JP2009192080A - Toroidal continuously variable transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive toroidal continuously variable transmission of high cooling performance, which simplifies a structure of a lubricating oil supply passage to a traction surface and a bearing part of a power roller while preventing splashes of lubricating oil during rotation of the power roller. <P>SOLUTION: The toroidal continuously variable transmission has a lubricating oil guide cover 300 extended to guide lubricating oil to the traction surface of the power roller 11. Specifically, the power roller 11 is covered with the lubricating oil guide cover 300 except for the traction surface, where the power roller 11 is in oil film contact with disks 2 and 3. The traction oil flows along the surface of the power roller 11 until it reaches the traction surface. The traction oil thus resides around the traction surface without any splashes and for a long time to cool the power roller 11 efficiently. <P>COPYRIGHT: (C)2009,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. 14, an input shaft 1 is rotatably supported inside the casing 50, and two input side disks 2, 2 and two output side disks 3 are disposed on the outer periphery of the input shaft 1. 3 is 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 driven to rotate by a drive shaft 22 via a loading cam type pressing device 12 provided between an input side disk 2 and a cam plate (loading cam) 7 located on the left side in the drawing. It has become. The output gear 4 is supported on a partition wall (intermediate wall) 13 formed by coupling two members via an angular ball bearing 107 and is supported in the casing 50 via the partition wall 13. Thus, while being able to rotate around the axis O of the input shaft 1, displacement in the direction of the axis O 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 is provided between the inner side surfaces (concave surface; also referred to as a traction surface) 2a and 2a of the input side disks 2 and 2 and the inner side surfaces (concave surface; also referred to as a traction surface) 3a and 3a of the output disks 3 and 3. 11 (see FIG. 15) is rotatably held.

  A step 2b is provided on the inner peripheral surface 2c of the input side disk 2 located on the right side in FIG. 14, 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. 14) of the input side disk 2 is abutted against a loading nut 9 screwed into a screw portion formed on the outer peripheral surface of the input shaft 1. 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.

  As shown in FIG. 15 which is a cross-sectional view taken along the line AA in FIG. 14, both discs 3 and 3 are sandwiched from both sides inside the casing 50 and laterally to the output side discs 3 and 3. The pair of yokes 23A and 23B is supported in the state. The pair of yokes 23A and 23B are formed in a rectangular shape by pressing or forging a metal such as steel. In order to support pivots 14 provided at both ends of the trunnion 15 to be described later in a swingable manner, circular support holes 18 are provided at the four corners of the yokes 23A and 23B, and the width direction of the yokes 23A and 23B. A circular locking hole 19 is provided at the center of the.

  The pair of yokes 23A and 23B is supported by support posts 64 and 68 formed on the inner surface of the casing 50 so as to be able to swing around the support posts 64 and 68 as fulcrums. These support posts 64 and 68 are provided so as to face the first cavity 221 and the second cavity 222, respectively, between the inner side surface 2a of the input side disk 2 and the inner side surface 3a of the output side disk 3. Yes.

  Therefore, the yokes 23 </ b> A and 23 </ b> B are supported by the support posts 64 and 68, and one end thereof faces the outer peripheral portion of the first cavity 221, and the other end faces the outer peripheral portion of the second cavity 222. is doing.

  Since the first and second cavities 221 and 222 have the same structure, only the first cavity 221 will be described below.

  As shown in FIG. 15, inside the casing 50, the first cavity 221 includes a pair of trunnions that swing around a pair of pivots (tilting shafts) 14 and 14 that are twisted with respect to the input shaft 1. 15 and 15 are provided. Note that the input shaft 1 is not shown in FIG. Each trunnion 15, 15 is a pair of bent portions formed at the both end portions in the longitudinal direction (vertical direction in FIG. 15) of the support plate portion 16, which is the main body portion, so as to be bent toward the inner surface side of the support plate portion 16. Wall portions 20 and 20 are provided. The trunnions 15 and 15 form a pocket portion K that is a concave accommodation space for accommodating the power roller 11 by the bent wall portions 20 and 20. 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 central portion of the support plate portion 16, and a base end portion (first shaft portion) 23 a of a displacement shaft 23 as a support shaft 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. In addition, each power roller 11 is rotatably supported around the tip end portion (second shaft portion) 23b of the displacement shaft 23 protruding from the inner surface of each trunnion 15, 15. 11 is 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, as described above, the pivot shafts 14 of the trunnions 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. 15). The trunnions 15 and 15 are restricted from moving in the horizontal direction by the yokes 23A and 23B. As described above, four circular support holes 18 are provided at the four corners of each of the yokes 23A and 23B, and the pivot shafts 14 provided at both ends of the trunnion 15 are respectively provided in the support holes 18 with radial needle bearings ( A tilting bearing 30 is supported so as to be swingable (tiltable). Further, as described above, the circular locking hole 19 is provided in the central part of the yokes 23A and 23B in the width direction (left and right direction in FIG. 14), and the inner peripheral surface of the locking hole 19 is a cylinder. Support posts 64 and 68 are internally fitted as surfaces. 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 that is a thrust rolling bearing, and a thrust needle bearing, in order 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 such thrust ball bearings 24 includes a plurality of balls (rolling elements) 26, 26, an annular retainer 27 that holds the balls 26, 26 in a freely rolling manner, and an annular outer ring 28. It consists of and. 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 each outer ring 28 from the power roller 11, while the power roller 11 and the outer ring 28 swing around the base end portion 23 a of each displacement shaft 23. Allow.

  Further, drive rods (shaft portions extending from the pivot shaft) 29 and 29 are provided at one end portions (lower end portions in FIG. 15) of the trunnions 15 and 15, respectively, and outer peripheral surfaces of intermediate portions of the drive rods 29 and 29 are provided. The drive pistons (hydraulic pistons) 33, 33 are fixedly provided. 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 drive shaft 22 is transmitted to the input side disks 2 and 2 and the input shaft 1 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 (offset) in opposite directions. For example, the power roller 11 on the left side of FIG. 15 is displaced downward in the figure, and the power roller 11 on the right side of FIG. 15 is displaced upward 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 (tilt) in opposite directions around the pivots 14 and 14 pivotally supported by the yokes 23A and 23B.

  As a result, the contact positions of the peripheral surfaces (traction surfaces) 11a and 11a of the power rollers 11 and 11 and the inner surfaces 2a and 3a change, and the rotational speed ratio between the input shaft 1 and the output gear 4 is changed. Change. 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 the toroidal type continuously variable transmission having the above-described configuration, the power transmission between the power roller 11 and the input / output side disks 2 and 3 is caused by a traction force through an oil film to prevent damage to the surface of these members. (Hereinafter, the interface between the power roller 11 formed by the oil film and the input / output side disks 2 and 3 is referred to as a traction surface. In this specification, for convenience, the peripheral surface 11a of the power roller 11 is referred to as a traction surface. May be referred to as a traction surface). Therefore, it is necessary to supply a sufficient amount of lubricating oil (traction oil) that can form an oil film for transmitting torque in a non-contact manner on the traction surface formed between the power roller 11 and the input / output side disk. is there.

  Further, in the power transmission between the disks 2 and 3 and the power roller 11 through such an oil film, a contact portion between the disks 2 and 3 and the power roller 11 and a bearing portion of the power roller 11 (for example, a thrust ball bearing) 24 etc.), so that heat is generated. Therefore, it is necessary to sufficiently supply the lubricating oil to the bearing portion of the power roller 11.

  Conventionally, the supply of lubricating oil to the traction surface and the bearing portion of the power roller 11 is formed in the trunnion and an oil passage formed in the trunnion and extending to the traction surface of the power roller 11 as disclosed in Patent Document 1, for example. And an oil passage extending to the bearing portion of the power roller 11.

JP 2007-154952 A

  In the structure disclosed in Patent Document 1, an oil passage for supplying lubricating oil to the traction surface of the power roller 11 and an oil passage for supplying lubricating oil to the bearing portion of the power roller 11 intersect with the trunnion. It is formed in a lump. Thus, when the oil path of the several path | route which goes to a different site | part is provided in crossing with the trunnion, manufacturing cost will increase.

  In addition, when lubricating oil is injected from the trunnion side to the traction surface through the oil passage, the lubricating oil is bounced and scattered by the rotation of the power roller, so that the traction surface cannot be efficiently lubricated. Therefore, it is necessary to increase the supply amount of the lubricating oil so as not to cause insufficient cooling of the traction surface or to prevent insufficient cooling.

  The present invention was made in view of the above circumstances, and the structure of the lubricating oil supply path to the traction surface and the bearing portion of the power roller can be simplified while preventing the scattering of the lubricating oil due to the rotation of the power roller. An object of the present invention is to provide a low-cost toroidal continuously variable transmission with high cooling performance.

  In order to achieve the above object, a toroidal continuously variable transmission according to the present invention is provided between an input side disk coupled to an input shaft receiving rotational force and rotating integrally with the input shaft. A toroidal-type continuously variable transmission including an output-side disk that receives the rotational force of the input-side disk at a predetermined speed ratio via a power roller, and power transmission between the power roller and the disk is performed via an oil film. The lubricating oil is guided to the traction surface of the power roller that faces the input shaft and is opposed to the surface of the power roller and transmits power to the disk via an oil film. And a lubricant supply means for supplying the lubricant to the vicinity of the center of the lubricant guide cover.

  According to the present invention, the lubricating oil (traction oil) supplied near the center of the lubricating oil guide cover creates a gap between the surface of the power roller (small end surface) facing the input shaft and the lubricating oil guide cover. It is carried radially outward by the rotation of the power roller and reaches the traction surface. In this case, the lubricating oil guide cover extends so as to guide the lubricating oil to the traction surface of the power roller, that is, the portion of the power roller other than the traction surface where the disk and the power roller come into oil film contact is lubricated. Since it is covered by the oil guide cover, the traction oil flows along the surface portion of the power roller until it reaches the traction surface. Therefore, since the traction oil is present in the vicinity of the traction surface for a long time without scattering, the power roller can be efficiently cooled. In addition, since the lubricating oil is supplied to the traction surface by the lubricating oil guide cover, there is no need to provide an oil passage in the trunnion for supplying the lubricating oil to the traction surface of the power roller (in other words, the power roller The lubricating oil passage to the bearing portion only needs to be provided in the trunnion), and the structure of the oil passage in the trunnion is simplified. In other words, a low-cost toroidal continuously variable transmission with high cooling performance that can simplify the structure of the lubricating oil supply path to the traction surface and bearing of the power roller while preventing the scattering of the lubricating oil due to the rotation of the power roller. Can provide.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The feature of the present invention lies in the form of supplying the lubricating oil to the traction surface of the power roller, and other configurations and operations are the same as the conventional configurations and operations described above. Therefore, the features of the present invention are described below. Only the portion will be referred to, and the other portions will be simply described with the same reference numerals as those in FIGS. 14 and 15.

  1 to 3 show a first embodiment of the present invention. This embodiment shows a half-toroidal continuously variable transmission, and a resin or metal lubricating oil guide cover 300 in the vicinity of the traction surface of the power roller 11 (a part on the outermost diameter side of the peripheral surface 11a). Is provided. Specifically, the lubricating oil guide cover 300 faces the input shaft 1 and is opposed to the surface of the power roller 11. The power roller 11 transmits power to the disks 2 and 3 via an oil film. It extends to guide the lubricant to the traction surface. More specifically, the lubricating oil guide cover 300 has a circular plane portion 300a facing the small end surface (a plane portion facing the input shaft 1) of the power roller 11 and a traction surface other than the traction surface contacting the discs 2 and 3. It consists of a peripheral surface facing portion 300b covering the peripheral surface 11a portion of the power roller 11 (opposing the peripheral surface 11a with a gap). Further, the lubricant guide cover 300 is, for example, snap-coupled to a displacement shaft 23 (formed as a shaft integral with the outer ring 28 in this embodiment) as a support shaft that rotatably supports the power roller 11. It is fitted and installed. Therefore, in this embodiment, a locking piece 300d that is elastically engaged with the engaging portion of the end surface of the displacement shaft 23 is provided near the center of the circular flat portion 300a of the lubricant guide cover 300, for example. Of course, the mounting form of the lubricant guide cover 300 to the displacement shaft 23 is not limited to this. For example, the metal lubricant guide cover 300 may be fixed to the displacement shaft 23 integral with the outer ring 28 with a retaining ring or the like. Similar effects can be obtained.

  In the present embodiment, a lubricating oil supply means for supplying the lubricating oil to the vicinity of the center of the lubricating oil guide cover 300 is provided. Specifically, the lubricating oil supply means includes a lubricating oil supply pipe 304 coupled to the support plate portion 16 of the trunnion 11, and a first oil passage formed in the support plate portion 16 and communicating with the lubricating oil supply pipe 304. 302 and a second oil passage formed on the displacement shaft 23 and communicating with the first oil passage 302 and opening near the center of the lubricant guide cover 300 (not shown in FIG. 1; see FIG. 3) Consists of.

  In this embodiment, the lubricating oil supply means includes a bearing lubricating oil passage 390 for supplying the lubricating oil to the thrust ball bearing 24. The bearing lubricating oil passage 390 is branched from the second oil passage.

  Therefore, in such a configuration, the traction oil is supplied from the lubricating oil supply pipe 304 attached to the trunnion 15 as indicated by an arrow P in FIG. 3, and the first oil passage 302 and the displacement shaft 23 of the trunnion 15 are supplied. Then, the oil is supplied to the vicinity of the center of the lubricating oil guide cover 300 through the end opening of the second oil passage. The traction oil supplied near the center of the lubricating oil guide cover 300 passes through the gap between the surface (small end surface) of the power roller 11 facing the input shaft 1 and the lubricating oil guide cover 300 by the rotation of the power roller 11. Carried radially outward to reach the traction surface. In this case, the lubricant guide cover 300 extends so as to guide the lubricant to the traction surface of the power roller 11 (the portion of the peripheral surface 11a of the power roller 11 that is not covered by the lubricant guide cover 300 in FIG. 2). In other words, since the portions of the power roller 11 other than the traction surface where the disks 2 and 3 and the power roller 11 are in oil contact with each other are covered with the lubricating oil guide cover 300, the traction oil reaches the traction surface. It flows along the surface portion of the power roller 11. On the other hand, a part of the lubricating oil introduced into the second oil passage is supplied to the thrust ball bearing 24 through the bearing lubricating oil passage 390 as indicated by an arrow P1 in FIG.

  As described above, in the present embodiment, the lubricant guide cover 300 extends so as to guide the lubricant to the traction surface of the power roller 11, that is, the disks 2 and 3, the power roller 11, and the like. Since the portion of the power roller 11 other than the traction surface that contacts the oil film is covered with the lubricating oil guide cover 300, the traction oil flows along the surface portion of the power roller 11 until reaching the traction surface. Therefore, since the traction oil is present in the vicinity of the traction surface for a long time without scattering, the power roller 11 can be efficiently cooled. Further, since the lubricating oil is supplied to the traction surface by the lubricating oil guide cover 300, it is not necessary to provide an oil passage in the trunnion 15 that directly guides the lubricating oil to the traction surface of the power roller 11 (or power It is only necessary to provide the trunnion 15 with a lubricating oil path to the thrust ball bearing (bearing portion) 24 of the roller 11), and the structure of the oil path in the trunnion 15 is simplified. That is, the structure of the lubricating oil supply path to the traction surface of the power roller 11 and the thrust ball bearing 24 can be simplified while preventing the scattering of the lubricating oil due to the rotation of the power roller 11. A continuously variable transmission can be provided.

  4 and 5 show a second embodiment of the present invention. As illustrated, in the present embodiment, the tip edges of the pair of bent wall portions 20 and 20 of the trunnion 15 are connected to each other by a lubricant guide cover 300A. In this way, by connecting the tip edges of the pair of bent wall portions 20 and 20 with the lubricating oil guide cover 300A, the support plate portion 16 (regardless of the thrust load applied to the support plate portion 16 from the power roller 11). It is possible to suppress the trunnion 15) from being elastically deformed. That is, in the present embodiment, the lubricant guide cover 300A not only has the function and effect unique to the lubricant guide cover described in the first embodiment, but also has a function as a trunnion reinforcing member. Specifically, in the present embodiment, the lubricant guide cover 300A includes a substantially U-shaped facing surface portion 300aa facing the small end surface (a planar portion facing the input shaft 1) of the power roller 11, and the disk 2. , 3 and a peripheral surface facing portion 300b covering the peripheral surface 11a portion of the power roller 11 other than the traction surface in contact with the oil film (opposing the peripheral surface 11a with a gap). Further, in the present embodiment, the small end surface of the power roller 11 is not opened but is closed so as to form a recessed portion, and the displacement shaft 23 is located in the recessed portion. In addition, a through hole that opens the second oil passage toward the lubricating oil guide cover 300 </ b> A is formed in a part of the small end surface of the power roller 11 that forms the recessed portion.

In the present embodiment having such a configuration, as in the first embodiment, the traction oil is supplied from the lubricating oil supply pipe 304 attached to the trunnion 15 as indicated by an arrow P in FIG. After being introduced into the first oil passage 302 and the second oil passage of the displacement shaft 23, the lubricating oil guide cover 300 of the lubricating oil guide cover 300 is passed through the end opening of the second oil passage (the through hole in the small end surface of the power roller 11). Supplied near the center. The traction oil supplied near the center of the lubricating oil guide cover 300 passes through the gap between the surface (small end surface) of the power roller 11 facing the input shaft 1 and the lubricating oil guide cover 300 by the rotation of the power roller 11. Carried radially outward to reach the traction surface. In this case, the lubricant guide cover 300 extends so as to guide the lubricant to the traction surface of the power roller 11 (the portion of the peripheral surface 11a of the power roller 11 that is not covered by the lubricant guide cover 300 in FIG. 4). In other words, since the portions of the power roller 11 other than the traction surface where the disks 2 and 3 and the power roller 11 are in oil contact with each other are covered with the lubricating oil guide cover 300, the traction oil reaches the traction surface. It flows along the surface portion of the power roller 11. On the other hand, a part of the lubricating oil introduced into the second oil passage is formed between the inner side surface portion of the small end surface of the power roller 11 forming the recessed portion and the displacement shaft 23 as shown by an arrow P1 in FIG. It flows to the thrust needle bearing 202 inserted between the displacement shaft 23 and the power roller 11 through the gap therebetween, and then reaches the thrust ball bearing 24.
Therefore, also in this embodiment, it is possible to obtain the same function and effect as in the first embodiment.

  FIG. 6 shows a third embodiment of the present invention. As shown in the figure, in the present embodiment, the lubricating oil supply means extends from the pivot 14 of the trunnion 15 to the lubricating oil guide cover 300A (also functions as a reinforcing member of the trunnion 15 as in the second embodiment). The lubricating oil supply passages 29a, 400, and 406 extend to the vicinity of the center of the bearing, and the bearing lubricating oil passages 402, 404, and 392 are branched from the lubricating oil supply passage. Therefore, the lubricating oil supplied from the lubricating oil supply passage 29a of the pivot 14 is supplied to the traction surface and the thrust ball bearing 24 via the paths indicated by arrows P and P1 in FIG.

  7 and 8 show a fourth embodiment of the present invention. In the present embodiment, the lubricant guide cover 300 </ b> B is attached to the trunnion 15. In this case, the lubricant guide cover 300 is attached to the trunnion 15 by, for example, caulking or snap coupling. For this reason, in the present embodiment, caulking portions or snap locking leg portions 300c extending to the trunnion 15 are provided at the four corners of the circular flat surface portion 300a of the lubricant guide cover 300B. Of course, the mounting form of the lubricant guide cover 300B to the trunnion 15 is not limited to this. In the present embodiment, the supply paths P and P1 for the lubricating oil to the traction surface and the thrust ball bearing 24 are the same as those in the second embodiment.

  9 and 10 show a fifth embodiment of the present invention. As shown in the drawing, in the present embodiment, the lubricating oil guide cover 300 </ b> C is formed with an oil groove 500 for guiding the lubricating oil on the surface facing the power roller 11. The oil groove 500 extends toward the traction surface of the power roller 11 (extends from the center of the cover to the vicinity of the side opening of the cover) and is formed toward the outlet side of the traction contact portion.

  By comprising in this way, much traction oil is introduce | transduced by the traction contact part exit vicinity. At the exit of the traction contact portion, the temperature is high immediately after the power transmission work is performed, and therefore, a large amount of lubricating oil is introduced into the outlet so that heat can be efficiently transferred (cooled). Further, since the oil introduced into the outlet reaches the opening on the opposite side, it flows along the surface of the power roller 11 (in the figure, Q indicates the rotational direction of the power roller 11 and C indicates the traction contact portion). ). Therefore, since the lubricating oil is in contact with the traction surface for a long time, further cooling can be performed. Note that the configuration of this embodiment can be applied to all the lubricant guide covers of the first to fourth embodiments described above.

11 and 12 show a sixth embodiment of the present invention. The toroidal-type continuously variable transmission according to the sixth embodiment is a convex that fits with a gap to an annular recess 310 formed on the small end surface (small-diameter side end surface) of the power roller 11 on the lubricant guide cover 300D. Except for the formation of the part 320, it has the same configuration as the toroidal continuously variable transmission of the first embodiment.
The lubricating oil guide cover 300D is provided with a notch at a portion facing the input side disk 2 or the output side disk 3 in the same manner as the lubricating oil guide cover 300 of the first embodiment shown in FIG. That is, as shown in FIG. 12, a notch 321 is formed between the peripheral surface facing portions 300b extending along the traction surface of the power roller 11 from the outer peripheral portion of the circular flat surface portion 300a of the lubricant guide cover 300D. ing.

The notch 321 is provided so that the lubricant guide cover 300D does not come into contact with the input-side disk 2 and the output-side disk 3, and the power roller 11 and the input-side disk 2 or the output at the notch 321 are provided. Torque is transmitted to the side disk 3.
In addition, although the notch part smaller than the said notch part 321 provided between the two peripheral surface opposing parts 300b (between the circumferential direction) is provided in the front-end | tip part of the peripheral surface opposing part 300b, The lubricant guide cover 300D is for preventing the trunnion 15 from coming into contact with the bent wall portion 20, and the portion exposed to the small cutout portion of the power roller 11 is close to the bent wall portion 20. Thus, scattering of the lubricating oil is suppressed.

  Here, by providing the lubricating oil guide cover 300D (300), the scattering of the lubricating oil from the power roller 11 can be largely prevented. However, the traction of the power roller 11 is notch 321 in the lubricating oil guide cover 300D. The surface (peripheral surface 11a) is not covered with the lubricant guide cover 300D, and there is a risk that the lubricant will scatter at portions that are not in contact with or close to the input side disk 2 or the output side disk 3.

  Therefore, in the lubricant guide cover 300D, an annular recess 310 is formed on the small end surface of the power roller 11 in order to prevent scattering of the lubricant oil from the notch 321 and the power roller 11 of the lubricant guide cover 300D is formed. A convex portion 320 that fits the concave portion 310 is provided at a position facing the annular concave portion 310 and corresponding to the notch portion 321 with a gap between the inner surface of the concave portion 310.

As shown in FIG. 1, an annular recess 310 is provided on the small end surface of the power roller 11 in the toroidal type continuously variable transmission according to the first embodiment. In this example, the small end surface of the power roller 11 is provided. The recessed part 310 formed in this is utilized. The annular recess 310 is formed in the small end surface of the power roller 11, is provided closer to the rotation center side than the traction surface (circumferential surface 11 a), and is provided outside the tip end portion 23 b of the displacement shaft 23. Yes.
In addition, the cross-sectional shape of the recess 310 is substantially flat at the center in the width direction. The left and right side edges in the width direction have a shape that becomes shallower (thinner) toward the end.

  The convex portion 320 is provided at a central portion of the lubricant guide cover 300D at a portion facing the small end surface of the power roller 11 of the circular flat surface portion 300a facing the small end surface of the power roller 11. And the convex part 320 is provided in the position which opposes the power roller 11 of the circular plane part 300a, and the position which opposes the said recessed part 310. FIG. Moreover, the convex part 320 is provided in the position corresponding to the center side of the radial direction of the notch part 321 of the lubricant guide cover 300D.

  Further, the notch portion 321 is provided in both the portion facing the input side disk 2 and the portion facing the output side disk 3 of the portion on the radially outer side of the circular plane portion 300a of the lubricant guide cover 300D. ing. Two protrusions 320 are also formed corresponding to the two notches 321. The convex portion 320 has a shape that fits into the annular concave portion 310 on the small end surface of the power roller 11 with a gap, and the cross-sectional shape is substantially the same as the cross-sectional shape of the concave portion 310, and the center in the width direction. The part is plate-shaped and has a shape that becomes thinner as the left and right ends in the width direction go to the end.

  Moreover, the planar shape of the convex part 320 is a strip | belt-shaped and circular arc shape corresponding to the strip | belt shape of the recessed part 310, and an annular | circular shape. That is, the two convex portions 320 have an arcuate planar shape that is a part of a ring centering on the center of the circular planar portion 300a on the extension line of the rotation center of the power roller 11, and the two convex portions. 320 are located at positions separated from each other in the circumferential direction. Further, the two convex portions 320 are arranged so as to be a target with respect to a line segment passing through the center between them and having the diameter of the circular plane portion 300a.

The lubricant guide cover 300D is fixed to the displacement shaft 23 (support shaft) as in the first embodiment.
Then, the protruding portion 320 of the lubricating oil guide cover 300D enters the recessed portion 310 of the small end surface of the power roller 11 in a state where the lubricating oil guide cover 300D is fixed to the support shaft of the power roller 11. However, the inner surface of the concave portion 310 and the outer surface of the convex portion 320 are not in contact with each other, and there is a slight gap between the inner surface of the concave portion 310 and the convex portion 320.

  Accordingly, the convex portion 320 of the lubricating oil guide cover 300D fixed to the rotating power roller 11 does not slide on the power roller 11, but is relatively in the annular concave portion 310 in a non-contact state. The arcuate convex portion 320 is moved in the circumferential direction. That is, the lubricant guide cover 300D and the power roller 11 are not in contact with each other, and a clear gap is provided between them. When the lubricating oil is discharged from the center opening of the small end surface of the power roller 11 in the second oil passage as in the first embodiment, the lubricating oil is subjected to centrifugal force due to the rotation of the power roller 11. Therefore, it goes from the center side of the small end face to the outside in the radial direction.

Of this lubricating oil, the lubricating oil traveling toward the notch 321 of the lubricating oil guide cover 300D along the radial direction of the power roller 11 passes through the recess 310 on the way from the center of the small end surface of the power roller 11 toward the peripheral surface 11a. And the convex portion 320, and thereby the movement of the power roller 11 to the outside in the radial direction is suppressed.
That is, the concave portion 310 having a gap therebetween and the portion where the concave portion 310 and the convex portion 320 are fitted function as a so-called labyrinth seal, and the movement of the lubricating oil to the outside from the concave portion 310 and the convex portion 320 is inhibited. become. In addition, there is a gap continuous in the radial direction between the concave portion 31 and the convex portion 320, and the movement along the radial direction of the lubricating oil is not completely stopped, but the movement is suppressed.

  Accordingly, the lubricating oil moves from the center of the small end surface of the power roller 11 rotating radially outward to reach the peripheral surface 11a, and further, the peripheral surface 11a extends from the small diameter side end surface (small end surface) to the large diameter side end surface. When moving, the lubricating oil heading toward the notch 321 side of the lubricating oil guide cover 300D is restrained from moving by the labyrinth seal composed of the concave portion 310 and the convex portion 320, and the amount of lubricating oil reaching the peripheral surface 11a is reduced. .

  On the other hand, the lubricating oil directed to the circumferential surface facing portion 300b, not the notch portion 321 of the lubricating oil guide cover 300D, passes through between the two convex portions 320 and is directed to the circumferential surface 11a. Without being affected by the portion in which 320 is fitted, the head smoothly moves to the peripheral surface 11a.

As a result, the amount of lubricating oil supplied to the peripheral surface 11a portion of the power roller 11 facing the peripheral surface facing portion 300b of the lubricating oil guide cover 300D is increased, and the peripheral surface facing portions 300b of the lubricating oil guide cover 300D are between each other. The amount of lubricating oil supplied to the portion of the peripheral surface 11 a of the power roller 11 exposed at the notch 321, that is, the portion overlapping the notch 321 is reduced.
Therefore, the amount of lubricating oil supplied to the peripheral surface 11a opened by the notch 321 is smaller than the amount of lubricating oil supplied to the portion covered by the peripheral surface facing portion 300b of the peripheral surface 11a of the power roller 11. Become.

  In addition, the amount of lubricating oil scattered at the notch 321 is greatly reduced, and the lubricating oil can be used efficiently. Even when the lubricating oil amount is the same as that of the first embodiment, the lubricating oil for cooling the power roller 11 or the like. The effect by can be further enhanced. In addition, it is possible to further reduce the amount of lubricating oil to be supplied.

In the lubricating oil guide cover 300D of this example, similarly to the fifth embodiment, the circular flat surface portion 300a (on the portion facing the small end surface of the power roller 11 of the circular flat surface portion 300a of the lubricating oil guide cover 300D). An oil groove 510 is formed along the radial direction of the power roller 11).
In this example, the oil groove 510 is disposed so that both ends thereof are directed to the circumferentially facing portion 300b, and the oil groove 510 passes between the left and right cutout portions 321 and between the left and right convex portions 320. Has been.

Further, the substantially cylindrical locking piece 300d is provided with a notch for passing the lubricating oil in a portion intersecting with the oil groove 510, and is opened at the center of the tip surface of the support shaft (displacement shaft 23). When the lubricating oil discharged from the second oil passage flows out of the locking piece 300d into the oil groove 510, it is easy to flow out.
In addition, the cutout portion 321 of the substantially cylindrical locking piece 300d is formed only at a portion intersecting the oil groove 510, and the cutout portion is formed so as to face the circumferential surface facing portion 300b. And it is not formed in the direction facing the notch 321. Also by this, it can suppress that lubricating oil flows into the notch part 321 side.

Further, the oil groove 510 guides the lubricating oil to the circumferential surface facing portion 300b side, and this also reduces the amount of lubricating oil flowing to the notch portion 321 side and lubrication flowing to the circumferential surface facing portion 300b side. The amount of oil can be increased.
From the above, the scattering of the lubricating oil from the notch 321 of the lubricating oil guide cover 300D can be suppressed, and the power roller 11 can be efficiently cooled.

  In this example, the oil groove 510 is a direction (a direction orthogonal to the input shaft 1) from the center of one peripheral surface facing portion 300b (the center in the rotation direction of the power roller 11) to the center of the other peripheral surface facing portion 300b. However, as in the fifth embodiment, the radially outer side of the oil groove 510 is directed toward the exit side of the traction contact portion with the input side disk 2 or the output side disk 3 of the power roller 11. It is good also as what is arrange | positioned diagonally.

That is, both ends of the oil groove 510 may be arranged not on the center of the circumferential surface facing portion 300b as in this example but on one end (side edge) side in the circumferential direction. At this time, one end portion of the circumferential end portions 300b in the circumferential direction (side edge portion) is opposite to the other end portion in the rotation direction of the power roller 11 (reverse rotation direction side). It becomes.
Note that the concave portion 310 and the convex portion 320 are not only the power roller 11 and the lubricant guide cover 300 of the first embodiment described above, but also the power roller 11 of the second embodiment to the fifth embodiment. Also, the present invention can be applied to the lubricating oil guide covers 300A and 300B, and the same operational effects as this example can be obtained.
In addition, although the concave portion 310 and the convex portion 320 are provided one step at a time in the radial direction, a plurality of steps may be provided at the radial direction. At this time, the plurality of concave portions 310 are formed in a plurality of annular shapes coaxially with the rotation center of the power roller 11 as the center, and the plurality of convex portions 320 are inserted into the respective concave portions 310 in the respective concave portions 310. It is formed in an arc shape so as to be relatively movable in the circumferential direction.

  FIG. 13 shows a seventh embodiment of the present invention. The toroidal continuously variable transmission according to the seventh embodiment is the same as the second embodiment shown in FIGS. 4 and 5 and the third embodiment shown in FIG. 6 except that the configuration of the lubricating oil supply means is different. It has the same composition as. That is, the lubricant guide cover 300 </ b> A is attached to the trunnion 15. As in the second and third embodiments, the tip edges of the pair of bent wall portions 20 and 20 of the trunnion 15 are connected to each other by the lubricant guide cover 300A.

  In this example, the configuration of the lubricating oil supply means is similar to that of the third embodiment, but the position where the lubricating oil is finally discharged is the rotation of the small end face of the power roller 11. Not the vicinity of the center of the lubricating oil guide cover 300A facing the center but the base end portion of the circumferential surface facing portion 300b of the lubricating oil guide cover 300A (the facing surface portion 300aa facing the small end surface of the power roller 11 of the lubricating oil guide cover 300A) , The portion facing the small end surface side of the peripheral surface 11 a of the power roller 11.

  That is, in the lubricating oil supply means in this example, the lubricating oil supplied from the pivot 14 side passes through the lubricating oil supply paths 29a, 400, 407, 408, and the lubricating oil supply paths 29a, 400 , 407, 408, bearing lubricating oil passages 402, 404, 392 are branched. That is, as shown in FIG. 13, the lubricating oil reaches the thrust ball bearing 24 through the path P1 passing through the bearing lubricating oil paths 402, 404, 392, and instead of the path P of the third embodiment, A route P2 passing through the lubricating oil supply passages 29a, 400, 407, and 408 is taken to reach the traction surface of the power roller 11.

Note that the route P1 is the same route as in the third embodiment.
The path P2 is formed from the proximal end side end of the pivot shaft 14 of the lubricating oil supply passage 29a provided on the pivot shaft 14 to the bent wall portion 20 of the trunnion 15 toward the distal end side of the bent wall portion 20. To the lubricating oil supply path 400. Then, the lubricating oil supply passage 407 is provided from the vicinity of the end of the bent wall portion 20 of the lubricating oil supply passage 400 to the lubricating oil supply passage 407 provided substantially across the entire width of the opposing surface portion 300aa of the lubricating oil guide cover 300A. .

  The lubricating oil supply path 407 is connected with a lubricating oil supply path 408 at both ends reaching the vicinity of the two bent wall portions 20. The lubricating oil supply path 408 is formed in the lubricating oil guide cover 300A so as to reach from the end of the facing surface portion 300aa of the facing surface portion 300aa of the lubricating oil guide cover 300A to the end portion of the facing surface portion 300aa of the facing surface portion 300b. Is formed.

And the lubricating oil supply path 408 has an end portion on the side of the circumferential surface facing portion 300b that is open at a portion facing the circumferential surface 11a of the power roller 11 at the end portion on the facing surface portion 300aa side of the circumferential surface facing portion 300b. Then, the lubricating oil is discharged and sprayed from the opening of the lubricating oil supply path 408 to the side edge portion on the small end face side of the power roller 11a.
That is, the lubricating oil supply means of this example has lubricating oil supply paths 29a, 400, 407, and 408 from the trunnion 15 to the lubricating oil guide cover 300A, and the power roller 11 directly from the lubricating oil guide cover 300A. The lubricating oil is supplied by spraying the lubricating oil onto the traction surface (circumferential surface 11a).

As a result, the lubricating oil is directly supplied to the portion of the peripheral surface 11a of the power roller 11 that is covered with the peripheral surface facing portion 300b of the lubricating oil guide cover 300A, so that the lubricating oil is notched in the lubricating oil guide cover 300A. The power roller 11 can be efficiently cooled by suppressing scattering from the H.321.
The opening position of the circumferential surface facing portion 300b of the lubricating oil guide cover 300A in the lubricating oil supply path 408 does not need to be the central portion in the circumferential direction of the circumferential surface facing portion 300b, and is disposed on one side edge side in the circumferential direction. You may be made to do. At this time, one side edge of both side edges in the circumferential direction of the circumferential surface facing portion 300b is opposite to the rotation direction of the power roller 11 with respect to the other side edge. In this case, when the portion exposed to the traction contact with the input-side disk 2 or the output-side disk 3 at the notch 231 of the peripheral surface 11a of the power roller 11 is rotated to the position where it overlaps the peripheral surface facing portion 300b. Lubricating oil will be sprayed, and the power roller 11 can be cooled more efficiently.

  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 the toroidal type continuously variable transmission which concerns on the 1st Embodiment of this invention. It is a principal part perspective view of the toroidal type continuously variable transmission which concerns on the 1st Embodiment of this invention. FIG. 2 is a cross-sectional view illustrating a lubricating oil supply path to a traction surface and a thrust ball bearing in the toroidal continuously variable transmission of FIG. 1. It is a principal part perspective view of the toroidal type continuously variable transmission which concerns on the 2nd Embodiment of this invention. FIG. 5 is a cross-sectional view showing a lubricating oil supply path to a traction surface and a thrust ball bearing in the toroidal type continuously variable transmission of FIG. 4. It is principal part sectional drawing of the toroidal type continuously variable transmission which concerns on the 3rd Embodiment of this invention. It is a principal part perspective view of the toroidal type continuously variable transmission which concerns on the 4th Embodiment of this invention. FIG. 8 is a cross-sectional view showing a lubricating oil supply path to a traction surface and a thrust ball bearing in the toroidal type continuously variable transmission of FIG. 7. It is a perspective view of the lubricating oil guide cover applied to the toroidal type continuously variable transmission which concerns on the 5th Embodiment of this invention. It is a principal part perspective view of the toroidal type continuously variable transmission which concerns on the 5th Embodiment of this invention. It is principal part sectional drawing of the toroidal type continuously variable transmission which concerns on the 6th Embodiment of this invention. It is a perspective view of the lubricant guide cover applied to the toroidal type continuously variable transmission which concerns on the 6th Embodiment of this invention. It is principal part sectional drawing of the toroidal type continuously variable transmission which concerns on the 6th Embodiment of this invention. It is principal part sectional drawing in the conventional toroidal type continuously variable transmission. It is sectional drawing which follows the AA line of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Input shaft 2 Input side disk 3 Output side disk 11 Power roller 14 Pivot 15 Trunnion 16 Support plate part 20 Bending wall part 23 Displacement axis (support axis)
24 Thrust bearing 28 Outer ring 300, 300A, 300B, 300C, 300D Lubricating oil guide cover 302 First oil passage 304 Lubricating oil supply pipe 310 Recessed portion 320 Convex portion 321 Notch portion 390, 392 Bearing lubricating oil passage 400, 407, 408 Lubrication Oil supply channel 500 Oil groove

Claims (12)

An input side disk coupled to an input shaft receiving rotational force and rotating integrally with the input shaft, and a power roller provided between the input side disk, receives the rotational force of the input side disk at a predetermined speed ratio. In a toroidal continuously variable transmission comprising an output-side disk, and power transmission between the power roller and the disk is performed via an oil film,
Lubrication that faces the input shaft and is opposed to the surface of the power roller and extends to guide the lubricating oil to the traction surface of the power roller that transmits power to the disk via an oil film. An oil guide cover,
Lubricating oil supply means for supplying lubricating oil to the vicinity of the center of the lubricating oil guide cover;
A toroidal-type continuously variable transmission.   2. The toroidal continuously variable transmission according to claim 1, wherein the lubricant guide cover is attached to a support shaft that rotatably supports a power roller.   A trunnion that swings about a pivot that is twisted with respect to a central axis of the disk and that supports the power roller is further provided, and the lubricant guide cover is attached to the trunnion. Item 2. The toroidal continuously variable transmission according to item 1.   The trunnion accommodates the power roller by having a pair of bent wall portions formed in a state of being bent toward the inner surface side of the support plate portion at both longitudinal ends of the support plate portion which is the main body portion. A space is formed on the inner side, the pivots are provided concentrically on the outer surface of each bent wall portion, and the tip edges of the pair of bent wall portions are connected by the lubricant guide cover. The toroidal continuously variable transmission according to claim 3.   The lubricating oil supply means includes a lubricating oil supply pipe coupled to the support plate portion of the trunnion, a first oil passage formed in the support plate portion and communicating with the lubricating oil supply pipe, and the power roller And a second oil passage that is formed on a support shaft that rotatably supports the first oil passage and communicates with the first oil passage and opens near the center of the lubricating oil guide cover. The toroidal-type continuously variable transmission of any one of Claim 4.   The bearing further includes a bearing provided between the power roller and the trunnion and supporting a load in a thrust direction applied to the power roller, and the lubricating oil supply means supplies the lubricating oil to the bearing. The toroidal continuously variable transmission according to any one of claims 1 to 5, further comprising a road.   A bearing provided between the power roller and the trunnion and supporting a thrust load applied to the power roller is further provided, and a bearing lubricating oil passage for supplying lubricating oil to the bearing is the second oil. 6. The toroidal continuously variable transmission according to claim 5, wherein the toroidal continuously variable transmission is branched from the road.   The lubricating oil supply means has a lubricating oil supply passage extending from the pivot shaft of the trunnion to the vicinity of the center of the lubricating oil guide cover, and the bearing lubricating oil passage is branched from the lubricating oil supply passage. The toroidal type continuously variable transmission according to claim 6.   2. The toroidal continuously variable transmission according to claim 1, wherein an oil groove for guiding the lubricating oil is formed on a surface of the lubricating oil guide cover facing the power roller.   The toroidal continuously variable transmission according to claim 9, wherein the oil groove extends toward a traction surface of the power roller. An annular recess centered on the rotation center of the power roller is formed on the end surface on the small diameter side of the power roller,
The lubricant guide cover has a notch formed in a portion facing the input side disk or the output side disk,
In addition, a convex portion that fits the concave portion is provided at a position facing the annular concave portion of the power roller of the lubricating oil guide cover and corresponding to the notch portion with a gap between the inner surface of the concave portion. The toroidal continuously variable transmission according to any one of claims 1 to 10, wherein the toroidal continuously variable transmission is provided. An input side disk coupled to an input shaft receiving rotational force and rotating integrally with the input shaft, and a power roller provided between the input side disk, receives the rotational force of the input side disk at a predetermined speed ratio. An output-side disk and a trunnion that swings about a pivot that is twisted with respect to the center axis of the disk and supports the power roller, and the power transmission between the power roller and the disk is an oil film. In the toroidal type continuously variable transmission performed via
Lubricating oil is applied to the traction surface of the power roller that faces the input shaft and is opposed to the surface of the power roller, is mounted on the trunnion, and transmits power to the disk via an oil film. A lubricating oil guide cover extending to guide,
Lubricating oil supply means that has a lubricating oil supply path from the trunnion to the lubricating oil guide cover, and sprays lubricating oil directly onto the traction surface of the power roller from the lubricating oil guide cover;
A toroidal-type continuously variable transmission.

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