JP2007032824A - Toroidal continuously variable transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a toroidal continuously variable transmission capable of efficiently supplying lubrication oil to a power roller side by suppressing supplying loss of the lubrication oil and capable of making a lubrication pump small. <P>SOLUTION: In the toroidal continuously variable transmission of this invention, the lubrication oil flows to a radial needle bearing 200 in a circle hole 21 through a first oil passage 300a, flows from the first oil passage 300a to a second oil passage 300b and reaches a thrust ball bearing 24 and a radial needle bearing 98 through the second oil passage 300b and a third oil passage 300c. In this case, as an outer ring 200b of the radial needle bearing 200 is equipped with a sealing member 310 for sealing the lubrication oil to be supplied to the radial needle bearing 200 in the circle hole 21 of a trunnion 15, the lubrication oil to be supplied to the radial needle bearing 200 is prevented from being supplied to the thrust needle bearing 25. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a toroidal continuously variable transmission that can be used for transmissions of automobiles and various industrial machines.

  For example, a double-cavity toroidal continuously variable transmission used as a transmission for an automobile is configured as shown in FIGS. As shown in FIG. 12, an input shaft (center shaft) 1 is rotatably supported inside the casing 50, and two input side disks 2, 2 and two outputs are provided on the outer periphery of the input shaft 1. Side disks 3 and 3 are attached. An output gear 4 is rotatably supported on the outer periphery of the intermediate portion of the input shaft 1. Output side disks 3 and 3 are connected to cylindrical flange portions 4a and 4a provided at the center of the output gear 4 by spline coupling.

  The input shaft 1 is rotationally driven by a drive shaft 22 via a loading cam type pressing device 12 provided between an input side disk 2 and a cam plate 7 located on the left side in the drawing. . The output gear 4 is supported in the casing 50 via a partition wall 13 formed by coupling two members, so that the output gear 4 can rotate around the axis O of the input shaft 1 while the axis O. Directional displacement is prevented.

  The output side disks 3 and 3 are supported by needle bearings 5 and 5 interposed between the input shaft 1 so as to be rotatable about the axis O of the input shaft 1. Further, the left input side disk 2 in the figure is supported on the input shaft 1 via a ball spline 6, and the right side input disk 2 in the figure is splined to the input shaft 1. Rotates with the input shaft 1. A power roller 11 (see FIG. 13) is rotatable between the inner side surfaces (concave surfaces) 2a, 2a of the input side disks 2, 2 and the inner side surfaces (concave surfaces) 3a, 3a of the output disks 3, 3. It is pinched.

  A step 2b is provided on the inner peripheral surface 2c of the input disk 2 located on the right side in FIG. 12, and the step 1b provided on the outer peripheral surface 1a of the input shaft 1 is abutted against the step 2b. At the same time, the back surface (right surface in FIG. 12) of the input side disk 2 is abutted against the loading nut 9. Thereby, the displacement of the input side disk 2 in the direction of the axis O with respect to the input shaft 1 is substantially prevented. Further, a disc spring 8 is provided between the cam plate 7 and the flange 1d of the input shaft 1, and this disc spring 8 is a concave surface 2a, 2a, 3a of each disk 2, 2, 3, 3. , 3a and the contact surface between the peripheral surfaces 11a and 11a of the power rollers 11 and 11 are applied with a pressing force.

  13 is a cross-sectional view taken along line AA in FIG. As shown in FIG. 13, inside the casing 50, a pair of trunnions 15 that swing (tilt) about a pair of pivots (tilting shafts) 14, 14 that are twisted with respect to the input shaft 1, 15 is provided. In FIG. 13, the input shaft 1 is not shown. Each trunnion 15, 15 is a pair of bent wall portions 20, 20 formed at both ends in the longitudinal direction (vertical direction in FIG. 13) of the support plate portion 16 so as to be bent toward the inner surface side of the support plate portion 16. have. The bent wall portions 20 and 20 form concave pocket portions P for accommodating the power rollers 11 in the trunnions 15 and 15. Further, the pivot shafts 14 and 14 are concentrically provided on the outer side surfaces of the bent wall portions 20 and 20, respectively.

  A circular hole 21 is formed in the center portion of the support plate portion 16, and a base end portion (first shaft portion) 23 a of the displacement shaft 23 is supported in the circular hole 21. Then, by swinging each trunnion 15, 15 about each pivot 14, 14, the inclination angle of the displacement shaft 23 supported at the center of each trunnion 15, 15 can be adjusted. Each power roller 11 is rotatably supported via a radial needle bearing 98 around a distal end portion (second shaft portion) 23b of the displacement shaft 23 protruding from the inner surface of each trunnion 15, 15. The power rollers 11 and 11 are sandwiched between the input disks 2 and 2 and the output disks 3 and 3. In addition, the base end part 23a and the front-end | tip part 23b of each displacement shaft 23 and 23 are mutually eccentric.

  Further, the pivot shafts 14 and 14 of the trunnions 15 and 15 are supported so as to be swingable with respect to the pair of yokes 23A and 23B and to be displaceable in the axial direction (vertical direction in FIG. 13). The horizontal movement of the trunnions 15 and 15 is restricted by 23B. Each yoke 23A, 23B is formed in a rectangular shape by pressing or forging a metal such as steel. Four circular support holes 18 are provided at the four corners of each of the yokes 23 </ b> A and 23 </ b> B, and the pivot shafts 14 provided at both ends of the trunnion 15 swing through the radial needle bearings 30. It is supported freely. In addition, a circular locking hole 19 is provided in the central portion of the yokes 23A and 23B in the width direction (the left-right direction in FIG. 13). The inner peripheral surface of the locking hole 19 is a spherical concave surface, and is a spherical post. 64 and 68 are fitted inside. That is, the upper yoke 23A is swingably supported by the spherical post 64 supported by the casing 50 via the fixing member 52, and the lower yoke 23B is supported by the spherical post 68 and the drive for supporting the same. The upper cylinder body 61 of the cylinder 31 is swingably supported.

  The displacement shafts 23 and 23 provided in the trunnions 15 and 15 are provided at positions 180 degrees opposite to the input shaft 1. Further, the direction in which the distal end portion 23b of each of the displacement shafts 23, 23 is eccentric with respect to the base end portion 23a is the same direction as the rotational direction of both the disks 2, 2, 3, 3 (in FIG. (Reverse direction). Further, the eccentric direction is a direction substantially orthogonal to the direction in which the input shaft 1 is disposed. Accordingly, the power rollers 11 and 11 are supported so that they can be slightly displaced in the longitudinal direction of the input shaft 1. As a result, even if each power roller 11, 11 tends to be displaced in the axial direction of the input shaft 1 due to elastic deformation of each component member based on the thrust load generated by the pressing device 12, each component This displacement is absorbed without applying an excessive force to the member.

  Further, between the outer surface of the power roller 11 and the inner surface of the support plate portion 16 of the trunnion 15, a thrust ball bearing 24, which is a thrust rolling bearing, and a thrust needle bearing are sequentially arranged from the outer surface side of the power roller 11. 25. Among these, the thrust ball bearing 24 supports the rotation of each power roller 11 while supporting the load in the thrust direction applied to each power roller 11. Each of the thrust ball bearings 24 is composed of a plurality of balls 26, 26, an annular retainer 27 for holding the balls 26, 26 in a freely rolling manner, and an annular outer ring 28. ing. Further, the inner ring raceway of each thrust ball bearing 24 is formed on the outer side surface (large end surface) of each power roller 11, and the outer ring raceway is formed on the inner side surface of each outer ring 28.

  The thrust needle bearing 25 is sandwiched between the inner surface of the support plate portion 16 of the trunnion 15 and the outer surface of the outer ring 28. Such a thrust needle bearing 25 supports the thrust load applied to the outer ring 28 from the power roller 11 and allows the power roller 11 and the outer ring 28 to swing around the base end portion 23 a of each displacement shaft 23. To do.

  Furthermore, drive rods (trunnion shafts) 29 and 29 are provided at one end portions (lower end portions in FIG. 13) of the trunnions 15 and 15, respectively, and a drive piston ( Hydraulic pistons) 33, 33 are fixed. Each of these drive pistons 33 and 33 is oil-tightly fitted in a drive cylinder 31 constituted by an upper cylinder body 61 and a lower cylinder body 62. The drive pistons 33 and 33 and the drive cylinder 31 constitute a drive device 32 that displaces the trunnions 15 and 15 in the axial direction of the pivots 14 and 14 of the trunnions 15 and 15.

  In the case of the toroidal continuously variable transmission configured as described above, the rotation of the input shaft 1 is transmitted to the input side disks 2 and 2 via the pressing device 12. Then, the rotation of the input side disks 2 and 2 is transmitted to the output side disks 3 and 3 via the pair of power rollers 11 and 11, and the rotation of the output side disks 3 and 3 is further transmitted to the output gear 4. It is taken out more.

  When changing the rotational speed ratio between the input shaft 1 and the output gear 4, the pair of drive pistons 33, 33 are displaced in opposite directions. As the drive pistons 33 and 33 are displaced, the pair of trunnions 15 and 15 are displaced in directions opposite to each other. For example, the power roller 11 on the left side in FIG. 13 is displaced to the lower side in the figure, and the power roller 11 on the right side in the figure is displaced to the upper side in the figure. As a result, the peripheral surfaces 11a and 11a of the power rollers 11 and 11 act on contact portions of the input side disks 2 and 2 and the inner side surfaces 2a, 2a, 3a and 3a of the output side disks 3 and 3, respectively. The direction of the tangential force changes. As the force changes, the trunnions 15 and 15 swing in opposite directions around the pivots 14 and 14 pivotally supported by the yokes 23A and 23B.

  As a result, the contact position between the peripheral surfaces 11a and 11a of the power rollers 11 and 11 and the inner surfaces 2a and 3a changes, and the rotational speed ratio between the input shaft 1 and the output gear 4 changes. Further, when the torque transmitted between the input shaft 1 and the output gear 4 fluctuates and the amount of elastic deformation of each component changes, the power rollers 11 and 11 and the outer rings attached to the power rollers 11 and 11 will be described. 28 and 28 slightly rotate around the base end portions 23a and 23a of the displacement shafts 23 and 23, respectively. Since the thrust needle bearings 25 and 25 exist between the outer side surfaces of the outer rings 28 and 28 and the inner side surfaces of the support plate portions 16 constituting the trunnions 15 and 15, respectively, the rotation is performed smoothly. Is called. Therefore, as described above, the force for changing the inclination angle of each displacement shaft 23, 23 can be small.

  By the way, in such a toroidal type continuously variable transmission, it is necessary to supply lubricating oil to each bearing of the rotating power roller 11 (see, for example, Patent Document 1). Lubrication of each bearing of the power roller 11 is performed, for example, in FIG. 14 (in this figure, the outer ring 28 and the displacement shaft 23 are integrally formed, and the distal end portion 23 b of the displacement shaft 23 ends in the power roller 11. ). Specifically, as indicated by an arrow in FIG. 14, the lubricating oil passes through the first oil passage 202 that extends from the pivot 14 of the trunnion 15 to the support plate 16 via the bent wall portion 20. To the radial needle bearing 200, and from here through the second oil passage 204 of the support plate portion 16 located on the opposite side of the first oil passage 202 with respect to the base end portion 23 a of the displacement shaft 23, the support plate It flows into the space S between the portion 16 and the outer ring 28. Then, the lubricating oil flows from the space S to the thrust needle bearing 25 and reaches the thrust ball bearing 24 through the third oil passage 208 formed in the outer ring 28, and is formed at the distal end portion 23 b of the displacement shaft 23. The radial needle bearing 98 is reached through the formed fourth oil passage 206. FIGS. 15 and 16 show an enlarged view of a B portion and an enlarged view of a C portion in FIG. 14, respectively.

Japanese Patent No. 3430648

  Of the bearings 24, 25, 98, and 200 related to the power roller 11, the thrust needle bearing 25 swings only when it rotates according to torque fluctuation or the like, so that the amount of lubricating oil is not so necessary. On the other hand, since the other bearings 24, 25, and 200 are always rotating, a sufficient amount of lubricating oil is required.

However, in the conventional structure shown in FIGS. 14 to 16, since a lot of lubricating oil is supplied also to the thrust needle bearing 25, a lot of lubricating oil leaks through the thrust needle bearing 25, and the supply loss of the lubricating oil. Will occur. As a result, the lubricating oil cannot be efficiently supplied to the power roller 11 side, and downsizing of the lubrication pump is hindered.
The thrust needle bearing 25 allows the power roller 11 and the outer ring 28 to swing around the base end portion 23a of each displacement shaft 23. That is, the power roller 11 and the outer ring 28 pivot. Because it is for supporting, it makes a rolling-sliding motion. Therefore, the thrust needle bearing 25 is inevitably worn during use, and wear powder may enter the thrust ball bearing 24, which is a power roller bearing, due to wear.

The present invention has been made in view of the above circumstances, and can suppress the supply loss of the lubricating oil, can efficiently supply the lubricating oil to the power roller side, and can reduce the size of the lubricating pump. An object is to provide a step transmission.
Another object of the present invention is to provide a toroidal type continuously variable transmission that can prevent wear powder from entering the power roller bearing.

  In order to achieve the above object, the toroidal continuously variable transmission according to claim 1 is characterized in that an input side disk and an output that are supported concentrically and rotatably with their respective inner surfaces facing each other. Side discs, a trunnion that swings around a pivot that is twisted with respect to the center axis of the input side disc and the output side disc, and a base end portion and a tip end portion that are eccentric to each other, and load in the radial direction. A displacement shaft having the base end portion supported in the trunnion hole via a first bearing to be supported, and a periphery of the distal end portion of the displacement shaft via a second bearing for supporting a radial load. A power roller sandwiched between the input-side disk and the output-side disk in a state of being rotatably supported by the power roller, and the power roller provided between the power roller and the trunnion. A third bearing for supporting a load in a thrust direction applied to the roller, and the third bearing includes an inner ring having a raceway surface formed by a large end surface of the power roller, an outer ring, and the inner ring and the outer ring. A plurality of rolling elements that roll on the raceway surface, and a fourth bearing that supports a thrust load applied to the outer ring from the power roller is sandwiched between the trunnion and the outer ring. In the toroidal continuously variable transmission, an oil passage for supplying lubricating oil is formed from the trunnion to the displacement shaft and the outer ring, and the oil passage extends to supply the lubricating oil to the first to third bearings. In addition, the first bearing is provided with lubricating oil supply blocking means for blocking the lubricating oil supplied to the first bearing from being supplied to the fourth bearing. . This configuration is particularly beneficial in a structure in which the first bearing communicates with the fourth bearing through a predetermined gap (space) and the lubricating oil leaks through the fourth bearing.

  The toroidal continuously variable transmission according to claim 2 is the toroidal continuously variable transmission according to claim 1, wherein the lubricating oil supply blocking means is provided on an outer ring of the first bearing and It is characterized by comprising a seal portion for sealing lubricating oil supplied to the first bearing in the hole of the trunnion.

  In the above configuration, the seal portion may be formed separately from the outer ring of the first bearing and attached to the outer ring, or may be formed integrally with the outer ring of the first bearing. Moreover, the shape of the seal portion is also arbitrary, and may have a cap structure, for example.

  A toroidal continuously variable transmission according to a third aspect of the present invention is the invention according to the first or second aspect, wherein the third bearing includes a cage that holds the plurality of rolling elements. The cage is formed with a dynamic pressure groove for increasing the pressure of the lubricating oil supplied from the oil passage, and the outer ring has oil penetrating between the outer ring and the trunnion from the vicinity of the dynamic pressure groove. A hole is formed.

  A toroidal continuously variable transmission according to a fourth aspect of the present invention is the invention according to the first or second aspect, wherein the third bearing includes a cage that holds the plurality of rolling elements, The outer ring has an oil hole penetrating between the outer ring and the trunnion from the vicinity of the retainer, and is supplied from the oil passage to the end of the oil hole that opens to the retainer side. An oil intake portion that takes in a part of the lubricating oil is formed.

In the toroidal type continuously variable transmission according to claim 1 and claim 2 of the present invention, lubricating oil supply blocking means for blocking the lubricating oil supplied to the first bearing from being supplied to the fourth bearing. Is provided on the first bearing. Therefore, it is prevented that the lubricating oil is supplied to the fourth bearing and leaks from the fourth bearing. As a result, it is possible to efficiently supply the lubricating oil to the power roller side while suppressing the supply loss of the lubricating oil, and to reduce the size of the lubricating pump.
In the toroidal type continuously variable transmission according to claim 3, the lubricating oil supplied from the oil passage formed from the trunnion to the displacement shaft and the outer ring is introduced into the third bearing and part of the lubricating oil. After the pressure is increased by the dynamic pressure groove formed in the cage, the fourth bearing is lubricated through the oil hole formed in the outer ring and between the outer ring and the trunnion. Therefore, the wear powder of the fourth bearing does not enter the third bearing which is the power roller bearing.
Furthermore, in the toroidal continuously variable transmission according to claim 4, the lubricating oil supplied from the oil passage formed from the trunnion to the displacement shaft and the outer ring is introduced into the third bearing and part of the lubricating oil. Is taken into the oil take-in portion, and then passes between the outer ring and the trunnion through an oil hole formed in the outer ring to lubricate the fourth bearing. Therefore, the wear powder of the fourth bearing does not enter the third bearing which is the power roller bearing.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The feature of the present invention resides in the supply form of the lubricating oil to the bearing on the power roller side, and other configurations and operations are the same as the conventional configurations and operations described above. Only the above will be referred to, and the other parts will be simply described with the same reference numerals as in FIGS.

  1 and 2 show an embodiment of the present invention. As shown in FIG. 1 (a), in the circular hole 21 of the trunnion 15, a radial needle bearing (solid needle bearing) 200 as a first bearing for supporting a radial load is provided. The base end portion 23a is supported. The power roller 11 is rotatably supported around a distal end portion 23b of the displacement shaft 23 via a radial needle bearing 98 as a second bearing for supporting a radial load. A thrust ball bearing 24 is provided between the power roller 11 and the trunnion 15 as a third bearing that supports a load in the thrust direction applied to the power roller 11. The thrust ball bearing 24 includes an inner ring whose raceway surface is formed by the large end surface 11 b of the power roller 11, an outer ring 28, and balls 26 as a plurality of rolling elements that roll on the raceway surfaces of the inner ring and the outer ring 28. And have. Further, between the trunnion 15 and the outer ring 28, the power roller 11 and the outer ring 28 swing around the base end 23 a of the displacement shaft 23 while supporting a thrust load applied to the outer ring 28 from the power roller 11. A thrust needle bearing 25 as an allowable fourth bearing is sandwiched. The thrust needle bearing 25 communicates with the radial needle bearing 200 through a space (gap) S between the support plate portion 16 and the outer ring 28 of the trunnion 15 and has a concave pocket portion P that accommodates the power roller 11. There is a gap leading to the space. This gap is to leak the lubricating oil into the space of the pocket portion P when the lubricating oil is supplied to the thrust needle bearing 25.

  In the present embodiment, an oil passage 300 for supplying lubricating oil is formed from the trunnion 15 to the displacement shaft 23 and the outer ring 28. The oil passage 300 includes a first oil passage 300a extending from the pivot 14 of the trunnion 15 through the bent wall portion 20 to the support plate portion 16 and reaching the circular hole 21, and the displacement shaft 23 extending in the axial direction over the entire length thereof. And a third oil passage 300c that intersects with the second oil passage 300b in a communicating state and reaches the thrust ball bearing 24.

  As clearly shown in FIG. 2, the radial needle bearing 200 has a bearing body 200 a and an outer ring 200 b that forms a raceway of the bearing body 200 a, and the outer ring 200 b is supplied to the radial needle bearing 200. A sealing member (seal part) 310 is provided as a lubricating oil supply blocking means for blocking the supply of lubricating oil to the thrust needle bearing 25. The seal member 310 is formed separately from the outer ring 200b of the radial needle bearing 200 and attached to the outer ring 200b, and seals the lubricating oil supplied to the radial needle bearing 200 in the circular hole 21 of the trunnion 15. .

  Therefore, in such a configuration, the lubricating oil flows to the radial needle bearing 200 in the circular hole 21 through the first oil passage 300a as shown by the arrow in FIG. The oil flows from the passage 300a to the second oil passage 300b and reaches the thrust ball bearing 24 and the radial needle bearing 98 through the second oil passage 300b and the third oil passage 300c. In this case, the outer ring 200b of the radial needle bearing 200 is provided with the seal member 310 that seals the lubricating oil supplied to the radial needle bearing 200 in the circular hole 21 of the trunnion 15, and is thus supplied to the radial needle bearing 200. Is prevented from being supplied to the thrust needle bearing 25. Therefore, the lubricating oil is prevented from being supplied to the thrust needle bearing 25 and leaking from the thrust needle bearing 25. As a result, it is possible to efficiently supply the lubricating oil to the power roller 11 side (the thrust ball bearing 24 and the radial needle bearing 98) while suppressing the supply loss of the lubricating oil, and to reduce the size of the lubricating pump.

  FIG. 3 shows a modification of the lubricating oil supply blocking means for blocking the lubricating oil supplied to the radial needle bearing 200 from being supplied to the thrust needle bearing 25. In this modification, the flange portion 400 at the end of the outer ring 200b of the radial needle bearing 200 extends in the radial direction of the displacement shaft 23 so as to perform the same function as the seal member 310 (a cap seal structure is formed). ). That is, the seal member 310 is formed integrally with the outer ring 200b.

  4 to 7 show other structural forms that suppress the supply loss of the lubricating oil. 4 and 5 (the arrow indicates the flow of the lubricating oil), in addition to the same configuration as that shown in FIG. 10, the trunnion side raceway surface of the thrust needle bearing 25 is L-shaped. The flange portion 500a of the thin plate 500 prevents the lubricating oil from leaking from the thrust needle bearing 25 (or is minimized).

  4 and 5, the flange portion 500a is located on the radially inner side of the bearing 25. However, the flange 500a may be located on the radially outer side of the bearing 25 as shown in FIG. Further, as shown in FIG. 7, a sealing member 505 may be attached to the flange 500a to further improve the sealing performance.

  As described above, the position where the flange portion 500 a is provided may be on the radially inner side or the radially outer side of the bearing 25, but is preferably on the radially inner side of the bearing 25. Further, the position where the seal member 505 is mounted is also preferably on the radially inner side of the bearing 25. The reason is as follows.

  That is, when the power roller 11 swings, the thrust needle bearing 25 and the outer ring 28 are displaced from each other. At this time, if the flange portion 500a is on the outer side in the radial direction, the flange portion 500a may come off from the outer ring 28. In this case, the sealing performance is lost. In addition, if it is attempted to secure a size that does not come off even in this case, downsizing of the device is restricted. In addition, when the seal member 505 is mounted, it is necessary to consider the friction when swinging. If the seal member 505 is on the outer side in the radial direction of the bearing 25, the turning radius when swinging becomes large. , Friction will increase. Further, as shown in FIG. 7, when the seal member 505 is mounted, it may be formed integrally with the thin plate 500, or even if it is a separate body, it may be mounted on the thin plate 500 by caulking or the like. good. The seal structure is not particularly limited, but a shape / material (PTFE) having a small friction coefficient is preferable.

  8 and 9 show another embodiment of the present invention. This embodiment differs from the embodiment shown in FIG. 1 and FIG. 2 in that a lubrication method is added to the thrust needle bearing (fourth bearing) 25, and other configurations are shown in FIG. Since it is the same as that of the embodiment shown in FIG. 2, common portions are denoted by the same reference numerals and description thereof is simplified or omitted.

  As shown in FIGS. 8 and 9, the thrust ball bearing (third bearing) 24 includes an annular cage 27 that holds a ball 26. A dynamic pressure groove 27 a is formed on the end surface of the cage 27. The dynamic pressure groove 27a increases the pressure of the lubricating oil supplied from the third oil passage 300c, and the thickness of the dynamic pressure groove 27a is smaller than that of the third oil passage 300c. The lubricating oil supplied from the third oil passage 300 c is introduced into the dynamic pressure groove 27 a through the gap between the cage 27 and the outer ring 28.

  The outer ring 28 has an oil hole 28a extending in the thickness direction. The oil hole 28a passes through the gap S between the outer ring 28 and the trunnion 15 from the vicinity of the dynamic pressure groove 27a, whereby lubricant is introduced into the gap S from the dynamic pressure groove 27a, and the thrust needle bearing 25 It is designed to lubricate.

  In this embodiment, the lubricating oil supplied from the third oil passage 300 c of the oil passage 300 formed from the trunnion 15 to the displacement shaft 23 and the outer ring 28 is introduced into the thrust ball bearing (third bearing) 24. In addition, a part of the lubricating oil is increased in pressure by a dynamic pressure groove 27 a formed in the cage 27, and then passed between the outer ring 28 and the trunnion 15 through an oil hole 28 a formed in the outer ring 28. The thrust needle bearing (fourth bearing) 25 is lubricated through the gap S. Therefore, the abrasion powder of the thrust needle bearing 25 does not enter the thrust ball bearing 24 that is a power roller bearing.

  The lubricating oil supply blocking means may be provided as a seal member (seal part) 310 on the outer ring 200b of the radial needle bearing 200, or the seal member 310 may be formed integrally with the outer ring 200b. Further, the lubricating oil supply blocking means includes a trunnion side raceway surface of the thrust needle bearing 25 constituted by an L-shaped thin plate (steel plate) 500, and leakage of lubricating oil from the thrust needle bearing 25 by the flange portion 500 a of the thin plate 500. It is good also as a structure which prevents.

  10 and 11 show still another embodiment of the present invention. This embodiment differs from the embodiment shown in FIG. 1 and FIG. 2 in that a lubrication method is added to the thrust needle bearing (fourth bearing) 25, and other configurations are shown in FIG. Since it is the same as that of the embodiment shown in FIG. 2, common portions are denoted by the same reference numerals and description thereof is simplified or omitted.

As shown in FIGS. 10 and 11, an oil hole 28 a is formed in the outer ring 28 of the thrust ball bearing (third bearing) 24. The oil hole 28 a passes through the gap S between the outer ring 28 and the trunnion 15 from the vicinity of the inner diameter portion of the cage 27. An oil intake portion 28b is formed at the end of the oil hole 28a that opens to the cage 27 side. The oil take-in portion 28b takes in a part of the lubricating oil supplied from the third oil passage 300c. The oil intake portion 28 b is formed in a hole shape, and its diameter is larger than the diameter of the oil hole 28.
An inclined surface 27 b is formed on the end surface of the inner diameter portion of the cage 27. The inclined surface 27b is inclined so as to be away from the end surface (the upper end surface in FIG. 11) of the retainer 27 as it goes inward of the retainer 27, whereby lubricant oil is directed toward the oil intake portion 28b. The flow path is narrowed and guided.

In this embodiment, the lubricating oil supplied from the third oil passage 300 c of the oil passage 300 formed from the trunnion 15 to the displacement shaft 23 and the outer ring 28 is introduced into the thrust ball bearing (third bearing) 24. In addition, after a part of the lubricating oil is taken into the oil take-in portion 28b, the oil passes through the oil hole 28a formed in the outer ring 28 and reaches the gap S between the outer ring 28 and the trunnion 15, so that the thrust needle bearing (Fourth bearing) 25 is lubricated. Therefore, the abrasion powder of the thrust needle bearing 25 does not enter the thrust ball bearing 24 which is a power roller bearing.
The lubricating oil supplied from the third oil passage 300c is introduced into a thrust ball bearing (third bearing) 24, and a part of the lubricating oil is pressured by an inclined surface 27b formed in the cage 27. In addition to being enhanced, the flow direction of the lubricating oil can be changed toward the oil intake portion 28b, so that the lubricating oil can be reliably taken into the oil intake portion 28b.

  Also in the present embodiment, the lubricating oil supply blocking means may be provided as a seal member (seal part) 310 on the outer ring 200b of the radial needle bearing 200, or the seal member 310 is formed integrally with the outer ring 200b. May be. Further, the lubricating oil supply blocking means includes a trunnion side raceway surface of the thrust needle bearing 25 constituted by an L-shaped thin plate (steel plate) 500, and leakage of lubricating oil from the thrust needle bearing 25 by the flange portion 500 a of the thin plate 500. It is good also as a structure which prevents.

  The present invention can be applied to various half-toroidal continuously variable transmissions such as a single cavity type and a double cavity type.

It is principal part sectional drawing of embodiment of this invention. It is a principal part expanded sectional view of FIG. It is sectional drawing which shows the modification of FIG. It is sectional drawing which shows another structural form which suppresses the supply loss of lubricating oil. It is a principal part expanded sectional view of FIG. It is sectional drawing which shows the modification of FIG. It is sectional drawing which shows the other modification of FIG. It is principal part sectional drawing of other embodiment of this invention. It is a principal part expanded sectional view of FIG. It is principal part sectional drawing of other embodiment of this invention. It is a principal part expanded sectional view of FIG. It is sectional drawing which shows an example of the specific structure of the half toroidal type continuously variable transmission conventionally known. It is sectional drawing which follows the AA line of FIG. It is sectional drawing which shows an example of the conventional lubricating oil supply structure. It is an expanded sectional view of the B section of FIG. It is an expanded sectional view of the C section of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Input shaft 2 Input side disk 3 Output side disk 11 Power roller 15 Trunnion 21 Circular hole (hole)
23 Displacement shaft 24 Thrust ball bearing (third bearing)
25 Thrust needle bearing (fourth bearing)
26 balls (rolling elements)
27 Cage 27a Dynamic pressure groove 28 Outer ring 28a Oil hole 28b Oil intake part 98 Radial needle bearing (second bearing)
200 Radial needle bearing (first bearing)
300a, 300b, 300c Oil passage 310 Seal member (lubricating oil supply blocking means; seal portion)
400 Flange (Lubricating oil supply blocking means; seal part)

Claims (4)

The input side disk and the output side disk supported concentrically and rotatably with the respective inner side surfaces facing each other, and the twisted position with respect to the center axis of the input side disk and the output side disk A trunnion that swings about a pivot, a base end portion and a tip end portion that are eccentric to each other, and the base end portion is supported in a hole of the trunnion via a first bearing that supports a radial load. And sandwiched between the input-side disk and the output-side disk in a state of being rotatably supported around the distal end portion of the displacement shaft via a second bearing that supports a radial load. And a third bearing that is provided between the power roller and the trunnion and supports a load in the thrust direction applied to the power roller. The bearing includes an inner ring whose raceway surface is formed by the large end surface of the power roller, an outer ring, and a plurality of rolling elements that roll on the raceway surfaces of the inner ring and the outer ring, and the trunnion and the outer ring In a toroidal type continuously variable transmission in which a fourth bearing for supporting a thrust load applied to the outer ring from the power roller is sandwiched,
An oil passage for supplying lubricating oil is formed from the trunnion to the displacement shaft and the outer ring, and the oil passage extends to supply lubricating oil to the first to third bearings, and to the first bearing. Is a toroidal continuously variable transmission, characterized in that it is provided with lubricating oil supply blocking means for blocking the lubricating oil supplied to the first bearing from being supplied to the fourth bearing.   The lubricating oil supply blocking means comprises a seal portion provided on an outer ring of the first bearing and sealing the lubricating oil supplied to the first bearing in the hole of the trunnion. Item 2. The toroidal continuously variable transmission according to item 1. The third bearing includes a cage that holds the plurality of rolling elements,
A dynamic pressure groove for increasing the pressure of the lubricating oil supplied from the oil passage is formed in the cage,
The toroidal continuously variable transmission according to claim 1 or 2, wherein an oil hole penetrating between the outer ring and the trunnion is formed in the outer ring from the vicinity of the dynamic pressure groove. Machine. The third bearing includes a cage that holds the plurality of rolling elements,
The outer ring has an oil hole penetrating between the outer ring and the trunnion from the vicinity of the cage,
The oil intake part which takes in a part of lubricating oil supplied from the said oil path is formed in the edge part of the said oil hole opened to the said holder | retainer side, The Claim 1 or Claim 2 characterized by the above-mentioned. The toroidal type continuously variable transmission described in 1.

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