DE102020114219A1 - Ultrasonic actuator - Google Patents

Abstract

The invention relates to an actuator made of a piezoelectric material with electrodes arranged at least on its outer surfaces or in its interior, which form two generators of acoustic waves, and with at least one friction element arranged on the actuator or a friction surface arranged on the actuator, the material of the actuator is either made of grains sintered together from a lead-free, ferroelectric, oxide, ceramic system, which forms a polycrystalline perovskite structure during sintering, or consists of a monocrystalline material whose specific weight is 1.5 to 2 times smaller than the specific weight of piezoelectric ceramics based on lead-zirconate-titanate.

Description

The invention relates to a piezoelectric ultrasonic actuator according to claim 1.

Piezoceramic ultrasonic actuators are usually made of lead-containing piezoelectric ceramics based on lead-zirconate-titanate (PZT). The lead content of the piezoceramic represents a major problem both when using the actuators and when recycling systems later. Lead is a heavy metal and therefore harmful to the human organism. It cannot be broken down by the human body and has a cumulative effect. Lead is mostly absorbed through the food chain, gets into the human body, accumulates in the body and damages the brain and internal organs, and impairs the functionality of the nervous system. Therefore, efforts are being made worldwide to avoid the use of lead. Researchers are currently intensively searching for alternative lead-free piezoelectric ceramics with lead-zirconate-titanate-like electromechanical properties.

From the pamphlets EP1747594B1 , DE102008026429A1 as DE102013105024B3 For example, piezoelectric ultrasonic motors with a plate-shaped or hollow-cylindrical actuator are known. Lead-containing piezoelectric ceramic based on PZT is used as the material for these motors. The acoustic standing waves are excited using the d31 charge constant.

In the known ultrasonic motors, the mechanical energy is tapped at specific points at which the vibration speed of the actuator is at its maximum. Friction elements are arranged at these points, which transfer the movement to an element to be driven via a friction contact. The friction elements are usually made of a different material than the ultrasonic actuator for the following reason: in high-frequency actuator operation, the friction elements are slowly worn away by wear. The resulting abrasive powder would contaminate the surrounding area with lead if the friction elements were made of a ceramic based on PZT. Further abrasion forms at the points where the ultrasonic actuator is held.

The object of the invention is therefore to provide an ultrasonic actuator in which the abrasion that inevitably occurs during operation does not contain any lead, and which at the same time offers the same performance as conventional ultrasonic actuators.

This object is achieved by an ultrasonic motor according to claim 1, the subsequent subclaims representing at least useful developments.

The ultrasonic actuator according to the invention therefore consists either of a piezoceramic, lead-free, ferroelectric, oxidic material system that crystallizes in a perovskite structure and, for example, of potassium-sodium-niobate, bismuth-sodium-titanate, potassium, sodium, bismuth, titanates or niobates and their Combinations, or of a piezoelectric single crystal or monocrystal of orthorhombic, trigonal, tetragonal, cubic, rhombic or hexagonal crystal symmetry, the specific weight of which is 1.5 to 2 times smaller than the specific weight of piezoelectric ceramic based on lead-zirconate-titanate . The abrasion occurring during the operation of the ultrasonic actuator is therefore far less dangerous than with ultrasonic actuators made of a lead-containing material and is therefore permissible for many applications.

Advantageously, the ultrasonic actuator and the friction element or the friction elements arranged thereon are made of the same material, so that the gluing process usually used to connect the friction element (s) to the ultrasonic actuator can be dispensed with. This reduces the manufacturing effort and at the same time increases the reliability of the ultrasonic actuator. In this context, a particular advantage results from the use of lead-free piezoelectric monocrystals due to their high hardness and the resulting advantageous wear properties.

Another advantage of lead-free piezoelectric monocrystals in particular is that they are not hydrophobic. Voltage breakdowns in the corresponding ultrasonic actuator due to water absorbed from the ambient air are thus largely prevented or completely excluded, so that a longer service life and reliability result.

In addition, it is not necessary to polarize lead-free piezoelectric monocrystals, as is the case with other piezoelectric materials. This eliminates the need for complex and costly manufacturing steps.

Furthermore, lead-free piezoelectric monocrystals tend to depolarize only at much higher temperatures, the corresponding temperature being referred to as the Curie temperature. With lithium niobate this is around 1145 ° C, while with conventional ferroelectrically hard piezoceramics it is around 300 ° C.

In addition, lead-free piezoelectric monocrystals lack the hysteresis that is otherwise common with piezoceramics; instead, they behave largely linearly, which is why there is no need for complex electronic measures to linearize the path characteristics.

Lead-free piezoelectric monocrystals are produced in large quantities, especially for optical applications, and are therefore inexpensive and available in differently oriented sections.

Lead-free piezoelectric materials continue to have a factor of 2 Lower density than piezoceramic based on PZT, which results in higher oscillation or resonance frequencies and an improved response behavior of the actuators, so that positioning systems with such actuators are faster or have greater dynamics.

1 shows an ultrasonic motor with an ultrasonic actuator according to the invention. The motor includes one in a housing 2 arranged piezoelectric actuator 1 as well as an element to be driven 3 in the form of a rod with a friction strip attached to it 4th . One at the actuator 1 arranged friction element 5 is with the help of pressure elements 6th elastic against the friction bar 4th pressed. The element to be driven 3 is in the motor housing 2 through a warehouse 7th movably mounted in the form of rollers so that it can move in the directions indicated by the double arrow.

2 shows in a top view and in a view from below of the ultrasonic actuator 1 according to 1 . The actuator 1 (hereinafter also referred to as an oscillator in some cases) is a lead-free piezoelectric plate 11th executed with a length L, a height H and a width B and includes two main surfaces 12th , two long side faces 13th and two end faces 14th . The plate 11th is divided into two equal parts by the parting plane Eq 15th , 16 divided and is cut by a longitudinal plane El.

The parting plane Eq runs through the middle of the oscillator length L and is perpendicular to the main surfaces 12th of the oscillator. The longitudinal plane El runs through the center of the end faces 14th and is perpendicular to the main surfaces 12th as well as the transverse plane Eq. The track 17th the parting plane Eq is on the actuator 1 marked with a dashed line. The line of intersection of the plane Eq with the plane El forms an axis of symmetry O. A friction element 5 is on the long side surfaces 13th the lead-free piezoelectric plate 11th arranged in the middle of the oscillator length L. However, it is also conceivable to have more than one friction element 5 on one of the long side surfaces 13th to arrange. It is also conceivable on both side surfaces 13th to arrange one friction element or more than one friction element. The part 15th of the actuator 1 includes an unbalanced generator 18th asymmetrical acoustic standing waves or static deformations. The unbalanced generator 18th is made by the excitation electrode 19th as well as the common electrode 20th formed which on the main surfaces 12th the polarized lead-free piezoelectric plate 11th are arranged. Under the term main surfaces 12th are to be understood as the areas of the actuator on which the electrodes 19th , 20th the generators of acoustic waves or static deformation 18th are arranged.

The direction of polarization of the lead-free piezoelectric material of the plate 11th is indicated by corresponding arrows and runs perpendicular to the electrodes.

The asymmetry of the generator 18th is due to its asymmetrical position in relation to the parting plane Eq as well as the fact that when it is excited in the oscillator, an asymmetrical two-dimensional standing wave is generated. The wave can be first, second or higher order. The length of the oscillator is related to the height and order of the excited wave as follows: L = K * H * n. K is a coefficient dependent on the width or the type of the piezoceramic; in the present case: K≈0.541. n is the order of the wave, where n = 2, 3, 4, ....

The part 16 of the oscillator 1 can have a second independent unbalanced generator 21 asymmetrical acoustic standing waves and static deformations with the excitation electrode 22nd and the common electrode 20th include.

The piezoelectric plate 11th is made of a piezoelectric material based on at least one lead-free, ferroelectric, oxidic material system that crystallizes in a perovskite structure, for example from potassium-sodium-niobate, bismuth-sodium-titanate, potassium, sodium, bismuth, from titanates or Niobates and their combinations.

The piezoelectric plate can also be made from a piezoelectric monocrystal with a polar axis Z (X3) and two electrical axes X1, X2. The orientation of the plate is chosen so that the polar crystal axis Z (X3) runs parallel to the axis of symmetry O of the plate (perpendicular to the main surfaces) and one of the electrical crystal axes X1, X2 runs parallel to the transverse plane Eq or to the transverse plane El ( Z-cut). Single crystals possible for this have an orthorhombic, trigonal, tetragonal, cubic, rhombic or hexagonal crystal symmetry, which includes quartz, lithium niobate, lithium tantalate or langatate. These are grown according to the Chochralski method.

3 shows in illustration 24 a piezoelectric actuator plate 11th of an ultrasonic actuator according to the invention in multilayer or multilayer construction. The piezoelectric plate 11th has a multilayer structure inside, made up of parallel layers of excitation electrodes 19th is formed, which is formed with parallel layers of common electrodes 20th and the layers of lead-free polarized piezoceramic arranged between them 23 alternate, the polarization direction of the layers of lead-free polarized piezoceramic 23 perpendicular to the electrodes 19th and 20th proceeds as in 4th in the and shown. The direction of polarization coincides with that of the polarization axis of the piezoelectric plate 11th together, see dotted line 27 in 3 .

All excitation electrodes 19th are in two unconnected groups of electrodes 28 and 29 divided, which are arranged symmetrically to one another with respect to the parting plane Eq. The dashed line 17th in 3 illustrates the line of intersection of the surface Eq with the main surfaces 12th and 13th . Each of the lines forms the center line of the corresponding area.

The excitation electrode groups 28 and 29 form together with parts of the common electrodes 19th and the piezoceramic layers arranged between them 23 the multi-layer generators 30th and 31 acoustic standing waves for dynamic operation (ultrasonic operation) and static deformations for static operation. Any generator 30th or 31 is arranged asymmetrically to the parting plane Eq.

The piezoceramic multilayer plate 11th can be manufactured using conventional multilayer technology. First, a thin strip of low-temperature piezoelectric raw material is produced in which the particles are bonded to one another with an organic binder. Then panels are cut out of the tape. The electrodes are then applied from paste containing palladium. The plates then become the plate as a compact block 11th pressed together and fired in the oven. During firing, the organic binder evaporates from the piezoceramic, the piezoceramic is sintered and the metal electrodes are formed from the paste containing palladium. With this technology, the usual thickness of each individual piezoceramic layer is 30th up to 100 micrometers.

The common electrodes 20th can consist of two equal parts 32 and 33 consist of the configuration of the excitation electrodes 19th repeat (see from 3 ).

Each of the electrodes 19th , 20th or any part of the electrodes 32 , 33 exhibits an electrically conductive approach 37 on, the electrically with current-conducting connection electrodes 34 , 35 and 36 connected is.

The electrodes can for example by means of ion sputtering, by screen printing or by baking onto the sintered surface of the plate 11th be upset. Common materials for this are chromium, copper, nickel or silver.

According to 3 are the electrodes 19th and 20th parallel to the main surfaces 12th the plate 11th arranged. However, the excitation electrodes 19th and the common electrodes 20th also parallel to the end faces 14th the plate 11th be arranged (see 5 ). In addition, the electrodes 19th and 20th parallel to the long side surfaces 13th the plate 11th be arranged (see 6th ).

According to 3 are the connection electrodes 34 , 35 , 36 on one of the long side faces 13th the plate 11th arranged. However, they can also be arranged on both side surfaces. The connection electrodes 34 , 35 , and 36 can also be on one of the main surfaces 12th or on both main surfaces 12th the plate 11th (please refer 5 ) be arranged. The connection electrodes 34 , 35 , 36 can also be used on the end faces 14th the plate 11th (please refer 6th ) to be appropriate.

4th clarified with the and the possible arrangements of the polarization directions within the piezoceramic layers 23 in the case of a multilayer piezoelectric plate 11th according to 3 .

5 shows in another embodiment of a multilayer lead-free piezoelectric actuator plate 11th . The piezoelectric plate 11th has a multilayer structure inside, made up of parallel layers of excitation electrodes 19th is formed facing the parallel layers of the common electrodes 20th (see in particular from 5 ) and the layers of lead-free polarized piezoceramic arranged between them 23 alternate with the piezoceramic layers 23 parallel to the transverse plane Eq, parallel to the end faces 14th and perpendicular to the long side faces 13th are arranged. The polarization vector runs perpendicular to the electrode surfaces 19th and 20th (see arrows in the and from 4th ).

6th shows according to a further embodiment of a multilayer lead-free piezoelectric actuator plate 11th . The piezoelectric plate 11th has a multilayer structure inside, made up of parallel layers of excitation electrodes 19th is formed facing the parallel layers of the common electrodes 20th (please refer from 6th ) and the layers of lead-free polarized piezoceramic arranged between them 23 alternate with the piezoceramic layers 23 perpendicular to the transverse plane Eq, perpendicular to the end faces 14th and parallel to the long side surfaces 13th are arranged. The polarization vector runs perpendicular to the electrode surfaces 19th and 20th , see arrows in the and from 4th ).

7th shows in an actuator according to the invention, in which a friction element 5 on one of the long side faces 13th is arranged, while after the actuator according to the invention on each of the long side faces 13th one friction element each 5 is arranged.

The friction element consists or the friction elements consist of a hard, wear-resistant material such as aluminum oxide (Al2O3), zirconium oxide (ZrO2), silicon nitride (Si3N4), silicon carbide (SiC), boron nitride (BN), boron carbide (B4C), tungsten carbide (WC) ) or titanium carbide (TiC).

8th illustrated in the FEM model of an actuator according to the invention 1 in multilayer construction with two generators 30th and 31 in a state in which no static electrical voltages are applied to the actuator. All areas between the electrodes 19th and 20th of the multi-layer generators 30th , 31 are not deformed, equal to each other and equal to k, and the friction element 5 is - relative to the plane Eq - arranged symmetrically in its middle position.

In from 8th are different to on the generators 30th and 31 static electrical voltages are applied, the being applied to the generator 30th applied voltage E1 is equal to -E, while that to the generator 31 applied voltage E2 is equal to + E.

All areas between the electrodes 19th and 20th of the generators 30th are compressed and equal to kx, where x is the size value for the elementary compression. In contrast, there are the areas between the electrodes 19th and 20th of the generators 31 stretched and equal to k + x, where x is the size value for the elementary stretch.

In from 8th are different to on the generators 30th and 31 static electrical voltages are applied, the being applied to the generator 30th applied voltage E1 is equal to + E, while that to the generator 31 applied voltage E2 is equal to -E.

The areas between the electrodes 19th and 20th of the generators 30th are stretched and equal to k + x. All distances between the electrodes 19th and 20th of the generators 31 are compressed and equal to kx.

9 shows in an actuator according to the invention 1 with two multi-layer generators 30th and 31 in a state where the static voltages E1 and E2 are zero. In this case all areas are between the electrodes 19th and 20th of the generators 30th , 31 undeformed, equal to each other and equal to k, and the friction element 5 is - based on the parting plane Eq - arranged symmetrically in its middle position.

from 9 in contrast shows the actuator 1 with two generators 30th and 31 in a state in which the static voltage E1 - applied to the generator 30th - equal to -E and the static voltage E2 - applied to the generator 31 - is equal to + E.

The areas between the electrodes 19th and 20th of the generators 30th are compressed and equal to kx, where x is the size value for the elementary compression. All areas between the electrodes 19th and 20th of the generators 31 are stretched and equal to k + x, where x is the size value for the elementary stretching.

The friction element 5 is - based on the plane Eq - shifted to the left by the amount x = nx, where n is the number of distances between the electrodes 19th and 20th of the generator 30th is.

from 9 finally shows the actuator 1 with two generators 30th and 31 in a position where the static voltage E1 is + E and the static voltage E2 is -E. In this case all areas are between the electrodes 19th and 20th of the generators stretched and equal to k + x. The distances between the electrodes 19th and 20th of the generators 31 are compressed and equal to kx.

The friction element 5 is - based on the plane Eq - shifted to the right by the amount x = nx, where n is the number of distances between the electrodes 19th and 20th of the generator 31 is.

In all cases, the piezoceramic is stretched and compressed between the electrodes 19th and 20th due to the reverse piezo effect, the size of the elementary expansion or the elementary compression being determined by the piezoelectric charge constant d33.

10 clarified in the and a possible embodiment of generators 60 , 61 for acoustic standing waves and static torsional longitudinal deformations in one Ultrasonic actuator according to the invention with strip-shaped electrodes arranged on the main surfaces. Here shows the 10 the front view and the 10 the rear view of the actuator.

The generators of acoustic standing waves and static torsional deformations 60 and 61 of the actuator 1 consist of alternately arranged strip-shaped excitation electrodes 62 and strip-shaped common electrodes 63 , arranged on the main surfaces 12th the plate 11th and the piezoceramic arranged between them.

The arrows with the index p indicate the polarization directions of the piezoceramic between the electrodes 62 and 63 at. The generators 60 , 61 have different polarization directions for the ceramic between the electrodes 62 and 63 on, the polarization directions running perpendicular to the strip-shaped electrodes.

The strip-shaped electrodes run in these generator designs 62 , 63 parallel to each other, perpendicular to the plane Eq, perpendicular to the end faces 14th and parallel to the long side surfaces 13th . The strip-shaped excitation electrodes 62 of the generator 60 have the connection 34 . The strip-shaped excitation electrodes 63 of the generator 61 have the connection 35 . The common strip-shaped electrodes 63 of the generators 60 and 61 have the connection 36 .

the and from 10 illustrate another possible embodiment of generators 60 , 61 for acoustic standing waves and static rotational longitudinal deformations in an ultrasonic actuator according to the invention with strip-shaped electrodes arranged on the main surfaces, wherein the front view of the actuator 1 and the rear view of the actuator 1 shows.

In generators designed in this way, the strip-shaped electrodes run 62 , 63 also parallel to one another, but parallel to the plane Eq, parallel to the end faces 14th and perpendicular to the long side faces 13th .

the and from 10 illustrate another possible embodiment of generators 60 , 61 for acoustic standing waves and static rotational longitudinal deformations in an ultrasonic actuator according to the invention with strip-shaped electrodes arranged on the main surfaces. Here the the front view of the actuator 1 , while the rear view of the actuator 1 shows.

In this embodiment of the generators, the strip-shaped electrodes run 62 , 63 parallel to one another and inclined at an angle a and -a to the transverse plane S. The angle of inclination a is advantageously in the range from 0 to 45 °.

Furthermore, the strip-shaped electrodes 62 , 63 have a mixed structure in their position in which parts or subregions of the electrodes run parallel, perpendicular or at an angle to the plane Eq.

The generators 60 , 61 of the actuator 1 have the following special design features.

The distance k (see 10 ) between the adjacent strip-shaped excitation electrodes 62 and the common strip-shaped excitation electrodes 63 may be equal to or less than half the thickness D of the piezoelectric plate 11th be. The width m (see 10 ) of the strip-shaped excitation electrodes 62 can range from 0.1 to 1 mm. The strip-shaped electrodes 62 , 63 can on the main area 12th the plate 11th for example by means of chemical deposition of nickel or by thermal application of chromium, copper or nickel in a vacuum or by ion plasma sputtering of chromium, copper, nickel, gold.

The structure of the strip-shaped electrodes 61 , 62 can be produced by laser milling, by chemical-lithographic etching, by spraying over a mask or by other common methods. The number of strip-shaped electrodes 61 , 62 on the main surfaces 12th is only limited by the technological manufacturing capabilities.

With generators designed in this way 60 , 61 with sheet-like excitation and common electrodes 62 , 63 the piezoelectric charge constant d33 is used to excite acoustic standing waves.

11th shows a possible embodiment for a piezoelectric plate 65 of the actuator according to the invention. The lead-free piezoelectric plate 65 is divided by a longitudinal parting plane El and a transverse parting plane Eq arranged perpendicular thereto. The plate 65 has two opposing, essentially parallel to one another arranged main surfaces 12th which are arranged perpendicular to the parting planes El and Eq. The opposing main surfaces 12th are connected to one another via eight side surfaces, two of which are work surfaces 66 represent, two of the side surfaces holding surfaces 67 and the remaining four side faces are free faces 68 are. In relation to the plane Et, which is arranged both perpendicular to the parting plane El and perpendicular to the parting plane Eq and which has one of the main surfaces 12th coincides or may be located between them, the cross-sectional area of the piezoelectric plate has a octagonal shape (see in particular from 11th ).

The parting planes Eq and El share the corresponding opposite work surfaces 66 and holding surfaces 68 in two equal parts. The line of intersection of the parting plane Eq with the parting plane El forms the axis of symmetry O.

The work surfaces 66 are essentially parallel to the parting plane El, the holding surfaces 67 essentially parallel to the parting plane Eq and the free surfaces 68 arranged at the same angle α to the parting plane SI and at the same angle φ to the parting plane Sq.

The piezoelectric plate 65 has the height H, which is the distance between the two work surfaces 66 and the length L, which corresponds to the distance between the two holding surfaces 67 is equivalent to. The width of the work surfaces 66 is equal to n, and the width of the holding surfaces 67 is equal to m. In addition, the piezoelectric plate has 65 the thickness t. In the ultrasonic actuator according to the invention, the ratio of the length L to the height H is in the range from 1.5 to 3. It is optimal if the ratio L / H is approximately equal to 1.6.

The piezoelectric plate 65 includes two generators 18th and 21 for generating acoustic standing waves and / or static deformations which are arranged symmetrically to the parting plane Eq and symmetrically with respect to the axis of symmetry O. Each of the generators 18th and 21 is in asymmetry based on the parting plane El. To connect an electrical excitation device, the generators have 18th and 21 Connection electrodes 34 , 35 , 36 . These can be attached to the holding surface 67 be arranged of the actuator.

12th shows another embodiment for a piezoelectric plate 71 of the actuator according to the invention. The lead-free piezoelectric plate 71 is divided by a longitudinal parting plane El and a transverse parting plane Eq arranged at an angle ϑ to it. The piezoelectric plate 11th has two opposing, essentially parallel to one another lying main surfaces 12th which are arranged perpendicular to the parting planes El and Eq. The opposing main surfaces 12th are connected to one another via eight side surfaces, two of which are work surfaces 66 represent, two sides holding surfaces 67 and the remaining four side faces are free faces 68 are. In relation to the plane Et, which is arranged both perpendicular to the parting plane EI and perpendicular to the parting plane Eq and which has one of the main surfaces 12th coincides or can be located between them, the cross-sectional area of the piezoelectric plate has an octagonal shape (see in particular from 12th ).

The parting planes Eq and El share the corresponding opposite work surfaces 66 and the holding surfaces 67 in two equal parts. The line of intersection of the parting plane Eq with the parting plane El forms the axis of symmetry O. The points of intersection of the axis O with the main surfaces 12th form the center of mass of the plate11.

The work surfaces 66 are essentially parallel to the parting plane EI, the holding surfaces 67 at an angle α and β to the parting plane El and the free surfaces 68 arranged at an angle φ and ψ to the parting plane Sq.

The piezoelectric plate 71 has the height H, which is the distance between the two work surfaces 66 and the length L, which corresponds to the distance between the two holding surfaces 67 is equivalent to. The width of the work surfaces 66 is equal to n, and the width of the holding surfaces 67 is equal to m. In addition, the piezoelectric plate has 71 the thickness t. In the ultrasonic actuator according to the invention, the ratio of the length L to the height H is in the range from 1.5 to 3. It is optimal if the ratio L / H is approximately equal to 1.6.

The piezoelectric plate 71 includes two unbalanced generators 18th and 21 for generating acoustic standing waves and / or static deformations. The generators are arranged symmetrically with respect to one another with respect to the axis of symmetry O. Each of the generators 18th and 21 are opposite to each other in asymmetry based on the parting plane Eq and El. To connect an electrical excitation device, the generators have 18th and 21 Connection electrodes 34 , 35 , 36 . These can, for example, on the holding surfaces 67 be arranged of the actuator.

The piezoelectric plate 71 the forms of execution according to the 11th and 12th is also manufactured according to the invention from a piezoelectric material based on at least one lead-free, ferroelectric, oxidic material system that crystallizes in a perovskite structure, for example potassium-sodium-niobate, bismuth-sodium-titanate-based, potassium, sodium, bismuth, titanates, Niobates and their combinations or similar lead-free material compositions, the piezoelectric material being polarized perpendicular to the electrodes.

The piezoelectric plate according to FIGS 11th and 12th can also be made from a piezoelectric monocrystal with a polar axis Z (X3) and two electrical axes X1, X2. The orientation of the plate is chosen so that the polar crystal axis Z (X3) is parallel to the axis of symmetry O of the plate (perpendicular to the main surfaces) and one of the electrical crystal axes X1, X2 is parallel to the transverse plane Eq or to the transverse plane El runs (Z-cut). The possible single crystals of the piezoelectric plate include, for example, crystals of orthorhombic, trigonal, tetragonal, cubic, rhombic or hexogonal crystal symmetry. This includes, for example, quartz, lithium niobate, lithium tantalate, langatate and other monocrystalline materials that are grown using the Chochralski method.

13th shows an ultrasonic motor with a piezoelectric actuator according to the invention according to FIG 11th . There are two runners in this motor 72 with the help of the pen 73 to the opposing friction elements 5 of the actuator 1 pressed. The actuator itself is attached to a circuit board 74 by means of a spring clip 75 pressed on. The spring clip 75 serves as a holder of the actuator 1 and can at the same time take over the task of the conductor who has the common electrodes 20th with conductive tracks 76 the circuit board 74 connects. The excitation electrodes 19th are directly or by means of an intermediate layer made of electrically conductive rubber 78 with the conductive tracks 76 connected by pressing. The circuit board 76 can also be designed as a plate on which the electronic components of the electrical excitation device of the ultrasonic actuator 1 are arranged. The moving element 77 this motor consists of the spring 76 that are firmly attached to the plastic-made runners during manufacture 72 is pressed. The runners 72 however, they can also be made of metal, ceramic, glass or filled plastic, for example from polyacrylamide filled with glass fibers or from epoxy resin filled with carbon fibers.

14th shows the schematic representation of an ultrasonic motor with an actuator according to the invention according to FIG 12th . The actuator is held by a bracket 79 on the holding surfaces 67 held. In this embodiment of the actuator, the work surfaces 66 arranged offset with respect to the axis of symmetry O or the centers of mass of the plate. The on the friction elements 5 or on the work surfaces 66 acting spring force F leads to the creation of a torque (in 14th indicated by an arrow).

The actuator jams in the bracket due to the torque 79 , whereby manufacturing tolerances of these two parts are compensated. The flexible circuit board 74 for contacting the actuator electrodes 19th , 20th can with the holding surface 67 be connected by clamping or otherwise.

15th shows in the and further application examples of the ultrasonic actuator according to the invention in an ultrasonic motor, the ultrasonic motor being arranged in the lens of a camera. In this lens there can be one or two or three groups of optical lenses 80 are used. The lens assemblies 80 can on the moving element 77 each motor is fixed by means of the guides arranged in the lens housing 83 be performed (see ), or the ultrasonic actuators 1 move with the lens assemblies attached to them 80 on the guides 83 according to from 15th . The flexible circuit board 74 every motor for contacting actuator electrodes 19th , 20th can be pressed against the actuator through part of the lens housing. In doing so, the one with the photo lens becomes the optical lens group 80 recorded image on a photo sensor 81 focused.

16 shows in the and an actuator according to the invention in the form of a hollow cylinder 86 from different perspectives. This can be subdivided into an even number of equal sectors (hollow cylinder segments) Sa and Sb by means of axially diametrical planes - here for example the three axially diametrical planes D1, D2 and D3, with all sectors Sa being a sector group A and all sectors Sb being one Form sector group B. The sectors Sa and the sectors Sb are alternating along the circumference of the hollow-cylindrical ultrasonic actuator 86 arranged and adjoin each other.

The axially diametrical planes D1, D2 and D3 are defined by the longitudinal or rotational axis O of the cylinder 86 and formed one of its parameters. The term equality of the sectors Sa and Sb means that the axially diametrical planes D1, D2 and D3 form the cylinder 86 divides into sectors Sa and Sb with the same circumferential angles α. The number of the cylinder 86 of the actuator 1 dividing axial-diametrical planes can be arbitrary, z. B. n.

17th shows part of a hollow cylindrical ultrasonic actuator according to the invention 90 , which is divided into n axially diametrical planes. The (circumferential) angle α of the sectors Sa and Sb for such an ultrasonic actuator is equal to 360 / 2n = 180 / n.

The hollow cylindrical ultrasonic actuator 86 has the generatrix Q (see from 17th ). Further geometric variables of the hollow cylindrical ultrasonic actuator or its sectors Sa or Sb are: the mean length L of the sector Sa or Sb, the height H in the direction of the longitudinal or rotational axis O and the wall thickness T in the radial direction. The mean length L is the length of the sector in the circumferential direction at position T / 2. The length of the generators Q is therefore the sum of the lengths L of all sectors Sa and Sb, ie Q = nL.

Friction elements 5 are on the face 91 of the cylinder 86 each in the area of the border of two adjacent sectors Sa and Sb ( Sector pair K) arranged, namely symmetrically with respect to the sector pair divided by the respective axially diametrical plane D.

According to from 17th the friction elements 5 also on both end faces 91 of the ultrasonic actuator 90 be arranged.

With a number of sector pairs of K = 6, the number of friction elements on each end face 3 be. A rotationally driven element (rotor) is only driven by 3 pairs of sectors K. As a result, the support of the rotor is determined mechanically and the resonator is acoustically relieved.

18th shows in the until hollow cylindrical ultrasonic actuators in plan view, which two, three, four, five, six and seven friction elements 5 exhibit. The friction elements are made from the oxide ceramic Al2O3, but can also be made from other hard and abrasion-resistant materials, for example from the oxide ceramic ZTO2 or from a non-oxide ceramic such as SIC or Si3N4. However, you can also consist of solid monocrystals such. B. made of sapphire, ruby or corundum. Furthermore, they can also be made of metal-ceramic based on tungsten carbide, titanium carbide and the like. In addition, the friction elements can also be made of different types of hard polymer materials, and with hard abrasion-resistant particles such. B. aluminum oxide, zirconium oxide, tungsten carbide, titanium carbide and the like. In the case of a monocrystalline hollow cylindrical actuator, the friction elements can be made in one piece with the hollow cylinder. This eliminates the gluing manufacturing step.

19th shows in the internal structure of a sector of an ultrasonic motor according to the invention with a hollow cylindrical actuator in three-dimensional view. According to the illustration, each sector Sa or Sb of each sector group A and B has layers of excitation electrodes arranged alternately in the axial direction 19th and common electrodes 20th on, each between adjacent excitation electrodes 19th and common electrodes 20th a layer of lead-free piezoceramic 23 is arranged. The layers of the excitation electrodes 19th are here as segments 92, and the layers of common electrodes 20th designed as segments 93.

The layers of the electrodes 19th , 20th are designed as thin silver-palladium layers with a thickness between 10 and 100 micrometers. However, it is also conceivable to use the layers of the electrodes 19th , 20th as thin silver-palladium-silver layers or thin copper layers. The piezoceramic layers 23 have a thickness between 30th and 100 microns. The ultrasonic actuator is manufactured using conventional multilayer technologies, but manufacturing by synthesizing piezoceramics in the air or under protective gas is also possible.

In each sector Sa and Sb are the layers 19th , 20th , 23 normal, ie arranged at an angle of 90 °, to the longitudinal or rotational axis O of the cylinder 286 and thus parallel to the end faces 91 of the cylinder.

The piezoceramic layers 23 are to the electrodes 19th , 20th normal polarized (in from 19th marked by arrows with the index p). With such a polarization, the polarization vector p is parallel to the longitudinal or rotational axis of the cylinder 86 and perpendicular to its end faces 91 directed.

All the layers of excitation electrodes belonging to the sectors Sa of the sector group A 19th are electrically connected to each other. Likewise are all layers of the excitation electrodes 19th the sector group B electrically connected to each other. In addition, all layers are common electrodes 20th of the sectors Sa and the sectors Sb of the sector groups A and B are electrically connected to each other. Here are all layers of the excitation electrodes in each sector Sa and Sb 19th connected to one another by means of the conductive tracks 94 and 95 and to the terminals 96 and 97, and all layers of the common electrodes 30th are among each other with the help of the conductive paths 98 with the connections 99 tied together.

With this type of connection of the electrodes, the following cases in particular are conceivable: In the first case, the excitation electrodes form 19th along with the common electrodes 20th and the piezoceramic layers 23 between them of all sectors Sa belonging to the sector group A the first combined generator for one along the generators Q of the piezoelectric cylinder 86 of the ultrasonic actuator 87 propagating acoustic longitudinal standing wave (that is to say an acoustic longitudinal standing wave propagating in the circumferential direction) and for one along the height H or the height extension of the piezoelectric cylinder 2 of the ultrasonic actuator 87 propagating acoustic longitudinal standing wave. The excitation electrodes 19th along with the common electrodes 20th and the piezoceramic layers 23 between them all of the sectors Sb belonging to the sector group B form the second combined generator for one along the line Q of the piezoelectric cylinder 86 of Ultrasonic actuator 87 or an acoustic longitudinal standing wave propagating in the circumferential direction and for one extending along the height H of the piezoelectric cylinder 86 of the ultrasonic actuator 87 or an acoustic longitudinal standing wave propagating in the vertical direction.

In the second case, form the excitation electrodes 19th along with the common electrodes 20th and the piezoceramic layers 23 between them of all sectors Sa belonging to the sector group A the first generator for one along the generators Q of the piezoelectric cylinder 86 of the ultrasonic actuator 87 propagating asymmetrical acoustic longitudinal standing wave. The excitation electrodes 19th form together with the common electrodes 20th and the piezoceramic layers 23 between them all of the sectors Sb belonging to the sector group B the second generator for one along the line Q of the piezoelectric cylinder 86 of the ultrasonic actuator 87 propagating asymmetrical acoustic longitudinal standing wave.

20th shows in an actuator according to the invention in the form of a hollow cylinder, in which the excitation electrodes 19th according to as segments 92 and the common electrodes 20th according to are designed as rings that cross all sectors Sa and Sb of both sector groups A and B.

21 shows in an actuator according to the invention in the form of a hollow cylinder 86 , in which the excitation electrodes 19th according to as segments 92 and the common electrodes 20th according to are designed as rings that are connected to the electrically conductive tracks 94 and 95. The tracks 94 connect the electrodes 19th of sectors Sa with each other, while tracks 45 are electrodes 19th of sectors Sb interconnect.

22nd shows schematically part of the developed lateral surface of an ultrasonic actuator according to the invention in the form of a hollow cylinder 87 with the electrodes 19th , 20th . All excitation electrodes 19th of the sectors Sa of the sector group A are connected to the conductive tracks 94 via the terminals 96 to the output 108 of the electrodes of sector group A connected while all excitation electrodes 19th the sectors Sb of the sector group B with the conductive tracks 95 via the connections 97 with the output 109 of the electrodes of sector group B are connected. All common electrodes 20th are with the electrically conductive tracks 98 over the connection 99 with the exit 110 of sector groups A and B.

23 shows schematically part of the developed lateral surface of a further embodiment of an ultrasonic actuator according to the invention in the form of a hollow cylinder with the electrodes 19th , 20th . All excitation electrodes 19th the sectors Sa of the sector groups A are connected to the conductive tracks 94 via the terminals 96 to the output 108 of the electrodes of sector group A connected. All excitation electrodes 19th of the sectors Sb of the sector group B are connected to the conductive tracks 95 via the terminals 97 to the output 109 connected to sector group B, and all common electrodes 20th are with the electrically conductive tracks 98 over the connection 99 with the exit 110 of sector groups A and B.

24 shows the structure of a possible embodiment of an ultrasonic motor with an actuator according to the invention on the basis of an exploded view 90 in the form of a hollow cylinder 86 . On one of the end faces 91 of the ultrasonic actuator are three friction elements 5 arranged at the same circumferential distance from one another. The rotor 133 is with the help of a feather 134 against the friction elements 5 pressed, with the rotor as a multi-part, with the axis 135 connected disc 136 is executed.

The multi-part disc 136 includes the bracket 137 , the friction rail 10 and that between the bracket 137 and the friction disc 138 located damping element 139 . The damping element 139 is designed as an elastic adhesive. It is also conceivable to design the damping element, for example, as a rubber ring or as a viscous layer enriched with solid particles. The friction disc 138 consists of an oxide ceramic based on Al2O3 with ZrO2 as an additive. Other oxide ceramics or other hard, wear-resistant materials such as non-oxide ceramics, e.g. B. silicon carbide, boron carbide, silicon nitride, aluminum nitride, boron nitride, etc., are also conceivable for this purpose.

The ultrasonic actuator 90 is in the holder 137 arranged. With its second face 91 , on which no friction elements are arranged, the actuator is supported 90 on the sound-insulating pad 140 away. The bracket 137 has a ball bearing 141 on, in which the axis 135 turns. The rotor 133 is through the retaining element 142 held.

25th shows with an electrical circuit for controlling an actuator according to the invention 1 with two generators 18th , 21 as well as with full-surface electrodes. from 25th shows an electrical circuit for an actuator according to the invention 1 with two generators 18th , 21 as well as strip-shaped electrodes (see 7th ). The circuit consists of the coupling capacitors C1, C2 and the isolating resistors R1, R2. The capacitance of the coupling capacitors is preferably equal to or greater than the capacitance C0 of the actuator 1 between the connections 34 , 36 of the generators 18th , 21 . The isolating resistances R1, R2 are preferably 5 to 10 times greater than that of the impedance X0 of the capacitance C0, where X0 = 1 / 6.28FrC0 and Fr represents the resonance frequency of the ultrasonic motor.

26th shows a block diagram of an electrical control device of a motor with two generators 18 ( 30th ), 21 ( 31 ) by means of single-phase electrical voltage. The circuit consists of the single-phase generator 115 for the electrical alternating voltage U1 at the output 116 , the switch 117 with the connections 118 , 119 , 120 , the generator 121 for static control of the electrical voltage Es at the output 122 , the linear amplifiers 123 and 124 the static electrical voltage with the outputs 125 , 126 , to which the static electrical voltages E1 and E2 are applied and the controller 127 with the entrance 128 . All components of the electrical control device 113 have the common connection 129 .

27 shows in the until Maximum deformations of differently designed actuators according to the invention, calculated by means of FEM simulation, when they are dynamically excited. shows a piezoelectric actuator in the form of a rectangular plate, which has full-area or strip-shaped and possibly internal electrodes, as for example in FIG 2 , 8th or 10 shown. from 27 shows an actuator according to the invention with 8 side surfaces, such as in FIG 11th and 12th shown. finally shows a hollow cylindrical actuator, such as in 16 shown.

28 shows a block diagram of an electrical circuit for regulating the operating frequency of an ultrasonic motor with an ultrasonic actuator according to the invention. The electrical circuit includes the current feedback element as an essential component 144 , the controller 145 , the frequency generator 146 and the power amplifier 147 .

A piezoelectric motor formed with the ultrasonic actuator according to the invention 1 can be operated in ultrasonic mode as well as in direct current mode. Accordingly, the control for the motor with the electrical control device 113 in a dynamic manner, ie in the ultrasonic mode, or in a static manner, ie in the DC mode.

The following first describes the dynamic control of a motor with two generators 18th ( 30th ), 21 ( 31 ) considered. A single-phase and a two-phase control are conceivable here.

The generator provides dynamic single-phase control of the motor 115 the electrical single-phase alternating voltage U1 ready, the frequency Fg of which is equal to or close to the resonance frequency of the motor Fr. On the one hand, the voltage U1 is applied via the connection 118 of the switch 117 and the capacitor C1 to the terminal 34 the excitation electrodes 19th of the generator 18th placed. On the other hand, the voltage U1 is via the common connection 129 to the connection 36 the common electrode 20th of the generator 18th laid (see 25th and 26th ). The voltage U1 excites the generator 18th dynamic, which makes the generator 18th in the actuator 1 the second mode generates an acoustic standing wave propagating along length L and along width B.

27 shows the current maximum deformation of the actuator using an FEM simulation 1 when the generator excites the second mode of an acoustic standing wave with frequency fr 18th ( 30th ). This wave corresponds to an asymmetrical volume standing wave. The switch is located 117 in a position in which it makes contact with the connector 120 has in 28 shown in dotted lines), the electrical voltage U1 is applied to the connection via the capacitor C2 35 the electrode 19th of the generator 21 ( 31 ), whereby this generator is controlled dynamically. The generator 21 ( 31 ) excited in the actuator 1 a standing wave. The shaft represents a mirror image of what is produced by the generator 18th ( 30th ) generated wave, whose images of maximum deformations in 27 in the and are shown.

The excitation voltage of the actuator can either be a harmonic (sinusoidal) or a non-harmonic signal. In the case of a non-harmonic signal form, the excitation voltage can also contain higher harmonics or other frequencies in addition to the basic frequency ω0, which corresponds to the resonance frequency Fr of the actuator. The generator 115 can generate a square wave signal, a triangle wave signal or any signal of any shape.

The dynamic excitation of the in 16 respectively. 17th The hollow cylindrical actuator shown is carried out in the same way. The current recordings of maximum deformations of the hollow cylindrical actuator with dynamic excitation are in from 27 shown.

With dynamic two-phase control, the generator generates 115 at the connections 118 , 120 the electrical alternating voltages U1 and U2 with a frequency Fg which is equal to the resonance frequency of the actuator Fr or is close to this frequency. The voltages U1 and U2 are shifted to one another by the angle φ, which can be in the range from zero to plus or minus 180 °. The voltages U1 and U2 reach the connections via the capacitors C1 and C2 at the same time 34 and 35 of the electrodes 19th and via the common connection 36 to the connections 129 of the electrodes 20th of the generators 18th ( 30th ) and 21 ( 31 ).

The generators generate from the applied voltages U1 and U2 18th ( 30th ) and 21 ( 31 ) in the actuator 1 two acoustic standing waves, their respective maximum deformations in the 27 are shown. The waves generated are shifted to one another by the time t, where t is equal to f / 360 ° Fg. The friction element experiences the excitation of a standing wave in the actuator 5 a movement along an elliptical or a rectilinear path. Due to the between the friction element 5 and the friction bar 4th frictional force is the element to be driven 3 emotional. The friction element 5 causes the element to be driven 3 in the in 1 to move in the direction shown with arrows with the index + V.

Used by the generator 21 ( 31 ) in the actuator 1 one to the in 27 generated mirror-inverted acoustic standing wave, the friction element moves 5 in an opposite direction. This causes the friction element 5 the element to be driven 3 in the in 1 to move in the opposite direction shown with arrow with the index -V.

With two-phase excitation of the two generators 18th ( 30th ) and 21 ( 31 ) are in the actuator 1 simultaneously generates two acoustic standing waves. The shape of the trajectory of the friction element 5 can be varied by changing the phase and amplitude of both voltages. This allows the speed of the element to be driven to be changed.

The generator can also 115 generate two signals of different frequencies. As a result, in addition to the working resonance of the actuator, other resonances are also excited. The aim is to superimpose the movement trajectories of the friction elements of different resonances. Such a stimulus can be used specifically to influence the movement of the element to be driven, for example to compensate for stick-slip effects during slow travel or during fine positioning.

The dynamic two-phase excitation of the in 16 respectively. 17th The hollow cylindrical actuator shown is carried out in the same way. The snapshots of maximum deformations of the hollow cylindrical actuator with dynamic excitation are in from 27 shown. The shape of the trajectory is determined by the dimensions of the plate 11th of the actuator 1 and the phases or amplitudes between them in the actuator 1 propagating acoustic standing waves.

Different forms of movement paths of the friction element 5 make it possible to implement different operating modes for an ultrasonic motor with an ultrasonic actuator according to the invention. The different shape of the movement paths also makes it possible to reduce the friction between the friction element 5 and the friction bar 4th to reduce.

The static control of an ultrasonic motor with an ultrasonic actuator according to the invention takes place as follows: first, the dynamic control is switched off. Comes a single phase control device 113 the switch is used 117 into the contact position with the terminal 119 (please refer 26th ) brought. At this position of the switch 117 become the generators 18th ( 30th ), 21 ( 31 ) dynamically not excited, ie no electrical voltage U1 reaches the electrodes 19th , 20th (please refer 25th , 26th ).

Becomes a two-phase control device 113 is used, the generator 115 switched off (see 26th ). The voltage amplitudes U1 and U2 are zero and the generators 18th ( 30th ), 21 ( 31 ) are not excited dynamically. The static voltage generator 121 puts at its exit 122 a static control voltage Es ready, which can change in the range of + Es ... 0 ... -Es. This voltage is generated by the linear amplifier 123 , 124 reinforced. This is at the exit 125 of the amplifier 123 the static voltage E1, which can change in the range of + E ... 0 ...- E. At the exit 126 of the amplifier 124 the inverted static voltage E2 acts, which can change in the range from -E ... 0 ... + E.

In the ultrasonic actuator according to the invention, the strip-shaped or multilayer generators form the acoustic standing waves 30th , 31 at the same time the generators for the static torsional deformations of the piezoelectric plate 11th of the actuator 1 ; therefore the static control of the ultrasonic actuator according to the invention takes place with the aid of the generators 30th , 31 . This is done as follows: on the one hand, the voltage E1 is applied to the connections via the resistors R1 34 the excitation electrodes 19th of the generators 18th ( 30th ) placed. On the other hand, the voltage E1 is via the common connections 129 to the connections 36 of the common electrodes 20th of the generators 21 ( 31 ) placed. On the one hand, the voltage E2 is applied to the connections via the resistors R2 34 the excitation electrodes 19th of the generators 18th ( 30th ) placed. On the other hand, the voltage E1 is via the general connections 129 to the connections 36 of the common electrodes 20 of the generators 21 ( 31 ) created.

8th shows in vividly the actuator 1 with the strip-shaped electrodes running parallel to the longitudinal plane El (see also 10 , , ) or multilayer electrodes (see 6th ) with two generators 30th and 31 in a position where the static voltages E1 and E2 are zero are. In this case all areas are between the electrodes 19th and 20th of the generators 30th , 31 not deformed, are equal to each other and equal to k, the friction element 5 is - relative to the plane Eq - arranged symmetrically in its middle position.

from 8th clearly shows the actuator 1 with two generators 30th and 31 in a position where the static voltage E1 is -E and the static voltage E2 is + E. In this case, the areas between the electrodes 19th and 20th of the generator 30th are compressed and are equal to kx, where x is the size value for the elementary compression. The areas between the electrodes 19th and 20th of the generator 31 are stretched and are equal to k + x, where x is the size value for the elementary stretching.

In the area of the piezoceramic under the friction element, a rotational deformation (torsion) of the plate material occurs in a plane that is essentially parallel to the main sides of the actuator plate, as shown in FIG from 8th with the arrows 49 is shown. In this case, the friction element experiences 5 a counterclockwise rotation or tilting motion. The points 50 the friction surface 51 of the friction element 5 are shifted to the left by the amount d = nx, based on or on the plane Eq, where d is greater, the greater the number of spacings n between the electrodes 19th and 20th of the generator 30th or the generator 31 is. The advance of the points 50 the friction surface 51 of the friction element 5 is greater than the advance of the points lying on the base of the friction element. The tilting of the friction element that is produced enables a far greater advance of the element to be driven in comparison to an advance caused by longitudinal expansions. The higher the friction element, the greater the feed generated due to its tilting.

from 8th clearly shows the actuator 1 with two generators 30th and 31 in a position where the static voltage E1 is -E and the static voltage E2 is + E. In this case all areas are between the electrodes 19th and 20th of the generator 30th stretched and equal to k + x. The distances between the electrodes 19th and 20th of the generator 31 are compressed and equal to kx. In the area of the piezoceramic under the friction element, a rotational deformation (torsion) of the plate material occurs in a plane arranged essentially parallel to the main sides of the actuator plate, as shown in FIG from 8th with the arrow 49 is shown. In this case, the friction element experiences 5 a clockwise rotation or tilting motion.

The points 50 the friction surface 51 of the friction element 5 are shifted to the right by the amount d = nx, based on the plane Eq, where n is the number of distances between the electrodes 19th and 20th of the generator 30th or the generator 31 is. The advance of the points 50 the friction surface 51 of the friction element 5 is greater than the advance of the points lying on the base of the friction element. The generated tilting of the friction element enables a far greater advance of the element to be driven in comparison to an advance caused by longitudinal expansions. The higher the friction element, the greater the feed generated when it is tilted.

Due to the continuous simultaneous change in the electrical voltage E1 in the range from + E via zero to -E and the voltage E2 from -E via zero to + E, it is possible to use the friction element 5 statically by the value X to the left or right of its middle position or the friction surface 51 to move.

from 9 clearly shows the actuator 1 with the strip-shaped electrodes running parallel to the transverse plane Eq (according to FIGS and from 10 ) or with multilayer electrodes (according to 5 ) with two generators 30th and 31 in a position where the static voltages E1 and E2 are zero. In this case all areas are between the electrodes 19th and 20th of the generators 30th , 31 not deformed, are equal to each other and equal to k, and the friction element 5 is - relative to the plane Eq - arranged symmetrically in its middle position.

Illustration 53 of 9 clearly shows the actuator 1 with two generators 30th and 31 in a position where the static voltage E1 is -E and the static voltage E2 is + E. In this case, the areas between the electrodes 19th and 20th of the generators 30th are compressed and are equal to kx, where x is the size value for the elementary compression. The areas between the electrodes 19th and 20th of the generators 31 are stretched and equal to k + x, where x is the size value for the elementary stretching.

In the area of the piezoceramic under the friction element 5 This creates a longitudinal deformation of the plate material in a plane arranged essentially parallel to the main surfaces of the actuator plate. The points 50 the friction surface 51 of the friction element 5 are shifted - based on the plane Eq - to the left by the amount d = nx, where d is greater, the greater the number of distances n between the electrodes 19th and 20th of the generator 30th or the generator 31 is. The advance of the points 50 the Friction surface 51 of the friction element 5 is greater than the advance of the points lying on the base of the friction element. The generated feed of the friction element enables a feed of the element to be driven.

from 9 clearly shows the actuator 1 with two generators 30th and 31 in a position where the static voltage E1 is -E and the static voltage E2 is + E. In this case all areas are between the electrodes 19th and 21 of the generator 30th stretched and equal to k + x. The distances between the electrodes 19th and 20th of the generator 31 are compressed and equal to kx. In the area of the piezoceramic under the friction element 5 This creates a longitudinal deformation of the plate material in a plane arranged essentially parallel to the main sides of the actuator plate. The points 50 the friction surface 51 of the friction element 5 are shifted to the right by the amount d = nx, based on the plane E5, where n is the number of distances between the electrodes 19th and 20th of the generator 30th or the generator 31 is.

The maximum displacement X is determined by the maximum values of the voltages E1, E2 and by the level of the breakdown voltage between the electrodes 19th and 20th limited. The actual maximum value is in the range of about 10 nm. The value is not limited downwards, ie towards smaller shifts. Due to the continuous simultaneous change in the electrical voltage E1 in the range from + E via zero to -E and the voltage E2 from -E via zero to + E, it is possible to use the friction element 5 to tilt statically by the value X to the left or right of its middle position or to move the friction surface.

The function of the actuator 1 with strip-shaped electrodes which run at an angle to the transverse plane Eq (see and from 7th ) is done in a similar way. With both static and dynamic control of an ultrasonic motor with an ultrasonic actuator according to the invention, all material points become 50 the friction surface 51 of the friction element 5 to the friction bar 4th of the element to be driven 3 pressed on. When the friction element is shifted 5 to the left or right - in relation to its middle position - the material points of the friction surface move 51 on an almost linear or curved trajectory and move the element to be driven 3 due to the friction to the left or right. The maximum displacement of the element to be driven 3 is + X or -X (+/- 10 nm). The minimum displacement of the friction element 5 or the resolving power is not limited here.

In the 28 electrical circuit shown 143 for regulating the operating frequency of an ultrasonic motor with an ultrasonic actuator according to the invention has the following mode of operation: the current feedback element 144 determines the phase angle φ _ui between the current Im flowing through the motor and the electrical voltage Um at the motor and feeds the value to the controller 145 to. The regulator 145 compares the angle with the reference value (e.g. 0 °) and controls the frequency generator 146 such that the angle φ _{ui equals} the reference value. From the frequency generator 146 the signal reaches the output stage 147 . This generates an electrical voltage Um with the necessary amplitude and current strength for the operation of the motor.

In a possible modification of the circuit 143 the current feedback element determines the control of the working frequency of the motor 144 a certain value of the motor current, such as the instantaneous value, the mean value, the rms value or the amplitude, and then regulates the working frequency of the motor.

As a frequency-generating generator of the circuit 144 A voltage-controlled or digitally controlled generator can be used, or a look-up table (ie values stored in a memory) can be used.

29 shows a variant embodiment of the piezoelectric plate 11th , 71 according to the 2 , 11th and 12th , produced from a Y cut of lithium niobate or LiNbO3 (Y cut) rotated by the angle β about the X1 axis. A crystallographic coordinate system is used internationally to clearly describe crystal sections. The coordinate system is perpendicular to the axes XYZ (X1X2X3). In this variant of the actuator, the large sides of the actuator plate run parallel to the Y-crystal section plane. A Y section of the crystal is the section that runs parallel to the X1, X3 axes and on which the X2 axis is perpendicular.

A Y-section of the monocrystal rotated by the angle β about the axis X1 has a derived right-angled coordinate system X1'X2'X3 ', which is created by rotating the original coordinate system X1X2X3 of the crystal. The X2 ', X3' axes of the section are rotated in relation to the X2, X3 axes by the angle β around the axis X1 in a counterclockwise direction. The X1 'axis of the section coincides with the X1 axis of the crystal. The Y-cutting plane is formed by the new axes X1-X3 '. The Y-section of lithium niobate rotated by the angle β about the axis X1 can advantageously be used for the resonator of the actuator according to the invention. properties of piezoelectric monocrystals are anisotropic. With certain oriented sections of the crystal, crystal properties experience advantageous values from the point of view of the possible excitation of acoustic waves. A two-dimensional acoustic standing wave is excited in the resonator of the motor according to the invention. So that the wave can exist and the trajectory of the friction contact is optimal, the piezoelectric d-coefficients of the piezoelectric material of the resonator in the two orthogonal directions lying in the plane of the plate must be essentially the same or differ by no more than a factor of two.

The curves of the piezoelectric d-coefficients of lithium niobate are shown in the diagram in 30th . For example, with a Y-section of LiNbO3, the d21, d23 coefficients in the area of the rotation around the axis X1 by the angle β from 10 ° to 55 ° and 120 ° to 170 ° do not differ more than the factor 2. The areas are in 30th marked with β. In these areas, a two-dimensional acoustic standing wave can be excited by the d21, d23 piezoelectric coefficients. The electric field is applied in the X2 direction. The ranges from 25 ° to 45 ° and 160 ° to 161 ° have proven to be particularly advantageous. There the d21, d23 coefficients are essentially the same (in 30th circled).

In this embodiment variant of the actuator, lithium tantalate or langatate or another monocrystal of the same crystal system can be used as a further material.

The friction element can be made from the same material as that of the actuator. This eliminates the process step of gluing.

The ultrasonic actuator according to the invention is RoHS-compliant and thus corresponds to the EU directives or meets the requirements according to the global trend in electronics production. By using the lead-free ultrasonic actuators according to the invention in ultrasonic motors with static and dynamic control, it is possible to reduce the costs for high-precision nanopositioning devices.

List of reference symbols

1 :

Actuator

2:

casing

3:

element to be driven

4:

Friction bar

5:

Friction element

6:

Pressure element

7:

camp

8th:

Resonator

11:

Lead-free piezoelectric actuator plate

12:

Main surface (of the actuator plate 11th )

13:

Long side surface (of the actuator plate 11th )

14:

Face (of the actuator plate 11th )

15, 16:

Parts (of the actuator 1 or the actuator plate 11th )

17:

Trace of the parting line

18:

Generator of acoustic standing waves and static deformations

19:

Excitation electrode (of the generator 18th )

20:

common electrode (of the generator 18th or the generator 21 )

21:

second generator of acoustic standing waves and static deformations

22:

Excitation electrode (of the second generator 21 )

23:

Layer of lead-free piezoelectric ceramic

27:

Polarization axis

28, 29:

Groups of excitation electrodes

30, 31:

Multi-layer generators of acoustic waves or static deformations

32, 33:

Parts of the common electrodes 20

34-36:

Connection electrodes

37:

Conductive approach

49:

Directional arrow of twist deformations

50:

Points of the friction surface 51

51:

Friction surface

60, 61:

Generator acoustic standing waves and static deformations with strip-shaped electrodes

62:

Strip-shaped excitation electrode

63:

Strip-shaped common electrode

65:

Piezoelectric plate

66:

Work surface

67:

Holding surface

68:

Free area

71:

Piezoelectric plate

72:

runner

73:

feather

74:

Circuit board

75:

Spring clip

76:

Conductive tracks (of the circuit board 74 )

77:

Movable element

78:

Conductive liner

79:

bracket

80:

optical lens

81:

Photo sensor

83:

guides

86:

piezoelectric hollow cylinder

90:

Hollow cylindrical ultrasonic actuator

91:

End face of the piezoelectric cylinder 86

98:

conductive traces of the common electrodes

99:

Electrode connections of conductive tracks 98

108-110:

Outputs of the electrode connections 96, 97, 99

113:

Electric control device

115:

Alternating voltage generator

116:

Outputs of the generator 115

117:

Toggle switch

118-120:

Connections of the switch 117

121:

Static voltage generator

122:

Output of the generator for static control 121

123, 124:

Linear amplifier

125, 126:

Outputs of the linear amplifiers 123 , 124

127:

Controller

128:

Controller input 127

129:

Common connection of the control device 113

133:

Rotary driven element (rotor)

134:

feather

135:

axis

136:

disc

137:

bracket

138:

Friction disc

139:

Damping element

140:

sound-insulating pad

141:

ball-bearing

142:

Retaining element

143:

Electric circuit for regulating the motor working frequency

144:

Current feedback element

145:

Regulator

146:

Frequency generator

147:

Power amplifier

148:

counter

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• EP 1747594 B1 [0003]
• DE 102008026429 A1 [0003]
• DE 102013105024 B3 [0003]

Claims (17)

Actuator made of a piezoelectric material with electrodes arranged at least on its outer surfaces or in its interior, which form two generators of acoustic waves, and with at least one friction element arranged on the actuator or a friction surface arranged on the actuator, characterized in that the piezoelectric material of the actuator Either is made of grains sintered together from a lead-free, ferroelectric, oxide, ceramic system, which forms a polycrystalline perovskite structure when sintered, or consists of a monocrystalline material whose specific weight is 1.5 to 2 times smaller than the specific weight of piezoelectric ceramics based on lead-zirconate-titanate. Actuator after Claim 1 , characterized in that the ceramic material system consists of potassium-sodium-niobate or bismuth-sodium-titanate or potassium or sodium or bismuth or of titanates or niobates or of combinations thereof. Actuator after Claim 2 , characterized in that the ceramic material system is polarized and the polarization direction is arranged perpendicular to the electrodes. Actuator after Claim 1 , characterized in that the piezoelectric monocrystalline material has an orthorhombic or trigonal or tetragonal or cubic or rhombic or hexagonal crystal symmetry. Actuator after Claim 4 , characterized in that the piezoelectric material consists of lithium niobate or of lithium tantanate or of langatate or of quartz or of another similar material. Actuator according to one of the preceding claims, characterized in that it essentially has the shape of a rectangular plate with a length L, a height H and a thickness t, the plate having a longitudinal parting plane EI, a transverse parting plane Eq and at least two main surfaces which are connected to one another via at least two side surfaces and at least two end surfaces, and the plate comprises at least two generators arranged symmetrically to the transverse plane Eq for generating acoustic standing waves. Actuator after Claim 6 , characterized in that it has inner layer-shaped electrodes, a layer of the piezoceramic material being arranged between adjacent inner electrodes, and the layer-shaped inner electrodes being arranged parallel to the main surfaces and parallel to the side surfaces and parallel to the end surfaces. Actuator after Claim 6 or 7th , characterized in that the generators of acoustic standing waves at the same time represent generators of static rotational deformations or static longitudinal rotational deformations or static longitudinal deformations of the area of the plate which is arranged below the at least one friction element between the two adjacent generators, the static deformation that can be generated by the generators mainly take place in a plane parallel to the main surfaces of the plate. Actuator after Claim 8 , characterized in that the generators of acoustic standing waves and static deformations are formed from alternately arranged on the two main surfaces strip-shaped excitation electrodes and strip-shaped common electrodes, wherein the strip-shaped electrodes run parallel or at an angle or perpendicular to the side surfaces of the plate and the polarization directions of the piezoelectric Plate between the strip-shaped electrodes run perpendicular to the strip-shaped electrodes. Actuator according to one of the Claims 6 until 9 , characterized in that the plate comprises at least eight side surfaces, at least two of the side surfaces being provided for contacting at least one element to be driven by the piezoelectric actuator, and at least two of the side surfaces being provided for holding the piezoelectric plate, and the remaining side surfaces below are arranged at the same angle alpha to the longitudinal parting plane El and / or at the same angle beta to the transverse parting plane Eq. Actuator according to one of the Claims 6 until 10 , characterized in that the generators of acoustic standing waves or the generators of acoustic standing waves and static deformations are arranged asymmetrically with respect to the parting planes EI, Eq and symmetrically to the cutting axis O formed by the parting planes. Actuator according to one of the Claims 6 until 11th , characterized in that the plate consists of a monocrystal with a polar axis Z and two further axes of crystal symmetry X1, X2, the polar axis Z of the monocrystal being perpendicular to the main surfaces of the plate and the X1, X2 axes perpendicular to the Z Axis and run parallel to the transverse plane El or parallel to the longitudinal plane Eq. Actuator according to one of the Claims 1 until 5 , characterized in that it has the shape of a hollow cylinder with an inner circumferential surface and an outer circumferential surface and end faces connecting the inner and outer peripheral surfaces, with friction elements being arranged on at least one of the end faces, and the actuator in the circumferential direction in an even number of sectors Sa and Sb are divided with an average length L of one sector in the circumferential direction, with a height H of one sector in the axial direction and a thickness T of one sector in the radial direction, and the sectors form a first sector group A and a second sector group B, in In the circumferential direction, the sectors Sa and Sb of the two sector groups A and B alternate and adjoin one another, and the friction elements are arranged in the area of the adjoining adjacent sectors, and each of the sectors Sa and Sb is provided by excitation electrons arranged alternately in the radial or tangential or axial direction of the hollow cylinder clear and common electrodes is formed. Actuator after Claim 13 , characterized in that the hollow cylinder is made of a piezoelectric monocrystal with a polar axis Z and two or three further crystal symmetry axes X1, X2, X3, the polar axis Z of the monocrystal running parallel to the longitudinal axis O of the cylinder and the X1, X2 , X3 axes are perpendicular to the Z axis and parallel to one of the transverse planes Eq. Actuator according to one of the preceding claims, with an electrical excitation device which has a feedback circuit for regulating the actuator operating frequency on the basis of the phase angle between the actuator current and the electrical voltage at the actuator. Actuator according to one of the Claims 1 until 14th with an electrical excitation device which has a feedback circuit for regulating the actuator operating frequency on the basis of the actuator current. Actuator according to one of the Claims 6 , 10 or 11th characterized in that the plate is made of a piezoelectric monocrystal trigonal crystal system from a Y cut rotated about the axis X1 by the angle β in the range from 10 ° to 55 ° or 120 ° to 170 °, so that the new axis X3 'des Monocrystalline section is perpendicular to the main surfaces of the plate and the X1 ', X2 axes are perpendicular to the Z axis and parallel to the transverse plane Eq or parallel to the longitudinal plane El.

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