JP6031397B2 - Bending gear system - Google Patents

Description

  The present invention relates to a flexure meshing gear device.

  A flexure meshing gear device disclosed in Patent Document 1 includes a vibrating body, and a cylindrical external gear having flexibility that is arranged on the outer periphery of the vibrating body and is bent and deformed by rotation of the vibrating body. A roller bearing disposed between the vibration generator and the external gear, a first internal gear having rigidity with which the external gear meshes internally, and the first internal gear. And a second internal gear having rigidity to be internally engaged with the external gear.

JP 2012-2318 A

  In a flexure meshing gear device as described in Patent Document 1, a roller bearing is disposed between a vibrating body and a cylindrical external gear, and the rollers of the roller bearing are skewed during torque transmission. There is a risk. When the roller skews, the roller bearing moves toward a member (side member) disposed on the side in the axial direction of the roller bearing of the flexure meshing gear device. Then, the end surface of the retainer of the roller bearing and the side member may collide and slide to generate a friction loss (also referred to as end surface loss) at the end surface of the retainer.

  Accordingly, the present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a flexibly meshing gear device capable of reducing end face loss caused by a roller bearing caused by axial movement of a roller bearing retainer. And

The present invention includes a vibrator, a cylindrical external gear that is arranged on an outer periphery of the vibrator and has a flexibility that is bent and deformed by rotation of the vibrator, the vibrator and the outer A roller bearing disposed between the external gear, a first internal gear having rigidity with which the external gear internally meshes, and an internal gear connected to the external gear that is arranged in parallel with the first internal gear. In a flexure meshing gear device comprising a second internal gear having a meshing rigidity, between the side member disposed on the side of the roller bearing in the axial direction and the roller bearing, A first restricting member for restricting movement of the retainer in the axial direction of the roller bearing is disposed, and the end face of the retainer and the first restricting member are more than the coefficient of friction between the end face of the retainer and the side member. friction coefficient between, or the coefficient of friction between the first regulating member and the side side member is smaller, between the external gear and the side lateral member A second restricting member for restricting the movement of the external gear in the axial direction is disposed, and the end surface of the external gear and the end surface of the external gear are larger than the friction coefficient between the end surface of the external gear and the side member. The coefficient of friction between the second restricting member or the coefficient of friction between the second restricting member and the side member is reduced, and the second restricting member is separated from the first restricting member. The outer diameter of the first restricting member is smaller than the minimum inner peripheral diameter of the outer ring of the roller bearing, and the inner diameter of the second restricting member is larger than the maximum outer diameter of the end surface of the retainer. It solves the problem.

  In this invention, a 1st control member is arrange | positioned between a side member and a bearing. Then, the friction coefficient between the end surface of the retainer and the first regulating member, or the friction between the first regulating member and the side member, rather than the friction coefficient between the end surface of the retainer and the side member of the roller bearing. The coefficient is reduced. That is, in the present invention, even if the roller bearing moves in the axial direction due to skew and the retainer collides with the side member via the first restricting member, the end surface of the retainer having a small friction coefficient and the first restricting member, or Sliding is performed between the first regulating member having a small friction coefficient and the side member. That is, according to the present invention, the end face loss can be reduced as compared with the end face loss caused by the direct sliding between the end face of the retainer having a large friction coefficient and the side member.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to reduce the end surface loss by the roller bearing which arises by the axial movement of the retainer of a roller bearing.

Sectional drawing which shows an example of the whole structure of the bending meshing gear apparatus which concerns on 1st Embodiment of this invention. Front view (A) and sectional view (B) showing the vibrator of FIG. The schematic diagram which shows an example of the positional relationship of the vibration body of FIG. 1, a roller bearing, an external gear, and a 1st, 2nd control member. The schematic diagram which shows an example of the positional relationship of the vibration body of FIG. 1, a roller bearing, an external gear, and an internal gear. The schematic diagram which shows an example of the positional relationship of the 1st, 2nd control member shown in FIG. Sectional drawing which shows an example of the whole structure of the bending meshing type gear apparatus which concerns on 2nd Embodiment of this invention.

  Hereinafter, an example of the first embodiment of the present invention will be described in detail with reference to the drawings.

  First, the overall configuration of the present embodiment will be schematically described.

  As shown in FIG. 1, the flexure meshing gear device 100 is formed in a tubular shape having a flexible structure that is arranged on the outer periphery of the vibrating body 104 and is bent and deformed by the rotation of the vibrating body 104. The external gear 120 (120A, 120B), the roller bearing 110 (110A, 110B) disposed between the vibration body 104 and the external gear 120, and the external gear 120A had a rigidity to be in mesh with the internal gear. A reduction internal gear (first internal gear) 130A and an output internal gear (second internal gear) having a rigidity that is provided in parallel with the external gear 120B and is arranged in parallel with the reduction internal gear 130A. (Both the reduction internal gear 130A and the output internal gear 130B are also simply referred to as the internal gear 130). The retainers 114A of the roller bearings 110A and 110B are disposed between the fixed wall 136 and the output device 138 (side members), which are respectively disposed on the sides of the roller bearings 110A and 110B in the axial direction O, and the bearings 110A and 110B. First restricting members 150A and 150B (150) that restrict the movement of 114B (114) in the axial direction O are disposed. Here, the first regulating member 150 is a thrust bearing.

  Hereinafter, each component will be described in detail.

  As shown in FIGS. 1 and 2, the vibrator 104 has a substantially columnar shape. More specifically, the vibrating body 104 has a meshing range FA with a constant curvature radius r1 centered on an eccentric position (eccentricity L), and has a shape in which a plurality of curvature radii are combined. The vibrating body 104 is configured to realize a meshing state between the external gears 120A and 120B, the reduction internal gear 130A, and the output internal gear 130B in the meshing range FA. The vibrator 104 is formed with an input shaft hole 106 into which the input shaft 102 is inserted at the center. A keyway 108 is provided in the input shaft hole 106 so that the vibrating body 104 rotates integrally with the input shaft 102 when the input shaft 102 is inserted and rotated. The input shaft 102 is rotatably supported on the fixed wall 136 via bearings 140 and 142.

  As shown in FIG. 1, the roller bearing 110 is a bearing disposed between the outer side of the vibrating body 104 and the inner side of the external gear 120. The roller bearing 110A (110B) includes an inner ring 112, a retainer 114A (114B), rollers 116A (116B) as rolling elements, and an outer ring 118A (118B). The inner ring 112 supports the rollers 116 </ b> A and 116 </ b> B, and is disposed in contact with the outer periphery of the vibrating body 104. The rollers 116A (116B) may have a cylindrical shape and include a needle shape. The retainer 114 (114A, 114B) holds the rollers 116A, 116B so as to be rotatable at regular intervals in the circumferential direction. The outer ring 118A (118B) is disposed outside the rollers 116A (116B). The outer ring 118 (118 </ b> A, 118 </ b> B) is bent and deformed by the rotation of the vibrating body 104 and deforms the external gear 120 disposed on the outer side thereof in the radial direction. A first restriction member 150 is disposed outside the roller bearing 110 in the axial direction O (described later).

  As shown in FIG. 1, the external gear 120 is composed of a base member 122 and external teeth 124 (124A, 124B) and has a cylindrical shape. The base member 122 is a flexible cylindrical member, and is disposed outside the roller bearing 110. As shown in FIG. 1, the external teeth 124 are divided in the axial direction O, but the base members 122 that support them are integrated and made common. The external tooth 124 has a tooth profile determined based on a trochoid curve so as to realize theoretical meshing. A second regulating member 152 is disposed outside the external gear 120 in the axial direction O (described later).

  As shown in FIG. 1, the internal gear 130A for deceleration is formed of a rigid member. The reduction internal gear 130A includes internal teeth 128A having i (i = 2, 4,...) More teeth than the external teeth 124A of the external gear 120A. A fixed wall 136 for fixing the flexure meshing gear device 100 is fixed to the reduction internal gear 130A with a bolt 134A through a bolt hole 132A. The reduction internal gear 130A contributes to the reduction of the rotation of the vibration generator 104 by meshing with the external gear 120A. The inner teeth 128A are shaped to theoretically mesh with the outer teeth 124A based on the trochoid curve.

  On the other hand, the output internal gear 130B is also formed of a rigid member, like the reduction internal gear 130A, as shown in FIG. The output internal gear 130B has the same number of teeth of the internal teeth 128B as the number of teeth of the external teeth 124B of the external gear 120B (constant speed transmission). An output device 138 to which an output from the flexure meshing gear device 100 is transmitted is fixed to the output internal gear 130B with a bolt 134B through a bolt hole 132B.

  In the present embodiment, as shown in FIG. 1, the axial O lengths of the vibration body 104, the roller bearing 110, and the external gear 120 that are radially inward of the internal gear 130 are the same as those of the internal gear 130. First and second regulating members 150 and 152 (described later) are arranged on the radially inner side of the internal gear 130 so as to be shorter than the length in the axial direction O. However, the present invention is not limited to this, and the vibrator, the roller bearing, and the external gear and the internal gear may be the same in the O length in the axial direction.

  Next, the 1st control member 150 (150A, 150B) and the 2nd control member 152 (152A, 152B) are demonstrated in detail using FIG. 1, FIG. 3-FIG.

  The first restricting members 150A and 150B are respectively disposed between the fixed wall 136 disposed on the side of the roller bearings 110A and 110B in the axial direction O, the output device 138 and the bearings 110A and 110B, and the retainers 114A and 114B. The movement in the axial direction O is restricted. And the 1st control member 150 is arrange | positioned at the radial inside of the 2nd control member 152, as shown in FIG. As described above, the first restricting member 150 is a ring-shaped thrust bearing, and includes two race rings and rolling elements sandwiched between the two race rings (the rolling elements may be balls, but rollers (needle). ).

  As shown in FIG. 1, the outer end face 150AA (150BA) of one raceway is adjacent to the end face 114AC (114BC) of the retainer 114A (114B) in the axial direction O with the inner end face 150AB (150BB) of the other raceway. It is fixed to the side surface 136A of the fixed wall 136 (the side surface 138A of the output device 138) so as to be performed (with or without a gap). That is, in the present embodiment, the friction coefficient μ0 between the end surface 114AC of the retainer 114A (the end surface 114BC of the retainer 114B) and the fixed wall 136 (the output device 138) is greater than that of the first restricting member 150A (150B) and the retainer 114A. It can be said that the friction coefficient μ2 between the end surface 114AC and the end surface 114AC is small (μ2 <μ0).

  The second restricting members 152A and 152B are separate from the first restricting member 150, and are disposed between the fixed wall 136, the output device 138, and the external gear 120, and the external gear 120 in the axial direction O. Restricts movement. Then, as shown in FIG. 1, the second restricting members 152A and 152B are respectively arranged on the radially outer side of the first restricting members 150A and 150B and on the radially inner side of the reduction internal gear 130A and the output internal gear 130B. ing. The second restricting members 152A and 152B are low friction members made of resin (PEEK material of low heat resistance polymer resin having low sliding resistance, nylon, fluorine resin, etc.), and has a ring shape. That is, the materials of the first restricting member 150 and the second restricting member 152 are made different.

  As shown in FIG. 1, the outer end face 152AA (152BA) of the second restricting member 152A (152B) has an inner end face 152AB (152BB) of the second restricting member 152A (152B) in the axial direction O and the external gear 120A (120B). ) Of the fixed wall 136 (side surface 138A of the output device 138) so as to be adjacent to the end surface 120AC (120BC) of the outer ring 118A and the end surface 118AC (118BC) of the outer ring 118A (118B). ). The end surfaces 120AC and 120BC of the external gears 120A and 120B and the second regulating members 152A and 152B are larger than the friction coefficient μ3 between the end surfaces 120AC and 120BC of the external gears 120A and 120B and the fixed wall 136 and the output device 138. The friction coefficient μ4 between the two is reduced (μ4 <μ3).

  The second regulating members 152A and 152B may not be fixed to the fixed wall 136 and the output device 138. In this case, the end surfaces 120AC and 120BC of the external gears 120A and 120B, the fixed wall 136, and the output device 138 The friction coefficient μ5 between the second regulating members 152A, 152B, the fixed wall 136, and the output device 138 may be smaller than the friction coefficient μ3 (μ5 <μ3).

  In FIG. 3, an example of the positional relationship of the vibration body 104, the roller bearing 110, the external gear 120, and the 1st, 2nd control members 150 and 152 is shown. Basically, when viewed from the axial direction O, the first restricting member 150 overlaps the retainer 114 at the position of the short axis Y, and the second restricting member 152 is connected to the external gear 120 and the outer ring 118 at the position of the long axis X. They are arranged so as to overlap. The positional relationship of each component will be described more specifically below with reference to FIGS. 4 and 5.

  In the flexure meshing gear device 100, the rotational speed ω1 of the vibrator 104 (including the inner ring 112), the rotational speed ω2 of the retainer 114 of the bearing 110, and the rotational speed ω3 of the external gear 120 (including the outer ring 118). In comparison, the rotational speed ω1 of the vibrator 104 is the fastest, and the rotational speed ω3 of the external gear 120 is the slowest (ω1> ω2> ω3). For this reason, it is most desirable to arrange the first restricting member 150 adjacent to the retainer 114 in the axial direction O so as not to overlap the vibration generator 104 and the external gear 120 in the axial direction O over the entire circumferential direction. At the same time, the second restricting member 152 adjacent to the external gear 120 in the axial direction O is most preferably arranged so as not to overlap the retainer 114 and the internal gear 130 in the axial direction O over the entire circumferential direction. Note that, depending on the design such as the reduction ratio, the relationship between the lengths of the major axis X and the minor axis Y of the vibrator 104 is appropriately changed. For this reason, in this embodiment, the outer diameter R2 of the first regulating member 150 is set to the roller bearing 110 so that the rotation speed ω2 of the retainer 114 of the roller bearing 110 and the rotation speed ω3 of the external gear 120 do not interfere with each other. Is smaller than the minimum inner peripheral diameter Roi of the outer ring 118 (R2 <Roi), and the inner diameter R3 of the second restricting member 152 is larger than the maximum outer diameter Rro of the end surfaces 114AC and 114BC of the retainer 114 (R3> Rro). . As shown in FIG. 4, the minimum inner diameter Roi of the outer ring 118 of the roller bearing 110 is obtained at the position of the short axis Y, and the maximum outer diameter Rro of the end surfaces 114AC and 114BC of the retainer 114 is obtained at the position of the long axis X. It is done.

  Further, at the position of the long axis X, as shown in FIG. 3, the first restricting member 150 may have the largest portion that overlaps the vibration generator 104. For this reason, the inner diameter R1 of the first restricting member 150 is set to a diameter that makes it possible to constitute a thrust bearing that supports a load caused by a skew at a minimum.

  Next, the operation of the flexure meshing gear device 100 will be described with reference to FIG.

  When the vibrator 104 is rotated by the rotation of the input shaft 102, the external gear 120 is bent and deformed via the roller bearing 110 according to the rotation state (that is, the external gear 120B is the same as the external gear 120A). Bends and deforms in phase).

  When the external gear 120 is bent and deformed by the vibrating body 104, the external teeth 124 move radially outward in the meshing range FA and mesh with the internal teeth 128 of the internal gear 130.

  The meshing position between the external gear 120 </ b> A and the reduction internal gear 130 </ b> A rotates as the vibration generator 104 rotates. Here, when the vibrating body 104 rotates once, the rotation phase of the external gear 120A is delayed by a difference in the number of teeth from the internal gear 130A for deceleration. That is, the reduction ratio of the external gear 120A by the reduction internal gear 130A fixed to the fixed wall 136 is ((the number of teeth of the external gear 120A−the number of teeth of the reduction internal gear 130A) / the external gear 120A. (Number of teeth).

  Since both the external gear 120B and the output internal gear 130B have the same number of teeth, the external gear 120B and the output internal gear 130B do not move with each other, and the same teeth can move. Will be engaged. For this reason, the same rotation as the rotation of the external gear 120B (external gear 120A) is output from the output internal gear 130B. As a result, the output device 138 connected to the output internal gear 130B can extract the output obtained by reducing the rotation of the input shaft 102 based on the reduction ratio of the reduction internal gear 130A.

  Thus, in this embodiment, the 1st control member 150 is arrange | positioned between the fixed wall 136, the output device 138, and the bearing 110. FIG. Here, the first regulating member 150 is a thrust bearing. For this reason, the present embodiment can prevent direct sliding between the end surface 114AC of the retainer 114A (the end surface 114BC of the retainer 114B) and the fixed wall 136 (the output device 138). The sliding friction between the end surface 114AC of the retainer 114A (the end surface 114BC of the retainer 114B) and the fixed wall 136 (the output device 138) can be used as the rolling friction of the roller bearing 110. In other words, in the present embodiment, the first regulating member 150 itself is more than the friction coefficient μ0 due to sliding friction between the end surfaces 114AC and 114BC of the retainers 114A and 114B of the roller bearings 110A and 110B and the fixed wall 136 and the output device 138. It can be said that the friction coefficient μ2 between the first regulating members 150A and 150B and the end surfaces 114AC and 114BC of the retainers 114A and 114B is reduced by the rolling friction. That is, even if the roller bearing 110 moves in the axial direction O due to the skew and the retainer 114 collides with the fixed wall 136 and the output device 138 via the first restricting member 150, the first restricting member 150 and the retainer 114 having a small friction coefficient μ2. Will be slid. That is, the end face loss can be reduced as compared with the end face loss caused by the direct sliding between the end faces 114AC and 114BC of the retainers 114A and 114B having a large friction coefficient μ0 and the fixed wall 136 and the output device 138.

  In the present embodiment, a second restriction member 152 that restricts the movement of the external gear 120 in the axial direction O is disposed between the fixed wall 136 and the output device 138 and the external gears 120A and 120B. Yes. The end surfaces 120AC and 120BC of the external gears 120A and 120B and the second regulating members 152A and 152B are larger than the friction coefficient μ3 between the end surfaces 120AC and 120BC of the external gears 120A and 120B and the fixed wall 136 and the output device 138. The friction coefficient μ4 between the two is reduced (μ4 <μ3). Therefore, when the external gear 120 moves in the axial direction O, the external gear 120 does not slide directly against the fixed wall 136 and the output device 138, and the external gear 120 is 2 Slide between the regulating member 152. That is, it is possible to reduce end face loss due to the external gear 120. The outer ring 118 is bent and deformed integrally with the external gear 120. For this reason, end face loss due to the end faces 118AC and 118BC of the outer rings 118A and 118B is also prevented by the second restricting member 152 at the same time.

  The first restricting member 150 and the second restricting member 152 are separated from each other, and the first restricting member 150 and the second restricting member 152 are made of different materials. For this reason, the end surface loss due to the retainer 114 can be reduced by the first restricting member 150 without being affected by the rotational speed ω <b> 3 of the external gear 120. At the same time, the end face loss due to the external gear 120 can be reduced by the second restricting member 152 without being affected by the rotational speed ω <b> 2 of the roller bearing 110. In addition, since the forces applied to the first restricting member 150 and the second restricting member 152 do not affect each other, the life of the first and second restricting members 150 and 152 can be extended.

  In the present embodiment, as described above, the second restricting members 152A and 152B are not fixed to the fixed wall 136 and the output device 138, but are also slid on the fixed wall 136 and the output device 138. It may be. In that case, the fixed wall 136 and the output device 138 may each include a recess (not shown) capable of positioning the second restriction members 152A and 152B. Of course, the second restricting member may be fixed to the external gear.

  Further, in the present embodiment, the outer diameter R2 of the first restricting member 150 is smaller than the minimum inner peripheral diameter Roi of the outer ring 118 of the roller bearing 110, and the inner diameter R3 of the second restricting member 152 is the end surfaces 114AC, 114BC of the retainer 114. Larger than the maximum outer diameter Rro. For this reason, the first regulating member 150 receives the force from the roller bearing 110 and does not receive the force from the external gear 120. On the other hand, the second restriction member 152 receives a force from the external gear 120 and does not receive a force from the roller bearing 110. That is, with such a configuration, it is possible to reliably avoid interference between the rotational speeds ω2 and ω3 of the roller bearing 110 and the external gear 120 via the first and second regulating members 150 and 152. . The shape of the first restricting member and the second restricting member is not limited to this, and can be determined as appropriate.

  In other words, in the present embodiment, it is possible to reduce the end face loss due to the roller bearing 110 caused by the axial movement O of the retainer 114 of the roller bearing 110.

  In the present embodiment, the roller bearings 110A and 110B are a portion that supports the outer teeth 124A and a portion that supports the outer teeth 124B in the axial direction O, respectively. For this reason, the flexure meshing gear device 100 of this embodiment includes the skew of the roller 116B caused by the meshing between the internal gear 130A for deceleration and the external teeth 124A, and the internal gear 130B and external teeth 124B for output. Each of the skews of the rollers 116 </ b> A caused by the meshing can be reduced.

  Although the present invention has been described with reference to the first embodiment, the present invention is not limited to the first embodiment. That is, it goes without saying that improvements and design changes can be made without departing from the scope of the present invention.

  For example, in the first embodiment, the first restricting member 150 is a thrust bearing, and the second restricting member 152 is a low friction member made of a material different from that of the first restricting member 150, but the present invention is limited to this. Not. For example, the first restriction member and the second restriction member may be the same material. For example, the second restricting member may be a thrust bearing, and one raceway ring may be fixed to the fixed wall and the output device. Or it may be like 2nd Embodiment shown in FIG. Since all but the first restricting member 250 is the same as that of the first embodiment, the description of the other than the first restricting member 250 with the same last two digits being the same is omitted.

  In the second embodiment, as shown in FIG. 6, the first restricting member 250 is a low friction member made of the same material as the second restricting member 252. The fixed wall 236 and the output device 238 are provided with a recess (not shown) in which the first restricting member 250 can be positioned. The first restricting member 250 also supports the retainer 214 with respect to the fixed wall 236 and the output device 238. But it is slidable. Then, the friction coefficient μ2 between the end surfaces 214AC, 214BC of the retainer 214 and the first regulating members 250A, 250B is larger than the friction coefficient μ0 between the end surfaces 214AC, 214BC of the retainer 214 and the fixed wall 236, the output device 238. In addition, the friction coefficient μ1 between the first restricting members 250A and 250B, the fixed wall 236, and the output device 238 is reduced (μ1 <μ0, μ2 <μ0). For this reason, this embodiment makes it easier to incorporate the first restricting member 250 and lower the cost compared to the first embodiment, while correspondingly achieving the effects obtained in the first embodiment. The first restricting members 250A and 250B may be fixed to the fixed wall 236 and the output device 238, respectively. Further, the first restricting member 250 may be fixed to the retainer 214. In this case, the coefficient of friction μ1 between the first regulating member 250 and the fixed wall 236 and the output device 238 is greater than the coefficient of friction μ0 between the end surfaces 214AC and 214BC of the retainers 214A and 214B and the fixed wall 236 and the output device 238. Has been made smaller.

  In the above embodiment, the first restriction member and the second restriction member are provided on both sides of the fixed wall side and the output device side. However, only the first restriction member is provided on both sides of the fixed wall side and the output device side. It may be provided. Alternatively, the first restriction member and the second restriction member may be provided only on one side of the fixed wall side and the output device side. Alternatively, the first restricting members (or second restricting members) provided on both sides of the fixed wall side and the output device side may have different configurations (shapes and materials).

  In the above embodiment, the fixed wall, the output device, and the external gear are made of metal and the second restricting member (and the first restricting member 250 of the second embodiment) is made of resin. However, the present invention is not limited to this. For example, if the fixed wall, the output device, and the external gear are ferrous metals, the first and second regulating members may be made of a highly slidable metal mainly composed of copper or aluminum. Alternatively, even if the first and second restricting members are made of the same material as the fixed wall, the output device, and the external gear, the surface treatment and finishing may be different from each other. The magnitude of the friction coefficient can be changed also by such a difference in configuration.

  In the above embodiment, the flexure meshing gear device includes the roller bearing having the inner ring, the retainer, the rolling element, and the outer ring. However, the present invention is not limited to this, and the roller bearing is not necessarily an oscillator. It is not necessary to have an inner ring separate from the outer ring and an outer ring separate from the external gear. For example, the inner ring may be integrated with the vibrator, and the outer ring may be integrated with the external gear.

  Moreover, in the said embodiment, although the 1st, 2nd control member was made into the continuous ring shape, this invention is not limited to this, Even if it is set as the shape intermittently arrange | positioned in the circumferential direction Good.

  Moreover, in the said embodiment, although it was set as the tooth profile based on the trochoid curve for the external tooth, this invention is not limited to this. The external teeth may be arc teeth or other teeth.

  Moreover, in the said embodiment, although the side member was made into the fixed wall and output device which were fixed to the internal gear, this invention is not limited to this, A side member is fixed to the internal gear. There is no need to be, and a member disposed on the side in the axial direction O of the external gear may be widely used as a side member.

  The present invention can be widely applied to a flexure meshing gear device having a roller bearing having a retainer and a cylindrical external gear as essential constituent elements.

DESCRIPTION OF SYMBOLS 100,200 ... Flexure meshing gear apparatus 104,204 ... Vibration body 110,110A, 110B, 210,210A, 210B ... Roller bearing 112,212 ... Inner ring 114,114A, 114B, 214,214A, 214B ... Retainer 118 118A, 118B, 218, 218A, 218B ... Outer ring 120, 120A, 120B, 220, 220A, 220B ... External gears 114AC, 114BC, 118AC, 118BC, 120AC, 120BC, 214AC, 214BC, 218AC, 218BC, 220AC, 220BC ... End faces 124, 124A, 124B, 224, 224A, 224B ... External teeth 128, 128A, 128B, 228, 228A, 228B ... Internal teeth 130, 230 ... Internal gears 130A, 230A ... Internal gears 1 for reduction 0B, 230B ... Internal gears for output 136, 236 ... Fixed walls 136A, 138A, 236A, 238A ... Side surfaces 138, 238 ... Output devices 150, 150A, 150B, 250, 250A, 250B ... First regulating members 152, 152A, 152B, 252, 252A, 252B ... second regulating member 150AA, 150BA, 152AA, 152BA, 250AA, 250BA, 252AA, 252BA ... outer end face 150AB, 150BB, 152AB, 152BB, 250AB, 250BB, 252AB, 252BB ... inner end face

Claims (3)

An exciter, a cylindrical external gear having flexibility that is arranged on the outer periphery of the exciter and is bent and deformed by the rotation of the exciter, and the exciter and the external gear A roller bearing disposed in between, a first internal gear having rigidity with which the external gear internally meshes, and a rigidity with which the external gear is internally meshed with the first internal gear. A flexibly meshing gear device comprising: a second internal gear having
A first restricting member for restricting movement of the retainer of the roller bearing in the axial direction is disposed between the roller bearing and the side member disposed on the axial side of the roller bearing,
The coefficient of friction between the end surface of the retainer and the first restricting member or the coefficient of friction between the end surface of the retainer and the side member is greater than the coefficient of friction between the end surface of the retainer and the side member. The coefficient of friction is reduced,
A second restricting member that restricts movement of the external gear in the axial direction is disposed between the side member and the external gear,
The friction coefficient between the end face of the external gear and the second restricting member, or the friction coefficient between the end face of the external gear and the side member, or the second restricting member and the side member. The coefficient of friction between the
The second restricting member is separate from the first restricting member,
The outer diameter of the first regulating member is smaller than the minimum inner diameter of the outer ring of the roller bearing,
The internal diameter of the said 2nd control member is made larger than the maximum outer diameter of the end surface of the said retainer. The bending meshing type gear apparatus characterized by the above-mentioned. In claim 1 ,
The material of the said 1st control member and the said 2nd control member is made to differ. The bending meshing type gear apparatus characterized by the above-mentioned. In claim 1 or 2 ,
The first engaging member is a thrust bearing. A flexure meshing gear device, wherein:

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