JP2009222222A - Worm reduction gear, revolvable camera using the same and radio wave receiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a worm reduction gear, a revolvable camera using the same and a radio wave receiver, capable of increasing accuracy in controlling a rotation angle of a worm wheel, by regulating movement in the axial direction of a motor shaft coaxially fixed with a worm. <P>SOLUTION: This worm reduction gear 1A has a motor 10, the worm 20 having the extending end side of the motor shaft 13 coaxially fixed to one end and rotatively driven by the motor 10 and the worm wheel 26 meshing with the worm 20, and has a member inserting wall 30 having a clearance between the other end of the worm 20 and itself and forming a through-hole 30a having the hole center positioned on the axis of the worm 20, a pressing member 31A slidably inserted in the axial direction of the worm 20 into the through-hole 30a, and a coil spring 34 for energizing the pressing member 31A to the worm 20 side and pressing the other end of the worm 20 to one end side via the pressing member 31A. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a worm speed reducer that can control the rotation angle of a driven gear that rotates in conjunction with the rotation of a worm, a swivel camera using the same, and a radio wave receiver.

  A conventional small motor with a worm speed reducer has a worm speed reducer attached to a motor portion. The worm speed reducer includes a worm coaxially attached to the motor shaft of the motor unit, and a worm wheel meshed with the worm and disposed so as to be rotatable about an axis orthogonal to the worm axis ( For example, see Patent Document 1).

JP-A-11-332177

  Although not described in detail in Patent Document 1, in a conventional small motor with a worm speed reducer, the motor shaft is rotatably supported by a bearing fixed to a case of a conventional small motor with a worm speed reducer. Is common. At this time, the movement of the motor shaft in the axial direction is not completely restricted, and when the motor shaft receives a force in the axial direction, the motor shaft is displaced in the axial direction.

  If the motor shaft is displaced in the axial direction while rotating the worm wheel, the worm attached to the motor shaft also moves in the axial direction. That is, the rotation angle resulting from the movement amount of the worm in the axial direction is added to the position where the worm wheel is rotated by a predetermined angle. Therefore, the accuracy of control of the rotation angle of the worm wheel is deteriorated.

  The present invention has been made to solve the above-described problem, and by controlling the movement of the motor shaft, in which the worm is coaxially fixed, in the axial direction, the accuracy of controlling the rotation angle of the worm wheel is increased. An object of the present invention is to obtain a worm speed reducer capable of rotating, a turning type camera using the same, and a radio wave receiving apparatus.

  The present invention provides a worm speed reducer comprising a motor, a worm having an extension end side of a motor shaft coaxially fixed at one end, and a driven gear meshing with the worm, and a gap is provided between the other end of the worm. A support member formed with a through hole in which the hole center is located on the axis of the worm, a pressing member inserted into the through hole so as to be slidable in the axial direction of the worm, and the pressing member on the worm side And a biasing means for pressing the other end of the worm to the one end side through the pressing member.

  According to the present invention, since the movement of the motor shaft, in which the worm is coaxially fixed, is restricted in the axial direction, the accuracy of control of the rotation angle of the driven gear can be increased.

The best mode for carrying out the present invention will be described below with reference to the drawings.
Embodiment 1 FIG.
1 is a perspective view of a worm reducer according to Embodiment 1 of the present invention, FIG. 2 is a plan view of the worm reducer according to Embodiment 1 of the present invention, and FIG. 3 is according to Embodiment 1 of the present invention. 4 is a front view of the worm reducer, FIG. 4 is a sectional view taken along arrow IV-IV in FIG. 3, and FIG. 5 is an enlarged view around the meshing portion of the worm reducer according to Embodiment 1 of the present invention. 6 is a system configuration diagram of the worm reduction gear according to Embodiment 1 of the present invention.

  1 to 6, a worm speed reducer 1 </ b> A includes a motor 10, a motor holder 2 that supports the motor 10, and one end of the motor shaft 13 that is coaxially fixed to the extending end of the motor shaft 13 by press-fitting. And a driven gear that is meshed with the worm 20 and is rotatably arranged around the driven shaft 25 whose axial direction is perpendicular to the axial direction of the worm 20 in conjunction with the rotation of the worm 20. The member insertion wall 30 as a support member is provided so as to face the other end in the axial direction of the worm 20 and has a through hole 30 a in which the hole center is located on the axial center of the worm 20. And. Further, the worm speed reducer 1A is inserted into the through hole 30a, and is provided with a pressing member 31A disposed so as to be in contact with the other end of the worm 20, and an urging unit that presses the pressing member 31A toward the other end of the worm 20. And a control device 40 that controls the drive of the motor 10 so as to rotate the worm wheel 26 by a command angle.

  The motor holder 2 has a rectangular flat base 3 and a motor support wall 4 extending perpendicularly to the base 3 from one short side of the base 3. A notch 4a is formed so as to open at an extension end of the motor support wall 4 from the base 3.

  The motor 10 is, for example, a stepping motor, and includes a case 11 and a motor shaft 13 that is rotatably supported around a shaft by a pair of bearings 12 fixed to both ends of the case 11. One end surface of one bearing 12 is exposed from the case 11, and the other end surface is disposed in the case 11. Further, one end surface of the other bearing 12 is disposed in the case 11, and the other end surface is exposed from the case 11.

  Further, the attachment portion 14 is formed integrally with the case 11 so as to protrude outside the case 11. The mounting portion 14 is fixed to one surface of the motor support wall 4 located on both sides of the notch 4 a, and the case 11 is supported by the motor support wall 4. The other end (extension end) side of the motor shaft 13 supported at one bearing 12 on one end side is extended to the outside of the case 11 and inserted into the notch 4a. A predetermined length extends from the other surface in the vertical direction.

  The member insertion wall 30 extends from the other short side of the base 3 so that one surface thereof faces the other surface of the motor support wall 4. Further, the through hole 30 a is formed in the member insertion wall 30 so that the hole direction coincides with the axial direction of the worm 20 and the hole center is located on the axial center of the worm 20. At this time, the member insertion wall 30 is disposed with a gap between the other end of the worm 20.

  Next, details of the worm 20 will be described. As shown in FIG. 5, the worm 20 includes a worm main body 21 having a shape in which a helical tooth portion 21 a is formed on the outer peripheral surface of a cylinder having a predetermined diameter, and one axial direction of the worm main body 21. A cylindrical small diameter portion 22a is coaxially connected to the worm main body portion 21 so that the diameter of the end surface is reduced stepwise. Furthermore, the worm 20 has a cylindrical press-fit portion 23 that is coaxially connected to the small diameter portion 22a so as to increase in diameter in a step shape at one end in the axial direction of the small diameter portion 22a, and the axial direction of the worm main body portion 21. On the other end side, there is a column-shaped pressed portion 24 that is coaxially connected to the worm main body portion 21 so that the diameter decreases stepwise. The other end side of the motor shaft 13 is press-fitted coaxially into the press-fit portion 23.

  Further, a conical contact groove 24 a is formed so as to open on the other end surface of the pressed part 24. At this time, the contact groove 24 a is formed such that the axial direction thereof coincides with the axial direction of the pressed part 24 and the apex of the cone is arranged at a predetermined distance from the other end surface of the pressed part 24.

  Further, the bottomed cylindrical closing member 35 faces the member insertion wall 30 so that its opening faces the other surface of the member insertion wall 30 and surrounds the opening edge portion of the through hole 30a formed on the other surface. It is fixed. The wall that forms the bottom of the closing member 35 is referred to as a fixed wall 35a. That is, the fixed wall 35 a is disposed so as to face the other surface of the member insertion wall 30.

Furthermore, the pressing member 31A has a so-called bullet shape that is processed so that the shape of one end side of the cylinder is an R-shaped curved surface that is convex toward the opposite side to the other end in the axial direction. Yes.
Then, the pressing member 31A faces the through hole 30a so that the contact portion 31a formed of an R-shaped curved surface faces the worm 20 and the axial direction of the pressing member 31A coincides with the hole direction of the through hole 30a. It is inserted in the loose fit state. At this time, the gap between the wall surface of the through hole 30a and the outer peripheral surface of the pressing member 31A is small, and the pressing member 31A can slide in the axial direction of the worm 20 with respect to the through hole 30a. .

  The coil spring 34 is contracted between the other end surface of the pressing member 31A and the fixed wall 35a. Thereby, the pressing member 31A moves to the pressed portion 24 side by the urging force of the coil spring 34, and comes into contact with the contact groove 24a in a pressed state. In other words, the coil spring 34 urges the pressing member 31A toward the worm 20 and presses the other end of the worm 20 toward one end via the pressing member 31A.

  The worm wheel 26 is press-fitted coaxially to a driven shaft 25 that is rotatably disposed around the shaft. Further, as shown in FIG. 5, the worm wheel 26 has teeth 26a formed on the outer peripheral surface thereof at a predetermined pitch in the circumferential direction. Further, the worm wheel 26 is arranged such that the axial center direction of the worm wheel 26 (driven shaft 25) is orthogonal to the axial center direction of the worm 20 and the tooth portion 26a meshes with the tooth portion 21a of the worm main body portion 21. Has been placed.

At this time, the distance between the shaft centers of the worm 20 and the worm wheel 26 is such that when the respective tooth portions 21a and 26a of the worm 20 and the worm wheel 26 are engaged with each other, a predetermined amount of backlash is generated between the tooth portions 21a. , 26a, the distance L1 is set.
As a result, the worm wheel 26 is smoothly rotated around the axis of the driven shaft 25 in conjunction with the rotation of the worm 20 around the axis.

Further, the control device 40 is a motor drive circuit disposed so as to be able to input a signal from the calculation unit 41 and a signal from the calculation unit 41 and to output an output based on the input signal from the calculation unit 41 to the motor 10. 45.
The calculation unit 41 includes a CPU 42 that performs various calculations, a RAM 43 that is used as a working area when the CPU 42 performs calculations, and a program that causes the CPU to perform predetermined calculations. It has a stored ROM 44 and the like. And the calculating part 41 has a communication interface (not shown). For example, by connecting a command device 46 such as a notebook computer to the calculation unit 41, it is possible to transmit an angle designation signal for designating the rotation angle of the worm wheel 26 from the command device 46 to the calculation unit 41.

  As described above, the motor 10 is a stepping motor, and includes a rotor having a permanent magnet (not shown) and a stator having a plurality of phase motor coils (not shown). The angular speed of the motor shaft 13 can be controlled by a pattern of pulse currents flowing through motor coils (not shown) of each phase provided in the motor 10.

  And the control apparatus 40 is producing | generating the pattern of the pulse current sent through a motor coil based on an angle designation signal. That is, the calculation unit 41 sets a command pattern of the angular velocity of the motor shaft 13 for rotating the worm wheel 26 by the rotation angle (command angle) of the worm wheel 26 designated by the angle designation signal. A command pulse is generated based on the command pattern and output to the motor drive circuit 45. The angular velocity command pattern of the motor shaft 13 defines the time change of the angular velocity of the motor shaft 13. The angular velocity pattern of the worm 20 that rotates together with the motor shaft 13 is the same as the angular velocity pattern of the motor shaft 13. Match. A command pulse corresponding to the angular velocity command pattern of the motor shaft 13 is input to the motor drive circuit 45, and a pulse current pattern is generated by the motor drive circuit 45 based on the command pulse.

  When the motor shaft 13 rotates, the worm 20 into which the motor shaft 13 is press-fitted is rotated by the same angle as the rotation angle of the motor shaft 13, and the worm wheel 26 is rotated by a predetermined ratio with respect to the rotation angle of the worm 20. It is decelerated and rotates. Thereby, the control device 40 can control the rotation angle of the worm wheel 26. Note that when the reduction ratio γ (<1) is the rotation angle of the worm wheel 26 / the rotation angle of the worm 20, the reduction ratio γ is set to about 1/40, for example.

  Here, as described above, the motor shaft 13 is supported by the pair of bearings 12 fixed to the case 11 so as to be rotatable around the shaft. At this time, although the motor shaft 13 is restricted from moving in the axial direction so as not to come off the bearing 12, it does not completely restrict the movement of the motor shaft 13 in the axial direction. That is, a play that allows the motor shaft 13 to move by a predetermined amount is formed in the axial direction of the motor shaft 13.

However, as described above, the other end side (the pressed portion 24) of the worm 20 is pressed against the pressing member 31 </ b> A by the biasing force of the coil spring 34 toward one end side (the press-fit portion 23 side) of the worm 20. . Therefore, the other end of the motor shaft 13 press-fitted into the press-fitting portion 23 is pressed against one end side of the motor shaft 13, and the motor shaft 13 is restricted from moving in the axial direction.
Moreover, the shape of the contact part of the contact part 31a and the contact groove 24a corresponds to the outer edge of a circle with a predetermined radius. That is, since the contact area between the contact portion 31a and the contact groove 24a is small, the rotation of the motor shaft 13 is not hindered by friction between the contact portion 31a and the contact portion of the contact groove 24a.
The motor shaft 13 is restricted from moving in the axial direction.

According to the first embodiment, since the movement of the motor shaft 13 in the axial direction is restricted, the movement of the worm 20 in the axial direction is also restricted.
Therefore, the accuracy of control of the rotation angle of the worm wheel 26 can be increased.

  In the first embodiment, the elastic member is described as being the coil spring 34. However, the elastic member is not limited to the coil spring 34, and the pressing member 31A is pressed toward the worm 20 side. An arranged leaf spring may be used.

  In addition, the fixed wall 35a has been described as being configured by the bottom of the closing member 35 fixed to the member insertion wall 30, but the fixed wall 35a is a wall in which the coil spring 34 can be contracted between the pressing member 31A. If so, the shape is not particularly limited.

  Further, when the pressing member 31A rotates around its axis due to friction between the contact portion 31a of the pressing member 31A and the contact groove 24a of the worm 20, the rotation around the axis of the pressing member 31A is suppressed as follows. That's fine. That is, on the pressing member 31A, a protruding portion (not shown) protruding in the radial direction from the outer peripheral surface of the pressing member 31A is formed so as to have a predetermined length in the axial direction, and on the inner wall of the through hole 30a, A fitting groove that can be fitted with the protruding portion without a substantial gap is formed in the entire direction along the through hole 30a. Then, the protruding portion and the fitting groove are fitted, and the pressing member 31A is inserted through the through hole 30a. Accordingly, the rotation of the pressing member 31A around the axis is restricted while the pressing member 31A is slidable in the direction along the through hole 30a (the axial center direction of the worm 20).

  In Embodiment 1 described above, the pressing member 31A has been described as using a cylinder whose one end is processed into an R shape. However, the pressing member 31A is not limited to this, and the shape of the pressing member 31A is as follows. The contact area between the contact portion 31a and the contact groove 24a is small, so long as the pressed portion 24 is pressed against one end of the worm 20 without obstructing the rotation of the motor shaft 13 around the axis. . For example, the pressing member may have a shape as in the first embodiment shown in FIG.

In FIG. 7, the pressing member 31 </ b> B includes a flat cylindrical mounting seat 32 and a sphere 33 fixed to the central portion of one end surface of the mounting seat 32.
The pressing member 31B is arranged in a state where the ball 33 is directed to the contact groove 24a, the axial direction of the mounting seat 32 is made to coincide with the axial direction of the through hole 30a, and the mounting seat 32 is inserted into the through hole 30a. .
Thereby, the shape of the contact part of the ball | bowl 33 and the contact groove 24a corresponds with the outer edge of the circle | round | yen of predetermined radius. That is, since the contact area between the sphere 33 and the contact groove 24a is small, the rotation of the motor shaft 13 is not hindered by friction between the sphere 33 and the contact portion of the contact groove 24a. Movement in the axial direction is restricted.

Thus, also in the first embodiment, since the movement of the motor shaft 13 in the axial direction is restricted, the worm 20 is restricted from moving in the axial direction in conjunction with the driving of the motor 10.
Therefore, the accuracy of control of the rotation angle of the worm wheel 26 can be increased.

Embodiment 2. FIG.
FIG. 8 is an enlarged view showing a meshed state of the worm body portion of the worm reduction gear according to the second embodiment of the present invention and the tooth portion of the worm wheel.
In FIG. 8, the same or corresponding parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
In FIG. 8, in the worm speed reducer 1B, the small diameter portion 22b of the worm 20 is made of an elastic resin such as polyacetal (POM). Further, the distance L2 between the axis of the worm 20 and the axis of the worm wheel 26 is set to be smaller than the distance L1 in the worm reduction gear 1A. That is, when the backlash between the meshed worm body 21 and the tooth portion 21a of the worm wheel 26 and the tooth portion 26a is compared between the worm reducer 1A and the worm reducer 1B, the worm reducer 1B Is getting smaller.
Other configurations are the same as those in the first embodiment.

  Since the backlash between the meshed tooth portion 21a and the tooth portion 26a is reduced, depending on the rotation angle of the worm 20, the tooth portion 21a and the tooth portion 26a approach each other so that the worm 20 is engaged with the worm wheel 26. It may be pressed with great force. Also, if the axis of the driven shaft 25 does not coincide with the axis of the worm wheel 26, or when the tooth portion 26a of the worm wheel 26 is formed, the dimension is slightly larger than the prescribed dimension. In addition, the worm 20 is pressed with a large force from the worm wheel 26 according to the rotation angle.

  Here, the backlash is a factor that deteriorates the accuracy of the control of the rotation angle of the worm wheel 26, so it is preferable to make it as small as possible. However, when the entire worm 20 is made of a material having rigidity, such as iron or stainless steel, if the backlash is made too small, the tooth portion 21a and the tooth portion 26a are engaged with each other, and the worm 20 and the worm wheel 26 Smooth rotation is hindered.

  On the other hand, the narrow diameter portion 22b of the worm 20 of this embodiment is formed on the one end side of the worm main body 21 so as to have a smaller diameter than the worm main body 21 by an elastic resin. That is, the small diameter portion 22 b is elastically deformed so as to separate the worm main body portion 21 from the worm wheel 26 according to the pressing force applied from the worm wheel 26 to the worm main body portion 21, and is added to the worm main body portion 21. It is configured to reduce the pressing force. Therefore, even when the worm 20 receives a large pressing force from the worm wheel 26, the worm 20 and the worm wheel 26 rotate smoothly while maintaining a state in which the backlash is reduced.

According to the second embodiment, since the small-diameter portion 22b is formed of a resin having elasticity, the worm 20 and the worm wheel 26 can be smoothly rotated in a state where the backlash is kept small.
Therefore, the control accuracy of the rotation angle of the worm wheel 26 can be further improved than in the first embodiment.

  In the second embodiment, the worm 20 has been described as having only the small-diameter portion 22b formed of an elastic resin. However, the worm 20 may be partially formed of resin including the small-diameter portion 22b. All of them may be made of resin.

Embodiment 3 FIG.
FIG. 9 is a sectional view of a worm reduction gear according to Embodiment 3 of the present invention.
In FIG. 9, the same or corresponding parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
In the worm speed reducer 1C, the small-diameter portion 22c is made of an elastic resin such as POM. And the small diameter part 22c is comprised so that a diameter may become small gradually as it goes to the center from the both ends of an axial direction.
Other configurations are the same as those of the first embodiment.

The effect of processing the shape of the small diameter portion 22c as described above will be described.
When the diameter of the small-diameter portion 22b is the same cylindrical shape throughout the entire axial direction as in the above-described small-diameter portion 22b, the force received from the worm wheel 26 by the worm 20 changes in diameter in a step shape. It concentrates on the connection site | part of the outer peripheral surface of the one end side of the thin diameter part 22b, and the other end surface of the press-fit part 23, or the connection site | part of the outer peripheral surface of the other end side of the small diameter part 22b, and the one end surface of the worm main body part 21.

  On the other hand, in the worm speed reducer 1C, in the cross section including the shaft center of the worm 20, the connecting portion between the one end surface of the small diameter portion 22c and the other end surface of the press-fit portion 23, and the other end surface of the small diameter portion 22c and the worm main body portion 21. Since the outer shape along the axial direction of the worm 20 is continuous at an obtuse angle, the force received by the worm 20 from the worm wheel 26 is dispersed without being concentrated on the connecting portion. .

  Therefore, according to the third embodiment, it is possible to prevent the force from concentrating on the small-diameter portion 22c. Therefore, in addition to the effects of the first and second embodiments, one end of the small-diameter portion 22c and the press-fit portion 23 are provided. There is an effect that the connecting portion between the other end of the small diameter portion 22c and the connecting portion between the other end of the small diameter portion 22c and the one end of the worm main body portion 21 are not easily damaged.

Embodiment 4 FIG.
FIG. 10 is a cross-sectional view of a worm reduction gear according to Embodiment 4 of the present invention.
In FIG. 10, the same parts as those in the third embodiment are denoted by the same reference numerals, and the description thereof is omitted.

The worm reduction gear 1D includes a first axial movement restricting member 36A having the same shape as the pressing member 31A. In the first axial movement restricting member 36 </ b> A, the end surface opposite to the contact portion 36 a corresponding to the contact portion 31 a is fixed to the fixed wall 35 a of the closing member 35. At this time, the contact portion 36 a has a predetermined gap g in the axial direction of the worm 20 between the contact groove 24 a, in other words, the other end of the worm 20.
The gap g is in a state where the motor shaft 13 is moved in the direction in which the worm 20 is moved toward one end of the worm 20, that is, toward one end in the axial direction of the motor shaft 13. The play is narrower than the axial play of the motor shaft 13.

Further, the gap g is an expansion of the worm 20 due to assembly tolerance and temperature change when the motor shaft 13 is moved to one end side in the axial direction of the motor shaft 13 by the play in the axial direction of the motor shaft 13. It is determined to be slightly wider than the maximum displacement amount in the axial direction of the motor shaft 13 due to the amount.
Further, the arrangement of the coil spring 34 is omitted, and the worm 20 has a cantilever support structure in which only one end side is supported.
Other configurations are the same as those in the first embodiment.

  When the motor shaft 13 is moved to the other end side in the axial direction and the worm 20 is moved to the other end side of the worm 20, the motor shaft 13 is moved to the other end side in the axial direction with respect to the play in the axial direction. Before moving the maximum amount, the contact groove 24a at the other end of the worm 20 contacts the contact portion 36a. That is, further movement of the motor shaft 13 toward the other end side in the axial direction is restricted by the first axial movement restricting member 36A.

  Therefore, according to the fourth embodiment, the maximum amount of movement of the motor shaft 13 in the axial direction can be reduced with respect to the axial play of the motor shaft 13 while omitting the coil spring 34. Therefore, the accuracy of control of the rotation angle of the worm wheel 26 can be improved while reducing the member cost.

  Further, the worm 20 has a cantilever support structure in which at least the small-diameter portion 22 c is made of resin and only one end side is supported by the motor 10. Therefore, when receiving a large force from the worm wheel 26, the small diameter portion 22 c separates the worm main body portion 21 from the worm wheel 26 in accordance with the pressing force applied from the worm wheel 26 to the worm main body portion 21. Thus, it is configured to be elastically deformed so as to reduce the pressing force applied to the worm body 21. Thus, even when the worm 20 receives a large pressing force from the worm wheel 26, the worm 20 and the worm wheel 26 rotate smoothly while maintaining a state in which the backlash is reduced.

  In the fourth embodiment, the first axial movement restriction member 36A has been described as having the same shape as the pressing member 31A, that is, a so-called bullet shape, but the first axial movement restriction member 36A The shape of is not particularly limited. The shape of the first axial movement restricting member 36A is not particularly limited as long as the shape does not hinder the rotation of the motor shaft 13 around the axis when the worm 20 comes into contact, for example, a sphere.

  Further, the worm 20 has been described as having at least the small-diameter portion 22c made of an elastic resin. However, for example, the entire worm 20 may be made of a resin. In this case, the worm 20 is elastically deformed according to the pressing force applied from the worm wheel 26 to the worm body 21 even if the small diameter portion 22 c is not provided. Can be reduced.

Embodiment 5 FIG.
FIG. 11 is a sectional view of a worm reduction gear according to Embodiment 5 of the present invention.
In FIG. 11, the same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
In the worm speed reducer 1E, an elastic member 38a as an urging means is formed integrally with the pressing member 31A. The elastic member 38a has one end connected to the other end surface of the pressing member 31A and the other end side closed. The member 35 is fixed to the fixed wall 35a. The elastic member 38a is bent at an intermediate portion between one end thereof and a fixing portion to the closing member 35, and an elastic force is exerted on the intermediate portion of the elastic member 38a in a direction to release the bending.
Other configurations are the same as those in the first embodiment.

  At this time, the elastic force of the elastic member 38a to release the bending has a component that presses the pressing member 31A toward the worm 20 side. Thereby, 31 A of press members are supported by the wall surface of the through-hole 30a in the state which the contact part 31a pressed the contact groove 24a.

  Therefore, according to the fifth embodiment, the same effect as in the first embodiment can be obtained.

  Here, in the fifth embodiment, both ends of the elastic member 38a are fixed to the pressing member 31A and the fixing wall 35a, respectively, and further, the intermediate portion of the elastic member 38a is curved to make the pressing member 31A warm. It demonstrated as what presses to 20 side. However, the shape and fixing method of the elastic member 38a are not particularly limited as long as the elastic member 38a presses the pressing member 31A toward the worm 20 side. Hereinafter, a second embodiment for explaining another shape of the elastic member will be described with reference to FIG.

The elastic member 38b as the urging means has a C-shaped cross section, and the outer wall of the C-shaped bottom is fixed to the fixed wall 35a. Further, the C-shaped opening is directed to the other end surface of the pressing member 31A, and both ends of the C-shape are fixed to the other end surface of the pressing member 31A.
At this time, the pressing member 31A is pressed to the worm 20 side by the elastic force due to the curve of the wall between the C-shaped ends and the fixed wall 35a. Thereby, 31 A of press members are supported by the wall surface of the through-hole 30a in the state which the contact part 31a pressed the contact groove 24a.
Therefore, also in the second embodiment, the same effect as in the first embodiment can be obtained.

Embodiment 6 FIG.
13 is a cross-sectional view of a worm reduction gear according to Embodiment 6 of the present invention.
In FIG. 13, the same or corresponding parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.
The worm 20 of the worm speed reducer 1 </ b> F has one end surface of the worm 20 when the other end of the motor shaft 13 is at a position that extends most from the case 11 with respect to the axial displacement caused by play of the motor shaft 13. The gap between the one end surface of the press-fit portion 23 and the exposed end surface of the other bearing 12 from the case 11 is c. The other bearing 12 constitutes a second axial movement restricting member.
The gap c moves in the direction in which the motor shaft 13 moves the worm 20 to the other end side of the worm 20, that is, toward the other end side in the axial direction of the motor shaft 13 by the play in the axial direction of the motor shaft 13. In the state, it is narrower than the axial play of the motor shaft 13.

  Further, the gap “c” indicates that the motor shaft 13 is caused by the assembly tolerance and the expansion amount of the worm 20 due to the temperature change when the motor shaft 13 is moved to the other end side in the axial direction by the play of the motor shaft 13 in the axial direction. It is determined to be wider than the maximum amount of displacement in the axial direction.

Further, the small diameter portion 22a is made of an elastic resin such as POM.
Further, the arrangement of the member insertion wall 30, the pressing member 31A, and the coil spring 34 is omitted. Thus, the worm 20 has a cantilever support structure in which only one end side is supported.
Further, the distance between the axis of the worm 20 and the axis of the worm wheel 26 is set to be smaller than the distance L1 in the worm reduction gear 1A.
Other configurations are the same as those in the first embodiment.

  Since the worm 20 and the motor 10 are arranged so that the gap c is formed as described above, the motor shaft 13 is moved to the axial direction at one end side by the maximum amount with respect to the axial play. The end face of the bearing 12 comes into contact with one end of the worm 20. That is, further movement of the motor shaft 13 toward the one end side in the axial direction is restricted by the bearing 12.

  Therefore, according to the sixth embodiment, the maximum movement amount in the axial direction of the motor shaft 13 can be reduced with respect to the play in the axial direction of the motor shaft 13 while omitting the coil spring 34 and the like. Therefore, the accuracy of control of the rotation angle of the worm wheel 26 can be improved while reducing the member cost.

Furthermore, the worm 20 has a cantilever support structure in which at least the small-diameter portion 22a is made of resin and only one end side is supported by the motor 10. Therefore, when receiving a large force from the worm wheel 26, the small diameter portion 22 a separates the worm main body portion 21 from the worm wheel 26 in accordance with the pressing force applied from the worm wheel 26 to the worm main body portion 21. Thus, it is configured to be elastically deformed so as to reduce the pressing force applied to the worm body 21. Thus, even when the worm 20 receives a large pressing force from the worm wheel 26, the worm 20 and the worm wheel 26 rotate smoothly while maintaining a state in which the backlash is reduced.
Therefore, the control accuracy of the rotation angle of the worm wheel 26 can be further improved than in the first embodiment.

In the sixth embodiment, the second axial movement restricting member is described as being the other bearing 12, but the second axial movement restricting member is not limited to being the other bearing 12. . When one end surface of the worm 20 can be disposed so as to face the outer wall surface of the case 11 and the motor support wall 4, the case 11 and the motor support wall 4 can be used as the second axial movement restriction member. .
The worm 20 has been described as having at least the small-diameter portion 22a made of an elastic resin. However, for example, the entire worm 20 may be made of a resin. In this case, the worm 20 is elastically deformed according to the pressing force applied from the worm wheel 26 to the worm body 21 even if the small diameter portion 22a is not provided. Can be reduced.

Embodiment 7 FIG.
14 is an enlarged view showing a meshed state of the worm body portion and the tooth portion of the worm wheel when the worm wheel of the worm reduction gear according to the seventh embodiment of the present invention is rotated in the first rotational direction. FIG. 16 is an enlarged view showing the meshing state of the worm body portion and the tooth portion of the worm wheel when the worm wheel of the worm reduction gear according to the seventh embodiment of the present invention is rotated in the second rotational direction. It is a figure explaining the relationship between the command pattern of the angular velocity of the motor shaft of the worm speed reducer which concerns on Embodiment 7 of invention, and the rotation operation of a worm wheel, (a) of FIG. 16 rotates a worm wheel only a command angle. FIG. 16B is a diagram showing the time change of the actual rotation angle of the worm wheel. FIG. 17 is an enlarged view of part A in FIG. 16B, and FIG. 18 is an enlarged view of part B in FIG.
14 and 15, the same reference numerals are given to the same or corresponding parts as those in the first embodiment, and the description thereof is omitted.

The worm reducer according to the seventh embodiment is configured in the same manner as the worm reducer 1A.
Next, the relationship between the rotation direction of the worm wheel 26 and the backlash formed between the meshed tooth portion 21a of the worm main body 21 and the tooth portion 26a of the worm wheel 26 will be described.

As shown in FIG. 14, when the worm 20 (motor shaft 13) is rotated in one direction of rotation (clockwise (CW direction)) when the worm 20 is viewed from the other end side in the axial direction, The tooth portions 21a and 26a of the worm 20 and the worm wheel 26 are configured so that the wheel 26 rotates in the CW direction (first rotation direction) when viewed from above in FIG. The rotation of the motor shaft 13 in the CW direction is defined as the rotation in a predetermined direction.
Further, when the motor shaft 13 is rotated in the direction opposite to the predetermined direction (counterclockwise (CCW direction)), the worm wheel 26 is viewed in the CCW direction (second rotation direction) as viewed from above in FIG. Rotate.

  As shown in FIG. 14, when the motor shaft 13 (worm 20) and the worm wheel 26 are rotating in the CW direction, the backlash is formed on the CCW side of the tooth portion 21a in the rotation direction of the worm wheel 26. Further, as shown in FIG. 15, when the worm 20 and the worm wheel 26 are rotating in the CCW direction, the backlash is formed on the CW side of the tooth portion 21a in the rotation direction of the worm wheel 26. That is, when the worm wheel 26 is rotated in the CW direction and when it is rotated in the CCW direction, the position where the backlash is generated with respect to the tooth portion 21a when the worm wheel 26 is stopped is different.

Here, the rotation control of the worm wheel 26 by the control device 40 when the angle designation signal for rotating the worm wheel 26 by the command angle D is input to the calculation unit 41 will be described in detail with reference to FIG. 6 again. .
As described above, when the angle designation signal is input to the calculation unit 41, the CPU 42 sets a command pattern of the angular velocity of the motor shaft 13 (worm 20) for rotating the worm wheel 26 by the command angle D. Then, the CPU 42 generates a command pulse corresponding to the angular velocity command pattern, and outputs the command pulse to the motor drive circuit 45, thereby driving the motor 10 and rotating the motor shaft 13. When the motor shaft 13 rotates, the worm wheel 26 also rotates according to the rotation of the worm 20 that rotates integrally with the motor shaft 13.
Hereinafter, the rotation of the motor shaft 13 by driving the motor 10 in accordance with the command pulse corresponding to the angular velocity command pattern is simply referred to as the rotation of the motor shaft 13 corresponding to the angular velocity pattern.

Next, the rotation operation of the worm wheel 26 rotated according to the rotation of the motor shaft 13 according to the angular velocity pattern will be described in detail with reference to FIGS. 16 to 18.
As shown in FIG. 15, the initial state is such that the backlash is positioned on the CW side of the worm wheel 26 in the rotational direction of the worm wheel 26 and the worm 20 and the worm wheel 26 are stopped. And

In FIG. 16A, a command pattern of the angular velocity of the motor shaft 13 (hereinafter referred to as an angular velocity pattern in the CW direction) for stopping the worm wheel 26 at a position rotated from the initial state by the command angle D in the CW direction. ) Is indicated by a solid line, and an angular velocity command pattern of the motor shaft 13 for stopping the worm wheel 26 at a position rotated from the initial state by the command angle D in the CCW direction (hereinafter referred to as an angular velocity pattern in the CCW direction). )) Is shown by a broken line.
16B, 17 and 18, only the actual rotation angle of the worm wheel 26 when the motor shaft 13 is rotated in accordance with the angular velocity pattern in the CW direction is indicated by a solid line.

  In FIG. 16A, the angular velocity pattern in the CW direction corrects the rotation angle error of the worm wheel 26 when the worm wheel 26 is rotated in the CW direction according to the rotation of the motor shaft 13 corresponding to the basic pattern and the basic pattern. The angular velocity pattern in the CCW direction is only the basic pattern.

First, the basic pattern will be described.
The basic patterns of the angular velocity pattern in the CW direction and the angular velocity pattern in the CCW direction have the same angular velocity at each elapsed time, and only the direction of the angular velocity is different.
That is, the basic pattern increases the magnitude of the angular velocity at a constant rate from time 0 (rotation start time of the worm 20) to t1 in both the angular velocity pattern in the CW direction and the angular velocity pattern in the CCW direction. After the time t has elapsed by t1, the motor shaft 13 is rotated at a constant angular velocity until t2 has elapsed, and after the time t has elapsed t2, the angular velocity is maintained at a constant rate until t3 has elapsed. Is set so that the angular velocity becomes zero when t3 elapses.

  Here, the rotation angle from the initial state of the motor shaft 13 when the motor shaft 13 rotates and stops in accordance with the basic pattern is a value obtained by integrating the basic pattern of angular velocity with time. At this time, the rotation angle of the motor shaft 13 in the basic pattern is a value obtained by dividing the command angle D of the worm wheel 26 by the reduction ratio γ when the reduction ratio of rotation of the worm 20 and the worm wheel 26 is γ (<1). Is set to In other words, if the worm wheel 26 rotates immediately in conjunction with the rotation of the motor shaft 13 according to the basic pattern, the rotation angle of the worm wheel 26 when the motor shaft 13 rotates and stops according to the basic pattern. The command angle D is obtained.

  Here, the occurrence position of the backlash is not constant with respect to the tooth portion 21a depending on the rotation direction of the motor shaft 13, and the worm wheel 26 is simply rotated by the command angle D according to the rotation of the motor shaft 13 in the CW direction or CCW direction. When trying to do so, it becomes a factor which degrades the precision of control of the rotation angle of the worm wheel 26. That is, the control accuracy of the rotation angle of the worm wheel 26 is deteriorated by the rotation angle of the worm wheel 26 corresponding to the backlash amount k. As shown in FIG. 14, the backlash amount k is a distance between the wall surfaces of the tooth portions 21a and 26a of the worm 20 and the worm wheel 26 forming the backlash when the worm wheel 26 is rotating. The smallest distance.

Hereinafter, a description will be given of the deterioration in the accuracy of control of the rotation angle that occurs due to the difference in backlash generation position with respect to the tooth portion 21a.
First, the actual rotation angle of the worm wheel 26 when the motor shaft 13 rotates in the CW direction and the CCW direction according to the basic pattern will be described.

First, the actual rotation angle of the worm wheel 26 when the motor shaft 13 rotates in the CW direction according to the basic pattern will be described.
In the initial state, as shown in FIG. 15, the backlash is formed on the CW side of the rotating direction of the worm wheel 26 of the tooth portion 21a. Therefore, when the motor shaft 13 is rotated in the CW direction, after the rotation of the motor shaft 13 is started, the worm 20 interlocked with the rotation of the motor shaft 13 causes the worm wheel 26 to move by an angle X corresponding to the backlash amount k. It takes time α to rotate by the rotation angle. In other words, after the rotation of the motor shaft 13 is started, a time α is required until the tooth portion 21a and the tooth portion 26a come into contact with each other and the worm wheel 26 starts to rotate. That is, when the worm wheel 26 is rotated in the CW direction, it takes time α from the initial state shown in FIG. 15 to the state shown in FIG. Accordingly, the rotation angle of the worm wheel 26 becomes 0 as shown in FIG. 17 until the time α elapses after the rotation of the motor shaft 13 is started.

  The worm 20 and the worm wheel 26 continue to rotate in the CW direction until the time t elapses after the time t elapses. During this time, the worm 20 always rotates the worm wheel 26 in the CW direction with the backlash formed on the CCW side of the rotation direction of the worm wheel 26 of the tooth portion 21a.

As described above, since the worm wheel 26 does not rotate until the time t elapses, the actual rotation angle of the worm wheel 26 when the rotation according to the basic pattern of the motor shaft 13 is finished (stopped) is As shown in FIG. 18, the command angle D decreases by an angle X corresponding to the backlash amount k.
Thus, when the motor shaft 13 is rotated according to the basic pattern of the angular velocity pattern in the CW direction, the rotation angle of the worm wheel 26 from the initial state in the CW direction has an error with respect to the command angle D due to backlash. appear.

Next, the actual rotation angle of the worm wheel 26 when the motor shaft 13 is rotated in the CCW direction according to the basic pattern will be described.
When the motor shaft 13 is rotated in the CCW direction, as shown in FIG. 15, in the initial state, the backlash is formed on the CW side of the rotation direction of the worm wheel 26 of the tooth portion 21a. Accordingly, when the motor shaft 13 rotates in the CCW direction, the worm wheel 26 rotates in conjunction with the rotation of the worm 20 that rotates instantaneously with the motor shaft 13. As a result, the worm wheel 26 rotates in conjunction with the rotation of the motor shaft 13 even between t = 0 and α.

  The worm wheel 26 rotates in the CCW direction until time t3 elapses after the start of the rotation of the motor shaft 13 and t3 has elapsed. Accordingly, the worm wheel 26 rotates in the CCW direction with the backlash always formed on the CW side of the rotation direction of the worm wheel 26 of the tooth portion 21a.

  That is, when the worm wheel 26 is rotated in the CCW direction according to the rotation of the worm 20 in the CCW direction according to the basic pattern, the rotation angle of the worm wheel 26 when the rotation according to the basic pattern of the worm 20 is finished (stopped). Corresponds to the command angle D.

  Therefore, when the motor shaft 13 is rotated in accordance with the angular velocity pattern in the CW direction, the decrease X of the rotation angle of the worm wheel 26 with respect to the command angle D is corrected, as shown in FIG. In addition, after the motor shaft 13 is rotated according to the basic pattern, the motor shaft 13 is further rotated according to the additional pattern described below.

Next, the additional pattern will be described.
The additional pattern gradually increases the angular velocity in the CW direction of the motor shaft 13 from 0 as time t further elapses from t3, and gradually decreases the angular velocity when time t4 elapses. The angular velocity is set to 0 when the time t has elapsed t5. Further, the additional pattern is such that after the time t has elapsed from t5, the motor shaft 13 is rotated in the CCW direction instead of the CW direction, and the magnitude of the angular velocity is gradually increased until the time t has elapsed t6. After the time t6 has elapsed, the magnitude of the angular velocity is gradually decreased, and when the time t has elapsed t7, the magnitude of the angular velocity is set to 0 and the rotation of the motor shaft 13 is stopped.

In the additional pattern, the magnitude obtained by time integration of the angular velocity pattern between t3 and t5 is equal to the magnitude obtained by time integration of the angular velocity pattern between t5 and t7.
That is, the rotation angle of the motor shaft 13 in the CW direction from t3 to t5 is equal to the rotation angle of the motor shaft 13 in the CCW direction from t5 to t7. Therefore, when the worm wheel 26 rotates in conjunction with the rotation of the worm 20 that rotates integrally with the motor shaft 13 according to the additional pattern, the rotation angle of the worm wheel 26 in the CW direction at t3 to t5 , The rotation angle of the worm wheel 26 in the CCW direction at t5 to t7 is set to be equal. At this time, each rotation angle of the worm wheel 26 between t3 to t5 and t5 to t7 when the worm wheel 26 rotates in conjunction with the rotation according to the additional pattern of the motor shaft 13 is the backlash amount k. It is set to be more than the corresponding angle.

  However, in practice, the backlash is formed on the CCW side of the rotation direction of the worm wheel 26 of the tooth portion 21a in a state immediately before the rotation direction of the motor shaft 13 is reversed after the time t has elapsed t5. Therefore, after the rotation direction of the motor shaft 13 is reversed from the CW direction to the CCW direction, the worm 20 rotating integrally with the motor shaft 13 rotates by an angle corresponding to rotating the worm wheel 26 by the backlash amount k. It takes time β. In other words, it takes time β after the rotation direction of the motor shaft 13 is reversed until the tooth portion 21a contacts the tooth portion 26a. Therefore, the worm wheel 26 does not rotate in conjunction with the rotation of the motor shaft 13 during the time β.

Therefore, from t3 to t7, the actual rotation angle of the worm wheel 26 in the CCW direction is smaller than the actual rotation angle of the worm wheel 26 in the CW direction.
At this time, as described above, since the rotation angle in the CW direction in the additional pattern of the motor shaft 13 is equal to the rotation angle in the CCW direction, the actual rotation angle in the CW direction of the worm wheel 26 and the CCW of the worm wheel 26 are The difference between the direction and the actual rotation angle coincides with the angle X corresponding to the backlash amount k.
Accordingly, the error in the rotation angle of the worm wheel 26 due to the backlash in the basic pattern that occurs when the motor shaft 13 is rotated in the CW direction is offset by the additional pattern.

  Therefore, according to the seventh embodiment, when the control device 40 rotates the worm wheel 26 by the command angle D in the CW direction (first rotation direction), first, the motor shaft 13 is set to the backlash amount k. It is rotated in the CW direction (predetermined direction) from the initial state by an angle obtained by dividing an angle obtained by adding a predetermined angle equal to or greater than the rotation angle of the corresponding worm wheel 26 and the command angle by a reduction ratio. Further, the control device 40 reverses the rotation direction of the motor shaft 13 in the CCW direction (the direction opposite to the predetermined direction), and the rotation angle of the motor shaft 13 after the rotation direction is reversed is determined by the reduction ratio. The rotation of the motor shaft 13 is stopped when it coincides with the divided angle. When the control device 40 rotates the worm wheel 26 in the CCW direction (second rotation direction) by the command angle D, the control device 40 moves the motor shaft 13 from the initial state to the CCW by an angle obtained by dividing the command angle by the reduction ratio. It is stopped after continuously rotating in the direction.

Therefore, regardless of whether the motor shaft 13 is rotated in the CW direction or the CCW direction, when the worm wheel 26 is rotated by the command angle D and stopped, the backlash is caused by the worm of the tooth portion 21a of the worm main body portion 21. The wheel 26 is always arranged on the CW side in the rotation direction.
Thereby, even when the worm wheel 26 is rotated in either the CW direction or the CCW direction according to the angular velocity pattern of the motor shaft 13, the error of the rotation angle due to the backlash is eliminated with respect to the command angle D. The effect that the rotation angle of 26 can be controlled with high accuracy is obtained.

  In the seventh embodiment, the angular velocity pattern in the CW direction is obtained by rotating the motor shaft 13 in accordance with the basic pattern so that the angular velocity of the motor shaft 13 is once set to 0 and then moving the motor shaft 13 in the CW direction. It has been described that the angular velocity is changed so that the motor shaft 13 is rotated by a predetermined angle and then the motor shaft 13 is rotated by a predetermined angle in the CCW direction. However, the angular velocity pattern in the CW direction is not limited to this. For example, the basic pattern and the additional pattern may be set as follows.

  That is, for the angle d equal to or larger than the rotation angle of the worm wheel 26 corresponding to the backlash amount k, the basic pattern is to continuously rotate the motor shaft 13 in the CW direction by a value obtained by dividing the angle (D + d) by the reduction ratio γ. After that, the angular velocity is set to zero. Further, the additional pattern is set so that the rotation of the motor shaft 13 is stopped after the motor shaft 13 is continuously rotated in the CCW direction by an angle obtained by dividing the angle d by the reduction ratio γ.

Even when the worm wheel 26 is rotated according to the rotation of the motor shaft 13 according to such an angular velocity pattern in the CW direction, the backlash causes the rotation direction of the worm wheel 26 of the tooth portion 21a when the rotation of the motor shaft 13 is stopped. Always placed on the CW side.
As a result, when the worm wheel 26 is rotated in either the CW or CCW direction, an error in the rotation angle of the worm wheel 26 due to backlash is eliminated with respect to the command angle D. Therefore, control of the rotation angle of the worm wheel 26 is controlled. Can be obtained with high accuracy.

In addition, when the occurrence position of the backlash with respect to the tooth portion 21a in the initial state is on the other side (CCW side) of the tooth portion 21a in the rotation direction of the worm wheel 26, the basic pattern only for the angular velocity pattern in the CCW direction. And an additional pattern may be provided.
Further, the control of the rotation angle of the worm wheel 26 with respect to the worm reduction gear 1A has been described, but the rotation angle of the worm wheel 26 is similarly controlled not only for the worm reduction gear 1A but also for the worm reduction gears 1B to 1F. In addition, the effect that the rotation angle of the worm wheel 26 can be controlled with high accuracy can be obtained.

Embodiment 8 FIG.
FIG. 19 is a view for explaining the relationship between the command pattern of the angular velocity of the motor shaft of the worm reduction gear according to the seventh embodiment of the present invention and the rotation operation of the worm wheel. FIG. FIG. 19B is a diagram illustrating a change over time in the command pattern of the angular velocity of the motor shaft for rotating by an angle, and FIG. 19B is a diagram illustrating a change over time in the actual rotation angle of the worm wheel.

Hereinafter, the rotation operation of the worm wheel 26 rotated in accordance with the rotation of the motor shaft 13 according to the angular velocity pattern will be described in detail with reference to FIG.
In the following description, the CW direction and the CCW direction are defined in the same manner as in the seventh embodiment.
Further, as shown in FIG. 15, the initial state is a state where the backlash is located on the CW side in the rotation direction of the worm wheel 26 of the tooth portion 21 a in the worm main body portion 21, and the worm 20 and the worm wheel 26 are stopped. It shall be.

In FIG. 19, the angular velocity pattern of the motor shaft 13 for rotating the worm wheel 26 by the command angle in the CW direction from the initial state is the basic pattern, the additional pattern, and the excitation performed between the basic pattern and the additional pattern. It consists of patterns. Further, the angular velocity pattern of the motor shaft 13 for rotating the worm wheel 26 in the CCW direction by a command angle is composed of a basic pattern and an excitation pattern implemented after the basic pattern.
The basic pattern and the additional pattern are the same as those in the seventh embodiment.
However, in Embodiment 7 described above, the end time of the basic pattern is t3. However, in Embodiment 8, the end time of the basic pattern is newly set to t8.

Next, the vibration pattern will be described.
The vibration pattern is performed between the basic pattern end time t8 and the additional pattern start time t3 when the worm wheel 26 is rotated by the command angle in the CW direction from the initial state.
The vibration pattern is changed to 0 by changing the magnitude of the angular velocity in the CW direction of the motor shaft 13 in a pulsed manner during a minute time (t9-t8) after the basic pattern ends at time t8, During the minute time (t10-t9), the magnitude of the angular velocity of the motor shaft 13 in the CCW direction is changed to 0, and further, the time t reaches t3 after a predetermined time has elapsed from t10. The angular velocity is maintained at 0. In addition, the time integral of the angular velocity between t8 and t9 (the rotation angle of the motor shaft 13) and the angle obtained by time integrating the angular velocity from t9 to t10 are minute angles having the same value.

  Here, as described above, the motor 10 is a stepping motor, and includes a rotor (not shown) made of a permanent magnet and a stator having a plurality of phase motor coils (not shown). The angular velocity of the motor shaft 13 can be controlled by a pattern of pulse currents flowing through the motor coils of each phase provided in the motor 10.

  In the angular velocity pattern of the motor shaft 13 described above, the driving of the motor 10 in the basic pattern end stage, the excitation pattern, and the additional pattern is performed by microstep driving in which the step angle is subdivided by controlling the current passed through the motor coil. Has been done. That is, the accuracy of angle control when the motor shaft 13 is rotated by performing the basic pattern end stage, the vibration pattern, and the additional pattern is improved.

  At this time, the rotation angle of the motor shaft 13 by the execution of the vibration pattern is less than 2 full steps. In the excitation pattern, the switching time of the pulse current in the micro step drive is shortened. For example, the rotation of the motor shaft 13 corresponding to one full step is performed in 1 ms or less.

Hereinafter, the significance of implementing the excitation pattern will be described.
At the start and end stages of the basic pattern, the rotation speed of the motor shaft 13 is gradually increased in order to prevent a phenomenon (step-out) in which the rotation of the motor shaft 13 does not follow the pulse current flowing through the motor coil of each phase of the motor 10. The angular velocity is set to 0 by changing.

  Here, when the motor shaft 13 is urged toward one end side in the axial direction by the coil spring 34 via the worm 20 and the pressing member 31A, the motor shaft 13 is rotated by performing the basic pattern. The motor shaft 13 may move to the other end side in the axial direction against the urging force of the coil spring 34. The cause of this has not been clearly elucidated. When the motor shaft 13 is rotated by performing the basic pattern, the frequency of the periodic change of the pulse current supplied to the motor coil is determined by the spring constant of the coil spring 34 and the mass of the worm 20 and the motor shaft 13. May match the natural frequency. This is considered to be one of the causes for moving the motor shaft 13 against the urging force of the coil spring 34.

Even when a force (counter biasing force) is applied to move the motor shaft 13 to the other end side in the axial direction against the biasing force of the coil spring 34, the counter force is applied at the final stage of the basic pattern. The power is released. The motor shaft 13 is urged toward one end in the axial direction by the urging force of the coil spring 34, and tends to go to the position on the one end side in the axial direction (steady position) in the movable range.
However, since the rotation of the motor shaft 13 is controlled to stop at a gradual speed change, when the frictional force between the motor shaft 13 and the bearing 12 is large, the motor shaft 13 moves to one end side in the axial direction. This movement stops before reaching the steady position. This means that the rotation angle of the worm wheel 26 is deviated from the command angle D, and becomes a factor that degrades the accuracy of control of the rotation angle of the worm wheel 26.

  The vibration pattern reduces deterioration in accuracy of control of the rotational angle of the worm wheel 26 caused by the motor shaft 13 being stopped and held at a position different from the normal position due to friction between the motor shaft 13 and the bearing 12. To do.

  Here, the rotational torque of the motor shaft 13 is approximately proportional to the temporal change rate of the angular velocity. When the motor shaft 13 is rotated by executing the vibration pattern, the angular velocity between the times t8 to t9 and t9 to t10 is so generated that a predetermined torque or more sufficient to vibrate the motor shaft 13 is instantaneously generated. Time rate of change has been determined. At this time, the motor shaft 13 also vibrates in the axial direction.

  In order to move the motor shaft 13 held and held at a position different from the steady position in the axial direction, a force larger than the static friction force between the motor shaft 13 and the bearing 12 must be applied. That is, when the motor shaft 13 is rotated with the vibration pattern being implemented, a force larger than the static frictional force between the motor shaft 13 and the bearing 12 is applied in the axial direction of the motor shaft 13 and the motor shaft 13 vibrates. To do.

  Once the motor shaft 13 moves in the axial direction, the motor shaft 13 moves in the axial direction of the motor shaft 13 if a force larger than the dynamic friction force between the motor shaft 13 and the bearing 12 is applied. That is, since the dynamic friction force is smaller than the static friction force, the motor shaft 13 is easily moved in the axial direction with a small force while the motor shaft 13 is moving, compared to the state in which the motor shaft 13 is stopped and held. . Since the motor shaft 13 is biased to one end side in the axial direction by the coil spring 34, when the motor shaft 13 is stopped and held at a position different from the steady position at the end of the basic pattern, the motor shaft 13 Is moved to one end side of the motor shaft 13 with respect to the position at the end of the basic pattern by the urging force of the coil spring 34 by performing the vibration pattern. Accordingly, it is possible to reduce deterioration in the accuracy of control of the rotation angle of the worm wheel 26 caused by the motor shaft 13 being stopped and held at a position different from the steady position due to friction between the motor shaft 13 and the bearing 12.

  When the worm wheel 26 is rotated by the command angle D in the CW direction, an additional pattern is provided after the vibration pattern in the same manner as in the seventh embodiment, and the worm wheel 26 with respect to the command angle D caused by backlash is provided. The error of the rotation angle is eliminated.

  In the additional pattern, the angular speed of the motor shaft 13 is not changed rapidly, and the low speed range is set so as to change more slowly than the angular speed of the motor shaft 13 in the basic pattern. When the motor shaft 13 rotates according to the pattern, the motor shaft 13 does not move in the axial direction.

  When the worm wheel 26 is rotated from the initial state in the CCW direction by the command angle D, only the rotation of the motor shaft 13 according to the vibration pattern is performed after the basic pattern end time t8. As a result, the motor shaft 13 is stopped and held at a position different from the steady position by friction between the motor shaft 13 and the bearing 12 as in the case where the worm wheel 26 is rotated by the command angle D in the CW direction from the initial state. The deterioration in the accuracy of control of the rotation angle of the worm wheel 26 due to the fact can be reduced.

According to the eighth embodiment, since the motor shaft 13 is rotated according to the vibration pattern after the motor shaft 13 is rotated according to the basic pattern, the motor shaft 13 rotating according to the basic pattern is When stopping, an error in the rotation angle with respect to the command angle D of the worm wheel 26 due to the fact that the motor shaft 13 is stopped and held at a position different from the steady position due to the frictional force between the motor shaft 13 and the bearing 12. Can be reduced.
Further, the step-out may occur when the motor shaft 13 is rotated by two full steps or more. Since the vibration pattern is completed at the rotation angle of the motor shaft 13 of less than 2 full steps, the step-out does not occur due to the rotation of the motor shaft 13 according to the vibration pattern.

Embodiment 9 FIG.
FIG. 20 is a perspective view of a revolving camera according to Embodiment 9 of the present invention.
In FIG. 20, the same or corresponding parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  In FIG. 20, the swivel camera 50 is rotatably attached in conjunction with the rotation of the worm reduction gear 1 </ b> A, the chassis 51 that supports the worm reduction gear 1 </ b> A, and the driven shaft 25 of the worm wheel 26. A photographing means 53 having a lens 52 exposed from the chassis 51 is provided.

  Although not shown, the motor holder 2 of the worm reduction gear 1A is fixed directly to the chassis 51 or indirectly by a mounting bracket (not shown), and the driven shaft 25 is attached to the chassis 51 so as to be rotatable about its axis. ing.

  Since the worm reduction gear 1A can control the rotation angle of the worm wheel 26 with high accuracy, the lens 52 of the imaging means 53 that rotates in conjunction with the rotation of the worm wheel 26 also has high accuracy with respect to the rotation direction of the worm wheel 26. The rotation angle can be controlled.

  Therefore, according to the ninth embodiment, it is possible to photograph the photographing point with the lens 52 accurately directed to the desired photographing point.

  In the ninth embodiment, the photographing means 53 is described as being attached to rotate in conjunction with the rotation of the worm wheel 26. However, instead of the photographing means 53, the antenna is interlocked with the rotation of the worm wheel 26. You may attach so that it may rotate. As a result, it is possible to obtain a swivel type radio wave receiver capable of accurately directing the antenna in a desired direction.

  In the above embodiments, the motor 10 is described as a stepping motor. However, the motor is not limited to a stepping motor, and may be a feedback DC motor with an angle detector.

  In each of the above embodiments, the driven gear is described as the worm wheel 26 that meshes with the worm 20 and that is rotatably disposed around the driven shaft 25 whose axial direction is orthogonal to the axial direction of the worm 20. The driven gear is not limited to the worm wheel 26. The driven gear may be a helical gear (tilted gear) that meshes with the worm 20 and rotates in conjunction with the rotation of the worm 20.

It is a perspective view of the worm reduction gear which concerns on Embodiment 1 of this invention. It is a top view of the worm reduction gear which concerns on Embodiment 1 of this invention. It is a front view of the worm gear reducer which concerns on Embodiment 1 of this invention. FIG. 4 is a cross-sectional view taken along arrow IV-IV in FIG. 3. It is an enlarged view around the meshing part of the worm and worm wheel of the worm reduction gear according to the first embodiment of the present invention. 1 is a system configuration diagram of a worm reduction gear according to Embodiment 1 of the present invention. FIG. It is sectional drawing explaining the shape of the press member of the worm speed reducer which shows the 1st embodiment of this invention. It is an enlarged view which shows the meshing state of the worm main-body part of the worm gear reducer which concerns on Embodiment 2 of this invention, and the tooth | gear part of a worm wheel. It is sectional drawing of the worm gear reducer which concerns on Embodiment 3 of this invention. It is sectional drawing of the worm gear reducer which concerns on Embodiment 4 of this invention. It is sectional drawing of the worm gear reducer which concerns on Embodiment 5 of this invention. It is sectional drawing explaining the shape of the elastic member of the worm speed reducer which shows the 2nd embodiment of this invention. It is sectional drawing of the worm gear reducer which concerns on Embodiment 6 of this invention. It is an enlarged view which shows the meshing state of the worm main-body part and the tooth | gear part of a worm wheel when the worm wheel of the worm reduction gear which concerns on Embodiment 7 of this invention is rotating in the 1st rotation direction. It is an enlarged view which shows the meshing state of the worm main-body part and the tooth | gear part of a worm wheel when the worm wheel of the worm gear reducer which concerns on Embodiment 7 of this invention is rotating in the 2nd rotation direction. It is a figure explaining the relationship between the instruction | command pattern of the angular velocity of the motor shaft of the worm gear reducer which concerns on Embodiment 7 of this invention, and rotation operation of a worm wheel. It is the A section enlarged view of FIG. It is the B section enlarged view of FIG. It is a figure explaining the relationship between the command pattern of the angular velocity of the motor shaft of the worm gear reducer which concerns on Embodiment 8 of this invention, and rotation operation of a worm wheel. It is a perspective view of the turning type camera which concerns on Embodiment 9 of this invention.

Explanation of symbols

  1A to 1F Worm reducer, 10 motor, 12 bearing (second axial movement restricting member), 13 motor shaft, 20 worm, 21 worm main body, 22a to 22c small diameter portion, 26 worm wheel (driven gear), 30 member insertion wall (support member), 30a through hole, 31A, 31B pressing member, 34 coil spring (biasing means), 35a fixed wall, 36A first axial movement restricting member, 38a, 38b elastic member (biasing) Means), 40 control device, 50 revolving camera, 53 photographing means.

Claims (11)

In a worm speed reducer comprising: a motor; a worm that is coaxially fixed to one end of the motor shaft at one end; and a worm that is rotationally driven by the motor; and a driven gear that meshes with the worm.
A support member which is disposed with a gap between the other end of the worm and a through hole in which a hole center is located on an axis of the worm;
A pressing member inserted in the through hole so as to be slidable in the axial direction of the worm;
Urging means for urging the pressing member toward the worm side and pressing the other end of the worm toward the one end side via the pressing member;
A worm speed reducer comprising:   The worm includes a worm main body portion having a predetermined diameter that meshes with the driven gear, and a small-diameter portion formed so as to be smaller in diameter than the worm main body portion at one end side from the worm main body portion, And the said small diameter part is comprised so that it may elastically deform according to the pressing force added to the said worm main-body part from the said driven gear, and the said pressing force added to the said worm main-body part may be reduced. The worm speed reducer according to claim 1.   The worm speed reducer according to claim 2, wherein the narrow diameter portion has a shape in which the diameter gradually decreases from both ends toward the center. A fixing wall disposed on the opposite side of the support member from the worm so as to face the support member;
The urging means is a resilient member disposed in a curved state between the fixed wall and the pressing member,
4. The worm according to claim 1, wherein the pressing member is urged toward the worm side by an elastic force of the elastic member that attempts to release the curved state. 5. Decelerator. In a worm speed reducer comprising a motor, a worm that is coaxially fixed to one end of the motor shaft at one end and driven to rotate by the motor, and a driven gear that meshes with the worm,
A first axial movement restricting member that contacts the other end of the worm and restricts the movement of the motor shaft when the motor shaft moves in a direction to move the worm toward the other end of the worm; Prepared,
The first axial movement restricting member is arranged so that the motor shaft moves in the axial direction of the motor shaft in a direction in which the motor shaft moves in the axial direction of the worm. A worm reduction gear having a gap narrower than an axial play between the motor shafts. In a worm speed reducer comprising a motor, a worm that is coaxially fixed to one end of the motor shaft at one end and driven to rotate by the motor, and a driven gear that meshes with the worm,
A second axial movement regulating member that abuts against one end of the worm and regulates the movement of the motor shaft when the motor shaft moves in a direction to move the worm toward one end of the worm;
The second axial movement restricting member is connected to one end of the worm in a state where the motor shaft is moved in the axial direction of the motor shaft in a direction to move the worm to the other end side of the worm. A worm reduction gear having a gap narrower than an axial play between the motor shafts.   The worm includes a worm main body having a predetermined diameter that meshes with the driven gear, the worm is supported in a cantilever state by the motor, and is further added to the worm main body from the driven gear. The worm speed reducer according to claim 5 or 6, wherein the worm speed reducer is configured to be elastically deformed according to a pressing force and to reduce the pressing force applied to the worm body. A control device for controlling the drive of the motor so as to rotate the driven gear by a command angle;
When the driven gear rotates the commanded gear in the first rotation direction by the command angle, the control device sets an angle obtained by adding a predetermined angle equal to or greater than the rotation angle of the driven gear corresponding to a backlash amount and the command angle. The motor shaft is rotated in the predetermined direction from the initial state by the angle divided by the reduction ratio, and the driven gear is rotated in the first rotational direction, and then the rotational direction of the motor shaft is reversed in the direction opposite to the predetermined direction. When the rotation angle of the motor shaft after the rotation direction is reversed coincides with the angle obtained by dividing the predetermined angle by the reduction ratio, the rotation of the motor shaft is stopped and the driven gear is rotated in the first rotation. When rotating the command angle in the second rotation direction opposite to the direction, the motor shaft is rotated from the initial state in a direction opposite to the predetermined direction by an angle obtained by dividing the command angle by a reduction ratio. Stop later Sea urchin worm reducer according to any one of claims 1 to 7, characterized in that for controlling the driving of the motor. A control device for controlling the drive of the motor so as to rotate the driven gear by a command angle;
When the driven device rotates the driven gear in the first rotation direction by the command angle, the control device rotates the motor shaft in a predetermined direction from an initial state by an angle obtained by dividing the command angle by a reduction ratio. The motor shaft is rotated in the predetermined direction by a minute angle by a change in angular velocity that generates a rotational torque greater than a predetermined value necessary for vibrating the motor shaft, and the motor shaft is further vibrated with the motor shaft. When a predetermined time elapses after the rotation is stopped by rotating in the direction opposite to the predetermined direction by the same angle as the minute angle due to a change in the angular velocity that generates a rotational torque greater than the predetermined necessary for the rotation, it corresponds to the backlash amount. After rotating the driven gear in the first rotational direction by an angle obtained by dividing a predetermined angle equal to or greater than the rotational angle of the driven gear by the reduction ratio, the rotational direction of the motor shaft is opposite to the predetermined direction. When the rotation angle of the motor shaft after the rotation direction is reversed coincides with the angle obtained by dividing the predetermined angle by the reduction ratio, the rotation of the motor shaft is stopped, and the driven gear is moved to the first gear. When rotating the command angle in the second rotation direction opposite to the rotation direction by the command angle, the motor shaft is rotated from the initial state in a direction opposite to the predetermined direction by an angle obtained by dividing the command angle by a reduction ratio. Then, the motor shaft is rotated in the predetermined direction by the minute angle by a change in angular velocity that generates a rotational torque greater than a predetermined value necessary for vibrating the motor shaft, and the motor shaft is further rotated by the motor shaft. 2. The method according to claim 1, wherein the rotation is stopped by rotating in a direction opposite to the predetermined direction by the same angle as the minute angle by a change in angular velocity that generates a rotational torque greater than a predetermined required for vibrating the motor. Worm reducer according to any one of 7. A worm reducer according to any one of claims 1 to 9,
Photographing means arranged to be able to turn in conjunction with the rotation of the driven gear;
A revolving camera characterized by comprising: A worm reducer according to any one of claims 1 to 9,
An antenna arranged to be pivotable in conjunction with the rotation of the driven gear;
A swivel type radio wave receiving apparatus comprising:

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