DE102013110356B4 - ultrasonic actuator - Google Patents

Abstract

Ultrasonic actuator (1), preferably for an ultrasonic motor, comprising a piezoelectric element (2) in the form of a rectangular piezoelectric plate (3) with two major surfaces (4, 5) with the largest surface area and the shorter and longer side surfaces (6, 7, 8 , 9), wherein on each of the main surfaces (4, 5) at least one electrode for electrical excitation of the ultrasonic actuator is arranged, and at one of the shorter side surfaces (8), which forms a connecting side surface, a friction element (14) is arranged Friction member having a base portion (15) having a connection surface (16) and an operative portion adjoining the base portion having a friction portion at its distal end, the friction member being connected to the connection side surface via the connection surface, and the surface of the connection surface being equal to the connection side surface , and where the Wi rkabschnitt extends in a direction away from the base portion so that the parallel to the connection side surface extending cross-sectional surfaces of the active portion, the effective portion cross-sectional areas S1, S2, S3, ..., Sn, continuously narrow in the extension direction, characterized in that a parallel to the two Main surfaces of the ultrasonic actuator extending cross-section of the active portion, which forms a Wirkabschnittslängsquerschnitt, a symmetrical shape with curvature sections (24), each of the curvature sections of the effective section longitudinal section by a reciprocal power function with the exponent 2 or 4 is writable.

Description

The invention relates to a Ultraschallaktor according to claims 1 to 6. Die DE 199 45 042 C2 describes a piezoelectric drive with a plate-shaped and substantially rectangular actuator, in which a friction element is arranged on one of its end faces. The actuator is designed to execute a bending vibration and a longitudinal vibration.

The US Pat. No. 6,879,085 B1 teaches a piezoelectric actuator with an actuator in the form of a thin, rectangular plate, the plate being provided with recesses which serve to shift the resonant frequency of the actuator.

US 2013/0 107 337 A1 discloses a piezoelectric and columnar element having a slider disposed thereon for contact with a drive section. The actual contact portion of the sliding element has a rounded shape.

The DE 101 54 526 A1 describes an actuator of a piezoelectric actuator in the form of a plate or a hollow cylinder, wherein the dimensions of the actuator are chosen such that the propagating in the actuator standing longitudinal acoustic waves along its length and along its height are the same.

The EP 2 200 101 A1 teaches an ultrasonic motor with an actuator in the form of a piezoelectric plate, wherein on one of its longer side surfaces, a friction element is arranged, which has two substantially vertical planar side surfaces, two inclined planar side surfaces and two concave curved side surfaces.

From the prior art according to the documents US 5 714 833 A or US Pat. No. 6,979,934 B1 are ultrasound actuators of ultrasonic motors with piezoelectric elements in the form of a rectangular piezoelectric plate having two major surfaces, with two side surfaces and with two end faces, wherein a friction element is disposed on one of the end faces known.

These ultrasonic actuators are designed so that two acoustic standing waves are simultaneously generated in them by means of an acoustic wave generator, namely a bending counter shaft and a longitudinal standing shaft which propagate longitudinally to the actuator. The bending wave thereby determines the oscillation amplitude of the actuator in the transverse direction, while the longitudinal standing wave determines the oscillation amplitude in the longitudinal direction.

When using such actuators in ultrasonic motors is determined by the bending shaft, the maximum speed of movement of a driven element, and by the Längsstehwelle the frictional force in the frictional contact, d. H. determines the force developed by the element to be driven.

The disadvantage of these actuators is that the ratio of the amplitude of the bending wave to the amplitude of the longitudinal standing wave is always constant and is determined by the configuration or arrangement of the electrodes. Therefore, in these actuators, the ratio of maximum movement speed to maximum force developed by the actuator is always constant.

In ultrasonic motors with such actuators, it is therefore impossible to increase the maximum force developed by the element to be driven without simultaneously increasing its maximum speed of movement. In other words, with such actuators, it is impossible to build an ultrasonic motor having a low moving speed and a sufficiently high force provided by the element to be driven. For this reason, occur in ultrasonic motors with such actuators at low speeds high mechanical losses in the actuators in no-load operation. Furthermore, they have a low efficiency in operation with alternating mechanical load. As a result, the actuators heat in no load operating regime, whereby the operating temperature range of the corresponding engines is restricted. In addition, in the no-load operating regime, increased abrasion of the friction element occurs, which shortens the life of the actuator in the engine.

It is therefore an object of the invention to provide an ultrasonic actuator in which a high force developed by the actuator results without increasing its maximum oscillation speed. At the same time in the ultrasonic actuator according to the invention, the mechanical losses during loadless operation or changing load and low speeds of movement of the driven element should be low, so that the heating of the ultrasonic actuator is reduced and the service temperature range is increased, or the abrasion of the friction element decreases and the Lifespan increased.

The object of the invention is achieved by an ultrasonic actuator according to claim 1, wherein the subsequent dependent claims comprise at least expedient refinements and developments. It is therefore assumed that an ultrasonic actuator, a piezoelectric element in the form of a rectangular piezoelectric Plate having two major areas in the largest area and the major surfaces interconnecting shorter and longer side surfaces, wherein at each of the main surfaces at least one electrode for electrical excitation of the ultrasonic actuator is arranged, and at one of the shorter side surfaces, which forms a connecting side surface, a friction element is arranged. The piezoelectric plate thus has two major surfaces, which are significantly larger from the surface than the other surfaces, which are side surfaces. Here, the side surfaces differ in their longitudinal extent. The friction member is disposed on a shorter side surface of the piezoelectric plate, which is an end face.

The friction element has a base portion with a connecting surface and an operative portion adjoining the base portion with a friction portion at its distal end, the distal end of the operative portion being spaced from the base portion. The friction portion has a friction surface which is provided for frictional contact with an element to be driven via the friction element.

The friction member is connected to the connection side surface of the piezoelectric plate via the connection surface, and the surface of the connection surface is equal to the connection side surface. The operative portion extends in a direction away from the base portion, i.e., in a direction away from the base portion. away from the base section, that the cross-sectional surfaces of the active section that run parallel to the connection side surface and that form the active section cross-sectional surfaces shrink continuously in the extension direction. Here, the operative portion at the interface with the base portion has an effective sectional area that is identical or nearly identical to the cross-sectional area of the base portion, the cross-sectional area resulting from the intersection of a plane parallel to the connection side surface and the base portion through which the plane passes. Starting from the effective section cross-sectional area at the interface between the base section and the active section, the effective section cross-sectional area decreases continuously in the extension direction of the active element, so that the corresponding cross-sectional area of the friction section is significantly smaller than the effective section cross-sectional area in the region of the interface between base section and active section.

A parallel to the two main surfaces of the ultrasonic actuator extending cross-section of the active portion, which forms a functional section longitudinal cross-section, has a symmetrical shape with curved sections or curved lines. This means that the effective section longitudinal cross-section has a symmetry line, and the cross-sectional geometry has a curvature at least in sections on both sides of the symmetry line. Each of the curved sections or each of the curved lines of the active section longitudinal section can be described by a reciprocal power function with the exponents 2 or 4. Advantageously, the effective section longitudinal cross-section has a parabolic shape.

The oscillations produced in the ultrasonic actuator by application of an electrical voltage to the electrodes or the corresponding vibrations of the connecting side surface are transmitted to the friction element arranged thereon, so that the latter in turn performs vibrations, whereby due to the special geometry of the friction element a comparatively large oscillation amplitude or large amplitude the longitudinal vibrations of the friction section or the friction surface can be achieved. As a result, a high frictional force is possible in frictional contact between friction element and element to be driven of a corresponding ultrasonic motor, which leads to an ultrasonic motor with increased driving force.

It may be advantageous that the effective section cross-sectional area has a right-angled or a circular or an elliptical shape. Here, mixed forms of the forms listed above are conceivable. In addition, it may be advantageous that the surface of the friction section forms a friction surface, and the friction surface consists of one or more planar sections and / or has a curved section. For example, the friction surface may consist of a single flat surface. But it can also consist of two or more flat and possibly inclined to each other surface sections. Furthermore, the friction surface may have a curved portion. In addition, it can be advantageous for the base section and / or the active section to have slots which run perpendicularly and / or parallel to the main surfaces of the ultrasound actuator. In particular, it may be advantageous in this case for the friction section to have slots which run parallel to the main surfaces of the ultrasound actuator.

Moreover, it may be advantageous that the friction element is attached to the connection side surface via an adhesive. Preferably, the adhesive consists of an adhesive.

In addition, it may prove to be an advantage that the friction element and the piezoelectric element are integrally formed with each other.

list of figures

• 1 : An embodiment of the ultrasonic actuator according to the invention
• 2 : Friction element of the ultrasonic actuator according to 1
• 3 : Friction element of the ultrasonic actuator according to 1 with an explanatory illustration relating to the tapered active section cross-sectional area
• 4 A further embodiment of a friction element of an ultrasound actuator according to the invention, with an explanatory illustration relating to the tapered active section cross-sectional area
• 5 FIG. 25: effective section of the longitudinal section of the friction element according to FIG 2 ; Representation 30: effective section longitudinal cross section of a further embodiment of a friction element of an ultrasonic actuator according to the invention
• 6 Figure 31: Top of an ultrasonic actuator according to the invention without friction element arranged thereon; Illustration 32: underside of the ultrasonic actuator according to illustration 31; Representation 33: Block diagram for an embodiment for the electrical contacting of the ultrasonic actuator according to the illustrations 31 and 32
• 7 Figure 35: Top of an ultrasonic actuator according to the invention without friction element arranged thereon; Illustration 36; Underside of the ultrasonic actuator according to illustration 35; Representations 37 and 38: Clarification of the polarization direction of the piezoceramic layers of the ultrasonic actuator according to the illustrations 35 and 36; Representation 39:
  • Arrangement of the electrodes in the electrode layers of the ultrasonic actuator according to the illustrations 35 and 36; Representation 40: Block diagram for an embodiment for electrical contacting of the ultrasonic actuator according to the representations 35 and 36th
• 8th Figure 43: Piezoelectric plate of an ultrasonic actuator according to the invention; Representation 44: Clarification of the phases of maximum deformation of the piezoelectric plate as shown in Figure 43 upon excitation of the second mode of a bending acoustic standing wave in this; Presentation 45:
  • Clarification of the vibrations of one of the shorter side surfaces of the piezoelectric plate as shown in Figure 43 upon excitation of the second mode of a bending acoustic standing wave in this; Presentation 46:
  • Clarification of the phases of maximum deformation of the piezoelectric plate as shown in Figure 43 upon excitation of the first mode of a longitudinal acoustic standing wave in this; Representation 47: Clarification of the vibrations of one of the shorter side surfaces of the piezoelectric plate as shown in Figure 43 upon excitation of the first mode of a longitudinal acoustic standing wave in this.
• 9 FIG. 48 shows a cross-section of an embodiment of a friction element of an ultrasound actuator according to the invention, showing its deformations on the basis of the vibrations transmitted thereto by the corresponding ultrasound actuator; Presentation 49:
  • Cross-section of a further embodiment of a friction element of an ultrasonic actuator according to the invention with an explanation of its deformations due to the vibrations transmitted to it by the corresponding ultrasonic actuator
• 10 : Representations 50 to 58: Different embodiments of a friction element of an ultrasonic actuator according to the invention
• 11 : An embodiment of a rotary ultrasonic motor with an ultrasonic actuator according to the invention
• 12 : Embodiment of a linear ultrasonic motor with an ultrasonic actuator according to the invention
• 13 : Representation of the vibration form of the friction element of an ultrasonic actuator according to the invention
• 14 FIG. 65: upper side of an embodiment of an ultrasonic actuator according to the invention as a two-phase actuator without a friction element arranged thereon; Illustration 66: underside of the ultrasonic actuator according to illustration 65; Representation 67: Block diagram for an embodiment for electrical contacting of the ultrasonic actuator according to the representations 65 and 66
• 15 FIG. 71: top side of a further embodiment of an ultrasonic actuator according to the invention as a two-phase actuator without a friction element arranged thereon; Illustration 72: underside of the ultrasonic actuator according to illustration 71; Representation 73: Electrode structure of the electrode layers of the ultrasonic actuator according to the illustrations 71 and 72; Representation 74: Block diagram for an embodiment for the electrical contacting of the ultrasonic actuator according to the illustrations 71 and 72
• 16 FIG. 75: Top side of a further embodiment of an ultrasonic actuator according to the invention as a two-phase actuator without a friction element arranged thereon; Illustration 76: underside of the ultrasonic actuator according to illustration 75; Representation 77: Block diagram for an embodiment for the electrical contacting of the ultrasonic actuator according to the illustrations 75 and 76
• 17 FIG. 78: top side of a further embodiment of an ultrasonic actuator according to the invention as a two-phase actuator; Illustration 79: underside of the ultrasonic actuator according to illustration 78; Illustration 80: Electrode structure of the electrode layers of the ultrasonic actuator according to the illustrations 78 and 79; Representation 81: Block diagram for an embodiment for the electrical contacting of the ultrasonic actuator according to the illustrations 78 and 79

1 shows a three-dimensional view of an ultrasonic actuator according to the invention 1 having a piezoelectric element 2 in the form of a rectangular monolithic piezoelectric plate 3 from a PZT ceramic with the two largest areas in terms of surface area 4 and 5 , the two longer side surfaces 6 and 7, as well as the two shorter side surfaces 8th and 9 , The shorter side surfaces 8th . 9 own the edges 10 . 11 . 12 and 13 ,

At the shorter side surface or end face 8th , which forms a connecting side surface, is a friction element 14 arranged. The friction element 14 here has a base section 15 with a connection surface 16 on. The edges 17 . 18 . 19 and 20 of the base section 15 in the area of the connection surface 16 are in contact or in coincidence with the edges 10 . 11 . 12 and 13 , and similarly, the area of the bonding surface 16 of the friction element identical to the connection side surface 8th ,

The friction element is made of aluminum oxide, but other hard and abrasion-resistant materials with a low specific weight or a low density are conceivable, for example zirconium dioxide or its compounds.

The connection between the friction element 14 and the piezoelectric plate 3 takes place with the aid of an adhesive in the form of a hard, yet elastic adhesive, wherein the adhesive on the one hand, the connection side surface 8 of the ultrasonic actuator 1 , and on the other hand the connection surface 16 of the base section 15 of the friction element 14 contacted. The adhesive here is such that the deformations on the connecting side surface 8th occur upon electrical excitation of the ultrasonic actuator, completely or almost completely on the friction element 14 be transmitted. The adhesive consists of epoxy resin filled with particles of a hard material. Likewise, the adhesive may be a fusible glass. Furthermore, as the adhesive materials are possible, which are a chemical compound with both the material of the piezoelectric plate 3 , as well as with the material of the friction element or with the material of the base portion of the friction element.

To the base section 15 of the friction element 14 closes an operative portion with a at its distal end - ie at the base portion 15 facing away from the region of action - arranged friction section, wherein the operative portion has two, a curvature having side surfaces 21 . 22 and a friction surface 23 having.

2 clarifies in detail the shape or geometry of the friction element of the ultrasonic actuator according to 1 , This has a height H, which in the present case corresponds to the height of the piezoelectric plate of the ultrasonic actuator.

3 explains the determination of the effective section cross-sectional area of the friction element according to 2 , The respective, from the distance to the base section 15 or from the y-position dependent effective section cross-sectional area results here as a sectional area between a plane which is parallel to the plane in which the connection side surface 8th or the connection surface of the base portion 15 lies (xz-plane), and the active section. Due to the curved side surfaces 21 . 22 arise in the direction of extension of the active portion, ie with increasing distance from the base portion, continuously decreasing or tapering Wirkabschnittquerschnittsflächen S1, S2, S3, ..., Sn.

In the active portion of the friction element according to 3 the effective section cross-sectional areas are rectangular or rectangular. However, they can also be circular or elliptical, or even form only one or more subregions of a circle or an ellipse (see in particular 4 ).

5 shows in presentation 25 the effective section longitudinal cross-section of the friction element according to 2 , In this case, the effective section longitudinal cross-section results as a sectional area between a plane which runs parallel to the two main surfaces of the ultrasound actuator (xy plane) and the active section. The effective section longitudinal cross-section results in a symmetrical with respect to the y-axis surface with the two curved sections or curved lines 24 , Each of these lines 24 can advantageously with a reciprocal power function with the exponent 2 or 4 to be discribed. Other exponents are also conceivable. The curved lines 24 each extending from the base portion in a direction away from the base portion and are bounded by the friction surface 23 , which is flat and in the cross-sectional representation correspondingly linear.

As shown 30 from 5 , which shows an effective section longitudinal cross-section of a further embodiment of a friction element of an ultrasonic actuator according to the invention, the curvature of the side surfaces can be 21 and 22 in the xy plane through the two straight lines 26 , 27 and the circle connected to them 28 describe the straight lines 26 . 27 in the points 29 the circle line 28 contact or touch tangentially. Again, the curved lines extend 24 each from the base portion in a direction away from the base portion and are bounded by the friction surface 23 , which is flat and in the cross-sectional representation correspondingly linear.

6 shows in presentation 31 the upper side of an ultrasonic actuator according to the invention without a friction element arranged thereon, the ultrasonic actuator representing a single-phase actuator or an actuator operated as a single-phase actuator. On the in presentation 31 recognizable main surface are two substantially equal, rectangular and diagonally opposite arranged excitation electrodes a and two substantially equal-sized, rectangular and also diagonally opposite arranged exciter electrodes b attached. presentation 32 from 6 shows the corresponding underside of the ultrasonic actuator, and on the main surface recognizable here, a general electrode c is arranged, which covers substantially the entire main surface. The direction of polarization of the piezoelectric material of the plate 3 is in the representations 31 and 32 indicated by the arrows or vectors with the index p. The polarization vector is normal or perpendicular to the electrodes a, b and c directed.

presentation 33 from 6 shows the block diagram for an embodiment for electrically contacting the ultrasonic actuator according to the representations 31 and 32. An electrical excitation device 34 with a switch 35 is about the connections 36 . 37 and 38 connected to the corresponding electrodes a, b and c. The exciter device 34 provides an electrical AC voltage U1 whose frequency f is equal to the operating frequency of the ultrasonic actuator 1 is.

When operating the switch 35 the voltage U1 is applied to the terminals 36 and 38 or to the connections 37 and 38 the electrical excitation device 34 placed. From the connections 36 and 38 respectively. 37 and 38 the electrical voltage reaches the electrodes a and c or the electrodes b and c of the piezoelectric element 2 ,

The at the electrodes 36 and 38 or at the electrodes 37 and 38 applied voltage U1 energized in the piezoelectric plate 3 of the piezo element 2 simultaneously the second mode of a bending acoustic standing wave and the first mode of a longitudinal acoustic standing wave.

7 shows in presentation 35 the top of another ultrasonic actuator according to the invention without a friction element arranged thereon. The ultrasonic actuator in this case has a multilayer piezoelectric plate, wherein the individual layers of the piezoelectric material are separated by the layers with the electrodes a, b and c (multilayer structure). This ultrasonic actuator also represents a single-phase actuator or is operated as such. In presentation 36 from 7 is the ultrasonic actuator as shown 35 shown from below. The representations 37 and 38 illustrate the polarization directions of the piezoelectric material of adjacent layers while imaging 39 shows the structure of the alternating electrode layers with the electrodes a, b and c respectively.

presentation 40 from 7 shows a block diagram of an embodiment for electrically contacting the ultrasonic actuator according to the representations 35 and 36 with the electrical excitation device 34 , the switch 35 and the connections 36 . 37 and 38 for the electrodes a, b and c.

When operating the switch 35 the voltage U1 is applied to the terminals 36 and 38 or to the connections 37 and 38 the electrical excitation device 34 placed. From the connections 36 and 38 respectively. 37 and 38 the electrical voltage reaches the electrodes a and c or the electrodes b and c of the piezoelectric element 2 ,

The at the electrodes 36 and 38 or at the electrodes 37 and 38 applied voltage U1 energized in the piezoelectric plate 3 of the piezo element 2 simultaneously the second mode of a bending acoustic standing wave and the first mode of a longitudinal acoustic standing wave. presentation 43 from 8th shows the piezoelectric plate of an ultrasonic actuator according to the invention and illustrates the position of a corresponding coordinate system. presentation 44 from 8th shows by means of the solid lines the phases of maximum deformation of the piezoelectric plate as shown 43 upon excitation of the second mode of an acoustic bending standing wave in this, while the dashed line the geometry of the piezoelectric Indicates plate in unexcited state or in initial state.

presentation 45 from 8th illustrates in a separate image the vibrations of one of the shorter side surfaces or the end face 8th the piezoelectric plate 3 in the excitation of the second mode of a bending acoustic standing wave in it as shown 44 from 8th , The excitement of such a bending standing wave leads to the face 8th Angular vibrations and thereby rotates about the angle α, without changing its surface, ie the end face 8th remains even when performing the angular oscillations.

presentation 46 from 8th shows by means of the solid lines the phases of maximum deformation of the piezoelectric plate as shown 43 upon excitation of the first mode of a longitudinal acoustic standing wave in this, while the dashed line indicates the geometry of the piezoelectric plate in the non-excited state or in their initial state. presentation 47 from 8th illustrates in a separate image the vibrations of one of the shorter side surfaces or the end face 8th the piezoelectric plate 3 in the excitation of the first mode of a longitudinal acoustic standing wave in it as shown 46 from 8th , The excitement of such a longitudinal standing wave leads to the end face 8th Longitudinal vibrations and further, hereinafter referred to as membrane vibrations oscillations. Due to the longitudinal vibrations, the surface moves 8th parallel to itself along the y-axis, while due to the membrane vibrations the end face 8th is inflated or pressed along the y-axis. The membrane vibrations or the corresponding deformations of the end face 8th are due to the fact that the volume of the piezoceramic of the plate 3 is constant.

The longitudinal vibrations of the face 8th take place here with the amplitude Ayl, while the membrane vibrations of the end face 8th with the amplitude Aym.

The membrane vibrations of the shorter side surface or end face effect on the friction element or its connecting surface arranged there 16 in that it carries out vibrations which are analogous to the membrane vibrations, as in the diagrams 48 and 49 from 9 can be seen. presentation 48 shows here the effective section longitudinal cross-section of the friction element as shown 25 from 5 wherein the solid lines represent the outer dimensions of the effective section longitudinal section in the unexcited or initial state, while the dashed lines show the maximum deformations of the friction element caused by the first mode of a longitudinal acoustic standing wave excited in the corresponding ultrasonic actuator. It can be seen that the ultrasound actuator via the connection surface 16 on the friction element transmitted membrane vibrations with the amplitude Aym a take place substantially along the y-axis longitudinal deformation or longitudinal vibration of the friction element having an amplitude Aymf.

In contrast shows presentation 49 from 9 the differently shaped effective section longitudinal section of the friction element as shown 30 from 5 wherein the solid lines represent the outer dimensions of the effective section longitudinal section in the unexcited or initial state, while the dashed lines show the maximum deformations of the friction element caused by the first mode of a longitudinal acoustic standing wave excited in the corresponding ultrasonic actuator. It's in comparison to the presentation 48 to recognize that the ultrasound actuator via the connection surface 16 On the friction element transmitted membrane oscillations with the amplitude Aym not only cause a longitudinal axis substantially along the y-axis longitudinal deformation or longitudinal vibration of the friction element with an amplitude Aymf effect, but at the same time an oscillating deformation parallel to the x-axis. The above regarding the representations 48 and 49 from 9 As a result, the longitudinal deformation of the friction element described is due to the fact that the friction element has two curved side surfaces 21 . 22 whose curvature is the - starting from the connection surface 16 in the direction of the friction surface 23 - Create tapered sections S1, S2, S3, ..., Sn of the friction element. Due to the monotonous tapering of the cross sections S1, S2, S3,..., Sn of the friction element, this becomes the transformer for the vibration velocities or the transformer for the vibration amplitudes. The low vibration amplitudes Aym of the connection surface 16 therefore result in significant vibration amplitudes Aymf of the friction surface 23 ,

The gain coefficient of the vibration amplitudes Ka = Aymf / Aym is proportional to μ Sm / Sf, where Sm is the cross-sectional area of the bonding surface 16 and Sf is the cross-sectional area of the friction surface 13 and μ in from the curvature of the curved surfaces 21 . 22 dependent coefficient. The coefficient μ is preferably in the range of 0.5 to 1.

When using a PZT ceramic for the piezoelectric plate 3 with a relatively high specific gravity or with a high density and the use of a material of low specific weight or lower specific Density for the friction element 14 is it possible to influence the friction element 14 on the waveform of the piezoelectric plate 3 to reduce. This means that the connection of friction element 14 with the piezoelectric plate 3 Amplitude of Aym practically does not decrease membrane vibrations.

It has been found experimentally that, for various structural designs of the friction element with different curvature of the surfaces 21 . 22 and with different surfaces for the surfaces 16 and 23, the gain coefficient of the vibration amplitudes Ka may be between 5 and 10. This means that at a ratio of the amplitude Aym of the membrane oscillations to the amplitude Ayl of the longitudinal oscillations from 02, to 0.3, the amplitude of the longitudinal vibrations of the friction surface Aymf caused by the membrane vibrations of the joint surface 16 between 1 and 3 times the amplitude Ayl.

The representations 50 to 58 from 10 show different embodiments of the friction element 14 , Here, according to the representations 50 . 56 . 57 and 58 the friction surface consist of a single flat surface, or according to the representations 51 and 54 consist of two or more flat and mutually inclined surface sections. According to the representations 52 and 55 from 10 the friction surface may also be a curved surface, wherein in the case of the friction element as shown 55 this has in the region of the friction section recesses or notches or slots. However, these recesses or indentations or slots are also conceivable for other geometries of the friction surface or of the friction section. As shown 53 from 10 For example, the friction portion or the friction surface has planar portions and a curved portion. Based on the representations 53 . 54 . 56 and 57 from 10 it becomes clear that the height H of the friction element (cf. 2 ) along its direction of extension - that is, starting from the base portion toward the friction portion - is not constant. Finally, representation is 58 from 10 it can be seen that also the base portion of the friction element can have recesses or notches or slots. In this case, the notches extend both in the height direction of the friction element, as well as perpendicular thereto.

11 shows an ultrasonic motor for a rotational movement with an ultrasonic actuator according to the invention. The actor 1 is in the holder 61 arranged, which is part of a housing. The friction element 14 of the ultrasonic actuator 1 is applied to the friction layer with the aid of force F. 61 as a rotor 63 pressed to driven element pressed.

12 in contrast shows an ultrasonic motor with an ultrasonic actuator according to the invention for a linear movement. Again, the actuator is in the holder 61 arranged, which is part of a housing. The friction element 14 is with a force F to the friction layer 63 as a slider 64 pressed to driven element pressed.

13 shows the waveform of the friction element of an ultrasonic actuator according to the invention, wherein in the ultrasonic actuator both the second mode of a bending acoustic standing wave, and the first mode of a longitudinal acoustic wave was excited, and excited in the ultrasonic actuator vibrations via the connecting surface on the friction element transfer.

As previously explained, the bending standing wave causes angular vibrations of the connecting side surface 8th the piezoelectric plate 3 out. The connecting side surface swings 8th by the angle α, without changing its surface, ie it remains flat. These vibrations are transmitted to the friction element, causing the friction element 14 rotates through the angle α. As a result, lead the friction surface 23 and the point P on its oscillations along the x-axis with the amplitude Axf.

The longitudinal acoustic standing wave causes longitudinal vibrations of the connecting side surface 8th along the y-axis with the amplitude Ayl and vibrations called the membrane side vibrations of the connecting side surface 8th with the amplitude Aym. These vibrations are also transmitted directly to the friction element, so that the friction surface 23 vibrates along the y-axis with the amplitude Ayl. The friction element 14 transforms the amplitude of the membrane vibrations Aym, whereby the friction surface 23 Longitudinal vibrations along the y-axis performs, caused by the membrane vibrations (see 9 ). These vibrations have the amplitude Aymf which is approximately ( 1 ... 3) Ayl is.

The total amplitude of the vibrations Ayf of the friction surface 23 and the point P on it along the y-axis corresponds to the sum of Ayl and Aymf, ie the total amplitude is ( 2 ... 4) Ayl.

Therefore, it is possible by the ultrasonic actuator according to the invention, the oscillation amplitude of the friction surface 23 of the friction element 14 in a purely mechanical way to increase many times, without, for example, the electrode structure of the piezoelectric plate 3 to change the actuator 1.

It is possible, the shape of the trajectory of the friction surface 23 and the point P on it, which represents an ellipse in the proposed invention.

The ultrasonic actuator according to the invention thus allows the amplitude of the longitudinal vibrations of the friction surface 23 of the friction element 14 to increase many times. This makes it possible to increase the frictional force in frictional contact of a corresponding ultrasonic motor, which on the other hand makes it possible to increase the maximum force developed by the ultrasonic actuator without increasing its maximum speed. This reduces the mechanical losses of the actuator in ultrasonic motors in no-load operation or in ultrasonic motors with variable mechanical load at low speeds of movement of the element to be driven. The reduction of mechanical losses in the actuator also reduces the heating of the actuator and thus extends its temperature range. In addition, this reduces the abrasion of the friction element and increases the service life of the actuator.

14 shows in presentation 65 the upper side of a two-phase actuator running or operated ultrasonic actuator without friction element arranged thereon, or in representation 66 the underside of the corresponding ultrasonic actuator. The upper side has the electrodes a, c and d, while the lower side has the identically shaped electrodes a, c and e. Upon application of the electrodes a and c with an electrical voltage arises in the plate 3 of the actor 1 an acoustic bending standing wave, and by the application of the electrodes d and e with an electrical voltage is formed in the plate 3 of the actuator an acoustic longitudinal standing wave. By simultaneous excitation of the electrodes a and c or d and e is in the plate 3 simultaneously excited an acoustic bending standing wave and acoustic longitudinal standing wave.

presentation 67 from 14 shows the block diagram for an embodiment for electrically contacting the ultrasonic actuator according to the representations 65 and 66 as a two-phase actuator. This is the actor 1 by the two-phase electrical excitation device 70 excited at the connections 36 and 38 respectively. 68 and 69 provides two electrical voltages U1 and U2 with the phase shift φ between them. To change the direction of the driven element of a corresponding ultrasonic motor angle φ to plus or minus 180 ° to change.

15 shows in the illustrations 71 and 72 Upper and lower side of an ultrasonic actuator designed and operated as a two-phase actuator without a friction element arranged thereon, which is the only difference to the ultrasonic actuator according to the illustrations 65 and 66 from 14 is designed as a multilayer element with a plurality of layers of piezoelectric material and in each case arranged therebetween layers with electrodes, wherein the electrode structure in illustration 73 from 15 can be seen.

16 shows in presentation 75 the upper side of a two-phase actuator running or operated ultrasonic actuator without friction element arranged thereon, or in representation 76 the underside of the corresponding ultrasonic actuator. The upper side has the electrodes a, c and e, while the lower side has the identically shaped electrodes a, c and d. Upon application of the electrodes a and c with an electrical voltage arises in the plate 3 of the actor 1 an acoustic bending standing wave, and by the application of the electrodes d and e with an electrical voltage is formed in the plate 3 of the actuator an acoustic longitudinal standing wave. By simultaneous excitation of the electrodes a and c or d and e is in the plate 3 simultaneously excited an acoustic bending standing wave and acoustic longitudinal standing wave.

presentation 77 from 16 shows the block diagram for an embodiment for electrically contacting the ultrasonic actuator according to the representations 75 and 76 as a two-phase actuator. This is the actor 1 by the two-phase electrical excitation device 70 excited at the connections 36 and 38 respectively. 68 and 69 provides two electrical voltages U1 and U2 with the phase shift φ between them. To change the direction of the driven element of a corresponding ultrasonic motor angle φ to plus or minus 180 ° to change.

17 shows in the illustrations 78 and 79 Upper and lower side of an ultrasonic actuator designed and operated as a two-phase actuator without a friction element arranged thereon, which is the only difference to the ultrasonic actuator according to the illustrations 75 and 76 from 16 is designed as a multilayer element with a plurality of layers of piezoelectric material and in each case arranged therebetween layers with electrodes, wherein the electrode structure in illustration 80 from 17 can be seen.

Claims (6)

Ultrasonic actuator (1), preferably for an ultrasonic motor, comprising a piezoelectric element (2) in the form of a rectangular piezoelectric plate (3) with two largest main surfaces (4, 5) in area and the main surfaces connecting shorter and longer side surfaces (6, 7, 8, 9), wherein at each of the main surfaces (4, 5) at least one electrode for electrical excitation of the ultrasonic actuator is arranged and a frictional member (14) is disposed on one of the shorter side surfaces (8) forming a connection side surface, and the friction member comprises a base portion (15) having a connection surface (16) and an operative portion adjoining the base portion having a friction portion at its a distal end, wherein the friction member is connected to the connection side surface via the connection surface, and the surface of the connection surface is equal to the connection side surface, and wherein the operation portion extends in a direction away from the base portion such that the lateral direction parallel to the connection side surface extends Outer surfaces of the active portion, the effective portion cross-sectional areas S1, S2, S3, ... Sn, continuously in the extension direction, characterized in that a parallel to the two main surfaces of the ultrasonic actuator extending cross-section of the active portion forming a Wirkabschnittslängsquerschnitt, a symmetrical shape with Curvature sections (24), wherein each of the curvature sections of the effective section longitudinal section by a reciprocal power function with the exponent 2 or 4 is writable. Ultrasonic actuator after Claim 1 , characterized in that the Wirkabschnittsquerschnittsflächen S1, S2, S3, ..., Sn have a right-angled or a circular or an elliptical shape. Ultrasonic actuator after Claim 1 or 2 , characterized in that the surface of the friction portion forms a friction surface (23), and the friction surface consists of one or more planar portions and / or has a curved portion. Ultrasonic actuator according to one of the preceding claims, characterized in that the base portion and / or the effective portion slits (59, 60) / which extend perpendicular and / or parallel to the main surfaces of the ultrasonic actuator. Ultrasonic actuator according to one of the preceding claims, characterized in that the friction element is attached to the connection side surface via an adhesive. Ultrasonic actuator according to one of the preceding Claims 1 to 4 , characterized in that the friction element and the piezoelectric element are integrally formed with each other.

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