JP6074384B2 - Power transmission device for vehicle - Google Patents

Description

  The present invention relates to a four-link mechanism type vehicle power transmission device.

  Patent Document 1 describes a four-link mechanism type vehicle power transmission device. For example, as shown in FIG. 11A, the vehicle power transmission device converts the rotation of the input shaft 120 connected to the engine into the reciprocating motion of the connecting rod 115, and the reciprocating motion of the connecting rod is output by the one-way clutch 117. This is converted into the rotational motion of the shaft 113. The swing link 118 is connected to the output shaft 113 via a one-way clutch 117.

  FIG. 11B is a diagram showing a schematic configuration of the BB cross section of FIG. 11A, and the large-diameter annular portion 115 a on the input shaft side of the connecting rod 115 is rotatably supported by a bearing 116. Further, the small-diameter annular portion 115b on the output shaft side of the connecting rod 115 is rotatably connected to a projecting side 118b provided on the swing end portion 118a of the swing link 118 by a connecting pin 119. In order for the connecting rod 115 to perform a smooth reciprocating motion, a predetermined amount of clearance is provided between the large-diameter annular portion 115 a of the connecting rod 115 and the bearing 116. Similarly, a predetermined amount of clearance is provided between the small-diameter annular portion 115b of the connecting rod 115 and the connecting pin 119, and between the side surface of the small-diameter annular portion 115b and the inner side surface of the projecting side 118b.

JP 2012-1048 A

  In the configuration of Patent Document 1, when the connecting rod 115 transmits torque by reciprocating motion, rattling may occur in the connecting rod 115 due to the influence of the clearance. Further, when the input shaft 120 is twisted or bent due to the reaction force of torque transmission, for example, the connecting rod 115 may be tilted by the clearance as shown in FIG.

  The contact portion between the small-diameter annular portion 115b and the connecting pin 119 or the contact portion between the small-diameter annular portion 115b and the inner side surface of the projecting side 118b of the swinging end portion 118a due to expansion or reduction of the clearance due to the falling of the connecting rod 115 Repeat separation and contact. Separation or repeated contact at the contact portion generates a collision sound, which causes a decrease in NVH (noise, vibration, harshness).

  In the case where the vehicle power transmission device is configured so as to reduce clearance to reduce rattling, smooth reciprocation of the connecting rod 115 is hindered by an increase in friction at the contact portion.

  An object of the present invention is to provide a vehicle power transmission device capable of correcting the falling of the connecting rod that occurs during torque transmission and improving NVH.

In order to achieve the above object, the present invention described in claim 1 is a vehicle including a transmission unit (20) for transmitting rotation of an input shaft (2) connected to a drive source to an output shaft (3). Power transmission device for
The transmission unit (20)
A swing link (18) supported so as to be swingable with respect to the output shaft (3);
Arranged between the output shaft (3) and the swing link (18), the swing link (18) swings relative to the output shaft (3) when the swing link (18) swings in one direction. A one-way clutch (17) that fixes the link (18) and idles the swing link (18) with respect to the output shaft (3) when the swing link (18) swings in the other direction. ,
An eccentric disk (6) that rotates eccentrically integrally with the input shaft (2);
A connecting rod (15) for connecting the eccentric disk (6) and the swing link (18) and swinging the swing link (18) by the eccentric rotation;
The connecting rod (15)
A large-diameter annular portion (15a) press-fitted into a bearing (16) provided on the outer peripheral surface of the eccentric disk (6);
A small-diameter annular portion (15b) connected via a pin (19) in a state having a predetermined clearance with respect to the swing end portion (18a) of the swing link (18);
A connecting portion for connecting the large-diameter annular portion (15a) and the small-diameter annular portion (15b),
The swing end (18a) of the swing link (18)
A pair of projecting sides (18b) projecting at a predetermined interval so as to sandwich the small-diameter annular portion (15b) in the axial direction are provided,
The pair of projecting sides (18b) includes an inclined surface (51) formed so as to narrow the interval as a part of the facing side faces toward the inner circumferential side,
A vehicle power transmission device is proposed in which the inclined surface (51) is formed at a position where it can come into contact with a part of the small-diameter annular portion (15b).

  Further, in the present invention described in claim 2, in addition to the configuration of claim 1, the inclined surface (51) is located at a position where a part of the small-diameter annular portion (15b) can contact the inclined surface (51). There is proposed a vehicle power transmission device including an inclined portion (52) having an inclination angle similar to the above.

  Further, in the present invention described in claim 3, in addition to the configuration of claim 1 or 2, the inclined surface (51) includes a center of the swing link (18) and a center of the small-diameter annular portion (15b). A vehicle power transmission device is proposed in which the swing link (18) is provided in a region on the one direction side in a swinging direction with respect to a straight line connecting the two.

  Further, in the present invention described in claim 4, in addition to the structure described in any one of claims 1 to 3, the inclined surface (51) is a side surface of the pair of projecting sides (18b) facing each other. Proposed is a vehicle power transmission device that is provided in each of the above.

Further, in the present invention described in claim 5, in addition to the configuration described in any one of claims 1 to 3, the transmission unit (20) includes the input shaft (2) and the output shaft ( 3) provided in parallel to the axial direction of 3),
The input shaft (2) and the output shaft (3) are each supported by a plurality of bearings in the axial direction (40A, 40B, 50A, 50B),
In each of the plurality of transmission units (20), the inclined surface (51) is provided only on one of the side surfaces of the pair of projecting sides (18b) facing each other,
The one side surface is a shaft relative to a projecting side (18b) facing the bearing of the output shaft (3) disposed at a position closest to the transmission unit (20) provided with the inclined surface (51). A vehicle power transmission device is proposed, which is a side surface of a projecting side (18b) disposed at a position having the predetermined interval in the direction.

  According to the structure of Claim 1 and Claim 4, it becomes possible to correct the fall of the connecting rod which arises at the time of torque transmission, and to aim at improvement of NVH.

  According to the structure of Claim 2, in addition to the effect of Claim 1, it becomes possible to reduce the fall of a connecting rod, reducing the surface pressure at the time of contacting with an inclined surface.

  Moreover, according to the structure of Claim 3 and Claim 5, in addition to the effect of Claim 1 or 2, it is possible to reduce a process man-hour and an operator's effort at the time of a process by optimizing a process area. become.

Sectional drawing which shows the structure of the power transmission device for vehicles of this embodiment. The figure which looked at the eccentricity adjustment mechanism, the connecting rod, and the rocking | fluctuation link of the power transmission device for vehicles of FIG. 1 from the axial direction. The figure which shows the change of eccentricity by the eccentricity adjustment mechanism of the power transmission device for vehicles of FIG. The figure which shows the relationship between the change of the eccentric amount by the eccentric amount adjustment mechanism of this embodiment, and the rocking | swiveling angle range of the rocking | fluctuation motion of a rocking | fluctuation link. The figure which shows the structure of the rocking | fluctuation end part of the rocking | fluctuation link of this embodiment, and the small diameter annular part of a connecting rod. The figure which shows the structure which juxtaposed the transmission unit of this embodiment in the axial direction. The figure explaining the structure of the inclined surface and inclination part which considered the deformation | transformation characteristic of the input shaft of this embodiment. The figure explaining the structure of the inclined surface and inclination part which considered the deformation | transformation characteristic of the input shaft of this embodiment. The figure which shows the structural example of the connection part of the small diameter annular part of a connecting rod, and a rocking | fluctuation link in the case of performing torque transmission by a push system in the vehicle power transmission device of this embodiment. The figure which shows the structural example of the connection part of the small diameter annular part of a connecting rod, and a rocking | fluctuation link in the case of performing torque transmission by a pull system in the vehicle power transmission device of this embodiment. The figure explaining the structural example of the conventional power transmission device for vehicles.

  Hereinafter, embodiments of the present invention will be exemplarily described in detail. However, the components described in this embodiment are merely examples, and the technical scope of the present invention is determined by the scope of the claims, and is not limited by the following individual embodiments. Absent. The present invention can be applied to modifications or variations of the following embodiments without departing from the spirit of the present invention.

<Structure of power transmission device for vehicle>
First, with reference to FIG. 1 and FIG. 2, the structure of the vehicle power transmission device of this embodiment will be described. The vehicle power transmission device 1 of the present embodiment has a speed change ratio i (i = rotational speed of the input shaft / rotational speed of the output shaft) of infinity (∞), and the rotational speed of the output shaft can be set to “0”. This is a type of so-called IVT (Infinity Variable Transmission).

  The vehicle power transmission device 1 of this embodiment includes an input shaft 2, an output shaft 3, and six eccentricity adjustment mechanisms 4. The input shaft 2, the output shaft 3, and the eccentricity adjustment mechanism 4 are accommodated in the transmission case 100. The transmission case 100 includes a first side wall portion 101 and a second side wall portion 102 that are spaced apart in the axial direction of the input shaft 2 and the output shaft 3. When viewed from the input shaft 2, the first side wall portion 101 is the upstream side where the driving force is input from the engine, and the second side wall portion 102 is the downstream side. On the other hand, when viewed from the output shaft 3, the first side wall portion 101 is the downstream side where the driving force is output from the engine, and the second side wall portion 102 is the upstream side.

  One end portion on the upstream side of the input shaft 2 is rotatably supported by the first side wall portion 101 via the first input bearing 40A, and the other end portion on the downstream side of the input shaft 2 is the second side wall portion. 102 is rotatably supported by the second input bearing 40B. The input shaft 2 is formed of a hollow member, and is rotationally driven around the rotation center axis P1 in response to a driving force from a traveling drive source such as an engine or a motor.

  Further, one end portion on the downstream side of the output shaft 3 is rotatably supported by the first side wall portion 101 via the first output bearing 50A, and the other end portion on the upstream side of the output shaft 3 is the second end portion. The side wall 102 is rotatably supported via the second output bearing 50B. The output shaft 3 is disposed in parallel to the input shaft 2 at a position separated from the input shaft 2 in the horizontal direction, and transmits driving force to the axle of the automobile through a forward / reverse switching mechanism, a differential gear, and the like.

  Each of the eccentricity adjustment mechanisms 4 is a driving force input unit, and is provided so as to rotate about the rotation center axis P1 of the input shaft 2, and a cam disk 5 as a cam part, an eccentric disk 6 as an eccentric member, And a pinion shaft 7. The turning radius adjusting mechanism (4 to 7) is configured to be able to adjust the turning radius and to rotate about the rotation center axis of the input shaft 2.

  The cam disks 5 have a disk shape, and are provided in pairs on the input shaft 2 so as to be eccentric from the rotation center axis P <b> 1 of the input shaft 2 and rotate integrally with the input shaft 2. Each set of cam disks 5 is set so as to have a phase difference of 60 °, and the six sets of cam disks 5 are arranged so as to make a round in the circumferential direction of the input shaft 2.

  The eccentric disk 6 has a disk shape, and is provided with a receiving hole 6a at a position eccentric from the center P3, and a set of cam disks 5 are rotatably supported so as to sandwich the receiving hole 6a. The eccentric disk 6 rotates eccentrically with the input shaft 2.

  The center of the receiving hole 6a of the eccentric disk 6 is a distance Ra from the rotation center axis P1 of the input shaft 2 to the center P2 of the cam disk 5 (center of the receiving hole 6a) and the center P2 of the cam disk 5 to the eccentric disk 6. The distance Rb to the center P3 is the same. Further, in the receiving hole 6 a of the eccentric disk 6, internal teeth 6 b are formed on the inner peripheral surface sandwiched between the set of cam disks 5.

  The pinion shaft 7 is disposed concentrically with the input shaft 2 in the hollow portion of the input shaft 2, and is supported on the inner peripheral surface of the input shaft 2 via a pinion bearing 7b so as to be relatively rotatable. Further, external teeth 7 a are provided on the outer peripheral surface of the pinion shaft 7. Further, a differential mechanism 8 is connected to the pinion shaft 7.

  Between the pair of cam disks 5 on the input shaft 2, a notch hole 2 a is formed at a location facing the eccentric direction of the cam disk 5 so that the inner peripheral surface communicates with the outer peripheral surface. Accordingly, the outer teeth 7 a of the pinion shaft 7 mesh with the inner teeth 6 b of the receiving holes 6 a of the eccentric disk 6.

  The differential mechanism 8 is a planetary gear mechanism, and includes a sun gear 9, a first ring gear 10 coupled to the input shaft 2, a second ring gear 11 coupled to the pinion shaft 7, the sun gear 9 and the first ring gear 10. The carrier 13 supports a stepped pinion 12 including a large-diameter portion 12a that meshes with the small-diameter portion 12b that meshes with the second ring gear 11 so that the stepped pinion 12 can rotate and revolve. The sun gear 9 of the differential mechanism 8 is connected to a rotating shaft 14a of an eccentricity adjusting drive source 14 composed of an electric motor for driving the pinion shaft 7.

  When the rotational speed of the eccentricity adjusting drive source 14 is the same as the rotational speed of the input shaft 2, the sun gear 9 and the first ring gear 10 rotate at the same speed, and the sun gear 9 and the first ring gear 10 are rotated. The four elements of the second ring gear 11 and the carrier 13 are locked so as not to be relatively rotatable, and the pinion shaft 7 connected to the second ring gear 11 rotates at the same speed as the input shaft 2.

  Further, when the rotational speed of the eccentricity adjusting drive source 14 is made slower than the rotational speed of the input shaft 2, the rotational speed of the sun gear 9 is Ns, the rotational speed of the first ring gear 10 is NR1, and the sun gear 9 and the first ring gear 10 Where j is the gear ratio (number of teeth of the first ring gear 10 / number of teeth of the sun gear 9), the rotation speed of the carrier 13 is (j · NR1 + Ns) / (j + 1). Further, the gear ratio between the sun gear 9 and the second ring gear 11 ((number of teeth of the second ring gear 11 / number of teeth of the sun gear 9) × (number of teeth of the large diameter portion 12a of the stepped pinion 12 / number of teeth of the small diameter portion 12b). ) Is k, the rotation speed of the second ring gear 11 is {j (k + 1) NR1 + (k−j) Ns} / {k (j + 1)}.

  Therefore, when the rotational speed of the eccentricity adjusting drive source 14 is made slower than the rotational speed of the input shaft 2, the rotational speed of the input shaft 2 to which the cam disk 5 is fixed and the rotational speed of the pinion shaft 7 are the same. If they are the same, the eccentric disk 6 rotates together with the cam disk 5. On the other hand, when there is a difference between the rotational speed of the input shaft 2 and the rotational speed of the pinion shaft 7, the eccentric disk 6 rotates the periphery of the cam disk 5 around the center P <b> 2 of the cam disk 5.

  As shown in FIG. 2, the eccentric disk 6 is eccentric with respect to the cam disk 5 so that the distance Ra from P1 to P2 and the distance Rb from P2 to P3 are the same. Therefore, the center P3 of the eccentric disk 6 is positioned on the same line as the rotation center axis P1 of the input shaft 2, and the distance between the rotation center axis P1 of the input shaft 2 and the center P3 of the eccentric disk 6, that is, the eccentric amount R1 is set. It can also be set to “0”.

  A connecting rod 15 is rotatably supported on the outer edge of the eccentric disk 6. The connecting rod 15 has a large-diameter large-diameter annular portion 15a at one end and a small-diameter small-diameter annular portion 15b at the other end. A flange portion (connecting portion) of the connecting rod 15 connects the large-diameter annular portion 15a and the small-diameter annular portion 15b. The large-diameter annular portion 15 a of the connecting rod 15 is supported on the outer edge portion of the eccentric disk 6 via a connecting rod bearing 16. The large-diameter annular portion 15 a is supported on the outer edge portion of the eccentric disk 6 while being press-fitted into the connecting rod bearing 16. The connecting rod 15 connects the eccentric disk 6 and the swing link 18, and swings the swing link 18 by the eccentric rotation of the eccentric disk 6.

  A swing link 18 is connected to the output shaft 3 via a one-way clutch 17 as a one-way rotation prevention mechanism. The swing link 18 is supported so as to be swingable with respect to the output shaft 3. The one-way clutch 17 fixes the swing link 18 with respect to the output shaft 3 and rotates in the other direction when it tries to rotate (swing) in one direction around the rotation center axis P4 of the output shaft 3. When swinging), the swing link 18 is idled with respect to the output shaft 3.

  The swing link 18 is provided with a swing end portion 18a, and the swing end portion 18a is provided with a pair of projecting pieces 18b formed so as to sandwich the small-diameter annular portion 15b in the axial direction. Yes. The pair of projecting pieces 18b are formed with through holes 18c corresponding to the inner diameter of the small-diameter annular portion 15b. The connecting rod 15 and the swing link 18 are connected by inserting the connecting pin 19 into the through hole 18c and the small-diameter annular portion 15b. Further, the swing link 18 is provided with an annular portion 18d. The small-diameter annular portion 15b is connected to the swing end portion 18a of the swing link 18 via a connecting pin 19 in a state having a predetermined clearance.

<Lever crank mechanism (transmission unit)>
Next, a lever crank mechanism 20 (transmission unit) of the vehicle power transmission device of the present embodiment will be described with reference to FIGS. As shown in FIG. 2, in the vehicle power transmission device 1 of the present embodiment, a turning radius adjusting mechanism (4-7) including an eccentricity adjusting mechanism 4, a connecting rod 15, and a one-way clutch 17 (one-way rotation prevention) Mechanism) and the swing link 18 constitute a lever crank mechanism 20 (a transmission unit by a four-bar linkage mechanism). The lever crank mechanism 20 (transmission unit) transmits the rotation of the input shaft 2 connected to the drive source (engine) to the output shaft 3.

  The lever crank mechanism 20 converts the rotational motion of the input shaft 2 into a swing motion of the swing link 18 around the rotation center axis P4 of the output shaft 3. As shown in FIG. 1, the vehicle power transmission device 1 of the present embodiment includes a total of six (No. 1 to No. 6) lever crank mechanisms 20 (transmission units).

  In the lever crank mechanism 20, when the eccentric amount R1 of the eccentric amount adjusting mechanism 4 is not "0", when the input shaft 2 and the pinion shaft 7 are rotated at the same speed, each connecting rod 15 changes its phase by 60 degrees. Then, the swing link 18 is swung by alternately pressing between the input shaft 2 and the output shaft 3 toward the output shaft 3 and pulling toward the input shaft 2.

  Since the one-way clutch 17 is provided between the swing link 18 and the output shaft 3, when the swing link 18 is pushed, the swing link 18 is fixed and the output shaft 3 is swung. When torque due to the swinging motion of the moving link 18 is transmitted and the output shaft 3 rotates and the swinging link 18 is pulled, the swinging link 18 idles and the swinging link 18 swings around the output shaft 3. Torque due to dynamic motion is not transmitted. Since the six eccentricity adjustment mechanisms 4 are arranged by changing the phase by 60 degrees, the output shaft 3 is driven to rotate in turn by the six eccentricity adjustment mechanisms 4.

  Further, in the vehicle power transmission device 1 of the present embodiment, the eccentric amount R1 can be adjusted by the eccentric amount adjusting mechanism 4 as shown in FIG.

  FIG. 3A shows a state in which the eccentric amount R1 is “maximum”, and the rotation center axis P1 of the input shaft 2, the center P2 of the cam disk 5, and the center P3 of the eccentric disk 6 are aligned. The pinion shaft 7 and the eccentric disk 6 are located. In this case, the gear ratio i is minimized. FIG. 3B shows a state in which the eccentric amount R1 is set to “medium” which is smaller than that in FIG. 3A, and FIG. 3C illustrates that the eccentric amount R1 is smaller than that in FIG. Is shown. The gear ratio i is “medium” which is larger than the gear ratio i in FIG. 3A in FIG. 3B, and “large” which is larger than the gear ratio i in FIG. 3B in FIG. Shows the state. FIG. 3D shows a state where the eccentricity R1 is set to “0”, and the rotation center axis P1 of the input shaft 2 and the center P3 of the eccentric disk 6 are located concentrically. In this case, the gear ratio i is infinite (∞).

  FIG. 4 shows the relationship between the change in the eccentric amount R1 by the eccentric amount adjusting mechanism 4 of the present embodiment and the swing angle range of the swing motion of the swing link 18.

  4A shows the case where the eccentric amount R1 is “maximum” in FIG. 3A (when the gear ratio i is the minimum), and FIG. 4B shows the case where the eccentric amount R1 is “ 4 (c) shows the case where the eccentric amount R1 is “small” in FIG. 3 (c) (when the gear ratio i is large). The swing range θ2 of the swing link 18 with respect to the rotational movement (rotation angle θ1) of the eccentricity adjusting mechanism 4 is shown. Here, the distance from the rotation center axis P4 of the output shaft 3 to the connecting point of the connecting rod 15 and the swinging end portion 18a, that is, the center P5 of the connecting pin 19, is the length R2 of the swinging link 18.

  As is apparent from FIG. 4, as the eccentric amount R1 becomes smaller, the swing angle range θ2 of the swing link 18 becomes narrower, and when the eccentric amount R1 becomes “0”, the swing link 18 Will no longer swing.

<Structure of Small Diameter Annulus 15b and Swing End 18a>
Next, a configuration for correcting the falling of the connecting rod 15 will be described. When the large-diameter annular portion 15a of the connecting rod 15 falls on the input shaft 2 side (tilt angle Θ), the tilt angle of the tilt is enlarged (Lc × Θ) by the length (Lc) of the connecting rod 15, and the small diameter The collapse appears larger on the annular portion 15b side. The small-diameter annular portion 15b is smaller in shape than the large-diameter annular portion 15a, and even if the small-diameter annular portion 15b is provided with a configuration for correcting the collapse, the increase in weight is small. Further, the geometrical positional relationship between the swing link 18 and the connecting rod 15 is changed by the operation of the lever crank mechanism 20 (transmission unit), and the connecting rod 15 may be tilted during torque transmission.

  In consideration of these points, it is effective to provide a configuration for correcting the falling of the connecting rod 15 on the small-diameter annular portion 15b and the swing end portion 18a side of the swing link 18. Hereinafter, the structure of the small-diameter annular portion 15b and the swinging end portion 18a will be described as a configuration for correcting the falling of the connecting rod 15.

  FIG. 5 is a view showing the cross-sectional shapes of the swing end 18a of the swing link 18 and the small-diameter annular portion 15b of the connecting rod 15 in the AA section of FIG.

  The swing link 18 connected to the output shaft 3 via the one-way clutch 17 is provided with a swing end 18a. The swing end 18a can sandwich the small-diameter annular portion 15b of the connecting rod 15 in the axial direction. A pair of projecting pieces 18b formed as described above is provided. A hole corresponding to the inner diameter of the small-diameter annular portion 15b is formed in the pair of projecting pieces 18b, and the connecting pin 15 is inserted into the hole and the small-diameter annular portion 15b, thereby connecting the connecting rod 15 to the swing link 18. Are connected to be rotatable.

  In order for the connecting rod 15 to reciprocate smoothly, between the inner diameter of the small-diameter annular portion 15b and the connecting pin 19, between the side surface of the small-diameter annular portion 15b and the inner side surface of the projecting piece 18b, and between the connecting pin 19 and A predetermined amount of clearance (C1, C2, C3) is provided between the holes.

  FIG. 5A is a diagram illustrating a state in which torque transmission is not performed. The swing end portion 18a of the swing link 18 is provided with a pair of projecting sides 18b that protrude with a predetermined interval so as to sandwich the small-diameter annular portion 15b in the axial direction. The pair of projecting pieces 18b includes an inclined surface 51 formed so that a part of the side surfaces facing each other becomes closer to the inner circumferential side in the circumferential direction. The inclined surface 51 is formed at a position where it can come into contact with a part of the small-diameter annular portion 15b. Further, a part of the small-diameter annular portion 15 b of the connecting rod 15 includes an inclined portion 52 having an inclination angle similar to the inclination angle of the inclined surface 51 at a position where it can contact the inclined surface 51. When a part of the small-diameter annular portion 15b includes the inclined portion 52, it is possible to reduce the falling of the connecting rod while reducing the surface pressure when contacting the inclined surface 51.

  In FIG. 5A, the inclined surface formed on the left protrusion 18b is defined as an inclined surface 51a, and the inclined surface formed on the right protrusion 18b is defined as an inclined surface 51b. The inclined surfaces 51a and 51b are collectively referred to as the inclined surface 51.

  Further, a part of the small-diameter annular portion 15b of the connecting rod 15 includes an inclined portion 52 having an inclination angle similar to that of the inclined surface at a position where it can come into contact with the inclined surface 51 formed on the projecting piece 18b. In FIG. 5A, an inclined portion 52a having an inclination angle similar to that of the inclined surface 51a is formed in a part of the left end surface of the small-diameter annular portion 15b at a position where it can come into contact with the inclined surface 51a. In addition, an inclined portion 52b having an inclination angle similar to that of the inclined surface 51b is formed in a part of the right end surface of the small-diameter annular portion 15b at a position where it can contact the inclined surface 51b. The inclined portions 52a and 52b are collectively referred to as the inclined portion 52. The inclination angle Θa of the inclined surface 51a and the inclination angle Θa of the inclined portion 52a are configured to be equal. Further, the inclination angle Θb of the inclined surface 51b and the inclination angle Θb of the inclined portion 52b are configured to be equal. The left and right inclination angles Θa and Θb may be the same, or different inclination angles may be set.

  FIG. 5B is a diagram exemplarily showing a state immediately before the start of torque transmission. The connecting rod 15 moves in the direction indicated by the arrow 55, and the inclined surface 51b of the right side protrusion 18b and the small-diameter annular portion 15b. It will be in the state which begins to contact the inclination part 52b formed in a part of right side end surface. The contact between the inclined surface 51b and the inclined portion 52b allows the connecting rod 15 to move in the direction of the arrow 55 without falling down following the inclination angle of the inclined surface 51b and the inclined portion 52b.

  FIG. 5C is a diagram exemplarily showing a state during torque transmission. The connecting rod 15 further moves in the direction indicated by the arrow 55, and the inclined surface 51b of the right side edge 18b and the small-diameter annular portion. The inclined portion 52a on the right end surface of 15b is in contact with the inclined surface 51a of the left protrusion side 18b and the inclined portion 52a formed on a part of the left end surface of the small-diameter annular portion 15b.

  Due to the contact between the inclined surface 51a and the inclined portion 52a and the contact between the inclined surface 51b and the inclined portion 52b, the connecting rod 15 follows the inclination angle and moves in the direction of the arrow 55 without falling down to transmit torque. Is possible. The inclined surfaces 51a and 51b of the projecting side 18b and the inclined portions 52a and 52b of the small-diameter annular portion 15b function as a fall correction portion that corrects the fall of the connecting rod. Even when a load is applied to the connecting rod 15 and the input shaft 2 during torque transmission, the connecting rod is brought into contact with the inclined surface 51b and the inclined portion 52b, and between the inclined surface 51a and the inclined portion 52a. Fifteen falls can be corrected.

  By correcting (suppressing) the falling of the connecting rod 15, the contact portion between the small-diameter annular portion 15b and the connecting pin 19, or the contact portion between the small-diameter annular portion 15b and the inner side surface of the projecting side 18b of the swinging end portion 18a. As a result, it is possible to suppress the occurrence of a collision sound due to repeated separation and contact, etc., so that it is possible to improve NVH (noise vibration harshness).

<Structure of small-diameter annular part and oscillating end part considering deformation characteristics of input shaft>
FIG. 6 is a diagram schematically showing a state in which a plurality of the six lever crank mechanisms 20 (transmission units) shown in FIG. 1 are provided so as to be juxtaposed in the axial direction of the input shaft 2 and the output shaft 3. . The engine side in FIG. 1 is shown as the upstream side (TOP) where power enters, and the eccentricity adjusting drive source 14 side is shown as the downstream side (BTM) with respect to the engine. In FIG. 6, six lever crank mechanisms 20 (transmission units) are shown as No. 1 to No. 6, respectively.

  In FIG. 6, the lever crank mechanism 20 disposed on the most upstream side (TOP) with respect to the engine is indicated as No. 1 (first lever crank mechanism 20). Further, the lever crank mechanism 20 disposed on the most downstream side (BTM) with respect to the engine is shown as No. 6 (sixth lever crank mechanism 20). Between the first lever crank mechanism 20 and the sixth lever crank mechanism 20, second to fifth lever crank mechanisms 20 are juxtaposed in the axial direction of the input shaft 2 and the output shaft 3.

  The input shaft 2 is supported by a plurality of bearings (first input bearing 40A and second input bearing 40B). The output shaft 3 is supported by a plurality of bearings (first output bearing 50A and second output bearing 50B).

  The eccentricity adjusting mechanism 4, the connecting rod 15, and the swing link 18 constitute a lever crank mechanism 20 (a transmission unit of a four-bar linkage mechanism). FIG. 6 illustrates the tilting of the connecting rod 15. Of the configuration of the lever crank mechanism 20, a swing link 18 to which the connecting rod 15, the large-diameter annular portion 15a, and the small-diameter annular portion 15b are coupled is shown as a representative.

  FIG. 6A shows an unloaded state in which torque transmission by the lever crank mechanism 20 is not performed. FIG. 6B shows a state in which the second lever crank mechanism 20 (No. 2) is transmitting torque. 6B, when a load acts as a reaction force of torque transmission on the input shaft 2 in the vicinity of the large-diameter annular portion 15a of the second lever crank mechanism 20 (No. 2), the input shaft 2 bends and has a large diameter. The annular portion 15a is inclined. When the inclined portion 52a of the small-diameter annular portion 15b and the inclined surface 51a of the projecting side 18b as described in FIG. 5 are not formed, the connecting rod 15 in the second lever crank mechanism 20 (No. 2) during torque transmission. Indicates a tendency to fall to the upstream side (TOP side) with respect to the engine due to the deflection (inclination) of the input shaft 2.

  FIG. 6C shows a state where the fifth lever crank mechanism 20 (No. 5) is transmitting torque. 6C, when a load acts as a reaction force of torque transmission on the input shaft 2 near the large-diameter annular portion 15a of the fifth lever crank mechanism 20 (No. 5), the input shaft 2 bends and has a large diameter. The annular portion 15a is inclined. When the inclined portion 52b of the small-diameter annular portion 15b and the inclined surface 51b of the projecting side 18b as described in FIG. 5 are not formed, the connecting rod 15 in the fifth lever crank mechanism 20 (No. 5) during torque transmission. Indicates a tendency to fall downstream (BTM side) with respect to the engine due to the deflection (inclination) of the input shaft 2.

  Taking FIG. 6B as an example, the length of the input shaft 2 between the first input bearing 40A and the second input bearing 40B (between the bearings) is L1, and the first input bearing 40A and the second input The center position between the bearings 40B is indicated by M. The length of the input shaft 2 from the bearings (first input bearing 40A, second input bearing 40B) to the center position M is L2 (= L1 / 2).

  Due to the deformation characteristics of the input shaft 2 as shown in FIGS. 6B and 6C, the first lever crank mechanism 20 to the first lever mechanism 20 are arranged between the first input bearing 40A and the center position M. The connecting rod 15 of the third lever crank mechanism 20 (No. 1 to No. 3) tends to fall to the TOP side. The connecting rods 15 of the fourth lever crank mechanism 20 to the sixth lever crank mechanism 20 (No. 4 to No. 6) disposed between the second input bearing 40B and the center position M are as follows. Shows a tendency to fall to the BTM side.

  7 and 8 are diagrams for explaining the structures of the inclined surface 51 and the inclined portion 52 in consideration of the deformation characteristics of the input shaft 2. In the configuration described with reference to FIG. 5, the configuration in which the inclined portions 52 are formed on the left and right sides of the small-diameter annular portion 15 b and the inclined surfaces 51 are also formed on the left and right projecting pieces 18 b has been described. In consideration, when the direction in which the connecting rod 15 falls can be specified, the inclined surface 51 and the inclined portion 52 may be provided on either one side. That is, in each of the plurality of lever crank mechanisms 20 (transmission units), the inclined surface 51 may be provided only on one of the side surfaces facing the pair of projecting sides 18b.

  Here, one side surface on which the inclined surface 51 is provided has a predetermined interval in the axial direction with respect to the projecting side 18 b facing the bearing of the output shaft 3 that is disposed closest to the lever crank mechanism 20. It is a side surface of the projecting side 18b arranged at the position.

  For example, when the lever crank mechanism provided with the inclined surface 51 is the second lever crank mechanism 20 (No. 2), the lever crank mechanism 20 (No. 2) is disposed at the closest position. The bearing of the output shaft 3 is the first output bearing 50A. The protrusion 18b facing the first output bearing 50A is the right protrusion 18b of the pair of protrusions. And the protrusion side arrange | positioned in the position which has a predetermined | prescribed space | interval with respect to the right side protrusion edge 18b is the left side protrusion edge 18b, and one side surface in which the inclined surface 51 is provided is the left side protrusion side. It becomes the projecting side 18b.

  FIG. 7 is a view showing a configuration in which an inclined surface 51a and an inclined portion 52a are provided in order to correct the connecting rod 15 falling to the TOP side. FIG. 7A is a diagram showing a state without torque transmission, and an inclined surface 51a is formed on the left projecting piece 18b. The lower end 53b of the right protruding piece 18b is formed at a right angle, and no inclined surface is formed. In addition, an inclined portion 52a having an inclination angle similar to that of the inclined surface 51a is formed in a part of the left end surface of the small-diameter annular portion 15b of the connecting rod 15 at a position where it can contact the inclined surface 51a. The corner portion 54b on the right end surface of the small-diameter annular portion 15b is formed at a right angle, and no inclined portion is formed. Similarly to FIG. 5A, between the inner diameter of the small-diameter annular portion 15b and the connecting pin 19, between the side surface of the small-diameter annular portion 15b and the inner side surface of the projecting piece 18b, and between the connecting pin 19 and the hole portion. A predetermined amount of clearance (C1, C2, C3) is provided between them.

  FIG. 7B is a diagram exemplarily showing a state immediately before the start of torque transmission. The connecting rod 15 moves in the direction indicated by the arrow 55, and the inclined surface 51a of the left side protrusion 18b and the small-diameter annular portion 15b. It will be in the state which begins to contact the inclination part 52a formed in a part of left side end surface.

  FIG. 7C is a view exemplarily showing a state during torque transmission. The connecting rod 15 further moves in the direction indicated by the arrow 55, and the inclined surface 51a of the left side 18b and the small-diameter annular portion. It will be in the state which the inclination part 52a of the left end surface of 15b contacted. For example, as shown in FIG. 6B, when the connecting rod 15 of the second lever crank mechanism 20 (No. 2) that is transmitting torque falls to the TOP side, the contact between the inclined surface 51a and the inclined portion 52a The connecting rod 15 can move in the direction of the arrow 55 without falling down, following the inclination angles of the inclined surface 51a and the inclined portion 52a, and can transmit torque. When the connecting rod 15 falls to the TOP side, the corner portion 54b on the right end surface of the small-diameter annular portion 15b does not come into contact with the right protrusion 18b, so that the inclined surface 51b and the inclined portion as shown in FIG. There is no need to provide 52b.

  FIG. 8 is a view showing a configuration in which an inclined surface 51b and an inclined portion 52b are provided in order to correct the connecting rod 15 falling to the BTM side. FIG. 8A is a diagram showing a state without torque transmission, and an inclined surface 51b is formed on the right protrusion 18b. The lower end 53a of the left projecting piece 18b is formed at a right angle, and no inclined surface is formed. In addition, an inclined portion 52b having an inclination angle similar to that of the inclined surface 51b is formed on a part of the right end surface of the small-diameter annular portion 15b of the connecting rod 15 at a position where it can come into contact with the inclined surface 51b. The corner portion 54a on the left end face of the small-diameter annular portion 15b is formed at a right angle, and no inclined portion is formed. Similarly to FIG. 5A, between the inner diameter of the small-diameter annular portion 15b and the connecting pin 19, between the side surface of the small-diameter annular portion 15b and the inner side surface of the projecting piece 18b, and between the connecting pin 19 and the hole portion. A predetermined amount of clearance (C1, C2, C3) is provided between them.

  FIG. 8B is a diagram exemplarily showing a state immediately before the start of torque transmission. The connecting rod 15 moves in the direction indicated by the arrow 55, and the inclined surface 51b of the right side protrusion 18b and the small-diameter annular portion 15b. It will be in the state which begins to contact the inclination part 52b formed in a part of right side end surface.

  FIG. 8C is a diagram exemplarily showing a state during torque transmission. The connecting rod 15 is further moved in the direction indicated by the arrow 55, and the inclined surface 51b of the right side 18b and the small-diameter annular portion are moved. It will be in the state which the inclination part 52b of the right end surface of 15b contacted. For example, as shown in FIG. 6C, when the connecting rod 15 of the fifth lever crank mechanism 20 (No. 5) that is transmitting torque falls to the BTM side, the contact between the inclined surface 51b and the inclined portion 52b The connecting rod 15 can move in the direction of the arrow 55 without falling down following the inclination angles of the inclined surface 51b and the inclined portion 52b, and can transmit torque. When the connecting rod 15 falls to the BTM side, the corner portion 54a on the left end surface of the small-diameter annular portion 15b does not come into contact with the left side protrusion 18b. Therefore, the inclined surface 51a and the inclined portion as shown in FIG. There is no need to provide 52a.

  According to the configuration shown in FIGS. 7 and 8, a processing region for forming the inclined surface 51 and the inclined portion 52 in accordance with the direction in which the connecting rod 15 is tilted is necessary to correct the tilting of the connecting rod. The range can be limited. In the configuration shown in FIGS. 7 and 8, the inclined surface 51 and the inclined portion 52 may be formed on either the left side or the right side. Therefore, when the inclined surface 51 and the inclined portion 52 are formed on both the left and right sides (FIG. Compared to 5), the number of processing steps is halved. By setting the range of the processing region to an optimum range limited to the required range, it is possible to reduce the processing man-hours and reduce the labor and labor associated with the processing.

<Structure of oscillating end 18a when torque is transmitted by push method>
Next, the structure of the oscillating end 18a when the lever crank mechanism transmits torque by the push method or the pull method will be described. FIG. 9 is a diagram illustrating a configuration example of a connection portion between the small-diameter annular portion 15b and the swing link 18a when torque transmission is performed by the push method. In the push system, the one-way clutch 17 (one-way rotation prevention mechanism) transmits torque to the output shaft 3 when the connecting rod 15 pushes the swing link 18 a in the direction of the arrow 90. When the connecting rod 15 pulls the swing link 18 a in the direction opposite to the direction of the arrow 90, the one-way clutch 17 causes the swing link 18 to idle with respect to the output shaft 3.

  In the configuration shown in FIG. 9, torque is transmitted to the output shaft 3 when the connecting rod 15 pushes the swing link 18a, so that the connecting rod 15 can be brought into contact with the small-diameter annular portion 15b of the connecting rod 15 when the connecting rod 15 is tilted during torque transmission. The inclined surface 51 may be formed in the side surface region S1 of the projecting piece 18b. A projecting piece 18b on the side in which the swing link 18a swings by a pushing operation of the connecting rod 15 with respect to a straight line connecting the center P4 of the swing link and the center P5 of the small-diameter annular portion 15b (center of the connecting pin 19). The inclined surface 51 may be formed in the side surface region S1.

  When torque transmission is performed by the push method, the pulling operation of the connecting rod 15 does not cause the connecting rod 15 to fall down due to torque transmission, so the center P4 of the swing link and the center P5 of the small-diameter annular portion 15b (the center of the connecting pin 19). It is not necessary to form the inclined surface 51 in a region symmetrical to the side surface region S1 with respect to the straight line connecting the two.

<Structure of oscillating end 18a when torque is transmitted by pull method>
Next, the structure of the oscillating end 18a when the lever crank mechanism 20 transmits torque in a pull manner will be described. FIG. 10 is a diagram illustrating a configuration example of a connection portion between the small-diameter annular portion 15b and the swing link 18a when torque transmission is performed by a pull method. In the pull system, the one-way clutch 17 (one-way rotation prevention mechanism) transmits torque to the output shaft 3 when the connecting rod 15 pulls the swing link 18 a in the direction of the arrow 95. When the connecting rod 15 pushes the swing link 18 a in the direction opposite to the direction of the arrow 95, the one-way clutch 17 idles the swing link 18 with respect to the output shaft 3.

  In the configuration of FIG. 10, torque is transmitted to the output shaft 3 when the connecting rod 15 pulls the swing link 18a, so that the connecting rod 15 can be brought into contact with the small-diameter annular portion 15b of the connecting rod 15 when the connecting rod 15 is tilted during torque transmission. The inclined surface 51 may be formed in the side surface region S2 of the projecting piece 18b. A protruding piece 18b on the side in which the swing link 18a swings by a pulling operation of the connecting rod 15 with respect to a straight line connecting the center P4 of the swing link and the center P5 of the small-diameter annular portion 15b (the center of the connecting pin 19). The inclined surface 51 may be formed in the side surface region S2.

  When the torque transmission is performed by the pull method, the connecting rod 15 is not tilted by the torque transmission when the connecting rod 15 is pushed. Therefore, the center P4 of the swing link and the center P5 of the small-diameter annular portion 15b (the center of the connecting pin 19). It is not necessary to form the inclined surface 51 in a region symmetric with respect to the side surface region S2 with respect to the straight line connecting).

  According to the configuration shown in FIG. 9 and FIG. 10, the projecting piece that can contact the small-diameter annular portion 15 b of the connecting rod 15 when torque transmission is performed by the push method or when torque transmission is performed by the pull method. The area | region which processes the inclined surface 51 to the side surface area | region (S1 or S2) of 18b can be limited.

  In the configuration shown in FIGS. 9 and 10, depending on the torque transmission method (push method or pull method) using the lever crank mechanism, either the side surface region S1 or the side surface region S2 of the projecting side 18b has an inclined surface. Since 51 may be formed, the number of processing steps is ½ compared to the case where the inclined surface 51 is formed in both the side regions S1 and S2 (FIG. 5).

  In the configuration shown in FIG. 7 and FIG. 8 described above, the position where the lever crank mechanism is arranged, for example, No. in FIG. 1-No. 3 or a No. 3 position. 4-No. 6, the processing region in which the inclined surface 51 and the inclined portion 52 are formed can be limited to either the left side or the right side. The processing man-hour when the inclined surface 51 and the inclined portion 52 are formed on either the left side or the right side is 1 in comparison with the processing man-hour when the inclined surface 51 and the inclined portion 52 are formed on both the left and right sides (FIG. 5). / 2.

  By combining the limitation of the machining area based on the arrangement position of the lever crank mechanism 20 and the limitation of the machining area based on the torque transmission method by the leverage crank mechanism, the machining man-hours form the inclined surface 51 and the inclined portion 52 on both the left and right sides. In addition, the man-hour required for forming the inclined surface 51 in the side regions S1 and S2 of the projecting side 18b is ¼.

  According to the configuration of the present embodiment, it is possible to correct the falling of the connecting rod that occurs during torque transmission and to improve NVH. In addition, by setting the range of the processing area to an optimum range limited to the required range, it is possible to reduce the processing man-hours and reduce the labor and labor associated with the processing.

  DESCRIPTION OF SYMBOLS 1 ... Vehicle power transmission device, 2 ... Input shaft, 3 ... Output shaft, 4 ... Eccentricity adjustment mechanism, 5 ... Cam disc, 6 ... Eccentric disc, 6a ... Receiving hole, 6b ... Internal tooth, 7 ... Pinion shaft, 7a ... External teeth, 7b ... Pinion bearing, 14 ... Eccentricity adjusting drive source, 14a ... Rotating shaft, 15 ... Connecting rod, 15a ... Large diameter annular part, 15b ... Small diameter annular part, 16 ... Connecting rod bearing, 17 ... One way Clutch, 18 ... swing link, 20 ... lever crank mechanism (transmission unit), 40A ... first input bearing, 40B ... second input bearing, 50A ... second output bearing, 50B ... second output bearing, DESCRIPTION OF SYMBOLS 100 ... Transmission case, 101 ... 1st side wall part, 102 ... 2nd side wall part

Claims (5)

A vehicle power transmission device including a transmission unit (20) for transmitting rotation of an input shaft (2) connected to a drive source to an output shaft (3),
The transmission unit (20)
A swing link (18) supported so as to be swingable with respect to the output shaft (3);
Arranged between the output shaft (3) and the swing link (18), the swing link (18) swings relative to the output shaft (3) when the swing link (18) swings in one direction. A one-way clutch (17) that fixes the link (18) and idles the swing link (18) with respect to the output shaft (3) when the swing link (18) swings in the other direction. ,
An eccentric disk (6) that rotates eccentrically integrally with the input shaft (2);
A connecting rod (15) for connecting the eccentric disk (6) and the swing link (18) and swinging the swing link (18) by the eccentric rotation;
The connecting rod (15)
A large-diameter annular portion (15a) press-fitted into a bearing (16) provided on the outer peripheral surface of the eccentric disk (6);
A small-diameter annular portion (15b) connected via a pin (19) in a state having a predetermined clearance with respect to the swing end portion (18a) of the swing link (18);
A connecting portion for connecting the large-diameter annular portion (15a) and the small-diameter annular portion (15b),
The swing end (18a) of the swing link (18)
A pair of projecting sides (18b) projecting at a predetermined interval so as to sandwich the small-diameter annular portion (15b) in the axial direction are provided,
The pair of projecting sides (18b) includes an inclined surface (51) formed so as to narrow the interval as a part of the facing side faces toward the inner circumferential side,
The vehicle power transmission device, wherein the inclined surface (51) is formed at a position where it can come into contact with a part of the small-diameter annular portion (15b).   A part of said small diameter annular part (15b) is provided with the inclined part (52) provided with the same inclination angle as the said inclined surface (51) in the position which can contact the said inclined surface (51). Item 4. The vehicle power transmission device according to Item 1.   The inclined surface (51) is the one of the directions in which the swing link (18) swings with respect to a straight line connecting the center of the swing link (18) and the center of the small-diameter annular portion (15b). The vehicular power transmission device according to claim 1, wherein the vehicular power transmission device is provided in a direction-side region.   The vehicle power transmission device according to any one of claims 1 to 3, wherein the inclined surfaces (51) are respectively provided on side surfaces of the pair of projecting sides (18b) facing each other. A plurality of the transmission units (20) are provided so as to be juxtaposed in the axial direction of the input shaft (2) and the output shaft (3),
The input shaft (2) and the output shaft (3) are each supported by a plurality of bearings in the axial direction (40A, 40B, 50A, 50B),
In each of the plurality of transmission units (20), the inclined surface (51) is provided only on one of the side surfaces of the pair of projecting sides (18b) facing each other,
The one side surface is a shaft relative to a projecting side (18b) facing the bearing of the output shaft (3) disposed at a position closest to the transmission unit (20) provided with the inclined surface (51). 4. The vehicle power transmission device according to claim 1, wherein the vehicle power transmission device is a side surface of a projecting side (18 b) disposed at a position having the predetermined interval in the direction. 5.

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