JP5246311B2 - Power transmission device - Google Patents

Description

  The present invention relates to a power transmission device, and more particularly to a power transmission device that shifts and transmits power.

  A gear transmission mechanism is used to shift and transmit power from a power source such as an electric motor or an engine. Since the gear transmission mechanism transmits torque by meshing teeth between gears, it is easy to increase the torque transmission capacity, but the friction torque increases during high-speed rotation, and vibration and noise due to meshing of the teeth also occur. Increase.

  In addition, a traction drive mechanism that transmits torque by oil film shearing force (traction force) generated at a contact portion via an oil film between rollers is also used to transmit power by shifting. The traction drive mechanism has a friction torque smaller than that of the gear transmission mechanism, and vibration and noise during high-speed rotation are also smaller than those of the gear transmission mechanism. However, it is difficult for the traction drive mechanism to have a larger torque transmission capacity than the gear transmission mechanism.

  Furthermore, a power transmission device using both a gear transmission mechanism and a traction drive mechanism has been proposed, and an example thereof will be described with reference to FIG. In the configuration example shown in FIG. 20, a planetary roller mechanism (traction drive mechanism) 112 and a planetary gear mechanism (gear transmission mechanism) 114 are connected in series between an input shaft 116 and an output shaft 118.

  The planetary roller mechanism 112 is sandwiched between the sun roller 121 connected to the input shaft 116, the ring roller 122 that surrounds the outer periphery of the sun roller 121, and the sun roller 121 and the ring roller 122. And a plurality of pinion rollers (planetary rollers) 123 and a carrier 124 that rotatably supports each pinion roller 123. The planetary gear mechanism 114 includes a sun gear 131 coupled to the ring roller 122 via a coupling member 125, a ring gear 132 coupled to the output shaft 118, and a plurality of pinion gears (planetary gears) meshing with the sun gear 131 and the ring gear 132. ) 133 and a carrier 134 that rotatably supports each pinion gear 133. The carriers 124 and 134 are fixed to the casing, so that their rotation is locked.

  The power input to the input shaft 116 (sun roller 121) is decelerated and transmitted to the ring roller 122 (sun gear 131) via each pinion roller 123. The power transmitted to the sun gear 131 is decelerated and transmitted to the ring gear 132 (output shaft 118) via each pinion gear 133. In this way, the power input to the input shaft 116 is decelerated by the planetary roller mechanism 112 and further decelerated by the planetary gear mechanism 114, thereby increasing the gear ratio (reduction ratio) of the entire power transmission device. Further, by arranging the planetary roller mechanism 112 on the input shaft 116 side and the planetary gear mechanism 114 on the output shaft 118 side, the torque transmitted by the planetary roller mechanism 112 is reduced and rotation of each gear of the planetary gear mechanism 114 is performed. Decreasing speed. As a result, the speed, efficiency and noise of the power transmission device (decelerator) are reduced. A power transmission device using both a gear transmission mechanism and a traction drive mechanism is also disclosed in Patent Document 1 and Non-Patent Document 1 below.

JP 2005-213762 A

Akira Ishibashi, Kenji Sonoda, Shinsuke Hattori, “Design, Production and Performance of Hybrid Reduction Gears Using Gears and Rollers (1st Report, Trial Production of New Reduction Gears and Their Power Transmission Efficiency)”, Japan Society of Mechanical Engineers paper Shu (C), December 1986, Vol. 52, No. 484, p. 3271-3276

  In the configuration example shown in FIG. 20, the ring roller 122 positioned on the outermost diameter side of the planetary roller mechanism 112 and the sun gear 131 positioned on the innermost diameter side of the planetary gear mechanism 114 are connected via a connecting member 125. The length of the power transmission device in the axial direction (left-right direction in the figure) is increased by the necessity to provide the connecting member 125, which leads to an increase in size of the power transmission device. Further, in the configuration example shown in FIG. 20, it is necessary to fix the rotation of the carriers 124 and 134 in order to transmit power between the input shaft 116 and the output shaft 118, but it rotates together with the ring roller 122 and the sun gear 131. Since the connecting member 125 is disposed between the carriers 124 and 134 in the axial direction of the power transmission device, it is necessary to fix the rotation of the carriers 124 and 134 at different locations. As a result, the axial length of the power transmission device increases, leading to an increase in size of the power transmission device.

  An object of this invention is to provide the power transmission device which can implement | achieve size reduction.

  The power transmission device according to the present invention employs the following means in order to achieve the above-described object.

A power transmission device according to a reference example of the present invention includes a planetary roller mechanism in which a pinion roller is sandwiched between a sun roller and a ring roller, and a pinion gear and a transmission gear mesh with each other, so that the pinion gear A transmission gear mechanism capable of transmitting torque between the transmission pin and the transmission gear, and the pinion roller and the pinion gear are provided on a common pinion rotating member rotatably supported by the carrier. The outside diameter of the pinion gear is different from the outside diameter of the pinion roller, and the gist is that the rotation of any one of the carrier, the ring roller, and the transmission gear is fixed.

In the reference example of the present invention, the pinion roller and the pinion gear are provided on a common pinion rotating member rotatably supported by the carrier, thereby connecting the roller of the planetary roller mechanism and the gear of the transmission gear mechanism. It becomes possible to combine and integrate directly without a member. Therefore, the axial length of the power transmission device can be shortened, and the power transmission device can be downsized.

  In one aspect of the present invention, the transmission gear mechanism is a mechanism capable of shifting and transmitting power between the pinion gear and the transmission gear, and the rotation of the carrier or the ring roller is fixed. It is preferable that the motive power can be shifted and transmitted between the sun roller and the transmission gear.

  In one aspect of the present invention, it is preferable that the rotation of the transmission gear is fixed so that the power can be shifted and transmitted between the sun roller and the carrier. In this aspect, the transmission gear is preferably a sun gear that meshes with the pinion gear by teeth provided on the outer periphery thereof.

  In one aspect of the present invention, the transmission gear is preferably a ring gear that meshes with the pinion gear by teeth provided on the inner periphery thereof. In this aspect, the transmission gear mechanism is preferably a planetary gear mechanism that further includes a sun gear meshing with the pinion gear in addition to the pinion gear and the ring gear.

Further, the power transmission device according to the present invention includes a planetary roller mechanism in which a pinion roller is sandwiched between a sun roller and a ring roller so that the pinion roller is rotatably supported by the first carrier, a sun gear, A planetary gear mechanism in which a pinion gear meshing with the ring gear is rotatably supported by the second carrier, the sun gear is connected to the first carrier, and the ring roller and the ring gear are provided in a common ring member. and which, by rotation of the first carrier or the ring member is fixed, Ri can der be transmitted by the shift power between the sun roller and the second carrier, wherein the ring member, the ring roller A buffer portion is provided for alleviating deformation of the ring gear in the radial direction due to deformation in the radial direction. In the ring member, the inner diameter of the buffer portion is larger than the inner diameter of the ring roller and the ring gear, and the outer diameter of the buffer portion is the ring roller and the ring gear. The gist is that it is smaller than the outer diameter of the gear .

  In the present invention, the ring roller and the ring gear are provided in a common ring member, and the rotation of the carrier or the ring member is fixed, so that power is shifted and transmitted between the sun roller and the second carrier. Therefore, the rotation members of the planetary roller mechanism and the transmission gear mechanism necessary for the fixing can be fixed at one place, and the distance between the ring roller and the ring gear in the axial direction of the power transmission device can be reduced. Therefore, the axial length of the power transmission device can be shortened, and the power transmission device can be downsized.

  In one aspect of the present invention, it is preferable to have a pressing mechanism that applies a pressing force to the contact portion between the sun roller and the pinion roller and the contact portion between the pinion roller and the ring roller by pressing the ring roller toward the inner diameter side. It is. In this aspect, a tapered surface whose outer diameter gradually decreases from one side to the other side in the axial direction is formed on the outer peripheral portion of the ring roller, and the pressing mechanism includes a pressing member that presses the tapered surface, The member is restrained from being displaced toward the outer diameter side of the ring roller, the ring roller is restrained from being displaced toward one side in the axial direction, and presses the pressing member toward one side in the axial direction of the ring roller. It is preferable to press toward the inner diameter side. In this aspect, the pressing mechanism is preferably a mechanism that presses the ring roller toward the inner diameter side by tightening the outer peripheral portion of the ring roller. In this aspect, it is preferable that the pressing mechanism is a mechanism that presses the ring roller toward the inner diameter side with a pressing force corresponding to the torque acting on the ring roller.

The power transmission device according to the reference example of the present invention includes a planetary roller mechanism in which a first pinion roller is sandwiched between a sun roller and a ring roller, and a second pinion roller and a transmission roller. A transmission roller mechanism capable of transmitting torque between the second pinion roller and the transmission roller by contact, and the first pinion roller and the second pinion roller are rotatable with respect to the carrier. The second pinion roller has a different outer diameter than the first pinion roller, and the rotation of any one of the carrier, the ring roller, and the transmission roller is fixed. The gist is that

In the reference example of the present invention, the first pinion roller and the second pinion gear are provided in a common pinion rotating member rotatably supported by the carrier, so that the roller of the planetary roller mechanism and the transmission roller mechanism It is possible to directly couple and integrate the roller without a connecting member. Therefore, the axial length of the power transmission device can be shortened, and the power transmission device can be downsized.

Further, in the power transmission device according to the reference example of the present invention, the first pinion roller is sandwiched between the first sun roller and the first ring roller, and the first pinion roller is freely rotatable by the first carrier. The second planetary roller mechanism is supported between the second sun roller and the second ring roller, and the second pinion roller is sandwiched between the second roller and the second ring roller, and the second pinion roller is rotatably supported by the second carrier. A second planetary roller mechanism, wherein the second sun roller is coupled to the first carrier, and the first ring roller and the second ring roller are provided on a common ring member, and the first carrier or ring The gist is that, by fixing the rotation of the member, it is possible to shift and transmit power between the first sun roller and the second carrier.

In the reference example of the present invention, the first ring roller and the second ring roller are provided on a common ring member, and the rotation of the first carrier or the ring member is fixed, so that the first sun roller and the second carrier are fixed. The rotating members of the first planetary roller mechanism and the second planetary roller mechanism necessary for shifting the power between the first planetary roller mechanism and the second planetary roller mechanism can be fixed at one place, and the first planetary roller mechanism in the axial direction of the power transmission device can be fixed. The interval between the ring roller and the second ring roller can be reduced. Therefore, the axial length of the power transmission device can be shortened, and the power transmission device can be downsized.

It is a figure which shows schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 1 of this invention. It is a figure which shows schematic structure of the press mechanism which presses a ring roller to an internal diameter side. It is a figure which shows the other schematic structure of the press mechanism which presses a ring roller to an internal diameter side. It is a figure which shows the other schematic structure of the press mechanism which presses a ring roller to an internal diameter side. It is a figure which shows the other schematic structure of the press mechanism which presses a ring roller to an internal diameter side. It is a figure which shows the other schematic structure of the press mechanism which presses a ring roller to an internal diameter side. It is a figure which shows schematic structure of the power transmission device which concerns on Embodiment 2 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 2 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 2 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 2 of this invention. It is a figure which shows the other schematic structure of the power transmission device which concerns on Embodiment 2 of this invention. It is a figure which shows schematic structure of the power transmission device which concerns on related technology.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as embodiments) will be described with reference to the drawings.

“Embodiment 1”
FIG. 1 is a diagram showing a schematic configuration of a power transmission device according to Embodiment 1 of the present invention, and shows a diagram viewed from a direction orthogonal to the axial direction. In the power transmission device according to the present embodiment, the planetary roller mechanism 12 and the transmission gear mechanism (transmission gear mechanism) 14 are connected in series between the input shaft 16 and the output shaft 18, such as an electric motor or an engine. The power input to the input shaft 16 from the power source is shifted (decelerated) by the planetary roller mechanism 12 and the transmission gear mechanism 14 and then transmitted to the output shaft 18. The power transmitted to the output shaft 18 is used to drive a load connected to the output shaft 18.

  The planetary roller mechanism 12 is sandwiched between the sun roller 21 connected to the input shaft 16, the ring roller 22 surrounding the outer periphery of the sun roller 21, and the sun roller 21 and the ring roller 22. And a plurality of pinion rollers (planetary rollers) 23 and a carrier 24 that rotatably supports each pinion roller 23. FIG. 1 shows an example in which the planetary roller mechanism 12 is a single pinion planetary roller mechanism. The outer diameter (pitch circle diameter) of each pinion roller 23 is set larger than the outer diameter (pitch circle diameter) of the sun roller 21. The planetary roller mechanism 12 here transmits power by the shear force (tangential traction force) of the oil film generated by applying a pressing force (normal force) to the contact portion of the rotating rollers through the oil film. Is a traction drive mechanism. For example, by assembling the planetary roller mechanism 12 by a shrink-fit method, contact portions (contact surfaces) 27 between the sun rollers 21 and the respective pinion rollers 23 and contact portions (contact surfaces) 28 between the respective pinion rollers 23 and the ring rollers 22 are formed. A pressing force (normal force) can be applied. Further, in the present embodiment, by applying a pressing force to the ring roller 22 toward the inner diameter side (sun roller 21 side), the contact portion 27 between the sun roller 21 and each pinion roller 23, and each pinion roller 23 and ring roller It is also possible to provide a pressing mechanism that applies a pressing force (normal force) to the contact portion 28 with the contact 22. A configuration example of the pressing mechanism here will be described later. In this way, by applying a normal force to the contact portions 27 and 28, a tangential traction force can be generated at the contact portions 27 and 28.

  The transmission gear mechanism 14 includes a plurality of pinion gears 33, a ring gear (internal gear) 32 connected to the output shaft 18 and meshed with each pinion gear 33, and a carrier 34 that rotatably supports each pinion gear 33. It is possible to transmit torque between each pinion gear 33 and the ring gear 32. The inner diameter (pitch circle diameter) of the ring gear 32 is set to be larger than the outer diameter (pitch circle diameter) of each pinion gear 33. The ring gear 32 is formed by teeth provided on the inner periphery thereof. Are engaged. The inner diameter (pitch circle diameter) of the ring gear 32 is set smaller than the inner diameter (pitch circle diameter) of the ring roller 22, and the outer diameter of each pinion gear 33 is different from the outer diameter of each pinion roller 23. The outer diameter of each pinion roller 23 is set smaller.

  In this embodiment, the carriers 24 and 34 are connected to each other, and the pinion roller 23 and the pinion gear 33 are provided on a common pinion rotating member 43 that is rotatably supported by the carriers 24 and 34. That is, the pinion roller 23 and the pinion gear 33 are integrated. The carriers 24 and 34 are fixed to the casing, so that their rotation is locked. Therefore, for each pinion rotating member 43 (pinion roller 23 and pinion gear 33), the revolution that is the rotation around the central axis of the carriers 24 and 34 is locked, and only the rotation that is the rotation around the own axis is allowed. ing. One of the carriers 24 and 34 may be omitted, and each pinion rotating member 43 (pinion roller 23 and pinion gear 33) may be rotatably supported on the other of the carriers 24 and 34.

  The power from the power source input to the input shaft 16 is transmitted from the sun roller 21 to each pinion rotating member 43 (pinion roller 23) by a tangential traction force generated at the contact portion 27 between the sun roller 21 and each pinion roller 23. Is slowed down. The power transmitted to each pinion rotating member 43 is decelerated by being transmitted from each pinion gear 33 to the ring gear 32 by meshing between each pinion gear 33 and the ring gear 32. The power transmitted to the ring gear 32 is output from the output shaft 18. As described above, the power transmission device according to the present embodiment functions as a speed reduction device, and the power from the power source input to the input shaft 16 is decelerated by the planetary roller mechanism 12 and further decelerated by the speed change gear mechanism 14. The Therefore, it is possible to increase the speed ratio (reduction ratio) in the entire power transmission device. In transmission of power from the input shaft 16 (sun roller 21) to the output shaft 18 (ring gear 32), each pinion rotating member 43 is not revolved but only each pinion rotating member 43 rotates.

  Since the transmission gear mechanism 14 transmits torque by meshing teeth, it is easier to increase its torque transmission capacity than the planetary roller mechanism 12 that transmits torque by traction force. However, the transmission gear mechanism 14 increases its friction torque during high-speed rotation, and further increases vibration and noise due to the meshing of teeth. On the other hand, the planetary roller mechanism 12 has a friction torque smaller than that of the transmission gear mechanism 14, and vibration and noise during high speed rotation are also smaller than that of the transmission gear mechanism 14. Therefore, when the power input to the input shaft 16 is decelerated and transmitted to the output shaft 18, the planetary roller mechanism 12 is disposed on the input shaft 16 side, and the speed change gear mechanism 14 is disposed on the output shaft 18 side, whereby the planetary gear mechanism is disposed. The torque transmitted by the roller mechanism 12 can be reduced, and the rotational speed of each gear (pinion gear 33 and ring gear 32) of the transmission gear mechanism 14 can be reduced. Accordingly, it is possible to achieve speedup, high efficiency, and low noise of the power transmission device (deceleration device).

  However, when the ring roller 122 of the planetary roller mechanism 112 and the sun gear 131 of the planetary gear mechanism 114 are connected as in the configuration example shown in FIG. 20 described above, the ring located on the outermost diameter side of the planetary roller mechanism 112 is used. Since it is necessary to provide the connecting member 125 between the roller 122 and the sun gear 131 located on the innermost diameter side of the planetary gear mechanism 114, the length (full length) of the power transmission device in the axial direction increases. As a result, the power transmission device is increased in size.

  On the other hand, in this embodiment, the pinion roller 23 and the pinion gear 33 are provided on the common pinion rotating member 43, and the pinion roller 23 and the pinion gear 33 are integrated, so that the roller of the planetary roller mechanism 12 and the speed change gear are used. It becomes possible to couple | bond directly with the gear of the gear mechanism 14 not via a connection member. Therefore, the length (full length) of the power transmission device in the axial direction (left-right direction in FIG. 1) can be shortened, and the power transmission device can be downsized. By omitting one of the carriers 24 and 34, the overall length of the power transmission device in the axial direction can be further shortened.

  In this embodiment, as shown in FIG. 2, instead of locking the rotation of the carrier 24, the ring roller 22 can be fixed to the casing to lock the rotation of the ring roller 22. In this case, for each pinion rotating member 43 (pinion roller 23 and pinion gear 33), both revolution and rotation are allowed. FIG. 2 shows an example in which the carrier 34 is omitted and each pinion rotating member 43 is rotatably supported by the carrier 24.

  In the configuration example shown in FIG. 2, the power from the power source input to the input shaft 16 is transmitted from the sun roller 21 to each pinion rotating member 43 (pinion roller 23) and the carrier 24. Here, both revolution and rotation of each pinion rotating member 43 are performed. The power transmitted to each pinion rotating member 43 (pinion gear 33) and the carrier 24 is transmitted to the ring gear 32. As a result, power is decelerated and transmitted from the input shaft 16 (sun roller 21) to the output shaft 18 (ring gear 32). According to the configuration example shown in FIG. 2, it is possible to further increase the speed ratio (reduction ratio) of the power transmission device.

  In the present embodiment, as shown in FIG. 3, a brake (fixing mechanism) B <b> 1 capable of fixing the rotation of the carrier 24 and a brake (fixing mechanism) capable of fixing the rotation of the ring roller 22. B2 can also be provided. In the configuration example shown in FIG. 3, the gear ratio of the power transmission device (by changing the engaging brake between the brakes B1 and B2, that is, by switching the rotating member that locks the rotation between the carrier 24 and the ring roller 22). The reduction ratio can be switched.

  Moreover, in this embodiment, as shown in FIGS. 4-6, the sun gear 31 which meshes with each pinion gear 33 by the tooth | gear provided in the outer periphery can also be provided in the gear mechanism 14 for transmission. FIGS. 4-6 has shown the example which added the sun gear 31 with respect to the structural example shown in FIGS. 1-3, respectively. The transmission gear mechanism 14 in this case is configured by a planetary gear mechanism in which a pinion gear (planetary gear) 33 that meshes with the sun gear 31 and the ring gear 32 is rotatably supported by a carrier 34. At the time of torque transmission, each pinion gear 33 receives a radial force by a reaction force from the ring gear 32, and the radial force also acts on the pinion shaft that rotatably supports each pinion gear 33. In the configuration example shown in FIGS. 4 to 6, by providing the sun gear 31 that meshes with each pinion gear 33, the radial force acting on each pinion gear 33 can be received by the sun gear 31, and the radial direction acting on the sun gear 31. The power of is balanced throughout. As a result, the radial force acting on the pinion shaft can be reduced.

  In the configuration example shown in FIGS. 1 to 6, a power source can be connected to the ring gear 32, and the power of the power source can be transmitted from the ring gear 32 to the sun roller 21 through each pinion rotating member 43 while being shifted. . The power transmission device in this case functions as a speed increasing device that speeds up the power input to the ring gear 32 and transmits it to the sun roller 21. Also in this case, the torque transmitted by the planetary roller mechanism 12 can be reduced, and the rotational speed of each gear of the transmission gear mechanism (transmission gear mechanism) 14 can be reduced.

  Further, in the present embodiment, as shown in FIG. 7, the ring gear 32 of the transmission gear mechanism 14 is fixed to the casing to lock the rotation of the ring gear 32 and the output shaft 18 is connected to the carriers 24 and 34. You can also. In the configuration example shown in FIG. 7, the power from the power source input to the input shaft 16 is transmitted from the sun roller 21 to each pinion rotation member 43 (pinion roller 23). Since the rotation of the ring gear 32 that meshes with the pinion gear 33 is fixed, both the revolution and rotation of each pinion rotating member 43 are performed, and the carriers 24 and 34 (output shafts) are interlocked with the revolution of each pinion rotating member 43. 18) rotates. As a result, the power is decelerated and transmitted from the input shaft 16 (sun roller 21) to the output shaft 18 (carriers 24, 34). In the configuration example shown in FIG. 7 as well, the outer diameter of the pinion gear 33 is set smaller than the outer diameter of the pinion roller 23 (the outer diameter of the pinion gear 33 is made different from the outer diameter of the pinion roller 23), thereby transmitting power. It is possible to increase the gear ratio (reduction ratio) of the device more than the transmission ratio (reduction ratio) of the planetary roller mechanism 12 alone.

  Further, in this embodiment, as shown in FIG. 8, a sun gear 31 that meshes with each pinion gear 33 by teeth provided on the outer periphery is provided in the transmission gear mechanism 14, and the sun gear 31 is fixed to the casing to rotate the sun gear 31. And the output shaft 18 can be coupled to the carriers 24 and 34. In the configuration example shown in FIG. 8, the power from the power source input to the input shaft 16 is transmitted from the sun roller 21 to each pinion rotating member 43 (pinion roller 23). Since the rotation of the sun gear 31 meshing with the pinion gear 33 is fixed, both the revolution and rotation of each pinion rotation member 43 are performed, and the carriers 24 and 34 (output shaft 18) are interlocked with the revolution of each pinion rotation member 43. ) Rotates. As a result, the power is decelerated and transmitted from the input shaft 16 (sun roller 21) to the output shaft 18 (carriers 24, 34). In the configuration example shown in FIG. 8 as well, the outer diameter of the pinion gear 33 is set smaller than the outer diameter of the pinion roller 23 (the outer diameter of the pinion gear 33 is different from the outer diameter of the pinion roller 23), thereby transmitting power. It is possible to increase the gear ratio (reduction ratio) of the device more than the transmission ratio (reduction ratio) of the planetary roller mechanism 12 alone.

  In the present embodiment, as shown in FIG. 9, a brake (fixing mechanism) B3 that can fix the rotation of the ring gear 32 and a brake (fixing mechanism) that can fix the rotation of the sun gear 31. B4 can also be provided. In the configuration example shown in FIG. 9, the gear ratio of the power transmission device (by changing the engaging brake between the brakes B3 and B4, that is, by switching the rotating member that locks the rotation between the ring gear 32 and the sun gear 31). The reduction ratio can be switched.

  7 to 9, the power source is connected to the carriers 24 and 34, and the power of the power source is shifted from the carriers 24 and 34 to the sun rollers 21 via the pinion rotating members 43 and transmitted. You can also. The power transmission device in this case functions as a speed increasing device that speeds up the power input to the carriers 24 and 34 and transmits the power to the sun roller 21.

  Here, in the power transmission device according to the present embodiment (configuration example shown in FIGS. 1, 2, 7, and 8), the transmission ratio (reduction ratio), the rotation speed of the output shaft 18 (output rotation speed), and the pinion rotation member The following table shows an example of calculating 43 rotation speeds (pinion rotation speeds). However, in the calculation results in the table below, the maximum outer diameter (outer diameter of the ring roller 22) of the configuration examples shown in FIGS. The rotation speed is a value when the rotation speed of the input shaft 16 is 50000 rpm. Although the reduction ratio differs depending on which one of the carrier 24 (34), the ring roller 22, the ring gear 32, and the sun gear 31 is fixed, generally, the planetary roller mechanism 12 alone Since the gear ratio (reduction ratio) at 3 is about 3 to 5, it can be seen that according to the present embodiment, the transmission ratio (reduction ratio) of the power transmission device can be increased while realizing a reduction in the size of the power transmission device. .

  Next, in the present embodiment, the configuration of a pressing mechanism that applies a pressing force (normal force) to the contact portion 27 between the sun roller 21 and each pinion roller 23 and the contact portion 28 between each pinion roller 23 and the ring roller 22. An example will be described. However, a known pressing mechanism can be used in addition to the configuration example described below.

  In the configuration example shown in FIG. 10, on the outer peripheral surface of the ring roller 22, a tapered surface (conical surface) 22a whose outer diameter gradually decreases from one side (left side in the drawing) to the other side (right side in the drawing). Is formed. A pressing ring (pressing member) 25 that presses the tapered surface 22 a of the ring roller 22 is provided. A taper surface (conical surface) 25 a whose inner diameter gradually decreases from one side to the other side in the axial direction of the ring roller 22 is formed on the inner peripheral surface of the pressing ring 25, and this taper surface 25 a is the ring roller 22. In contact with the tapered surface 22a. The pressing ring 25 is restrained from displacement toward the outer diameter side of the ring roller 22 (upper side in FIG. 10), and the ring roller 22 is restrained from displacement toward one side in the axial direction.

  In the configuration example shown in FIG. 10, by applying a pressing force to the pressing ring 25 on one side in the axial direction of the ring roller 22, the tapered surface 25 a of the pressing ring 25 presses the tapered surface 22 a of the ring roller 22, The ring roller 22 is pressed toward the inner diameter side (sun roller 21 side) by the wedge effect. Accordingly, a pressing force (normal force) can be applied to the contact portions 27 and 28, and a traction force can be stably generated at the contact portions 27 and 28. The normal force applied to the contact portions 27 and 28 can be adjusted by adjusting the pressing force to the one side in the axial direction of the ring roller 22 applied to the pressing ring 25.

  In the configuration example shown in FIG. 11, the belt 26 is wound around the outer peripheral surface of the ring roller 22. By tightening the outer peripheral surface of the ring roller 22 with the belt 26, the ring roller 22 can be pressed toward the inner diameter side, and normal force can be applied to the contact portions 27 and 28. The normal force acting on the contact portions 27 and 28 can be adjusted by adjusting the tightening force of the belt 26.

  In the configuration example shown in FIG. 12, an outer ring 29 surrounding the outer periphery of the ring roller 22 is provided. Cam surfaces 22b and 29b are formed on the outer peripheral surface of the ring roller 22 and the inner peripheral surface of the outer ring 29 so as to face each other, and the rolling ball 30 is disposed between the cam surfaces 22b and 29b. It is installed. As a result, a torque cam is configured to press the ring roller 22 toward the inner diameter side with a pressing force corresponding to the torque acting on the ring roller 22. More specifically, when a phase difference occurs between the ring roller 22 and the outer ring 29 due to the torque acting on the ring roller 22, the rolling ball 30 rolls along the cam surfaces 22b and 29b. The ring roller 22 is pressed toward the inner diameter side with a pressing force corresponding to this phase difference. As a result, a normal force corresponding to the torque acting on the ring roller 22 can be applied to the contact portions 27 and 28, and the normal force applied to the contact portions 27 and 28 can be adjusted more appropriately.

  In the configuration example shown in FIGS. 13 and 14, a hydraulic chamber 35 is formed between the outer peripheral surface of the ring roller 22 and the inner peripheral surface of the outer ring 29. A cylinder chamber 37 communicating with the hydraulic chamber 35 is formed in the outer ring 29, and a hydraulic piston 36 connected to the ring roller 22 is provided in the cylinder chamber 37. The hydraulic chamber 35 and the cylinder chamber 37 are filled with hydraulic oil. 13 shows a view from the input shaft 16 side, and FIG. 14 shows a view from the output shaft 18 side.

  13 and 14, when a phase difference occurs between the ring roller 22 and the outer ring 29 due to the torque acting on the ring roller 22, the hydraulic piston 36 slides along the peripheral wall of the cylinder chamber 37. As a result, an oil pressure corresponding to the phase difference is generated in the hydraulic chamber 35. When the ring roller 22 is pressed toward the inner diameter side by this oil pressure, a normal force acts on the contact portions 27 and 28. Accordingly, the ring roller 22 can be pressed toward the inner diameter side with a pressing force corresponding to the torque acting on the ring roller 22. That is, a normal force corresponding to the torque acting on the ring roller 22 can be applied to the contact portions 27 and 28.

“Embodiment 2”
FIG. 15 is a diagram illustrating a schematic configuration of a power transmission device according to the second embodiment of the present invention. In the following description of the second embodiment, the same or corresponding components as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted.

  In this embodiment, as compared with the first embodiment, the transmission gear mechanism 14 further includes a sun gear 31 that meshes with each pinion gear 33 in addition to the pinion gear 33, the ring gear 32, and the carrier 34. That is, the speed change gear mechanism 14 is constituted by a planetary gear mechanism in which a pinion gear (planetary gear) 33 that meshes with the sun gear 31 and the ring gear 32 is rotatably supported by the carrier 34. FIG. 15 shows an example in which the speed change gear mechanism 14 is a single pinion planetary gear mechanism. The carrier 24 of the planetary roller mechanism 12 is connected to the sun gear 31 of the transmission gear mechanism (planetary gear mechanism) 14, and the carrier 34 of the transmission gear mechanism 14 is connected to the output shaft 18. Further, the ring roller 22 and the ring gear 32 are provided on a common ring member 42, so that the ring roller 22 and the ring gear 32 are integrated. The rotation of the ring member 42 (ring roller 22 and ring gear 32) is locked by being fixed to the casing. Other configurations are the same as those in the first embodiment, and thus the description thereof is omitted.

  The power from the power source input to the input shaft 16 is caused by the revolution (rotation around the central axis of the carrier 24) and rotation (rotation around the own axis) of each pinion roller 23 by the traction force generated at the contact portions 27 and 28. By being performed, the sun roller 21 decelerates to the carrier 24 and is transmitted. The power transmitted to the carrier 24 is caused by the revolution (rotation around the central axis of the carrier 34) and rotation (rotation around the own axis) of each pinion gear 33 due to the engagement of each pinion gear 33 with the sun gear 31 and the ring gear 32. As a result, the sun gear 31 decelerates to the carrier 34 and is transmitted. The power transmitted to the carrier 34 is output from the output shaft 18. As described above, the power transmission device according to the present embodiment functions as a speed reduction device, and the power from the power source input to the input shaft 16 is decelerated by the planetary roller mechanism 12 and further decelerated by the speed change gear mechanism 14. The Therefore, it is possible to increase the speed ratio (reduction ratio) in the entire power transmission device. Further, by arranging the planetary roller mechanism 12 on the input shaft 16 side and the transmission gear mechanism 14 on the output shaft 18 side, the torque transmitted by the planetary roller mechanism 12 can be reduced and the transmission gear mechanism 14 can be reduced. Since the rotational speed of each of the gears can be reduced, it is possible to increase the speed, increase the efficiency, and reduce the noise of the power transmission device (reduction gear).

  Since the planetary roller mechanism 12 and the transmission gear mechanism (planetary gear mechanism) 14 are both mechanisms having two degrees of freedom of rotation, in order to transmit power between the input shaft 16 and the output shaft 18. Any one of the rotating members constituting the planetary roller mechanism 12 and any one of the rotating members constituting the transmission gear mechanism 14 need to be fixed. However, when the ring roller 122 of the planetary roller mechanism 112 and the sun gear 131 of the planetary gear mechanism 114 are connected and the rotation of the carriers 124 and 134 is fixed as in the configuration example shown in FIG. The connecting member 125 that rotates together with the sun gear 131 is disposed between the carriers 124 and 134 in the axial direction of the power transmission device. In that case, since it is necessary to fix rotation of the carriers 124 and 134 at different locations, the length (full length) of the power transmission device in the axial direction increases. As a result, the power transmission device is increased in size.

  On the other hand, in this embodiment, the ring roller 22 and the ring gear 32 are provided on the common ring member 42, and the ring roller 22 and the ring gear 32 are integrated. Thus, the rotation of the ring roller 22 of the planetary roller mechanism 12 and the ring gear 32 of the transmission gear mechanism 14 can be fixed at one place, and the ring roller 22 and the ring gear 32 in the axial direction of the power transmission device can be fixed. The interval can be reduced. Therefore, the length (full length) of the power transmission device in the axial direction can be shortened, and the power transmission device can be downsized.

  In the present embodiment, as shown in FIG. 16, instead of locking the rotation of the ring member 42 (ring roller 22 and ring gear 32), the carrier 24 and the sun gear 31 are fixed to the casing and the carrier 24 and the sun gear 31 are rotated. Can also be locked. In this case, the revolution of the pinion roller 23 is locked, and only rotation is allowed.

  In the configuration example shown in FIG. 16, the power from the power source input to the input shaft 16 is decelerated and transmitted from the sun roller 21 to the ring member 42 (ring roller 22) by the rotation of each pinion roller 23. The power transmitted to the ring member 42 is shifted from the ring gear 32 to the carrier 34 and transmitted by the revolution and rotation of each pinion gear 33. As described above, also in the configuration example shown in FIG. 16, the power from the power source input to the input shaft 16 is decelerated by the planetary roller mechanism 12 and further decelerated by the transmission gear mechanism 14. Therefore, it is possible to increase the speed ratio (reduction ratio) in the entire power transmission device. In the configuration example shown in FIG. 16, the rotation of the carrier 24 of the planetary roller mechanism 12 and the sun gear 31 of the transmission gear mechanism 14 can be fixed at one place, and the ring roller 22 in the axial direction of the power transmission device The space | interval with the ring gear 32 can be narrowed. Therefore, the length (full length) of the power transmission device in the axial direction can be shortened, and the power transmission device can be downsized.

  In the present embodiment, as shown in FIG. 17, the brake (fixing mechanism) B <b> 3 capable of fixing the rotation of the ring member 42 (ring roller 22 and ring gear 32), and the rotation of the carrier 24 and sun gear 31. And a brake (fixing mechanism) B4 capable of fixing the motor. In the configuration example shown in FIG. 17, the rotating direction of the output shaft 18 is changed by switching the brake to be engaged between the brakes B3 and B4, that is, by switching the rotating member that locks the rotation between the ring member 42 and the carrier 24. It is possible to switch.

  In this embodiment, since the ring gear 32 is coupled to the ring roller 22, when the ring roller 22 is pressed toward the inner diameter side in order to apply a normal force to the contact portions 27 and 28, With the elastic deformation toward the inner diameter side, the ring gear 32 is also easily elastically deformed toward the inner diameter side. When the elastic deformation of the ring gear 32 toward the inner diameter side increases, the friction torque of the transmission gear mechanism 14 increases. Therefore, in this embodiment, it is preferable that the deformation of the ring gear 32 to the inner diameter side accompanying the deformation of the ring roller 22 to the inner diameter side can be reduced.

  In the configuration example shown in FIG. 18, a buffer portion between the ring roller 22 and the ring gear 32 in the ring member 42 for reducing the radial deformation of the ring gear 32 due to the radial deformation of the ring roller 22. 46 is provided. The thickness in the radial direction of the buffer portion 46 is set to be smaller than the thickness in the radial direction of the ring roller 22 and the ring gear 32 so that the buffer portion 46 is easily elastically deformed in the radial direction. By providing the buffer portion 46, the influence of the elastic deformation of the ring roller 22 toward the inner diameter side can be absorbed by the elastic deformation of the buffer portion 46. Therefore, elastic deformation of the ring gear 32 toward the inner diameter side accompanying elastic deformation of the ring roller 22 toward the inner diameter side can be suppressed, and an increase in friction torque of the transmission gear mechanism 14 can be suppressed. In addition, as shown in FIG. 19, the radial thickness of the buffer portion 46 can be gradually reduced.

  Also, in the configuration examples shown in FIGS. 15 to 19, the power source can be connected to the carrier 34, and the power of the power source can be shifted from the carrier 34 to the sun roller 21 and transmitted. The power transmission device in this case functions as a speed increasing device that speeds up the power input to the carrier 34 and transmits it to the sun roller 21. Also in this case, the torque transmitted by the planetary roller mechanism 12 can be reduced, and the rotation speed of each gear of the transmission gear mechanism 14 can be reduced.

  In the first and second embodiments, a speed change roller mechanism (transmission roller mechanism) that is a traction drive mechanism may be provided instead of the speed change gear mechanism (transmission gear mechanism) 14 that is a gear transmission mechanism. it can.

  When the speed change roller mechanism (transmission roller mechanism) is provided in the first embodiment, a plurality of pinion rollers (second pinion rollers) are provided instead of the pinion gear 33, and a ring roller (first roller) that contacts the plurality of pinion rollers is provided. 2 ring rollers) are provided instead of the ring gear 32. Then, the pinion roller (first pinion roller) 23 of the planetary roller mechanism 12 and the second pinion roller of the speed change roller mechanism are provided on a common pinion rotating member 43, and these pinion rollers are integrated. Further, the outer diameter of the second pinion roller is made different from the outer diameter of the pinion roller 23 (for example, the outer diameter of the second pinion roller is set smaller than the outer diameter of the pinion roller 23), the carrier 24 (34), the ring roller The rotation of any one of the (first ring roller) 22 and the second ring roller is fixed. The transmission roller mechanism can transmit torque between the second pinion roller and the second ring roller, and when the rotation of the second ring roller is not fixed, the second pinion roller and the second pinion roller It is possible to shift and transmit power to and from the ring roller. Further, instead of the sun gear 31, a sun roller (second sun roller) that contacts the second pinion roller may be provided in the transmission roller mechanism. Furthermore, the rotation of the second sun roller can be fixed.

  When the speed change roller mechanism is provided in the second embodiment, a sun roller (second sun roller) connected to the carrier 24 is provided instead of the sun gear 31, and a ring roller (second ring roller) surrounding the outer periphery of the second sun roller is a ring. A plurality of pinion rollers (second pinion rollers) provided in place of the gear 32 and in contact with and sandwiched between the second sun roller and the second ring roller (second pinion roller) are provided in place of the pinion gear 33. . That is, the speed change roller mechanism is constituted by a planetary roller mechanism (second planetary roller mechanism). Then, the ring roller (first ring roller) 22 of the planetary roller mechanism (first planetary roller mechanism) 12 and the second ring roller of the speed change roller mechanism (second planetary roller mechanism) are provided on a common ring member 42, These ring rollers are integrated.

  In the first and second embodiments, regarding the operation when the speed change roller mechanism (transmission gear mechanism) is provided instead of the speed change gear mechanism (transmission gear mechanism) 14, the sun gear 31 is the second in the above description. A case where the sun gear is replaced, the ring gear 32 is replaced with the second ring roller, and the pinion gear 33 is replaced with the second pinion roller may be considered. Also in the case where the speed change roller mechanism is provided, the length (full length) of the power transmission device in the axial direction can be shortened, and the power transmission device can be downsized.

  As mentioned above, although the form for implementing this invention was demonstrated, this invention is not limited to such embodiment at all, and it can implement with a various form in the range which does not deviate from the summary of this invention. Of course.

  12 planetary roller mechanism, 14 gear mechanism for transmission (transmission gear mechanism), 16 input shaft, 18 output shaft, 21 sun roller, 22 ring roller, 23 pinion roller, 24, 34 carrier, 31 sun gear, 32 ring gear, 33 pinion Gear, 42 Ring member, 43 Pinion rotating member, 46 Buffer part.

Claims (5)

A planetary roller mechanism in which a pinion roller is sandwiched between the sun roller and the ring roller, and the pinion roller is rotatably supported by the first carrier;
A planetary gear mechanism in which a pinion gear meshing with the sun gear and the ring gear is rotatably supported by the second carrier;
Have
The sun gear is connected to the first carrier,
A ring roller and a ring gear are provided on a common ring member,
By rotation of the first carrier or the ring member is fixed, Ri can der be transmitted by the shift power between the sun roller and the second carrier,
The ring member is provided with a buffer portion for relaxing deformation in the radial direction of the ring gear due to deformation in the radial direction of the ring roller,
The radial thickness of the buffer portion is set to be thinner than the radial thickness of the ring roller and the ring gear,
In the ring member, the inner diameter of the buffer portion is larger than the inner diameter of the ring roller and the ring gear, and the outer diameter of the buffer portion is smaller than the outer diameter of the ring roller and the ring gear . The power transmission device according to claim 1,
A power transmission device including a pressing mechanism that applies a pressing force to a contact portion between a sun roller and a pinion roller and a contact portion between the pinion roller and the ring roller by pressing the ring roller toward an inner diameter side . The power transmission device according to claim 2,
On the outer peripheral portion of the ring roller, a tapered surface is formed in which the outer diameter gradually decreases from one side to the other side in the axial direction.
The pressing mechanism includes a pressing member that presses the tapered surface,
The pressing member is restrained from displacement toward the outer diameter side of the ring roller, the ring roller is restrained from displacement toward one side in the axial direction,
A power transmission device that presses the ring roller toward the inner diameter side by pressing the pressing member toward one side in the axial direction of the ring roller . The power transmission device according to claim 2 ,
The power transmission device is a mechanism that presses the ring roller toward the inner diameter side by tightening the outer peripheral portion of the ring roller . The power transmission device according to claim 2 ,
The pressing mechanism is a power transmission device that is a mechanism that presses the ring roller toward the inner diameter side with a pressing force corresponding to a torque acting on the ring roller .

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