JP2008082357A - Continuously variable transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a small and simply structured continuously variable transmission. <P>SOLUTION: An input rotary shaft 1a, a rotation transmitting shaft 22a, and an output rotary shaft 30 are arranged in parallel with each other. A transmission gear 42 for carrying out transmission of power between a toroidal type continuously variable transmission 21a and the rotation transmitting shaft 22a between a forward gear 43 and a reverse gear 44 composing a forward/reverse changing mechanism 31. As a result, in each cavity of the toroidal type continuously variable transmission 21a, each gear 43, 44 for forward and reverse, and each clutch 48, 49 for forward and reverse can be provided facing each other, and the input rotary shaft 1a and the rotation transmitting shaft 22a can be provided adjacently to each other. For that portion, miniaturization can be carried out. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an improvement of a continuously variable transmission that is used, for example, as an automatic transmission for automobiles or as a transmission for adjusting the operating speed of various industrial machines such as pumps. More specifically, the continuously variable transmission is designed to be small and simple. For example, an automatic transmission for an FF vehicle (front engine front wheel drive vehicle) has a limited space such as an engine room. It is particularly suitable as a transmission incorporated in the interior.

  For example, as described in many publications such as Patent Document 1 and Non-Patent Documents 1 and 2, it has been studied to use a toroidal continuously variable transmission as a transmission unit constituting an automatic transmission for an automobile. Have been implemented in part. FIG. 6 shows a so-called double cavity type of such a toroidal type continuously variable transmission. This toroidal-type continuously variable transmission supports a pair of input-side disks 2 a and 2 b at two positions in the axial direction of the input rotary shaft 1. Both the input side disks 2a and 2b are concentric with the input rotation shaft 1 with the input side inner side surfaces 3 and 3 each having a toroidal curved surface (concave arc-shaped concave surface) facing each other. In addition, it supports the synchronized rotation freely.

  Further, the intermediate portion of the input rotary shaft 1 is inserted through a through hole 6 provided in a partition wall portion 5 installed in a casing 4 housing a toroidal type continuously variable transmission. A cylindrical output tube 7 is rotatably supported by a pair of rolling bearings 8 and 8 on the inner diameter side of the through-hole 6. The output gear 9 constituting the first power transmission member described in 1 is fixed. Further, a pair of output side disks 10a and 10b are rotatably connected to both ends of the output cylinder 7 from both outer side surfaces of the partition wall section 5 in synchronization with the output cylinder 7 by spline engagement. I support it. In this state, the output side inner surfaces 11, 11, each of which is a toroidal curved surface (concave arc-shaped concave surface), face the both input side inner surfaces 3, 3. As the output side disks 10a and 10b, the pair of output side disks 10a and 10b are coupled and fixed as in the structure described in Patent Documents 3 and 4 described later (structure shown in FIG. 8), for example. The integrated output side disk 10 having such a shape may be employed.

  In addition, a plurality (generally two or three) of power rollers 12 are provided in a portion (cavity) between the input side and output side inner side surfaces 3 and 11 around the input rotation shaft 1. , 12 are arranged. Each of these power rollers 12 and 12 has a spherical convex surface on the peripheral surfaces 13 and 13 that are in contact (rolling contact) with the input and output side inner surfaces 3 and 11, respectively. 14 is supported on the inner surface of 14 so as to be freely rotatable and slightly swingable. Each of the trunnions 14 and 14 is provided with a swinging displacement about a pivot that is twisted with respect to the input rotary shaft 1.

  When changing the gear ratio between the input side disks 2a, 2b and the output side disks 10a, 10b, the trunnions 14, 14 are displaced in the axial direction of the pivot (front and back direction in FIG. 6). As a result, rolling contact portions between the peripheral surfaces 13 and 13 of the power rollers 12 and 12 and the input and output inner surfaces 3 and 11 of the input and output disks 2a, 2b, 10a and 10b ( The direction of the tangential force acting on the traction section changes (side slip occurs in the rolling contact section). As the direction of the force changes, the trunnions 14 and 14 swing (tilt) about the pivot, and the peripheral surfaces 13 and 13 of the power rollers 12 and 12 and the input side and output The contact positions of the side disks 2a, 2b, 10a and 10b with the input side and output side inner surfaces 3 and 5 change.

  For example, as shown in FIG. 6, the peripheral surfaces 13, 13 of the power rollers 12, 12 are connected to the radially inner portions of the input side inner surfaces 3, 3 of the input side disks 2a, 2b and the output side disks. If it is brought into rolling contact with the radially outer portions of the output side inner surfaces 11, 11 of 10a, 10b, the gear ratio between the two disks 2a, 2b, 10a, 10b becomes the deceleration side. On the other hand, conversely to FIG. 6, the peripheral surfaces 13, 13 of each of the power rollers 12, 12 are arranged radially outside the input side inner surfaces 3, 3 of the input side disks 2 a, 2 b, If the rolling contact is made with the radially inner portions of the output side inner surfaces 11, 11 of the output side disks 10a, 10b, the gear ratio between the two disks 2a, 2b, 10a, 10b will be increased. Become.

  During operation of the toroidal-type continuously variable transmission as described above, one input side disk 2a (left side in FIG. 6) is connected to a loading cam type pressing device by a drive shaft 15 connected to a drive source (power source) such as an engine. 16 is driven to rotate. As a result, the pair of input-side disks 2a and 2b supported at both ends of the input rotation shaft 1 rotate synchronously while being pressed in a direction approaching each other. Then, this rotation is transmitted to both the output side disks 10a and 10b via the power rollers 12 and 12, and is taken out from the output gear 9.

  By the way, when the above-described toroidal continuously variable transmission is used as a transmission unit constituting an automatic transmission for a vehicle (for automobiles), for example, the toroidal continuously variable transmission is connected to a forward / reverse switching mechanism ( It is necessary to configure a continuously variable transmission in combination with a forward / reverse switching mechanism. This is because, for example, in the case of an automobile, it is necessary not only to move forward but also to move backward. The rotational direction of the power transmitted from the engine that is the drive source to the output shaft (wheel) is changed by the forward / reverse switching mechanism. This is because it is necessary to switch between a direction corresponding to (forward rotation direction) and a direction corresponding to the reverse direction (reverse rotation direction). For example, a structure described in Patent Document 2 is known as a continuously variable transmission that is a combination of such a toroidal type continuously variable transmission and a forward / reverse switching mechanism that is a forward / reverse switching mechanism.

  FIG. 7 shows the structure described in Patent Document 2. In the case of the structure shown in FIG. 7, the forward / reverse switching mechanism 20 including the planetary gear type transmission 17 and the forward and reverse clutches 18 and 19 is connected to the toroidal portion with respect to the direction of transmission of power from the engine as the drive source. It is provided upstream of the continuously variable transmission 21. However, in this structure, the forward / reverse switching mechanism 20 and the toroidal continuously variable transmission 21 are provided in series in the axial direction (the forward / reverse switching mechanism 20 and the toroidal continuously variable transmission 21 are concentric. Therefore, the axial dimension of the continuously variable transmission is increased. For this reason, it is difficult to adopt as an automatic transmission for an FF vehicle (front engine front wheel drive vehicle) that needs to be incorporated in a limited space such as an engine room.

  On the other hand, in Patent Documents 3 and 4, as shown in FIG. 8, a planetary gear type transmission 17a (planetary gear type transmission 17a for realizing a geared neutral state) constituting a forward / reverse switching mechanism 20a. Is described in the downstream of the toroidal type continuously variable transmission 21 with respect to the direction of transmission of power from the drive source. In the case of this structure, the planetary gear type transmission 17a is provided around the rotation transmission shaft 22 provided in parallel with the input rotation shaft 1 of the toroidal continuously variable transmission 21. Therefore, the axial dimension can be reduced as compared with the structure described in Patent Document 2 shown in FIG. However, in the case of the structures described in Patent Documents 3 and 4, the distance between the input rotary shaft 1 of the toroidal-type continuously variable transmission 21 and the rotation transmission shaft 22 tends to be large. That is, the planetary gear type transmission 17a provided around the rotation transmission shaft 22 is provided with the sun gear 23, the planetary gears 24 and 24, and the ring gear 25 superimposed in the radial direction. Tends to be bulky. In addition, a low-speed clutch 26 having a diameter larger than that of the ring gear 25 is provided so as to face the ring gear 25 provided on the outermost diameter side in the axial direction. For this reason, a necessary radial dimension around the rotation transmission shaft 22 is increased, and accordingly, the distance between the rotation transmission shaft 22 and the input rotation shaft 1 is increased. Increases overall size.

  In the illustrated structure, the planetary gear type transmission 17a and the low speed clutch 26 are opposed to one of the cavities of the toroidal-type continuously variable transmission 21 (left side in FIG. 8). It is arranged with. For this reason, it is difficult to make the components compact in a compact manner, for example, an excess space (useless space) is likely to be formed in a portion facing the other cavity (the right side in FIG. 8). I can't. A power transmission mechanism for transmitting power between the toroidal continuously variable transmission 21 and the planetary gear type transmission 17a between the toroidal continuously variable transmission 21 and the rotation transmission shaft 22; Since the low speed and high speed clutches 26 and 27 for switching the power transmission state between the power transmission mechanism and the planetary gear type transmission 17a are provided, the structure around the rotation transmission shaft 22 is provided. It becomes complicated. In addition, it is necessary to provide a lubricating oil supply path to the planetary gears 24 and 24 (the planetary shafts 28 and 28 supporting the planetary gears 24 and 24) constituting the planetary gear type transmission 17a, and the structure is complicated also from this aspect. .

JP 2001-317601 A JP 2006-46573 A JP-A-10-267116 JP 11-63139 A Motoo Aoyama, “Bessed Best Car Red Badge Series 245 / A book that understands the latest mechanics of cars”, Sangensha Co., Ltd./Kodansha Co., Ltd., December 20, 2001, p. 92-93 Hirohisa Tanaka, “Toroidal CVT”, Corona Inc., July 13, 2000

  The present invention has been invented in order to realize a continuously variable transmission that is small and simple in view of the circumstances as described above.

The continuously variable transmission of the present invention includes an input rotation shaft, a toroidal continuously variable transmission, a rotation transmission shaft, a power transmission mechanism, an output rotation shaft, and a forward / reverse switching mechanism (forward / reverse switching mechanism). Prepare.
Of these, the input rotary shaft receives power from a drive source (for example, a power source such as an engine).
The toroidal continuously variable transmission is provided around the input rotation shaft and concentric with the input rotation shaft.
The rotation transmission shaft is provided downstream of the input rotation shaft in parallel with the input rotation shaft in the power transmission direction.
The power transmission mechanism transmits power between the toroidal type continuously variable transmission and the rotation transmission shaft. For example, a power transmission mechanism such as a gear type or a chain / sprocket type can be employed.
The output rotation shaft is provided downstream of the rotation transmission shaft in parallel with the rotation transmission shaft with respect to the power transmission direction.
Further, the forward / reverse switching mechanism (forward / reverse switching mechanism) is provided between the rotation transmission shaft and the output rotation shaft with respect to the transmission direction of the power, and the power output from the output rotation shaft. The rotation direction is switched between forward rotation and reverse rotation (direction corresponding to forward movement, direction corresponding to backward movement).

The toroidal type continuously variable transmission is of a double cavity type and includes a pair of input side disks, an output side disk, and a plurality of power rollers.
Each of the input side disks is supported concentrically and freely in a synchronized manner via the input rotation shaft.
The output side disk is supported between the two input side disks so as to be concentric with the two input side disks and to rotate independently of the two input side disks.
Each of the power rollers is sandwiched between both side surfaces of the output side disk and the side surfaces of both input side disks, and transmits power between the input side disk and the output side disk. To do.

Furthermore, the power transmission mechanism is provided concentrically with the output side disk, and rotates in synchronization with the output side disk (for example, an output gear, an output sprocket, etc.), and the rotation transmission shaft. And a second power transmission member (for example, a transmission gear, a transmission sprocket, etc.) that rotates in synchronization with the rotation transmission shaft. Then, power is transmitted between the output side disk and the rotation transmission shaft via both the first and second power transmission members.
The forward / reverse switching mechanism (forward / reverse switching mechanism) is provided concentrically with the rotation transmission shaft, and transmits a power corresponding to the forward rotation (forward direction). For example, a forward rotation gear) and a reverse rotation power transmission member (for example, a reverse rotation gear) that is provided concentrically with the rotation transmission shaft and transmits power corresponding to the reverse rotation direction (reverse direction). It is provided. Even when a sprocket is used as the power transmission member, only one of the power transmission members is used, and the other power transmission member can be used as a gear to change the rotation direction.
The second power transmission member is provided between the forward rotation power transmission member and the reverse rotation power transmission member with respect to the axial direction of the rotation transmission shaft.

  Further, when the continuously variable transmission as described above is implemented, preferably, the forward / reverse switching mechanism (forward / reverse switching mechanism) is replaced with a gear (such as a helical gear) as described in claim 2. Configure by mechanism. Then, the forward rotation gear (for example, the forward gear) constituting the forward rotation power transmission member is directly meshed with the first output gear provided on the output rotation shaft, and the reverse rotation constituting the reverse rotation power transmission member. A gear (for example, a reverse gear) is engaged with a second output gear provided on the output rotation shaft via an idle gear.

  Preferably, as described in claim 3, with respect to the direction of transmission of power from the drive source, a power transmission that constitutes a forward / reverse switching mechanism downstream of the toroidal continuously variable transmission. A clutch for switching the state is provided. More specifically, as described in claim 4, with respect to the transmission direction of the power, between the rotation transmission shaft and a normal rotation power transmission member (for example, a normal rotation gear, a forward gear), these rotation transmission shafts. A forward rotation clutch (forward clutch) that switches between a state where power is transmitted and a state where power is not transmitted between the forward rotation power transmission member and the forward rotation power transmission member. Reversing clutches (reverse clutches) that switch between a state in which power is transmitted and a state in which power is not transmitted between the rotation transmission shaft and the power transmission member for reverse rotation are provided between the gears).

  Preferably, as described in claim 5, the output side disk is constituted by a single member (set as an integrated output side disk). At the same time, a first power transmission member (for example, an output gear) is provided on the outer peripheral surface of the axially intermediate portion of the output side disk. Then, power can be transmitted from the first power transmission member to a second power transmission member (for example, a transmission gear) in an accelerated state. The first power transmission member is a separate member from the output side disk as in the structure described in Patent Documents 3 and 4 described above (the structure shown in FIG. 8). In addition to being configured to be coupled and fixed (synchronized rotation is freely coupled), it is also configured to be directly fixed to an integrated output side disk (the first power transmission member is also provided integrally with the output side disk). You can also.

According to the present invention as described above, the continuously variable transmission can be made compact and simple.
That is, the forward and reverse power transmission members constituting the forward / reverse switching mechanism are arranged in a state shifted in the axial direction of the rotation transmission shaft with the second power transmission member constituting the power transmission mechanism interposed therebetween. To do. Therefore, the forward and reverse power transmission members can be opposed to the cavities existing on both sides of the output side disk in the axial direction with the output side disk of the toroidal-type continuously variable transmission as the center. In other words, the power transmission members for forward rotation and reverse rotation and the members provided close to these members can be opposed to the cavities with sufficient space, and the center of the toroidal continuously variable transmission ( The input rotation shaft that is the shaft) and the forward / reverse switching mechanism (the rotation transmission shaft that is the central axis thereof) can be brought close to each other (in the radial direction). For this reason, it is possible to reduce useless space and to reduce the size of the continuously variable transmission.

  Further, for example, as in the case of the structure described in Patent Documents 3 and 4 shown in FIG. 8, that is, the structure in which the forward / reverse rotation switching mechanism is constituted by the planetary gear type transmission 17a, The members corresponding to the two power transmission members (the conventional sun gear 23, the planetary gears 24 and 24, and the ring gear 25) do not overlap in the radial direction. For this reason, it can prevent that the radial direction dimension of the member arrange | positioned around the said rotation transmission shaft becomes large, and also from this surface, the said toroidal type continuously variable transmission (input rotation shaft) and the said forward / reverse switching mechanism ( Rotation transmission shaft). In addition, since the planetary gear type transmission having a complicated structure is not incorporated as the forward / reverse switching mechanism, the forward / reverse switching mechanism can be simply configured.

In addition, if the forward / reverse switching mechanism is a gear mechanism as described in claim 2, it can be configured more simply (compared to a case where it is constituted by a sprocket and a chain). Moreover, for example, if it is constituted by a helical gear generally used in an automobile transmission or the like, the forward / reverse switching mechanism can be constructed simply and inexpensively.
When the configurations described in claims 3 and 4 are employed, the same (diameter) clutch plate (friction material) can be used for each of the forward rotation and reverse rotation clutches. For this reason, it is not necessary to increase the diameter (surrounding dimensions) of the shaft (rotation transmission shaft) on which these clutches are provided (for example, in accordance with a clutch having a large diameter), and the reduction ratio (gear ratio, gear ratio) The flexibility of selection can be secured.
Further, when the configuration described in claim 5 is adopted, the axial dimension of the toroidal-type continuously variable transmission can be reduced by integrating the output side disk, and the power is transmitted in an accelerated state. Capacity can be reduced. For this reason, the axial and radial dimensions of the clutch can be reduced (can be reduced in size), and further downsizing of the continuously variable transmission can be achieved. Further, the toroidal continuously variable transmission (input rotation shaft) and the forward / reverse rotation switching mechanism (rotation transmission shaft) can be brought closer to each other to further reduce the size of the entire continuously variable transmission.

1 to 5 show an example of an embodiment of the present invention. The continuously variable transmission of this example includes an input rotary shaft 1a, a toroidal continuously variable transmission 21a, a rotation transmission shaft 22a, a power transmission mechanism 29, an output rotary shaft 30, and the positive rotation speed described in the claims. A forward / reverse switching mechanism 31 corresponding to a rotation / reverse switching mechanism is provided.
Of these, the input rotary shaft 1a receives power from a drive source (power source) such as an engine via the torque converter 32 and the drive shaft 15a. Such an input rotating shaft 1a is rotatably provided to a fixed part such as a casing. The toroidal continuously variable transmission 21a is provided concentrically with the input rotary shaft 1a. The rotation transmission shaft 22a is fixed to the casing or the like by a pair of tapered roller bearings 33, 33 provided at both ends thereof on the downstream side of the input rotation shaft 1a in the power transmission direction. Is provided in parallel with the input rotation shaft 1a in a state of being rotatably supported.

  The power transmission mechanism 29 transmits power between the toroidal type continuously variable transmission 21a and the rotation transmission shaft 22a. The output rotating shaft 30 is fixed to the casing or the like by another pair of tapered roller bearings 34, 34 provided at both ends thereof on the downstream side of the rotation transmitting shaft 22a in the power transmission direction. And is provided in parallel with the rotation transmission shaft 22a in a state of being rotatably supported with respect to this portion. Further, the forward / reverse switching mechanism 31 is provided between the rotation transmission shaft 22a and the output rotation shaft 30 with respect to the power transmission direction, and the rotation direction of the power output from the output rotation shaft 30 is set to be normal. The rotation is switched to reverse rotation (direction corresponding to the forward direction, direction corresponding to the backward direction).

  The toroidal type continuously variable transmission 21a is of a double cavity type, and includes a pair of input side disks 2a, 2b, an output side disk 10, and a plurality of power rollers 12, 12 (see FIGS. 6 to 8). ). Each of the input side disks 2a and 2b is supported concentrically and freely in a synchronized manner via the input rotation shaft 1a. The output side disk 10 rotates between the input side disks 2a and 2b, concentrically with the input side disks 2a and 2b, and independent of the input side disks 2a and 2b. It is supported as free. In the case of this example, a pair of support columns 36 are provided in each cavity in a state of being supported via a actuator body 35 on a fixed part such as a casing. The axial ends of the output-side disk 10 are rotatably supported via thrust ball bearings 38 and 38 on support rings 37 and 37 provided at intermediate portions of the columns 36 and 36. The input rotary shaft 1a can be freely rotated through the through hole 39 provided in the central portion of the output side disk 10 supported as described above via the radial needle bearings 40 and 40 and can be displaced in the axial direction. It is supported by. Such an input rotating shaft 1a has one input (left side in FIG. 1) according to the pressing force generated by the hydraulic pressing device 16a (according to expansion / contraction of the hydraulic chamber 41 constituting the pressing device 16a). Along with the other input side disk 2b (to the right in FIG. 1), the side disk 2a is displaced in the axial direction.

  Each of the power rollers 12 and 12 has a plurality of each between the both side surfaces of the output side disk 10 and the side surfaces of the both input side disks 2a and 2b, similarly to the structure shown in FIG. The power is transmitted between the input side disks 2a and 2b and the output side disk 10 by being sandwiched. The power rollers 12 and 12 are trunnions (support members) 14 and 14 (FIG. 6, FIG. 6), each of which is provided with a swinging displacement about a pivot that is twisted with respect to the input rotary shaft 1a. 8) is supported so as to be freely rotatable and slightly swingable. The operation of inclining each of the trunnions 14 and 14 (changing the transmission ratio of the toroidal type continuously variable transmission 21a) is performed by using the hydraulic actuator (not shown) provided in the actuator body 35 to cause the trunnions 14 and 14 to This is done by displacing in the axial direction of the pivot axis.

  Further, the power transmission mechanism 29 includes an output gear 9a corresponding to the first power transmission member described in the claims provided on the outer peripheral surface of the output side disk 10 in the axial direction, and the rotation transmission shaft 22a. And a transmission gear 42 corresponding to the second power transmission member described in the claims. The output gear 9a and the transmission gear 42 are directly meshed with each other so that power can be freely transmitted between the output gear 9a and the transmission gear 42 (between the output side disk 10 and the rotation transmission shaft 22a). In the case of this example, the output side disk 10 is constituted by a single member. The output gear 9 a is directly formed (fixed) on the outer circumferential surface of the intermediate portion in the axial direction of the output side disk 10. In this example, the power can be transmitted from the output gear 9a to the transmission gear 42 in an accelerated state. That is, the number of teeth of the transmission gear 42 is smaller than that of the output gear 9a (the outer diameter is reduced).

  The forward / reverse switching mechanism 31 is constituted by a gear mechanism (helical gear in the case of this example), and the forward rotation power transmission member and the forward rotation gear corresponding to the forward rotation gear described in the claims. The gear 43 includes a reverse gear 44 corresponding to the reverse power transmission member and the reverse gear, first and second output gears 45 and 46, and an idle gear 47. Along with this, each of the clutches described in the claims constitutes a forward clutch 48 corresponding to the forward rotation clutch described in the claims, and a reverse clutch 49 also corresponding to the reverse rotation clutch. Prepare. Of these, the forward gear 43 is rotatably supported via a radial needle bearing 50 at a position adjacent to the transmission gear 42 in the axial direction at an intermediate portion of the rotation transmission shaft 22a. The reverse gear 44 is rotatably supported via another radial needle bearing 51 at a portion near the other end of the rotation transmission shaft 22a (a portion near the right end in FIGS. 1, 3 and 4). The transmission gear 42 can freely rotate in the middle of the rotation transmission shaft 22a between the forward and reverse gears 43, 44 in synchronization with the rotation transmission shaft 22a (for example, a spline engagement). (For example, by key engagement).

  Further, the first output gear 45 is in a state in which the first output gear 45 is directly meshed with the forward gear 43 at a portion near one end of the output rotary shaft 30 (portion near the left end in FIGS. 1, 3 and 5). Rotation synchronized with 30 is supported freely (for example, by spline engagement, key engagement, etc.). The second output gear 46 meshes with the reverse gear 44 via the idle gear 47 at the other end portion (the right end portion in FIGS. 1, 3, and 5) of the output rotating shaft 30. In this state, the rotation synchronized with the output rotation shaft 30 is supported freely (for example, by spline engagement, key engagement, etc.). The first output gear 45 rotates in the direction opposite to the rotation transmission shaft 30 (the direction corresponding to the forward direction), whereas the second output gear 46 has the same direction as the rotation transmission shaft 30. Rotate in the direction corresponding to the backward direction. A third output gear 52 is formed directly at a position near the other end of the output rotating shaft 30 at a position adjacent to the second output gear 46 in the axial direction. The third output gear 52 is meshed with an input gear 53 of a differential gear so that the pair of wheel drive shafts 54 can be driven to rotate.

  Further, the forward and reverse clutches 48 and 49 are downstream of the toroidal-type continuously variable transmission 21a with respect to the direction of transmission of power from the drive source, that is, in this example, the rotation transmission shaft 22a. It is provided around. Of these, the forward clutch 48 is provided between the rotation transmission shaft 22a and the forward gear 43 with respect to the direction of power transmission, and transmits power between the rotation transmission shaft 22a and the forward gear 43. Switching between a state to be performed (connected state) and a state not to be performed (state disconnected). The reverse clutch 49 is provided between the rotation transmission shaft 22a and the reverse gear 44 in the power transmission direction, and transmits power between the rotation transmission shaft 22a and the reverse gear 44. Switching between a state to be performed (connected state) and a state not to be performed (state disconnected). Each of the forward and reverse clutches 48 and 49 is connected to one of the clutches 48 (49) corresponding to the traveling direction in accordance with the operation of the shift lever (operating lever) by the driver.

  Each of the forward and reverse clutches 48 and 49 is a wet multi-plate clutch. The forward clutch 48 includes a clutch housing 55a, a piston 56a, an outer drum 57a, a plurality of pressure plates 58a and 58a, an inner drum 59a, a plurality of clutch disks 60a and 60a, and a compression coil spring 61a. And a retaining ring 67a. Of these, the clutch housing 55a is supported by the rotation transmission shaft 22a so as to freely rotate in synchronization with the rotation transmission shaft 22a. The piston 56a is oil-tightly fitted inside the clutch housing 55a. A portion between the side surface of the piston 56a and the inner surface of the clutch housing 55a that are opposed to each other in the axial direction of the rotation transmission shaft 22a is a hydraulic chamber 62a.

  The outer drum 57a is provided integrally with the clutch housing 55a. The pressure plates 58a and 58a can be displaced relative to each other in the axial direction on the inner peripheral surface, and cannot be displaced in the rotational direction ( The rotation synchronized with the outer drum 57a is freely supported. Further, the retaining ring 67a is locked to a portion near the opening of the inner peripheral surface of the outer drum 57a to prevent the pressure plate 58a farthest from the piston 56a from coming out of the outer drum 57a. The inner drum 59a is fixed to the side surface of the forward gear 43, and the clutch disks 60a, 60a can be axially displaced on the outer peripheral surface and can be displaced in the rotational direction. It is impossible (rotation synchronized with the inner drum 59a is freely supported).

  The compression coil spring 61a is provided on the inner side of the inner drum 59a, and a direction in which side surfaces facing each other in the axial direction approach each other between the clutch housing 55a and the piston 56a (direction in which the hydraulic chamber 62a narrows). ) Elasticity. When pressure oil is introduced into the hydraulic chamber 62a through an oil supply passage 63a provided in the rotation transmission shaft 22a, the piston 56a is displaced in the axial direction against the elasticity of the compression coil spring 61a. As a result, the pressure plates 58a and 58a and the clutch disks 60a and 60a are sandwiched between the piston 56a and the retaining ring 67a, and the rotation transmission shaft 20a and the forward gear 43 are interposed. Power can be transmitted (the rotation transmission shaft 20a and the forward gear 43 rotate in synchronization). Further, when the introduction of the pressure oil into the hydraulic chamber 62a is cut off (when released to the oil reservoir), the side surfaces of the pressure plates 58a and 58a and the clutch disks 60a and 60a face each other. Slipping each other, and no power is transmitted between the rotation transmission shaft 20a and the forward gear 43.

  Similarly to the forward clutch 48, the reverse clutch 49 also includes a clutch housing 55b, a piston 56b, an outer drum 57b, a plurality of pressure plates 58b and 58b, an inner drum 59b, and a plurality of sheets. Clutch disks 60b and 60b, a compression coil spring 61b, and a retaining ring 67b are provided. These members 55b, 56b, 57b, 58b, 59b, 60b, 61b, 67b constituting such a reverse clutch 49 are members 55a, 56a, 57a, 58a, 59a, 60a, constituting the forward clutch 48, respectively. It has the same configuration as 61a and 67b. The hydraulic oil is introduced into the hydraulic chamber 62b of the reverse clutch 49 through an oil supply passage 63b different from the oil supply passage 63a for introducing the pressure oil into the hydraulic chamber 62a of the forward clutch 48.

  In the case of the reverse clutch 49, the clutch housing 55b is configured by using a part of the transmission gear 42. That is, an annular recess 64 (for constituting the hydraulic chamber 62b) is provided on the side surface of the transmission gear 42 so as to be recessed from the side surface, and the opening edge ( The outer drum 57b is fitted and fixed (coupled and fixed) in an oil-tight manner by an interference fit or the like on the inner peripheral surface), whereby the clutch housing 55b is integrally incorporated in one side portion of the transmission gear 42. In the case of the reverse clutch 49, a centrifugal hydraulic pressure canceling chamber 65 is provided on the opposite side of the hydraulic chamber 62b with the piston 56b interposed therebetween. The centrifugal oil pressure canceling chamber 65 is supplied with low-pressure oil through a lubricating oil supply passage 66 that is a separate system from the oil supply passage 63b that introduces pressure oil into the hydraulic chamber 62b. In a state where the connection of the reverse clutch 49 is cut off (pressure oil is not introduced into the hydraulic chamber 62b), the hydraulic pressure is not released from the hydraulic chamber 62b based on centrifugal force, and the reverse clutch 49 is connected to the piston 56b. Even if the force in the direction to be applied tends to be applied, the force can be offset by applying the centrifugal force to the oil existing in the centrifugal hydraulic chamber cancel chamber 65 in the same manner. That is, the hydraulic force based on the centrifugal force is applied to the piston 56b in a direction that cancels each other out from both the hydraulic chambers 62b and 65 located on both sides in the axial direction across the piston 56b. For this reason, the reverse clutch 49 is reliably disconnected regardless of the rotation of the rotation transmission shaft 22a during operation (particularly during forward movement).

According to the structure of this example as described above, the continuously variable transmission can be made small and simple.
That is, as described above, the forward and reverse gears 43 and 44 are arranged in a state of being shifted in the axial direction of the rotation transmission shaft 22a with the transmission gear 42 interposed therebetween. For this reason, the forward and reverse gears 43 and 44 are opposed to the cavities existing on both sides in the axial direction of the output side disk 10 around the output side disk 10 of the toroidal type continuously variable transmission 21a. It is done. In other words, the forward and backward gears 43 and 44 and the forward and backward clutches 48 and 49 can be opposed to the cavities with sufficient space, and the input rotary shaft 1a and the rotation transmission shaft 22a Can be made close to each other (in the radial direction). For this reason, it is possible to reduce useless space and to reduce the size of the continuously variable transmission.

  Further, for example, as in the case of the structure described in Patent Documents 3 and 4 shown in FIG. 8 described above, that is, the structure in which the forward / reverse switching mechanism is constituted by the planetary gear type transmission 17a, The members (sun gear 23, planetary gears 24, 24, ring gear 25) corresponding to the power transmission members for use do not overlap in the radial direction. For this reason, it is possible to prevent the radial dimension of the members disposed around the rotation transmission shaft 22a from increasing, and the input rotation shaft 1a and the rotation transmission shaft 22a can be brought close to each other also from this surface. In addition, since the planetary gear type transmission having a complicated structure is not incorporated as the forward / reverse switching mechanism 31, the forward / backward switching mechanism 31 can be configured simply.

  Further, the forward / reverse switching mechanism 31 is a gear mechanism and is constituted by a helical gear generally used in an automobile transmission or the like. For example, when it is constituted by a sprocket and a chain, etc. Compared to this, it can be configured more simply and inexpensively. Further, forward and backward clutches 48 and 49 are provided around the rotation transmission shaft 22a on the downstream side of the toroidal-type continuously variable transmission 21a with respect to the power transmission direction, and the clutches 48 and 49 are accelerated. Since power is transmitted, the torque capacity of each of the clutches 48 and 49 can be reduced. For this reason, the axial and radial dimensions of the forward and reverse clutches 48 and 49 can be reduced (can be made smaller), and the continuously variable transmission can be further reduced in size. Further, the pressure plates 58a and 58b and the clutch disks 60a and 60b having the same diameter can be used in the forward and reverse clutches 48 and 49, respectively. For this reason, it is not necessary to increase the diameters of the rotation transmission shaft 22a and the output rotation shaft 30, and the flexibility in selecting the reduction ratio (gear ratio, gear ratio) can be ensured. Moreover, since the output side disk 10 is comprised by the single member, the axial direction dimension of the toroidal type continuously variable transmission 21a can be reduced. For this reason, also from this aspect, the entire continuously variable transmission can be reduced in size.

In the case of this example, a torque converter 32 constituting a starting device is provided upstream of the input rotary shaft 22a of the toroidal-type continuously variable transmission 21a with respect to the direction of transmission of power from the engine. However, when the forward and reverse clutches 48 and 49 are provided with a function as a starting clutch (for example, a half-clutch function), the torque converter 32 can be omitted. In this case, the drive shaft 15a can be downsized in the axial direction.
Note that an oil pump 68 (FIG. 2) for generating hydraulic pressure to be introduced into a portion requiring pressure oil, such as the forward and backward clutches 48 and 49 and the pressing device 16a described above, is provided on the drive shaft 15a. It is driven to rotate through a sprocket 69 (FIG. 1) and a chain 70 (FIGS. 1 and 2). Thus, since the oil pump 68 is arranged separately from the drive shaft 15a (on another shaft shifted in the radial direction), the drive shaft 15a portion can be reduced in size in the axial direction also from this surface.

  The structure of the toroidal type continuously variable transmission incorporated in the continuously variable transmission of the present invention may be either a half toroidal type or a full toroidal type.

Sectional drawing which shows one example of embodiment of this invention. The figure seen from the left side of FIG. Sectional drawing similar to FIG. 1 cut | disconnected in the surface which an idle gear meshes | engages. Sectional drawing which takes out and shows the rotation transmission shaft and the member assembled | attached to this. Sectional drawing which takes out and shows the output rotating shaft and the member assembled | attached to this. Sectional drawing which shows one example of a toroidal type continuously variable transmission. Sectional drawing which shows an example of a conventional structure. Sectional drawing which shows another example of a conventional structure.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1a Input rotating shaft 2a, 2b Input side disk 3 Input side inner surface 4 Casing 5 Partition part 6 Through-hole 7 Output cylinder 8 Rolling bearing 9, 9a Output gear 10, 10a, 10b Output side disk 11 Output side inner surface 12 Power roller 13 Peripheral surface 14 Trunnion 15, 15a Drive shaft 16, 16a Press device 17, 17a Planetary gear type transmission 18 Forward clutch 19 Reverse clutch 20, 20a Forward / reverse switching mechanism 21, 21a Toroidal type continuously variable transmission 22, 22a Rotation transmission shaft 23 Sun gear 24 Planetary gear 25 Ring gear 26 Low speed clutch 27 High speed clutch 28 Planetary shaft 29 Power transmission mechanism 30 Output rotation shaft 31 Forward / reverse switching mechanism 32 Torque converter 33 Tapered roller bearing 34 Tapered roller bearing 35 Actuator body 36 support 37 support ring 8 Thrust ball bearing 39 Through hole 40 Radial needle bearing 41 Hydraulic chamber 42 Transmission gear 43 Forward gear 44 Reverse gear 45 First output gear 46 Second output gear 47 Idle gear 48 Forward clutch 49 Reverse clutch 50 Radial needle bearing 51 radial needle bearing 52 third output gear 53 input gear 54 axle drive shaft 55a, 55b clutch housing 56a, 56b piston 57a, 57b outer drum 58a, 58b pressure plate 59a, 59b inner drum 60a, 60b clutch disc 61a, 61b compression coil spring 62a, 62b Hydraulic chamber 63a, 63b Oil supply passage 64 Recessed portion 65 Centrifugal hydraulic cancel chamber 66 Lubricating oil supply passage 67a, 67b Retaining ring 68 Oil pump 69 Sprocket 70 Che

Claims (5)

An input rotary shaft to which power from the drive source is input;
Around the input rotation shaft, a toroidal continuously variable transmission provided concentrically with the input rotation shaft;
A rotation transmission shaft provided in parallel to the input rotation shaft on the downstream side of the input rotation shaft with respect to the transmission direction of the power,
A power transmission mechanism for transmitting power between the toroidal continuously variable transmission and the rotation transmission shaft;
With respect to the transmission direction of the power, an output rotation shaft provided in parallel to the rotation transmission shaft on the downstream side of the rotation transmission shaft,
A forward / reverse switching mechanism that is provided between the rotation transmission shaft and the output rotation shaft with respect to the power transmission direction and switches the rotation direction of the power output from the output rotation shaft between normal rotation and reverse rotation. And
Of these, the toroidal-type continuously variable transmission includes a pair of input-side disks supported concentrically and freely in synchronization with each other via the input rotation shaft, and between the two input-side disks. The output side disk supported concentrically with both the input side disks and independent of the both input side disks, and both side surfaces of the output side disk and the side surfaces of the both input side disks A plurality of power rollers that are sandwiched between each of them and that transmit power between the input side disk and the output side disk are provided.
The power transmission mechanism is provided concentrically with the output-side disk, and is provided concentrically with the first power transmission member that rotates in synchronization with the output-side disk, and with the rotation transmission shaft. A second power transmission member that rotates synchronously, and transmits power between the output side disk and the rotation transmission shaft via the first and second power transmission members,
The forward / reverse switching mechanism is provided concentrically with the rotation transmission shaft, and is provided concentrically with the forward transmission power transmission member for transmitting power corresponding to the forward rotation direction. A power transmission member for reverse rotation for transmitting power corresponding to the reverse direction,
A continuously variable transmission in which the second power transmission member is provided between the forward power transmission member and the reverse power transmission member in the axial direction of the rotation transmission shaft.   The forward / reverse switching mechanism is constituted by a gear mechanism, and the forward rotation gear constituting the forward rotation power transmission member is directly meshed with the first output gear provided on the output rotation shaft, and the reverse rotation power transmission member is The continuously variable transmission according to claim 1, wherein the reverse rotation gear is configured to mesh with a second output gear provided on the output rotation shaft via an idle gear.   With respect to the direction of transmission of power from the drive source, a clutch for switching the transmission state of power, which constitutes a forward / reverse switching mechanism, is provided downstream of the toroidal type continuously variable transmission. The continuously variable transmission according to any one of 2.   A forward clutch that switches between a state in which power is transmitted and a state in which power is not transmitted between the rotation transmission shaft and the forward power transmission member between the rotation transmission shaft and the forward power transmission member with respect to the power transmission direction. Similarly, between the rotation transmission shaft and the reverse power transmission member, a reverse rotation clutch for switching between a state in which power is transmitted between the rotation transmission shaft and the reverse power transmission member and a state in which the power transmission is not performed, respectively. The continuously variable transmission according to claim 3 provided. The output side disk is constituted by a single member, and a first power transmission member is provided on the outer peripheral surface in the axial direction of the output side disk, and the power is increased from the first power transmission member to the second power transmission member. The continuously variable transmission according to any one of claims 1 to 4, wherein the continuously variable transmission is capable of being transmitted in a fast state.

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