JP2021001672A - Transaxle - Google Patents

Abstract

To provide a transaxle suppressing an increase in oil agitation torque by lowering an oil level in the transaxle while suppressing costs, and capable of improving energy efficiency such as electric power consumption and fuel consumption.SOLUTION: A transaxle 10 has a transaxle housing 20, a differential ring gear 60, and a speed reducing mechanism 44 equipped with a gear body 50, and a spacer side space portion 36 into which oil in the transaxle housing 20 flows. In an inner space 21 of the transaxle housing 20, a differential area 21b and a primary speed reduction area 21a are formed. Between the differential area 21b and the primary area 21a, oil can flow back and forth. On the gear body 50, a communication hole 54 penetrating that in an axial direction X is formed.SELECTED DRAWING: Figure 1

Description

The present invention relates to a structure for reducing the rotational resistance that a gear receives from oil in a transaxle.

Conventionally, in the structure of a transaxle, a wing is attached to a rotating member (gear, shaft, etc.) in order to lubricate the oil by splashing, or the oil is scooped up by the gear. On the other hand, if the amount of lubricating oil in the transaxle is large, the oil stirring torque becomes large, resulting in loss torque. In order to solve the problem of increasing the oil stirring torque, for example, Patent Document 1 below discloses a structure for reducing the rotational resistance that the ring gear receives from the oil.

Japanese Unexamined Patent Publication No. 2016-11734

However, it has been pointed out that it is necessary to add extra parts or provide a partition in order to store oil, which increases the cost. Further, if an oil pump or the like is provided to return the stored oil to the transaxle again, there is a problem that the cost increases more and more.

Therefore, the present invention can contribute to the improvement of energy efficiency such as electricity consumption and fuel consumption by suppressing the increase in oil agitation torque by lowering the oil level in the transaxle while suppressing the cost. The purpose was to provide.

Here, in the transaxle, the space in which the differential ring gear is housed (diff area) and the space in which the primary reduction mechanism such as the input side gear and the output side gear are housed (primary deceleration area) are mutually connected. A vertical layout that allows oil to flow in and out is provided. In such a transformer axle, oil is sent to the primary reduction mechanism side (primary deceleration region) by the rotation of the differential gear, the amount of oil in the primary deceleration region on the high rotation side increases, and torque loss due to oil stirring torque increases. There is a technical problem of becoming larger.

There is also a problem of how to return the oil flowing into the primary deceleration region side to the differential region while reducing the influence of torque of the rotating body or the like.

When the inventors of the present invention examined a structure for solving the above-mentioned problems, they provided a configuration for temporarily storing the oil scooped up by rotating members such as a ring gear and a gear on the primary reduction mechanism side. It has been found that the above-mentioned problems can be solved by providing a through hole inside the gear on the primary reduction mechanism side.

The transaxle of the present invention provided based on the above findings includes a transaxle housing containing oil, a differential gear, a reduction mechanism including a gear body for transmitting power to the differential gear, and the inside of the transaxle housing. The transaxle housing has a storage space for inflowing the oil, and a differential region in which the differential ring gear is housed and a primary speed reduction region in which the speed reduction mechanism is housed are formed in the internal space of the transaxle housing. The oil can flow back and forth between the differential region and the primary deceleration region, and the gear body is formed with a communication hole penetrating in the axial direction, and the communication hole is formed. However, it is characterized in that it communicates from the storage space portion to the differential region.

According to the transaxle of the present invention, the oil scooped up by the differential ring gear or the rotating body can be temporarily stored in the storage space. As a result, the transaxle of the present invention can lower the oil level inside the transaxle. As a result, the transaxle of the present invention can reduce the oil stirring torque and suppress the increase in torque loss, and can contribute to the improvement of energy efficiency such as electricity cost and fuel consumption while suppressing the cost. ..

Further, according to the transaxle of the present invention, the oil in the storage space can flow into the differential region through the communication hole of the rotating body. That is, according to the transaxle of the present invention, the oil can be returned to the differential region without being affected by the torque of the rotating body in the primary deceleration region. As a result, the configuration of the differential region (ring gear, etc.) can be efficiently lubricated.

Further, in the transaxle of the present invention, the communication hole has a different opening diameter in the axial direction, and the communication hole on the storage space side has a large diameter larger than the opening diameter on the differential region side. It should be a part.

According to the above configuration, oil can be stored in a large diameter portion of the communication hole (the communication hole has an oil catching function), and the oil level in the transaxle can be lowered more efficiently. Further, by increasing the opening diameter of the communication hole on the storage space side and reducing the opening diameter of the communication hole on the differential region side, oil can easily flow to the differential region side. As a result, the oil can be returned to the differential region more effectively.

Further, in the transaxle of the present invention, the transaxle housing is provided with a partition portion for partitioning the differential region and the primary deceleration region, and the compartment portion is provided with the differential region and the primary deceleration region. It is preferable that an oil communication hole for allowing oil to communicate with the vehicle is provided.

According to the above configuration, the oil scooped up by the defling gear can be sent to the primary deceleration region. Further, according to the above configuration, it is possible to suppress the occurrence of an extreme bias between the amount of oil on the differential region side and the amount of oil on the primary deceleration region side.

Here, if the oil communication hole is large, the oil sent to the primary deceleration region immediately returns to the differential region, and the oil scooped up by the gears on the primary deceleration region side (input side gear, output side gear, etc.) It is expected that the amount will decrease. Then, the amount of oil flowing into the storage space or the communication hole provided in the gear body may decrease. Therefore, the oil communication hole is large in the radial direction so that the amount of oil scooped up by the differential ring gear (Ma) is larger than the amount of oil returned from the primary deceleration region to the differential region (Mb) (Ma> Mb). Is desirable to be adjusted. As a result, it is possible to prevent the amount of oil flowing into the storage space and the communication hole from becoming insufficient.

Further, in the transaxle of the present invention, the transaxle housing is provided with a partition portion for partitioning the differential region and the primary deceleration region, and the compartment portion is provided with the differential region and the primary deceleration region. It is preferable that an air hole for communicating with the air is provided.

According to the above configuration, the oil can be moved back and forth between the differential region and the primary deceleration region more smoothly.

According to the present invention, a transaxle capable of lowering the oil level in the transaxle to suppress an increase in oil agitation torque and contributing to improvement of energy efficiency such as electricity consumption and fuel consumption while suppressing costs. Can be provided.

It is a top view which shows the transaxle which concerns on embodiment of this invention. It is a top view which shows the oil catch part of the transaxle of FIG. FIG. 5 is a cross-sectional view taken along the line AA'of the transaxle of FIG. (A) is a perspective view showing a gear housing of the transaxle of FIG. 1, (b) is a sectional view showing a partition, and (c) is a sectional view showing a modified example of the partition. It is sectional drawing in the side view which shows the gear housing of FIG. It is a conceptual diagram in the side view which shows the transaxle of FIG. It is a figure which shows the section part of the transaxle of FIG. It is sectional drawing which shows the gear body of the transaxle of FIG.

Hereinafter, the transaxle 10 according to the embodiment of the present invention will be described in detail with reference to the drawings.

As shown in FIG. 1, the transaxle 10 is provided in the vehicle V. The transaxle 10 is connected to the motor 2 (drive source). The transaxle 10 and the motor 2 constitute a drive device 1 for the vehicle V.

In the drive device 1, the axis L1 which is the rotation axis of the input side gear 46 provided in the reduction gear 42 and the axis L2 which is the rotation axis of the output side gear 52 (gear body 50) are along the front-rear direction of the vehicle V. It is a so-called vertical layout. The drive device 1 can drive the vehicle V by transmitting the power output from the motor 2 to the drive wheels 80 via the reduction mechanism 42.

In the following description, the front-rear direction of the vehicle V may be simply described as "front-rear direction X" (or axial direction X).

Further, in the front-rear direction X of the vehicle V, the front may be simply referred to as "front Fr" and the rear may be simply referred to as "rear Rr". Further, in the vertical direction H of the vehicle V, the upper part may be simply referred to as "upper Up" and the lower part may be simply referred to as "lower Lw".

The motor 2 is a so-called motor generator that has a power generation function in addition to a motor function that outputs power for traveling the vehicle toward the drive wheels 80. In the motor 2, the rotor (not shown) rotates with respect to the stator (not shown) in the motor housing by supplying electric power from the battery (not shown) via an inverter (not shown). ..

As shown in FIG. 1, the transaxle 10 includes a transaxle housing 20, a reduction mechanism 42, and a differential gear mechanism 58. As shown in FIG. 1, the reduction mechanism 42 and the differential gear mechanism 58 are housed in the transaxle housing 20. Further, the transaxle 10 is provided with a plurality of gears 40 (rotating members) in the internal space 21.

As shown in FIG. 1, the reduction gear 42 includes a gear body 50 in which an input side gear 46 (rotating member), an output side gear 52, and an intermediate gear 56 are integrated. These configurations of the speed reduction mechanism 42 are housed inside the transaxle housing 20.

The input side gear 46 (rotating member) is a gear arranged so that the axis L1 is along the front-rear direction X of the vehicle V. The shaft portion 44 of the input side gear 46 is connected to a motor shaft (not shown), and rotational power is transmitted from the motor 2 to rotate the gear 46.

The gear body 50 is a shaft body in which the output side gear 52 and the intermediate gear 56 are connected by a spline structure. As shown in FIG. 8, the gear body 50 is formed with a communication hole 54 penetrating in the axis L2 direction.

The output side gear 52 is arranged so as to mesh with the input side gear 46. The output side gear 52 is arranged at a position where the axis L2 is offset from the axis L1 of the input side gear 46.

As shown in FIG. 6, the gear body 50 is arranged in the space portion 36 on the seat side, which will be described later, on the rear Rr side of both sides in the axial direction X, and the front Fr side (intermediate gear 56) reaches the differential region 21b. It is arranged like this. Further, the gear body 50 is arranged so that the shaft portion 51 is located higher than the oil level F in the transaxle housing 20.

The communication hole 54 is a hollow through hole formed inside the gear body 50. As shown in FIG. 6, when the gear body 50 is arranged in the transaxle 10, the communication hole 54 is arranged so as to communicate the space portion 36 on the seat side and the differential region 21b, which will be described later.

Further, as shown in FIG. 8, the communication holes 54 have different radial sizes in the axial direction X. More specifically, the communication hole 54 on the seat side space 36 side (rear Rr side) is a large diameter portion 54a having a large diameter, and the communication hole 54 on the differential region 21b side (front Fr side) is It is said that the small diameter portion 54b has a small diameter. Therefore, the communication hole 54 has a structure in which oil easily flows from the space portion 36 on the seat side having a large diameter toward the differential region 21b having a small diameter.

The transaxle 10 has a function of storing oil in the communication hole 54. As a result, a large amount of oil can flow into the large diameter portion 54a or the like, and the oil level in the transaxle housing 20 can be lowered.

Further, as will be described in detail later, in the transaxle 10, the oil in the spacer side space 36 can be returned to the differential region 21b through the communication hole 54. Therefore, the transaxle 10 can return the oil to the differential region 21b while avoiding the influence of the torque of the gear 40 (input side gear 46 and output side gear 52) arranged in the primary deceleration region 21a. As a result, it can contribute to higher energy efficiency (electricity cost and fuel consumption).

The input side gear 46 and the output side gear 52 are provided so that their respective axes are along the front-rear direction X of the vehicle V. Therefore, when the input side gear 46 and the output side gear 52 rotate, the oil contained in the transaxle housing 20 is scooped up toward the width direction W (side of the transaxle 10) of the vehicle V.

The intermediate gear 56 is provided so as to be integrally rotatable with respect to the shaft portion 51 of the output side gear 52. The intermediate gear 56 meshes with the differential gear 60 of the differential gear mechanism 58. Therefore, the reduction mechanism 42 can reduce the output of the motor 2 and transmit it to the differential gear mechanism 58.

As shown in FIG. 1, the differential gear mechanism 58 includes a differential gear 60. The differential gear mechanism 58 is connected to a pair of drive wheels 80 via a pair of drive axles 82. The differential gear mechanism 58 distributes and transmits the power of the motor 2 transmitted to the differential gear 60 to each of the pair of drive wheels 80. When a rotation difference occurs between the pair of drive wheels 80, the differential gear mechanism 58 transmits power while allowing the rotation difference.

The differential gear 60 is housed inside the transaxle housing 20. The differential ring gear 60 is in a direction (front-rear direction X) where the rotation directions intersect with the rotation direction (width direction W) of the output side gear 52, the input side gear 46, and the like. When the differential gear 60 rotates, the oil contained in the transaxle housing 20 is scooped up toward the rear Rr side of the vehicle V.

The transaxle housing 20 is a hollow member that houses the reduction mechanism 42 and the differential gear mechanism 58. More specifically, in the transaxle housing 20 of the present embodiment, the primary deceleration portion 22 accommodating the deceleration mechanism 42 and the differential portion 24 accommodating the differential gear mechanism 58 are integrally formed. Oil is stored in the transaxle housing 20.

As shown in FIG. 1, the internal space 21 of the transaxle housing 20 accommodates a primary deceleration region 21a (inside the primary deceleration portion 22) in which the input side gear 46 and the output side gear 52 are housed, a differential ring gear 60, and the like. The differential region 21b (inside the differential portion 24) to be formed is formed. As described above, the transaxle 10 is configured such that the differential ring gear 60 and the reduction mechanism 42 such as the input side gear 46 and the output side gear 52 are housed in the same internal space 21.

More specifically, as shown in FIG. 6, the transaxle housing 20 is provided with a partition portion 23 that divides the internal space 21 into a primary deceleration region 21a and a differential region 21b. As shown in FIG. 7, the section 23 is provided with a plurality of through holes. More specifically, an oil communication hole 23a and an air hole 23b are provided as through holes for communicating the primary deceleration region 21a and the differential region 21b. Further, the compartment 23 is provided with a gear insertion hole 23c through which the gear body 50 is inserted.

The gear body 50 is inserted through the gear insertion hole 23c and is arranged so as to reach the differential region 21b from the primary deceleration region 21a.

As shown in FIG. 7, the oil communication hole 23a is provided near the lower Lw of the compartment 23. Oil can be exchanged between the primary deceleration region 21a and the differential region 21b via the oil communication hole 23a and the gear insertion hole 23c. Further, the air hole 23b is provided near the upper Up of the compartment 23.

Here, if the oil communication hole 23a is large, the oil sent to the primary deceleration region 21a immediately returns to the differential region 21b, and the gear 40 on the primary deceleration region 21a side (input side gear 46, output side gear 52, etc.) ) Is expected to reduce the amount of oil that is scooped up. Then, the amount of oil flowing into the communication hole 54 provided in the space portion 36 on the spacer side or the gear body 50 may decrease. Therefore, the radial size of the oil communication hole 23a is such that the "amount of oil scooped up by the differential ring gear 60 (Ma)" is larger than the "amount of oil returned from the primary deceleration region 21a to the differential region 21b (Mb)". It is desirable to adjust so that it becomes large (Ma> Mb). As a result, it is possible to prevent the amount of oil flowing into the space 36 on the seat side and the communication hole 54 from being insufficient. Since the viscosity of the oil (diff oil) is high, when the oil returns from the primary deceleration region 21a to the differential region 21b through the oil communication hole 23a, the oil slowly (slowly) flows in.

As shown in FIG. 1, the transaxle housing 20 is provided with a spacer 26 that forms a seat (seat surface) for connecting the transaxle 10 and the motor 2. Further, the transaxle housing 20 is provided with a gear housing 30 attached to the spacer 26.

As shown in FIG. 6, oil is contained in the transaxle housing 20. The oil contained in the transaxle housing 20 is scooped up in the rotation direction of these gears 40 as the differential ring gear 60, the input side gear 46, the output side gear 52, and the like rotate.

As shown in FIG. 1, an oil catching portion 28 (oil storage portion) is provided in the primary deceleration portion 22 of the transaxle housing 20.

As shown in FIGS. 2 and 3, the oil catch portion 28 is a pocket-shaped portion provided so as to partition a side portion of the transaxle housing 20. The oil catch portion 28 is provided inside the transaxle housing 20. Further, the oil catch portion 28 is provided at a position on the side of the transaxle 10. The oil catch portion 28 is provided so that the upper Up side opens, and can receive the oil scooped up by the rotation of the input side gear 46 and the output side gear 52 on the side of the transaxle housing 20.

As shown in FIGS. 2 and 3, the oil catch portion 28 is provided inside the transaxle housing 20 in the vicinity of the input side gear 46 and the output side gear 52, and is provided on the Up side above the oil level F. There is. More specifically, the oil catch portion 28 is provided so as to be adjacent to the gear 40 (rotating member) arranged in the primary reduction gear 22 such as the input side gear 46 and the output side gear 52.

To further explain from another viewpoint, the oil catch portion 28 is located outside the peripheral surface of the gear 40 (input side gear 46 and output side gear 52) provided so that the axis line is along the front-rear direction X of the vehicle V. It is provided in. Further, the oil catch portion 28 is provided so as to be at a position higher than the oil level F.

Here, as shown in FIG. 3, when the input side gear 46 and the output side gear 52 rotate, the oil (oil that stays at the bottom of the primary deceleration region 21a) in the internal space 21 of the transaxle 10 is replaced by these gears 40. It is scraped up toward the side of the transaxle 10 (the width direction W of the vehicle V) along the direction of rotation of the transaxle. So to speak, the oil catch portion 28 can efficiently receive the oil scooped up by the rotation of the gear 40 arranged in the primary deceleration region 21a such as the input side gear 46 and the output side gear 52.

Further, by providing the oil catch portion 28 at a position on the side of the transaxle 10, the height of the transaxle 10 can be lowered as compared with the case where the oil catch portion 28 is provided on the upper Up side.

As shown in FIG. 2, an oil hole 29 (first oil guide portion) as a through hole is provided on the rear Rr side of the oil catch portion 28. More specifically, the oil hole 29 is formed so as to be on the lower Lw side (bottom side) of the oil catch portion 28, and the oil received by the oil catch portion 28 flows down to the spacer side space portion 36. It is formed to make it.

The spacer 26 is a portion that functions as a seating surface when connecting the transaxle 10 to the motor 2. In other words, the transaxle 10 is connected to the motor 2 so as to use the spacer 26 as an intervening member. Further, the spacer 26 is provided at the position closest to the motor 2 in the transaxle 10. A gear housing 30, which will be described later, is attached to the spacer 26.

The gear housing 30 is provided to support the input side gear 46 and the output side gear 52 (gear body 50). As shown in FIG. 2, the gear housing 30 is attached to the seat portion 26 of the transaxle housing 20.

As shown in FIG. 4A, the gear housing 30 is provided with a mounting portion 31, two gear accommodating portions 32, and a recess 34. The gear housing 30 is provided with two gear accommodating portions 32, an output side gear accommodating portion 32a and an input side gear accommodating portion 32b.

Further, as shown in FIG. 5, the internal space of the gear housing 30 (mainly the internal space of the gear accommodating portion 32) is hollow, and the interstitial space portion 36 (storage space portion) is provided as a partitioned space. It is formed. Further, as shown in FIG. 5, a plurality of oil holes 35 (first oil guide portion, second oil) in the gear housing 30 allow oil to flow in or out by communicating the inside and the outside of the spacer side space 36. Information section) is provided.

The output side gear accommodating portion 32a accommodates and supports the end portion (rear Rr side of the shaft portion 51) on the rear Rr side (motor 2 side) of the output side gear 52. Further, the input side gear accommodating portion 32b is supported by inserting the shaft portion 44 of the input side gear 46. Further, bearings 70 are fitted inside each gear accommodating portion 32 of the gear housing 30, and each gear 40 (input side gear 46 and output side gear 52) is rotatably supported via the bearing 70. ..

As shown in FIG. 4A, a recess 34 is formed on the upper Up side of the gear housing 30. The recess 34 is provided as a recess provided at a position serving as a connecting portion between the two gear accommodating portions 32. In other words, the recess 34 is a recessed portion of two substantially cylindrical housings formed substantially cylindrically to accommodate the gear 40. The recess 34 is formed along the front-rear direction X (the axial direction of the input side gear 46 and the output side gear 52). Further, as shown in FIG. 5, the bottom portion 34b of the recess 34 is formed so as to have a downward slope toward the rear Rr side (motor 2 side).

As shown in FIG. 4A, the recess 34 is provided in the gear housing 30 on the upper Up side of the input side gear 46 and the output side gear 52. Further, the recess 34 is provided at a position on the rear Rr side of the differential ring gear 60. Therefore, the recess 34 receives the oil scooped up by the input side gear 46 and the output side gear 52 and the oil scooped up toward the rear Rr side by the diff ring gear 60.

Further, as shown in FIG. 4A, a partition 34a is provided on the front Fr side of the recess 34. The oil scooped up by the gear 40 flows into the recess 34. An oil hole 35 (inflow side oil hole 35a, second oil guide portion) is formed as a through hole at the bottom of the recess 34. The inflow side oil hole 35a (second oil guide portion) is provided so as to communicate with the spacer side space portion 36 from the recess 34. Further, the bottom portion 34b of the recess 34 is formed so as to have a downward slope toward the rear Rr side. Therefore, the oil flowing into the recess 34 is guided by the inclination of the bottom 34b of the recess 34 and flows down to the rear Rr side to reach the inflow side oil hole 35a while being blocked from flowing down to the front Fr side by the partition 34a. , It flows into the spacer side space 36 through the inflow side oil hole 35a. As a result, the oil received in the recess 34 can be efficiently guided to the spacer side space 36. The partition 34a may have a plate-like shape as shown in FIG. 4B, or may have a slope-like shape inclined toward the differential region 21b side as shown in FIG. 4C. If the partition 34a has a slope shape, the oil is transmitted from the differential region 21b side to the inclined surface of the partition 34a, and the oil easily flows into the recess 34.

Further, as shown in FIG. 5, the gear housing 30 is formed with an outflow side oil hole 35b (outflow side oil guide portion) and an outflow side oil hole 35c as oil holes 35. The outflow side oil hole 35b (outflow side oil guide portion) is formed in the vicinity of the bearing 70. Therefore, the oil that has flowed into the spacer side space 36 lubricates the bearing 70 through the outflow side oil hole 35b, and gradually flows down to the primary deceleration region 21a (the oil is returned to the primary deceleration region 21a). Further, the outflow side oil hole 35c is provided so as to supplement the amount of oil flowing out from the outflow side oil hole 35b.

<Oil flow in transaxle>
Subsequently, the flow of oil in the transaxle housing 20 will be described with reference to FIG.

As described above, the vehicle V has a so-called vertical layout, and the gear 40 of the reduction mechanism 42 such as the input side gear 46 has an axis line arranged along the front-rear direction X of the vehicle V. Further, in the internal space 21 of the transaxle 10, a differential gear 60 is arranged on the front Fr side, and a reduction mechanism 42 such as an input side gear 46 is arranged on the rear Rr side. The oil contained in the transaxle 10 is conveyed to the rear Rr side (primary deceleration region 21a side) by the rotation of the differential ring gear 60.

Further, when the input side gear 46 and the output side gear 52 housed in the primary deceleration region 21a rotate, the amount of oil in the primary deceleration region 21a increases due to the oil conveyed to the primary deceleration region 21a by the differential ring gear 60. There is a problem peculiar to the vehicle V having a vertical layout, that the torque loss due to the oil stirring torque when the input side gear 46 and the output side gear 52 rotate becomes large.

In a vehicle V having a vertical layout and in which the primary deceleration side gear 40 (input side gear 46 and output side gear 52) constituting the diff ring gear 60 and the reduction mechanism 42 is arranged in the same internal space 21, the diff ring gear 60 The oil is conveyed to the primary deceleration side by the rotation of the gear, and there is a problem that the oil level F on the primary deceleration side (oil level F in the primary deceleration region 21a) becomes high. Another problem is that the direction in which the input side gear 46 and the output side gear 52 rotate to lubricate the oil in a splash (side of the transaxle 10) is different from the direction in which the oil is desired to be splash lubricated (for example, the differential ring gear 60 side). was there.

The problem of the vehicle V having such a vertical layout is solved by providing the space portion 36 on the seat side, the oil catch portion 28, the recess 34, the plurality of oil holes 35, and the like in the transaxle 10. Hereinafter, a specific description will be given.

As shown in FIG. 5, the oil scooped up by the rotation of the diff ring gear 60 is conveyed to the rear Rr side (motor 2 side) in the transaxle 10 and is received by the recess 34. Further, as shown in FIG. 5, the oil that has reached the recess 34 flows down to the rear Rr side along the inclination of the bottom 34b of the recess 34, reaches the spacer side space 36 through the inflow side oil hole 35a, and reaches the spacer side space 36. It is temporarily stored.

Further, as shown in FIG. 3, when the input side gear 46 and the output side gear 52 rotate, the oil in the transaxle 10 is received by the oil catch portion 28 in the transaxle 10. The oil that has reached the oil catch portion 28 flows into the spacer side space portion 36 through the oil hole 29 (first oil guide portion) and is temporarily stored.

In this way, when the gears 40 such as the differential gear 60 and the input side gear 46 are rotating (when the vehicle V is driven), the oil scooped up by these gears 40 is received by the oil catch portion 28 and the recess 34. It flows into the space 36 on the side of the gear and is temporarily stored. As a result, the amount of oil staying in the primary deceleration region 21a can be reduced to lower the oil level F, and the oil stirring torque of the input side gear 46 and the like can be reduced.

The transaxle 10 can reduce the amount of oil in the transaxle housing 20 when the gear 40 rotates, and can reduce the rotational resistance of the gear 40. As a result, the transaxle 10 can reduce the torque loss (no-load loss torque) due to the oil stirring torque of the gear 40, and can improve the energy efficiency such as the power consumption and fuel consumption of the vehicle V.

Further, as shown in FIG. 5, the oil stored in the spacer side space 36 gradually flows into the primary deceleration region 21a through the outflow side oil hole 35b (outflow side oil guide portion). More specifically, the oil stored in the spacer side space 36 is primarily decelerated again through the outflow side oil hole 35b formed in the vicinity of the bearing 70 (not shown in FIGS. 5 and 6). The bearing 70 is lubricated when it is returned to the region 21a and flows into the primary deceleration region 21a. As a result, when the gear 40 is stopped (when the vehicle V is stopped), the transaxle 10 causes the oil temporarily stored in the spacer side space 36 to flow down into the internal space 21.

Further, as shown in FIG. 6, an oil communication hole 23a is provided in the partition portion 23 that partitions the differential region 21b and the primary deceleration region 21a. As a result, the transaxle 10 can move oil back and forth between the differential region 21b and the primary deceleration region 21a, and can suppress the occurrence of an extreme bias in the amount of oil.

Further, as described above, the compartment 23 is provided with an air hole 23b (not shown in FIG. 6). As a result, the oil can be moved back and forth between the differential region 21b and the primary deceleration region 21a more smoothly.

Further, as described above, the gear body 50 is provided with a communication hole 54. As shown in FIG. 6, the transaxle 10 can return the oil stored in the spacer side space 36 to the differential region 21b through the communication hole 54 without passing through the oil pool in the primary deceleration region 21a. In other words, the transaxle 10 can return the oil to the differential region 21b through the inside of the shaft (the inside of the gear body 50) which is not affected by the rotational torque of the gear 40 or the like. As a result, the transaxle 10 can realize higher energy efficiency (electricity cost and fuel consumption) improvement.

Further, as described above, in the transaxle 10, the communication hole 54 plays a role of an oil catch. As a result, the oil level F in the primary deceleration region 21a can be lowered more efficiently. The oil level F in the differential region 21b is lowered by raising the differential ring gear 60. As described above, in the transaxle 10, since the space portion 36 on the spacer side and the communication hole 54 play the role of oil catch, it is not necessary to provide the oil catch portion on the upper part of the transaxle housing 20. As a result, the height of the transaxle 10 can be suppressed.

In this way, the transaxle 10 can form an oil path R as a circulation path for the oil scooped up by the gear 40. Therefore, the transformer axle 10 forms an oil path R for appropriately lubricating the bearing 70 and the like without providing an oil pump and the like to appropriately supply oil to the bearing 70 and the like, and the bearing 70 and the like due to insufficient oil supply. Damage can be suppressed. As a result, the transaxle 10 does not need to be provided with an oil pump, a separate component for storing oil, or the like, and the cost can be suppressed.

Further, as shown in FIG. 6, the space portion 36 (gear housing 30) on the seat side of the transaxle 10 is provided so as to be adjacent to the motor 2. Therefore, the transaxle 10 can heat the oil stored in the space 36 on the interstitial side by the heat of the motor 2 in a short time. As a result, the transaxle 10 can efficiently reduce the viscosity of the oil, preferably circulate the oil in the transaxle 10, and contribute to the cooling of the motor 2, and more efficiently consume the electricity. It is possible to improve energy efficiency such as fuel efficiency and fuel efficiency.

In this way, the transaxle 10 realizes a reduction in torque loss due to the oil stirring torque of the gear 40, suppresses costs, and appropriately supplies oil to a portion requiring lubrication (bearing 70, etc.). We are solving conflicting issues at the same time.

As described above, the transaxle 10 can reduce the amount of oil to be agitated during rotation and reduce the no-load loss torque by allowing oil to flow into the room above the gear 40 (rotating body). Further, in the transaxle 10, when the rotation of the gear 40 is stopped, the oil naturally drops downward and the oil level returns, so that the oil is supplied to the gear 40 and the bearing 70 without providing parts such as an oil pump. To.

Although the transaxle 10 according to the embodiment of the present invention has been described above, the transaxle of the present invention is not limited to the above-described embodiment.

For example, in the transaxle 10 according to the above-described embodiment, an example in which both the oil catch portion 28 and the recess 34 are provided is shown, but the transaxle of the present invention is not limited to this, and at least one of them is provided. It should be.

Further, the size and position of the oil hole 35 can be appropriately selected according to the amount of oil and the position to be provided. It is desirable that the oil holes 35 are provided with larger or more inflow side oil holes 35a than the outflow side oil holes 35b.

Further, it is desirable that the outflow side oil hole 35b is formed on the upper side of the parts to be lubricated, such as the bearing 70.

Further, in the transaxle 10 according to the above-described embodiment, an example in which the recess 34 is provided in the gear housing 30 is shown, but the present invention is not limited thereto. The recess of the transaxle of the present invention may be provided, for example, inside the transaxle housing. Further, in the transaxle 10 according to the present embodiment, an example in which the transaxle housing 20 and the gear housing 30 are separated is shown, but even if the gear housing is integrally formed with the transaxle housing. Good.

Further, in the transaxle 10 according to the above-described embodiment, an example in which the space portion 36 (storage space portion) on the seat side is formed inside the gear accommodating portion 32 of the gear housing 30 is shown, but the transaxle of the present invention is It is not limited to the above-described embodiment. For example, the transaxle of the present invention may have a storage space portion directly formed in a transaxle housing such as a spacer. It is desirable that the storage space portion is provided at a position close to the motor (drive source).

Further, in the transaxle 10 according to the above-described embodiment, an example in which a pocket-shaped oil catch portion 28 is provided inside the transaxle housing 20 is shown, but the transaxle of the present invention is not limited to this. Specifically, the oil catch portion may be attached to the inside of the transaxle housing by providing a pocket-shaped member as a separate body.

Further, although the transaxle 10 according to the above-described embodiment is used for the vehicle V which is an electric vehicle, the transaxle of the present invention is not limited to this. That is, the transaxle of the present invention may be used for an engine vehicle, a hybrid vehicle, or the like.

The present invention can be suitably adopted as a transaxle of a vehicle.

10 Transaxle 14 Motor 20 Transaxle housing 21 Internal space 21a Primary deceleration area (internal space)
21b differential area (internal space)
22 Primary reduction unit (transaxle housing)
24 Diff (transaxle housing)
26 Seat (transaxle housing)
28 Oil catch part 29 Oil hole (first oil guide part)
30 Gear housing 34 Recess 35 Oil holes (1st oil guide, 2nd oil guide)
35a Inflow side oil hole (first oil guide)
35b Outflow side oil hole (second oil guide)
35c Outflow side oil hole (second oil guide)
36 Spatial space (storage space)
40 gear (rotating member)
46 Input side gear (rotating member)
50 Gear body 52 Output side gear (gear body, rotating member)
54 Communication hole 54a Large diameter part (communication hole)
56 Intermediate gear (gear body, rotating member)
60 Defling gear (rotating member)
H Vertical direction V Vehicle W Width direction X Front and rear direction

Claims (1)

A transaxle housing containing oil and
Defling gear and
A reduction mechanism including a gear body that transmits power to the differential ring gear,
It has a storage space for allowing oil to flow into the transaxle housing.
In the internal space of the transaxle housing, a differential region in which the differential ring gear is housed and a primary speed reduction region in which the speed reduction mechanism is housed are formed.
Oil can flow back and forth between the differential region and the primary deceleration region.
The gear body is formed with a communication hole penetrating in the axial direction.
A transaxle characterized in that the communication hole communicates from the storage space portion to the differential region.

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