KR20100124400A - Generator using vibration - Google Patents

Abstract

PURPOSE: The oscillation generator multiplies the generated energy by each other organically uniting the development method by the development method by the piezoelectric effect and electromagnetic induction. CONSTITUTION: The piezoelectric element part is vibrated by the outside excitation circle in order to induce the electricity. The oscillating element(40) is into one body vibrated with the piezoelectric element part in order to occur the electromagnetic induction. The fixing member(50) occurs the electromagnetic induction with interaction with the oscillating element.

Description

Vibration Generator {GENERATOR USING VIBRATION}

The present invention relates to a generator, and more particularly to a vibration generator for inducing power based on vibration.

In general, a generator is a device that converts external force, which is mechanical energy, into electrical energy, and is used in various fields.

In particular, as generators face the seriousness of energy crisis and environmental pollution due to exhaustion of fossil fuels, the development of technology in various countries around the world to produce electric power using external energy such as wind energy, tidal power, solar power, noise, vibration, etc. It is becoming.

In recent years, the use of wireless mobile devices such as mobile phones and laptops has rapidly increased, and in order to supply electric power to street lamps and traffic sensors wirelessly for visual images and safety, self-powered devices that obtain electric energy using an external environment ( Energy scanvengers are being developed and applied.

The double vibration can be continuously generated by various factors such as driving of the vehicle, rapid braking of the vehicle, rapid acceleration, people walking, machine operation, and noise. It has the advantage that it can be easily used without being influenced by time and seasonal factors such as light and noise, weather conditions and terrain that are difficult to artificially adjust.

Therefore, a lot of research and development on the vibration generator is progressing, and in particular, unlike the wind, tidal, solar power generation, technology development as a small-capacity generator such as wireless portable devices, street lights, road sensors is required.

The present invention has been made to solve the above problems, and the object of the present invention is to provide a vibrating generator which is advantageous in terms of cost, such as miniaturization, manufacturing / maintenance, while generating a very high power generation.

In order to solve the above problems, the present invention is a piezoelectric element unit vibrating by an external vibration source to induce power; A vibration member vibrating integrally with the piezoelectric element portion and provided to generate electromagnetic induction; It proposes a vibration generator comprising a; fixing member provided to generate electromagnetic induction by interaction with the vibration member.

The piezoelectric element unit may include a cantilever formed of a piezoelectric element, one side of which is fixed to a base for transmitting the external vibration source, and the vibration member installed on the other side.

The cantilever may have a shape in which a portion opposite to the other side on which the vibrating member is installed is relatively bent with respect to one side fixed to the base.

The vibration member may be provided with a permanent magnet or an electromagnet, and the fixing member may be provided with an induction coil in which a magnetic field is changed by relative movement of the vibration member.

The vibration member may further include a support block coupled to the piezoelectric element part and supporting the permanent magnet or the electromagnet.

The support block is coupled to each other around the piezoelectric element portion, a pair of block members having a seating groove in which the permanent magnet or the electromagnet is seated on a surface facing the fixing member; It may include; at least one clamp member for binding the pair of block members.

According to the present invention, the power generation method by the piezoelectric effect and the power generation method by the electromagnetic induction are organically combined with each other, and thus the power generation amount is significantly increased, and thus, it can be more advantageous in terms of miniaturization and cost.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figure 1, the vibration generator according to the present invention, the piezoelectric element portion 30 to be vibrated by an external vibration source (arrow F) to induce power; A vibrating member 40 integrally with the piezoelectric element portion 30 (arrow V) and provided to generate electromagnetic induction; It may be configured to include a fixing member 50 provided to generate the electromagnetic induction by interaction with the vibration member 40.

That is, when an external vibration source (arrow F) is transmitted to the piezoelectric element portion 30, a stress (stree) is generated by the vibration (arrow V) in the piezoelectric element portion 30, whereby electric power is induced by the piezoelectric effect. Can be.

In addition, as the vibrating member 40 vibrates (arrow V) together with the piezoelectric element part 30, the vibrating member 40 moves relative to the fixing member 50, thereby causing electric power due to electromagnetic induction. This can be induced.

Therefore, as the energy conversion technology based on vibration (arrow V), the two generations of power generation (E1) by the piezoelectric effect and the power generation (E2) by the electromagnetic induction are simultaneously performed, thereby significantly increasing the generation amount. Can be obtained.

In particular, the piezoelectric element portion 30 induces electric power by the piezoelectric effect, and also serves as an external vibration source (arrow F) for electromagnetic induction. The vibration member 40 also interacts with the fixing member 50 for electromagnetic induction, and serves as a mass weight for smooth and sufficient vibration (arrow V) of the piezoelectric element part 30.

Therefore, in the present invention, the power generation method by the piezoelectric effect and the power generation method by electromagnetic induction are not related to each other and are not simply combined together, but are organically combined with each other structurally as well as in operation and operation. More advantageous in terms of manufacturing, maintenance and repair can be obtained.

Hereinafter, each structure is demonstrated in detail.

The piezoelectric element part 30 may have any structure as long as it includes a piezoelectric element made of a material having a piezoelectric effect, but takes a cantilever structure so as to sufficiently respond to fine vibration (arrow V) to draw the maximum power induction. It may be more preferable.

That is, the piezoelectric element part 30 is formed of a piezoelectric element that is a piezofiber, and one side is fixed to the base 10 for transmitting an external vibration source (arrow F), and the vibration member 40 is installed on the other side. It can be composed of a cantilever 32 (contilever).

Therefore, when the external dust source (arrow F) is transmitted to the cantilever 32 through the base 10, the cantilever 32 itself is vibrated (arrow V) and stress is generated in the cantilever 32, and by this stress Power can be derived.

The cantilever 32 may take various structures. However, as the stress generated in the cantilever 32 increases, power induction may be maximized by the piezoelectric effect. Therefore, the cantilever 32 may be more preferably designed and manufactured so as to have a parameter capable of matching an external vibration source (arrow F) with a resonance frequency, that is, a material, a shape, a dimension, a spring constant, and the like.

Here, as shown, the cantilever 32 may have a shape in which the other end 32A of the other side having the vibrating member 40 installed relative to one side fixed to the base 10 is relatively bent. Accordingly, the cantilever 32 can be more reliably prevented from the piezoelectric element binding block 20 described later, the cantilever 32 can be vibrated more stably (arrow V), and the cantilever 32 can be prevented. Can take advantage of the vibration (arrow V) in response to the external source (arrow F) more fully.

On the other hand, the base 10 may take any structure as long as it can transmit an external vibration source (arrow F) and support the piezoelectric element unit 30.

However, when the piezoelectric element portion 30 and the base 10 interfere with the vibration (arrow V) of the piezoelectric element portion 30, the vibration (arrow V) of the piezoelectric element portion 30 is disturbed and smooth power generation is achieved. Bar cannot be made, the piezoelectric element binding block 20 for supporting the piezoelectric element portion 30 in a sufficiently spaced state from the base 10 can be fixed on the base (10).

The piezoelectric element binding block 20 is fixed to the base 10 by a fastening member 12 such as a screw, and any structure may be adopted as long as it can firmly bind one side of the piezoelectric element portion 30.

As shown in a preferred example, the piezoelectric element binding block 20 is fixed on the base 10 and has a lower member 22 having a predetermined height so that the piezoelectric element portion 30 can be sufficiently spaced apart from the base 10. ), The upper member 24 coupled to the lower member 22 around the piezoelectric element portion 30, the upper member 24 and the lower member 22, and the piezoelectric element portion 30 may be bound. It may be configured to include a fastening member 26, such as a screw fastened to the upper member 24 and the lower member 22. At this time, at least one of the upper member 24 and the lower member 22, the piezoelectric element portion mounting groove (2) in which the piezoelectric element portion 30 may be seated for easy and firm binding of the piezoelectric element portion 30 ( 22A) can be formed.

If the piezoelectric element portion 30 can be sufficiently bound to the piezoelectric element binding block 20 only by being interposed between the upper member 24 and the lower member 22, the fastening member 26 is connected with the upper member 24. Only the lower member 22 can be fastened. Alternatively, the fastening member 26 may be fastened through the piezoelectric element part 30 as necessary so that the piezoelectric element part 30 is more firmly bound by the fastening member 26.

Next, for electromagnetic induction, the magnet moves around the induction coil 52 or the induction coil 52 moves around the magnet, thereby disturbing the magnetic field M formed by the induction coil 52. Therefore, the vibration member 40 may be any one of the magnet and the induction coil 52. However, the vibration member 40 may be more preferably provided with a magnet for the following reasons.

That is, as described above, the mass of the vibrating member 40 serving as the mass weight is also an external vibration source (arrow F) and as one of important parameters for matching the resonance frequency of the cantilever 32, the cantilever 32 has an external vibration. The vibration member 40 preferably has a weight in order to sufficiently react to vibration (arrow V) of the circle (arrow F).

Therefore, the vibrating member 40 is more preferably provided with a magnet having a certain weight only by the magnet and the induction coil 52 itself.

In particular, the vibrating member 40 may be more preferably provided as a permanent magnet 42 that does not require an external power source than an electromagnet in terms of efficiency, ease of maintenance, repair and the like.

Furthermore, the vibration member 40 may be composed of only the permanent magnet 42, but may further include a support block 44 coupled to the piezoelectric element part 30 and supporting the permanent magnet 42 as follows. have.

That is, by the support block 44, the vibration member 40 can be more easily coupled to the cantilever 32, the structure of the permanent magnet 42, as well as the permanent magnet 42 for the cantilever 32 The installation position of the can be designed more freely. In addition, the support block 44 can ensure a sufficient mass for the vibration member 40 to act as a mass weight of the piezoelectric element portion 30, it is possible to reduce the size of the permanent magnet 42, accordingly In terms of cost, the application of the expensive permanent magnet 42 is not burdensome.

The support block 44 may have various structures according to the structure of the peripheral element such as the cantilever 32 and the permanent magnet 42.

As a preferred example, as long as the support block 44 is coupled to each other around the piezoelectric element part 30 and a seating groove 44B in which the permanent magnet 42 is seated on a surface facing the fixing member 50 is formed. A pair of block members 44A; It may be configured to include at least one clamp member (44C) for binding the pair of block members (44A).

Therefore, the support block 44 can be easily coupled with the piezoelectric element portion 30 and the permanent magnet 42, it can be made easy to manufacture, maintenance, repair.

Here, the pair of block members 44A and the clamp members 44C may be bound to each other by various methods, and as a preferred example, may be bound to each other by fastening members 44D, such as screws or bolts, as shown. Can be.

As described above, the fixing member 50 may be any one of the magnet and the induction coil 52, and may be fixed without vibration (arrow V) by an external source (arrow F), thereby stably inducing electric power. As such, it may be more preferable that the induction coil 52 changes in the magnetic field M by the relative movement of the vibration member 40.

Induction coil 52 may be composed of only a coil, it may be implemented in a variety of ways, such as to take the structure wound coil in a bobbin or the like.

Furthermore, the fixing member 50 may further include a fixing block 54 fixed on the base 10 by a fastening member 14 such as a screw on the base 10 to stably support the induction coil 52.

Here, as shown in the fixing member 50 is composed of one on each of the left and right sides of the vibration member 40, the permanent magnet 42 of the vibration member 40 also supports the support block corresponding to the fixing member 50 One of the left and right sides of 44 may be configured.

Alternatively, although not shown, the fixing member 50 is configured above and below the vibration member 40, and correspondingly, the permanent magnets 42 of the vibration member 40 are also provided on the upper and lower surfaces of the support block 44, respectively. Can be configured.

Alternatively, although not shown, the fixing member 50 may have a cylindrical structure surrounding the vibration member 40.

In addition, the number and relative positions, structures, etc. of the vibration member 40 and the fixing member 50 may be variously modified and implemented as necessary.

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1 is a schematic view of the operation of the vibration generator according to the present invention.

2 is a perspective view of a vibration generator according to the present invention.

3 is an exploded perspective view of the vibration generator according to the present invention.

4 is a cross-sectional view taken along the line A-A of FIG.

Figure 5 is a view corresponding to Figure 4, a schematic diagram of the operation of the vibration generator according to the present invention.

6 is a cross-sectional view taken along the line B-B in FIG.

Figure 7 is a view corresponding to Figure 6, a schematic diagram of the operation of the vibration generator according to the present invention.

<Explanation of symbols on main parts of the drawings>

10; Base 20; Piezoelectric element binding block

30; Piezoelectric element section 32; Cantilever

40; Vibration member 42; Permanent magnet

44; Support block 50; Fixing member

52; Induction coil 54; Fixed block

Claims (6)

A piezoelectric element unit vibrating by an external vibration source to induce electric power; A vibration member vibrating integrally with the piezoelectric element portion and provided to generate electromagnetic induction; A fixing member provided to generate electromagnetic induction by interaction with the vibration member; Vibration generator comprising a. The method according to claim 1, The piezoelectric element portion is formed of a piezoelectric element, one side is fixed to the base for transmitting the external vibration source, and the other side vibration generator comprising a cantilever in which the vibration member is installed. The method according to claim 2, The cantilever is a vibration generator, characterized in that the other end of the other side is installed in a relatively bent shape around the one side is fixed to the base. The method according to any one of claims 1 to 3, The vibration member is provided with a permanent magnet or an electromagnet, The fixing member is a vibration generator characterized in that the induction coil is provided with a magnetic field is changed by the relative movement of the vibration member. The method according to claim 4, The vibration member is coupled to the piezoelectric element portion, characterized in that it further comprises a support block for supporting the permanent magnet or the electromagnet. The method according to claim 5, The support block is coupled to each other around the piezoelectric element portion, a pair of block members having a seating groove in which the permanent magnet or the electromagnet is seated on a surface facing the fixing member; At least one clamp member for engaging the pair of block members; Vibration generator comprising a.

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