RU2062545C1 - Reverse piezoelectric motor - Google Patents

Abstract

FIELD: automatic control systems. SUBSTANCE: device has two piezoelectric oscillators which pushing rods are bent to sides which are opposite to field of individual rotors. Rolling members (balls) are located between rotors and are connected to output shaft through separating disk. When high-frequency voltage is supplied to one oscillator, corresponding rotor starts its rotation in some direction and leads rotation of rolling members which start rotation of output shaft. When both oscillators are started simultaneously, rotation speed of rotor is algebraic average of rotation speed of rotors. Another claim of invention describes design in which rotors are connected to output shaft in alternating order through friction members. EFFECT: increased range of rotation speed. 2 cl, 8 dwg

Description

 The present invention relates to piezoelectric devices, and more specifically to reversible piezoelectric rotational motion motors, and can be used as low speed gearless drives of various mechanisms, in particular such as tape drives of tape recorders, input-output devices, digital printers, in the automotive industry in quality of wiper drives, power windows, etc.

 Known reversible piezoelectric motor [1] comprising a rotor with a piezoelectric oscillator installed in it in the form of a rod, with pushers at the ends. The oscillator is mounted on a swinging lever so that in the extreme positions of the lever one of the pushers interacts with the working surface of the rotor, providing rotation of the rotor in the corresponding direction.

The disadvantage of such an engine is the limited specific power (referred to the volume) due to the fact that the torque is provided by the interaction of only one pusher. (An increase in the number of oscillators and / or pushers complicates the design, but does not solve the power problem.)
Known reversible piezoelectric engine [2] The engine contains two coaxially mounted piezoelectric oscillators with electrodes and pushers. One of the oscillators is mounted on the stator motionless, the other on the output shaft, while the electrical contact of the electrodes of the moving oscillator is made using slip rings and brushes. The pushers on the oscillators are bent in one direction and interact with the intermediate rotor in the form of a cylinder. When applying alternating voltage to the electrodes of a stationary oscillator, its pushers rotate the intermediate rotor and then the output shaft with a movable oscillator due to the friction of its pushers bent along the rotation of the intermediate rotor. When voltage is applied to the electrodes of the moving oscillator, its pushers interacting with the stationary intermediate rotor, which is inhibited by the pushers of the fixed oscillator, rotate the moving oscillator with the output shaft in the opposite direction. If there is no voltage on both oscillators, the engine is inhibited.

 The disadvantage of this engine is the presence of slip rings with brushes, which significantly reduce its reliability, as well as a limited moment, since the moment is transmitted to the output shaft from the active (switched on) oscillator due to the friction forces pressed by the pushers of the passive oscillator, pressed to the intermediate rotor, i.e. the “intermediate rotor passive oscillator” pair is in fact a friction clutch with a limited torque. As for the negative influence of slip rings, the following circumstances must be considered. For the oscillator to work, it is necessary to apply a high-frequency voltage of hundreds of volts to its electrodes at currents from fractions to several amperes, which limits the use of motors with such current leads in explosive conditions.

 The basis of the invention is the creation of a reversible piezoelectric motor with such a design that would allow, due to the implementation of the intermediate rotor of two independent parts, each of which can be connected with the output shaft, firstly, to increase the reliability of the engine due to the fixed installation in the housing both oscillators, thus eliminating the need for sliding contacts, and, secondly, to reduce or eliminate torque limitation.

 The problem is solved in that in a reversible piezoelectric motor (option I), comprising a housing with two piezoelectric oscillators placed in it, on the working surfaces of which pushers are mounted obliquely, friction-coupled with the working surface of the rotor connected to the output shaft, according to the invention, both oscillators are installed in the housing motionless, the pushers on the oscillators are bent in opposite directions, and the rotor is made of two independent parts of individual rotors, between which we placed rolling bodies connected with the output shaft, interacting with the rotors in friction or by gearing. Moreover, according to the invention, the oscillators are made in the form of flat rings with electrodes on flat surfaces and cylindrical working surfaces.

 In addition, according to the invention, the working surfaces of the rotors are cylindrical. Moreover, according to the invention, the oscillators and their rotors are concentric. And also according to the invention, the engine contains elements for elastic pressing of the rotors to the rolling bodies interacting with the rotors frictionally.

 In addition, according to the invention, the working surfaces of the rotors are conical and oriented vertically counter. And also according to the invention, the oscillators are made in the form of cylinders with electrodes on cylindrical surfaces and end working surfaces, and the working surfaces of the rotors are made flat.

 The problem is also solved by the fact that in a reversible piezoelectric engine (II option), containing a housing with two piezoelectric oscillators placed in it in the form of flat rings, on the cylindrical working surfaces of which pushers are obliquely mounted, frictionly coupled to the working surface of the rotor associated with the output shaft , according to the invention, both oscillators are fixed in the housing, the pushers on the oscillators are bent in opposite directions, the rotor is made of two independent hours individual rotors for each oscillator equipped with friction elements on the outer ends, with conical working surfaces oriented vertices (smaller bases) outward, and the engine additionally contains disks with friction elements mounted on the output shaft on both sides of the rotors for interaction with friction elements rotors, and the rotors themselves are interconnected in the axial direction and are mounted with the possibility of rotation relative to each other and movement in the axial direction and before contact in extreme positions of its friction elements with friction elements of the disks.

 This invention will significantly improve the reliability of a reversible piezoelectric motor due to the absence of moving (sliding) contacts in the oscillator power supply circuit, as well as increase the torque by reducing the slip of the passive group of pushers (i.e., the pushers of the de-energized oscillator) or by eliminating the passive group of pushers when transmitting the moment.

 The invention is further illustrated by specific examples of its implementation and the accompanying drawings, in which: FIG. 1 depicts a reversible piezoelectric motor with axially arranged pairs of rotor oscillator elements with a cylindrical working surface, with rolling bodies between rotors and with elements for pressing rotors against rolling bodies, a longitudinal section according to the invention; FIG. 2 depicts a reversible piezoelectric motor, cross section AA in FIG. 1, according to the invention; FIG. 3 shows a reversible piezoelectric motor with axially arranged pairs of elements, an oscillator rotor with a conical working surface, with rolling bodies between rotors, according to the invention; FIG. 4 shows a reversible piezoelectric motor with coaxially arranged rotors, with rolling bodies in the form of gears between them, according to the invention; FIG. 5 depicts a reversible piezoelectric motor with coaxially arranged oscillators and rotors with flat working surfaces, with rolling bodies between the rotors, according to the invention; FIG. 6A.6D depict a reversible piezoelectric motor with a concentric arrangement of oscillators and rotors, with rolling bodies in the form of gears (rollers) or conical smooth rollers between the rotors, according to the invention; FIG. 7 shows a reversible piezoelectric motor according to the II embodiment with rotors coaxially arranged and provided with friction elements and disks mounted on the output shaft, according to the invention; FIG. 8 illustrates the operation of a reversible piezoelectric motor according to I embodiment, according to the invention.

 The reversible piezoelectric motor according to I embodiment (Fig. 1) comprises a housing 1 in which the piezoelectric oscillators 2 and 3 are fixedly mounted with pushers 4 and 5, respectively, and rotors 6 and 7 are movably rotatably and axially displaced, between which, as between the clips thrust bearings, balls 8 are placed around the circumference in circular treadmills-grooves of the rolling body 8. Balls are installed in the holes of the separator disk 9, fixed motionless on the output shaft 10 of the engine. The rotors 6 and 7 are pressed against the balls 8 by the force of the compression springs 11 through the thrust ball bearings, in which the pressure ring 13, the rotors 6 and 7 and the housing 1 perform the function of the cages between which the balls 12 are placed.

 The rolling bodies can also be made in the form of gears 14 mounted between the rotors 6 and 7, which have respective gear rims 15 around the circumference (Fig. 4). The gears 4 are mounted on the axles 16 and the leashes 17, fixed motionless on the output shaft 10.

 Piezoelectric oscillators 2 and 3 of radial vibrations are acoustically isolated from the housing 1 by means of gaskets 18 made of elastic material (for example, rubber) and mounted on it with nuts 19. The housing 1 serves to protect the piezoelectric oscillators and other engine elements from damage, as well as to fix piezoelectric motor in the product.

 The piezoelectric radial oscillator is an electromechanical device for converting electrical energy into mechanical energy of vibrational, mainly in the radial direction, particle motion of the active element of the piezoelectric oscillator - piezoelectric element 20, made in the form of a body of revolution. To create radial vibrations in a piezoelectric oscillator, the piezoelectric element 20 is made in the form of a ring (disk with a hole) and is made of a material having piezoelectric properties, with electrodes 21 on the flat surfaces of the ring equipped with leads 22. The electrodes are a thin metal coating on the polished surface of the piezoelectric element 20 An alternating voltage from a power source (not shown in the drawings) is supplied to the electrodes 21 through the terminals 22 soldered to the electrodes, as shown in FIG. 1 (or by contact).

 Pushers 4, 5 are mounted on the working cylindrical surfaces of the piezoelectric elements, which abut against the inner surfaces of the rotors 6 and 7 at an acute angle with the other ends, and in opposite directions, forming two groups of multidirectional pushers.

 In FIG. Figure 3 shows a similarly reversible piezoelectric motor with conical working surfaces of the rotors 6 and 7 and obliquely cut ends of the pushers 4 and 5. This form of the elements ensures that the engine generates axial forces on the rotors 6 and 7, which ensure that the rotors are pressed against the rolling bodies 3.

 In the engine shown in FIG. 5, the oscillators 2, 3 are made in the form of hollow cylindrical elements with electrodes 21 on their cylindrical surfaces and with pushers 4, 5 mounted on the end surfaces. Pushers 4, 5 on the oscillators are bent in opposite directions and abut their free ends against the flat surfaces of the rotors 6 and 7, between which the rolling elements 8 are mounted, mounted in the holes of the separator disk 9, mounted on the output shaft 10.

 In FIG. 6 shows a reversible piezoelectric motor with a concentric arrangement of piezoelectric oscillators and rotors. Oscillators 2 and 3 with pushers 4 and 5 are mounted concentrically in the housing 1. In the space between them there are rotors 6 and 7, and between the rotors of the rolling body are cylindrical gears 14 in the form of rollers interacting with gear rims 15 on the cylindrical surfaces of the rotors 6 and 7 (Fig. 6C).

 The gears 14 are installed on the axles 16 and the leashes 17, fixed motionless on the output shaft 10. On the axles 16 in the plane of the ends of the rotors 6 and 7 washers 23 are installed (Fig. 6B), which prevent the axial displacement of the rotors.

 The use of gearing between the rotors 6 and 7 and the rolling bodies of the gears (rollers) 14 does not require additional pressing of the rotors to the rollers.

 However, in the case of using smooth (non-toothed) rolling elements (balls or rollers), special elements are used to provide the necessary force to compress the rotors to the rolling elements. In FIG. 6 shows a diagram of the interaction of the rotor with rolling bodies in the form of conical rollers 24. The rollers are placed between the rotors 6 and 7 on the axes 16; with their lateral surface, the rollers touch the edges of the rotors. In the axial direction, each pair of rollers 24 is preloaded by spring compression 25, the force of which, in combination with the angle of conicity of the rollers, determines the force that the rotors press against the rollers.

 Reversible piezoelectric motor (I option) works as follows.

 When applying to the electrodes 21 of one of the piezoelectric oscillators of radial vibrations (2 in Fig. 1) an electric voltage of a certain frequency equal to or close to the resonant frequency of the longitudinal radial vibrations of the piezoelectric element 20, longitudinal radial vibrations arise in it. These vibrations are transmitted to the pushers 4 mounted on the cylindrical surface of the piezoelectric element.

When expanding the piezoelectric element 20, its surface moves the inner ends of the pushers 4 located in mechanical contact with it in the radial direction. The opposite ends of the pushers, which abut against the cylindrical working surface of the rotor 6, due to jamming create a tangential force on the rotor (since the angle between the pusher and the tangent to the rotor surface is less than 90 ^° ), which causes the rotor 6 to rotate counterclockwise in FIG. 2.

 When compressing the piezoelectric element 20, the inner ends of the pushers 4, mounted on the surface of the piezoelectric element, move in the radial direction to its center. In this case, the outer ends of the pushers 4 interacting with the surface of the rotor 6, due to a decrease in the pressing force and, accordingly, a decrease in the friction force, slip along the working surface of the rotor and take a new position in the circumferential direction of the rotor. The reverse rotation of the rotor 6 can be hindered to a large extent by the inertia forces of the mass of the rotor and the associated masses of the rotatable mechanism.

 Such a process is repeated during oscillations of the piezoelectric element 20 and is accompanied by the appearance of a constant moment leading the rotor 6 of the piezoelectric motor into rotation.

 The balls 8 located between the rotating rotor 6 and the stationary rotor 7 of the rolling body 7, which are in frictional interaction with the surfaces of the rotors 6 and 7, are rolled along their treadmills and entrain the separator 9, leading the output shaft 10 to rotate.

 Prevention of slipping of the rolling bodies of the balls 8 on the surface of the treadmills on the rotors 6 and 7 is provided by increasing the friction force between them by increasing the mutual pressing of the rotors 6 and 7 to the balls 8 under the action of compression springs 11.

 The use of rolling elements in the form of gears 14 interacting with the gear ends 15 on the rotors (Fig. 4) eliminates slipping and does not require pressing the rotors to the gears, but only fixing the distance between them.

 When such an engine operates for one revolution of the rotor 6, the separator 9 with balls 8 and, accordingly, the output shaft make half a revolution, i.e. output shaft speed is lower than rotor speed.

 When an alternating voltage is applied to another oscillator 3 and the oscillator 2 is turned off, the engine will operate in the same way as described above, except for the direction of reverse rotation, due to the fact that the pushers 4 and 5 on the oscillators 2 and 3 are bent in opposite directions.

 The rotational speed of the rotors 6 and 7 is determined as the resonant frequency of the piezoelectric elements and the design parameters of the engine, in particular the size and angle of the tappets, and the parameters of the supply voltage frequency and amplitude. Varying the last parameter, it is possible to widely control the frequency of rotation of the engine rotors and, accordingly, the output shaft 10.

При такой схеме работы двигателя возможно получение весьма низких частот вращения без снижения крутящего момента.With the simultaneous supply of the supply voltage to both oscillators, the rotation frequency of the output shaft 10 is an algebraic half-sum of the rotation frequencies of the rotors 6 and 7:
ω ₁₀ = (ω ₆ -ω ₇ ) / 2
By changing the order of switching on the oscillators (one, the other, or both together) and the voltage parameters (in particular, the amplitude), you can smoothly control the output shaft speed in the range from

With such a scheme of the engine, it is possible to obtain very low speeds without reducing torque.

 In the engine of FIG. 3, the rotors are pressed against the rolling bodies due to the axial component of the interaction force of the obliquely cut ends of the pushers 4, 5 with the conical surfaces of the rotors 6, 7. Otherwise, the operation of such an engine completely repeats the operation of the engine of FIG. 1-2.

 A motor with a concentric arrangement of oscillators and rotors (FIG. 6A) operates in the same way as the engine of FIG. 1-2. A feature of this engine is the difference in the characteristics of the oscillators 2 and 3 due to differences in size. Oscillator 3 due to its large size has a lower resonant frequency. Therefore, and also because the diameter of the rotor 7 is larger than the diameter of the rotor 6, the rotational speed of the rotor 7 will be lower than the rotational speed of the rotor 6, and the torque is higher.

 In the engines of FIG. 1 and 3, using smooth balls 8 as rolling bodies, the minimum number of balls is three; with a larger number of them, very stringent requirements must be imposed on their sizes to ensure contact of all balls with the racetracks of rotors 6 and 7.

As can be seen from the diagram of FIG. 8, the circumferential force F _n reduced to the ball 8 from the moment of load on the shaft 10 is balanced by the forces F ₆₈ and F ₇₈ applied to the ball from the side of the rotors 6, 7 due to the friction forces between it and the rotors 6 and 7. In this case, one of the forces (for example, F ₆₈ ) is created by the "active" rotor 6, driven by the pushers 4 of the included oscillator 2, and the other by the stationary, "passive" rotor 7. This force is balanced by the friction force F ₅₇ F _{78 of the} rotor 7 and the ends bent in the direction of action pushers 5. It is seen that in this scheme the passive elements of the rotor 7 with pushers 5 i They are actually a friction clutch characterized by a certain maximum permissible torque. The diagram also shows that the friction force is equal to half the load force F _n , i.e. reversible motor in accordance with the circuit of FIG. 1-2, and also FIG. 3-6 is characterized by twice the maximum allowable torque compared to the prototype.

 The momentum transmitted by each ball 8 to the output shaft 10 is determined by the normal pressure force and the friction coefficient (i.e., the friction force between the surfaces of the balls 8 and the racetracks of the rotors 6 and 7), as well as the diameter of the racetracks of the rotors.

 Since with an increase in the number of balls the force of normal pressure per each ball is proportionally reduced, an increase in their number is not effective; increasing the transmitted moment (to prevent slippage) can be achieved by increasing the force of the springs 11 of FIG. 1 and the diameter of the treadmills of the rotors.

 In an engine with a concentric arrangement of rotors 6 and 7 and rolling elements in the form of conical rollers 24, twisted in pairs by springs 25, each such pair is independent of the others; the maximum moment transmitted to the output shaft is determined by the angle of the cone of the rollers 24 and the force of the springs 25, as well as the radius of the rotors.

 The reversible piezoelectric motor according to the second embodiment (see Fig. 7) comprises a housing 1 in which the piezoelectric oscillators 2 and 3 are fixedly mounted with pushers 4 and 5, respectively, with oblique ends cut off. The rotors 6 are made with conical working surfaces and are mounted on a sleeve 26 located on the output shaft 10 with the possibility of rotation and axial movement. The rotors 6 and 7 are mounted on the sleeve 26 with the possibility of rotation on it independently of each other. On the outer end faces of the rotors 6 and 7, friction elements 27 and 28 are made in the form of a flat ring. On the output shaft 10, the disks 29 and 30 are fixedly mounted with similar friction elements 31, 32, opposite the corresponding friction elements 27, 28 of the rotors 6, 7, and interacting with them in the extreme positions of the rotors.

 Reversible piezoelectric motor according to option II (Fig. 7) works as follows.

When one of the piezoelectric oscillators, for example 2, is supplied to the electrodes 21, an electric voltage of a certain frequency equal to or close to the resonant frequency of the radial vibrations of the piezoelectric element 20, longitudinal radial vibrations arise in it, which are transmitted to the followers 4. When the piezoelectric element 20 expands, its outer working surface moves the inner ends of the pushers 4 which are in mechanical contact with it in the radial direction. The opposite ends of the pushers, inclined abutting against the working conical surface of the rotor 6, due to jamming create a tangential force on the rotor (since the angle between the pusher and the tangent to the rotor surface is less than 90 ^o ), which causes the angular displacement of the rotor.

 When compressing the piezoelectric element 20, the inner ends of the pushers 4, mounted on the surface of the piezoelectric element, move in the radial direction to its center. In this case, the outer ends of the pushers 4 interacting with the surface of the rotor 6, due to a decrease in the friction force, slip along the working surface of the rotor and occupy a new position in the circumferential direction of the rotor. The reverse rotation of the rotor 6 can be hindered to a large extent by the inertia forces of the mass of the rotor and the associated masses of the rotatable mechanism.

 Such a process is repeated during oscillations of the piezoelectric element 20 and is accompanied by the appearance of a constant moment leading the rotor 6 of the piezoelectric motor into rotation. In this engine, torque is transmitted from the rotors 6, 7 to the output shaft through friction elements 27, 28, 31, 32 on the rotors and on the disks 29, 30 mounted on the shaft 10.

 The movement of the block of rotors 6-7, united by a sleeve 26, occurs due to the axial component of the interaction force of the obliquely cut ends of the pushers 4 with the conical working surface of the rotor 6. When the oscillator 2 is operating and the oscillator 3 is turned off, the pushers 4 interact with the conical surface of the rotor 6, bringing it into rotation. At the same time, due to the axial component of the interaction force of the pushers with the rotor 6, the rotor 6 and the rotor 7 connected to it by a sleeve 26 move upward, while the friction element 28 of the rotor 7 comes out of contact with the friction element on the disk 30 mounted on the output shaft 10, and the friction elements 27 and 31 on the rotor 6 and the disk 29 come into contact, providing reverse engine. The movement of the rotor 7 is possible due to some straightening and bending of the pushers 5 of the inoperative oscillator 3 and the free installation of the rotor 7 on the sleeve 26, allowing its rotation.

 Such an engine can operate only with one oscillator switched on, unlike engines with rolling bodies (according to the I variant), which allow operation with both oscillators.

 A characteristic feature of this engine is the absence of torque restrictions from the side of the “passive” pair of rotors 7 pushers 5, since the “active” rotor is connected directly to the output shaft 10.

 The proposed piezoelectric motor can be used as a gearless continuous rotation motor with reverse. The engine can be used in actuators of automation systems, in the automotive industry in drives for lowering and raising glass, and for other purposes. YYY2 YYY4 YYY6

Claims (8)

 1. Reversible piezoelectric engine, comprising a housing with two piezoelectric oscillators located in it, on the working surfaces of which pushers are obliquely mounted, frictionly coupled to the working surface of the rotor associated with the output shaft, characterized in that both oscillators are mounted in the housing motionless, the pushers on the oscillators bent in opposite directions, while the rotor is made of two parts of individual rotors, between which are placed the rolling body associated with the output shaft, interacting with rotors by friction or gearing.  2. The engine according to claim 1, characterized in that the oscillators are made in the form of flat rings with electrodes on flat surfaces and cylindrical working surfaces.  3. The engine according to claim 2, characterized in that the working surfaces of the rotors are cylindrical.  4. The engine according to claim 3, characterized in that the oscillators and rotors are concentric.  5. The engine according to claim 3 or 4, characterized in that it further comprises elements for elastic pressing of the rotors to the rolling bodies.  6. The engine according to claim 2, characterized in that the working surfaces of the rotors are conical and oriented vertically in the opposite direction.  7. The engine according to claim 1, characterized in that the oscillators are made in the form of cylinders with electrodes on cylindrical surfaces and end working surfaces, while the working surfaces of the rotors are made flat.  8. A reversible piezoelectric motor, comprising a housing with two piezoelectric oscillators placed in it in the form of flat rings, on the cylindrical working surfaces of which pushers are obliquely mounted, frictionally coupled to the working surface of the rotor connected to the output shaft, characterized in that both oscillators are fixed the pushers on the oscillators are bent in opposite directions, the rotor is made of two parts of individual rotors equipped with friction elements on the outer ends ntami, with conical working surfaces oriented outward by smaller bases, while the engine additionally contains disks with friction elements mounted on the output shaft on both sides of the rotors for interacting with friction elements of the rotors, and the rotors are axially connected and mounted to rotate relative to each other and axial movement to contact in the extreme positions of its friction elements with friction elements of the disks.

Images