JP6902433B2 - Driving force transmission gear device, its manufacturing method, and automatic transmission - Google Patents

Description

The present invention relates to a driving force transmission gear device, a method for manufacturing the same, and an automatic transmission.

Regarding a driving force transmission gear mounted on a vehicle, a structure is disclosed in which the gear is housed in a case containing oil such as lubricating oil, and the gear is sandwiched between a pair of baffle plates from both sides (see Patent Document 1). ).

By covering the circumference of the gear with a baffle plate, the oil pool that stores the oil in the case is divided into two parts inside and outside the baffle plate, suppressing the ingress of oil into the space around the gear in the baffle plate and rotating the gear. This is an attempt to reduce the agitation resistance of the oil.

Japanese Patent No. 5844019

However, since the pair of baffle plates are individually fixed to the case, a gap must be provided between the pair of baffle plates so that manufacturing errors and assembly errors can be tolerated.

Therefore, oil may enter the space around the gear inside the baffle plate from the gap, and the reduction of the stirring resistance by the gear may not be achieved.

The present invention has been devised in view of such a problem, and is a driving force transmission gear device and the like, which can enhance the effect of reducing the stirring resistance of oil due to the rotation of the gear by using a pair of baffle plates. It is an object of the present invention to provide a manufacturing method and an automatic transmission.

(1 ) In order to achieve the above object, the first driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear, and a case containing oil. It has a pair of baffle plates installed in the case and sandwiching the gear, and a liquid-tight structure is provided between the pair of baffle plates. In the liquid-tight structure, the pair of baffle plates are in contact with each other. Moreover, it is characterized in that it has a structure fixed by a fastener.
( 2 ) The second driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. anda pair of baffle plates sandwiching, the liquid-tight structure provided between the pair of baffle plates, the liquid-tight structure, as characterized by a labyrinth structure formed by the pair of baffle plates There is .
( 3 ) The third driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It has a pair of baffle plates that sandwich the baffle plate, and a liquid-tight structure is provided between the pair of baffle plates. The structure is characterized in that the bent portion is in contact with the other surface of the pair of baffle plates.

(4 ) The fourth driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It has a pair of baffle plates that sandwich the baffle plate, and a liquid-tight structure is provided between the pair of baffle plates, and the liquid-tight structure is a structure having a sealing member that closes a gap between the pair of baffle plates. The seal member is adhered to one of the pair of baffle plates, the seal member is in contact with the other of the pair of baffle plates, and the seal member is a lip seal . ..
( 5 ) The fifth driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It has a pair of baffle plates that sandwich the baffle plate, and a liquid-tight structure is provided between the pair of baffle plates, and the liquid-tight structure is a structure having a sealing member that closes a gap between the pair of baffle plates. has one recess of the pair of baffle plates, the sealing member is characterized by being accommodated in the recess.
( 6 ) The fastener is preferably an occlusal member that can be inserted in one direction.
( 7 ) The occlusal member is preferably integrated with one of the pair of baffle plates.

( 8 ) The fastener is preferably a hook-shaped member.
( 9 ) The fastener is preferably a bolt or a nut.
( 10 ) It is preferable that one of the pair of baffle plates has a recess, and the labyrinth structure is formed by inserting the other part of the pair of baffle plates into the recess.

(11) The sixth driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It is characterized in that it has a pair of baffle plates that sandwich the baffle plates, and the edges of the pair of baffle plates are in contact with each other and are fixed by fasteners.
(12) The seventh driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It is characterized by having a pair of baffle plates sandwiching the baffle plate and having a labyrinth structure composed of the pair of baffle plates.
(13) The eighth driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It has a pair of baffle plates that sandwich the baffle plate, a bent portion that is curved and formed on one of the pair of baffle plates, and a structure in which the bent portion is in contact with the other surface of the pair of baffle plates. It is characterized by that.
(14) The ninth driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It has a pair of baffle plates that sandwich the baffle plate, and has a lip seal that closes a gap between the pair of baffle plates. The lip seal is provided on one of the pair of baffle plates, and the lip seal is provided. Is in contact with the other of the pair of baffle plates.
(15) The tenth driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and the gear installed in the case. It has a pair of baffle plates that sandwich the baffle plate, has a sealing member that closes the gap between the pair of baffle plates, has a recess in one of the pair of baffle plates, and the sealing member is housed in the recess. It is characterized by being done.
(16) The driving force transmission gear device preferably has a second gear that meshes with the gear.
( 17 ) The automatic transmission of the present invention is characterized by being equipped with the above-mentioned driving force transmission gear device.

( 18 ) The method for manufacturing the first driving force transmission gear device of the present invention includes a gear that transmits a driving force, a case that houses and supports the gear, and contains oil, and is installed in the case. , A lip that is adhered to one tip of the pair of baffle plates that sandwiches the gear and abuts on the other tip of the pair of baffle plates to close the gap between the pair of baffle plates. A method of manufacturing a driving force transmission gear device including a seal, wherein a baffle plate arranged on the back side in the assembling direction of the pair of baffle plates is assembled to the case, and the gear is attached to the case. The step of assembling the baffle plate to the case and the step of assembling the baffle plate arranged on the front side in the assembling direction of the pair of baffle plates to the case are carried out in this order.

( 19 ) The method for manufacturing the second driving force transmission gear device of the present invention includes a gear that transmits a driving force, a case that houses and supports the gear, and contains oil, and is installed in the case. , A pair of baffle plates sandwiching the gear, a recess provided at one tip of the pair of baffle plates, and a seal member housed in the recess and abutting against the other tip of the pair of baffle plates. A method of manufacturing a driving force transmission gear device including, a step of assembling a baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and assembling the gear to the case. It is characterized in that the step, the step of accommodating the seal member in the recess, and the step of assembling the baffle plate arranged in front of the pair of baffle plates in the assembling direction to the case are performed in this order. There is.

( 20 ) The method for manufacturing the third driving force transmission gear device of the present invention includes a gear that transmits a driving force, a case that houses and supports the gear, and contains oil, and is installed in the case. A labyrinth structure in which a pair of baffle plates sandwiching the gear and the other tip of the pair of baffle plates are arranged in an overlapping state outside the side wall of one tip of the pair of baffle plates. A method of manufacturing a driving force transmission gear device including, a step of assembling a baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and assembling the gear to the case. The labyrinth structure is formed by assembling the baffle plate arranged on the front side of the pair of baffle plates in the assembling direction to the case so as to be located on the outside or inside of the baffle plate previously assembled. It is characterized in that the steps to be performed are carried out in this order.
(21) The fourth method for manufacturing a driving force transmission gear device of the present invention includes a gear that transmits a driving force, a case that houses and supports the gear, and contains oil, and is installed in the case. , A pair of baffle plates sandwiching the gear and one tip of the pair of baffle plates are provided to abut the other tip of the pair of baffle plates to close the gap between the pair of baffle plates. A method for manufacturing a driving force transmission gear device including a lip seal, wherein a baffle plate arranged on the back side in the assembling direction of the pair of baffle plates is assembled to the case, and the gear is attached to the case. It is characterized in that the step of assembling to the case and the step of arranging the baffle plate arranged on the front side in the assembling direction of the pair of baffle plates are performed in this order.
(22) The fifth method of manufacturing the driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and a case installed in the case. , A pair of baffle plates sandwiching the gear, a recess provided at one tip of the pair of baffle plates, and a seal member housed in the recess and abutting against the other tip of the pair of baffle plates. A method of manufacturing a driving force transmission gear device including, a step of assembling a baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and assembling the gear to the case. It is characterized in that the step, the step of accommodating the seal member in the recess, and the step of arranging the baffle plate arranged on the front side in the assembling direction of the pair of baffle plates are performed in this order. ..
(23) The sixth method of manufacturing the driving force transmission gear device of the present invention includes a gear for transmitting driving force, a case for accommodating and supporting the gear and containing oil, and a case installed in the case. A labyrinth structure in which a pair of baffle plates sandwiching the gear and the other tip of the pair of baffle plates are arranged in an overlapping state outside the side wall of one tip of the pair of baffle plates. A method of manufacturing a driving force transmission gear device including, a step of assembling a baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and assembling the gear to the case. A step of forming the labyrinth structure by arranging a baffle plate arranged on the front side of the pair of baffle plates in the assembling direction so as to be located on the outside or inside of the baffle plate previously assembled. , Are carried out in this order.
(24) It is preferable that the lip seal is provided on the baffle plate arranged on the front side in the assembling direction of the pair of baffle plates.
(25) It is preferable that the driving force transmission gear device has a second gear that meshes with the gear.

According to the present invention, the liquid-tight structure suppresses the infiltration of lubricating oil from between the pair of baffle plates to the outside of the pair of baffle plates, so that the effect of suppressing the stirring resistance can be enhanced.

It is sectional drawing explaining the automatic transmission which has the driving force transmission gear device which concerns on each embodiment of this invention. It is a block diagram of the automatic transmission which concerns on each embodiment of this invention. It is sectional drawing of the main part of the automatic transmission which concerns on each embodiment of this invention. It is sectional drawing of the main part of the automatic transmission explaining the problem about the gap between baffle plates. It is a figure which shows the main part of the automatic transmission in 1st Embodiment of this invention, (a) is the cross-sectional view of the main part, (b) is the enlarged view of the part A of (a). It is sectional drawing of the main part of the automatic transmission which concerns on the modification of 1st Embodiment of this invention, (a) shows the 1st modification, (b) shows the 2nd modification, (c) is the 1st. 3 Modification examples are shown. It is sectional drawing of the main part of the automatic transmission which concerns on the 2nd Embodiment of this invention and the modified example, (a) shows the 2nd Embodiment, and (b) shows the 1st modified example. It is a figure which shows the main part of the automatic transmission which concerns on the modification of 2nd Embodiment of this invention, (a) is the cross-sectional view of the essential part which concerns on the 2nd modification, and (b) is the 3rd modification. It is a cross-sectional view of a main part according to an example, (c1) is a cross-sectional view of a main part according to the fourth modified example [cross-sectional view taken along the line BB of FIG. 8 (c2)], and (c2) is the fourth FIG. 5 is a cross-sectional view of a main part according to a modified example [cross-sectional view taken along the line CC of FIG. 8 (c1)]. It is sectional drawing of the main part of the automatic transmission which concerns on 3rd Embodiment of this invention and the modified example, (a), (b) show 3rd Embodiment, (c), (d) are the 1st. A modified example is shown, and (e) shows the second modified example. It is a figure which shows the main part of the automatic transmission which concerns on 4th Embodiment of this invention and the modified example, (a) shows the 4th Embodiment, and (b) shows the 1st modified example.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. It should be noted that the embodiments shown below are merely examples, and there is no intention of excluding the application of various modifications and techniques not specified in the following embodiments. The configurations of the following embodiments can be variously modified and implemented without departing from their gist.

[Structure of automatic transmission according to each embodiment]
FIG. 2 is a configuration diagram showing an automatic transmission 2 having a driving force transmission gear device according to each embodiment and configured as a belt-type continuously variable transmission. As shown in FIG. 2, the automatic transmission 2 has a first axis O ₁ , a second axis O ₂ , a third axis O _3, and a fourth axis O _4, and each axis O ₁ to each power transmission element O ₄ is equipped.

On the first shaft O ₁ , the engine 1, the lock-up torque converter 11 connected to the engine 1, the forward / backward switching mechanism 12 connected to the torque converter 11, and the forward / backward switching mechanism 12 are connected. The primary pulleys 13 are arranged in this order.

A secondary pulley 15 connected to the primary pulley 13 via a belt 14 is arranged on the second shaft O _2. On the third axis O ₃ is an idler gear 16 which is drivingly connected to the secondary pulley 15 is arranged. On the fourth shaft O _4, the differential mechanism 17 having a final gear 17a that meshes with the idler gear 16 is disposed.

In the automatic transmission 2 composed of such four axes, each power transmission element is housed and supported in a case 3 composed of a converter housing (first case member) 4 and a transmission case (second case member) 5. To.

The torque converter 11 is housed in the converter housing 4, and the forward / backward switching mechanism 12 is housed on the torque converter 11 side in the axial direction in the space formed by combining the converter housing 4 and the transmission case 5. The first case portion 3a and the third case portion 3c in which the idler gear 16 and the differential mechanism 17 are housed are provided, and the primary pulley 13 and the secondary pulley 15 are housed on the side opposite to the torque converter 11 in the axial direction. The second case portion 3b is provided.

The driving force transmission gear device 10 according to each embodiment is composed of the final gear 17a of the differential mechanism 17 mounted in the case 3 of the automatic transmission 2 and structural elements around the final gear 17a.

As shown in FIGS. 2 and 3, the differential mechanism 17 includes a final gear 17a that meshes with the output gear 16c of the idler gear 16, a differential case 17b in which the final gear 17a is coupled, and a differential case (hereinafter, differential case) 17b. It is equipped with a pinion gear 17c that is equipped inside and revolves integrally with the differential case 17b, and side gears 17d that are connected to the rotating shafts 6a and 6a of the left and right drive wheels 6 and 6.

The shafts (diff shafts) 17e of the left and right side gears 17d are supported by the case 3 by bearings 18a and 18b via the differential case 17b, respectively. Therefore, the final gear 17a coupled to the differential case 17b is also supported by the case 3 via the bearings 18a and 18b.

Tapered roller bearings are applied to the bearings 18a and 18b. In FIG. 3, the right side gear 17d is supported by the first tapered roller bearing 18a in the converter housing 4, and the left side gear 17d is second tapered in the transmission case 5. It is supported by a roller bearing 18b.

The idler gear 16 has an input gear 16b and an output gear 16c fixedly attached to the idler shaft 16a, and the input gear 16b is an output gear fixedly attached to the rotating shaft 15a of the secondary pulley 15 of the continuously variable transmission mechanism. 15b is in mesh.

Such a differential mechanism 17 is housed in a third case portion 3c of a case 3 including a converter housing 4 and a transmission case 5. Further, inside the case 3, lubricating oil is stored in order to supply lubricating oil to each sliding portion such as a bearing portion and a meshing portion of a gear.

FIG. 1 is a cross-sectional view showing the automatic transmission 2 cut along a cross section orthogonal to each of the axes O _{1 to} O _4. As shown in FIG. 1, the axes O _{1 to} O ₄ are compactly arranged so as to be adjacent to each other and aggregate, and the fourth axis O ₄ equipped with the final gear 17a is arranged at the lowermost position in the vertical direction.

An oil pan 7 is mounted on the lower part of the case 3. An oil sump 7a is formed above the inside of the oil pan 7 at the lower part of the case 3, and lubricating oil is stored in the oil sump 7a. The lubricating oil in the oil sump 7a is sucked from the oil suction port 8 by a pump (not shown) and supplied to each lubricating portion from the upper part in the case 3.

Most fourth shaft O ₄ final gear 17a provided arranged in the lower portion, the which lower part is arranged to dip into the oil reservoir 7a, reduced oil level of the lubricating oil in the oil reservoir 7a Unless otherwise, the lower part of the final gear 17a is submerged in oil.

As shown in FIGS. 3 to 5, a baffle plate set 20 (hereinafter, also simply referred to as a baffle plate 20) composed of a pair of baffle plates 21 and 22 is placed between the final gear 17a and the case 3. Have been placed. The baffle plate 20 is a partial region including a vertical portion below the rotation center (fourth axis) O ₄ of the final gear 17a, and is centered on a vertical line Lv1 _{extending downward from the rotation center O 4 of the final gear 17a.} The final gear 17a is arranged so as to surround the final gear 17a in the upstream and downstream regions in the rotation direction.

[Baffle plate according to each embodiment]
The baffle plate 20 is composed of a transmission case-side baffle plate 21 supported by the transmission case 5 and a housing-side baffle plate 22 supported by the converter housing 4.

The transmission case side baffle plate 21 is arranged between the final gear 17a and the transmission case 5, and has a fan-shaped flat plate portion 21a and a partial cylindrical portion formed along the arcuate outer peripheral edge of the flat plate portion 21a. It has 21b and.

The flat plate portion 21a is arranged between the one side surface 17a1 and the inner wall surface 5a of the transmission case 5 facing the one side surface 17a1 so as to cover one side surface 17a1 of the final gear 17a. The partial cylindrical portion 21b is arranged between the outer peripheral gear surface 17a3 and the inner peripheral surface 5b of the outer peripheral wall portion of the transmission case 5 facing the outer peripheral gear surface 17a3 so as to cover the outer peripheral gear surface 17a3 of the final gear 17a.

The flat plate portion 21a and the partially cylindrical portion 21b, as shown in FIG. 1, around the horizontal line Lh1 passing through the rotation center _{O 4} only central angle of 90 degrees in the direction of rotation of the final gear 17a than the vertical line Lv1 upstream of the final gear 17a from being disposed further over to the downstream than the horizontal line Lh2 passing through the rotation center O ₄ Final only central angle of 90 degrees in the direction of rotation of the gear 17a downstream of the final gear 17a than vertical line Lv1.

The housing-side baffle plate 22 is arranged between the final gear 17a and the inner wall surface 4a of the converter housing 4 facing the final gear 17, and is formed on the fan-shaped flat plate portion 22a and the inner peripheral side of the flat plate portion 22a in front view. It has a curved surface portion 22b.

The flat plate portion 22a is arranged so as to cover the other side surface 17a2 of the final gear 17a, and the curved surface portion 22b is arranged so as to cover the differential case 17b adjacent to the other side surface 17a2.

The flat plate portion 22a and a curved portion 22b also, from the vicinity of the horizontal line Lh1 passing through the rotation center _{O 4} of the final gear 17a of the central angle of 90 degrees by the upstream side in the rotational direction of the final gear 17a than vertical line Lv1, Final than vertical line Lv1 They are arranged further over to the downstream than the horizontal line Lh2 passing through the rotation center O ₄ only central angle of 90 degrees in the direction of rotation of the gear 17a downstream of the final gear 17a.

By arranging the baffle plate 20 around the lower portion of the final gear 17a in this way, the oil sump 7a formed below the final gear 17a and storing the lubricating oil is the internal space 20b and the external space of the baffle plate 20. It is divided into 20a and 20a.

As a result, even inside the case 3, the lubricating oil in the oil sump 7a of the outer space (baffle plate outer space) 20a outside the baffle plate 20 is not agitated and does not become a resistance, and the lubricating oil is agitated around the final gear 17a. Will be limited to the space inside the baffle plate 20. Since the amount of oil to be stirred in this way is reduced, the stirring resistance is lowered.

Incidentally, the baffle plate 20, the final downstream side in the rotation direction of the gear 17a (see outline arrows in FIG. 1) is, the horizontal line Lh2 passing through the rotation center O ₄ up to a position higher than the upstream side (the final gear 17a Although it is arranged further downstream (further downstream), this is because the lubricating oil moves in the rotation direction along the inner wall of the case 3 with the rotation of the final gear 17a, and is located on the downstream side in the rotation direction (vertically above in terms of arrangement). This is to cope with the rise in the oil level of the lubricating oil. That is, by providing the baffle plate 20 in this portion, the lubricating oil that tends to move upward along the inner wall of the case 3 is applied to the baffle plate 20 to attenuate the force of moving the baffle plate 20 upward.

Further, as shown in FIG. 3, although the tip edge portion 21c of the partial cylindrical portion 21b of the mission case side baffle plate 21 and the outer peripheral side edge portion 22c of the flat plate portion 22a of the housing side baffle plate 22 are close to each other. A gap G is formed.

The mission case side baffle plate 21 is individually fixed to the mission case 5, and the housing side baffle plate 22 is individually fixed to the converter housing 4. Therefore, an assembly error occurs in addition to the manufacturing error of each member, and a gap G is provided so that these errors can be tolerated.

As described above, by dividing the oil sump 7a into the inside and outside of the baffle plate 20 by the baffle plate 20, it is possible to prevent the oil in the baffle plate outer space 20a from being agitated, but the oil in the baffle plate internal space 20b. Is agitated by the rotation of the final gear 17a, so that this amount of agitation resistance is generated.

If the amount of oil in the baffle plate internal space 20b is large, the stirring resistance generated by the stirring of the oil due to the rotation of the final gear 17a also increases. Therefore, if the oil intrusion into the baffle plate internal space 20b is suppressed, the stirring resistance also decreases. Can be made to.

In the oil sump 7a at the lower part of the case 3, the oil supplied from the oil sump 7a to the upper part of the case 3 lubricates each part, and the surface of each part and the wall surface inside the case 3 (inner wall surface 4a of the converter housing 4) and the like. It flows down along the inner wall surface 5a) of the transmission case 5.

In particular, the oil flowing down along the wall surface in the case 3 drops into the baffle plate outer space 20a, and then infiltrates into the baffle plate internal space 20b through the gap G, and as shown in FIG. 4, the baffle The amount of oil in the plate internal space 20b increases.

As a result, the stirring resistance generated by the stirring of the oil due to the rotation of the final gear 17a also increases. Therefore, if the oil intrusion into the baffle plate internal space 20b from such a gap G is suppressed, the oil in the baffle plate internal space 20b is suppressed. It is possible to reduce the amount of stirring and reduce the stirring resistance.

Therefore, in this device, in the gap G between the pair of baffle plates 21 and 22, that is, in the gap G between the tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion 22c of the housing-side baffle plate 22. A liquid-tight structure 30 is provided to prevent oil from entering the baffle plate inner space 20b from the baffle plate outer space 20a.

Incidentally, as described above, the case side baffle plate 21 and the housing side baffle plate 22, the center angle of 90 degrees by the upstream side in the vicinity of the horizontal line Lh1 than vertical line Lv1 passing through the rotation center O _4, the center than a vertical line Lv1 It is arranged further over to the downstream than the horizontal line Lh2 passing through the rotation center O ₄ only corners 90 degrees downstream final gear 17a, formed in a range corresponding to the leading edge 21c and the outer edge 22c Has been done.

The liquid-tight structure 30 is preferably provided over the entire length of the tip edge portion 21c and the outer peripheral side edge portion 22c, but is limited to the locations where oil is likely to be present in the vertically lower region of the tip edge portion 21c and the outer peripheral side edge portion 22c. It may be provided.

Hereinafter, the specific configuration of the liquidtight structure 30 will be described by exemplifying the first to fourth embodiments.
In each embodiment, the materials of the case-side baffle plate 21 and the housing-side baffle plate 22 are not limited, but metal (sheet metal), resin, or a composite thereof can be used for the baffle plates 21 and 22.

[First Embodiment]
The first embodiment will be described with reference to FIGS. 5 (a) and 5 (b) and FIGS. 6 (a) to 6 (c). In FIGS. 5 (a) and 5 (b) and 6 (a) to 6 (c), the above-mentioned reference numerals indicate the same ones, and thus the description thereof will be omitted.
In the present embodiment, as the liquid-tight structure 30, a sealing member that closes between the pair of baffle plates 21 and 22 is applied. Specifically, as shown in FIGS. 5A and 5B, 1 of the sealing member 1 is applied. One lip seal 31 is applied.

In this example, the base portion 31a of the lip seal 31 is adhered to the outer peripheral side edge portion 22c of the housing side baffle plate 22, and the lip portion 31b at the tip of the lip seal 31 is elastic to the tip edge portion 21c of the case side baffle plate 21. It is in close contact with.

Contrary to FIGS. 5A and 5B, the base portion 31a of the lip seal 31 is adhered to the tip edge portion 21c of the case side baffle plate 21, and the lip portion 31b at the tip of the lip seal 31 is on the housing side. The baffle plate 22 may be elastically adhered to the outer peripheral side edge portion 22c.

Further, various rubber materials are usually applied to the seal member such as the lip seal 31, but the material of the seal member is not limited as long as the lip portion 31b can elastically adhere to the seal surface. ..

As a method of manufacturing the driving force transmission gear device equipped with the lip seal 31 as the liquid-tight structure 30, first, the base portion of the lip seal 31 is attached to one of the tip portions 21c or 22c of the pair of baffle plates 21 and 22. After adhering 31a, it can be carried out as follows. Here, it is assumed that each part is assembled from the converter housing 4 side on the right side in FIGS. 3 and 5.
A step (first step) of assembling the case-side baffle plate 21, which is a baffle plate arranged on the back side of the pair of baffle plates 21 and 22 in the assembling direction, to the case 3 is performed, and then the final gear 17a is attached. A step of assembling to the case 3 (second step) is performed, and then the housing-side baffle plate 22 which is a baffle plate arranged on the front side in the assembling direction of the pair of baffle plates 21 and 22 is attached to the case 3. The step of assembling to (third step) is carried out.

As described above, the driving force transmission gear device according to the present embodiment has a liquid-tight structure 30 in which a lip seal 31 is interposed in the gap G between the pair of baffle plates 21 and 22, so that the baffle plate is formed. Oil is suppressed from entering the baffle plate internal space 20b from the external space 20a through the gap G, and the stirring resistance due to the rotation of the final gear 17a in the baffle plate internal space 20b is reduced.

Further, according to the method of manufacturing the driving force transmission gear device according to the present embodiment, since the lip seal 31 is previously adhered to or attached to either of the pair of baffle plates 21 and 22, the assembling property is improved.

The lip seal 31 may be adhered to either the tip edge portion 21c of the case-side baffle plate 21 or the outer peripheral side edge portion 22c of the housing-side baffle plate 22, but the outer periphery of the housing-side baffle plate 22 may be adhered as in the present embodiment. It is preferable to adhere to the side edge portion 22c.

If the lip seal 31 is previously adhered to the tip edge 21c of the case-side baffle plate 21, the final gear 17a and the case-side baffle plate 21 will be attached when the final gear 17a is assembled after the case-side baffle plate 21 is assembled. The lip seal 31 may be damaged due to interference with the tip edge portion 21c.

However, since the housing-side baffle plate 22 is assembled after the final gear 17a is assembled, if the lip seal 31 is adhered to the outer peripheral side edge 22c side of the housing-side baffle plate 22, the lip seal 31 interferes with the final gear 17a. The risk of injury is avoided.

The structure of the seal member may be as shown in FIGS. 6 (a) to 6 (c). In either case, the sealing member suppresses the infiltration of oil into the baffle plate internal space 20b and reduces the stirring resistance.

In the first modification of the first embodiment shown in FIG. 6A, a groove-shaped recess 22d is formed in the outer peripheral side edge 22c of the housing-side baffle plate 22, and an O-ring as a sealing member is formed in the recess 22d. 32 is installed, and the O-ring 32 is elastically brought into close contact with the tip edge 21c of the case-side baffle plate 21.

In the second modification of the first embodiment shown in FIG. 6B, a groove-shaped recess 21d is formed in the tip edge portion 21c of the case-side baffle plate 21, and an O-ring 32 as a sealing member is formed in the recess 21d. The O-ring 32 is elastically brought into close contact with the outer peripheral side edge 22c of the housing side baffle plate 22.

In the third modification of the first embodiment shown in FIG. 6 (c), either the tip edge portion 21c of the case-side baffle plate 21 or the outer peripheral side edge portion 22c of the housing-side baffle plate 22 is used as a sealing member. One surface of the gasket 33 is adhered, and the other surface of the gasket 33 is brought into close contact with either the tip edge portion 21c or the outer peripheral side edge portion 22c. The gasket 33 is made of paper, for example.

The method of manufacturing the driving force transmission gear device equipped with the O-ring 32 as the sealing member shown in FIGS. 6A and 6B can be carried out as follows. Also in this case, each part shall be assembled from the converter housing 4 side on the right side in FIGS. 3 and 6.
A step (first step) of assembling the case-side baffle plate 21, which is a baffle plate arranged on the back side of the pair of baffle plates 21 and 22 in the assembling direction, to the case 3 is performed, and then the final gear 17a is attached. A step of assembling to the case 3 (second step) is carried out, then a step of accommodating the O-ring 32 of the sealing member in the recess 21d or the recess 22d (second step) is carried out, and then a pair of baffle plates are carried out. A step (fourth step) of assembling the housing-side baffle plate 22 which is a baffle plate arranged on the front side in the assembling direction of 21 and 22 to the case 3 is performed.

However, as shown in FIG. 6B, when the manufacturing method according to the present embodiment is carried out, the inside of the recess of the baffle plate which is arranged on the back side in the assembling direction and is assembled first [in the case of the present embodiment, FIG. It is preferable to accommodate a seal member such as an O-ring 322 in the recess 21d of the case-side baffle plate 21 shown in 6 (b).

A seal member such as an O-ring 32 is assembled in the recess of the baffle plate arranged on the front side in the assembly direction [in the recess 22d of the housing-side baffle plate 22 shown in FIG. 6 (a) in the case of this embodiment]. In this case, since the baffle plate containing the seal member is to be assembled later, the seal member is likely to fall off, but if the seal member is assembled in advance in the recess of the baffle plate to be assembled first, the seal is sealed. It becomes difficult for the member to fall off.

[Second Embodiment]
A second embodiment will be described with reference to FIGS. 7 (a) and 7 (b) and FIGS. 8 (a) to 8 (c2). In FIGS. 7 (a) and 7 (b) and 8 (a) to 8 (c2), the above-mentioned reference numerals indicate the same ones, and thus the description thereof will be omitted.
In the present embodiment, as the liquid-tight structure 30, a structure in which a pair of baffle plates 21 and 22 are fixed in contact with each other by a fastener is applied.

In this embodiment, fastening members such as bolts and nuts are used as fasteners. In the example shown in FIG. 7A, bolts 41 are used as fasteners, and the bolts 41 are concentric with the tip edge 21c of the case-side baffle plate 21 and the outer peripheral edge 22c of the housing-side baffle plate 22. By inserting and fastening the holes 21e and 22e formed, the tip edge portion 21c and the outer peripheral side edge portion 22c are fixed in contact with each other.

In the example shown in FIG. 7A, the bolt 41 is inserted from the outer peripheral side edge 22c side to the tip edge 21c side, and the bolt 41 is screwed into the hole 21e of the tip edge 21c. On the contrary, the bolt 41 may be inserted from the side of the tip edge portion 21c to the side of the outer peripheral side edge portion 22c, and the bolt 41 may be screwed into the hole 21e of the outer peripheral side edge portion 22c. Further, the nut may be fastened to the protruding end of the bolt 41.

As described above, the structure in which the pair of baffle plates 21 and 22 are fixed in contact with each other by the fastener also suppresses the infiltration of oil into the baffle plate internal space 20b and reduces the stirring resistance.

As such a fastener, those shown in FIGS. 7 (b) and 8 (a), (b), (c1), and (c2) may be used. In either case, since the pair of baffle plates 21 and 22 are fixed in contact with each other by the fastener, the infiltration of oil into the baffle plate internal space 20b is suppressed and the stirring resistance is reduced.

In the first modification of the second embodiment shown in FIG. 7B, a stud bolt 42 and a nut 43 screwed thereto are used. That is, the stud bolt 42 is inserted into the hole (here, the hole 21e) formed in one of the tip edge portion 21c and the outer peripheral side edge portion 22c (in this example, the tip edge portion 21c) to fix the base portion, and the tip is fixed. A stud bolt 42 is inserted into a hole (here, a hole 22e) formed in the other side of the edge portion 21c and the outer peripheral side edge portion 22c (in this example, the outer peripheral side edge portion 22c), and the nut 43 is screwed and fastened.

In the second modification of the second embodiment shown in FIG. 8A, an occlusal member (so-called fastener clip) 44 having a locking claw is used instead of the bolt 41 of the second embodiment. The occlusal member 44 has a tapered tip portion 44a, a shaft-shaped intermediate portion 44b, and a hole that are larger than the inner diameters of the holes 21e and 22e and can be reduced in diameter from the inner diameters of the holes 21e and 22e by elastic deformation. It has a base end portion 44c whose diameter is larger than the inner diameters of 21e and 22e.

When the occlusal member 44 is inserted from the tip portion 44a into the holes 21e and 22e of the tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion 22c of the housing-side baffle plate 22, the tip portion 44a becomes the holes 21e and 22e. When the tip portion 44a has passed through the holes 21e and 22e and protrudes from the holes 21e and 22e, the diameter is expanded beyond the inner diameters of the holes 21e and 22e. As a result, the pair of baffle plates 21 and 22 are fixed in contact with each other.

The third modification of the second embodiment shown in FIG. 8B has an occlusal portion 45 (having a tapered tip portion 45a and a shaft-shaped intermediate portion 45b) corresponding to the occlusal member 44 of the second modification. , The tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion 22c of the housing-side baffle plate 22 (in this example, the tip edge portion 21c) are integrally formed.

The tapered tip portion 45a is inserted into the holes 21e and 22e (hole 22e in this example) of the other end of the tip edge portion 21c and the outer peripheral side edge portion 22c (in this example, the outer peripheral side edge portion 22c). When projected from 22e, the tip edge portion 21c and the outer peripheral side edge portion 22c are fixed in contact with each other by the tip portion 45a and the wall portion of the tip edge portion 21c corresponding to the base portion or the outer peripheral side edge portion 22c.

In the fourth modification of the second embodiment shown in FIGS. 8 (c1) and 8 (c2), a hook portion (hook-shaped member) 46 is used. The hook portion 46 is formed from either one of the tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion 22c of the housing-side baffle plate 22 (in this example, the outer peripheral side edge portion 22c) to the other (in this example, the tip end). It has a wedge-shaped tip portion 46a integrally formed via a plate-shaped arm portion 46b toward the edge portion 21c).

The arm portion 46b is elastically deformable in the thickness direction. An inclined surface 46c is formed on the tip portion 46a on one side in the thickness direction [upper in FIGS. 8 (c1) and (c2)], and the inclined surface 46c increases the thickness of the tip portion 46a toward the base. A step portion 46d is formed between the tip portion 46a and the arm portion 46b.
Further, a locking wall 21f for locking the step portion 46d is formed on the other side of the tip edge portion 21c and the outer peripheral side edge portion 22c (in this example, the tip edge portion 21c).

When the tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion of the housing-side baffle plate 22 are brought closer to each other, the inclined surface 46c is in sliding contact with the edge of the locking wall 21f, and the arm portion 46b is in the thickness direction. The tip portion 46a advances on the locking wall 21f while being elastically deformed, and the step portion 46d is locked to the locking wall 21f by the elastic force of the arm portion 46b. By this locking, the tip edge portion 21c and the outer peripheral side edge portion 22c are fixed in contact with each other.

[Third Embodiment]
A third embodiment will be described with reference to FIGS. 9 (a) to 9 (e). In FIGS. 9A to 9E, the above-mentioned reference numerals indicate the same ones, and thus the description thereof will be omitted.
In this embodiment, the labyrinth structure is applied as the liquidtight structure 30.

As shown in FIGS. 9A and 9B, in the present embodiment, the tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion 22c of the housing-side baffle plate 22 are both flat plate shapes 21g. It is formed in 22 g and is arranged so as to approach each other with a slight gap and overlap each other to form a labyrinth structure 51.

Further, as shown in FIGS. 9C and 9D, one of the tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion 22c of the housing-side baffle plate 22 is a double structure 21h or 22h, and the tip end is formed. The labyrinth structure 52 may be formed by inserting the other of the edge portion 21c and the outer peripheral side edge portion 22c into the inside of the double structure 21h or 22h so as to approach and overlap each other with a slight gap.

Further, as shown in FIG. 9E, one of the tip edge portion 21c of the case-side baffle plate 21 and the outer peripheral side edge portion 22c of the housing-side baffle plate 22 (in this case, the outer peripheral side edge portion 22g) is bent. The groove portion 22i is formed, and the other end of the tip edge portion 21c and the outer peripheral side edge portion 22c is inserted into the groove portion 22i in parallel or substantially parallel to each other with a slight gap to approach the labyrinth structure. 53 may be formed.

By providing the labyrinth structures 51, 52, and 53 at the locations where the gaps G are formed in this way, the infiltration of oil from the gaps G into the baffle plate internal space 20b is suppressed.

The method of manufacturing the driving force transmission gear device equipped with the labyrinth structures 51, 52, 53 shown in FIGS. 9A to 9E can be carried out as follows. Also in this case, each part shall be assembled from the converter housing 4 side on the right side in FIGS. 3 and 9.
First, a step (first step) of assembling the case-side baffle plate 21, which is a baffle plate arranged on the back side of the pair of baffle plates 21 and 22 in the assembling direction, to the case 3 is performed, and then the final gear. A step of assembling 17a to the case 3 (second step) is performed, and then the housing-side baffle plate 22, which is a baffle plate arranged on the front side of the pair of baffle plates 21 and 22 in the assembling direction, is first used. A step (third step) of forming the labyrinth structures 51, 52, and 53 by assembling to the case 3 so as to be located outside or inside the assembled case-side baffle plate 21 is performed.

In forming the labyrinth structures 51, 52, 53, if the baffle plates forming the inside of the labyrinth structures 51, 52, 53 are assembled after the final gear 17a is assembled, the final gear 17a and the baffle plate to be assembled later are assembled. Interfere with each other, making it difficult to assemble by the manufacturing method according to this embodiment.

On the other hand, as in the configuration example shown in FIGS. 9A and 9D, the structure in which the baffle plate to be assembled later constitutes the outside of the labyrinth structure, and the configuration example shown in FIG. 9E. If the baffle plate to be assembled later does not protrude toward the assembly space side of the final gear 17a inside the labyrinth structure, the assembly can be easily performed.

[Fourth Embodiment]
A fourth embodiment will be described with reference to FIGS. 10 (a) and 10 (b). In FIGS. 10A and 10B, the above-mentioned reference numerals indicate the same ones, and thus the description thereof will be omitted.
In the present embodiment, as the liquid-tight structure 30, a structure in which a bent portion curvedly formed on one baffle plate 21 or 22 and the bent portion abuts on the surface of the tip end portion of the other baffle plate 22 or 21 is formed. Applying.

As shown in FIGS. 10A and 10B, in the present embodiment, one end of the tip edge 21c of the case-side baffle plate 21 and the outer peripheral edge 22c of the housing-side baffle plate 22 is bent. The bent portion 21j or 22j is formed, the other end of the tip edge portion 21c and the outer peripheral side edge portion 22c is formed into a flat plate shape 21g, 22g, and the bent portion 21j or 22j is in contact with the plate shapes 21g, 22g. It is arranged.

Since the bent portion 21j or 22j is elastically deformed, the bent portion 21j or 22j can be brought into contact with the plate shapes 21g and 22g while allowing manufacturing errors and assembly errors, and the gap G is suppressed, so that the gap G is suppressed. The infiltration of oil into the internal space 20b of the baffle plate is suppressed.

[Other]
Although the embodiments of the present invention have been described above, the present invention is not limited to these embodiments and can be variously modified and implemented without departing from the spirit of the present invention.

For example, in the above embodiment, the final gear 17a of the differential mechanism 17 is illustrated, but the present invention is not limited to the final gear 17a and can be applied to various gears using a baffle plate.

1 Engine 2 Automatic transmission (belt type continuously variable transmission)
3 Case 4 Converter housing (1st case member)
5 Transmission case (second case member)
6 Drive wheel 7 Oil pan 7a Oil sump 8 Oil suction port 10 Drive force transmission gear device 11 Lock-up torque converter 12 Forward / backward switching mechanism 13 Primary pulley 14 Belt 15 Secondary pulley 16 Idler gear 17 Differential mechanism 17a Final gear 17b Differential case 18a 1st bearing (1st taper roller bearing)
18b 2nd bearing (2nd taper roller bearing)
20 Baffle plate 20a Baffle plate external space 20b Baffle plate internal space 21 Mission case side baffle plate 22 Housing side baffle plate 21d, 22d Recess 21j, 22j Bending part 21g, 22g Plate shape 30 Liquidtight structure 31 Lip seal 32 O-ring 41 Bolt 42 Stud bolt 43 Nut 44 Occlusal member 45 Occlusal part (occlusal member)
46 Hook part (hook-shaped member)
51, 52, 53 labyrinth structure Lv1 vertical line Lh1, Lh2 horizon O ₄ fourth shaft (rotation center of the final gear 17a)

Claims (25)

Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
A liquidtight structure is provided between the pair of baffle plates.
The liquid-tight structure is a driving force transmission gear device characterized in that the pair of baffle plates are in contact with each other and are fixed by fasteners. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
A liquidtight structure is provided between the pair of baffle plates.
The liquid-tight structure is a driving force transmission gear device characterized by having a labyrinth structure composed of the pair of baffle plates. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
A liquidtight structure is provided between the pair of baffle plates.
The liquid-tight structure is characterized in that a bent portion curvedly formed on one of the pair of baffle plates and the bent portion abut on the other surface of the pair of baffle plates. Transmission gear device. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
A liquidtight structure is provided between the pair of baffle plates.
The liquid-tight structure is a structure having a sealing member that closes a gap between the pair of baffle plates.
The sealing member is adhered to one of the pair of baffle plates.
The sealing member is in contact with the other of the pair of baffle plates.
A driving force transmission gear device, wherein the seal member is a lip seal. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
A liquidtight structure is provided between the pair of baffle plates.
The liquid-tight structure is a structure having a sealing member that closes a gap between the pair of baffle plates.
One of the pair of baffle plates has a recess.
A driving force transmission gear device, wherein the seal member is housed in the recess. In claim 1 ,
The fastener is a driving force transmission gear device characterized by being an occlusal member that can be inserted in one direction. In claim 6 ,
A driving force transmission gear device, wherein the occlusal member is integrated with one of the pair of baffle plates. In claim 1 ,
The fastener is a driving force transmission gear device characterized by being a hook-shaped member. In claim 1 ,
The driving force transmission gear device, wherein the fastener is a bolt or a nut. In claim 2 ,
One of the pair of baffle plates has a recess.
A driving force transmission gear device characterized in that the labyrinth structure is formed by inserting the other part of the pair of baffle plates into the recess. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
The edges of the pair of baffle plates were in contact with each other and fixed by fasteners.
A driving force transmission gear device characterized by the fact that. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
It has a labyrinth structure composed of the pair of baffle plates.
A driving force transmission gear device characterized by the fact that. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
A bent portion formed in a curved shape on one of the pair of baffle plates,
It has a structure in which the bent portion is in contact with the other surface of the pair of baffle plates.
A driving force transmission gear device characterized by the fact that. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
It has a lip seal that closes the gap between the pair of baffle plates.
The lip seal is provided on one of the pair of baffle plates.
The lip seal is in contact with the other of the pair of baffle plates.
A driving force transmission gear device characterized by the fact that. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
It has a pair of baffle plates that are installed in the case and sandwich the gear.
It has a sealing member that closes the gap between the pair of baffle plates.
One of the pair of baffle plates has a recess.
The sealing member is housed in the recess.
A driving force transmission gear device characterized by the fact that. In any one of claims 1 to 15,
Has a second gear that meshes with the gear
A driving force transmission gear device characterized by the fact that. An automatic transmission equipped with the driving force transmission gear device according to any one of claims 1 to 16. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
A pair of baffle plates installed in the case and sandwiching the gear,
A driving force transmission gear device including a lip seal that is adhered to one tip of the pair of baffle plates and abuts on the other tip of the pair of baffle plates to close the gap between the pair of baffle plates. It is a manufacturing method of
The process of assembling the baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and
The process of assembling the gear to the case and
A method for manufacturing a driving force transmission gear device, which comprises assembling a baffle plate arranged on the front side in the assembling direction of the pair of baffle plates to the case in this order. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
A pair of baffle plates installed in the case and sandwiching the gear,
A recess provided at one tip of the pair of baffle plates and
A method for manufacturing a driving force transmission gear device including a seal member housed in the recess and abutting on the other tip of the pair of baffle plates.
The process of assembling the baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and
The process of assembling the gear to the case and
The step of accommodating the seal member in the recess and
A method for manufacturing a driving force transmission gear device, which comprises assembling a baffle plate arranged on the front side in the assembling direction of the pair of baffle plates to the case in this order. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
A pair of baffle plates installed in the case and sandwiching the gear,
Manufacture of a driving force transmission gear device including a labyrinth structure in which the other tips of the pair of baffle plates are arranged in an overlapping state on the outer side of the side wall of one tip of the pair of baffle plates. It ’s a method,
The process of assembling the baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and
The process of assembling the gear to the case and
A step of assembling the baffle plate arranged on the front side in the assembling direction of the pair of baffle plates to the case so as to be located on the outside or inside of the baffle plate previously assembled to form the labyrinth structure. A method for manufacturing a driving force transmission gear device, which comprises carrying out the above steps in this order. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
A pair of baffle plates installed in the case and sandwiching the gear,
A lip seal provided at one tip of the pair of baffle plates, which comes into contact with the other tip of the pair of baffle plates and closes the gap between the pair of baffle plates.
It is a manufacturing method of a driving force transmission gear device equipped with
The process of assembling the baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and
The process of assembling the gear to the case and
The step of arranging the baffle plate arranged on the front side in the assembling direction of the pair of baffle plates is carried out in this order.
A method for manufacturing a driving force transmission gear device. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
A pair of baffle plates installed in the case and sandwiching the gear,
A recess provided at one tip of the pair of baffle plates and
A method of manufacturing a driving force transmission gear device including a seal member housed in the recess and abutting on the other tip of the pair of baffle plates.
The process of assembling the baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and
The process of assembling the gear to the case and
The step of accommodating the seal member in the recess and
A method for manufacturing a driving force transmission gear device, characterized in that the steps of arranging the baffle plates arranged on the front side in the assembling direction of the pair of baffle plates are carried out in this order. Gears that transmit driving force and
A case that houses and supports the gear and has oil built-in,
A pair of baffle plates installed in the case and sandwiching the gear,
Manufacture of a driving force transmission gear device including a labyrinth structure in which the other tips of the pair of baffle plates are arranged in an overlapping state on the outer side of the side wall of one tip of the pair of baffle plates. It ’s a method,
The process of assembling the baffle plate arranged on the back side of the pair of baffle plates in the assembling direction to the case, and
The process of assembling the gear to the case and
The step of forming the labyrinth structure by arranging the baffle plate arranged on the front side in the assembling direction of the pair of baffle plates so as to be located on the outside or the inside of the baffle plate previously assembled. Carry out in order
A method for manufacturing a driving force transmission gear device. 21.
The lip seal is provided on a baffle plate arranged on the front side in the assembly direction of the pair of baffle plates.
A method for manufacturing a driving force transmission gear device. In any one of claims 18 to 24,
The driving force transmission gear device has a second gear that meshes with the gear.
A method for manufacturing a driving force transmission gear device.

Images