JPH0799200B2 - Rotating member support structure for automatic transmission - Google Patents

Description

The present invention relates to a rotary member support structure for an automatic transmission.

(B) Conventional Technology As a conventional rotary member supporting structure for an automatic transmission, for example,
"Automatic transaxle, RN4F02A type, RL4F0
2A type, 1984, maintenance manual "(issued by Nissan Motor Co., Ltd.)
On page 10 of. In the rotating member supporting structure of the automatic transmission shown in this figure, the output shaft is rotatably supported by the inner diameter portion of the retainer fixed to the wall portion of the casing. A clutch drum is supported on the outer diameter portion of the retainer. Hydraulic pressure is supplied to the clutch drum through oil passages provided in the casing wall and the retainer.

(C) Problems to be Solved by the Invention However, in the conventional rotary member supporting structure for an automatic transmission as described above, there is a problem that the shape of the retainer is complicated and the radial and axial dimensions are large. That is, the retainer is centered by being fitted to the wall portion of the casing on the outer diameter side, and is fixed by a bolt at a flange portion having a diameter larger than this outer diameter. Therefore, the retainer is large in the radial direction. Also, the oil passage that supplies the hydraulic pressure to the clutch drum is
The retainer and the wall of the casing are connected at the fitting portion, and the retainer needs to have holes in the radial direction and the axial direction, and the size in the axial direction is also large. The present invention aims to solve such problems.

(D) Means for Solving the Problem The present invention is to provide a centering fitting that connects oil passages at a contact surface between a retainer and a wall of a casing and that is provided on the inner diameter side of these oil passages. The above problem is solved by centering the retainer in the section.
That is, in the rotating member support structure of the automatic transmission according to the present invention, the cylindrical retainer (60) is in close contact with the mounting surface (74) of the wall portion (51) of the casing (50) at the contact surface (72) on one end side. The oil passages (76, 78, 80) for the clutch drum (70) are connected between the contact surface of the retainer and the mounting surface of the casing wall, and the bolts (58) for mounting the retainer are connected. ) Is pierced through the wall from the side opposite to the mounting surface of the casing wall, and is screwed into the screw hole provided in the contact surface of the retainer. Has a centering shaft portion (82) projecting toward the casing wall portion side, and this centering shaft portion is fitted in the centering hole portion (84) of the casing wall portion, A seal is provided between the retainer and the rotary shaft on the inner diameter side of the centering shaft. The sealing member (86) or the bearing member for supporting the rotary shaft is provided that. The reference numerals in parentheses indicate the corresponding members in the embodiments described later.

(E) Action The retainer is in close contact with the wall of the casing at the contact surface of the cylindrical end surface, and is centered at the centering shaft. Therefore, the retainer has a simple cylindrical shape, and the outer diameter dimension is also small. Further, the oil passage of the clutch drum can also be configured by an axial hole that opens to the contact surface side,
It has a simple structure. Further, since the inner diameter portion of the centering shaft portion is used for the seal member or the bearing member, the axial dimension is also shortened.

(F) Example FIG. 2 shows a frame diagram of an automatic transaxle. The automatic transmission mechanism portion of an automatic transaxle connected to an engine 10 mounted laterally with respect to a vehicle, that is, orthogonal to the vehicle front-rear direction, includes a torque converter 12, a planetary gear transmission mechanism 14, and the like. The torque converter 12 to which the rotation from the engine 10 is input has a pump impeller 18, a turbine runner 20, and a stator 22.
And a lockup clutch 24. The turbine runner 20 is connected to the input shaft 26, and when the lockup clutch 24 is released, the rotational force is transmitted from the pump impeller 18 to the input shaft 26 via fluid, and the lockup clutch 24 is engaged. Then, the rotational force is mechanically input to the input shaft 26. The lockup clutch 24 operates by the differential pressure between the apply chamber T / A and the release chamber T / R. In addition,
The torque converter 12 is configured to drive the oil pump 28. The planetary gear speed change mechanism 14 is the first planetary gear set.
G ₁ and has the second has a planetary gear set G _2, the first planetary gear set
G ₁ is the first sun gear S ₁ , the first internal gear R ₁ ,
A first pinion carrier PC ₁ supporting a first pinion gear P ₁ that meshes with both gears S ₁ and R ₁ at the same time, and a second planetary gear set G ₂ includes a second sun gear S ₂ and a second sun gear S ₂ . Two
A second pinion carrier that supports an internal gear R ₂ and a second pinion gear P ₂ that meshes with both gears S ₂ and R ₂ at the same time.
It consists of PC ₂ and. The first sun gear S ₁ has an input shaft 26
Always connected to the 1st pinion carrier PC ₁
The second internal gear R ₂ is always connected to the output shaft 30. The first internal gear R ₁ is connected to the second pinion carrier PC via the forward one-way clutch F / O and the forward clutch F / C arranged in series, and the overrun clutch O / C arranged in parallel with these. Can be connected with ₂ . The second sun gear S ₂ is a reverse clutch R /
It can be connected to the input shaft 26 via C, and the second pinion carrier PC ₂ can be connected to the input shaft 26 via the high clutch H / C. The second sun gear S ₂ can be fixed to the stationary part by a band brake B / B, and the second pinion carrier PC ₂ is a low one-way clutch L / O and a low and reverse brake L & R / B arranged in parallel with each other. It can be fixed to the stationary part via and. An output gear 32 is provided integrally with the output shaft 30. A counter gear 34 is provided so as to mesh with the output gear 32, and a reduction gear 36 is connected to the counter gear 34 via a counter shaft 35 so as to rotate integrally. Reduction gear
The 36 engages with the ring gear 38 of the differential mechanism 16. The drive shafts 40 and 42 project left and right from the differential mechanism 16, and the left and right front wheels are connected thereto.

This planetary gear speed change mechanism 14 operates clutches F / C, H / C, O / C and R / C, brakes B / B and L & R / B, and one-way clutch F / O and L / O in various combinations. Each element of the planetary gear set G ₁ and G ₂ (S ₁ , S ₂ , R ₁ , R ₂ , PC ₁
And it can change the rotating state of the PC _2), whereby it is possible to change various rotational speed of the output shaft 30 to the input shaft 26. That is, by operating each clutch, brake, etc. in a combination as shown in FIG. 3, it is possible to obtain the fourth forward speed and the first reverse speed. In addition, in FIG.
The mark indicates that the clutch and brake are engaged,
Also, in the case of a one-way clutch, the engaged state is shown. In addition, 2A, 3R and 4A are shown in the band brake B / B column respectively for the second speed apply chamber 2A, the third speed release chamber 3R and the fourth speed apply of the hydraulic servo device that operates the band brake B / B. The chamber 4A is shown, and the mark ○ indicates that hydraulic pressure is being supplied. Further, α ₁ and α ₂ are the ratios of the number of teeth of the sun gears S ₁ and S _{2 to} the number of teeth of the internal gears R ₁ and R ₂ , respectively, and the gear ratio is the ratio of the input shaft 26 to the rotation speed of the output shaft 30. It is the ratio of the number of rotations.

By the operation of the planetary gear speed change mechanism 14 as described above, the input shaft
The rotation of 26 is subjected to a predetermined speed change and is output to the output shaft 30. The rotational force of the output shaft 30 is transmitted to the ring gear 38 of the differential mechanism 16 via the output gear 32, the counter gear 34, and the reduction gear 36. As a result, the left and right front wheels can be driven via the drive shafts 40 and 42. By doing so, it is possible to perform automatic forward four-speed shift with overdrive.

A part of the power transmission mechanism shown as a frame diagram in FIG.
The figure shows the actual structure. In FIG. 1, members corresponding to those shown in FIG. 2 are designated by the same reference numerals. A side cover 52 is attached to the casing body 50 with bolts 54. The left end side in FIG. 1 of the output shaft 30 integrally provided with the output gear 32 is supported by the side cover 52 via a ball bearing 56. Casing body
Output retainer is attached to wall 51 of 50 by bolt 58.
60 is installed and this output retainer 60
A radial needle bearing 62 is provided on the inner diameter of the output shaft 30 to support the right end side of the output shaft 30 in the figure. Further, a thrust needle bearing 64 is arranged between the wall portion 51 of the casing body 50 and the side surface of the output gear 32. A clutch drum 70 that houses the pistons 66 and 68 of the overrunning clutch O / C and the forward clutch F / C is arranged on the outer peripheral side of the output retainer 60. The output retainer 60 has a cylindrical shape, and the contact surface 72 on the left end side is in close contact with the mounting surface 74 of the wall portion 51 of the casing body 50. The oil passage 76 on the casing body 50 side and the oil passage 78 on the output retainer 60 side communicate with each other via the mounting surface 74 and the contact surface 72. The other oil passage 80 of the output retainer 60 also communicates with the casing main body 50 similarly to the oil passage (not shown). The oil passage 78 and the oil passage 80 are for supplying hydraulic pressure to the clutch drum 70. A centering shaft portion 82 is provided on the inner diameter side of the left end portion of the output retainer 60.
The outer diameter portion of the centering shaft portion 82 fits in the centering hole portion 84 of the wall portion 51. A seal member 86 supported by the output shaft 30 is arranged in the inner diameter portion of the centering shaft portion 82.

Next, the operation of this embodiment will be described. The torque input from the engine 10 to the torque converter 12 is output from the automatic transmission mechanism to the output shaft 30, transmitted to the counter shaft 35 via the output gear 32 and the counter gear 34, and further transmitted to the differential mechanism 16. To be done. Oil paths 78 and 80 on the clutch drum 70
Oil pressure is supplied through the output retainer 60, but the oil passages 78 and 80 are configured by axial holes machined from the contact surface 72 side of the output retainer 60, and the output retainer 60 is provided to provide the oil passages 78 and 80. Does not increase in size in the radial and axial directions. The output retainer 60 also has a simple cylindrical shape. The output retainer 60 is centered by the centering shaft portion 82 on the inner diameter side, and the inner diameter portion of the centering shaft portion 82 is used for contact with the seal member 86, so the axial dimension is shortened. Has been done.

In this embodiment, the seal member 86 is arranged on the inner diameter side of the centering shaft portion 82, but it is also possible to arrange the needle bearing 90 (or bush) which is a bearing member as shown in FIG. Is.

(G) Effect of the Invention As described above, according to the present invention, since the configuration is as described above, the shape of the retainer can be simplified into a cylindrical shape, and the axial and radial dimensions can be reduced. .

[Brief description of drawings]

FIG. 1 is a diagram showing an embodiment of the present invention, FIG. 2 is a skeleton diagram of an automatic transaxle, FIG. 3 is a diagram showing a combination of elements that act at each shift stage, and FIG. 4 is another embodiment. FIG. 30 …… Output shaft, 32 …… Output gear, 34 …… Counter gear,
50 …… Casing body, 51 …… Wall, 52 …… Side cover, 56 …… Ball bearing, 58 …… Bolt, 60 …… Output retainer, 62 …… Radial needle bearing, 64 …… Thrust needle bearing, 70 …… Clutch drum, 72 …… Contact surface, 74 …… Mounting surface, 76, 78, 80 ……
Oil passage, 82 …… Centering shaft, 84 …… Centering hole, 86 …… Seal member.

Claims (1)

[Claims] 1. A rotary member supporting structure for an automatic transmission, wherein a hollow retainer is fixed to a wall portion of a casing by bolts, a rotary shaft is supported by an inner diameter portion of the retainer, and a clutch drum is supported by an outer diameter portion of the retainer. In the above, the cylindrical retainer is in close contact with the mounting surface of the casing wall at the contact surface on one end side, and the oil passage for the clutch drum is provided between the contact surface of the retainer and the mounting surface of the casing wall. Connection is made, the bolt for mounting the retainer penetrates the wall portion from the side opposite to the mounting surface of the wall portion of the casing, and is screwed into a screw hole provided in the contact surface of the retainer, The retainer has a centering shaft that protrudes toward the wall side of the casing on the inner diameter side of the contact surface, and this centering shaft is located in the centering hole of the wall of the casing. The automatic gear shifting is characterized in that a sealing member for sealing between the retainer and the rotary shaft or a bearing member for supporting the rotary shaft is provided on the inner diameter side of the centering shaft. Machine rotation member support structure.