KR100683933B1 - Micro piezoelectric linear motor - Google Patents

Abstract

A micro piezoelectric linear motor is provided to realize miniaturization and to increase degree of freedom in configuration by reducing influence of a piezoelectric ceramic. A micro piezoelectric linear motor includes a beam shaped elastic substrate(23), a piezoelectric body(22), and a shaft(21). A hollow core is formed inside the beam shaped elastic substrate(23). The piezoelectric body(22) is attached to an upper part of the elastic substrate(23). The shaft(21) is formed on the upper part of the elastic substrate(23). The piezoelectric body(22) is displaced in a perpendicular direction to a displacement direction of the shaft(21). A length of the piezoelectric body(22) according to a lengthwise direction of the elastic substrate(23) is shorter than a length of the hollow core.

Description

Micro piezoelectric linear motor

Figure 1 shows a simplified structure of a conventional piezoelectric linear motor.

2A and 2B show an example of a conventional mobile body.

Figure 3 shows a perspective view of one embodiment of a piezoelectric linear motor of the present invention.

Figure 4 shows a cross-sectional view of one embodiment of a piezoelectric linear motor of the present invention.

{Description of main parts of the drawing}

11 elastic substrate 12 piezoelectric plate

13 support means 14 shaft

15: moving body 16: transfer system

17: pressing ring 21: shaft

22: piezoelectric body 23: elastic substrate

The present invention relates to a piezoelectric linear motor used to drive a lens such as a camera, and more particularly, a moving shaft is attached to a piezoelectric plate attached to an elastic body and the piezoelectric plate and the elastic body are displaced by the piezoelectric effect. A linear motor vibrating linearly together with a moving body mounted thereon also relates to a linear motor having improved driving performance.

A motor mounted to drive a camera lens in a portable mobile communication terminal such as a mobile phone or a PDA is formed in a very small size. Stepping motor among the small motors that can be used for driving camera lens should use reduction gear and cam to change the fast rotation to linear movement. Due to the error occurs and the power consumption is large, the use is limited, and there are disadvantages such as generating high current and heat.

In order to solve the above disadvantages, a linear motor driven by using a piezoelectric effect has been developed. The linear motor using the piezoelectric effect combines the method of driving with the traveling wave generated by the flexural wave and the longitudinal and lateral vibration actuators to generate vertical and horizontal vibrations repeatedly. Known driving methods and the like are known.

The basic form of the standing wave type linear motor is to use plural vibrations generated by combining vibrators having different operating modes, which are used to control the vibration of the piezoelectric actuator and the piezoelectric actuator in the vertical and horizontal directions. It consists of a shaft that transmits mechanical displacement to a moving body.

Various methods have been proposed as a method of transmitting vertical vibration of the piezoelectric actuator in the vertical direction to the moving body through the shaft. In particular, there is a method in which the piezoelectric substrate is bonded to the elastic body to use the bending motion of the elastic body and the piezoelectric plate as a driving force as a driving force.

Figure 1 shows a simplified structure of a conventional piezoelectric linear motor.

In FIG. 1, a piezoelectric linear motor is attached to an elastic substrate 11 and a piezoelectric plate 12 bonded to the elastic substrate, a support means 13 supporting the elastic substrate from below, and the elastic substrate to bend the elastic substrate. And a shaft 14 for transmitting movement to the movable body, and the movable body 15.

The elastic substrate 11 is deformed together with the piezoelectric plate as the piezoelectric plate 12 attached to one or both surfaces thereof is stretched or contracted by the piezoelectric effect, and the peripheral portion of the elastic substrate 11 is fixed to the supporting means 13. The center portion, which is not fixed to the support means 13, displaces upward or downward.

The shaft 14 is attached to the upper portion of the elastic substrate, the shaft is vibrated in the vertical direction in accordance with the bending displacement movement, thereby moving the movable body 15 is performed as a linear motor. When the middle portions of the elastic substrate 11 and the piezoelectric plate 12 are displaced up and down, the shaft 14 attached to the upper portion of the elastic substrate moves linearly. Through the linear movement of the shaft, the bending motion of the elastic substrate and the piezoelectric plate is transmitted to the movable body 15 to drive the movable body, and the movable body 15 is directly or indirectly connected to the lens to drive the lens.

The movable body 15 is moved by inertia and friction. The conventional movable body is composed of a conveying system which is in contact with the shaft 14 with a constant frictional force and restraining means that compresses and constrains the conveying system to the shaft.

2A and 2B illustrate an example of a conventional mobile body, and illustrate a mobile body included in the piezoelectric linear motor shown in FIG. 1.

Figure 2a shows only the moving part, which includes an inner 'b' shaped conveying system 16 and an outer crimping ring 17 for pressing the conveying system to the shaft.

FIG. 2B illustrates a state in which the movable body is in contact with the shaft, and illustrates a state in which the transfer system 16 of the movable body of FIG. 2A is in contact with the shaft 14.

The moving body is driven by the movement of the shaft by the transfer system 16 is in contact with the shaft 14 with a frictional force. 2a and 2b, the conventional movable body shown in FIG.

As described above, in the conventional moving body, a 'b' type or other type of feed system is in linear contact with the shaft.

Therefore, it is preferable to increase the efficiency in which the bending motion of the elastic substrate and the piezoelectric plate is transmitted to the movable body by increasing the contact area of the line contact and increasing the frictional force.

In addition, the prior art amplifies the small generated displacement of the piezoelectric body by using a mechanical enlargement mechanism, but the structural area of the elastic substrate is small, which is problematic.

An object of the present invention devised to solve the above problems is to generate a beam-shaped elastic body having a hollow core as a displacement expanding mechanism used to amplify simple driving of piezoelectric ceramics in a motor using a conventional stacked piezoelectric actuator. To provide a piezoelectric linear motor that can be used to improve speed.

Piezoelectric linear motor of the present invention for achieving the above object is a beam-shaped elastic substrate having a hollow core therein; A piezoelectric body attached to an upper portion of the elastic substrate; And a shaft installed on the elastic substrate.

The piezoelectric body is characterized in that the displacement in the direction perpendicular to the displacement direction of the shaft.

The length of the piezoelectric body in the longitudinal direction of the elastic substrate may be smaller than that of the hollow core.

The hollow core may be a beam-shaped hole having the same width as the elastic substrate and having a length shorter than that of the elastic substrate.

In addition, the height of the hollow core is larger than the maximum displacement to the lower side of the piezoelectric body.

In addition, the shaft is characterized in that the circular or polygonal cross section formed.

The apparatus may further include a movable body that linearly moves according to the movement of the shaft by wrapping the shaft and contacting the shaft, wherein the movable body includes the movable body and the shaft when the shaft linearly moves in conjunction with the deformation of the piezoelectric body. When the inertial force of the movable body is greater than the frictional force therebetween, the position in contact with the shaft is changed by sliding along the shaft.

The piezoelectric linear motor of the present invention improves the shape and coupling structure of the piezoelectric body and the elastic substrate, and the shaft and moving parts are not significantly different from those of the conventional piezoelectric linear motor shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In adding reference numerals to components of the following drawings, it is determined that the same components have the same reference numerals as much as possible even if displayed on different drawings, and it is determined that they may unnecessarily obscure the subject matter of the present invention. Detailed descriptions of well-known functions and configurations will be omitted.

3 is a shaft 21 of a piezoelectric linear motor according to an embodiment of the present invention is installed on the piezoelectric body 22, the piezoelectric body 22 is installed on the elastic substrate 23, the elastic substrate 23 The bottom surface is fixedly installed in the housing of the application to be installed.

4 is a cross-sectional view of FIG. 3 to clearly understand the shape of the hollow core of the elastic substrate 23 and the coupling relationship between the piezoelectric body 22 and the elastic substrate 23.

The displacement direction of the piezoelectric body 22 should be a direction perpendicular to the shaft 21. That is, the center portion of the piezoelectric body 22 may be bent up and down by vertical displacement while the piezoelectric body 22 is attached to the elastic substrate 23 and restrained.

The piezoelectric body 22 may be attached to the upper portion of the elastic substrate 23, and at this time, an adhesive such as epoxy may be used.

The elastic substrate 22 is a beam-shaped plate, the hollow core is formed therein. The elastic substrate 23 supports the piezoelectric body 22 and serves to secure a space in which the piezoelectric body 22 is displaced downward.

The hollow core is formed to receive the vertical displacement generated by the piezoelectric body 22 and vibrate together. The height of the hollow core must be greater than the maximum displacement of the piezoelectric body 22 downward.

In addition, the hollow core is preferably formed longer than the length of the piezoelectric body 22 (length relative to the longitudinal direction of the elastic substrate 22).

Of course, the width of the piezoelectric body 22 is preferably equal to or smaller than the width of the elastic substrate 23.

The elastic substrate 22 is fixedly installed on the flat surface of the housing inside the application to be installed.

In addition, the application should be able to secure enough space for the top of the shaft 21 to displace.

The shaft 21 for vertical displacement is fixed to the central portion of the piezoelectric body 22.

The shaft 21 should be at least a size not exceeding the width direction of the piezoelectric body 22.

The shaft 21 may be attached to the piezoelectric body 22 by an adhesive such as an epoxy resin.

In the piezoelectric linear motor of the present invention, as shown in FIG. 1, the elastic substrate 23 provided with the piezoelectric body 22 vibrates and flexes in the vertical direction as the piezoelectric body 22 shrinks or extends, and the piezoelectric body 22 is rotated. The shaft 21 attached to one side at the top of the) is linearly moved in the vertical direction in conjunction with the bending motion.

The shaft 21 is preferably formed in the shape of a rod having a cylindrical or polygonal cross section having a thin circular cross section in order to more efficiently transfer the bending motion of the elastic body to a moving body (not shown).

The movable body in contact with the shaft linearly moves in conjunction with the shaft, and is in contact with the shaft to surround at least a portion of the shaft, so that a predetermined frictional force is generated between the shaft and the movable body. The movable body may move integrally with the shaft or move while moving on the shaft according to the interaction of the frictional force with the shaft and the inertial force according to the continuation of the movement.

For example, when the inertia force is greater than the friction force, the movable body may slide and move along the shaft to move in contact with the shaft, and when the friction force is very large, the relative position with respect to the shaft is large. You can also exercise without changing. In the present invention, in particular, the frictional force is increased, which is more useful when the shaft and the moving body need to move integrally.

As described above, although described with reference to the preferred embodiment of the present invention, those skilled in the art will be variously modified and modified within the scope of the present invention without departing from the spirit and scope of the present invention described in the claims below. It will be appreciated that it can be changed.

As described above, the piezoelectric linear motor using the structural resonance proposed in the present invention, unlike the motor directly using the piezoelectric ceramics, uses the resonance of the structure, thereby affecting the size and displacement of the piezoceramic. It is an independent motor that can be reduced.

In addition, by using a beam-shaped elastic substrate having a hollow core, not only the effect of expanding the displacement of the existing piezoelectric ceramics, but also the advantage of using the resonance of the structure is not only effective in improving the characteristics of the motor, but also in the shape of the beam Structural safety using the integral base of the elastic substrate is competitive in terms of improving the reliability of the motor and ease of assembly.

In addition, the driving frequency can be changed by controlling the size of the elastic substrate.

The piezoelectric linear motor is unlikely to be implemented or controlled by piezoelectric ceramics, and thus, the piezoelectric linear motor may reduce the influence of the piezoelectric ceramics, thereby increasing the degree of freedom of miniaturization and construction.

Claims (7)

A beam-shaped elastic substrate having a hollow core formed therein; A piezoelectric body attached to an upper portion of the elastic substrate; And a shaft installed on an upper portion of the elastic substrate. The piezoelectric linear motor according to claim 1, wherein the piezoelectric body is displaced in a direction perpendicular to the displacement direction of the shaft. The piezoelectric linear motor of claim 1, wherein a length of the piezoelectric body in the longitudinal direction of the elastic substrate is smaller than a length of the hollow core. The piezoelectric linear motor of claim 1, wherein the hollow core is a beam-shaped hole having the same width as that of the elastic substrate and having a length shorter than that of the elastic substrate. The piezoelectric linear motor according to claim 1, wherein a height of the hollow core is larger than a maximum displacement of the piezoelectric body downward. The piezoelectric linear motor of claim 1, wherein the shaft is formed in a circular or polygonal cross section. The apparatus of claim 1, further comprising a movable body linearly moving according to the movement of the shaft by wrapping the shaft and contacting the shaft, wherein the movable body is configured such that the shaft moves linearly in response to deformation of the piezoelectric body. And when the inertia force of the movable body is greater than the frictional force between the movable body and the shaft, the piezoelectric linear motor according to the present invention slides along the shaft to be in contact with the shaft.

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