JPH0449872A - Ultrasonic wave motor - Google Patents

Abstract

PURPOSE:To simplify a manufacturing process due to the omission of the reduc ing and bonding process of the number of the component parts of a moving body, and lighten the weight of a motor, and obtain the efficient and stable ultrasonic wave motor by forming the moving body, with a fiber reinforced resin complex reinforced with the use of carbon fibers at least. CONSTITUTION:A moving body 24 is formed with a carbon fiber reinforced resin complex. A reason for using carbon fibers is to enhance the rigidity of a frictional contact surface and to improve the mechanical strength of the moving body 24. It is molded by using a metallic mold, as a working method. Besides, compared with a conventional moving body, the weight of the moving body 24 can be reduced. Besides, the progressive wave of deflection oscillation due to an oscillating body 23 can be transmitted to the moving body 24 efficient ly, and also on driving for a long time, stable motor characteristic can be kept. It is desirable that the including quantity of the carbon fibers is 10weight% or more and 70weight% or less. As a result, the characteristic is stabilized, and a manufacturing process can be simplified due to the reduction of the number of the component parts of the moving body and the omission of a bonding process, and the weight of a motor can be lightened.

Description

[Detailed description of the invention] Industrial application field of the present invention? 1 Regarding ultrasonic motors that generate driving force by exciting elastic waves using piezoelectric bodies such as piezoelectric ceramics.More specifically, regarding the configuration of the moving body of ultrasonic motors.Conventional technologyRecently, configurations using piezoelectric bodies Ultrasonic motors, which generate elastic vibrations in a vibrating body and use this as a driving force, have been attracting attention. Below, the conventional technology of ultrasonic motors will be explained with reference to the drawings.

Fig. 4 is a partially cutaway perspective view of a conventional annular ultrasonic motor. The vibrating body 4 is laminated together, and 7 is a movable body in which a wear-resistant friction material 6 is bonded to an elastic body 5, and is installed in pressure contact with the vibrating body 4.

FIG. 5 is a partially cutaway perspective view of a conventional disc type ultrasonic motor. In the figure, 4a is a vibrating body constructed by bonding a disk-shaped piezoelectric material 3a to the bottom surface of a disk-shaped elastic substrate 2a having a plurality of protrusions 1a. 7 more
A is a movable body consisting of an elastic body 5a combined with a wear-resistant friction material 6a, and is installed in pressure contact with the vibrating body 4a.Here, in the above two conventional examples of ultrasonic motors, Conventionally, metals such as iron or stainless steel have been used as the material for the elastic bodies 5 and 5a.
Although the moving body 7.7a of the ultrasonic motor is constructed by bonding wear-resistant friction materials 6, 6a to the piezoelectric body 3.3a by bonding or other methods, two sets of drive electrodes (not shown) are attached to the piezoelectric body 3.3a. is configured, and when two AC voltages having a predetermined phase difference are applied to the drive electrodes, the piezoelectric body 3.3
a undergoes stretching and contraction vibration, and the elastic substrates 2 and 2a act to resist expansion and contraction, so even if the traveling wave of bending vibration is excited in the vibrating body 4.4a due to the same effect as a bimetal, the vibrating body 4.4a Any point on the surface of the oscillating body moves along an elliptical trajectory due to the traveling wave of the bending vibration.Protrusions 1 and la expand the displacement of this elliptical trajectory in the lateral direction (component in the direction in which the traveling wave travels). The movable body 7.7a installed in pressure contact with the protrusion 1.1a of 4, 4a is frictionally driven and rotated by the enlarged lateral displacement.

Problems to be Solved by the Invention Ultrasonic motors excite traveling waves of bending vibration with an amplitude of several microns in a vibrating body consisting of a piezoelectric material and an elastic substrate.
This is a motor that magnifies the lateral displacement caused by this traveling wave with a protrusion and drives a moving body installed in pressure contact with the tip of the protrusion. When a moving body is constructed by coupling an elastic body such as It must have enough rigidity to prevent large elastic deformation in the direction (direction of travel of the traveling wave).

In addition, in order to efficiently transmit the traveling wave of bending vibration from the vibrating body to the vibrating body, it is necessary to realize uniform contact in the pressurized contact state. If a certain force is used (if a highly rigid material such as metal or ceramic is used for the contact surface), the elastic deformation in the vertical direction during pressurization will be small and it will be difficult to achieve uniform contact, resulting in the generation of noise. This results in a decrease in motor efficiency.

On the other hand, in the above case, when a moving body is constructed by bonding a wear-resistant friction material to an elastic body such as metal, L
When the thickness of the friction material is made thinner (the force that varies depending on the pressing force of the motor) may cause noise and a decrease in motor efficiency. This is thought to be due to the fact that the elastic deformation in the vertical direction becomes smaller, making it impossible to achieve uniform contact, and increasing the mechanical quality factor (Ql) against unnecessary vibrations.

Furthermore, like the above? 'w When a moving body is constructed by bonding a wear-resistant friction material to an elastic body such as metal,
Since metal materials have a high specific gravity, the weight of the moving object is large (as a result, the total weight of the motor increases, which creates a limit when trying to reduce the weight of an ultrasonic motor.Moving objects and elastic objects The process is complicated due to the combination with the present invention.
The objective is to simplify the manufacturing process by reducing the number of moving body parts and omitting the bonding process, while at the same time reducing the weight of the motor, and to provide an efficient and stable ultrasonic motor. Means for Solving the Problems According to Invention 1: A vibrating body in which a piezoelectric body is bonded to an elastic substrate. A superstructure that moves the movable body by bringing the movable body into pressure contact and exciting a traveling wave of flexural vibration in the vibrating body. In the sonic motor, the moving body is made of a fiber-reinforced resin composite reinforced with at least carbon fiber.

By constructing the working moving body from a fiber-reinforced resin composite reinforced with at least carbon fibers, the carbon fibers can increase the rigidity in a small area of the friction contact surface, while at the same time increasing the elasticity in a large area. By increasing the
It has a surface correction effect that absorbs the undulations of the contact surface between the vibrating body and the moving body, and can ensure flatness. It is possible to efficiently transmit the traveling wave of bending vibration from the vibrating body to the moving body. becomes.

In addition, by constructing the moving body from a fiber-reinforced resin composite reinforced with at least carbon fiber, this composite has excellent wear resistance. It has the effect of imparting lubricity, making it possible to maintain stable motor characteristics even during long-term operation, making it possible to realize an ultrasonic motor with excellent long-term reliability. By constructing a fiber-reinforced resin composite reinforced with carbon fibers, the number of parts of the moving body is reduced compared to a structure in which a friction material is bonded to a metal elastic body, and the adhesive process is omitted. The process can be simplified and at the same time the weight of the moving body can be reduced, and therefore the weight of the ultrasonic motor can be reduced. Give an explanation.

(First Embodiment) FIG. 1 shows the appearance of the main parts of an annular ultrasonic motor which is a first embodiment of the present invention.

In the figure, reference numeral 23 denotes a piezoelectric body 22 on the bottom surface of a stainless steel annular elastic substrate 21 having a plurality of protrusions 20.
A24 is a moving body made of a fiber-reinforced resin composite reinforced with at least carbon fiber, and this moving body 24 is installed in pressure contact with the vibrating body 13. Accordingly, the moving body 24 constituting the ultrasonic motor is installed in pressure contact with the vibrating body 23 using a disc spring (not shown). 4 is a partially enlarged side view of the configuration of the main parts of the motor. The lateral displacement due to the traveling wave of the bending vibration excited by the vibrating body 23 is magnified by a plurality of protrusions 20, and the movement is installed in pressurized contact. Therefore, the moving body 2
4 has enough rigidity to prevent the contact surface of this moving body 24 from being significantly elastically deformed in the lateral direction due to the load torque, and at the same time requires appropriate mechanical strength to transmit the driving force of the Lumi motor to the outside. In this embodiment, the moving body 24 is made of a carbon fiber-reinforced resin composite in order to increase the rigidity by using carbon fiber as described above, and at the same time to compensate for the insufficient mechanical strength with the resin alone.

Here, the reasons for using carbon fiber are as follows: By using carbon fiber, the rigidity of a moving body is improved compared to inorganic fibers such as glass fiber at the same fiber content. This is because it is possible to increase the rigidity of the frictional contact surface by increasing the amount, and at the same time, it is possible to improve the mechanical strength of the moving body.

Specifically (L In this example, by injection molding a kneaded material of 30% by weight of carbon fiber and 70% by weight of polyphenylene sulfide resin, a ring-shaped material with a specific gravity of 1
．． Mobile body 2 made of a carbon fiber reinforced resin composite of No. 45
4 and 9 As a result, the conventional annular ultrasonic motor does not require an adhesion process to bond the friction material to the metal elastic body, and can be made using a mold using a method such as injection molding or compression molding. By having the above configuration, the movable body 24 can be easily molded like a conventional annular ultrasonic motor. The weight of the moving body 24 can be reduced to at least 1/4 compared to a moving body of the same size constructed by bonding a friction material to a stainless steel elastic body. We were able to realize an ultrasonic motor that can efficiently transmit traveling waves to a moving object, maintain stable motor characteristics even during long-term operation, and has excellent long-term reliability. Example) The appearance of the second example is the same as that shown in Fig. 1. In this example, a moving body 24 made of a carbon fiber-reinforced resin composite having an annular shape and a specific gravity of 1.44 was obtained. As in the 11th example, it was lightweight, required fewer man-hours to manufacture, had UX, and had stable characteristics. Ultrasonic waves were obtained (Third Example) The third example is shown in FIG.

First, a piezoelectric material 32 is bonded to the bottom surface of a stainless steel disc-shaped elastic substrate 31 having a plurality of protrusions 30, thereby forming a circular shape made of a carbon fiber reinforced resin composite that constitutes a disc-shaped vibrating body 33. Plate-shaped moving body 34
ii It is obtained by injection molding a mixture of 30% by weight of carbon fiber and 70% by weight of polyethersulfone resin, and its specific gravity is 1.47. This movable body 34 is press-fitted into the vibrating body 33 and is installed in pressurized contact with the vibrating body 33.In the disk-type ultrasonic motor of this embodiment, the friction is similar to that in the conventional disk-type ultrasonic motor. In addition, it has become possible to easily mold the moving body 34 using a mold using methods such as injection molding and compression molding. It is possible to reduce the weight of the moving body 34 to at least 1/4 of that of a moving body of the same size constructed by bonding a friction material to a stainless steel elastic body, such as a plate-type ultrasonic motor. (Fourth Example) The external appearance of the fourth example is the same as that shown in Fig. 3, but in this example the motor is made of a carbon fiber reinforced resin composite. Body 3414.6
It is obtained by compression molding a composite in which 0% by weight carbon fiber woven fabric is impregnated with 40% by weight polyphenylene sulfide resin, and its specific gravity is 1.45. Similarly, in each of the above embodiments in which it is possible to obtain an ultrasonic motor that is lightweight, requires few man-hours, and has stable characteristics, what is the content of carbon fiber contained in the fiber-reinforced resin composite that constitutes the moving body? ! A force that can be adjusted according to the pressing force of the ultrasonic motor (if the fiber content is less than 10% by weight, the effect of improving rigidity is insufficient, and if the fiber content exceeds 70% by weight) The force varies depending on the molding method or the fluidity of the resin (molding becomes difficult and at the same time the mechanical strength of the molded product becomes weak).A range of 10% by weight or more and 70% by weight or less is preferable.

In addition, as a type of reinforcing fiber, force fork using carbon fiber is used.
It is also possible to use inorganic fibers other than carbon fibers in combination with the above carbon fibers, and in order to further adjust the rigidity, inorganic fibers such as graphite powder, tetrafluoroethylene powder, molybdenum sulfide powder, graphite fluoride powder, etc. can be used in the above fibers. Although it is possible to combine fillers, they can also be used as resins constituting fiber-reinforced resin composites.
Strength using thermoplastic resins such as polyphenylene sulfide resin, polyether ether ketone resin, and polyether sulfone resin, but is not limited to these.
It is desirable to use a resin with a high heat distortion temperature, and it is also possible to use thermosetting resins such as phenolic resins, bismaleimide triazine resins, etc.

Effects of the Invention By constructing the moving body of the ultrasonic motor of the present invention from a fiber-reinforced resin composite reinforced with at least carbon fiber, the characteristics are stabilized, and the number of parts of the moving body can be reduced and bonded. By omitting steps, it is possible to simplify the manufacturing process and at the same time reduce the weight of the motor.

[Brief explanation of the drawing]

FIG. 1 is an exploded perspective view partially showing the main components of an annular ultrasonic motor, which is an embodiment of the ultrasonic motor of the present invention, in cross section. FIG. 4 is an exploded perspective view partially showing the main components of the sonic motor in cross section. Fifth
The figure is an exploded perspective view, partially in cross section, of the main components of a conventional annular ultrasonic motor. 1, la, 20, 30...protrusion 2.2a,
21.31...Elastic substrate 3.3a, 22.32 Piezoelectric body 4.4a, 13, 23, 33... Vibrating body
5.5a...Elastic body 6, 6a...Friction material, 7.
7a River mobile body 4, 4, ... Carbon fiber reinforced resin mobile body Fig. 5... Rotating stock

Claims (2)

[Claims] (1) In an ultrasonic motor that moves a movable body by bringing a movable body into pressure contact with a vibrating body having a piezoelectric body coupled to an elastic substrate and exciting a traveling wave of bending vibration to the vibrating body, the moving body An ultrasonic motor whose body is made of a fiber-reinforced resin composite reinforced with at least carbon fiber. (2) The content rate of carbon fiber in the moving body is expressed as a weight content rate,
The ultrasonic motor according to claim 1, wherein the ultrasonic motor is in a range of 10% or more and 70% or less.