JPH11252953A - Ultrasonic motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ultrasonic motor wherein production of abnormal noise is prevented and furthermore the movement of mover is controlled properly. SOLUTION: A pressure-welded face 69 is made narrower as compared with the cases of full-face contact by means of a projected portion 6p formed on one 6 of members, a stator 5 and a mover 6, and pressure-welded to the other member 5 via a buffering frictional member 12 in-between, thereby preventing attenuation of traveling waves. The buffering frictional member 12 is stuck to the one member 6 by means of an adhesive 13 placed in a gap 8a which is beside the projected portion 6p, so that the buffering frictional member 12 is prevented from rotating unstable due to the traveling waves with suppressed attenuation, and that the adhesive 13 will not present at the pressure-welded face on which load is exerted, that is, in a position facing opposite to the projected face 6q.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to an ultrasonic motor.

[0002]

2. Description of the Related Art Conventional general ultrasonic motors include:
A stator (stator) composed of an elastic body made of metal and a piezoelectric element (vibrator) provided on the elastic body, and a rotor (movable element) made of metal opposed to the elastic body and pressed against the elastic body via a buffer friction member ), By supplying a signal of a predetermined frequency to the piezoelectric element, causing the piezoelectric element to vibrate to generate a traveling wave on the press-contact surface of the stator elastic body, and the driving force by the traveling wave is provided. Is transmitted to a rotor via a cushioning friction member to thereby rotationally drive the rotor.

For example, Japanese Patent Laid-Open Publication No. Hei 2-179281 discloses that the above-mentioned ultrasonic motor is developed and the rotor is composed of a metal elastic body and a piezoelectric element provided on the metal elastic body. By supplying a signal of a predetermined frequency to both the piezoelectric element and the rotor-side piezoelectric element, both the piezoelectric elements are vibrated, and a traveling wave is applied to the pressure contact surfaces of both the stator-side elastic body and the rotor-side elastic body. Although an ultrasonic motor that generates and drives the rotor to rotate by both traveling waves is disclosed, there is no description about the cushioning friction member.

[0004] Here, the cushioning friction member generates a normal traveling wave on the press contact surface, and also avoids the direct contact between the metals (stator and rotor) to prevent the generation of abnormal noise (squealing noise). Further, it is used for the purpose of improving the durability of the pressure contact portion between the stator and the rotor.

[0005]

However, in a configuration in which the cushioning friction member is merely interposed between the stator and the rotor, there are times when the rotor rotates with the rotor and times when the rotor does not rotate. , It is difficult to accurately control the rotation of the rotor.

Therefore, a configuration is known in which an adhesive is provided between the pressure contact surface of one of the pressure contact portions and the buffer friction member, and the buffer friction member is adhered to the pressure contact surface. In this configuration, since the thickness of the adhesive is inevitably nonuniform (thickness unevenness), the load on the press-contact portion fluctuates due to the unevenness in thickness, and multiple resonances occur. There is a problem that a sound (slapping sound) is generated.

SUMMARY OF THE INVENTION The present invention has been made in order to solve such a problem, and an object of the present invention is to provide an ultrasonic motor capable of controlling the movement of a movable element while preventing abnormal noise. .

[0008]

SUMMARY OF THE INVENTION An ultrasonic motor according to the present invention includes a stator and a movable member which are opposed to each other and are pressed against each other via a buffer friction member, and a vibrator provided on at least one of the stator and the movable member. On the other hand, by supplying a signal of a predetermined frequency, the vibrator is vibrated, and in the ultrasonic motor that drives the mover by a traveling wave generated on the side having the vibrator among the stator and the mover, A protrusion provided on either one of the armature and the mover, and pressed into contact with the other member via the cushioning friction member, and a cushioning friction member interposed between the protrusions and the gap therebetween. And an adhesive for bonding.

In the ultrasonic motor, when the stator and the mover are in full contact, the traveling wave of the member having the vibrator is largely transmitted to the other member, and the displacement of the traveling wave is attenuated. There is a possibility that a normal traveling wave is not formed and the mover does not move.

Here, according to the ultrasonic motor of the present invention,
Due to the configuration in which the convex portion provided on either the stator or the mover is pressed against the other member via the buffer friction member, the pressure contact surface is narrowed compared to the entire surface contact, and the The attenuation of the traveling wave is suppressed. At this time, the adhesive is disposed in the gap by using the gap beside the convex portion, and the cushioning friction member is bonded and fixed to one of the members.
The damping friction member does not rotate instablely due to the traveling wave whose attenuation is suppressed, and the mover is well controlled for movement. Further, since no adhesive is interposed on the pressure contact surface on which the load acts, generation of abnormal noise is prevented.

Further, the ultrasonic motor according to the present invention comprises a stator and a movable member which are opposed to each other and are pressed against each other via a buffer friction member. In the ultrasonic motor that vibrates the vibrator by supplying a signal having a frequency of, and drives the mover by a traveling wave generated on the side having the vibrator among the stator and the mover, the stator or the mover The convex portion is provided on any one of the members, and is provided at a position excluding a surface opposed to the convex surface of the convex portion of the other member, and a cushioning friction member. And an adhesive interposed in the gap and bonding the cushioning friction member to the other member.

According to the ultrasonic motor of the present invention, since the projection provided on one of the stator and the mover is in pressure contact with the other member via the cushioning friction member,
Similarly to the above invention, the pressure contact surface is made narrower than the entire surface contact, and the attenuation of the generated traveling wave is suppressed. At this time, an adhesive is provided at a position other than the surface of the other member facing the convex surface of the convex portion, and an adhesive is disposed in a gap formed between the buffer member and the buffer member. Since the damping friction member is not fixedly rotated by the traveling wave with the damping suppressed, the movable member is favorably controlled to move. Further, since no adhesive is interposed on the pressure contact surface on which the load acts, generation of abnormal noise is prevented.

Further, the ultrasonic motor of the present invention includes a stator and a rotor which are opposed to each other and pressed against each other via a buffer friction member, and a predetermined vibration is applied to a vibrator provided on at least one of the stator and the rotor. In the ultrasonic motor that vibrates the vibrator by supplying a signal of a frequency of the same and drives the rotor by a traveling wave generated on the side having the vibrator among the stator and the rotor, the stator or the rotor A pair of engaging portions provided on each one of the member and the buffering friction member and engaging with each other to restrict the rotational movement of the buffering friction member with respect to the one member; And a hole having a size to which the shaft portion of the rotor is inserted to restrict the radial movement of the cushioning friction member.

According to the ultrasonic motor of the present invention, the pair of engaging portions provided on either the stator or the rotor and the cushioning friction member engage with each other to form the cushioning friction member. The movement in the rotation direction with respect to one of the members is restricted. That is, the cushioning friction member is immobilized in the rotational direction together with the stator when engaged with the stator, and rotates with the rotor in the rotational direction when engaged with the rotor. Further, the hole provided in the center of the buffer friction member and into which the shaft portion of the rotor is inserted restricts the radial movement of the buffer friction member. Therefore, the cushioning friction member does not rotate unstably due to the generated traveling wave, and the rotation of the rotor is favorably controlled. Further, since no adhesive is interposed on the pressure contact surface on which the load acts, generation of abnormal noise is prevented.

Further, the ultrasonic motor according to the present invention includes a stator and a rotor which are opposed to each other and pressed against each other via a buffering friction member. In the ultrasonic motor that vibrates the vibrator by supplying a signal of a frequency of the same and drives the rotor by a traveling wave generated on the side having the vibrator among the stator and the rotor, the stator or the rotor And a pair of engaging portions provided on each one of the member and the buffering friction member to regulate the radial movement and the rotation direction movement of the buffering friction member with respect to the one member by engaging with each other. .

According to the ultrasonic motor of the present invention, the pair of engaging portions provided on either the stator or the rotor and the cushioning friction member engage with each other to form the cushioning friction member. The movement in the radial direction and the rotation direction with respect to one of the members is restricted. That is, the damping friction member is immobilized in the rotation direction together with the stator when engaged with the stator while being restricted from moving in the radial direction, and rotates together with the rotor when engaged with the rotor. Follow in the direction. Therefore, the cushioning friction member does not rotate unstably due to the generated traveling wave, and the rotation of the rotor is favorably controlled. Also, since no adhesive is interposed on the pressure contact surface where the load acts,
The generation of abnormal noise is prevented.

Here, it is preferable that the pair of engaging portions include a convex portion and a groove or a hole engaging with the convex portion. When such a configuration is adopted, the cost is reduced because the configuration is simple.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of an ultrasonic motor according to the present invention will be described below with reference to the accompanying drawings. In the description of the drawings, the same elements or elements having the same functions will be denoted by the same reference symbols, without redundant description.

FIG. 1 is a cross-sectional view showing an ultrasonic motor according to the first embodiment. This ultrasonic motor includes an ultrasonic motor main body 1 composed of a mechanical drive mechanism and a drive circuit 2 for driving the ultrasonic motor main body 1.

The ultrasonic motor body 1 has a fixing base 3 fixed to a fixed side of a main body device such as a camera to which the ultrasonic motor is applied, and a circular outer edge fixed on the fixing base 3. A stator 5, a rotating base 4 that penetrates the fixing base 3 and a central portion of the stator 5, is rotatably supported by a bearing 7 fixed to the stator 5, and is press-fitted and fixed to the rotating shaft 4. And a rotor 6 having a circular outer edge opposed to the rotor 5. The rotor 6 is rotated by a traveling wave traveling in a circumferential direction on the surface (upper side in the figure) of the stator 5 (details will be described later).

The stator 5 includes an annular vibrator 5v made of a ceramic piezoelectric element, and an annular elastic body 5e made of metal with the vibrator 5v adhered to the outer periphery of the back surface. Outer peripheral portion 5o and inner peripheral portion 5i of this elastic body 5e
Is thick, the vibrator 5v is attached to the back surface of the outer peripheral portion 5o, and the inner peripheral portion 5i is fixed to the fixing base 3 by, for example, screwing. An annular intermediate portion 5m between the outer peripheral portion 5o and the inner peripheral portion 5i of the elastic body 5e is thin, and the intermediate portion 5m facilitates the vibration of the outer peripheral portion 5o.
Vibration transmission between the outer peripheral portion 5o and the inner peripheral portion 5i is suppressed.

The piezoelectric vibrator 5v has a plurality of circumferentially divided regions, and has been subjected to a polarization process in advance so that the polarization directions in the thickness direction in the adjacent regions are opposite to each other. . These regions are divided into a sine-side electrode portion and a cos-side electrode portion, and the sine-side electrode portion and the cos-side electrode portion have an electrical angle of 90 degrees.
° It is arranged so as to be spaced apart in the circumferential direction.

The rotor 6 is formed of an annular elastic body made of metal. The inner peripheral portion 6i of the rotor 6 and the outer peripheral portion 6o facing the outer peripheral portion 5o of the stator 5 are thick, and an annular thin intermediate portion 6m is provided between the outer peripheral portion 6o and the inner peripheral portion 6i of the rotor 6. And the inner peripheral portion 6i is
Press-fit and fixed. A flange portion 4f is provided on the upper portion of the rotating shaft 4, and a snap ring 9 such as a C-ring is attached on a lower portion thereof. A spacer 10 is provided between the snap ring 9 and the bearing 7. The compression spring 11 is interposed through. The rotating shaft 4 and the rotor 6 are constantly urged downward by the compression spring 11 and the flange portion 4f.

The rotor 6 has a narrow annular convex portion 6p in the outer peripheral portion 6o substantially at the center of the surface facing the outer peripheral portion 5o of the stator 5. When the stator-side elastic body 5e and the rotor 6 are brought into full contact, the excitation side (stator-side elastic body)
Most of the vibration is transmitted to the other side (rotor), and the displacement of the traveling wave is attenuated. However, the rotor 6 has the convex portion 6p, and the pressure contact surface is narrowed as compared with the entire surface contact. Therefore, a normal traveling wave can be formed on the stator-side elastic body 5e.

The rotor-side convex portion 6p and the outer peripheral portion 5 of the stator 5
An annular cushioning friction member 12 made of, for example, resin is interposed between the cushioning member o and the cushioning friction member 12 in a state of being pressed against them. That is, the rotor-side protrusion 6p is connected to the compression spring 11
Of the stator 5 via the cushioning friction member 12 by the elastic force of
Is pressed against the outer peripheral portion 5o.

The cushioning friction member 12 serves as a kind of vibration low-pass filter that operates so that the traveling wave generated in the outer peripheral portion 5o of the stator 5 is hardly transmitted to the rotor 6 side. A normal traveling wave is generated, and direct contact between metals (the outer peripheral portion 5o and the convex portion 6p) is avoided to prevent generation of abnormal noise (squealing noise) and further improve durability of the press contact portion.

On both sides of the rotor side convex portion 6p, an annular gap portion 8a is formed by the convex portion 6p and the cushioning friction member 12.
8b are each defined.

In this embodiment, these gaps 8a, 8
The gap 13a is filled with an adhesive 13 by utilizing one of the gaps 8b (the outer gap in this embodiment) of the rotor 6b. Adhesively fixed to the side.

The structure of the ultrasonic motor body 1 has been described above.
For the drive circuit 2 for driving the ultrasonic motor body 1, the sin-side electrode portion of the piezoelectric vibrator 5v and the cos
The side electrode unit is connected. The drive circuit 2 applies a sine wave voltage signal (sine wave voltage signal) between the ground (GND) and the sin-side electrode of the piezoelectric vibrator 5v, and applies this between the ground and the cos-side electrode. A sine wave voltage signal (cos wave voltage signal) having a phase difference of 90 ° in electrical angle is applied simultaneously. At this time, the frequency of the applied voltage signal is a frequency at which the stator 5 itself resonates most (resonant frequency) or a frequency in the vicinity thereof.

A signal having such a frequency is transmitted to the piezoelectric vibrator 5v.
Is applied, the piezoelectric vibrator 5v vibrates, and a traveling wave traveling in the circumferential direction is generated on the surface of the outer peripheral portion 5o of the stator 5 by combining the standing waves. At this time, the rotor-side convex portion 6p that makes the pressure contact surface narrower than the entire surface contact suppresses the attenuation of the displacement amount of the generated traveling wave, and the buffer friction member 12 functions as a low-pass filter for vibration. Therefore, a normal traveling wave is formed on the outer peripheral portion 5o of the stator 5.
When this traveling wave is generated, each point of the minute area on the surface of the outer peripheral portion 5o of the stator 5 is moved in a plane defined by the traveling direction of the traveling wave and the thickness direction of the stator-side elastic body 5e. Performs elliptical motion in the opposite direction to the direction. The driving force due to the elliptical motion is accurately transmitted to the rotor-side convex portion 6p through the buffer friction member 12 which is pressed against the outer peripheral portion 5o of the stator 5. Thereby, the rotor 6 rotates in the direction opposite to the traveling direction of the traveling wave. At this time, the generation of abnormal noise (squealing noise) is prevented by the buffer friction member 12, and the durability of the press contact portion is improved. When the phase of the applied voltage is reversed, the traveling direction of the traveling wave is reversed, and the rotor 6 also rotates in the direction opposite to the above-described rotation direction.

In this embodiment, in particular, in the present embodiment, the gap 8a beside the rotor-side protrusion 6p is used to fill the gap 8a with the adhesive 13, and the cushioning friction member 12 is bonded to the rotor 6 side. Due to the fixed configuration, the cushioning friction member 12 rotates together with the rotor 6 rotating by the normal traveling wave, and does not rotate in an unstable manner as in the related art. As a result, the rotation of the rotor 6 can be favorably controlled. Further, since the adhesive 13 does not intervene at the pressure contact surface on which the load acts, that is, at the position facing the convex surface 6q of the rotor-side convex portion 6p, generation of abnormal noise (slap noise) during rotation of the rotor 6 can be prevented. become.

In this embodiment, the outer gap 8a of the gaps 8a and 8b beside the rotor-side protrusion 6p is used.
Although the adhesive 13 for adhering and fixing the buffer friction member 12 is filled, the gap 8b on the inside may be filled, or the gaps 8a and 8b may be filled. .

FIG. 2 is a cross-sectional view showing a stator, a rotor, and a cushioning friction member of an ultrasonic motor according to a second embodiment. The ultrasonic motor of the second embodiment is
The difference from the embodiment is that, instead of the rotor-side convex portion 6p, an outer peripheral surface thereof is flush with the outer peripheral surface of the rotor 6 and an annular convex portion 16p defining a gap 18b inside thereof.
And the gap 13b is filled with the adhesive 13 so that the cushioning friction member 12 is bonded and fixed to the rotor 6 side.

Even with this configuration, the same effect as in the first embodiment can be obtained. That is, since the buffer friction member 12 rotates together with the rotor 6, the rotation of the rotor 6 can be controlled well, and the adhesive 13 does not intervene at the pressure contact surface where the load acts, that is, at the position facing the convex surface 16q of the rotor side convex portion 16p. Therefore, generation of abnormal noise (slap noise) when the rotor 6 rotates can be prevented.

The rotor-side convex portion 16p is provided on the inner peripheral side of the outer peripheral portion 6o of the rotor 6, and a gap defined outside the convex portion 16p is filled with an adhesive 13 to form a cushioning friction member. 12 may be bonded and fixed to the rotor 6 side.

FIG. 3 is a cross-sectional view showing a stator, a rotor, and a cushioning friction member of an ultrasonic motor according to a third embodiment. The ultrasonic motor of the third embodiment is
The difference from the embodiment is that, while eliminating the rotor-side projection 6p and bringing the outer peripheral portion 6o into full contact with the cushioning friction member 12, a narrow annular annular portion is formed substantially at the center of the surface of the outer peripheral portion 5o of the stator 5. The convex portion 5p is provided, and the gap 13b is filled with the adhesive 13 using the gap portion 28b defined inside the convex portion 5p, so that the cushioning friction member 12 is bonded and fixed to the stator 5 side. That is the point.

According to the ultrasonic motor configured as described above, the stator-side convex portion 5p that makes the pressure contact surface narrower than the entire surface contact suppresses the attenuation of the displacement amount of the generated traveling wave. A normal traveling wave can be formed on the convex portion 5p.

In particular, since the cushioning friction member 12 is immobilized together with the stator 5, it does not rotate in an unstable manner as in the prior art. As a result, the rotation of the rotor 6 can be controlled well. In addition, since the adhesive 13 does not intervene at the pressure contact surface on which the load acts, that is, at the position facing the convex surface 5q of the stator-side convex portion 5p, generation of abnormal noise (slap noise) when the rotor 6 rotates can be prevented.

As described in the first embodiment, the adhesive 13 may be filled in the gap 28a outside the stator-side protrusion 5p.
a, 28b may be filled.

Further, in the same manner as described in the second embodiment, the stator-side protrusion 5p is
The adhesive 13 is provided on one of the outer peripheral side and the inner peripheral side of the protruding portion 5p.
And the cushioning friction member 12 may be bonded and fixed to the stator 5 side.

FIG. 4 is a cross sectional view showing a stator, a rotor and a cushioning friction member of an ultrasonic motor according to a fourth embodiment. The ultrasonic motor according to the fourth embodiment is
The difference from the embodiment is that an annular gap portion 38a cut in a tapered shape is provided on a portion of the outer peripheral portion 5o of the stator 5 on the outer peripheral side from a position facing the convex surface 6q of the rotor-side convex portion 6p, The difference is that the gap 13a is filled with the adhesive 13 so that the cushioning friction member 12 is bonded and fixed to the stator 5 side.

Even with such a configuration, there is a change in the configuration in which the adhesive 13 for fixing the cushioning friction member does not intervene at the pressure contact surface on which the load acts, that is, at the position facing the convex surface 6q of the rotor-side convex portion 6p. Therefore, the same effect as in the first embodiment can be obtained.

In the outer peripheral portion 5o of the stator 5, an annular gap portion cut in a tapered shape is provided at a portion on the inner peripheral side from a position facing the convex surface 6q of the rotor side convex portion 6p. May be filled with an adhesive 13 so that the cushioning friction member 12 is bonded and fixed to the stator 5 side.
Further, a gap may be provided on the outer circumference side and the inner circumference side, and the gap 13 may be filled with the adhesive 13.

FIG. 5 is a cross-sectional view illustrating a stator, a rotor, and a cushioning friction member of an ultrasonic motor according to a fifth embodiment. The ultrasonic motor according to the fifth embodiment is the third type.
The difference from the embodiment is that an annular gap portion 48b cut in a tapered shape is provided in a portion of the outer peripheral portion 6o of the rotor 6 on the inner peripheral side from a position facing the convex surface 5q of the stator-side convex portion 5p. The gap 48b is filled with an adhesive 13, and the cushioning friction member 12 is bonded and fixed to the rotor 6 side.

Even with such a configuration, there is a change in the configuration in which the adhesive 13 for fixing the cushioning friction member does not intervene at the pressure contact surface on which the load acts, that is, at the position facing the convex surface 5q of the stator-side convex portion 5p. Therefore, the same effect as in the third embodiment can be obtained.

An annular gap portion which is notched in a tapered shape is provided on a portion of the outer peripheral portion 6o of the rotor 6 which is on the outer peripheral side from a position facing the convex surface 5q of the stator side convex portion 5p. An adhesive 13 may be filled to bond and fix the buffer friction member 12 to the rotor 6 side. Further, a gap may be provided on the outer circumference side and the inner circumference side, and the gap 13 may be filled with the adhesive 13.

Further, in the fourth and fifth embodiments,
Although the gaps 38a and 48b are annular gaps cut out in a tapered shape, the gaps may be flat annular gaps with a constant gap interval, that is, except for the pressure contact surface on which a load acts. Any configuration may be used as long as the adhesive 13 is interposed at the position where the adhesive 13 is located.

FIG. 6 is a cross-sectional view showing a stator, a rotor, and a cushioning friction member of an ultrasonic motor according to a sixth embodiment, and FIG. 7 is a stator and a rotor of the ultrasonic motor according to the sixth embodiment. FIG. 8 is a cross-sectional view taken along the line XX in FIG.

The ultrasonic motor according to the sixth embodiment has first to
The difference from the fifth embodiment is that the buffer friction member 12 is
Instead of the configuration in which the adhesive 13 is used to bond and fix to either the rotor 6 side or the stator 5 side, the cushioning friction member 1
2 is configured to engage with either the rotor 6 side or the stator 5 side.

That is, in the sixth embodiment, an engaging projection 6r protruding toward the buffer friction member 12 is provided on a part of the outer peripheral portion of the outer peripheral portion 6o of the rotor 6, and the cushion friction member 12 An engagement groove 12r into which the engagement protrusion 6r enters and engages is provided on a part of the outer peripheral side of. When the pair of engaging portions 14 composed of the engaging convex portions 6r and the engaging grooves 12r are engaged, the movement of the cushioning friction member 12 in the rotation direction with respect to the rotor 6 is restricted. At this time, since the outer peripheral side of the engagement groove 12r is open, the radial movement of the cushioning friction member 12 is not restricted by this engagement.

On the other hand, a hole 12h having a diameter slightly larger than the rotation shaft 4 is provided at the center of the cushioning friction member 12, and the rotation shaft 4 is inserted into the hole 12h. The configuration in which the rotating shaft 4 is inserted into the hole 12h restricts the radial movement of the cushioning friction member 12.

According to the ultrasonic motor configured as described above, when the rotor 6 rotates, the cushioning friction member 12 moves together with the rotor 6 while the movement in the radial direction is restricted by the hole 12 h of the cushioning friction member 12. Since it rotates in the rotation direction, the cushioning friction member 12 does not rotate in an unstable manner as in the related art, can control the rotation of the rotor 6 well, and also has a pressure contact surface on which a load acts, that is, the rotor side protrusion 6.
Since the adhesive 13 does not intervene at the position facing the convex surface 6q of p, generation of abnormal noise (slapping noise) when the rotor 6 rotates can be prevented.

In addition, since the engaging projections 6r and the engaging grooves 12r forming the pair of engaging portions 14 have simple structures,
Cost reduction can be achieved.

FIG. 9 is a sectional view showing a main part of an ultrasonic motor according to a seventh embodiment, and is a sectional view corresponding to FIG. The ultrasonic motor according to the seventh embodiment is different from the ultrasonic motor according to the sixth embodiment in that an engagement protrusion 6ra protruding toward the buffer friction member 12 is provided on a part of the inner periphery of the inner periphery 6i of the rotor 6. At the same time, a part of the inner peripheral side of the cushioning friction member 12 is provided with an engagement groove 12ra which is connected to the hole 12h of the cushioning friction member 12 and in which the engagement protrusion 6ra enters and engages. It is. The engagement protrusion 6ra may be provided on the rotating shaft 4.

The engaging projection 6ra and the engaging groove 12r
It is needless to say that the same effect as in the sixth embodiment can be obtained even if a pair of engaging portions 24 constituted by a are used.

FIG. 10 is a sectional view showing a main part of an ultrasonic motor according to the eighth embodiment, and is a sectional view corresponding to FIG. The ultrasonic motor according to the eighth embodiment is different from the ultrasonic motor according to the sixth embodiment in that a part of the rotor 6 includes a cushioning friction member 1.
This is the point that an engaging projection 6rb projecting to the second side is provided, and an engaging hole 12rb into which the engaging projection 6rb enters and engages is provided in a part of the cushioning friction member 12.

The engaging projection 6rb and the engaging hole 12r
When the pair of engaging portions 34 constituted by b are engaged, the rotational and radial movements of the cushioning friction member 12 with respect to the rotor 6 are restricted. Therefore, the hole 12ha into which the rotating shaft 4 of the cushioning friction member 12 is inserted does not need to restrict the movement in the radial direction, and as shown in FIG.
It may be formed relatively large with respect to the rotating shaft 4.

According to the ultrasonic motor configured as described above, when the rotor 6 rotates, the cushioning friction member 12 moves together with the rotor 6 while the movement in the radial direction is restricted by the engagement of the pair of engagement portions 34. Since the cushioning friction member 12 is rotated in the rotation direction, the cushioning friction member 12 does not rotate in an unstable manner as in the related art, and can control the rotation of the rotor 6 well, and at the same time, a pressure contact surface on which a load acts, that is, the rotor-side convex portion 6p Convex surface 6q
Since the adhesive 13 does not intervene at the position opposing the above, generation of abnormal noise (slap noise) when the rotor 6 rotates can be prevented.

In the sixth to eighth embodiments, the engaging protrusions 6r, 6ra, 6rb are provided on the rotor side, and the engaging grooves 12r, 12ra or the engaging holes 12r of the buffer friction member 12 are provided.
rb, but a similar engaging projection is provided on the stator side so that the engaging groove 12
The same effect as in the sixth to eighth embodiments can be obtained even if the buffer friction member 12 is engaged with the stator 5 in the rotational direction by engaging with the r, 12ra or the engagement hole 12rb.

Furthermore, even if the relationship between the engaging projection and the engaging groove (engaging hole) in the sixth to eighth embodiments is reversed,
The same effect as in the eighth embodiment can be obtained.

As described above, the invention made by the inventor has been specifically described based on the embodiments. However, the present invention is not limited to the above embodiments, and can be variously modified without departing from the gist thereof. Needless to say,
For example, as described in JP-A-2-179281, the rotor is made of an elastic body, and a piezoelectric vibrator is fixed to the back surface of the rotor. The piezoelectric vibrator has the same structure as that described in the above embodiment. By applying two-phase drive signals having similar phases, a traveling wave traveling in the circumferential direction is also generated on the rotor surface, and the traveling wave generated on the rotor surface and the traveling wave generated on the stator surface described above are generated. Utilizing the cushioning friction member 12 described in the above embodiment also for an ultrasonic motor of a type that rotationally drives a rotor,
It goes without saying that the present invention can be applied by interposing between the rotor and the stator.

Further, the construction (fixed with an adhesive) described in the first to fifth embodiments provides a linear ultrasonic motor in which the shape of the movable element is a long plate and the movable element is driven as a slider. The same can be applied to this.

[0063]

The ultrasonic motor according to the present invention is provided on one of the stator and the movable member, and is provided with a convex portion which comes into pressure contact with the other member via a cushioning friction member, and a gap beside the convex portion. And an adhesive for adhering the cushioning friction member to one of the members, and suppressing the attenuation of the traveling wave generated by making the pressure contact surface narrower than the whole surface contact. The buffer friction member is adhered and fixed to one of the members by the adhesive disposed in the gap portion using the gap portion on the side of the portion, and the buffer friction member is unstable due to the traveling wave whose attenuation is suppressed. In this configuration, the adhesive is not interposed on the press-contact surface on which the load acts, so that it is possible to control the movement of the mover satisfactorily and to prevent generation of abnormal noise.

Also, the ultrasonic motor according to the present invention is provided on one of the stator and the movable member, and has a convex portion which comes into pressure contact with the other member via a buffer friction member, and the convex portion of the other member. A gap portion provided between the cushioning member and the portion provided except for a surface facing the convex surface of the portion,
Interposed in the gap portion, an adhesive for bonding the cushioning friction member to the other member, comprising: attenuating the traveling wave generated by narrowing the pressure contact surface compared to the entire surface contact, The adhesive arranged in the gap portion adheres and fixes the cushioning friction member to the other member so that the cushioning friction member does not rotate unstably due to the traveling wave whose attenuation is suppressed, and the load is reduced. The structure is such that the adhesive does not intervene on the press contact surface on which the action is made, so that it is possible to control the movement of the mover satisfactorily and to prevent the generation of abnormal noise.

Further, the ultrasonic motor according to the present invention is provided on each of either the stator or the rotor and the cushioning friction member, and engages with each other to rotate the cushioning friction member relative to one of the members. A pair of engaging portions for regulating the movement of the frictional member, and a hole having a size provided at the center of the cushioning friction member, the shaft portion of the rotor being inserted to regulate the radial movement of the cushioning friction member. The buffer friction member is provided with a rotational movement and a radial movement with respect to one member of the shock-absorbing friction member, so that the shock-absorbing friction member is prevented from being unstablely rotated by the generated traveling wave. Since it is configured so that the adhesive does not intervene on the pressure contact surface where
The rotation of the rotor can be favorably controlled, and generation of abnormal noise can be prevented.

Further, the ultrasonic motor according to the present invention is provided on each of either the stator or the rotor and the cushioning friction member, and engages with each other so as to engage the cushioning friction member in the radial direction with respect to the one member. And a pair of engaging portions that regulate the movement in the rotation direction and the movement thereof, so that the cushioning friction member does not rotate unstably due to the generated traveling wave,
Since the configuration is such that the adhesive does not intervene on the pressure contact surface on which the load acts, it is possible to control the rotation of the rotor satisfactorily and to prevent the generation of abnormal noise.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view showing an ultrasonic motor according to a first embodiment.

FIG. 2 shows a stator of an ultrasonic motor according to a second embodiment,
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 3 shows a stator of an ultrasonic motor according to a third embodiment,
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 4 shows a stator of an ultrasonic motor according to a fourth embodiment;
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 5 shows a stator of an ultrasonic motor according to a fifth embodiment;
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 6 shows a stator of an ultrasonic motor according to a sixth embodiment;
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 7 shows a stator of an ultrasonic motor according to a sixth embodiment;
It is a right view which extracts and shows a rotor and a buffer friction member.

FIG. 8 is a cross-sectional view taken along line XX in FIG.

FIG. 9 is a sectional view showing a main part of an ultrasonic motor according to a seventh embodiment, and is a sectional view corresponding to FIG.

FIG. 10 is a sectional view showing a main part of an ultrasonic motor according to an eighth embodiment, and is a sectional view corresponding to FIG.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Ultrasonic motor main body, 2 ... Drive circuit, 4 ... Rotary axis, 5
... stator (stator), 5p, 6p, 16p ... convex part, 5
q, 6q, 16q: convex surface, 5v: vibrator, 6: rotor (movable element), 8a, 8b, 18b, 28a, 28b, 3
8a, 48b: gap portion, 12: cushioning friction member, 12h ...
Holes in buffer friction member, 13 ... adhesive, 14, 24, 34
... A pair of engaging portions.

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[Submission date] April 6, 1999

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FIG. 1 is a cross-sectional view showing an ultrasonic motor according to a first embodiment.

FIG. 2 shows a stator of an ultrasonic motor according to a second embodiment,
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 3 shows a stator of an ultrasonic motor according to a third embodiment,
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 4 shows a stator of an ultrasonic motor according to a fourth embodiment;
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

FIG. 5 shows a stator of an ultrasonic motor according to a fifth embodiment;
It is a cross-sectional view which extracts and shows a rotor and a buffer friction member.

[Description of Signs] 1 ... Ultrasonic motor main body, 2 ... Drive circuit, 4 ... Rotary axis, 5
... stator (stator), 5p, 6p, 16p ... convex part, 5
q, 6q, 16q: convex surface, 5v: vibrator, 6: rotor (movable element), 8a, 8b, 18b, 28a, 28b, 3
8a, 48b: gap portion, 12: buffer friction member, 13: adhesive.

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Claims (5)

[Claims] 1. A stator and a mover which oppose each other and are pressed against each other via a buffer friction member, and a signal of a predetermined frequency is supplied to a vibrator provided on at least one of the stator and the mover. An ultrasonic motor that drives the mover by a traveling wave generated on a side of the stator and the mover having the vibrator by vibrating the vibrator by performing the stator or the mover. A convex portion provided on one of the members and pressed against the other member via the buffer friction member, and the buffer friction member is bonded to the one member with a gap interposed between the convex portions. An ultrasonic motor comprising: an adhesive; 2. A system according to claim 1, further comprising: a stator and a movable member which are opposed to each other and press-contact with each other via a buffer friction member. An ultrasonic motor that drives the mover by a traveling wave generated on a side of the stator and the mover having the vibrator by vibrating the vibrator by performing the stator or the mover. A convex portion provided on any one of the members, and pressed against the other member via the cushioning friction member, provided at a position excluding a surface facing the convex surface of the convex portion of the other member, An ultrasonic motor, comprising: a gap formed between the cushioning friction member; and an adhesive interposed in the gap to adhere the cushioning friction member to the other member. 3. A stator and a rotor opposed to each other and pressed against each other via a buffer friction member, and a signal of a predetermined frequency is supplied to a vibrator provided on at least one of the stator and the rotor. An ultrasonic motor that drives the rotor by a traveling wave generated on the side of the stator and the rotor that has the transducer by vibrating the transducer by performing the stator or the rotor. A pair of engaging portions provided on each one of the member and the buffering friction member, and engaging with each other to regulate movement of the buffering friction member in the rotational direction with respect to the one member; An ultrasonic motor comprising: a hole provided at the center of the member and having a size into which a shaft portion of the rotor is inserted to restrict the radial movement of the cushioning friction member. 4. A stator and a rotor which are opposed to each other and are pressed against each other via a buffer friction member, and a signal of a predetermined frequency is supplied to a vibrator provided on at least one of the stator and the rotor. An ultrasonic motor that drives the rotor by a traveling wave generated on the side of the stator and the rotor that has the transducer by vibrating the transducer by performing the stator or the rotor. And a pair of engaging portions provided on each of the one member and the buffering friction member, and engaging each other to restrict radial movement and rotational movement of the buffering friction member with respect to the one member. Ultrasonic motor equipped with. 5. The ultrasonic motor according to claim 3, wherein the pair of engaging portions comprises a convex portion and a groove or a hole engaging with the convex portion.