JP4252052B2 - Transmission rotor support structure and transmission rotor support assembly method - Google Patents

Description

  The present invention relates to a rotating body support portion structure that supports a rotating body of a transmission in a rotatable manner by a rotating body support portion of a casing of the transmission, and particularly to an oil passage structure thereof.

As a conventional clutch drum support portion structure of an automatic transmission, there is one described in Patent Document 1, for example.
In this structure, the side cover of the automatic transmission is provided with a support portion of the clutch drum that protrudes in a cylindrical shape in the axial direction, and the inner cylinder portion formed on the center side of the clutch drum on the outer peripheral surface of the support portion can be rotated. It is something to support.
The support portion includes a shaft-shaped portion that is formed integrally with the side cover and protrudes in a cylindrical shape in the axial direction, and a cylindrical sleeve member that is press-fitted to the outer periphery of the shaft-shaped portion.
Further, the sleeve member is fitted in the seal ring groove, a circumferential oil groove provided in a circumferential direction on the outer peripheral surface thereof to be an oil passage, a pair of seal ring grooves formed on both sides of the circumferential oil groove, and the seal ring groove. A pair of seal rings.
The side cover is made of an aluminum material that is easy to process and is inexpensive, and the sleeve member is made of a material that is compatible with the seal ring (a material that does not wear even if it comes into direct contact with the seal ring, such as an iron material). .

An oil hole is formed in the inner cylinder portion of the clutch drum at a position facing a circumferential oil groove formed in the sleeve member.
The sleeve member is formed with an oil passage hole that connects the bottom wall of the circumferential oil groove and the inner peripheral surface of the sleeve member.
A radial oil passage that opens at a position facing the oil passage hole of the sleeve member and an axial oil passage that is formed in the axial direction are formed in the axial portion of the side cover. One end side of this is in communication with an oil passage formed in the side cover, and an intermediate portion of the axial oil passage is in communication with the radial oil passage.

As a result, the hydraulic pressure regulated by the control valve and supplied to the oil passage of the side cover is changed into the axial oil passage, the radial oil passage, the oil passage hole provided in the sleeve member, the circumferential oil groove of the sleeve member, the clutch It is supplied as hydraulic oil for a piston disposed in the clutch drum through an oil hole provided in the inner cylinder portion of the drum.
Further, a seal member is disposed on the other end side of the axial oil passage so as to prevent leakage of hydraulic pressure supplied to the clutch drum.

Further, another conventional clutch drum support structure of an automatic transmission is disclosed in Patent Document 2.
In addition to the structure described in Patent Document 1, the support structure is formed by forming a small-diameter cylindrical portion that extends on the front end side of the shaft-shaped portion in the sleeve member, and a planetary gear mechanism in the small-diameter cylindrical portion. The structure which couple | bonds the internal peripheral surface of this sun gear and controls rotation of a sun gear is described.
Japanese Patent Laid-Open No. 9-60714 JP 2000-220704 A (FIG. 20)

By the way, the sleeve members of Patent Documents 1 and 2 described above have an opening in the radial oil passage of the shaft-like portion and an oil passage hole formed in the sleeve member in order to prevent poor supply of oil to be supplied to the clutch drum. It was necessary to always face each other, and it was necessary to prevent the sleeve member from rotating.
Therefore, in the support structure of Patent Document 1, one engagement claw is provided on the inner peripheral surface of the sleeve member, and the engagement claw is fitted into a recess formed on the side surface in the protruding direction of the shaft-shaped portion protruding from the side cover. To prevent the sleeve member from rotating.
However, in the sleeve member on which a large torque acts, it cannot be said that the rotation is sufficiently prevented only by fitting a single engagement claw into the recess.

In particular, in the support structure of Patent Document 2, it is apparent that a larger torque acts on the sleeve member than that of Patent Document 1 in consideration of the necessity of regulating the rotation of the sun gear by the sleeve member. It is necessary to reliably prevent the rotation of the member.
Therefore, by performing serration coupling, which is a general anti-rotation structure, between the sleeve member inner circumferential surface and the shaft-shaped portion outer circumferential surface, the sleeve member does not rotate on the shaft-shaped portion outer circumferential surface, The positional deviation between the oil passage hole provided in the sleeve member and the opening of the radial oil passage provided in the shaft-like portion can be reliably suppressed.

However, when the structure in which the sleeve member and the shaft-like portion are serrated and connected is applied to the clutch drum support structure of the automatic transmission, the following problems occur.
That is, in the serration coupling, the sleeve member is press-fitted while cutting the outer peripheral surface of the shaft-like portion protruding from the side cover. At this time, shavings generated at the time of press-fitting serration enter the oil passage from the opening of the radial oil passage formed in the shaft-like portion.
Since the sleeve member is extended to form the small-diameter cylindrical portion and covers the side surface in the protruding direction of the shaft-like portion, the sleeve member is assembled to the shaft-like portion as in Patent Document 1. Before, the opening side of the axial oil passage formed in the shaft-like portion is sealed, or the opening of the axial oil passage formed in the shaft-like portion as in Patent Document 2 is the outer peripheral surface of the shaft-like portion (sleeve member If the structure is such that the shavings are exposed to the press-fitted portion), it becomes difficult for the shavings during serration press-fitting into the oil passage that supplies oil to the clutch drum, and to be reliably discharged. There is a problem in that shavings flow backward to the control valve side, which causes the control valve to malfunction.

  Accordingly, in view of such problems, the present invention supports a rotating body of a transmission in which shavings during press-fitting into serrations enter into an oil passage that supplies oil to a clutch drum or the like and do not cause malfunction of a control valve. An object is to provide a partial structure.

  The present invention relates to a transmission in which a sleeve member that supports a rotating body is fitted to a shaft-like portion that protrudes in a cylindrical shape in an axial direction from a support wall portion fixed to a case of the transmission, and is serrated and coupled. The sleeve member includes a cylindrical portion whose inner peripheral side is fitted into the shaft-shaped portion, a first radial through hole that connects the outer peripheral surface and the inner peripheral surface of the cylindrical portion, and a shaft member. And a gear-coupled cylindrical portion that extends in the opposite direction from the opposed surface to the cylindrical portion and is coupled to one of the rotating elements of the planetary gear mechanism. The one end side opens to the tip end surface of the shaft-like portion, the other end side is connected to the internal oil passage of the transmission, the one end side is connected to the axial oil passage, and the other end side is the first diameter. The sleeve member has an axial direction on the opposite surface. A through hole is formed at a position opposite to the opening of the oil passage, and the opening of the axial oil passage is sealed by a seal member inserted from the through hole, and the oil supplied from the internal oil passage of the transmission is The axial oil passage and the radial oil passage are supplied to the first radial through hole, and the oil can be supplied from the first radial through hole to the rotating body side.

According to the present invention, in the sleeve member that is fitted into the shaft-shaped portion and serrated and connected, the through hole is formed at a position facing the opening of the axial oil passage of the shaft-shaped portion, and after the serration connection, the seal member is formed from the through hole. So that the shavings generated by serration press-fitting can be removed in the axial oil passage by cleaning the axial oil passage before assembling the seal member. Can be reliably discharged through the through hole.
Therefore, the shavings generated at the time of serration press-fitting is prevented from flowing back to the control valve side for controlling the hydraulic pressure supplied to the clutch drum, and malfunction of the control valve does not occur.

Next, embodiments of the present invention will be described by way of examples.
FIG. 1 is a skeleton diagram showing a transmission to which the embodiment is applied.
An automatic transmission 1 connected to the engine 2 is mounted on a vehicle (not shown).
The power of the engine 2 input to the torque converter 3 is input to the carrier 5 of the double pinion planetary gear mechanism 4 via the rotation shaft S1.
The double pinion type planetary gear mechanism 4 includes a sun gear 7 (rotating element) that is connected to a side cover 50 that covers an opening on one end side of the transmission case 6 and whose rotation is restricted, and an inner diameter side pinion gear 8 that meshes with the sun gear 7. An outer diameter side pinion gear 9 that meshes with the ring gear 10.
The inner diameter side pinion gear 8 and the outer diameter side pinion gear 9 mesh with each other, and each shaft is supported by the carrier 5.

The ring gear 10 is connected to a rotation shaft S2 that covers the outer periphery of the rotation shaft S1 and extends toward the engine 2 through the inner diameter side of an output gear 17 described later.
The carrier 5 is connected to a rotating shaft S3 that covers the outer periphery of the rotating shaft S2 and extends toward the engine 2 via a high clutch H / C.
The end of the rotary shaft S3 opposite to the side where the high clutch H / C is connected is connected to a carrier 16 that supports the pinion gear 13 of the single pinion type planetary gear mechanism 11.
The carrier 16 is connected to the transmission case 6 via a low and reverse brake L & R / B.

The single pinion type planetary gear mechanism 11 meshes with the second sun gear 14 with the pinion gear 13 disposed on the engine 2 side and the first sun gear 12 disposed on the opposite side to the engine 2 side and with the ring gear 15. .
The first sun gear 12 extends in a direction opposite to the engine 2 and is connected to a rotation shaft S4 that covers the outer periphery of the rotation shaft S3. The rotation shaft S4 is connected to the transmission case 6 via a 2-6 brake 2-6 / B. Connected.
The second sun gear 14 passes through the inner diameter side of the output gear 17 and extends to the engine 2 side, and is connected to a rotating shaft S5 that covers the outer periphery of the rotating shaft S2. The rotating shaft S5 is connected to the 3-5 reverse clutch 3-5R / C. Via the rotary shaft S2 and the low clutch L / C.

A single pinion planetary gear mechanism 18 is provided between the output gear 17 and the 3-5 reverse clutch 3-5R / C on the outer peripheral side of the rotation shaft S5.
The single pinion planetary gear mechanism 18 meshes with the sun gear 19 connected to the rotation shaft S5, the ring gear 21 disposed on the outer diameter side of the sun gear 19, the sun gear 19 and the ring gear 21, and is supported by the carrier 22. And a pinion gear 20.

The ring gear 21 is connected to the rotation shaft S2 via the low clutch L / C.
The carrier 22 covers the outer peripheral side of the rotary shaft S5 and is connected to the rotary shaft S6 that passes through the inner diameter side of the output gear 17 and extends to the ring gear 15 side. The rotation shaft S6 is connected to the ring gear 15.
A partition-shaped bearing support portion 30 extends from the transmission case 6 between the single pinion planetary gear mechanism 18 and the single pinion planetary gear mechanism 11. A cylindrical bearing support portion 31 extending along the rotation axis S6 is provided at the center portion of the bearing support portion 30.

A bearing 40 is fitted on the outer periphery of the bearing support portion 31, and the output gear 17 connected to the ring gear 15 is supported by the outer periphery of the bearing 40.
The inner diameter side of the bearing support portion 31 has a multilayer structure in which the rotation shafts S1, S2, S5, and S6 overlap.

  The power of the engine 2 is high clutch H / C, 2-6 brake 2-6 / B, low and reverse brake L & R / B, low clutch L / C and 3-5 reverse clutch 3-5R / C. Is converted to a desired number of revolutions, and is transmitted from the output gear 17 to the driving wheels of the vehicle (not shown) via the counter shaft 23 and the differential gear 24.

Next, FIG. 2 shows an engagement table of each clutch and brake for obtaining a desired gear stage.
The first speed is obtained by engaging the low clutch L / C and the low and reverse brake L & R / B.
The second speed is obtained by engaging the low clutch L / C and the 2-6 brake 2-6 / B. By engaging the 2-6 brake 2-6 / B at the second speed, the first sun gear 12 and the pinion gear 13 are fixed to the transmission case. Further, since the pinion gear 13 and the second sun gear 14 mesh with each other, the rotation shaft S5 connected to the second sun gear 14 is fixed to the transmission case 6.

The third speed is obtained by engaging the 3-5 reverse clutch 3-5R / C and the low clutch L / C, and the fourth speed is engaging the high clutch H / C and the low clutch L / C. Is obtained.
The fifth speed is obtained by engaging the high clutch H / C and the 3-5 reverse clutch 3-5R / C.

The sixth speed is obtained by engaging the high clutch H / C and the 2-6 brake 2-6 / B. At the sixth speed, the rotation shaft S5 is fixed by engaging the 2-6 brake 2-6 / B as in the second speed.
The reverse is obtained by engaging the 3-5 reverse clutch 3-5R / C and the low and reverse brake L & R / B.

Next, a connection structure between the shaft-like portion protruding from the side cover and the sleeve member will be described.
FIG. 3 shows a cross section around the sleeve member of the automatic transmission.
The side cover 50 includes a support wall 55 and a cylindrical shaft 51 extending from the support wall 55 coaxially with the rotation axis S1.
The shaft portion 51 supports one end of the rotation shaft S1 on the cylindrical inner peripheral surface.
A cylindrical sleeve member 60 is fitted and fixed to the outer peripheral portion of the shaft-like portion 51. Details of the coupling structure of the shaft-like portion 51 and the sleeve member 60 will be described later.

The sleeve member 60 includes a ring-shaped connecting portion 66 (opposing surface) that expands in a diameter direction with respect to a cylindrical shaft, and a large-diameter cylindrical portion 62 (cylindrical portion) that extends from the outer peripheral edge of the connecting portion 66 to one side. And a small-diameter cylindrical portion 61 (gear-coupled cylindrical portion) extending from the inner peripheral edge of the connecting portion 66 to the other side.
The inner peripheral portion of the large-diameter cylindrical portion 62 is fitted into the outer peripheral portion of the shaft-shaped portion 51, and the surface of the connecting portion 66 on the large-diameter cylindrical portion 62 side is in contact with the tip surface of the shaft-shaped portion 51. .
The small-diameter cylindrical portion 61 extends from the connecting portion 66 in the same direction as the protruding direction of the shaft-like portion 51, and the rotation axis S1 passes through the inside.
The inner peripheral portion of the sun gear 7 of the double pinion type planetary gear mechanism 4 is spline-fitted to the outer peripheral portion of the small diameter cylindrical portion 61.
Therefore, the sun gear 7, the sleeve member 60, and the side cover 50 (shaft-shaped portion 51) are coupled together and are integrated in the rotation direction.

The large-diameter cylindrical portion 62 of the sleeve member 60 rotatably supports the inner peripheral surface of the inner cylinder portion 42 serving as the shaft of the clutch drum 41 (rotating body) of the high clutch H / C at the outer peripheral portion thereof.
The inner cylindrical portion 42 meshes with the carrier 5 that supports the inner diameter side pinion gear 8 and the outer diameter side pinion gear 9 at the end on the double pinion type planetary gear mechanism 4 side.
A disc-shaped drum side wall 46 extends in an approximately diametrical direction from the end of the inner cylinder portion 42 on the side cover 50 side.
The outer cylinder connected to the outer periphery of the drum side wall portion 46 is spline-engaged with the friction plate 45 of the high clutch H / C.

A clutch piston 43 is arranged on the outer periphery of the inner cylinder part 42 so as to be movable in the axial direction of the inner cylinder part 42.
A hydraulic chamber 44 is formed between the drum side wall 46 and the clutch piston 43.
The inner cylinder portion 42 is provided with a drum radial oil passage 47 that connects the inner peripheral surface of the inner cylinder portion 42 and the hydraulic chamber 44 (the outer peripheral surface of the inner cylinder portion 42).
A circumferential oil groove 63 is formed on the outer peripheral surface of the large-diameter cylindrical portion 62 of the sleeve member 60 along the locus of the opening on the sleeve member 60 side of the drum radial oil passage 47 formed when the clutch drum 41 rotates. Is formed.
In addition, the sleeve member 60 is formed with a first radial through hole 64 that connects the bottom wall of the circumferential oil groove 63 and the inner peripheral surface of the large-diameter cylindrical portion 62.

An axial oil passage 52 is formed in the shaft-like portion 51 of the side cover 50 from the tip (right side in FIG. 3) to the support wall portion 55.
The end of the axial oil passage 52 on the support wall 55 side is connected to an internal oil passage of an automatic transmission (not shown), and the end of the axial oil passage 52 on the front end side is sealed by a seal member 54. Yes.

The shaft-like portion 51 is provided with a radial oil passage 53 that connects the axial oil passage 52 to a position facing the first radial through hole 64 on the outer peripheral surface of the shaft-like portion 51.
As a result, the hydraulic pressure supplied from the internal oil passage (not shown) is supplied to the hydraulic chamber 44 via the axial oil passage 52, the radial oil passage 53, the first radial through hole 64, and the drum radial oil passage 47. be able to.
When the hydraulic pressure is supplied into the hydraulic chamber 44, the clutch piston 43 moves to the right side in FIG. 3 to press the friction plate 45, and the high clutch H / C is engaged.

An internal oil passage 71 is formed inside the rotary shaft S1, and a rotary shaft radial oil passage 70 that connects the internal oil passage 71 and the outside of the rotary shaft S1 is formed.
As a result, the oil that has passed through the in-axis oil passage 71 of the rotation shaft S1 is discharged out of the rotation shaft S1 through the rotation shaft radial oil passage 70.

Next, detailed shapes of the shaft-like portion 51 and the sleeve member 60 will be described.
First, the shaft portion 51 will be described.
FIG. 4 is a view of the inner surface of the side cover 50 as viewed from the axial direction, and FIG. 5 is a perspective view of the shaft-like portion 51.
A cylindrical shaft-shaped portion 51 protrudes from the support wall portion 55, and a tip surface of the shaft-shaped portion 51 is a shaft-shaped portion end surface 56.
An axial oil passage 52 is formed in the shaft-like portion 51 by drilling from the end portion 56 of the shaft-like portion, and a first end face oil passage 57 a (bearing lubricating oil passage) is formed around the axial oil passage 52. Has been.

A second end face oil passage 57b (bearing lubricating oil passage) is formed on the shaft-like portion end face 56 by groove processing from the inside to the outside of the shaft-like portion 51.
As shown in FIG. 5 in particular, the outer peripheral surface of the shaft-shaped portion 51 has a shaft-shaped portion small-diameter portion 73 on the tip side, and a shaft-shaped portion large-diameter portion 74 having a larger diameter on the support wall 55 side than the shaft-shaped portion small-diameter portion 73. It has become.
A shaft portion serration 58 is formed in the axial direction of the shaft portion 51 on the outer peripheral surface of the shaft portion small diameter portion 73.

Next, the sleeve member 60 will be described.
FIG. 6A shows a view of the sleeve member 60 viewed from the small-diameter cylindrical portion 61 side, and FIG. 6B shows a cross section taken along the line AA in FIG.
FIG. 7 is a perspective view of the sleeve member 60 as viewed from the large-diameter cylindrical portion 62 side. In FIG. 7, the seal ring 85 is not shown.
A spline 81 is formed on the outer peripheral surface of the small diameter cylindrical portion 61 of the sleeve member 60 in the same direction as the axial direction of the sleeve member 60.
As shown in FIG. 3, the spline 81 is meshed with a spline groove formed on the inner peripheral surface of the sun gear 7 of the double pinion type planetary gear mechanism 4 so that the sleeve member 60 and the sun gear 7 are integrated in the rotation direction. It has become.

In the sleeve member 60, a part of the outer peripheral surface of the small diameter cylindrical part 61 is scraped off and a through hole 67 that penetrates the connecting part 66 is formed.
On the outer circumferential surface of the large-diameter cylindrical portion 62, a circumferential oil groove 63 is formed along the trajectory of the drum radial oil passage 47 formed in the inner cylinder portion 42 as shown in FIG.
A seal ring groove 84 is formed on both sides of the circumferential oil groove 63 in parallel with the circumferential oil groove 63, and a seal ring 85 is fitted in the seal ring groove 84.
As shown in FIG. 3 in particular, the seal ring 85 has a sleeve member 60 rotatably supporting the inner cylinder portion 42 of the clutch drum 41 and the outer peripheral surface of the large diameter cylindrical portion 62 and the clutch drum 41. The inner peripheral surface is sealed.
Thereby, the oil in the circumferential oil groove 63 does not flow out in the axial direction of the sleeve member 60.

The large-diameter cylindrical portion 62 is formed with a first inner diameter large diameter portion 82 and a second inner diameter large diameter portion 83 having different inner peripheral diameters, and an inner peripheral surface having a smaller diameter than the second inner diameter large diameter portion 83. A first inner diameter / large diameter portion 82 having an inner diameter is formed on the connecting portion 66 side, and a second inner diameter / large diameter portion 83 is formed on the other side.
The first inner diameter / large diameter portion 82 is formed with a second radial through hole 65 that connects the outer peripheral surface and the inner peripheral surface of the first inner diameter / large diameter portion 82 and extends in the diameter direction of the sleeve member 60.
The second inner diameter large diameter portion 83 is connected to the bottom wall of the circumferential oil groove 63 and the inner peripheral surface of the second inner diameter large diameter portion 83, and extends in the diameter direction of the sleeve member 60. A hole 64 is formed.

In particular, as shown in FIG. 7, a sleeve serration 86 is formed in the axial direction of the sleeve member 60 on the inner peripheral surface of the first inner diameter large diameter portion 82.
Note that, on the inner peripheral surface of the first inner diameter large diameter portion 82, the surface closer to the connecting portion 66 than the second radial direction through hole 65 is a serration non-forming portion 87 that does not form the sleeve serration 86.

Next, a state in which the large-diameter cylindrical portion 62 of the sleeve member 60 is fitted into the shaft-like portion 51 will be described.
FIG. 8 is a cross-sectional view showing the periphery of the second radial through-hole 65, and FIG. 9 is a cross-sectional view showing the periphery of the first radial through-hole 64 and the through hole 67. FIG. 10 is a cross-sectional view showing the periphery of the second end face oil passage 57b.
The sleeve member 60 is fitted into the shaft-like portion 51 so that the positions of the through hole 67 and the opening of the axial oil passage 52 of the shaft-like portion 51 are aligned.
As shown in FIG. 8, the large-diameter cylindrical portion 62 of the sleeve member 60 is inserted into the shaft-like portion 51 until the shaft-like portion end surface 56 contacts the connecting portion 66 of the sleeve member 60.
At this time, the shaft portion serration 58 and the sleeve serration 86 are serrated.

In addition, the axial length of the shaft-like portion small diameter portion 73 is formed longer than the axial length of the first inner diameter large diameter portion 82 of the sleeve member 60.
Thus, when the sleeve member 60 is fitted into the shaft-like portion 51, the outer peripheral surface of the end portion on the shaft-like portion large-diameter portion 74 side of the shaft-like portion small-diameter portion 73 and the inside of the second inner-diameter large-diameter portion 83 An annular shavings reservoir 91 that accumulates shavings due to serration coupling can be formed between the peripheral surface and the peripheral surface.

By forming a chamfered portion 92 at the outer peripheral side corner at the distal end portion of the shaft-shaped portion 51, when the sleeve member 60 is fitted into the shaft-shaped portion 51, the large-diameter cylindrical portion 62 and the connecting portion 66. An annular annular oil passage 90 is formed between the inner surface and the chamfered portion 92.
By providing the serration non-forming portion 87 on the inner peripheral surface of the first inner diameter large diameter portion 82, the second radial direction through hole 65 and the annular oil passage 90 are connected to the shaft portion serration 58 of the shaft portion 51. It communicates through the valley. (Between the valley portion of the shaft-shaped portion serration 58 and the serration non-forming portion 87 constitutes a part of the bearing lubricating oil passage)

Next, as shown in FIG. 9, the radial oil passage 53 extends in the radial direction from the axial oil passage 52 formed in the shaft-like portion 51, and faces the first radial through hole 64 of the sleeve member 60. ing.
The opening end of the axial oil passage 52 is sealed by screwing a seal member 54.
The seal member 54 is inserted and fixed from the through hole 67 formed in the sleeve member 60 toward the axial oil passage 52 of the shaft-like portion 51 in a state where the sleeve member 60 is fitted into the shaft-like portion 51. Is done. The procedure for assembling the seal member 54 will be described later.
Next, as shown in FIG. 10, the second end face oil passage 57 b is formed on the shaft-like portion end face 56, so that the inside of the shaft-like portion 51 and the annular oil passage 90 are communicated with each other.

As a result, as shown in FIG. 3, the oil that has passed through the in-shaft oil passage 71 in the rotary shaft S1 is discharged from the rotary shaft radial oil passage 70, and as shown in FIGS. The oil flows into the annular oil passage 90 through the two end face oil passages 57a and 57b.
As shown in FIG. 8, the oil in the annular oil passage 90 is discharged out of the sleeve member 60 from the second radial through hole 65 through the valley of the shaft-like portion serration 58 that faces the serration non-forming portion 87, As shown in FIG. 3, it is supplied to a bearing 95 sandwiched between the large-diameter cylindrical portion 62 and the inner cylindrical portion 42.
The hydraulic pressure supplied from the oil passage (not shown) to the axial oil passage 52 is supplied into the hydraulic chamber 44 through the radial oil passage 53 and the first radial through hole 64, and the hydraulic pressure for operating the clutch piston 43. Become.

Next, the assembly procedure of the sleeve member 60 to the shaft-like portion 51 and the assembly procedure of the seal member 54 will be described.
FIG. 11 shows an assembling procedure of each part performed by the operator, and FIG. 12 shows an assembling state of each part.
In step 100, the operator aligns the opening of the axial oil passage 52 provided in the shaft-like portion 51 of the side cover 50 and the through hole 67 of the sleeve member 60, and moves the sleeve member 60 to the shaft-like portion. Serrated into 51.
The sleeve member 60 is press-fitted to a position where the connecting portion 66 of the sleeve member 60 comes into contact with the shaft-like portion end surface 56.

Next, in step 101, the side cover 50 is cleaned.
Specifically, the oil is allowed to flow through the axial oil passage 52 and the chips generated during the serration press-fitting are surely discharged.
At the same time, the shavings accumulated in the annular oil passage 90 are also discharged.
It should be noted that the shavings accumulated in the shavings reservoir 91 when the serration is pressed are confined in the shavings reservoir 91.

In step 102, the seal member 54 is inserted from the through hole 67 of the sleeve member 60 into the axial oil passage 52 of the shaft-like portion 51.
A thread is provided on the inner peripheral surface in the vicinity of the opening of the axial oil passage 52, and the inserted seal member 54 is screwed to a predetermined position with a hexagon wrench 99 or the like.
A thread that meshes with a thread provided near the opening of the seal member 54 is also formed on the outer peripheral surface of the seal member 54.
Further, in a state where the seal member 54 is screwed to a predetermined position, a part of the seal member 54 overlaps with the connecting portion 66 of the sleeve member 60 (the end portion on the front side in the insertion direction of the seal member 54 (in FIG. 9) The right end portion of the left side) remains in the through hole 67).

  After the seal member 54 is attached, the sun gear 7 of the double pinion planetary gear mechanism 4 is attached to the small diameter cylindrical portion 61 of the sleeve member 60, and the inner cylinder portion 42 of the clutch drum 41 is attached to the large diameter cylindrical portion 62 of the sleeve member 60. Fit.

By screwing the seal member 54 into the axial oil passage 52 in this way, the opening on the connecting portion 66 side of the axial oil passage 52 is sealed.
Further, since the end of the seal member 54 on the front side in the insertion direction remains in the through hole 67, oil leaking from the through hole 67 to the sun gear 7 side can be reduced.
Prior to sealing the axial oil passage 52 with the seal member 54, the side cover 50 is cleaned to remove the shavings generated by the serration press-fitting, so that no shavings remain in the axial oil passage 52. .

The present embodiment is configured as described above, and in the sleeve member 60 that is serrated and press-fitted into the shaft-like portion 51, a through-hole 67 is formed at a position facing the opening of the axial oil passage 52 of the shaft-like portion 51. Since the seal member 54 is inserted from 67 to seal the opening of the axial oil passage 52, the shaving generated by the serration press-fitting is cleaned in the axial oil passage 52 before the seal member 54 is assembled. By doing so, the oil can be reliably discharged from the axial oil passage 52 through the through hole 67 and the radial oil passage 53.
Therefore, the shavings generated at the time of serration press-fitting is prevented from flowing back to the control valve side for controlling the hydraulic pressure supplied to the clutch drum, and malfunction of the control valve does not occur. (Effects corresponding to claims 1 and 3)
Further, since the sleeve member 60 and the shaft-like portion 51 are serrated and connected, even when a large torque is input to the sleeve member 60 from the sun gear 7 whose rotation needs to be restricted, the sleeve member 60 is reliably rotated. Stop can be done. (Effects corresponding to claim 1)

  Further, since the seal member 54 is partly overlapped with the connecting portion 66 of the sleeve member 60 in a state where the seal member 54 is screwed to a predetermined position, the rotation shaft radial oil passage 70 of the rotation shaft S1 is used. When oil flows into the second radial direction through hole 65 of the sleeve member 60, the oil leaking from the through hole 67 can be reduced, and the oil can be efficiently supplied to the bearing 95 for lubrication. (Effects corresponding to claim 2)

  In this embodiment, the sleeve member 60 is coupled to the sun gear 7 of the double pinion type planetary gear mechanism 4. However, the present invention is not limited to this. It may be a drum connected to a carrier or ring gear.

It is a skeleton figure which shows the transmission to which this invention is applied. It is a fastening table of a clutch and a brake. It is sectional drawing which shows a shaft-shaped part and a sleeve member. It is a front view which shows the axial part of a side cover. It is a perspective view which shows an axial part. It is a figure which shows a sleeve member. It is a perspective view which shows the inner surface of a sleeve member. It is sectional drawing which shows the combined state of a shaft-shaped part and a sleeve member. It is sectional drawing which shows the combined state of a shaft-shaped part and a sleeve member. It is sectional drawing which shows the combined state of a shaft-shaped part and a sleeve member. It is a figure which shows the flow of the assembly | attachment operation | work of a shaft-shaped part and a sleeve member. It is sectional drawing which shows the assembly | attachment state to the axial part of a sleeve member.

Explanation of symbols

4 Double pinion type planetary gear mechanism 6 Transmission case 7 Sun gear (Rotating element)
41 Clutch drum (Rotating body)
42 Inner cylinder portion 43 Clutch piston 44 Hydraulic chamber 47 Drum radial oil passage 50 Side cover 51 Axial portion 52 Axial oil passage 53 Radial oil passage 54 Seal member 55 Support wall portion 56 Axis portion end surface 57a First end face oil Road (bearing lubricating oil path)
57b Second end face oil passage (bearing lubricating oil passage)
58 Axial part serration 60 Sleeve member 61 Small diameter cylindrical part (gear-coupled cylindrical part)
62 Large-diameter cylindrical part (cylindrical part)
63 Circumferential oil groove 64 1st radial direction through-hole 65 2nd radial direction through-hole 66 Connection part (opposing surface)
67 Through-hole 70 Rotary shaft radial oil passage 71 In-shaft oil passage 84 Seal ring groove 85 Seal ring 86 Sleeve serration 87 Serration non-forming portion 90 Annular oil passage (bearing lubricating oil passage)
91 Shavings accumulation 95 Bearing 99 Hexagon wrench S1 Rotating shaft

Claims (3)

A rotating body support portion of a transmission in which a sleeve member that supports a rotating body is fitted into a shaft-shaped portion that protrudes in a cylindrical shape in an axial direction from a support wall portion fixed to a transmission case, and is serrated and coupled. Structure,
The sleeve member is
A cylindrical portion whose inner peripheral side is fitted into the shaft-shaped portion;
A first radial through hole connecting the outer peripheral surface and the inner peripheral surface of the cylindrical portion;
A facing surface facing the tip surface of the shaft-shaped portion;
A gear-coupled cylindrical portion extending in an opposite direction to the cylindrical portion from the opposing surface and coupled to one of the rotating elements of the planetary gear mechanism;
The shaft portion is
One end side opens to the tip surface of the shaft-like portion, and the other end side connects to an internal oil passage of the transmission, and an axial oil passage;
One end side is connected to the axial oil passage, and the other end side is provided with a radial oil passage facing the opening of the first radial through hole,
The sleeve member has a through hole formed at a position facing the opening of the axial oil passage on the facing surface,
The opening of the axial oil passage is sealed by the seal member inserted from the through hole,
Oil supplied from the internal oil passage of the transmission is supplied from the axial oil passage and the radial oil passage to the first radial through hole, and the oil is supplied from the first radial through hole to the rotating body side. A structure for supporting a rotating body of a transmission. The sleeve member rotatably supports the rotating body via a bearing;
The cylindrical portion is formed with a second radial through-hole for supplying oil to the bearing,
Formed between the inner peripheral surface of the sleeve member and the outer peripheral surface of the shaft-shaped portion, and between the tip surface of the shaft-shaped portion and the opposing surface, the inner diameter side of the shaft-shaped portion and the second diameter It has a bearing lubricating oil passage that connects the direction through hole,
2. The transmission according to claim 1, wherein a part of the sealing member remains in the through hole in a state where the opening of the axial oil passage is sealed. Rotating body support structure. This is a method of assembling a rotating body support portion of a transmission, in which a sleeve member is covered with a shaft-like portion that protrudes from a support wall portion and an axial oil passage of a shaft-like portion oil passage opens on a protruding side end surface. And
Forming a through hole at a position facing the opening of the axial oil passage in the sleeve member;
The sleeve member is press-fitted into the shaft-like portion by aligning the positions of the opening of the axial oil passage and the through hole,
Thereafter, the shaft-like oil passage is washed,
A method of assembling a rotating body support portion of a transmission, wherein a sealing member is inserted from the through hole after the cleaning to seal an opening of the axial oil passage.

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