JP2008089051A - Planetary gear device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a planetary gear device enabling improvement of workability and stiffness, in a carrier for supporting a long pinion and a short pinion with different length. <P>SOLUTION: The carrier 2 configures a frame body 3 by providing a center plate 10 and fixing a peripheral part 12b of a second carrier plate 12 and a peripheral part 11b of a first carrier plate 11 to both axial sides of a substrate part 10a of the center plate 10. Three members including the center plate 10, the second carrier plate 12 and the first carrier plate 11 respectively support both end parts of the short pinion 17 and the long pinion 15. The three members are respectively formed in press-workable cup shapes and thus stiffness is improved and cost and weight can be reduced. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a planetary gear device used in, for example, an automatic transmission for a vehicle, and more particularly to a Ravigneaux type planetary gear device including a carrier having a short pinion and a long pinion meshing with the short pinion.

  In general, for example, an automatic transmission provided in an automobile or the like uses a planetary gear device formed by integrally combining two planetary gears called Ravigneaux type. This Ravigneaux type planetary gear device is composed of, for example, four rotating elements, that is, two sun gears rotatably supported on an input shaft, a carrier, and a ring gear. A plurality of short pinions arranged on the same circumference so as to mesh with the sun gear, and a plurality of long pinions arranged on the same circumference so as to mesh with the short pinion, the second sun gear, and the ring gear. It is comprised by supporting so that rotation is possible.

  By the way, a planetary gear carrier is generally configured by supporting a plurality of pinions by two side plates and connecting the two side plates by a carrier bridge. The Ravigneaux type planetary gear device as described above is used. In this case, it is necessary to support the short pinion and the long pinion, that is, two types of pinions having different lengths are supported.

  As such a Ravigneaux type planetary gear device, one side plate supports the end portions of both pinions, and the other side plate forms a thick wall portion, and the other side plate forms the end portion of the long pinion. And a carrier configured to support the end portion of the short pinion (of the pinion shaft) at the thick portion (see Patent Document 1). In this case, a carrier bridge is extended from each of the two side plates of the carrier, and a brake hub for locking the rotation of the carrier is sandwiched between the carrier bridges. Connected.

  On the other hand, a Ravigneaux type planetary gear device is also proposed in which two side plates are pressed into a cup shape and a carrier is formed by fixing the two cup side plates (Patent Document 2). reference). In this, two cup-shaped members are fixed so that the opening direction is the same direction, that is, the bottom portion of one cup-shaped member has the same role as the thick portion, that is, a short pinion (pinion It serves to support the end of the shaft at the axially central portion of the carrier. Also, the cup-shaped member that supports the end of the short pinion cuts a part of the drum-shaped part, and then tilts the cut part in a direction perpendicular to the axial direction, A portion for supporting the end of the shaft is formed, that is, the same member also serves as a side plate for supporting the long pinion.

JP 2006-125425 A Japanese Patent No. 2852819

  However, since the planetary gear device of Patent Document 1 forms a thick portion on the side plate of the carrier as described above, it supports both pinions while maintaining a relatively strong rigidity (compared to that of Patent Document 2). However, it is necessary to manufacture by cutting, which is not good in workability and hinders cost reduction. In addition, since the thick portion is formed on the carrier, it is difficult to reduce the weight, and there is a problem that the inertia with respect to the rotational drive is large, which hinders the improvement of the controllability especially at the time of shifting.

  On the other hand, since the carrier of the planetary gear device shown in Patent Document 2 is composed of two cup-shaped members as described above, it can be formed by pressing, and the workability is improved (compared to that of Patent Document 1). Although it is possible to cut a part of the drum-shaped part to form the support part of the long pinion, the number of presses is increased, and the rigidity of the cup-shaped member, particularly the support part of the long pinion There was a problem that became weak.

  Further, since the drum portion of the cup-shaped member is notched and the long pinion is penetrated, it is difficult to fix a brake, a clutch hub or the like on the outer peripheral side of the drum portion, and the end portions of the two cup-shaped members In other words, a brake or clutch hub is fixed to the end of the Ravigneaux type planetary gear device. For this reason, the power transmission path between the carrier and the hub becomes long, and in particular, when the brakes and clutches are engaged, twisting is likely to occur between the hub and the carrier, that is, as an assembly of the hub and the carrier. There was a problem that the rigidity became weak.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a planetary gear device that can improve workability and rigidity in a carrier that supports a long pinion and a short pinion having different lengths.

The present invention according to claim 1 (see, for example, FIGS. 1 to 9) includes a carrier (2) that rotatably supports a short pinion (17) and a long pinion (15) meshing with the short pinion. In the planetary gear device (1),
The carrier (2)
A central member (10) having a substrate portion (10a) for supporting one end of the pinion shaft (16) of the short pinion (17);
A bottom plate portion (12a) and a peripheral edge portion (12b) extending integrally from the periphery of the bottom plate portion in one axial direction (X1 direction), and an axis of the substrate portion (10a) of the central member (10) One side member (12) which is disposed on one side in the direction (X2 direction) and supports one end of the pinion shaft (14) of the long pinion (15) by the bottom plate portion (12a);
A bottom plate portion (11a) and a peripheral edge portion (11b) extending integrally from the periphery of the bottom plate portion toward the other side in the axial direction (X2 direction), and the axis of the substrate portion (10a) of the central member (10) The other end of the pinion shaft (16) of the short pinion (17) and the other end of the pinion shaft (14) of the long pinion (15) are arranged on the other side of the direction (X1 direction). 11a), and the other side member (11) supported by
The peripheral part (12b) of the one side member (12) and the peripheral part (11b) of the other side member (11) on both sides in the axial direction (X1-X2 direction) of the substrate part (10a) of the central member (10). To constitute a frame that supports the short pinion (17) and the long pinion (15),
This is in the planetary gear device (1).

According to a second aspect of the present invention (see, for example, FIGS. 1 to 9), the central member (10) is axially integrated from the periphery of the bottom plate portion (10a) with the base plate portion (10a) as a bottom plate portion. Having a peripheral edge (10b) extending to
It exists in the planetary gear apparatus (1) of Claim 1 characterized by the above-mentioned.

According to a third aspect of the present invention (see, for example, FIGS. 1 to 9), the central member (10) is related to the friction member (21) of which the peripheral edge (10b) is the first friction engagement element (20). Consisting of a matching hub member,
It exists in the planetary gear apparatus (1) of Claim 2 characterized by the above-mentioned.

In the present invention according to claim 4 (see, for example, FIGS. 1, 5, and 9), the peripheral portion (10b) of the central member (10) is the same as the peripheral portion (12b) of the one side member (12). Arranged on the outer circumference,
The other side member (11) comprises a hub member whose peripheral edge portion (11b) engages with the friction member (31) of the second friction engagement element (30).
It exists in the planetary gear apparatus (1) of Claim 2 or 3 characterized by the above-mentioned.

According to the fifth aspect of the present invention (see, for example, FIGS. 1, 5, and 9), the peripheral portion (12b) of the one side member (12) has an outer diameter of the long pinion (15). (12b) provided with a notch (12e) that protrudes,
A ring gear (8) disposed on the outer peripheral side of the peripheral edge (12b) of the one side member (12) and meshing with the long pinion (15);
It exists in the planetary gear apparatus (1) in any one of Claim 1 thru | or 4 characterized by the above-mentioned.

According to the sixth aspect of the present invention (see, for example, FIGS. 1 to 9), the central member (10), the one side member (12), and the other side member (11) can be formed by pressing.
The planetary gear device (1) according to any one of claims 1 to 5, wherein the planetary gear device (1) is provided.

  In addition, although the code | symbol in the said parenthesis is for contrast with drawing, this is for convenience for making an understanding of invention easy, and has no influence on the structure of a claim. It is not a thing.

  According to the first aspect of the present invention, the center member is disposed, and the peripheral portion of the one-side member and the peripheral portion of the other-side member are fixed to both sides in the axial direction of the substrate portion of the central member. Thus, the rigidity of the carrier frame can be increased.

  In addition, since one end of the pinion shaft of the short pinion is supported by the substrate portion of the central member, it is not necessary to form a thick portion as in the prior art, and in particular the one side member and the other side member It is only necessary to form a peripheral edge portion extending in the axial direction integrally from the periphery of the bottom plate portion, and other than the cutting work for obtaining the accuracy of the fixing portion with respect to the three members of the central member, the one side member, and the other side member. Therefore, it is not necessary to perform the cutting process, the workability can be improved, and the cost can be reduced. Furthermore, since it is not necessary to form a thick portion, the weight can be reduced, and the controllability of the automatic transmission on which the planetary gear device is mounted can be improved.

  In addition, since both ends of the short pinion and the long pinion are respectively supported by the central member, the one side member, and the other side member, for example, the drum portion of the cup-shaped member is cut out and the short pinion and the long pinion are formed by one member. It is not necessary to support one end of the carrier, and the workability can be improved (that is, the number of presses can be reduced), while the rigidity of the carrier frame can be increased.

  Further, when a clutch that transmits rotation to the carrier and a brake that locks the rotation of the carrier are provided on the outer peripheral side of the planetary gear device, for example, the hub member is fixed to the substrate portion of the central member, The peripheral edge or the peripheral edge of the other side member can be used as a hub member, and the transmission path between the carrier and the hub can be shortened, that is, the rigidity of the hub member and the carrier can be increased. it can.

  According to the second aspect of the present invention, since the central member has the base plate portion as the bottom plate portion and has a peripheral edge portion extending integrally in the axial direction from the periphery of the bottom plate portion, the central member is formed in a cup shape. The rigidity of the central member itself can be increased.

  According to the third aspect of the present invention, since the central member includes the hub member whose peripheral portion engages with the friction member of the first friction engagement element, the cup-shaped peripheral portion for increasing rigidity is provided as the hub member. The automatic transmission on which the planetary gear device is mounted can be made compact.

  According to the fourth aspect of the present invention, since the peripheral portion of the other side member is formed of the hub member that engages with the friction member of the second friction engagement element, that is, the rigidity of the other side member is increased and the carrier bridge is provided. The cup-shaped peripheral portion that serves as the above can be shared as a hub member, and the automatic transmission on which the planetary gear device is mounted can be made compact.

  According to the fifth aspect of the present invention, the peripheral portion of the one side member is provided with a notch portion that projects the outer diameter of the long pinion from the peripheral portion, and the outer peripheral side of the peripheral portion of the one side member Since the ring gear meshing with the long pinion is disposed, the one side member and the ring gear can be disposed without crossing the members.

  According to the sixth aspect of the present invention, the central member, the one side member, and the other side member can be formed by pressing, and the cost of the planetary gear device can be reduced.

  Embodiments according to the present invention will be described below with reference to FIGS.

  A planetary gear device 1 according to an embodiment of the present invention is a so-called Ravigneaux type planetary gear that is provided in, for example, an automatic transmission mounted on an automobile and has four rotating elements.

  As shown in FIG. 1, the planetary gear device 1 is composed of four rotating elements including two sun gears 6 and 7, a carrier 2, and a ring gear 8 that are rotatably supported on the input shaft 5. A plurality of short pinions 17 arranged on the same circumference so as to mesh with the sun gear 6, and arranged on the same circumference so as to mesh with the short pinion 17, the sun gear 7 and the ring gear 8. The plurality of long pinions 15 are rotatably supported.

  As for the input shaft 5, the flange part 5e is integrally formed by the shaft-shaped member formed in the hollow shaft shape. An oil passage 5a for supplying lubricating oil is formed in the hollow portion of the input shaft 5, and 5b, 5c, 5d communicating the oil passage 5a and the outer surface of the input shaft 5 are provided. Is provided.

  The sun gear 6 is a hollow shaft-shaped member having a large-diameter portion 6g and a small-diameter portion 6s, and a tooth surface is formed on the outer peripheral surface of the large-diameter portion 6g. In the large-diameter portion 6g, the short pinion 17 and Meshed. The sun gear 6 is rotatably supported by the input shaft 5 penetrating through the hollow portions of the large diameter portion 6g and the small diameter portion 6s. Specifically, the flange portion of the input shaft 5 at the large diameter portion 6g. The bearing 45 and the shaft portion of the input shaft 5 are rotatably supported via a bush 42 between the bearing 45 and the shaft 5e. Further, oil passages 6a, 6b, 6c and 6d are provided in the large diameter portion 6g and the small diameter portion 6s of the sun gear 6 so as to connect the inner peripheral surface and the outer peripheral surface in order to supply lubricating oil.

  The sun gear 7 is a hollow shaft-shaped member having a large-diameter portion 7g and a small-diameter portion 7s, and a tooth surface is formed on the outer peripheral surface of the large-diameter portion 7g. In the large-diameter portion 7g, the long pinion 15 and Meshed. The sun gear 7 is rotatably supported by the small diameter portion 6s of the sun gear 6 that passes through the hollow portions of the large diameter portion 7g and the small diameter portion 7s. A bearing 46 and a small-diameter portion 6s of the sun gear 6 are rotatably supported via a bush 43 between the large-diameter portion 6g. Further, oil passages 7a and 7b are provided in the small diameter portion 7s of the sun gear 7 so as to communicate the inner peripheral surface and the outer peripheral surface in order to supply lubricating oil.

  The ring gear 8 includes a gear portion 8a and a flange portion 8b, which are internal gears formed in a hollow shaft shape. The gear portion 8a is engaged with the flange portion 8b by a spline provided on the inner peripheral side on the X2 direction side, the movement in the axial direction is restricted by the snap ring 52, and a parking gear is provided on the outer peripheral side on the X2 direction side. 8c is formed.

  As shown in FIGS. 1 to 5, the carrier 2 includes a frame 3 having a center plate (center member) 10, a first carrier plate (other side member) 11, and a second carrier plate (one side member) 12. As shown in FIG. 1 and FIGS. 6 to 9, three sets of a short pinion shaft 16 and a long pinion shaft 14 supported by the frame body 3 and a short pinion shaft 16 are rotatably supported. The short pinion 17 and the long pinion 15 rotatably supported by the long pinion shaft 14 are configured.

  The short pinion 17 is an external gear formed in a hollow shaft shape, and is rotatably supported on the short pinion shaft 16 penetrating the hollow portion via a bearing 51. As described above, the sun gear is provided. 6 gear portion 6g.

  The short pinion shaft 16 is supported by a hole 11e of the first carrier plate 11 which will be described in detail later on the X1 direction side, and by a hole 10d of the center plate 10 which will be described in detail later on the X2 direction side. A washer 48 a is disposed between the first carrier plate 11 and the short pinion 17, and a washer 48 b is disposed between the center plate 10 and the short pinion 17. The short pinion shaft 16 is provided with oil passages 16a and 16b for supplying lubricating oil.

  The long pinion 15 is an external gear formed in a hollow shaft shape, and is supported rotatably on a long pinion shaft 14 penetrating through the hollow portion via a bearing made up of a needle 41 and a cage 44. As described above, the gear portion 7g of the sun gear 7 and the ring gear 8 are engaged with each other.

  The long pinion shaft 14 is supported by a hole 11d of the first carrier plate 11 on the X1 direction side, and by a hole 12c of the second carrier plate 12 described in detail later on the X2 direction side. A washer 47 a is disposed between the first carrier plate 11 and the long pinion 15, and a washer 47 b is disposed between the second carrier plate 12 and the long pinion 15. The long pinion shaft 14 is provided with oil passages 14a and 14b for supplying lubricating oil.

  As shown in FIGS. 1 to 3, the center plate 10 has a substrate portion 10a formed in a hollow disk shape, and the substrate portion 10a as a bottom plate portion, and is integrally extended from the periphery to the X2 direction side. It is comprised from the peripheral part 10b. The substrate portion 10a is formed with a hollow portion through which the input shaft 5 passes, and a notch portion 10g is formed at a portion where the long pinion 15 is disposed, and the hole portion 10d that supports the short pinion shaft 16 described above, Three elongated holes 10e for fixing the peripheral edge 12b of the second carrier plate 12 are formed in three places. A spline 10c that engages with an inner friction plate 21 of a brake (first friction engagement element) 20, which will be described in detail later, is formed on the outer peripheral surface 10b. Further, the substrate portion 10a and the peripheral portion 10b have an L-shaped cross section, that is, the center plate 10 has a cup shape with the substrate portion 10a as a bottom plate portion, and is formed to have high rigidity. ing.

  As shown in FIGS. 1 and 4, the first carrier plate 11 includes a bottom plate portion 11a formed in a hollow disk shape, and a peripheral portion 11b integrally extending from the periphery of the bottom plate portion 11a to the X2 direction side. It is composed of The bottom plate portion 11a is formed with a hollow portion through which the input shaft 5 penetrates, and a hole portion 11d that supports the long pinion shaft 14 and a hole portion 11e that supports the short pinion shaft 16 are formed in three places, respectively. Has been. A spline 11c that engages with an inner friction plate 31 of a clutch (second friction engagement element) 30, which will be described in detail later, is formed on the peripheral edge portion 11b. Further, the bottom plate portion 11a and the peripheral edge portion 11b have an L-shaped cross section, that is, the first carrier plate 11 has a cup shape, and is formed to have high rigidity.

  By the way, in the automatic transmission provided with the planetary gear device 1 according to the embodiment of the present invention, a wet multi-plate brake 20 and a clutch 30 are provided on the outer peripheral side of the planetary gear device 1. The brake 20 is located on the outer peripheral side of the peripheral edge portion 10b of the center plate 10 constituting the frame 3 of the carrier 2 provided in the planetary gear device 1, and the transmission case (not shown) of the automatic transmission. An outer friction plate 23 engaged with a spline (not shown) formed on the inner peripheral surface of the inner friction plate 21 and an inner friction plate 21 engaged with the spline 10c of the center case 10 are not shown. By a piston (not shown) that is pressed and driven by the action of the above, it can be locked to the case.

  The clutch 30 is located on the outer peripheral side of the peripheral edge portion 11b of the first carrier plate 11 constituting the frame 3 of the carrier 2 provided in the planetary gear device 1, and is included in the clutch drum 34 of the automatic transmission. The outer friction plate 32 engaged with the spline 33 formed on the peripheral surface and the inner friction plate 31 engaged with the spline 11c of the first carrier plate 11 are pressed by the action of a hydraulic servo (not shown). The piston 35 is configured to be engageable with the clutch drum 34 by the driven piston 35.

  As shown in FIGS. 1 and 5, the second carrier plate 12 includes a bottom plate portion 12a formed in a hollow disc shape, and a peripheral portion 12b integrally extending from the periphery of the bottom plate portion 12a to the X1 direction side. The cross-sectional shape is L-shaped by the cup-shaped shape, that is, the bottom plate portion 12a and the peripheral edge portion 12b, and is a shape for increasing rigidity. The bottom plate portion 12a is formed with a hollow portion through which the input shaft 5 passes, and a boss portion 12d is formed integrally extending from the periphery of the hollow portion toward the X2 direction. 7 is rotatably supported, that is, is rotatably supported with respect to the input shaft 5. Further, the flange portion 8 b of the ring gear 8 is configured to be rotatable relative to the flange portion 8 b via the washer 53 and is not in contact therewith. The bottom plate portion 12a has three holes 12c and 12f that support the long pinion shaft 14, respectively.

  Since the peripheral edge portion 12b is on the inner peripheral side with respect to the input shaft 5 with respect to the outer diameter of the long pinion 15, the notch portion 12e for projecting the outer diameter portion of the long pinion 15 is provided. The long pinion 15 is configured to be able to mesh with the ring gear 8.

  When assembling the carrier 2 of the plantary gear device 1 according to the present invention, first, the center plate 10 is formed into a cup shape by pressing and a hole 10d for supporting the short pinion shaft 16 is formed. Therefore, prior to the drilling step described later, a temporary hole having a smaller diameter than the hole 10d is formed at the same position as the hole 10d. Similarly, the first carrier plate 11 is also formed into a cup shape by pressing, and has a hole portion 11e for supporting the short pinion shaft 16 and a hole portion 11d for supporting the long pinion shaft 14. In order to drill, prior to the drilling process described later, temporary holes having a smaller diameter than the holes 11e and 11d are formed at the same positions as the holes 11e and 11d. deep. Similarly, the second carrier plate 12 is also formed into a cup shape by pressing, and a hole 12c and a hole 12f for supporting the long pinion shaft 14 are formed. Prior to this, a temporary hole having a smaller diameter than that of the hole 12c and the hole 12f is formed at the same position as the hole 12c and the hole 12f.

  Next, as shown in FIG. 2, the end portion of the peripheral edge portion 12b of the second carrier plate 12 is inserted into the elongated hole portion 10e of the center plate 10 and is aligned in the circumferential direction in accordance with the temporary hole, welding, etc. It adheres by. Similarly, as shown in FIG. 3, the first carrier plate 11 and the center plate 10 are aligned with the temporary holes in the circumferential direction, and the connection portion 10 f of the center plate 10 and the first carrier plate 11 are aligned. The end of the peripheral edge 11b is fixed by welding or the like.

  Thereafter, the process proceeds to the step of drilling each hole, and in order to accurately assemble the short pinion shaft 16 and the long pinion shaft 14 with respect to the axial direction, the fixed center plate 10, first carrier plate 11, Two holes 10d, 11d, 11e, 12c, and 12f are formed in the carrier plate 12 with high accuracy. Thereby, as shown in FIG.4 and FIG.5, the assembly of the frame 3 is completed.

  2 and 3 are diagrams showing a progress state during the assembly of the center plate 10, the first carrier plate 11, and the second carrier plate 12, and originally the temporary holes are formed. However, for convenience of explanation, the holes 10d, 11d, 11e, 12c, and 12f are illustrated as being accurately drilled.

  Next, as shown in FIGS. 8 and 9, in the frame 3, the bottom plate portion 11 a and the second carrier plate are inserted into the center portion of the bottom plate portion 11 a of the first carrier plate 11, that is, from the hole through which the input shaft 5 and the like pass. The long pinion 15 is inserted between the bottom plate 12a and the hole 11d of the first carrier plate 11, the hole of the long pinion 15, and the hole 12c of the second carrier plate 12 are coaxial. Align so that The long pinion shaft 14 is inserted into the hole having the same axial center, and one end portion of the long pinion shaft 14 and the hole portion 11d are connected, and the other end portion of the long pinion shaft 14 and the hole portion 12c are connected. Each sticks. Further, the two long pinions 15 are assembled by the same method, and all the three long pinions 15 are assembled. Next, the sun gear 7 is inserted from the center portion of the bottom plate portion 11a of the first carrier plate 11 (that is, from the left side to the right side in FIG. 1), and the sun gear 7 is inserted into the three long pinions 15. Mesh with each other.

  Next, in the frame 3, a short pinion 17 is inserted from the center portion of the bottom plate portion 11 a of the first carrier plate 11 between the bottom plate portion 11 a and the substrate portion 10 a of the center plate 10, and the first carrier plate 11 holes 11e, short pinion 17 and center plate 10 hole 10d are aligned with each other so as to be in the same axial center and mesh with long pinion 15. The short pinion shaft 16 is inserted into the hole having the same axial center, and one end of the short pinion shaft 16 and the hole 11e are fixed, and the other end of the short pinion shaft 16 and the hole 10d are fixed to each other. To do. In addition, two short pinions 17 are assembled in the same manner, and all three short pinions 17 are assembled.

  Thereafter, the sun gear 6 is inserted from the center portion of the bottom plate portion 11a of the first carrier plate 11 (that is, from the left side to the right side in FIG. 1) and is engaged with the three short pinions 17 respectively. Then, the gear portion 8a of the ring gear 8 is combined with the long pinion 15 while being engaged, and the flange portion 8b is spline-engaged with the gear portion 8a of the ring gear 8 so as to be prevented from coming off by the snap ring 52, and the carrier 2 of the planetary gear device 1 is Assembly is complete.

  As described above, according to the planetary gear device 1 according to the present invention, the center plate 10 is disposed, and the peripheral portion 12b of the second carrier plate 12 and the first carrier plate 11 are disposed on both sides in the axial direction of the substrate portion 10a of the center plate 10. Since the frame 3 of the carrier 2 is configured by fixing the peripheral edge portion 11b, the rigidity of the carrier 2 as the frame 3 can be increased.

  Further, since one end of the pinion shaft 16 of the short pinion 17 is supported by the substrate portion 10a of the center plate 10, it is not necessary to form a thick portion as in the prior art, and particularly the first carrier plate. 11 and the second carrier plate 12 only need to form a peripheral edge portion extending in the axial direction integrally from the periphery of the bottom plate portion, and these three members of the center plate 10, the first carrier plate 11, and the second carrier plate 12 are sufficient. On the other hand, it is possible to eliminate the need to perform a cutting process other than the cutting process for increasing the accuracy of the fixed portion, improve the workability, and reduce the cost. Furthermore, since it is not necessary to form a thick portion, the weight can be reduced, and the controllability of the automatic transmission on which the planetary gear device 1 is mounted can be improved.

  Further, the three members of the center plate 10, the first carrier plate 11, and the second carrier plate 12 support the both ends of the short pinion 17 and the long pinion 15, respectively. It is not necessary to support one end of the short pinion and the long pinion by one member, and the workability can be improved (that is, the number of presses can be reduced). The rigidity can be increased.

  Further, when the clutch 30 for transmitting the rotation to the carrier 2 and the brake 20 for locking the rotation of the carrier 2 are provided on the outer peripheral side of the planetary gear device 1, for example, the hub member is fixed to the substrate portion 10a of the center plate 10. Or the peripheral edge portion 12b of the second carrier plate 12 or the peripheral edge portion 11b of the first carrier plate 11 can be used as a hub member, and the transmission path between the carrier 2 and the hub can be shortened. The rigidity as the assembly of the hub member and the carrier 2 can be increased.

  Further, since the center plate 10 has the base plate portion 10a as a bottom plate portion and has a peripheral edge portion 10b integrally extending from the periphery of the bottom plate portion 10a in the axial direction, the center plate 10 can be formed in a cup shape. The rigidity of the center plate 10 itself can be increased.

  Further, since the peripheral edge portion 10b of the center plate 10 is composed of a brake hub member that engages with the friction member 21 of the brake 20, the cup-shaped peripheral edge portion 10b for increasing rigidity can be shared as a brake hub member. Therefore, the automatic transmission on which the planetary gear device 1 is mounted can be made compact.

  Further, since the peripheral edge portion 11b of the first carrier plate 11 is formed of a clutch hub member that engages with the friction member 31 of the clutch 30, that is, a cup that increases the rigidity of the first carrier plate 11 and serves as a carrier bridge. The peripheral edge portion 11b can be shared as a clutch hub member, and the automatic transmission on which the planetary gear device 1 is mounted can be made compact.

  Further, the peripheral edge 12b of the second carrier plate 12 is provided with a notch 12e for projecting the outer diameter of the long pinion 15 from the peripheral edge 12b, and on the outer peripheral side of the peripheral edge 12b of the second carrier plate 12. Since the ring gear 8 meshing with the long pinion 15 is arranged, the second carrier plate 12 and the ring gear 8 can be arranged without crossing members.

  Further, the center plate 10, the first carrier plate 11, and the second carrier plate 12 can be formed by pressing, and the cost of the planetary gear device 1 can be reduced.

  In the present embodiment described above, the planetary gear device including the carrier having the peripheral edge shared with the brake hub member in the central member has been described. However, for example, the central member may not have the peripheral edge. As long as it has a substrate portion that supports one end of a pinion shaft of a short pinion, the present invention can be applied.

  Further, in the present embodiment described above, the planetary gear device provided with the carrier in which the peripheral portion of the other side member is shared with the clutch hub member has been described. However, for example, the peripheral portion of the other side member is the clutch hub member. The present invention may be applied if the other side member has a peripheral edge portion that extends integrally in the axial direction from the periphery of the bottom plate portion.

  Further, in the present embodiment described above, the planetary gear device of the type provided with three sets of pinions has been described. However, for example, a planetary gear device of the type provided with four sets of pinions may be used. The present invention can be applied as long as the three members of the side member and the other side member are provided with carriers that respectively support both ends of the short pinion and the long pinion.

Sectional drawing which shows a planetary gear apparatus. The perspective view which shows the state which combined the center plate and the 2nd carrier plate from the center plate side. The perspective view which shows the state which combined the center plate and the 1st carrier plate from the center plate side. The perspective view which shows a frame from the 1st carrier plate side. The perspective view which shows a frame from the 2nd carrier plate side. The perspective view which shows the state which combined the long pinion and the short pinion in FIG. 2 from the center plate side. The perspective view which shows the state which combined the long pinion and the short pinion in FIG. 3 from the center plate side. The perspective view which shows a carrier from the 1st carrier plate side. The perspective view which shows a carrier from the 2nd carrier plate side.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Planetary gear apparatus 2 Carrier 8 Ring gear 10 Center member (center plate)
10a Substrate part 10b Peripheral part 11 The other side member (first carrier plate)
11a Bottom plate part 11b Peripheral part 12 One side member (second carrier plate)
12a Bottom plate part 12b Peripheral part 12e Notch part 14 Pinion shaft (long pinion shaft)
15 Long pinion 16 Pinion shaft (short pinion shaft)
17 Short pinion 20 First friction engagement element (brake)
30 Second friction engagement element (clutch)
X1-X2 direction Axial direction

Claims (6)

In a planetary gear device including a carrier that rotatably supports a short pinion and a long pinion meshing with the short pinion,
The carrier is
A central member having a substrate portion supporting one end of the pinion shaft of the short pinion;
A bottom plate portion and a peripheral edge portion integrally extending from the periphery of the bottom plate portion to one side in the axial direction, arranged on one side in the axial direction of the substrate portion of the central member, and of the pinion shaft of the long pinion One side member supporting one end with the bottom plate part,
A bottom plate portion and a peripheral edge portion integrally extending from the periphery of the bottom plate portion to the other side in the axial direction, and disposed on the other side in the axial direction of the substrate portion of the central member, and of the pinion shaft of the short pinion The other side member that supports the other end and the other end of the pinion shaft of the long pinion with the bottom plate portion, and
The frame member that supports the short pinion and the long pinion by fixing the peripheral edge of the one side member and the peripheral edge of the other side member on both sides in the axial direction of the substrate portion of the central member,
A planetary gear device characterized by that. The central member has a peripheral edge portion extending in the axial direction integrally with the base plate portion as a bottom plate portion from the periphery of the bottom plate portion,
The planetary gear device according to claim 1. The central member is a hub member whose peripheral edge engages with a friction member of the first friction engagement element.
3. The planetary gear device according to claim 2, wherein The peripheral part of the central member is arranged on the outer peripheral side of the peripheral part of the one side member,
The other side member includes a hub member whose peripheral edge engages with a friction member of the second friction engagement element.
4. The planetary gear device according to claim 2, wherein the planetary gear device is provided. The peripheral part of the one side member includes a notch part that projects the outer diameter of the long pinion from the peripheral part,
The ring gear is disposed on the outer peripheral side of the peripheral portion of the one side member, and meshes with the long pinion.
The planetary gear device according to any one of claims 1 to 4, wherein the planetary gear device is provided. The central member, the one side member, and the other side member can be formed by pressing.
The planetary gear device according to any one of claims 1 to 5, wherein

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