch pressing force according to the rotation amount of the actuator 70.

  On the other hand, when releasing the engagement of the friction clutch 41, the plate cam 60 rotates in the opposite direction to the above operation, so that the operation opposite to the above operation is performed. Thereby, the clutch pressing member 44 of the friction clutch 41 can be moved in a change pattern corresponding to the shape of the cam surface formed on the outer surface of the plate cam 60.

  According to the configuration of the transfer 1 according to the above embodiment, the following effects can be obtained.

(1) The drive cam plate 52 of the ball cam mechanism 50 is rotationally driven by the cam follower 56 following the cam surface of the plate cam 60, so that the clutch plate of the friction clutch 41 is compared with the configuration in which the drive cam plate is rotationally driven by a pinion gear. It is possible to move a long movement distance at a small rotation angle by the actuator 70 when the clutch engagement release state, which is spaced from the clutch release state, is shifted to the clutch engagement state.
(2) The length of the HL fork main body 32 in the shift rod axial direction ensures a moving stroke in which the slide leg 33a of the slide holder 33 passes through the spring load receiving portion 32a of the HL fork main body 32. At the same time, the HL fork main body 32 having the minimum internal space necessary for assembling the sliding holder 33 and the coil spring 34 can be formed. The shift mechanism 30 having the two advantages of reducing the size and shortening of the HL fork main body 32 can be obtained.

(Configuration of 4L mechanical lock mode mechanism)
As shown in FIG. 1, one main basic configuration of this embodiment is a shift mechanism 30 of the sub-transmission 20. When the sub-transmission 20 is in the low speed stage L (4L position), the rear wheel output shaft 6 and the front wheel output shaft 7 are arranged on the drive transmission path between the HL fork main body 32 and the drive sprocket gear 8 of the front wheel drive chain 10.

  This direct coupling mechanism includes a 4WD unlocking shift fork (4WD releasing fork) 110 and a 4WD unlocking shift rod (4WD releasing shift rod) 111 that release 4WD lock when traveling at high speed stage H. Yes. When the clutch sleeve 31 is shifted to the 4L position, the low-speed rotational driving force is directly coupled to the front wheel output shaft 7 via the auxiliary transmission 20 to enter the 4L mechanical lock mode, and the friction clutch device 40 is not controlled. .

  As shown in FIG. 1, one end of the 4WD releasing shift rod 111 is cantilevered by a fixing means such as welding at the engaging step 33d formed at the fork base end of the HL fork main body 32. It is fixed in parallel with the shift rod 35 for HL switching. The 4WD releasing shift rod 111 is formed in a short shaft shape having a diameter smaller than the diameter of the shift rod 35.

  As shown in FIG. 1, the fork 110 for releasing 4WD is formed in a shape obtained by bending a sheet metal into a substantially U shape, and has long and short side plates 110b and 110c facing both sides of the substrate 110a. Each of the side plates 110b and 110c is formed with a sliding hole penetratingly inserted and supported on the 4WD releasing shift rod 111 so as to be movable in the axial direction. Of these side plates 110b and 110c, a bifurcated fork that is engaged with and connected to a slide sleeve 112 for 4WD lock (4WD lock slide sleeve 112) is extended at the tip of the long side plate 110b. Yes.

  As shown in FIG. 1, a waiting spring 113 made of a coil spring interposed coaxially with the 4WD releasing shift rod 111 is accommodated between the opposing inner surfaces of the opposing side plates 110b and 110c. One end of the waiting spring 113 is supported in contact with the fork base end portion of the HL fork main body 32. The other end of the waiting spring 113 is supported via a washer 115 locked to a snap ring 114 fitted on the 4WD releasing shift rod 111, and movement in the shift rod axial direction is restricted.

  The waiting spring 113 urges the 4WD releasing fork 110 toward the HL fork main body 32 as shown in FIG. A force accumulation mechanism (waiting mechanism) is configured by a spring that temporarily stores the elasticity of the waiting spring 113 that compresses toward the HL fork main body 32 and transmits the stored elasticity to the 4WD lock slide sleeve 112. In place of the coil spring, for example, a spring mechanism such as a disc spring or a leaf spring can be used.

(Switching operation between HL fork main body and 4WD release fork)
Referring to FIG. 2, an operation example of the HL fork main body 32 and the 4WD releasing fork 110 is schematically illustrated in FIG. 2.

  When the HL fork main body 32 is in the 4WD locked state in the 4L position shown in FIG. 2A, the 4WD lock slide sleeve 112 is pressed by the HL switching clutch sleeve 31, and the spline of the 4WD lock slide sleeve 112 is pressed. Is engaged with and connected to a spline 8 a formed on the drive sprocket gear 8 of the front wheel drive chain 10. The 4WD releasing fork 110 is held at a position in contact with the HL fork main body 32 via a waiting spring 113.

  Now, when the actuator 70 is driven to rotate, the driving rotation of the actuator 70 is transmitted to the shift cam 37 via the reduction gear mechanism 71, and the shift cam 37 rotates. When the shift cam 37 rotates, the shifter pin 33c of the sliding holder 33 of the HL fork main body 32 is moved in the shift rod axial direction along the inclined portion of the cam groove 37a from the straight portion of the cam groove 37a of the shift cam 37.

  The movement of the sliding holder 33 presses one of the end portions of the coil spring 34 via the sliding leg 33 a and the washer 36 of the sliding holder 33. As the slide holder 33 moves, the slide holder 33 moves the coil spring 34 toward the inner surface of the spring load receiving portion 32a of the HL fork main body 32 via the washer 36, as shown in FIG. While being compressed, the HL fork main body 32 moves toward the inner surface of the standing side wall in the length direction, and abuts against and presses against the inner surface of the fork main body in the length direction.

  The other end of the coil spring 34 presses the inner surface of the spring load receiving portion 32a of the HL fork main body 32 through the washer 36, and the coil spring 34 bends to be in a compressed state. At this time, the shifter pin 33c of the sliding holder 33 moves from the inclined portion of the cam groove 37a of the shift cam 37 along the straight portion of the cam groove 37a, and the sliding holder 33 reaches the shift completion position. The coil spring 34 is in the maximum compression state, and the moving load of the sliding holder 33 is applied to the HL fork main body 32.

  Until the phases of the clutch sleeve 31 for HL switching and the sun gear 21 of the auxiliary transmission 20 coincide with each other, the sliding leg 33a of the sliding holder 33, the washer 36, and the HL fork main body 32 The coil spring 34 is held in a compressed state by the action of a waiting mechanism including the spring load receiving portion 32a, and the shift operation force is temporarily stored in the coil spring 34. At this time, energization to the actuator 70 is cut off.

  When the phases of the clutch sleeve 31 for HL switching and the sun gear 21 of the auxiliary transmission 20 coincide with each other, as shown in FIG. 2 (c), the restoring spring force of the coil spring 34 that has accumulated the shift operating force is used. The HL fork main body 32 moves instantaneously along the shift rod 35. The HL switching clutch sleeve 31 slides on the spline of the rear wheel output shaft 6 and quickly switches to the H position.

  On the other hand, when the HL fork main body 32 moves along the shift rod 35 for the HL fork as shown in FIGS. 2B and 2C, the 4WD release fork 110 moves to the 4WD release fork rod. One end of the waiting spring 113 is pressed via 111. The other end of the waiting spring 113 presses the inner surface of the long side surface 110b of the 4WD releasing fork 110, and the waiting spring 113 is bent to be in a compressed state.

  At this time, the urging force of the waiting spring 113 is transmitted to the 4WD releasing fork 110. However, when the torque is applied between the 4WD lock slide sleeve 112 and the drive sprocket gear 8 of the front wheel drive chain 10, the 4WD lock is applied. Since the slide sleeve 112 cannot be removed, the waiting spring 113 is held in a compressed state, and the shift operating force is temporarily stored in the waiting spring 113.

  When the torque between the 4WD lock slide sleeve 112 and the drive sprocket gear 8 is released during vehicle travel, as shown in FIG. 2 (d), the restoring spring force of the waiting spring 113 that has accumulated the shift operation force causes The 4WD releasing fork 110 moves instantaneously along the 4WD releasing fork rod 111. Then, the 4WD lock slide sleeve 112 slides on the spline of the rear wheel output shaft 6 and quickly switches to the H position, and enters the 4WD lock release state at the H position. In the illustrated example, the 4WD lock slide sleeve 112 and the HL switching clutch sleeve 31 come to rest in contact with each other.

  With the above shift operation, the switching from the 4L position to the H position and the switching from the 4WD locked state to the 4WD unlocked state are completed. When switching from the 4WD unlocked state to the 4WD locked state as opposed to the above shifting operation, the shifting operation is the reverse of the above shifting operation, and by switching the HL fork main body 32 from the H position to the 4L position, This is achieved by the clutch sleeve 31 pushed by the HL fork main body 32 pushing the 4WD lock slide sleeve 112. Until the phases of the 4WD lock slide sleeve 112 and the drive sprocket gear 8 coincide with each other, the coil spring (waiting spring) 34 of the HL fork main body 32 is bent and enters a waiting state.

  According to the 4L mechanical lock mode mechanism according to the above embodiment, the following effects can be obtained.

(1) The auxiliary transmission 20 can always be maintained at the 4L position by the 4WD releasing fork 110.
(2) The 4WD releasing fork 110 and the 4WD releasing fork rod 111 are integrated with the HL fork main body 32, and the 4WD releasing fork 110 and the 4WD releasing fork rod 111 are integrated with the HL fork body 32 and the front wheel. Since the configuration is arranged on the drive transmission path with the drive chain 10, only one shift rod 35 is required to straddle the transfer case, and the space between the opposed inner sides of the front wheel drive chain 10 is reduced. It is possible to provide the 4WD releasing fork 110 even in a small and small capacity model.
(3) The 4WD releasing fork 110 is disposed on the drive transmission path between the HL fork main body 32 and the front wheel driving chain 10 and is formed on the opposing inner surfaces of the pair of side plates 110b and 110c in the 4WD releasing fork 110. It has a configuration in which a waiting spring 113 is provided therebetween. Therefore, the support span of the 4WD releasing fork 110 can be set longer while shortening the overall length of the 4WD releasing fork 110. Since the support span can be set long, a smooth movement with little distortion is possible.

(Overall configuration of shift / clutch control mechanism)
Another main basic configuration of this embodiment is a shift / clutch control mechanism 80 for controlling the shift mechanism 30 and the friction clutch device 40, as shown in FIG. The components of the transfer 1 configured as described above are the same as the conventional ones except for the shift mechanism 30 and the ball cam mechanism 50. Therefore, the basic configuration of the transfer 1 is not limited to the illustrated example.

  A typical shift / clutch control mechanism 80 according to this embodiment individually controls the switching operation of the auxiliary transmission 20 and the connection / disconnection operation of the friction clutch device 40 by continuous rotation of a single actuator 70. Make it possible. According to the illustrated example, this control performs clutch control on one side (right rotation) with the shift position (high speed stage H position) of the shift cam 37 as the control origin, and the shift position (high speed stage H position) as the control origin. Switching control of the auxiliary transmission 20 is performed on the other side (left rotation) opposite to the one side.

  As shown in FIGS. 1 and 3, the shift / clutch control mechanism 80 includes a shift cam 37 that linearly moves the shift mechanism 30 along the shift rod 35, and a plate cam 60 that changes the clutch pressing force of the friction clutch 41. The rotation cam 37 and the plate cam 60 are mainly constituted by a rotation drive member 81 for individually rotating the drive. The shift cam 37, the plate cam 60, and the rotation drive member 81 are arranged coaxially with the actuator output shaft 72 and operate according to the rotation amount of the actuator 70.

(Configuration of rotation drive member)
As shown in FIGS. 3 and 4, the rotation drive member 81 has a circumferential surface integrally formed with a large-diameter portion 82 on the shift cam facing side and a small-diameter portion 83 on the plate cam facing side in a direction of the center line O through a step. It is made of a cylindrical body. As shown in FIGS. 3 and 4, the large-diameter portion 82 is supported by the shift rod 35 so as to be rotatable relative to the end surface of the shift cam 37. The rotary drive member 81 is supported by the actuator output shaft 72 with the inner peripheral portion of the small diameter portion 83 on the plate cam side fixed by a spline. A plate cam 60 is supported on the outer periphery of the small diameter portion 83 so as to be relatively rotatable.

  As shown in FIGS. 3 and 4, a pair of rectangular drive projections 84 for the clutch control mechanism and a drive projection 85 for the shift control mechanism are provided on the large-diameter portion 82 of the rotary drive member 81. It protrudes to the 60 side. The drive protrusions 84 and 85 are arranged on the same circumference of the large diameter portion 82 with a predetermined phase difference. The drive protrusion 84 has a drive surface 84 a that abuts on the driven protrusion 63 formed on the plate cam 60 and rotates the plate cam 60 synchronously by the right rotation drive of the rotation drive member 81. One drive protrusion 85 has a stopper surface 85 a that abuts on the driven protrusion 63 of the plate cam 60 and stops the operation of the rotation drive member 81 by the left rotation drive of the rotation drive member 81.

  As shown in FIGS. 3 and 4, a rotation shaft 86 extending in the normal direction of the outer surface is provided on the outer surface of the flat large-diameter portion 82 formed by cutting out between the pair of drive protrusions 84 and 85. The ratchet lever 87 is supported via a bi-directional rotation. The ratchet lever 87 is biased toward the end face of the shift cam 37 by a spring 89 and rotates in a direction orthogonal to the rotation direction of the rotation drive member 81.

  As shown in FIGS. 3 and 4, the ratchet lever 87 is integrally formed with a ratchet portion 90 provided around the rotation shaft 86. The ratchet pawl 91 that is a drive pawl of the ratchet portion 90 is formed in an outer shape that can drive the end face of the shift cam 37 in both the shift direction (left direction) and the return direction (right direction) opposite to the shift direction. Has been. The ratchet pawl 91 can be engaged with and disengaged from the ratchet groove 38 formed on the end face of the shift cam 37 against the elasticity of the spring 89.

  As shown in FIGS. 3 and 4, the ratchet lever 87 is integrally formed with an arm portion 88 on the shift cam 37 side that is orthogonal to the rotation shaft 86. The arm portion 88 is inclined clockwise from the rotation center line of the rotation drive member 81. The side surface in the clockwise direction of the arm portion 88 has a cam surface 88a. The cam surface 88 a causes the ratchet pawl 91 to be detached from the ratchet groove 38 of the shift cam 37 when the rotation driving member 81 drives the plate cam 60 to rotate synchronously by the right rotation driving, so that the rotation driving member 81 and the shift cam 37 rotate synchronously. It has a function to prevent.

(Configuration of shift control mechanism)
As shown in FIG. 3, one plate cam 60 is formed with a cylindrical drive pin 61 projecting from an opposing surface on the rotation drive member 81 side. The drive pin 61 is arranged in the rotation locus of the arm portion 88 of the ratchet lever 87. The drive pin 61 is for holding the ratchet pawl 91 in an open state only when the friction clutch device 40 is driven. The drive pin 61 abuts against the cam surface 88a of the arm portion 88 on the shift cam 37 side to press the ratchet pawl 91. 91 is operated outside the rotation locus of the ratchet groove 38 of the shift cam 37.

  The shift control mechanism is mainly configured by the ratchet groove 38 of the shift cam 37, the drive pin 61 of the plate cam 60, the drive protrusion 85 of the rotation drive member 81, and the ratchet lever 87. Since the ratchet lever 87 is fixed and supported so as to be bi-directionally rotatable about the axis in the normal direction of the rotation center line of the rotation drive member 81, it is necessary for the ratchet pawl 91 to be detached from the ratchet groove 38. Thus, it becomes possible to reduce the operating rotation angle of the ratchet pawl 91.

  Referring to FIG. 5, FIG. 5 shows a developed state where the shift cam 37, the plate cam 60, and the rotation driving member 81 are assembled. In the figure, two check grooves 39, ratchet grooves 38, drive pins 62, and driven protrusions 63 located on both sides of the check ball 104 are the same, but are shown separately in a developed view.

  In FIG. 5A, the actuator output shaft 72 and the shift cam 37 are at the control origin, and the shift position of the shift cam 37 is the high speed H position (H position). When the drive surface 84a of the drive projection 84 of the rotation drive member 81 is away from the driven projection 63 of the plate cam 60, it becomes the control start position of the shifter pin 33c of the shift mechanism 30 that moves in the cam groove 37a of the shift cam 37. .

  FIG. 5 (b) shows that the shift cam 37 rotates in the left direction together with the rotation drive member 81 by rotating the rotation drive member 81 in the left direction (in the development view, the rotation drive member 81 is moved in the left direction). The shift cam 37 and the rotary drive member 81 are integrally rotated in an engaged state in which the ratchet pawl 91 of the rotation drive member 81 is hooked on the ratchet groove 38 of the shift cam 37. The plate cam 60 is stopped while remaining at the control start position.

  When the rotation angle of the rotation drive member 81 reaches 180 °, as shown in FIG. 5C, the check ball 104 is fitted into the next check groove 39 to shift to the low speed L position (L position). Position to position. The shifter pin 33c of the shift mechanism 30 is guided and moved in the axial direction along the cam groove 37a of the shift cam 37, and the movement to the 4L position is completed.

  In FIG. 5C, the stopper surface 85 a of the driving protrusion 85 in the rotation driving member 81 comes into contact with the driven protrusion 63 of the plate cam 60 and stops. The ratchet pawl 91 of the ratchet lever 87 is kept engaged with the ratchet groove 38 of the shift cam 37.

  As shown in FIG. 5D, when the rotation driving member 81 rotates in the backward direction (returns) in the right direction (in the development view, the rotation driving member 81 is moved in the right direction), the rotation driving member 81 and the shift cam 37 are rotated. Together with each other, rotate backward (return) in the right direction (in the development view, the rotation drive member 81 is moved in the right direction). Then, the state returns to the state shown in FIG.

  The above shift operation completes switching from the H position to the 4L position. Note that when switching from the 4L position to the H position, the shift operation is the reverse of the shift operation. Therefore, the description of the operation for switching from the 4L position to the H position is omitted.

(Configuration of clutch control mechanism)
As shown in FIG. 3, the cam surface 64 formed on the outer periphery of the plate cam 60 forms a cam rising portion 65 in a nonlinear manner in which the rate of change in the distance between the shift rod 35 and the cam surface changes in a quadratic curve. In addition, a linear shape is formed from the cam rising portion 65 to the drive rotation direction. Due to the action of the plate cam 60, the gap between the clutch plates is reduced from the initial position of the friction clutch 41 and the clutch pressing force is applied with a small rotation angle of the play portion of the friction clutch 41. Therefore, the clutch engagement / disengagement operation can be performed in a short time in a section where the stroke from the initial position of the friction clutch 41 to the position where the clutch pressing force is applied by reducing the gap between the clutch plates.

  As shown in FIG. 3, the plate cam 60 has the same circle between the drive surface 84a of the drive projection 84 for the clutch control mechanism of the rotation drive member 81 and the stopper surface 85a of the drive projection 85 for the shift control mechanism. A driven projection 63 is formed on the circumference. The driven projection 63 of the plate cam 60 and the drive projection 84 of the rotation drive member 81 mainly constitute a clutch control mechanism.

Referring to FIG. 6, FIG. 6 shows a developed state in which the shift cam 37, the plate cam 60, and the rotation drive member 81 are assembled as in FIG. 5. In FIG. 6A, the drive surface 84a of the drive protrusion 84 of the rotation drive member 81 is made to be a plate by rotating the rotation drive member 81 in the right direction (in the development view, the rotation drive member 81 is moved in the right direction). The position where the cam 60 abuts on the driven projection 63 is the control start position in the clutch control mechanism . In the illustrated example, the clutch control mechanism is configured to be operable when the shift cam 37 is in the H position.

In this clutch control mechanism, when the rotation drive member 81 is rotated in the right direction, the arm portion 88 on the shift cam 37 side of the ratchet lever 87 is pressed against the drive pin 61 of the plate cam 60. The ratchet pawl 91 of the ratchet lever 87 rotates to the left about the rotation shaft 86 against the elasticity and is released.

  The driven projection 63 of the plate cam 60 receives a pressing load by the driving surface 84 a of the driving projection 84 of the rotation driving member 81. The rotation driving member 81 rotates the plate cam 60 in the right direction while leaving the shift cam 37 in the H position. At this time, the ratchet pawl 91 rotates in the right direction along the end surface of the shift cam 37.

  As shown in FIG. 6B, the plate cam 60 is rotationally driven together with the rotational drive member 81 in the right direction. Along with the rotation of the plate cam 60 by the rotation drive member 81, the drive cam plate 52 is rotationally driven with respect to the reaction force cam plate 51 in a certain direction. The driving cam plate 52 increases the clutch pressing force by pressing the friction clutch 41 via the cam follower 56 while being pressed by the ball 57 in the ball cam groove. On the other hand, when the rotation drive member 81 rotates counterclockwise, the clutch pressing force is reduced according to the rotation of the plate cam 60, contrary to the above operation.

  The shift / clutch control mechanism 80 can perform the following switching operation of the sub-transmission 20 and connection / disconnection operation of the multi-plate friction clutch 41 by continuous rotation of the single actuator 70. .

(1) The auxiliary transmission 20 is in the H position, and the friction clutch 41 is in a free state in which the clutch plates are separated (2H).
(2) The auxiliary transmission 20 is fixed at the H position, and the friction clutch 41 is automatically controlled for driving torque to the front wheel output shaft 7 in accordance with a torque command from the four-wheel drive vehicle (4H auto).
(3) The auxiliary transmission 20 is fixed at the H position, and the friction clutch 41 is maintained at the maximum torque (4H rigid).
(4) The auxiliary transmission 20 is fixed at the 4L position, and the friction clutch 41 is held in a free state in which the clutch plates are separated. When the shift mechanism 30 shifts the auxiliary transmission 20 to the 4L position, the 4WD releasing fork 110 is in the 4WD locked state in the 4L position shown in FIG. 2A, and the 4WD lock slide sleeve 112 is connected to the front wheel drive chain 10. The rear wheel output shaft 6 and the front wheel output shaft 7 are directly connected to each other and are in a 4WD mode (4L mechanical lock).

  According to the shift / clutch control mechanism 80 according to the above embodiment, the following effects can be obtained.

(1) Since the friction clutch device 40 is configured to be operable when the shift cam 37 is in the H position, it is not necessary to drive the friction clutch device 40 when the shift cam 37 is in the 4L position. In the 4L mechanical lock in which the rear wheel output shaft 6 and the front wheel output shaft 7 are directly coupled, the sub-transmission 20 can always be maintained at the 4L position by the 4WD releasing fork 110, thus simplifying the mechanism and reducing the cost. And can be achieved.
(2) The response to the switching of the sub-transmission 20 and the clutch pressing force of the friction clutch device 40 can be improved without increasing the motor current or increasing the reduction ratio of the motor.
(3) Since the ratchet lever 87 that rotates in a direction orthogonal to the rotation direction of the rotation drive member 81 is mounted, the operating rotation angle of the ratchet pawl 91 that is required to disengage from the ratchet groove 38 is reduced. And the shift time can be shortened.
(4) Since the switching time of the shift mechanism 30 is shortened, the rotation drive member 81 does not stop during the shift. Even if the rotation drive member 81 stops in the middle of the shift, it can be returned to its original position.

(Check mechanism configuration)
As shown in FIGS. 1, 3, and 7, a check mechanism 100 that constitutes another main part of the shift / clutch control mechanism 80 is coaxially supported at the end of the shift cam 37 near the rotational drive member. Has been. The check mechanism 100 determines the shift position of the shift cam 37, and includes a check box 101 having a circular casing that rotates relative to the shift cam 37, and a pair of elongated cylindrical check blocks formed integrally with the check part 101. 102, 102.

  As shown in FIGS. 3 and 7, the check block 102 extends radially outward with the same phase difference on the outer periphery of the check unit 101. Inside the check block 102, a check ball 104 that is pressed against the check groove 39 of the shift cam 37 by an elastic repulsive force (biasing force) of the coil spring 103 is provided. The front end opening of the check block 102 is closed by a plug 105.

  A check groove 39 into which the check ball 104 is fitted and engaged is formed at the end of the shift cam 37 as shown in FIGS. The check groove 39 of the shift cam 37 is formed corresponding to two shift ends that are shift positions determined by the ratchet groove 38 of the shift cam 37. By engaging the check ball 104 with the check groove 39, the shift position of the H position and the 4L position of the auxiliary transmission 20 is positioned.

  As shown in FIGS. 3 and 7, a flat holding piece 106 that prevents rotation of the check mechanism 100 is integrally formed between one check block 102 and the check unit 101 of the pair of check blocks 102. Is formed. The holding piece 106 is supported by penetrating the positioning rod 11 that supports the reaction cam plate 51 while preventing reverse rotation of the plate cam 60.

  By the way, if the actuator 70 loses driving force while the friction clutch 41 is pressed, the actuator 70 may be driven in reverse by the repulsive force of the friction clutch device 40.

  Another basic configuration of this embodiment is that the check mechanism 100 checks so that the energy absorbed by the check mechanism 100 is greater than the energy released when the actuator 70 is driven in reverse by the repulsive force of the friction clutch 41. The purpose is to set the torque and the rotation angle.

  Here, the absorbed energy of the check mechanism 100 is calculated from the check torque of the check mechanism 100 and the rotation angle of the shift cam 37. This check torque is applied to the check ball 104 engaged with the check spring 104 while being energized by the elastic force of the coil spring 103 against the check ball 104 and the check groove 39 against the energizing force of the coil spring 103. This is the resistance torque that releases the connection. The absorption energy of the check mechanism 100 is calculated by the following equation (1).

  Absorbed energy of check mechanism 100 = resistance torque of check mechanism 100 × rotation angle of shift cam 37 (1)

  According to the configuration of the check mechanism 100 according to the above embodiment, the following effects can be obtained.

(1) By setting the absorbed energy of the check mechanism 100 to the relationship of the above equation (1), even if the transfer cam 37 is configured to perform clutch control and shift control with a single actuator 70, the shift cam 37 It is possible to prevent the auxiliary transmission 20 from being switched while the vehicle is running without being driven to rotate in the shift direction.
(2) Since a pair of check balls 104 are provided at diagonal positions on the circular outer periphery of the check portion 101, a strong check torque can be generated by the inexpensive check balls 104 and the coil spring 103.

  As is clear from the above description, the driving force distribution device of the present invention has been described based on the above embodiment and the illustrated example, but the present invention is not limited to the above embodiment and the illustrated example. The present invention can be implemented in various modes without departing from the scope of the invention. In the present invention, the following modifications are possible.

  In the above embodiment, the case where the driving force distribution device of the present invention is applied to the transfer of an FR type four-wheel drive vehicle has been described, but the present invention is of course not limited thereto. For example, the driving force distribution device of the present invention can be effectively used for a transfer such as an FF type four-wheel drive vehicle. In the above-described embodiment, the auxiliary transmission 20 that switches the traveling shift between the H position and the 4L position has been described. However, the present invention is not limited to this. The present invention can be set by increasing various positions such as neutral, for example, as positions in the sub-transmission.

  Needless to say, the driving force distribution device of the present invention can be effectively used in various vehicles such as motorcycles, working vehicles such as agricultural machinery, construction engineering machinery, and transporting machinery.

DESCRIPTION OF SYMBOLS 1 ... Transfer, 2 ... Front case, 3 ... Rear case, 4 ... Input shaft, 5 ... Bearing, 6 ... Rear-wheel output shaft, 7 ... Front-wheel output shaft, 8 ... Drive sprocket gear, 9 ... Driven sprocket gear, 10 ... Chain, 11 ... Positioning rod, 20 ... Sub-transmission, 21 ... Sun gear, 22 ... Ring gear, 23 ... Planetary gear, 24 ... Support shaft, 25 ... Carrier case, 26 ... Ring body, 26a ... Inner spline, 30 ... Shift mechanism, DESCRIPTION OF SYMBOLS 31 ... Clutch sleeve, 32 ... HL fork main body, 32a ... Spring load receiving part, 33 ... Sliding holder, 33a ... Sliding leg part, 33b ... Arm part, 33c ... Shifter pin, 33d ... Engagement step part, 34 ... Coil spring, 35 ... Shift rod, 36 ... Washer, 37 ... Shift cam, 37a ... Cam groove, 38 ... Ratchet groove, 39 ... Check groove, 40 ... Wear Clutch device, 41 ... friction clutch, 42 ... clutch hub, 43 ... clutch drum, 44 ... clutch pressing member, 50 ... ball cam mechanism, 51 ... reaction force cam plate, 52 ... drive cam plate, 52a ... arm portion, 53, 55 ... thrust bearing, 54 ... fixing member, 56 ... cam follower, 57 ... ball, 60 ... plate cam, 61 ... driving pin, 63 ... driven projection, 64 ... cam surface, 65 ... cam rising portion, 70 ... actuator, 71 ... Reduction gear, 72 ... Actuator output shaft, 80 ... Shift / clutch control mechanism, 81 ... Rotary drive member, 82 ... Large diameter portion, 83 ... Small diameter portion, 84, 85 ... Drive projection, 84a ... Drive surface, 85a ... Stopper surface , 86 ... Rotating shaft, 87 ... Ratchet lever, 88 ... Arm part, 88a ... Cam surface, 89 ... Spring, 90 ... Ratchet part, 91 ... Ratchet 100 ... Check mechanism, 101 ... Check section, 102 ... Check block, 103 ... Coil spring, 104 ... Check ball, 105 ... Plug, 106 ... Holding piece, 110 ... 4WD release fork, 111 ... 4WD release shift Rod, 112 ... 4WD lock slide sleeve, 110a ... substrate, 110b, 110c ... side plate, 113 ... waiting spring, 114 ... snap ring, 115 ... washer

Claims (2)

A sub-transmission that switches the power to the input shaft to at least two stages, a high speed stage and a low speed stage, and transmits it to the main output shaft;
A friction clutch for transmitting the power of the main output shaft to the sub output shaft;
A rotational drive member fixed to the output shaft of the actuator;
A friction clutch drive cam that is coaxially disposed at one end of the rotation drive member so as to be relatively rotatable, and changes a pressing force of the friction clutch;
A shift cam that is coaxially disposed at the other end of the rotational drive member so as to be relatively rotatable, and that converts the rotational motion of the actuator into a linear motion to shift the sub-transmission;
A mechanism for directly connecting the shift operation of the shift cam said the auxiliary transmission state near Rutoki said main output shaft releasing the pressing force of the low speed stage near I the friction clutch and the secondary output shaft,
A ratchet lever provided around the axis of the normal direction of the outer surface of the rotation drive member as a rotation center, and rotated and switched around the axis to a position interlocked with the friction clutch drive cam and a position interlocked with the shift cam; With
The ratchet lever is located at a high speed position where the shift cam switches the auxiliary transmission to the high speed stage, and the rotary drive member is located at a predetermined position on one side from a control start position with the high speed position as a control origin. When rotating, the rotation around the axis is adjusted to increase the pressing force of the friction clutch in conjunction with the friction clutch driving cam, and the shift cam is at the high speed position and the rotation When the drive member is driven to reciprocate between the control start position and a predetermined position on the other side, the shift cam switches the auxiliary transmission from the high speed stage to the low speed stage in conjunction with the shift cam. And configured to reciprocate between the high speed position,
The direct coupling mechanism maintains the low speed stage of the sub-transmission until the shift cam rotates from the high speed stage position to the low speed stage position and then returns to the high speed stage position from the low speed stage position. A driving force distribution device characterized by the above.   The ratchet lever abuts against a drive claw that meshes with a ratchet groove formed in the shift cam and rotates the shift cam, and a drive pin provided on the friction clutch drive cam, so that the drive claw is brought into contact with the ratchet groove. The driving force distribution device according to claim 1, wherein an arm portion that rotates and retracts to an open position that does not mesh with the driving force is integrally formed.

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