JP2021021468A - Gear device and geared motor - Google Patents

Abstract

To provide a small-sized geared motor having a torque limiter function and a backlash removing function.SOLUTION: A gear device comprises: an output shaft 44 extending in an output axis; a gear set 43 supported movably in the rotating direction and in the axial direction by the output shaft; a flange portion 45 provided on the outer circumferential surface of the output shaft and located on one axial side of the gear set; an elastic member 46 located on the other axial side of the gear set; and an intermediate gear 39 which rotates centered on an intermediate axis parallel to the output axis, and meshes with the gear set to transmit power. Ridge portions 45b and root portions engaging with each other in the axial direction are provided in each of surfaces where the flange portion and the gear set are opposite to each other. The gear set has a pair of gears which are lined up in the axial direction and one of which has the number of teeth more than the other. The pair of gears is relatively rotatable to each other and comes in contact with each other at surfaces where they face each other. The elastic member pushes the ridge portions against the root portion and imparts surface pressure to between the pair of gears.SELECTED DRAWING: Figure 2

Description

The present invention relates to gear devices and geared motors.

In recent years, with the refinement of electronic devices such as smartphones, the development of smaller and more sophisticated geared motors has been promoted. For example, Patent Document 1 discloses a geared motor that suppresses shaft shake of an output shaft.

Japanese Unexamined Patent Publication No. 2011-179607

As an example of improving the performance of a geared motor, a torque limiter function and a backlash removal function may be required. A geared motor that simultaneously satisfies these functions has a problem that the number of parts increases and the size increases.

In view of the above problems, one aspect of the present invention is to provide a gear device and a geared motor having a torque limiter function and a backlash removing function, and capable of suppressing an increase in the number of parts and an increase in size. ..

One aspect of the gear device of the present invention is an output shaft extending along an output axis, a gear set movably supported by the output shaft in the rotational direction and the axial direction, and an outer peripheral surface of the output shaft. A flange portion located on one side in the axial direction of the gear set, an elastic member located on the other side in the axial direction of the gear set, and an intermediate gear that rotates around an intermediate axis parallel to the output axis and transmits power to the gear set. , Equipped with. A mountain portion and a valley portion that mesh with each other in the axial direction are provided on the surfaces of the flange portion and the gear set facing each other. The gear set has a pair of gears that are aligned in the axial direction and one has more teeth than the other. The pair of gears can rotate relative to each other and come into surface contact with each other on facing surfaces. The elastic member presses the peak portion against the valley portion and applies surface pressure between the elastic member and the pair of gears.

According to one aspect of the present invention, there is provided a gear device and a geared motor that have a torque limiter function and a backlash removing function, and can suppress an increase in the number of parts and an increase in size.

FIG. 1 is a perspective view of the geared motor of one embodiment. FIG. 2 is a cross-sectional view of the geared motor of one embodiment. FIG. 3 is an enlarged front view of a part of the output gear mechanism of one embodiment. FIG. 4 is a cross-sectional view showing how the gear set of one embodiment and the intermediate gear are engaged with each other.

Hereinafter, the geared motor according to the embodiment of the present invention will be described with reference to the drawings. The scope of the present invention is not limited to the following embodiments, and can be arbitrarily changed within the scope of the technical idea of the present invention.

In the drawings, the XYZ coordinate system is shown as a three-dimensional Cartesian coordinate system as appropriate. Unless otherwise specified in the following description, the direction parallel to the motor axis J1 and the output axis J4 (Z-axis direction) is simply referred to as "axial direction", the + Z side is simply referred to as one axial direction, and the -Z side is simply referred to as one axial direction. , Simply referred to as the other side in the axial direction.

FIG. 1 is a perspective view of the geared motor 1. FIG. 2 is a cross-sectional view of the geared motor. The geared motor 1 of the present embodiment is mounted on a thin electronic device whose dimensions along the Y-axis direction are suppressed.

As shown in FIG. 2, the geared motor 1 includes a motor 2, a flexible substrate 3, a gear device 5, and a frame 10. Hereinafter, each part of the geared motor 1 will be described in detail.

<Motor>
The motor 2 is, for example, a stepping motor. The motor 2 has a substantially cylindrical motor body 2a centered on the motor axis J1, a motor shaft 2b extending from the other end of the motor body 2a in the axial direction, and a pinion gear 2c.

Inside the motor body 2a, a rotor connected to the motor shaft 2b and a stator surrounding the rotor are provided. Four terminals 2p are provided on the outer peripheral surface of the motor body 2a. The four terminals 2p are connected to the flexible substrate 3.

The motor shaft 2b extends in the axial direction about the motor axis J1. The motor shaft 2b rotates about the motor axis J1. The pinion gear 2c is fixed to the motor shaft 2b. The pinion gear 2c transmits the power of the motor 2 to the drive gear mechanism 20 of the gear device 5.

<Gear device>
The gear device 5 includes a drive gear mechanism 20, an intermediate gear mechanism 30, and an output gear mechanism 40. The drive gear mechanism 20 is arranged around the drive axis J2. The intermediate gear mechanism 30 is arranged around the intermediate axis J3. The output gear mechanism 40 is arranged around the output axis J4. The motor axis J1, the drive axis J2, the intermediate axis J3, and the output axis J4 extend parallel to each other. That is, the motor axis J1, the drive axis J2, and the intermediate axis J3 are parallel to the output axis J4. The motor axis J1, the drive axis J2, the intermediate axis J3, and the output axis J4 are aligned linearly in the X-axis direction when viewed from the axial direction.

(Drive gear mechanism)
The drive gear mechanism 20 has a two-stage gear member 23. The two-stage gear member 23 has a first gear 21 and a second gear 22 arranged side by side along the axial direction. Both the first gear 21 and the second gear 22 are centered on the drive axis J2.

The two-stage gear member 23 is provided with a central hole 23a that penetrates in the axial direction along the drive axis J2. A drive shaft 15 extending from the frame 10 about the drive axis J2 is inserted into the central hole 23a. As a result, the two-stage gear member 23 is rotatably supported by the frame 10 about the drive axis J2. As a result, the plurality of gears (first gear 21 and second gear 22) of the drive gear mechanism 20 rotate about the drive axis J2.

The first gear 21 meshes with the pinion gear 2c. As a result, power is transmitted from the motor 2 to the first gear 21. The second gear 22 is a single member with the first gear 21. Therefore, the second gear 22 rotates together with the first gear 21. The second gear 22 is located on one side in the axial direction with respect to the first gear 21. The second gear 22 is a gear having a smaller diameter than the first gear 21. The second gear 22 is connected to the intermediate gear mechanism 30. The drive gear mechanism 20 decelerates the power of the motor 2 and transmits it to the intermediate gear mechanism 30.

(Intermediate gear mechanism)
The intermediate gear mechanism 30 has a plurality of gears that rotate around the intermediate axis J3. The plurality of gears of the intermediate gear mechanism 30 include a counter gear 31 and an intermediate gear 39. Further, the intermediate gear mechanism 30 has a planetary gear mechanism 32 arranged between the counter gear 31 and the intermediate gear 39 in the axial direction. The counter gear 31 is connected to the other side of the planetary gear mechanism 32 in the axial direction. On the other hand, the intermediate gear 39 is connected to one side in the axial direction of the planetary gear mechanism 32.

The counter gear 31 is centered on the intermediate axis J3. The counter gear 31 meshes with the second gear 22 of the drive gear mechanism 20. The counter gear 31 is provided with a central hole 31a that penetrates in the axial direction along the intermediate axis J3. An intermediate shaft 16 extending from the frame 10 about the intermediate axis J3 is inserted into the central hole 31a. As a result, the counter gear 31 is rotatably supported by the frame 10 about the intermediate axis J3.

The planetary gear mechanism 32 includes a first sun gear 33a, three first planet gears 33b, a first carrier 33c, a second sun gear 34a, three second planet gears 34b, and a second carrier 34c. It has an internal gear 35 and.

The internal gear 35 has a tubular shape extending in the axial direction about the intermediate axis J3. The internal gear 35 meshes with the first planetary gear 33b and the second planetary gear 34b in a gear provided on the inner peripheral surface. The internal gear 35 is fixed to the frame 10 and does not rotate.

The first sun gear 33a is connected to the counter gear 31. The first sun gear 33a is a gear having a smaller diameter than the counter gear 31. The first sun gear 33a rotates about the intermediate axis J3 together with the counter gear 31.

The three first planetary gears 33b are arranged at equal intervals in the circumferential direction of the intermediate axis J3. The three first planetary gears 33b mesh with the first sun gear 33a. The three first planetary gears 33b revolve in the circumferential direction of the intermediate axis J3 as the first sun gear 33a rotates. A through hole 33ba is provided in the center of the first planetary gear 33b.

The first carrier 33c has a disk portion 33cc, three first sub-shafts 33ca, and a first main shaft 33cc. The disk portion 33cc extends in the radial direction about the intermediate axis J3. The three first sub-shafts 33ca extend from the disk portion 33cc to the other side in the axial direction. The three first sub-shafts 33ca are each inserted into the through holes 33ba of the first planetary gear 33b. As a result, the first carrier 33c rotatably supports the first planetary gear 33b on the first sub-shaft 33ca. The first carrier 33c rotates about the intermediate axis J3 as the three first planetary gears 33b revolve around the intermediate axis J3. The first main shaft 33cc extends from the disk portion 33cc to one side in the axial direction about the intermediate axis J3.

The second sun gear 34a is provided on the outer peripheral surface of the first main shaft 33cc. The second sun gear 34a rotates about the intermediate axis J3 together with the first main shaft 33cc.

The three second planetary gears 34b are arranged at equal intervals in the circumferential direction of the intermediate axis J3. The three second planetary gears 34b mesh with the second sun gear 34a. The three second planetary gears 34b revolve in the circumferential direction of the intermediate axis J3 as the second sun gear 34a rotates. A through hole 34ba is provided in the center of the second planetary gear 34b.

The second carrier 34c has a disk portion 34cc, three second sub-shafts 34ca, and a second main shaft 34cc. The disk portion 34cc extends in the radial direction about the intermediate axis J3. The three second sub-shafts 34ca extend from the disk portion 34cc to the other side in the axial direction. The three second subshafts 34ca are each inserted into the through holes 34ba of the second planetary gear 34b. As a result, the second carrier 34c rotatably supports the second planetary gear 34b on the second subshaft 34ca. The second carrier 34c rotates about the intermediate axis J3 as the three second planetary gears 34b revolve around the intermediate axis J3. The second main shaft 34cc extends from the disk portion 34cc to one side in the axial direction about the intermediate axis J3. Further, the tip of the second main shaft 34cc on one side in the axial direction is rotatably supported by the frame 10.

The intermediate gear 39 is provided on the outer peripheral surface of the second main shaft 34cc. The intermediate gear 39 rotates about the intermediate axis J3 together with the second main shaft 34cc. The intermediate gear 39 is connected to the output gear mechanism 40.

The intermediate gear mechanism 30 of the present embodiment transmits the power of the motor 2 transmitted to the counter gear 31 at the other end in the axial direction to the output gear mechanism 40 at the intermediate gear 39 at the end on the other side in the axial direction. The intermediate gear mechanism 30 has a planetary gear mechanism 32 that rotates around the intermediate axis J3. Therefore, the intermediate gear mechanism 30 decelerates the power and transmits the power to the output gear mechanism 40 in the process of transmitting the power of the motor 2. Further, the planetary gear mechanism 32 of the present embodiment has two types of sun gears and planetary gears, and is decelerated in two stages. Therefore, according to the intermediate gear mechanism 30 of the present embodiment, a large reduction ratio can be realized.

(Output gear mechanism)
The output gear mechanism 40 includes an output shaft 44, a flange portion 45, a gear set 43, a coil spring (elastic member) 46, and a pair of ball bearings 49A and 49B. The flange portion 45, the gear set 43, and the coil spring 46 are arranged in this order from one side in the axial direction to the other side. The flange portion 45 is fixed to the output shaft 44. The coil spring 46 presses the gear set 43 against the flange portion 45.

The output shaft 44 extends along the output axis J4. The output shaft 44 has a first end portion 44a located on one side in the axial direction and a second end portion 44b located on the other side in the axial direction. Both ends (first end 44a and second end 44b) of the output shaft 44 are rotatably supported around the output axis J4 by ball bearings 49A and 49B, respectively. The pair of ball bearings 49A and 49B are held by the frame 10. In the following description, of the pair of ball bearings 49A and 49B, one that supports the first end portion 44a is referred to as a first ball bearing 49A, and the other that supports the second end portion 44b is referred to as a second ball bearing 49B. Called.

A flange portion 45 extending radially outward is provided on the outer peripheral surface of the output shaft 44. The flange portion 45 rotates around the output axis J4 together with the output shaft 44. In the present embodiment, the output shaft 44 and the flange portion 45 are a single member. However, the output shaft 44 and the flange portion 45 may be separate members as long as they are fixed to each other.

The flange portion 45 is located on one side of the gear set 43 in the axial direction. The flange portion 45 has a circular shape centered on the output axis J4. The flange portion 45 has a first facing surface 45a facing one side in the axial direction and a second facing surface 45f facing the other side in the axial direction.

The first facing surface 45a is a flat surface orthogonal to the output axis J4. The first facing surface 45a faces the first ball bearing 49A in the axial direction. The first facing surface 45a comes into contact with the inner ring of the first ball bearing 49A.

FIG. 3 is an enlarged front view of a part of the output gear mechanism 40.
The second facing surface 45f faces the gear set 43 in the axial direction. The second facing surface 45f is provided with a plurality of first mountain portions 45b that project to the other side in the axial direction and are lined up along the circumferential direction.

The first mountain portion 45b has a first top surface portion 45ba and a pair of first inclined side portions 45bb located on both sides of the first top surface portion 45ba in the circumferential direction. The first top surface portion 45ba has a planar shape orthogonal to the axis. The first inclined side portion 45bb is inclined to one side in the axial direction, which is separated from the first top surface portion 45ba in the circumferential direction. In the present embodiment, the first inclined side portion 45bb is inclined at 45 ° with respect to the axial direction.

A first valley portion 45c is provided between the first peak portions 45b arranged along the circumferential direction. The first valley portion 45c is a space between the first mountain portions 45b. The first valley portion 45c has a first bottom surface portion 45ca facing the other side in the axial direction. The second facing surface 45f of the flange portion 45 is a wavy surface in which the first top surface portion 45ba, the first inclined side portion 45bb, the first bottom surface portion 45ca, and the first inclined side portion 45bb are alternately arranged along the circumferential direction. ..

As shown in FIG. 2, the gear set 43 has a pair of gears (main gear 41 and sub gear 42). The main gear 41 and the sub gear 42 are separate members from each other. The main gear 41 and the sub gear 42 are arranged along the axial direction. The sub gear 42 has more teeth than the main gear 41. That is, the gear set 43 has a pair of gears (main gear 41 and sub gear 42) on which one has more teeth than the other. The main gear 41 and the sub gear 42 mesh with the intermediate gear 39, respectively. That is, the gear set 43 meshes with the intermediate gear 39. The intermediate gear 39 transmits power to the gear set 43.

The main gear 41 is provided with a through hole 41h penetrating in the axial direction, and the sub gear 42 is provided with a through hole 42h penetrating in the axial direction. The through holes 41h and 42h of the main gear 41 and the sub gear 42 have circular shapes having substantially the same diameter. The output shaft 44 is inserted through the through hole 41h of the main gear 41 and the through hole 42h of the sub gear 42. The diameters of the through holes 41h and 42h of the main gear 41 and the sub gear 42 are slightly larger than the outer diameter of the portion inserted through the through holes 41h and 42h of the output shaft 44. Therefore, the main gear 41 and the sub gear 42 can move in the rotational direction and the axial direction with respect to the output shaft 44. That is, the gear set 43 is movably supported by the output shaft 44 in the rotational and axial directions. Further, the main gear 41 and the sub gear 42 can rotate relative to each other.

The main gear 41 is located on one side of the sub gear 42 in the axial direction. The main gear 41 has a larger tooth width (dimension along the axial direction of the teeth) than the sub gear 42.

The main gear 41 has a third facing surface 41a facing one side in the axial direction and a fourth facing surface 41f facing the other side in the axial direction. The third facing surface 41a faces and contacts the flange portion 45 in the axial direction. On the other hand, the fourth facing surface 41f faces and contacts the sub gear 42 in the axial direction.

As shown in FIG. 3, the third facing surface 41a of the main gear 41 is provided with a wavy surface extending in the circumferential direction similar to the second facing surface 45f of the flange portion 45. That is, the third facing surface 41a is provided with a plurality of second mountain portions 41b that project to one side in the axial direction and are lined up along the circumferential direction.

The second mountain portion 41b has a second top surface portion 41ba and a pair of second inclined side portions 41bb located on both sides of the second top surface portion 41ba in the circumferential direction. The second top surface portion 41ba has a planar shape orthogonal to the axis. The second inclined side portion 41bb is inclined to the other side in the axial direction, which is separated from the second top surface portion 41ba in the circumferential direction. In the present embodiment, the second inclined side portion 41bb is inclined at 45 ° with respect to the axial direction. A second valley portion 41c is provided between the second peak portions 41b arranged along the circumferential direction. The second valley portion 41c has a second bottom surface portion 41ca that faces one side in the axial direction.

The second peak portion 41b and the second valley portion 41c of the third facing surface 41a of the main gear 41 mesh with the first peak portion 45b and the first valley portion 45c of the second facing surface 45f of the flange portion 45. More specifically, the second mountain portion 41b fits into the first valley portion 45c, and the first mountain portion 45b fits into the second valley portion 41c. Along with this, the second inclined side portion 41bb and the first inclined side portion 45bb come into contact with each other.

The flange portion 45 and the peak portions 45b and 41b and the valley portions 45c and 41c of the gear set 43 mesh with each other in the axial direction, so that the gear set 43 and the flange portion 45 rotate synchronously. As a result, the power transmitted to the gear set 43 is transmitted to the output shaft 44 via the flange portion 45.

As described above, the gear set 43 is pressed against the flange portion 45 by the coil spring 46. Therefore, when the gear set 43 rotates, the meshing of the peaks 45b and 41b and the valleys 45c and 41c is maintained, and the rotation of the gear set 43 is transmitted to the flange 45. On the other hand, when the reaction force applied between the first inclined side portion 45bb and the second inclined side portion 41bb becomes large and exceeds a certain value, the first inclined side portion 45bb and the second inclined side portion 41bb become The power transmission between the sliding gear set 43 and the flange portion 45 is cut off from each other.

According to the present embodiment, the ridges 45b, 41b and the valleys 45c, 41c of the flange portion 45 and the gear set 43 are pressed by the coil spring 46 to function as a torque limiter. As a case where the torque limiter function works, for example, when the motor is driven while the output shaft 44 is locked, an excessive rotational force is applied from the output shaft 44 side to the gear set 43 side. According to the present embodiment, even when an excessive load is applied to the output gear mechanism 40, the power transmission is cut off by the torque limiter function, so that the power transmission path from the motor 2 to the intermediate gear mechanism 30 It is possible to suppress an excessive load applied to each part and prevent damage to each part.
In the present embodiment, the first inclined side portion 45bb and the second inclined side portion 41bb facing each other are inclined at 45 ° in opposite directions with respect to the output axis J4. By increasing both of these angles, it is possible to increase the torque threshold value limited by the torque limiter function.

As shown in FIG. 2, the sub gear 42 is located on the other side of the main gear 41 in the axial direction. The sub gear 42 has a fifth facing surface 42a facing one side in the axial direction and a sixth facing surface 42f facing the other side in the axial direction. The fifth facing surface 42a faces and contacts the main gear 41 in the axial direction. On the other hand, the sixth facing surface 42f contacts the end portion of the coil spring 46 on one side in the axial direction in the axial direction.

The fifth facing surface 42a of the sub gear 42 and the fourth facing surface 41f of the main gear 41 are both flat surfaces orthogonal to the output axis J4. The fourth facing surface 41f and the fifth facing surface 42a are in contact with each other, and surface pressure is applied by the coil spring 46. That is, the sub gear 42 and the main gear 41 come into surface contact with each other on the surfaces facing each other.

FIG. 4 is a cross-sectional view showing how the gear set 43 and the intermediate gear 39 are engaged with each other. In FIG. 4, the rotation direction T1 of the gear set 43 and the rotation direction T2 of the intermediate gear are illustrated. In the present embodiment, the number of teeth of the sub gear 42 is one more than the number of teeth of the main gear 41.

The main gear 41 meshes with the intermediate gear 39 and rotates around the output axis J4 as the intermediate gear 39 rotates. At this time, the main gear 41 comes into contact with the intermediate gear 39 on the tooth surface facing the rotation direction T1. On the other hand, since the number of teeth of the sub gear 42 is larger than the number of teeth of the main gear 41, the rotation speed of the sub gear 42 is slower than that of the main gear 41. That is, a difference in rotational speed occurs between the intermediate gear 39 and the sub gear 42 due to the difference in the number of teeth. Further, the sub gear 42 is pressed against the main gear 41 by the coil spring 46, and a frictional force is generated between the fourth facing surface 41f and the fifth facing surface 42a. Then, due to this frictional force and the difference in rotation, the intermediate gear 39 comes into contact with the intermediate gear 39 on the tooth surface facing the opposite side in the rotation direction T1. As a result, backlash is removed between the intermediate gear 39 and the gear set 43. That is, the gear set 43 has a backlash removing function.

As shown in FIG. 2, the coil spring 46 is located on the other side of the gear set 43 in the axial direction. The output shaft 44 is passed through the inner diameter of the coil spring 46. The coil spring 46 presses the gear set 43 against the flange portion 45. In this embodiment, an example in which a coil spring is used as an elastic member for pressing the gear set 43 against the flange portion 45 side will be described, but other springs such as leaf springs and disc springs may be used, and rubber or elastomer resin may be used. And so on.

The coil spring 46 has a coil spring main body 47 and a pair of bush members 48 attached to both ends of the coil spring main body 47.

The bush member includes 48, a bush cylinder portion that fits into the inner diameter portion of the coil spring body 47, and a bush flange that extends radially outward from one end of the bush cylinder portion. One of the pair of bush members 48 located on one side in the axial direction comes into contact with the sixth facing surface 42f of the sub gear 42 at the bush flange. Further, the other of the pair of bush members 48 located on the other side in the axial direction comes into contact with the inner ring of the second ball bearing 49B at the bush flange.

The coil spring 46 is sandwiched between the gear set 43 and the inner ring of the second ball bearing 49B in a compressed state of the coil spring body 47. As a result, the gear set 43 is pressed to one side in the axial direction, and the inner ring of the second ball bearing 49B is pressed to the other side in the axial direction.

The coil spring 46 presses the peaks 41b and 45b of the main gear 41 and the flange 45 against the valleys 41c and 45c, and applies surface pressure between the main gear 41 and the sub gear 42. That is, the compressive force of the coil spring 46 is used for the torque limiter function and the backlash removing function. According to the present embodiment, one coil spring 46 can be used to obtain a torque limiter function and a backlash removing function, and it is possible to reduce the number of parts, reduce costs, and reduce the size of the gear device 5. it can.

According to this embodiment, the coil spring 46 presses the output shaft 44 against the frame 10 on one side in the axial direction. Therefore, the coil spring 46 can remove the backlash in the axial direction of the output shaft 44.

In the present embodiment, both ends of the output shaft 44 are supported by the first ball bearing 49A and the second ball bearing 49B. Further, the coil spring 46 presses the inner ring of the first ball bearing 49A to one side in the axial direction via the gear set 43. The coil spring 46 presses the inner ring of the second ball bearing 49B to the other side in the axial direction. That is, the coil spring 46 presses the inner rings of the pair of ball bearings 49A and 49B in the directions away from each other to apply a preload, and makes the ball bearings 49A and 49B realize smooth rotation.

<Frame>
As shown in FIG. 1, the frame 10 has a first frame member 11 and a second frame member 12. The first frame member 11 and the second frame member 12 are molded by, for example, metal powder injection molding (MIM). The first frame member 11 and the second frame member 12 are fixed to the motor body 2a. The first frame member 11 is located on one side in the axial direction with respect to the motor 2. On the other hand, the second frame member 12 is located on the other side in the axial direction with respect to the motor 2.

The first frame member 11 includes a motor support portion 11a, an intermediate gear mechanism support portion 11b, a first output shaft support portion 11c, and a fixing portion 13.

The motor support portion 11a has a disk shape that covers one end of the motor body 2a in the axial direction. A welded portion 9 is provided at the boundary between the motor support portion 11a and the motor main body 2a. As a result, the first frame member 11 is welded and fixed to the motor body 2a at the welded portion 9. More specifically, the first frame member 11 is welded and fixed to one end of the motor body 2a on one side in the axial direction.

The intermediate gear mechanism support portion 11b is located on one side in the axial direction of the intermediate gear mechanism 30. The intermediate gear mechanism support portion 11b has a tubular portion 11ba and a bottom portion 11bb located at one end of the tubular portion 11ba in the axial direction.

The tubular portion 11ba is connected to the motor support portion 11a at the other end in the axial direction. The tubular portion 11ba surrounds the intermediate gear 39 from the radial outside of the intermediate axis J3. The tubular portion 11ba is provided with a notch portion 11bc. The notch portion 11bc is located at a portion where the intermediate gear 39 and the gear set 43 mesh with each other.

As shown in FIG. 2, a holding hole 11bd is provided on the bottom surface of the bottom portion 11bb facing the other side in the axial direction. The second main shaft 34cc of the intermediate gear mechanism 30 is inserted into the holding hole 11bd. As a result, the intermediate gear mechanism support portion 11b supports the end portion of the intermediate gear mechanism 30 on one side in the axial direction.

The first output shaft support portion 11c holds the first ball bearing 49A of the output gear mechanism 40. The first output shaft support portion 11c supports the output shaft 44 via the first ball bearing 49A. The first output shaft support portion 11c has a surrounding cylinder portion 11ca that surrounds the outer ring of the first ball bearing 49A from the outside in the radial direction, and a top plate portion 11cc that extends radially inward from the upper end portion of the surrounding cylinder portion 11ca. The top plate portion 11cc is provided with an insertion hole 11cc through which an end portion on one side in the axial direction of the output shaft 44 is inserted. The output shaft 44 is connected to an external device (not shown) at the tip that has passed through the insertion hole 11cc.

As shown in FIG. 1, the fixing portion 13 has a plate shape extending along the XZ plane. The fixing portion 13 is connected to a surface of the motor support portion 11a facing one side in the axial direction. Further, the fixing portion 13 is connected to the outer peripheral surface of the tubular portion 11ba of the intermediate gear mechanism support portion 11b. The fixing portion 13 is provided with two fixing holes 13a penetrating in the plate thickness direction. The two fixing holes 13a are arranged along the radial direction of the output axis J4. Fixing screws for fixing the geared motor 1 to an external member (not shown) are inserted into the two fixing holes 13a.

According to the present embodiment, the first frame member 11 has a fixing portion 13 for fixing to the external member, and supports the output end 44p of the output shaft 44 that transmits power to the external device. That is, the first frame member 11 supports the output shaft 44 and is fixed to the external member in a single member. Therefore, the position accuracy of the output end 44p of the output shaft 44 with respect to the external member can be improved, and the power of the motor 2 can be efficiently transmitted to the external device.

According to the present embodiment, the first frame member 11 is fixed to the other end of the motor body 2a in the axial direction, supports the drive gear mechanism 20, and has the other end of the intermediate gear mechanism 30 in the axial direction. It supports and supports the other end of the output shaft 44 in the axial direction. That is, the first frame member 11 can support each axis of the geared motor 1 from the other side in the axial direction by a single member, can maintain the distance between the axes of the gears with high accuracy, and can rotate the gears efficiently. Can be enhanced.

According to this embodiment, the motor axis J1, the drive axis J2, the intermediate axis J3, and the output axis J4 are aligned linearly when viewed from the axial direction. That is, the shafts of the geared motor 1 are arranged side by side in one direction, and the geared motor 1 having a miniaturized dimension in the Y-axis direction can be provided. Therefore, according to the present embodiment, it is possible to provide a geared motor 1 that can be mounted in a thin crisis such as a smartphone.

Further, according to the present embodiment, the first frame member 11 is fixed to the end on one side in the axial direction of the motor body 2a, supports the end on one side in the axial direction of the intermediate gear mechanism 30, and the output shaft 44. Supports one end in the axial direction, which is the output end of. That is, the first frame member 11 can support each axis of the geared motor 1 from one side in the axial direction by a single member, can maintain the distance between the axes of the gears with high accuracy, and can rotate the gears efficiently. Can be enhanced.

The second frame member 12 has a gear case 12a, a second output shaft support portion 12c, and a pair of beam portions 14.

The gear case 12a has a disk shape that covers the end of the motor body 2a on the other side in the axial direction, the drive gear mechanism 20, and the end of the intermediate gear mechanism 30 on the other side in the axial direction. The gear case 12a has a bale-shaped plate portion 12aa that is orthogonal to the axial direction, and an outer wall portion 12ab that extends from the outer edge of the plate portion 12aa to one side in the axial direction. The plate portion 12aa and the outer wall portion 12ab cover the ends of the pinion gear 2c, the drive gear mechanism 20, and the intermediate gear mechanism 30 on the opposite side in the axial direction.

A welded portion 9 is provided at the boundary between the gear case 12a and the motor body 2a. As a result, the second frame member 12 is welded and fixed to the motor body 2a at the welded portion 9. More specifically, the second frame member 12 is welded and fixed to the other end of the motor body 2a in the axial direction.

As shown in FIG. 3, the gear case 12a is located on the other side of the drive gear mechanism 20 and the intermediate gear mechanism 30 in the axial direction. A drive shaft 15 and an intermediate shaft 16 are provided on the bottom surface of the plate portion 12aa facing one side in the axial direction. The drive shaft 15 extends in the axial direction about the drive axis J2. The drive shaft 15 rotatably supports the two-stage gear member 23 of the drive gear mechanism 20. Similarly, the intermediate shaft 16 extends axially about the intermediate axis J3. The intermediate shaft 16 rotatably supports the counter gear 31 of the intermediate gear mechanism 30.

The second output shaft support portion 12c holds the second ball bearing 49B of the output gear mechanism 40. The second output shaft support portion 12c supports the output shaft 44 via the second ball bearing 49B. The second output shaft support portion 12c has a surrounding cylinder portion 12ca that surrounds the outer ring of the second ball bearing 49B from the outside in the radial direction, and a top plate portion 12cc that extends radially inward from the upper end portion of the surrounding cylinder portion 12ca.

As shown in FIG. 1, the beam portion 14 extends from the outer wall portion 12ab of the gear case 12a to one side in the axial direction. The beam portion 14 is located between the motor main body 2a and the planetary gear mechanism 32. A welded portion 9 is provided at a boundary portion between an end portion of the beam portion 14 on one side in the axial direction and the first frame member 11. As a result, one end of the beam portion 14 in the axial direction is welded and fixed to the first frame member 11.

According to this embodiment, the first frame member 11 is welded and fixed to the motor body 2a. Therefore, the first frame member 11 and the motor body 2a are firmly fixed, the stability of each shaft with respect to the motor 2 is enhanced, and the power transmission efficiency can be enhanced. Similarly, according to the present embodiment, the second frame member 12 is welded and fixed to the motor body 2a. Therefore, the power transmission efficiency of the motor 2 can be improved.

According to the present embodiment, the first frame member 11 and the second frame member 12 are welded to each other via the beam portion 14. Therefore, it is possible to prevent both ends of each axis in the axial direction from being displaced from each other. In the present embodiment, the second frame member 12 has the beam portion 14, but the first frame member 11 may have the beam portion 14. That is, any one of the first frame member 11 and the second frame member 12 may have a beam portion 14 that extends to the other side along the axial direction and is welded and fixed to the other side.

Although the embodiments and modifications of the present invention have been described above, the configurations and combinations thereof in the embodiments are examples, and the configurations are added, omitted, replaced, and the like without departing from the spirit of the present invention. Other changes are possible. Moreover, the present invention is not limited to the embodiments.

1 ... Geared motor, 2 ... Motor, 2a ... Motor body, 2b ... Motor shaft, 2c ... Pinion gear, 5 ... Gear device, 10 ... Frame, 11 ... First frame member, 12 ... Second frame member, 13 ... Fixed part, 14 ... Beam part, 20 ... Drive gear mechanism, 30 ... Intermediate gear mechanism, 32 ... Planetary gear mechanism, 39 ... Intermediate gear, 41b, 45b ... Mountain part, 41c, 45c ... Tani part, 41 ... Main gear, 42 ... Sub gear, 43 ... Gear set, 44 ... Output shaft, 44p ... Output end, 45 ... Flange, 46 ... Coil spring, 46 ... Coil spring (elastic member), 49A ... Ball bearing, J1 ... Motor axis, J2 ... Drive axis, J3 ... Intermediate axis , J4 ... Output axis

Claims (13)

An output shaft that extends along the output axis and
A gear set that is supported by the output shaft so that it can move in the rotational and axial directions,
A flange portion provided on the outer peripheral surface of the output shaft and located on one side in the axial direction of the gear set, and
An elastic member located on the other side in the axial direction of the gear set,
An intermediate gear that rotates around an intermediate axis parallel to the output axis and transmits power by engaging with the gear set is provided.
On the surfaces where the flange portion and the gear set face each other, peaks and valleys that mesh with each other in the axial direction are provided.
The gear set has a pair of gears aligned in the axial direction, one with more teeth than the other.
The pair of gears can rotate relative to each other and come into surface contact with each other on facing surfaces.
The elastic member presses the peak portion against the valley portion and applies surface pressure between the elastic member and the pair of gears.
Gear device. Both ends of the output shaft are supported by ball bearings, respectively.
The gear device according to claim 1. The elastic member presses the inner rings of the pair of ball bearings in a direction away from each other.
The gear device according to claim 2. An intermediate gear mechanism including the intermediate gear and having a plurality of gears rotating around the intermediate axis.
It has a drive gear mechanism having a plurality of gears rotating about a drive axis parallel to the output axis and transmitting power to the intermediate gear mechanism.
The gear device according to any one of claims 1 to 3. The intermediate gear mechanism has a planetary gear mechanism that rotates around the intermediate axis.
The gear device according to claim 4. The gear device according to claim 4 or 5.
A motor body, a motor shaft extending from the motor body and rotating about a motor axis parallel to the output axis, and a motor having a pinion gear fixed to the motor shaft and transmitting power to the drive gear mechanism.
Geared motor. The motor axis, the drive axis, the intermediate axis, and the output axis are aligned linearly when viewed from the axial direction.
The geared motor according to claim 6. It has a first frame member fixed to the motor body, and has
The first frame member has a fixing portion for fixing to the external member and supports the output end of the output shaft that transmits power to the external device.
The geared motor according to claim 6 or 7. The first frame member is
It is fixed to one end of the motor body in the axial direction and
Supporting one end of the intermediate gear mechanism in the axial direction,
Supports one end in the axial direction, which is the output end of the output shaft.
The geared motor according to claim 8. The first frame member is welded and fixed to the motor body.
The geared motor according to claim 8 or 9. Has a second frame member
The second frame member is
It is fixed to the other end of the motor body in the axial direction.
Supporting the drive gear mechanism,
Supporting the other end of the intermediate gear mechanism in the axial direction,
Supports the other end of the output shaft in the axial direction.
The geared motor according to any one of claims 8 to 10. The second frame member is welded and fixed to the motor body.
The geared motor according to claim 11. One of the first frame member and the second frame member has a beam portion extending to the other side along the axial direction and welded and fixed to the other side.
The geared motor according to claim 11 or 12.

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