KR100982643B1 - An apparatus of energy harvesting for using piezoelectric-ceramic and magnet - Google Patents

Abstract

PURPOSE: An energy harvesting device is provided to generate a voltage from a piezoelectric ceramic by using attraction force and repulsive force. CONSTITUTION: A rotary shaft(210) revolves with a ventilator(250). A support stand includes a first and a second support part. The first and the second support parts are arranged in both sides of the rotary shaft. A piezoelectric ceramics includes a first and a second piezoelectric ceramics. The first and the second piezoelectric ceramics are arranged in the first and the second support part, respectively. A housing(270) protects the rotary shaft, the support stand, the piezoelectric ceramics, and a magnet part from external force. A power source charging part(290) stores power which is generated by the vibration of the piezoelectric ceramics.

Description

An apparatus of energy harvesting for using piezoelectric-ceramic and magnet}

The present invention relates to an energy harvesting apparatus using a piezoceramic and a magnet, and more particularly, by driving a ventilator using wind power, using a attraction force and a repulsive force between a rotating disk, a magnet and a magnet of a support on which the piezoceramic is attached. The present invention relates to an energy harvesting apparatus using a piezoelectric ceramic and a magnet capable of generating energy.

Background Art Conventionally, windmills and the like have been used for wind power generation. As conventional windmills, horizontal axis windmills in which the rotation axis is disposed horizontally with respect to the wind, and vertical axis windmills in which the rotation axis is disposed vertically with respect to the wind are known.

Among these, the vertical axis windmill is attracting attention as an urban windmill for power generation because it is not influenced by the direction of the wind, and has the advantages of being excellent in staticity and matching with the urban landscape.

As the vertical axis windmill, the windmill is rotated by the drag type that rotates the windmill by the drag force generated on the blade, such as the paddle type or the savonius type, and the lift force that is generated on the blade, such as the Darius type or the gyro mill type. There is a lift type to let.

However, in the case of a vertical axis and drag type windmill, when the main speed ratio (blade blade tip speed / wind speed) is 1, there is no moment more than the rotation of the windmill. Since the rotation speed cannot be obtained, there is a problem that the power generation efficiency is low at high wind speeds. In the case of the vertical lift type, the aerodynamic characteristics are good and the power generation efficiency is improved under a circumferential speed ratio of more than 1, but the aerodynamic characteristics of the windmill are poor at a circumferential speed ratio of 1 or less, and the rotation moment for rotating the windmill is reduced. Since the power generation efficiency is not only low, but the aerodynamic characteristics under the weak wind are poor, a separate power is required for starting in the stationary state, which causes a problem in power efficiency.

On the other hand, Japanese Patent Publication No. Hei 3-10037 (hereinafter referred to as Patent Document 1) connects the shaft of an impeller to a ring gear, and has a concentric shape and an axial center of the impeller through a plurality of planetary gears in contact with the ring gear. Disclosed is a wind power generator in which a sun gear disposed is rotated and a shaft of the sun gear is connected to a generator. These ring gears, planetary gears, and sun gears constitute a planetary gear reducer, and the rotation of the vanes connected to the ring gear increases in speed at the reducer and is transmitted to the generator. Accordingly, the generator can be operated efficiently even when the wind power is weak and the number of revolutions of the van is small. In addition, Japanese Patent Application Laid-Open No. 2001-132617 (hereinafter referred to as Patent Document 2) has a shaft of a vane and an upper vane of vanes which are fitted into and coupled outwardly concentrically with the rotary shaft, and the windshields of these vanes are mutually Disclosed are wind turbine generators in opposite directions. It can develop efficiently because either vane up or down wind receives strong wind in any direction. It is also disclosed to float the vanes due to the repulsive force of the magnet and to rotate them with low friction. However, this conventional technology also has a problem in that the efficiency is less efficient in terms of power use.

Accordingly, in the technical field, there is a demand for technology development to provide a harvesting device capable of generating additional energy using magnetic flux as well as wind power.

Technical problem of the present invention devised to improve the above problems is to drive a ventilator using wind power, the piezoceramic and magnets for utilizing the attraction force, repulsive force between the rotating disk, the magnet and the support of the piezoceramic attached support It is to provide an energy harvesting apparatus used.

According to an embodiment of the present invention, an object of the present invention is to provide an energy harvesting apparatus using a piezoelectric ceramic and a magnet for storing an energy source generated by inducing bending of the piezoelectric ceramic to generate a voltage from the piezoelectric ceramic.

According to an embodiment of the present invention, an object of the present invention is to provide an energy harvesting apparatus using a piezoceramic and a magnet for using an energy source generated by generating a voltage from the piezoceramic by inducing the bending of the piezoceramic as an independent power source. .

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

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According to a feature of the present invention in order to achieve the above object, it comprises a rotating shaft, a support, a piezoceramic, a magnet portion, a ventilator, a housing, a power charging portion, wherein the magnet portion comprises a magnet of S pole and N pole In the wind power generator using a piezoelectric ceramic and a magnet comprising a first magnet portion, a second magnet portion including the magnets of the S and N poles, and a third magnet portion including the magnets of the N and S poles. Is formed orthogonal to the rotating shaft to perform a rotary motion together in accordance with the rotation of the ventilator; It is formed as a first support, a second support, each of which is formed to be spaced apart in parallel to each other around the rotation axis, both ends of the first support and the second support is formed in a form coupled to the top and bottom of the housing The support; A first piezoelectric ceramic formed on the first support, and a second piezoelectric ceramic formed on the second support, wherein the first piezoelectric ceramic and the second piezoelectric ceramic are magnets facing each other. Bending of the first support and the second support, which are flexible by the attractive force between the magnet of the magnet of the S pole of the second magnet part and between the magnet of the N pole of the second magnet part and the magnet of the N pole of the third magnet part The piezoceramic for generating a power output by vibrations transmitted due to generation; The ventilator for starting the rotational movement when the wind blows around to transfer the rotational force to the rotational axis located on the extension line of its central axis; A housing having a hollow inside and having an upper surface opened, the housing having a larger diameter than the ventilator, the housing configured to protect the rotating shaft, the support, the piezoceramic, and the magnet part from an external force; A power charging unit formed in a form in which both ends of the first and second piezoelectric ceramics are connected, and receiving and storing power generated by the bending of the first piezoelectric ceramic and the second piezoelectric ceramic; It provides an energy harvesting device using a piezoelectric ceramic and a magnet comprising a.

At this time, according to an additional feature of the present invention, the first magnet portion, the magnet of its S pole and the N pole magnet is formed symmetrically about the first support, the magnet of the S pole of the second magnet portion It is formed of a magnet of its own north pole which is formed in a spaced apart shape facing each other, and the magnet of its own S pole formed on the opposite side, the second magnet portion, The magnet is formed symmetrically about the rotation axis, the magnet of its own S pole which is formed in a form spaced apart from the magnet of the N pole of the first magnet portion, and the N pole of the third magnet portion formed on the opposite side It is formed of a magnet of its own north pole which is formed facing away from the magnet of the third magnet portion, the magnet of its own north pole and the magnet of its own S pole so that the symmetry around the second support Of the N pole of the second magnet portion Seats are formed in the form of their being in a face looking away form the N-pole magnet and, the other side may be formed by a magnet of their S-poles.

In addition, according to an additional feature of the present invention, as the ventilator is driven, the bending occurs in the support by the attraction force and repulsive force of the magnet portion, the vibration is transmitted to the piezoelectric ceramic, thereby causing the And a storage unit for collecting the voltage induced by the piezoelectric characteristics in the dust collector and storing the voltage collected by the dust collector for use in other power sources.

The energy harvesting apparatus using the piezoelectric ceramic and the magnet according to the present invention drives the ventilator using wind power, thereby providing an effect of using the attraction force and repulsive force between the rotating disk, the magnet and the magnet of the support on which the piezoelectric ceramic is attached.

In addition, the present invention provides the effect of inducing the bending of the piezoceramic to generate a voltage from the piezoceramic to store the generated energy source.

In addition, according to the present invention, the bending of the piezoelectric ceramic is induced to generate a voltage from the piezoelectric ceramic, thereby providing an effect of using the generated energy source as an independent power source.

Hereinafter, a detailed description of a preferred embodiment of the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted when it is deemed that they may unnecessarily obscure the subject matter of the present invention.

In the present specification, when one component 'transmits' data or a signal to another component, any one component may directly transmit data or a signal to another component, and at least one other component. This means that data or a signal can be transmitted to other components through the APC.

1 is a view showing a wind turbine 100 using a piezoelectric ceramic and a magnet according to an embodiment of the present invention. Referring to FIG. 1, a wind power generator 100 using a piezoelectric ceramic and a magnet includes a rotating shaft 110, a support 120, a piezoelectric ceramic 130, a magnet 140, a ventilator 150, and a housing 170. ), The power charging unit 190 may be included.

The rotation shaft 110 is formed orthogonal to the center of the cylindrical ventilator 150 to perform a rotational movement together with the rotation of the ventilator 150.

The support 120 is formed of a first support 120a, a second support 120b, each of which is spaced apart from each other in parallel to the rotation axis 110. One end of the first support member 120a and the second support member 120b may be coupled to the upper end of the housing 170 to be fastened.

The piezoelectric ceramic 130 includes a first piezoelectric ceramic 130a formed on the first support 120a and a second piezoelectric ceramic 130b formed on the second support 120b.

The first piezoelectric ceramics 130a and the second piezoelectric ceramics 130b are the repulsive force between the magnets of the north pole of the first magnet part 143 and the magnets of the north pole of the second magnet part 145, which are opposite magnets. Vibration transmitted due to bending of the flexible first supporter 120a and the second supporter 120b by the repulsive force between the magnet of the S pole of the magnet portion 145 and the magnet of the S pole of the third magnet portion 147. The voltage is generated by the. Voltages generated from the first and second piezoelectric ceramics 130a and 130b are transmitted to respective terminals of the power charging unit 190.

The magnet part 140 may include a first magnet part 143, a second magnet part 145, and a third magnet part 147.

The first magnet part 143 is formed so that the magnet of the S pole and the magnet of the N pole are symmetric about the first support base 120a, and the magnet of the N pole of the first magnet part 143 is the second magnet. The first magnet part 143 is configured to be spaced apart to face the magnet of the N pole of the part 145 and the magnet of the S pole of the first magnet part 143 is symmetric about the first support member 120a. The magnet of the north pole is composed on the opposite side.

The second magnet part 145 is formed such that the magnet of the N pole and the magnet of the S pole are symmetric about the rotation axis 110, and the magnet of the N pole of the second magnet part 145 is the first magnet part. The magnets of the S pole of the second magnet part 145 are spaced apart from each other while facing the magnets of the N pole of 143. The N of the second magnet part 145 is symmetric about the rotation axis 110. It is configured on the opposite side of the pole, the magnet of the S pole of the second magnet portion 145 is formed spaced apart facing the magnet of the S pole of the third magnet portion 147.

The third magnet part 147 is formed such that the magnet of the S pole and the magnet of the N pole are symmetric about the second support 120b, and the magnet of the S pole of the third magnet part 147 is the second magnet. The magnet of the north pole of the third magnet portion 147 is formed so as to face the magnet of the S pole of the portion 145, the third magnet portion 147 to be symmetrical about the second support (120b). Magnet on the opposite side of the pole.

The ventilator 150 starts the rotational movement when the wind blows around, and transmits the rotational force to the rotational shaft 110 located on the extension line of its central axis.

The housing 170 may be formed as a hollow cylinder, and may have a larger diameter than the ventilator 150. The housing 170 includes a rotation shaft 110 positioned at the center thereof, and includes a first support 120a, a second support 120b, a piezoelectric ceramic 130, and a magnet 140 about the rotation shaft 110. Is located to protect internal components from external forces.

The power charging unit 190 receives and stores power generated by the vibration force of the first piezoelectric ceramic 130a and the second piezoelectric ceramic 130b, and may be formed as a capacitor.

2 is a diagram illustrating an energy harvesting apparatus 200 using a piezoelectric ceramic and a magnet according to another embodiment of the present invention. 1 and 2, the energy harvesting apparatus 200 using piezoelectric ceramics and magnets includes a rotating shaft 210, a supporter 220, a piezoelectric ceramic 230, a magnet part 240, and a ventilator 250. The housing 270 may include a power charging unit 290.

The rotating shaft 210 is formed to be orthogonal to the center of the cylindrical ventilator 250 to perform a rotational movement together with the rotation of the ventilator 250.

The support 220 is formed of a first support (220a), a second support (220b), each is formed spaced apart in parallel to both sides about the rotation axis (210).

Unlike the first support 220a and the second support 220b, FIG. 1, both ends of the first support 220a and the second support 220b are coupled to the lower end as well as the upper end of the housing 270. It is formed in the form of. By forming such a structure, the pressure on the first and second piezoelectric ceramics 230a and 230b can be increased by eliminating warpage of the first and second supports 220a and 220b.

In addition, there is a possibility that the first and second support members 220a and 220b may be attached to each other by the pulling force between the magnets 240 due to the bending phenomenon, thereby preventing them, and preventing the center and both supports 220a and the rotation shaft 210. 220b) is formed in such an improved form to receive the maximum force by centering between the magnets.

The piezoelectric ceramic 230 includes a first piezoelectric ceramic 230a formed on the first support 220a and a second piezoelectric ceramic 230b formed on the second support 220b.

The first piezoelectric ceramic 230a and the second piezoelectric ceramic 230b are repulsive forces between the magnets of the N pole of the first magnet part 241 and the magnets of the N pole of the second magnet part 243, which are opposite magnets. Due to the repulsion between the magnet of the S pole of the second magnet portion 243 and the magnet of the S pole of the third magnet portion 245, the flexible first support 220a and the second support 220b are transmitted due to the occurrence of bending. Voltage is generated by vibration. Voltages generated from the first and second piezoelectric ceramics 230a and 230b are transmitted to respective terminals of the power charger 290.

The magnet part 240 may include a first magnet part 241, a second magnet part 243, and a third magnet part 245.

The first magnet part 241 is formed so that the magnet of the S pole and the magnet of the N pole are symmetric about the first support base 220a, and the magnet of the N pole of the first magnet part 241 is the second magnet. The magnets of the S pole of the first magnet part 241 are spaced apart to face the magnets of the N pole of the part 243, and the magnets of the S pole of the first magnet part 241 are symmetric about the first support part 220a. Magnets of the north pole of the

The second magnet part 243 is formed such that the magnet of the N pole and the magnet of the S pole are symmetric about the rotation axis 210, and the magnet of the N pole of the second magnet part 243 is the first magnet part. And the magnets of the S pole of the second magnet part 243 are symmetric about the rotational axis 210 so as to be symmetric about the N pole of the 241. The magnets of the S poles of the second magnet part 243 are spaced apart from each other to face the magnets of the S poles of the third magnet part 245.

The third magnet part 245 is formed so that the magnet of the S pole and the magnet of the N pole are symmetric about the second support 220b, and the magnet of the S pole of the third magnet part 245 is the second magnet. The second magnet portion 245 is configured to be spaced apart to face the magnet of the S pole of the portion 243, and the magnet of the N pole of the third magnet portion 245 is symmetric about the second support 220b. Magnet on the opposite side of the pole.

The ventilator 250 starts the rotational movement when the wind blows around, and transmits the rotational force to the rotational shaft 10 located on the extension line of its central axis.

The housing 270 is hollow and is formed in a cylinder having an upper surface opened, and may have a larger diameter than the venturi 250. The housing 270 includes a rotation shaft 210 positioned at the center thereof, and includes a first support 220a, a second support 220b, and first and second piezoelectric ceramics 230a around the rotation shaft 210. , 230b) and the magnet part 240 are located inside to protect the internal components from external forces.

The power charging unit 290 is formed in a form in which both ends are connected to the first and second piezoelectric ceramics (230a and 230b), through the power generated from the bending of the first and second support (230a, 230b), The power generated from the first piezoelectric ceramic 230a and the second piezoelectric ceramic 230b is received and stored, and may be formed of a capacitor.

As described above, by driving the ventilator (150, 250) using the principle of wind power, piezoceramic and magnet, by using the attraction force, repulsive force between the rotating shaft (110, 210) and the magnet and the magnet of the support, The bending is induced to generate a voltage from the piezoceramic so that the generated energy source can be stored or used as an independent power source.

When the ventilators 150 and 250 are driven according to the wind power according to the configuration shown in FIGS. 1 and 2, the piezoelectric ceramics 130 and 230 vibrate through bending of the supports 120 and 220 according to the attraction force and repulsive force of the magnet. The piezoelectric ceramics 130 and 230 are bent at the same time to generate power.

At this time, the voltage waveform induced in the piezoelectric ceramics 130 and 230 by the positive effect of the piezoelectric ceramics 130 and 230 according to the vibration is displayed as shown in FIG. 4 and the waveform of the induced voltage in response to the applied current is variable. It is created and modified.

On the other hand, when a voltage is generated according to the operation of the piezoelectric ceramic (130,230), the voltage generated by the transmission through the wire or cable connected to the piezoelectric ceramic (130,230), dust collection connected to the end of the wire or cable Collected on the device 400.

The voltage collected through the dust collector 400 may be collected as one place through the storage unit 500 and used as an extra power source.

4 is a graph showing the output characteristics of the energy harvesting apparatus (100, 200) using a piezoelectric ceramic and a magnet according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating a rectifier circuit configuration used in the energy harvesting apparatuses 100 and 200 using piezoelectric ceramics and magnets according to an exemplary embodiment of the present invention. FIG. 5 is a reference view, and the operation of the LED may be confirmed using the rectifier circuit designed as described above.

On the other hand, the housing (170, 270) used in the energy harvesting device (100, 200) using the piezoelectric ceramic and magnet of the present invention can be used as an aluminum material, the material is a material that does not conduct electricity to those skilled in the art It can be applied variably according to.

Although the contents of the present invention have been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art may realize various modifications and other equivalent embodiments therefrom. I will understand. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

By using the piezoceramic and magnet energy harvesting apparatus of the present invention, the bending of the piezoceramic is induced by using the attractive force and the repulsive force between the rotating disk, the magnet and the magnet of the support with the piezoceramic to generate a voltage from the piezoceramic. It can be used as an independent power source such as street lights on the road by using the generated energy source to store or use as an independent power source.

BRIEF DESCRIPTION OF THE DRAWINGS In order to better understand the drawings cited in the detailed description of the invention, a brief description of each drawing is provided.

1 is a view showing an energy harvesting apparatus using a piezoelectric ceramic and a magnet according to an embodiment of the present invention.

2 is a view showing an energy harvesting apparatus using a piezoelectric ceramic and a magnet according to another embodiment of the present invention.

3 is a configuration diagram for power collection of the induced voltage of the piezoelectric ceramic according to the operation of the ventilator, the magnet and the piezoelectric ceramic according to FIGS.

4 is a graph showing the output characteristics of the wind power generator using a piezoelectric ceramic and a magnet according to an embodiment of the present invention.

5 is a view showing the configuration of the rectifier circuit used in the energy harvesting apparatus using a piezoelectric ceramic and a magnet according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

110: axis of rotation 120: support

130: piezoelectric ceramic 140: magnet portion

150: ventilator 170: housing

190: power charging unit

210: rotating shaft 220: support

230: piezoelectric ceramic 240: magnet portion

250: ventilator 270: housing

290: power charging unit

Claims (5)

delete delete The rotating shaft 210, the support 220, the piezoelectric ceramic 230, the magnet portion 240, the ventilator 250, the housing 270, the power charging unit 290, the magnet portion 240 is S A first magnet part 241 including magnets of the pole and the N pole, a second magnet part 243 including the magnets of the S pole and the N pole, and a third magnet part including magnets of the N pole and the S pole ( In the energy harvesting apparatus using a piezoelectric ceramic and a magnet comprising: A rotation shaft 210 which is formed to be orthogonal to the ventilator 250 and performs rotational movement together with the rotation of the ventilator 250; It is composed of a first support (220a), a second support (220b), each of which is spaced apart in parallel to both sides of the rotation shaft 210, the first support (220a) and the second support (220b) Both ends of the support 220 is formed in the form coupled to the top and bottom of the housing 270; And a first piezoelectric ceramic 230a formed on the first support 220a and a second piezoelectric ceramic 230b formed on the second support 220b, wherein the first piezoelectric ceramic 230a and the first support 220a are formed. The second piezoelectric ceramic 230b is a repulsive force between the magnet of the north pole of the first magnet part 241, which is the magnet facing each other, and the magnet of the north pole of the second magnet part 243, and the second magnet part 243 of the second magnet part 243. Power source by the vibration transmitted due to the bending of the first support 220a and the second support 220b that are flexible by the repulsive force between the magnet of the S pole and the magnet of the S pole of the third magnet portion 245. The piezoceramic 230 for generating an output; The ventilator 250 for starting the rotational movement when the wind blows around to transfer the rotational force to the rotational axis 210 located on the extension line of its central axis; Hollow and the upper surface is formed into a cylinder, the diameter is larger than the ventilator 250, the rotating shaft 210, the support 220, the piezoelectric ceramic 230 and the magnet portion 240 therein The housing 270 to protect the from external force; Both ends of the first and second piezoelectric ceramics 230a and 230b are formed to be connected to each other, and the power generated by the vibration force generated by the first piezoelectric ceramics 230a and the second piezoelectric ceramics 230b is received. The power charging unit 290 for storing; Energy harvesting device using a piezoceramic and magnet, characterized in that it comprises a The method of claim 3, wherein The first magnet portion 241, the magnet of its own pole and the N pole magnet is formed symmetrically about the first support (220a), the magnet of the N pole of the first magnet portion 241 is The magnets are spaced apart from each other to face the magnets of the N pole of the second magnet part 243, and the magnets of the S pole of the first magnet part 241 are symmetric about the first support 220a. Is formed on the opposite side of the magnet of the north pole of the portion 241, The second magnet part 243 is formed such that its magnet of the north pole and the magnet of the south pole are symmetric about the rotation axis 210, and the magnet of the north pole of the second magnet part 243 is made of the first magnet. The second magnet part 243 is configured to be spaced apart from each other to face the magnet of the N pole of the first magnet part 241, and the magnet of the S pole of the second magnet part 243 is symmetric about the rotation axis 210. And the magnet of the S pole of the second magnet part 243 are spaced apart to face the magnet of the S pole of the third magnet part 245. The third magnet portion 245, the magnet of its own S pole and the magnet of the N pole is formed symmetrically about the second support 220b, the magnet of the S pole of the third magnet portion 245 is The magnets are spaced apart from each other to face the magnets of the S poles of the second magnet part 243, and the magnets of the N poles of the third magnet part 245 are symmetric about the second support 220b. Energy harvesting apparatus using a piezoelectric ceramic and a magnet, characterized in that formed on the opposite side of the magnet of the S pole of the portion (245). delete

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