JP2008144857A - Post positioning device and positioning method for troidal continuously variable transmission - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a post positioning device and positioning method capable of positioning a first post and a second post for retaining a power roller in an assembling process of a troidal continuously variable transmission. <P>SOLUTION: The post positioning device for the troidal continuously variable transmission has the first post 24 and the second post 31A for supporting the power roller contacted with an input disk and an output disk 5, and performs relative positioning of the first post 24 and the second post 31A. The device has a tool 211 movable around an axis X1 of the input disk and the output disk 5, and has a constitution for performing relative positioning by making the tool 211 contact with the first post 24 and the second post 31A. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  According to the present invention, a rotary member such as a power roller whose outer peripheral surface is a curved surface corresponding to the toroidal surface is sandwiched between an input disc having a toroidal surface and an output disc, and the traction oil formed between these three members. A post positioning device for positioning a first post and a second post that hold the power roller in a process of assembling a toroidal type (traction type) continuously variable transmission that transmits torque using the shear force of an oil film; The present invention relates to a post positioning method.

  Generally, a toroidal-type continuously variable transmission includes a power roller having a circumferential surface imitating the toroidal surface between an input disk and an output disk whose opposing surfaces are toroidal surfaces. The oil film of the traction oil is formed between the two and the glass is increased to increase the pressure applied to the oil film, and the torque is transmitted between the input disk and the output disk using the accompanying shear force. Has been. The power roller is rotatably supported by a support arm called a trunnion. Further, a holding member is provided that holds the trunnion so as to be movable in a plane direction orthogonal to the first axis of the input disk and that can rotate about the second axis in the plane. . When the trunnion moves in the axial direction, a side slip force (tilting force) is induced at the contact point between the power roller and the toroidal surface, and the tilt angle of the power roller changes, and each power roller with respect to the toroidal surface changes. The contact radius of the contact point changes. In this way, the gear ratio of the toroidal continuously variable transmission changes.

  Patent Document 1 describes a specific configuration of a trunnion and a holding member in such a toroidal continuously variable transmission, and an assembly process of the toroidal continuously variable transmission. The toroidal continuously variable transmission described in Patent Document 1 is a so-called double-cavity toroidal continuously variable transmission that is configured by arranging two sets of toroidal transmission units composed of a pair of input and output disks in series on the same axis. It is a transmission. More specifically, it has a first toroidal transmission unit and a second toroidal transmission unit, and the two toroidal transmission units have the same configuration. Explaining the configuration of each toroidal transmission unit, there are provided a pair of input / output disks that can rotate around a horizontal axis, and a pair of power rollers that are clamped by the pair of input / output disks. The pair of power rollers are rotatably supported by a pair of trunnions via a pivot shaft. In addition, an upper link and a lower link that are swingable in a plane orthogonal to the rotation axis of the input / output disk are provided, and needle bearings attached to the upper and lower shafts of the pair of trunnions are provided with upper links. Are attached to the through hole of the lower link and the through hole of the lower link.

  On the other hand, the two toroidal transmission units are disposed in the casing, and a positioning member fixed by a bolt is provided on the inner peripheral upper surface of the casing. The casing and the positioning member are positioned by a knock pin. The positioning member is provided with a pin, and the upper link is swingably attached to the pin. Further, a cylinder body and a cylinder body bottom are attached to the lower part of the casing, and a link support member is fixed to the cylinder body bottom by bolts and nuts. The link support member is provided with a pin, and the lower link is swingably supported by the pin. The cylinder body bottom and the link support member are positioned by a knock pin.

  When the assembly of the toroidal continuously variable transmission configured as described above is completed, the upper link is held at a predetermined position in the X, Y, and Z axial directions by the link support member fastened to the positioning member. On the other hand, the lower link is positioned at an arbitrary position only in the X-axis direction by a link support member fastened to the cylinder. Here, the X axis is a horizontal direction and is an axis in a direction perpendicular to the axis line of the input / output disk, and the Y axis is a horizontal direction and an axis in a direction parallel to the axis line of the input / output disk. , Z axis is a vertical axis.

  In the correction process for correcting the positional deviation of the power roller, the link support member can be displaced in the X-axis direction by loosening the nut that has fixed the link support member. On the other hand, the displacement of the input / output disk in the rotational axis direction is restricted, and the lower link can be displaced in the longitudinal direction (X-axis direction) together with the link support member. When the continuously variable transmission is operated in this state and the input / output disk and the power roller are rotated, the link support member is displaced in the X-axis direction, and the lower link is displaced only along the longitudinal direction. The error of the machining accuracy and the assembly accuracy is absorbed, and the position deviation of the power roller is corrected. As the lower link is displaced in the X-axis direction, the trunnion is also displaced in the axial direction. Thereafter, the nut is tightened in the operating state of the continuously variable transmission. In this way, it is possible to maintain a state in which the thrust force applied to the power roller is equal. A technique relating to positioning or fixing of parts constituting the toroidal-type continuously variable transmission is also described in Patent Document 2.

JP 11-1181010 A JP-A-10-299851

  However, in the positioning device and positioning method for the link support member described in Patent Document 1, the nut that fixes the lower link is loosened and the continuously variable transmission is operated to correct the position of the power roller, Thereafter, a process of tightening the nut is necessary, and there is a problem that the number of assembling steps for the parts constituting the continuously variable transmission increases. Accordingly, a jig that contacts the two link support members is prepared, and in the stage before tightening the nut, that is, in the stage where the two link support members are temporarily fixed to the cylinder body and the positioning member, It is also conceivable to tighten the nut after relatively positioning the link support members. However, when positioning using a jig, if the processing accuracy of the two link support members and their attachment locations is poor, the jig and the two link support members may be deformed in the process of tightening the nut, There is a possibility that inconvenience that the jig is difficult to come off occurs.

  The present invention has been made paying attention to the technical problem described above, and the two posts are independent of the processing accuracy of the two posts supporting the power roller or the processing accuracy of the fixing member to which the two posts are attached. Provided is a post positioning device and a positioning method for a toroidal-type continuously variable transmission capable of positioning materials reliably, more specifically, without deforming two posts or fixing members or jigs. It is for the purpose.

  To achieve the above object, the invention according to claim 1 provides a first power roller that supports the power roller in contact with the input disk and the output disk, and is disposed at a position sandwiching the axis of the input disk and the output disk. A post and a second post, the first post being temporarily fixed to the first fixing member, and the second post being temporarily fixed to the second fixing member, perpendicular to the axis In a post positioning device for a toroidal-type continuously variable transmission that performs relative positioning between the first post and the second post in a plane to be operated, a treatment that can operate around the axis in the plane. The jig includes a first contact portion disposed on a line segment passing through the axis line in the plane, and disposed on both sides of the axis line in the plane. 2 contact parts are provided The first post is provided with a first mating portion that comes into contact with the first contact portion, and the second post comes into contact with the second contact portion. The jig is configured such that the first contact portion and the first post are in contact with each other, and the second contact portion and the second post are in contact with each other. The first post and the second post are positioned relative to each other.

  According to a second aspect of the present invention, in addition to the configuration of the first aspect, the first mating portion has a gap amount substantially equal to the first contact portion when the jig is operated around the axis. The second mating part is maintained in the same manner, and when the jig operates around the axis, the gap amount with the first contact part is maintained substantially the same. It is what.

  According to a third aspect of the present invention, in addition to the configuration of the second aspect, the shape of the first contact portion or the shape of the first mating portion in the plane is configured to be substantially circular, and the first in the plane is the first shape. The shape of the second contact portion or the shape of the second counterpart portion is formed in a substantially circular shape.

  According to a fourth aspect of the present invention, there are provided a first post and a second post that support a power roller that contacts the input disk and the output disk, and that are disposed at positions sandwiching the axis of the input disk and the output disk. A plane orthogonal to the axis of the input disk and the output disk in a state where the first post is temporarily fixed to the first fixing member and the second post is temporarily fixed to the second fixing member. The first post and the second post are relatively positioned, and then the first post and the first fixing member are fixed, and the second post and the second post are fixed. In a post positioning method for a toroidal-type continuously variable transmission that fixes two fixing members, a jig operable around the axis in the plane is prepared, and the first post is fixed to the first fixed member. In a state where the second post is temporarily fixed to the member and the second post is temporarily fixed to the second fixing member, the jig is brought into contact with the first post and the second post, so that the axis is After the relative positioning of the first post and the second post within an orthogonal plane, the first post and the first fixing member are fixed, and the second post And the second fixing member are fixed.

  According to the first aspect of the present invention, the first post that supports the power roller is temporarily fixed to the first fixing member, and the second post that supports the power roller is temporarily fixed to the second fixing member. To do. Next, the first contact portion and the first post are in contact with each other, and the second contact portion and the second post are in contact with each other, so that the first post is within a plane orthogonal to the axis. And relative positioning of the second post. Thereafter, in the step of fixing the first post and the first fixing member and fixing the second post and the second fixing member, the first contact portion and the first post are in contact with each other. In addition, the jig can operate around the axis in the plane while the second contact portion and the second post are in contact with each other. Therefore, the first post, the second post, or the first fixing, regardless of the processing accuracy of any one element of the first post, the second post, the first fixing member, or the second fixing member. The first post and the second post can be reliably positioned without any one element of the member, the second fixing member, or the jig being deformed or the jig being difficult to come off.

  According to the invention of claim 2, in addition to obtaining the same effect as that of the invention of claim 1, the first mating part and the first contact part are in contact with each other, and the second mating part and When the two contact portions come into contact with each other, the first post and the second post are relatively positioned. Then, in the step of fixing the first post and the second post, when an external force is applied to the first post and the second post, the jig can operate around the axis. . For this reason, the gap amount between the first contact portion and the first counterpart portion is maintained substantially the same, and the gap amount between the second contact portion and the second counterpart portion is maintained substantially the same. The Therefore, any one of the first post, the second post, the first fixing member, the second fixing member, or the jig is deformed or the jig is difficult to be removed. It can be reliably suppressed.

  According to the invention of claim 3, in addition to obtaining the same effect as that of the invention of claim 2, the first contact portion and the first mating portion are in point contact, and the second contact portion and the second contact portion The first post and the second post are positioned by the point contact with the counterpart. Further, when the jig operates around the axis, the contact portion between the first contact portion and the first mating portion slides, and the contact portion between the second contact portion and the second mating portion slides. Move.

  According to the invention of claim 4, the first post supporting the power roller is temporarily fixed to the first fixing member, and the second post supporting the power roller is temporarily fixed to the second fixing member. To do. Next, the first contact portion and the first post are in contact with each other, and the second contact portion and the second post are in contact with each other, so that the first post is within a plane orthogonal to the axis. And relative positioning of the second post. Thereafter, in the step of fixing the first post and the first fixing member and fixing the second post and the second fixing member, the first contact portion and the first post are in contact with each other. In addition, the jig can operate around the axis in the plane while the second contact portion and the second post are in contact with each other. Therefore, the first post, the second post, or the first fixing, regardless of the processing accuracy of any one element of the first post, the second post, the first fixing member, or the second fixing member. The first post and the second post can be reliably positioned without any one element of the member, the second fixing member, or the jig being deformed or the jig being difficult to come off.

  Next, the present invention will be described based on specific examples. First, a schematic configuration when the toroidal continuously variable transmission according to the present invention is used in a vehicle will be described with reference to FIGS. 2 and 4. FIG. 2 is a schematic side sectional view showing the configuration of the toroidal continuously variable transmission, and FIG. 4 is a perspective view showing the relationship between the axis and the plane in this embodiment in a three-dimensional manner. In FIG. 4, the first plane G1 and the second plane G2 are indicated by substantially square imaginary lines, but the first plane G1 and the second plane G2 do not physically exist. For convenience, it is merely represented by a substantially square. First, in FIG. 2, the input shaft 1 and the output shaft 2 are disposed so as to be rotatable about the axis X1, and the axis X1 is disposed substantially horizontally. That is, FIG. 2 is a longitudinal sectional view in the direction along the axis X1. The input shaft 1 is connected to a power source (not shown) so that power can be transmitted, and the output shaft 2 is connected to wheels (not shown) so that power can be transmitted. The output shaft 2 is formed in a cylindrical shape, and the input shaft 1 is inserted into a shaft hole 212 formed in the axial direction of the output shaft 2 so as to be relatively rotatable. A toroidal-type continuously variable transmission 100 that controls the gear ratio between the input shaft 1 and the output shaft 2 is provided. The power source may be a single power source or a plurality of power sources having different power generation principles. Examples of the power source include an internal combustion engine, an electric motor, a hydraulic motor, and a flywheel system.

  The toroidal continuously variable transmission 100 includes an input disk 4 and an output disk 5, and the input disk 4 is connected to rotate integrally with the input shaft 1, and the output disk 5 rotates integrally with the output shaft 2. It is connected to. The input disk 4 is formed with a toroidal surface 6 centered on the axis X1, and the output disk 5 is formed with a toroidal surface 7 centered on the axis X1. An annular cavity T <b> 1 is formed between the toroidal surface 6 and the toroidal surface 7. Here, the example shown in FIG. 2 is a so-called double cavity type in which a plurality of transmission parts 3 having a cavity T1 formed by an input disk 4 and an output disk 5 are formed on the same axis, specifically, two places. Toroidal-type continuously variable transmission 100. The toroidal surfaces 7 of the output disk 5 are arranged in opposite directions. Further, a plurality of, for example, two power rollers 8 are provided that come into contact with the toroidal surfaces 6 and 7 of each transmission unit 3 with a lubricating oil film (traction oil) interposed therebetween. Each power roller 8 has an outer peripheral surface shape following the toroidal surfaces 6 and 7. The two sets of transmission units 3 are both provided in the casing 9.

  Moreover, the lower part of the casing 9 is opened, and the cylinder body 10 and the lower cover 11 are overlapped and attached so as to close the opening part of the casing 9. Specifically, the cylinder body 10 is disposed between the casing 9 and the lower cover 11 in the vertical direction of FIG. A plurality of bearings (radial bearings) 62 that rotatably support the input shaft 1 are provided, and these bearings 62 are attached to the shaft holes 63 of the casing 9. In this way, the input shaft 1 is positioned with respect to the casing 9 in a direction along the first plane G1 orthogonal to the axis X1. When the toroidal continuously variable transmission 100 is mounted on a vehicle, the first plane G1 is a plane along a substantially vertical direction (substantially vertical direction).

  On the other hand, the two output disks 5 are arranged between the input disks 4 in the direction along the axis X 1 and are spline-fitted to the hollow output shaft 2. A drive gear 64 is formed on the output shaft 2 and a driven shaft 66 having a driven gear 65 is provided. A driven gear 65 and a drive gear 64 are engaged with each other, and a driven shaft 66 is rotatably supported by a plurality of bearings 67. The output shaft 2 is also supported by two bearings 68. An intermediate wall 69 is fixed inside the casing 9. The intermediate wall 69 has component pieces 70 and 71 divided into two in the direction along the axis X 1, and one of the bearings 67 and two bearings 68 are held by the intermediate wall 69. The other bearing 67 is held by the casing 9. In this way, the output shaft 2 and the driven shaft 66 are positioned with respect to the casing 9 in the direction along the first plane G1.

  Hereinafter, the structure of the transmission part 3 is demonstrated based on FIG. FIG. 3 is a longitudinal sectional view taken along a first plane G1 orthogonal to the axis X1, and here, for convenience, the configuration facing the cavity T1 shown on the left side in FIG. 2 is shown in FIG. In addition, the structure which faces the cavity T1 shown on the right side in FIG. 2 is configured symmetrically. Inside the casing 9, two trunnions 12 for supporting the two power rollers 8 separately are provided. The structures of the two trunnions 12 and the power roller 8 and the like are substantially symmetrical with respect to a plane including the axis X1 (a plane in the vertical direction in FIG. 3). Note that the trunnion 12 arranged on the left side in FIG. 3 is sometimes referred to as trunnion 12A for convenience, and of the two trunnions 12, the trunnion 12 arranged on the right side in FIG. 3 is sometimes referred to as trunnion 12B for convenience. Each trunnion 12 is formed with a support shaft 13 at a lower portion in the vehicle height direction, and each trunnion 12 is formed integrally with a support shaft 14 at an upper portion in the vehicle height direction. Has been. The support shafts 13 and 14 are coaxially arranged, and an annular piston 15 is attached to each support shaft 13. Each piston 15 is formed with an annular pressure receiving portion 16.

  Further, the support shafts 13 and 14 of each trunnion 12 are configured to be rotatable about an axis A1 arranged in the vertical direction. Each trunnion 12 is provided with an upper projecting portion 17 and a lower projecting portion 18 at different positions in the direction of the axis A1. The upper projecting portion 17 and the lower projecting portion 18 protrude so as to face each other in a direction orthogonal to the axis A1. Further, the upper overhanging portion 17 is disposed above the lower overhanging portion 18 in the height direction of the vehicle. A lower washer 19 is attached to the outer periphery of each support shaft 13 between the lower projecting portion 18 and the piston 15. A plate 20 is attached to the outer periphery of each support shaft 13 between the piston 15 and the lower washer 19. Further, needle bearings 21 are attached to the outer periphery of each support shaft 13 between the lower washer 19 and the lower projecting portion 18.

  In the cylinder body 10, a lower post 24 is attached at a position facing the inside of the casing 9. The lower post 24 is fastened and fixed using bolts 60 and nuts 61, and a support shaft 23 is provided on the lower post 24. Further, a single (single) lower link 22 is provided inside the casing 9, and the lower link 22 is rotatably supported by a support shaft 23. The support shaft 23 extends in a direction parallel to the axis X1. In addition, a support shaft 23 is provided between the two trunnions 12 in the first plane direction orthogonal to the axis X1. Further, the support shaft 23 is disposed below the axis X1 in the first planar direction. In this way, the lower link 22 is configured to be able to swing like a seesaw in the first plane G1 orthogonal to the axis X1. That is, as shown in FIG. 4, one lower post 24 is provided between the two shaft holes 26 supporting the two trunnions 12 corresponding to one cavity T1 in the direction along the second plane G2. Has been placed. The lower post 24 is also provided corresponding to each of the two cavities T1. The lower post 24 is fixed to the cylinder body 10 by tightening the screw member 60, and the contact surfaces of the lower post 24 and the cylinder body 10 are configured to be substantially flat. Further, elastic members 25 are interposed between the lower post 24 and the lower link 22 on both sides of the support shaft 23. The elastic member 25 is a mechanism that applies an upward force to the lower link 22. As the elastic member 25, for example, a compression coil spring can be used.

  Further, a shaft hole 26 penetrating the lower link 22 in the height direction is formed, and the needle bearing 21 is disposed in the shaft hole 26. Each needle bearing 21 is configured to be movable along the axis A <b> 1 with respect to the lower link 22. The lower link 22 is shared by the two sets of transmission units 3, and shaft holes 26 are provided at substantially four corners of the lower link 22. In the second plane G2, the distance from the center of the two shaft holes 26 corresponding to one cavity T1 to the axis of the support shaft 23 is the same. And the needle bearing 21 is attached to the four trunnions 12 provided in two sets of the transmission parts 3, and these needle bearings 21 become the structure arrange | positioned at each shaft hole 26. As shown in FIG. The needle bearing 21 has a large number of rolling elements (needles) 21A that come into contact with the support shaft 13, and an annular outer ring 21B that holds these rolling elements 21A. Further, between the cylinder body 10 and the lower cover 11, hydraulic chambers 27 and 28 corresponding to the piston 15 of one trunnion 12A are provided. The hydraulic pressure in the hydraulic chambers 27 and 28 is configured to act on the pressure receiving portion 16 of the piston 15. Further, between the cylinder body 10 and the lower cover 11, hydraulic chambers 29 and 30 corresponding to the piston 15 of the other trunnion 12B are provided. The hydraulic pressure in the hydraulic chambers 29 and 30 is configured to act on the pressure receiving portion 16 of the piston 15.

  On the other hand, the upper post 31 </ b> A is positioned and fixed to the top plate 31 constituting the upper part of the casing 9. The contact surfaces of the upper post 31A and the top plate 31 are both flat. A support shaft 33 is provided on the upper post 31A. The support shaft 33 is disposed between the trunnion 12A and the trunnion 12B in the first planar direction, and the support shaft 33 extends in a direction parallel to the axis X1. A single (single) upper link 34 that swings (rotates) in the form of a seesaw in the first plane around the support shaft 33 is provided. The upper posts 31A are also provided corresponding to the two cavities T1, respectively. The upper link 34 is disposed above the upper projecting portion 17. The upper link 34 is provided with shaft holes 35 penetrating in the vertical direction on both sides of the support shaft 33. The distance from the center of the two shaft holes 35 corresponding to one cavity T1 to the support shaft 33 is the same in the second plane G2.

  A needle bearing 36 is attached to the outer periphery of each support shaft 14, and the needle bearing 36 is disposed in the shaft hole 35. The needle bearing 36 is configured to be movable with respect to the upper link 34 in the direction of the axis A1. As shown in FIG. 4, the upper link 34 has a substantially quadrangular shape in the second plane and is configured in a frame shape. The upper link 34 is shared by the two sets of transmission units 3, and shaft holes 35 are provided at substantially four corners of the upper link 34. Then, needle bearings 36 are respectively attached to the four trunnions 12 provided in the two sets of transmission units 3, and all the needle bearings 36 are arranged in the respective shaft holes 35. Yes. The needle bearing 36 is arranged outside the multiple needles 36A in the radial direction of the support shaft 14 so as to hold the multiple rolling elements (needles) 36A contacting the periphery of the support shaft 14 and the multiple needles 36A. And an outer ring 36B.

  An annular plate 37 is attached to the support shaft 14 above the needle bearing 36, and a snap ring 50 is attached to the support shaft 14 above the plate 37. . In this way, the trunnion 12 and the needle bearing 36 are positioned in the direction of the axis A1. That is, the trunnion 12 and the needle bearing 36 can operate integrally in the axial direction. As described above, the upper link 34 and the trunnion 12 are connected with the needle bearing 36 interposed therebetween, and when the trunnion 12 moves along the axis A1, the upper link 34 swings around the support shaft 33 as a fulcrum. Then, the trunnion 12 and the upper link 34 relatively rotate within the second plane G2 shown in FIG. The second plane G2 is a plane orthogonal to the axis A1, and is specifically a horizontal plane.

  Further, elastic members 41 are interposed between the top plate 31 and the upper link 34 and on both sides of the support shaft 33. The elastic member 41 is a mechanism that applies a downward force to the upper link 34. As the elastic member 41, for example, a compression coil spring can be used. The two power rollers 8 are provided between the upper projecting portion 17 and the lower projecting portion 18 of each trunnion 12. Each trunnion 12 has a side wall 141 connecting the upper projecting portion 17 and the lower projecting portion 18, and the outer ring 42 is rotatably held by each side wall 141. More specifically, the outer ring 42 has shaft portions 43 and 44 that are eccentric to each other, and the shaft portion 43 is rotatably supported by the side wall 141 with a radial bearing 45 interposed therebetween. Further, the power roller 8 is rotatably supported by the shaft portion 44 with a radial bearing 46 interposed therebetween. Further, a thrust bearing 47 is provided between the power roller 8 and the outer ring 42. The shaft portion 43 supported by the radial bearing 45 can rotate about the axis C1, and the power roller 8 supported by the radial bearing 46 can rotate about the axis D1. That is, the shaft portion 44 revolves around the shaft portion 43, and the power roller 8 can revolve and rotate around the shaft portion 44.

  The axes C1 and D1 are arranged in parallel with the first plane G1. Then, the shape of the toroidal surfaces 6, 7, the first surface G 1, and the first surface G 1 are set such that the contact point between the toroidal surfaces 6, 7 and the power roller 8 deviates from the axis A 1. Conditions such as the position of the axis A1 in the plane G1 and the shape of the power roller 8 are set. That is, the toroidal continuously variable transmission 100 is a so-called half-toroidal continuously variable transmission. In addition, an actuator (not shown) that provides a force in a direction in which the input disk 4 and the output disk 5 are brought close to each other in the direction along the axis X1 is provided. Furthermore, a hydraulic control device (not shown) for controlling the hydraulic pressure of the hydraulic chambers 27, 28, 29, 30 is provided. Further, the upper projecting portion 17 and the lower projecting portion 18 are connected by a connecting member 48. By this connecting member 48, each trunnion 12 is improved in strength against a load in the direction along the axis A1.

  In the toroidal type continuously variable transmission 100 configured as described above, an oil film of traction oil is formed between the power roller 8 and each of the toroidal surfaces 6 and 7, and the pressure applied to the oil film is increased to cause glass transition. Torque is transmitted between the input shaft 1 and the output shaft 2 by utilizing the accompanying shearing force. Next, the shift control of the transmission unit 3 will be described by taking as an example the case where the input disk 4 shown in FIG. 2 rotates clockwise in FIG. Based on the relationship between the hydraulic pressure in the hydraulic chamber 27 and the hydraulic pressure in the hydraulic chamber 28, the position of the piston 15 of the trunnion 12A in the direction of the axis A1 is controlled, and the hydraulic pressure in the hydraulic chamber 29 and the hydraulic pressure in the hydraulic chamber 30 are Based on the relationship, the position of the piston 15 of the trunnion 12B in the direction of the axis A1 is controlled. Specifically, in conjunction with the operation of each piston 15, each trunnion 12 integrally operates in the direction of the axis A1, and the axis D1 is offset (non-crossed) with respect to the axis X1. Then, a side slip force (tilting force) is induced at the contact point between the power roller 8 and the toroidal surfaces 6 and 7, and the tilt angle of the power roller 8 changes, and the contact of each power roller 8 with the toroidal surface 6. The contact radius of the point and the contact radius of the contact point of each power roller 8 with respect to the toroidal surface 7 change. In this way, the gear ratio between the input shaft 1 and the output shaft 2 changes. When the tilt angle of the power roller 8 is changed and a desired speed ratio is achieved, the trunnion 12 is operated in the direction of the axis A1 and the axis D1 and the axis X1 intersect (neutral position). And the gear ratio is maintained.

  On the other hand, a force in a direction to bring the input disk 4 and the output disk 5 close to each other is applied by the actuator to generate a clamping force with respect to the power roller 8 and control the torque capacity. As described above, in the half-toroidal-type continuously variable transmission, the toroidal surfaces 6 and 7 are set so as to open outward in the radial direction of the input disk 4 and the output disk 5. Depending on the clamping force applied to the roller 8, a component force is generated in a direction to push outward from the gap between the input disk 4 and the output disk 5 in the radial direction. When such a component force is generated in the power roller 8, a load corresponding to the component force is transmitted to the trunnion 12 via the outer ring 42. Here, in each transmission unit 3, the directions of the loads transmitted from the two power rollers 8 to the lower link 22 and the upper link 34 are opposite to each other, so that the two loads are substantially canceled out.

  Next, in the toroidal-type continuously variable transmission 100 of the half toroidal type as shown in FIG. 3, the toroidal surface is generated so as to generate a force that pushes the power roller 8 out of the cavity T1 in the second plane direction. 6 and 7, the shape of the outer peripheral surface of the power roller 8, the position of the axis A1 of each trunnion 12, and the like are set. Each trunnion in the second plane direction is such that the center of curvature (not shown) of the toroidal surfaces 6 and 7 and the intersection of the axis A1 and the second plane G2 coincide with each other in the second plane direction. 12 is positioned. By positioning the trunnion 12, the radius from the axis A1 to the contact point of the power roller 8 with respect to the toroidal surfaces 6 and 7 is always the same radius regardless of the tilt angle of the power roller 8. A structure for positioning the trunnion 12 will be described. As described above, the input disk 4 and the output disk 5 are positioned on the casing 9 by the bearing 62 in the second plane direction. Each trunnion 12 is positioned by the upper link 34 and the lower link 22 in the second plane direction. The upper link 34 is positioned and fixed to the casing 9 via the upper post 31A. On the other hand, the lower link 22 is positioned and fixed to the cylinder body 10 via the lower post 24.

  On the other hand, the casing 9 and the cylinder body 10 are separately configured parts, and the casing 9 and the cylinder body 10 are positioned and fixed in the assembly process of the toroidal type continuously variable transmission 100. For example, as shown in FIG. 3, the casing 9 is provided with a plurality of recesses 9B facing the end surface 9A, and the cylinder body 10 is provided with a plurality of recesses 10B facing the end surface 10A, and the recess 9B. The casing 9 and the cylinder body 10 are positioned in the second plane direction by positioning pins (knock pins) 72 inserted into both the recess 10B. The casing 9, the cylinder body 10 and the lower cover 11 are fixed by fastening a plurality of bolts 73. Further, the upper post 31 </ b> A is positioned and fixed to the casing 9, and the lower post 24 is positioned and fixed to the cylinder body 10. Further, the upper post 31A and the lower post 24 are relatively positioned. Hereinafter, in the assembly process of the toroidal-type continuously variable transmission 100, configuration examples of an apparatus and a positioning method for performing these positioning will be sequentially described.

(Configuration example 1)
First, the structural example 1 is demonstrated based on FIG. 1 and FIG. FIG. 1 is a longitudinal sectional view in the first plane G1, and FIG. 5 is a longitudinal sectional view in a direction along the axis X1. 1 and 5 are shown upside down from FIG. 3 for convenience. First, the lower post 24 is provided with a recess 200, and the cylinder body 10 is provided with a recess 201. And the positioning pin (knock pin) 202 arrange | positioned over both the recessed parts 200 and 201 is provided. Further, the lower post 24 is provided with a hole 208. In the example of FIGS. 1 and 5, the planar shape of the hole 208 is circular, and the center line (not shown) of the hole 208 is disposed along the vertical direction. Further, the swing center of the lower link 22 is disposed on the center line of the hole 208 in a plane orthogonal to the axis X1.

  On the other hand, the upper post 31A is attached to the inner surface of the top plate 31, and the top plate 31 is provided with a shaft hole 204. The upper post 31 </ b> A is provided with a female thread portion 206, and a bolt 207 inserted into the shaft hole 204 is tightened to position and fix the upper post 31 </ b> A to the casing 9. Further, the upper post 31 is provided with a hole 209. In the example of FIGS. 1 and 5, the planar shape of the hole 209 is circular, and the center line (not shown) of the hole 209 is disposed along the vertical direction. Further, the swing center of the upper link 34 is arranged on the center line of the hole 209 in a plane orthogonal to the axis X1. The inner diameters of the holes 208 and 209 are the same. In the example shown in FIG. 5, the inner diameter of the shaft hole 5 </ b> A of the output disk 5 is configured to be larger than the inner diameter of the shaft hole 212 of the output shaft 2. That is, when the output disk 5 and the output shaft 2 shown in FIG. 5 are used, the inner periphery of the output disk 5 and the input shaft 1 of the input shaft 1 in the state where the toroidal continuously variable transmission 100 is assembled as shown in FIG. A radial bearing (not shown) can be arranged between the outer periphery.

  Next, a configuration of a “positioning device” for relatively positioning the upper post 31A and the lower post 24 in the first plane G1 will be described. This positioning device has a shaft member 210 that is a first jig and an arm 211 that is a second jig. First, the outer peripheral shape of the shaft member 210 is circular in the first plane G1. That is, the shaft member 210 is configured by a column or a cylinder. Further, the outer diameter of the shaft member 210 is slightly smaller than the inner diameter of the shaft hole 212 of the output shaft 2, and the shaft member 210 can be inserted into the shaft hole 212. The fitting relationship between the shaft member 210 and the output shaft 2 is a clearance. As described above, the shaft member 210 has a configuration in which the shaft member 210 is arranged around the axis line X1 when inserted into the shaft hole 212 of the output shaft 2.

  Next, the configuration of the arm 211 will be described. The arm 211 has a cylindrical portion 213 fitted to the outer periphery of the shaft member 210. That is, the arm 211 can rotate relative to the shaft member 210 about the axis X1. Further, on the outer periphery of the cylindrical portion 213, two shaft portions 214 that are extended (projected) in the radial direction about the axis X1 are provided. The two shaft portions 214 are provided at positions different by 180 degrees on the outer periphery of the cylindrical portion 213. That is, the two shaft portions 214 are provided radially, and the two shaft portions 214 are arranged along a line segment (straight line) F1 passing through the axis line X1 in the first plane G1. Yes. A spherical portion 216 is provided at the free ends of the two shaft portions 214. Further, within a plane orthogonal to the axis X1, a linear distance from the axis X1 to the center (not shown) of one sphere 216 and the center of the other sphere 216 from the axis X1 (not shown). The linear distance up to is configured to be the same. That is, in the first plane G1, the two spheres 216 are arranged at point-symmetric positions with the axis X1 as the center. Further, the outer diameters of the two ball portions 216 are the same. One shaft member 210 is provided, and two arms 211 are provided. One arm 211 is used when positioning a pair of upper post 31 and lower post 24 corresponding to each cavity T1.

  Next, a method of performing relative positioning of the upper post 31A and the lower post 24 in the first plane G1 using the shaft member 210 and the arm 211 will be described. First, the upper post 31A is brought into contact with the inner surface of the top plate 31 of the casing 9, the bolt 207 is slightly tightened, and the upper post 31A is temporarily fixed to the casing 9. In this temporarily fixed state, the upper post 31A can be moved relative to the casing 9 in the left-right direction in FIG. 1 within the range of the clearance between the shaft portion of the bolt 207 and the inner surface of the shaft hole 204. . On the other hand, the lower post 24 is brought into contact with the inner surface of the cylinder body 10, the bolt 60 is slightly tightened, and the lower post 24 is temporarily fixed to the cylinder body 10. In this temporarily fixed state, either the range of the clearance between the shaft portion of the bolt 60 and the inner surface of the shaft hole 203 or the range of the clearance between the positioning pin 202 and the inner surfaces of the holes 200 and 201 is selected. Within the smaller range, the lower post 24 can be moved relative to the cylinder body 10 in the left-right direction in FIG.

  Further, with the output shaft 2 attached to the intermediate wall 69, the shaft member 210 is inserted into the shaft hole 212 of the output shaft 2. Then, the two arms 214 are attached to the outer periphery of the shaft member 210 on both sides of the intermediate wall 69. Thereafter, the intermediate wall 69 and the casing 9 are brought close to each other, and the ball portions 216 provided at one end portion of both ends of the two arms 214 are respectively inserted into the holes 209 of the upper post 31A. Further, the cylinder body 10 is brought close to the intermediate wall 69 and the remaining ball portion 216 is inserted into the hole 208 of the lower post 24, and the intermediate wall 69 and the cylinder body 10 are connected to a bolt (not shown). Tighten and fix with. Further, the cylinder body 10 and the casing 9 are positioned by the positioning pins 72.

  In the state where the arm 214 is attached to the shaft member 210 by the above process, one sphere portion 216 contacts the inner peripheral surface of the hole 209 of the upper post 31A, and the other sphere portion 216 contacts the lower post. It contacts the inner peripheral surface of the 24 holes 208. Specifically, each sphere 216 touches at two locations within the first plane G1. In this way, the upper post 31A and the lower post 24 are relatively positioned in the first plane G1. That is, the lower post 24 and the upper post 31A are disposed on the line segment F1, and the swing center of the lower link 22 and the swing center of the upper link 34 are both disposed on the line segment F1. Then, the lower post 24 and the upper post 31A are positioned. After the relative positioning of the upper post 31A and the lower post 24 is completed, the bolt 207 is further tightened to fix the upper post 31A to the casing 9, and the bolt 60 is further tightened to fix the lower post 24 to the cylinder body 10. .

  Thereafter, the shaft member 210 is moved along the axis X <b> 1, and the shaft member 210 is removed from the arm 211. Next, the casing 9 and the cylinder body 10 are pulled apart in the vertical direction in FIGS. 1 and 5, and the ball portion 216 of the arm 214 is extracted from the hole 209 of the upper post 31 </ b> A and the hole 208 of the lower post 24. Furthermore, when the casing 9 and the cylinder body 10 are positioned again by the positioning pins 72 and then the bolts 73 are tightened, the casing 9 and the cylinder body 10 are fixed.

  As described above, in the assembly process (manufacturing process) of the toroidal type continuously variable transmission 100, when the positioning device shown in FIGS. 1 and 5 is used, the assembly of the toroidal type continuously variable transmission 100 is completed before the assembly of the toroidal type continuously variable transmission 100 is completed. The upper post 31A and the lower post 24 can be positioned. An upper link 34 is attached to the upper post 31 </ b> A, and the trunnion 12 is attached to a shaft hole 35 of the upper link 34. The lower link 22 is attached to the lower post 24, and the trunnion 12 is attached to the shaft hole 26 of the lower link 22. Therefore, when the assembly of the toroidal type continuously variable transmission 100 is completed as shown in FIG. 3, the positioning accuracy of the power roller 8 held by one trunnion 12A with respect to the input disk 4 and the output disk 5 is determined. And the positioning accuracy of the power roller 8 held by the other trunnion 12B can be matched.

  For example, the power roller 8 held by one trunnion 12A is in contact with the input disk 4 and the output disk 5, and the power roller 8 held by the other trunnion 12B is the input disk 4 and The radius of the contact point that contacts the output disk 5 matches. Then, after the assembly of the toroidal continuously variable transmission 100 is completed, when torque is transmitted by the toroidal continuously variable transmission 100, the power roller 8 held by one trunnion 12A is connected to the input disk 4 and the output. Conditions such as load, tangential force, torque capacity, traction coefficient, etc. generated in contact with the disk 5 and the power roller 8 held by the other trunnion 12B are generated in contact with the input disk 4 and output disk 5. Conditions such as load, tangential force, torque capacity, and traction coefficient can be matched. Therefore, “After the assembly of the toroidal-type continuously variable transmission is completed, torque transmission is performed to measure the positioning accuracy of the upper post and the lower post, and the toroidal-type continuously variable transmission is disassembled based on the measurement result to determine the positioning. The work of “adjusting the accuracy” can be avoided in advance, and an increase in the man-hours for assembling the toroidal-type continuously variable transmission can be suppressed.

  Further, after the relative positioning of the lower post 24 and the upper post 31A within the first plane G1, the lower post 24 and the cylinder body 10 are fixed, and the upper post 31A is fixed. When an external force along a plane orthogonal to the axis X1 is applied to the lower post 24 or the upper post 31A, the sphere 216 and the lower post 24 come into contact with each other, and the sphere 216 and the upper post 31A The arm 211 can operate around the axis line X1 in the plane while being in contact with each other.

  For example, in FIG. 1, when the lower post 24 translates horizontally along the inner surface of the cylinder body 10, the ball portion 216 slides while being in contact with the inner peripheral surface of the hole 208. In FIG. 1, when the upper post 31 </ b> A is translated in the horizontal direction along the inner surface of the top plate 31, the ball portion 216 slides while being in contact with the inner peripheral surface of the hole 209. In this way, the swing center of the lower link 22 and the swing center of the upper link 34 are both held in a state of being positioned on the line segment F1. Therefore, the lower post 24, the upper post 31, the cylinder body 10, the top plate 31, or the lower post 24, the upper post 31, the cylinder body 10, or the top plate 31, regardless of the processing accuracy of any one element. The lower post 24 and the upper post 31 </ b> A can be reliably positioned without any one element of the arm 211 being deformed or the ball portion 216 not easily coming off the holes 208 and 209.

  In addition, since the outer peripheral shape of the sphere 216 is circular in the first plane G1, even when the arm 211 operates around the axis X1, the sphere 216 and the sphere 216 are in the plane. The gap amount between the inner peripheral surface of the hole 208 is maintained substantially the same (does not change), and the gap amount between the spherical portion 216 and the inner peripheral surface of the hole 209 is maintained substantially the same in the plane. (Does not change). Therefore, any one of the lower post 24, the upper post 31A, the cylinder body 10, the casing 9, or the arm 211 is prevented from being deformed or the arm 211 is less likely to come off. it can.

  Here, the correspondence between the configuration shown in FIGS. 1 to 5 and the configuration of the present invention will be described. The axis X1 corresponds to the axis of the present invention, and the lower post 24 corresponds to the first post of the present invention. The upper post 31A corresponds to the second post of the present invention, the cylinder body 10 corresponds to the first fixing member of the present invention, and the casing 9 corresponds to the second fixing member of the present invention. The first plane G1 corresponds to the “plane perpendicular to the axis” in the present invention, the shaft member 210 and the arm 211 correspond to the jig of the present invention, and the line segment F1 corresponds to this The two ball portions 216 correspond to the first contact portion and the second contact portion of the present invention, and the inner peripheral surface of the hole 208 corresponds to the “first of the present invention”. The inner peripheral surface of the hole 209 corresponds to the “part of the mating part”. Corresponding to the opponent part ". Further, the technical meaning of “positioning the relative position between the first post and the second post” in the present invention is more specifically that the lower post 24 and the upper post 31A are arranged on the line segment F1. Specifically, the lower post 24 and the upper post 31A are positioned so that the swing center of the lower link 22 and the swing center of the upper link 34 are both arranged on the line segment F1.

(Configuration example 2)
Next, a configuration example 2 of a “positioning device” and a “positioning method” for positioning the upper post 31A and the lower post 24 in the process of assembling the toroidal type continuously variable transmission 100 will be described with reference to FIGS. 1 and 6. explain. In this configuration example 2, the inner diameter of the shaft hole 5 </ b> A of the output disk 5 is configured to be smaller than the inner diameter of the shaft hole 212 of the output shaft 2. That is, when the toroidal type continuously variable transmission 100 is assembled using the output shaft 2 and the output disk 5 shown in FIG. 6, a radial bearing (see FIG. 6) is provided between the inner periphery of the output disk 5 and the outer periphery of the input shaft 1. (Not shown) can be arranged. Other configurations in the configuration example 2 are the same as those in the configuration example 1. In the second configuration example, when the shaft member 210 is inserted across the shaft hole 5A of the input disk 5 and the shaft hole 212 of the output shaft 2 in the assembly process of the toroidal-type continuously variable transmission 100. The shaft member 210 contacts the inner peripheral surface of the shaft hole 5A of the two output disks 5, and the shaft member 210 is disposed coaxially with the axis X1. Also in this configuration example 2, the same effects as those of the configuration example 1 can be obtained.

(Configuration example 3)
Next, a configuration example 3 of a “positioning device” and a “positioning method” for positioning the upper post 31A and the lower post 24 in the process of assembling the toroidal type continuously variable transmission 100 will be described with reference to FIGS. 1 and 7. explain. In the configuration example 3, the shaft member 210 is divided into two in the direction along the axis X1, and each shaft member 210 is provided with an arm 211. One shaft member 210 and the arm 211 are configured to be integrally rotatable. For example, the cylindrical portion 213 and the shaft member 210 can be fixed by welding connection or screw connection. Further, without providing the cylindrical portion 213, the arm 211 can be configured by fixing two shaft portions 214 to the outer periphery of the shaft member 210 by welding or screwing. Also in this configuration example 3, the inner diameter of the shaft hole 5A of the output disk 5 is configured to be smaller than the inner diameter of the shaft hole 212 of the output shaft 2. That is, when the toroidal type continuously variable transmission 100 is assembled using the output shaft 2 and the output disk 5 shown in FIG. 7, a radial bearing (see FIG. 5) is provided between the inner periphery of the output disk 5 and the outer periphery of the input shaft 1. (Not shown) can be arranged. Other configurations in the configuration example 3 are the same as those in the configuration example 1.

  In the configuration example 3, each shaft member 210 is inserted into the shaft hole 5A of the input disk 5 separately in the assembly process of the toroidal-type continuously variable transmission 100, whereby each shaft member 210 is The two shaft members 210 are arranged coaxially with the axis line X1 in contact with the inner peripheral surfaces of the shaft holes 5A of the two output disks 5 separately. In the configuration example 3, when positioning the upper post 31A and the lower post 24, the shaft member 210 and the arm 211 can rotate around the axis X1, and the same effects as the configuration example 1 Can be obtained.

(Configuration example 4)
Next, a configuration example 4 of a “positioning device” and a “positioning method” for positioning the upper post 31A and the lower post 24 in the process of assembling the toroidal type continuously variable transmission 100 will be described with reference to FIGS. explain. 8 and 10 are longitudinal sectional views in the direction along the first plane G1, and FIGS. 9 and 11 are longitudinal sectional views in the direction along the axis X1. In this configuration example 4, the upper post 31A is not in contact with and fixed to the top plate 31, but a base portion 220 as an intermediate member is attached to the top plate, and the upper post 31A is attached to the base portion 220. It has a configuration that can be. 8 and 9 show a state before the upper post 31A is attached to the base portion 220, and FIGS. 10 and 11 show a state where the upper post 31A is attached to the base portion 220. FIG.

  First, as shown in FIGS. 8 and 9, the base portion 220 has a plate shape and has two holes 221 penetrating in the thickness direction. One hole 221 is formed for each cavity T1. The hole 221 has a substantially circular shape in a plane parallel to the second plane G 2, and the hole 221 has the same inner diameter as the hole 208. The center line of the hole 221 is arranged in the vertical direction. The base portion 220 is provided with a female screw portion 222, and the bolt 207 is screwed into the female screw portion 222 and tightened, so that the base portion 220 is fixed to the top plate 31. Yes. As shown in FIGS. 10 and 11, a concave portion 223 is provided on the upper surface of the base portion 220 in a state where the base portion 220 is fixed to the top plate 31. A plurality of the recesses 223 are provided so as to correspond to a single upper 31A. Further, the upper post 31 </ b> A is attached to the upper surface of the base portion 220. The upper post 31A is also provided with a plurality of recesses 224. A single positioning pin (knock pin) 225 is disposed across the recess 223 and the recess 224, and the upper post 31A and the base portion 220 are connected to each other. It is relatively positioned in a plane parallel to the second plane G2. The upper post 31 </ b> A and the base portion 220 are configured to be fastened and fixed by bolts (not shown). Other configurations in the configuration example 4 are the same as those in the configuration example 1.

  In the configuration example 4, the base portion 220 and the casing 9 are temporarily fixed by the bolt 207 in the assembly process of the toroidal type continuously variable transmission 100. In a state where the base portion 220 and the casing 9 are temporarily fixed by the bolts 207, the base portion 220 and the top plate 31 are left and right in FIG. 8 and FIG. Relative movement is possible. In this configuration example 4, with the base portion 220 temporarily fixed, the lower post 24 and the base portion 220 are relative to each other within the first plane G1 using the shaft member 210 and the arm 211. Perform proper positioning. In the fourth structural example, the steps of temporarily fixing the lower post 24 to the cylinder body 10 and holding the shaft member by the output shaft 2 are the same as in the first structural example.

  And in this structural example 4, one spherical part 216 is inserted in the said recessed part 221, and the outer peripheral surface of the spherical part 216 is made to contact the inner peripheral surface of the said recessed part 221, and thereby the inside of the first plane G1 Thus, the lower post 24 and the base 220 are relatively positioned. Then, the bolt 60 is tightened to fix the lower post 24 to the cylinder body 10, and the bolt 207 is tightened to fix the base 220 to the casing 9. When an external force in a substantially horizontal direction in FIG. 8 is applied to at least one of these, the arm 211 rotates within the predetermined angle range about the axis X1, so that one sphere 216 contacts the lower post 24. In addition, the state in which the other ball portion 216 is in contact with the base portion 220 is maintained. Therefore, the relative positional relationship between the lower post 24 and the base portion 220 is maintained.

  Next, the cylinder body 10 and the casing 9 are pulled apart, and the shaft member 210 and the arm 211 are removed. Further, as shown in FIG. 10 and FIG. 11, the base portion 220 and the upper post 31A are positioned using positioning pins 225, and bolts are tightened to fix the upper post 31A. Thereafter, in a state where the cylinder body 10 is positioned and fixed to the casing 9, the upper post 31A and the lower post 24 are relatively positioned in the first plane G1. As described above, also in the configuration example 4, the upper post 31A and the lower post 24 can be relatively positioned in the assembly process of the toroidal type continuously variable transmission 100. Therefore, the same effects as those of Configuration Example 1 can be obtained. In Configuration Example 4, the upper post 31A and the base portion 220 correspond to the second post in the present invention, and the inner peripheral surface of the hole 221 corresponds to the first mating portion in the present invention.

(Configuration example 5)
Next, a configuration example 5 of a “positioning device” and a “positioning method” for positioning the upper post 31A and the lower post 24 in the process of assembling the toroidal type continuously variable transmission 100 will be described with reference to FIGS. explain. FIG. 12 is a longitudinal sectional view in the direction along the first plane G1, and FIG. 13 is a longitudinal sectional view in the direction along the axis X1. In this configuration example 5, a recess 226 is provided on the inner surface of the top plate 31, and a recess 227 that is opened on the surface of the upper post 31 </ b> A that contacts the top plate 31 is provided. And the positioning pin (knock pin) 228 arrange | positioned over the recessed part 226 and the recessed part 227 is provided. In this configuration example 5, the basic configuration is the same as that in configuration example 1. In this configuration example 5, when the upper post 31A is temporarily fixed to the casing 9, the positioning is performed in a plane parallel to the second plane G2, that is, in a substantially horizontal plane in FIGS. The upper post 31 </ b> A and the top plate 31 are positioned by the pins 228. Also in this configuration example 5, the same effects as those of the configuration example 1 can be obtained.

(Configuration example 6)
Next, a configuration example 6 of a “positioning device” and a “positioning method” for positioning the upper post 31A and the lower post 24 in the process of assembling the toroidal type continuously variable transmission 100 will be described with reference to FIG. FIG. 14 is a longitudinal sectional view in the direction along the axis X1. In this configuration example 6, the length of the cylindrical portion 213 of the arm 211 differs between the two arms 211 in the direction along the axis X1. Specifically, the length of the cylindrical portion 213 of the arm 211 arranged on the left side in FIG. 14 is configured to be longer than the length of the cylindrical portion 213 of the arm 211 arranged on the right side in FIG. The technology of Configuration Example 6 can be used in combination with any of Configuration Example 1, Configuration Example 2, Configuration Example 4, and Configuration Example 5. Therefore, in the configuration example 6, the same effect as any of the configuration example 1, the configuration example 2, the configuration example 4, and the configuration example 5 can be obtained. In the configuration example 6, since the cylindrical portion 213 of the arm 211 is long, the contact area between the outer peripheral surface of the shaft member 210 and the cylindrical portion 213 is enlarged. Therefore, the angle (range) in which the shaft member 211 and the arm 211 rotate relative to each other within the longitudinal section in the direction along the axis line X1 can be slightly suppressed. If comprised in this way, relative positioning of the said upper post 31A and the said lower post 24 can be performed within the longitudinal cross section of the direction along the said axis line X1.

(Configuration example 7)
Next, a configuration example 7 of a “positioning device” and a “positioning method” for positioning the upper post 31A and the lower post 24 in the step of assembling the toroidal type continuously variable transmission 100 will be described with reference to FIGS. explain. FIG. 15 is a longitudinal sectional view in the direction along the first plane G1, and FIG. 16 is a longitudinal sectional view in the direction along the axis X1. In the configuration example 7, the lower post 24 is not in contact with the cylinder body 10 and fixed, but a base portion 229 that is an intermediate member is attached to the cylinder body 10, and the lower post 24 is attached to the cylinder body 10. It is configured to be attached. The lower cover 1 is positioned by a knock pin 72 and fixed to the casing 9.

  First, the cylinder body 10 has a plate shape, and the cylinder body 10 is provided with a female threaded portion 231. The bolt 232 is screwed into the female threaded portion 231 and tightened. Is fixed to the lower cover 11. Further, as shown in FIGS. 15 and 16, a concave portion 233 is provided on the lower surface of the cylinder body 10 in a state where the cylinder body 10 is fixed to the lower cover 11. A plurality of recesses 233 are provided corresponding to one lower post 24. Further, the lower post 24 is attached to the lower surface of the cylinder body 10. The lower post 24 is also provided with a plurality of recesses 234, and a single positioning pin (knock pin) 235 is disposed across the recess 233 and the recess 234, so that the lower post 24 and the cylinder body 10 are connected to the first post. Are relatively positioned in a plane parallel to the second plane G2. The lower post 24 and the cylinder body 10 are configured to be fastened and fixed by bolts 60. Other configurations in the configuration example 7 are the same as those in the configuration example 6.

  In the configuration example 7, in the assembling process of the toroidal type continuously variable transmission 100, first, the upper post 31A is fixed to the casing 9, and then the base portion 229 and the cylinder body 10 are bolted. In the state of being fastened and fixed at 232, it is temporarily fixed to the casing 9. Further, the lower post 24 and the base portion 229 are temporarily fixed by the bolt 60, and in this state, the base portion 229 and the lower post 24 are moved in the left-right direction, specifically in FIGS. Is relatively movable in a substantially horizontal direction. In the configuration example 7, the lower post 24 and the upper post 31 </ b> A are relatively positioned in the first plane G <b> 1 using the shaft member 210 and the arm 211 with the lower post 24 temporarily fixed. The principle of performing is the same as that of the configuration example 1. Next, the lower post 24 is fixed to the base portion 229 by tightening the bolt 60. Further, the cylinder body 10 and the casing 9 are pulled apart, the shaft member 210 and the arm 211 are removed, and the cylinder body 10 is positioned and fixed to the casing 9 again. Thus, also in the configuration example 7, the relative positioning of the upper post 31A and the lower post 24 toroidal continuously variable transmission can be performed in the assembly process of the toroidal continuously variable transmission 100. Therefore, the same effects as those of Configuration Example 1 can be obtained. In the configuration example 7, the cylinder body 10 and the base portion 229 correspond to the first fixing member in the present invention.

  In each configuration example, a disk portion 250 as shown in FIG. 17 can be provided instead of the ball portion 216. The disc portion 250 corresponds to the first contact portion and the second contact portion of the present invention. In this case, the planar shape of each of the holes 208, 209, and 221 is a square such as a square or a rectangle. That is, the arm 211 can be rotated around the axis X1 in a state where the outer peripheral surface of the disc portion 250 is in contact with the inner peripheral surface of the hole, and the same effects as those of the respective configuration examples can be obtained. That is, in each configuration example, if the outer peripheral shape in the first plane G1 is substantially circular, the outer peripheral surface is the upper post (or base portion) and the lower post, regardless of whether the spherical portion 216 or the disk portion. It suffices that the arm 211 can rotate around the axis X1 in a state where the inner surface of the hole of the (or base portion) is in contact at two points. Also in this case, the gap amount between the inner peripheral surface of the hole and the outer peripheral surface of the disc portion 250 is maintained substantially constant. Therefore, the first contact portion and the second contact portion can obtain the operational effects of the present invention as long as the outer peripheral shape in the first plane G1 is substantially circular.

  Moreover, it is also possible to use what is shown in FIG. 18 as another structure of a 1st contact part and a 2nd contact part, and another structure of a 1st other party part and a 2nd other party part. That is, neither the ball part 216 nor the disk part 250 is provided at the tip of the shaft part 214 of the arm 211, and the thickness or diameter of the shaft part 214 is set to be uniform. In contrast, the inner peripheral surface of the hole 251 provided in the upper post 31A has an arc shape protruding in a direction approaching each other, and the inner peripheral surface of the hole 252 provided in the lower post 24 is It has an arc shape protruding in a direction approaching each other. When the configuration shown in FIG. 18 is adopted, the arm 211 can rotate around the axis line X1 with the shaft portion 214 in contact with the inner peripheral surfaces of the holes 251 and 252 at one point. Similar effects can be obtained. Also in this case, the gap amount between the holes 251 and 252 and the shaft portion 214 is maintained substantially constant. In the configuration of FIG. 18, the shaft portion 214 corresponds to the first contact portion and the second contact portion of the present invention, and the inner surfaces of the holes 251 and 252 correspond to the first counterpart portion and the second contact portion of the present invention. Corresponds to the other party.

  Furthermore, the positioning device and the positioning method of the present invention can also be used when assembling the toroidal continuously variable transmission in a state where the axis X1 is arranged in a direction other than the horizontal direction, for example, in the vertical direction. Furthermore, the first fixing member and the second fixing member of the present invention include structural parts such as a lid member, a housing, a bracket, and a mount portion in addition to the cylinder body and the casing. That is, the first fixing member and the second fixing member are components or structural members that accommodate the input disk, the output disk, and the power roller, or parts that are arranged around the input disk, the output disk, and the power roller. It is impossible to rotate around the axis X1, and it is fixedly arranged so as not to move in the direction along the axis X1. And the 1st fixing member and the 2nd fixing member are positioned relatively. Further, a fixing mechanism for fixing the first fixing member and the second fixing member, a fixing mechanism for fixing the first post and the first fixing member, and fixing the second post and the second fixing member. As a fixing mechanism and a fixing mechanism for fixing the first fixing member and the second fixing member, in addition to a female screw and a bolt, a combination of a bolt and a nut, welding, adhesion using an adhesive, caulking, or the like can be used. It may be used. Furthermore, in the present invention, all the jigs are made of a metal material, for example, a carbon steel for machine structure, an aluminum alloy, aluminum, or the like, or a highly rigid resin material. In addition, this embodiment can also be applied to a toroidal continuously variable transmission used for machine tools other than vehicles, industrial machines, transport machines, and the like.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a toroidal continuously variable transmission assembly device according to the present invention, and is a schematic longitudinal sectional view in a direction perpendicular to an axis. BRIEF DESCRIPTION OF THE DRAWINGS It is a power transmission device which has a toroidal type continuously variable transmission made into object by this invention, and is a schematic longitudinal cross-sectional view in the direction along an axis. 1 is a toroidal continuously variable transmission according to the present invention, and is a longitudinal sectional view in a direction perpendicular to an axis. It is a schematic diagram which shows three-dimensional positioning of the element of the toroidal type continuously variable transmission of this invention. It is the longitudinal cross-sectional view in the direction along the axis which shows the structural example 1 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction which followed the structural example 2 of the assembly apparatus of the toroidal type continuously variable transmission in this invention, and followed the axis line. It is the longitudinal cross-sectional view in the direction along the axis which shows the structural example 3 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction orthogonal to an axis | shaft which shows the structural example 4 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction along the axis which shows the structural example 4 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction orthogonal to an axis | shaft which shows the structural example 4 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction along the axis which shows the structural example 4 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction orthogonal to an axis | shaft which shows the structural example 5 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction along the axis which shows the structural example 5 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction along the axis which shows the structural example 6 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction orthogonal to an axis | shaft which shows the structural example 7 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is the longitudinal cross-sectional view in the direction along the axis which shows the structural example 7 of the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is sectional drawing which shows the other structure of the jig | tool in the assembly apparatus of the toroidal type continuously variable transmission in this invention. It is sectional drawing which shows the other structure of the jig | tool in the assembly apparatus of the toroidal type continuously variable transmission in this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 4 ... Input disc 5 ... Output disc 8 ... Power roller 9 ... Casing 10 ... Cylinder body 24 ... Lower post 31A ... Upper post 100 ... Toroidal continuously variable transmission 208, 209, 221 ... Hole 210 ... Axis member, 211 ... Arm, 220,229 ... Base part, X1 ... Axis line, G1 ... First plane, F1 ... Line segment.

Claims (4)

A first post and a second post that support a power roller that contacts the input disk and the output disk and are disposed at a position sandwiching an axis of the input disk and the output disk; The first post and the second post in a plane perpendicular to the axis in a state where the second post is temporarily fixed to the first fixing member and the second post is temporarily fixed to the second fixing member. In the post-positioning device for toroidal-type continuously variable transmissions that perform relative positioning with
A jig operable around the axis in the plane, the jig being arranged on a line segment passing through the axis in the plane and sandwiching the axis in the plane; A first contact portion and a second contact portion disposed on both sides in the
The first post is provided with a first mating portion that contacts the first contact portion, and the second post is contacted by the second contact portion with the second post. Is provided,
The jig is configured such that the first contact portion and the first post are in contact with each other, and the second contact portion and the second post are in contact with each other, whereby the first post and the second post are in contact with each other. A post-positioning device for a toroidal-type continuously variable transmission, characterized by having a configuration for performing relative positioning with respect to the post.   When the jig is operated around the axis, the first mating part is maintained at approximately the same gap amount with the first contact part, and the second mating part is The post of the toroidal continuously variable transmission according to claim 1, wherein when the jig operates around the axis, the gap amount with the first contact portion is maintained substantially the same. Positioning device.   The shape of the first contact portion or the shape of the first counterpart in the plane is configured to be substantially circular, and the shape of the second contact portion or the shape of the second counterpart in the plane is The post positioning device for a toroidal continuously variable transmission according to claim 2, wherein the post positioning device is substantially circular. A first post and a second post are provided that support a power roller that contacts the input disk and the output disk, and that are disposed at positions that sandwich the axis of the input disk and the output disk. In a state where the first post is temporarily fixed to the first fixing member and the second post is temporarily fixed to the second fixing member, the first post is within a plane perpendicular to the axis of the input disk and the output disk. After the relative positioning between the post and the second post, the first post and the first fixing member are fixed, and the second post and the second fixing member are fixed. In the post positioning method of the toroidal type continuously variable transmission,
A jig operable in the plane around the axis is prepared, the first post is temporarily fixed to the first fixing member, and the second post is temporarily fixed to the second fixing member. In a stopped state, the jig is brought into contact with the first post and the second post, so that the relative relationship between the first post and the second post is within a plane perpendicular to the axis. The first post and the first fixing member are fixed after the positioning is performed, and the second post and the second fixing member are fixed. Post positioning method for transmission.

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