KR20110067562A - Power generating apparatus - Google Patents

Abstract

PURPOSE: A power generating device is provided to enable a user to use a tire pressure monitoring system without replacing a battery by generating electric energy from vibration energy according to the rotation of a wheel. CONSTITUTION: A panel(120) is arranged on the upper side of a main body(110) and is deformed by the transmitted energy. A link unit(130) transmits vibration energy generated by the rotation of the main body into a panel and connects the main body to the panel with a constant space. A piezoelectric device(140) is installed on a part of the panel and generates electric energy corresponding to the pressure generated in the deformed panel.

Description

Power generating device {POWER GENERATING APPARATUS}

The present invention relates to a power generator, and more particularly, to a power generator having a piezoelectric element to generate electrical energy from vibration energy generated by the rotation of the wheel.

The tire pressure monitoring system checks the pressure and condition of the tire, which is closely related to the stability of the vehicle, and prepares for a serious situation that may occur in the vehicle.

To this end, the conventional tire pressure monitoring system includes a plurality of sensors, rectifiers, and the like, and includes a power supply such as at least one battery for each driving. At this time, the power supply is one of known battery types (eg, lithium-ion battery, nickel-hydrogen battery, etc.) is used and mainly installed inside the tire.

These power supplies have a limited lifespan because of their characteristics, and therefore, they need to be replaced regularly.

In addition, the user or technician has a disadvantage in that the system (tire, rim, nipple, etc.) required for the wheels must be separated in order to replace the power supply mounted inside the tire.

In addition, since the power supply of the conventional tire pressure monitoring system is installed inside the tire, it may interfere with the rotation of the wheels and the wheel device, and may have a bad effect on the performance of the wheel alignment and the like. .

Accordingly, there is a need for a technology that makes it easy to replace or semi-permanently use the power supply of the tire pressure monitoring system.

The present invention has been made to solve the problems of the prior art as described above and the need for the development of the technology, the object of the present invention is to provide the electric power from the vibration energy according to the rotation of the wheel to permanently use the power supply of the tire pressure monitoring system It is an object to provide a power generator for generating energy.

In addition, an object of the present invention is to provide a power generating device having an effective linkage and load means of various methods to increase the strain of the panel to increase the efficiency of the pressure applied to the piezoelectric element provided to promote the efficient generation of electrical energy. There is this.

The present invention to achieve the above object; A panel disposed on an upper side of the main body and deformed by the transmitted energy; At least one link means connecting the main body to the panel and transmitting vibration energy generated when the main body rotates to the panel; And a piezoelectric element installed at a predetermined portion of the panel and generating electrical energy corresponding to the pressure generated as the panel is deformed.

In a preferred embodiment, the body is characterized in that the fixed portion attached to a portion of the rim of the wheel or a portion of the rim of the wheel.

The present invention also provides a sensor for measuring the pressure of the tire to achieve the above object; A power generator fixed to a predetermined portion of the rim of the wheel and generating power when the wheel is rotated; A rectifier for rectifying the power generated by the power generator; And a battery configured to charge the DC current rectified by the rectifier and supply the DC current to the sensor, wherein the power generator includes: a main body attached to a predetermined portion of a rim of a wheel; A panel disposed on an upper side of the main body and deformed by the transmitted energy; At least one link means connecting the main body to the panel and transmitting vibration energy generated when the main body rotates to the panel; And a piezoelectric element installed at a portion of the panel, the piezoelectric element generating electrical energy corresponding to the pressure generated as the panel is deformed.

In a preferred embodiment, the link means is connected to each other while maintaining the main body and the panel at a predetermined interval.

In a preferred embodiment, the link means has a first link means for connecting one side of the main body and one side of the panel and a second link means for connecting the other side of the main body and the other side of the panel, the first The link means includes a first link means fixed to one side of the main body and a first pin inserted to be rotatable in a hole formed on the other side of the first link means main body to connect one side of the panel. The second link means is inserted into the hole formed in one side of the second link means main body and the second link means main body is a second pin for connecting the other side of the panel and the hole formed in the other side of the second link means main body Inserted so as to be rotatable in the third pin for connecting the other side of the main body.

In a preferred embodiment, the link means comprises a first link means for connecting one side of the body and one side of the panel and a second link means for connecting the other side of the body and the other side of the panel, the first The link means includes a first link means fixed to one side of the main body and a first pin inserted to be rotatable in a hole formed on the other side of the first link means main body to connect one side of the panel. The second link means is inserted into the second link means main body fixed to the other side of the main body and the hole formed in the other side of the second link means main body is rotatable and horizontally movable second pin connecting the other side of the panel Characterized in that consists of.

In a preferred embodiment, the panel is characterized in that it comprises a load means having a certain mass on one side or both sides.

The present invention has the following excellent effects.

First, according to the power generator of the present invention, by generating the electric energy using the vibration energy according to the rotation of the wheel to supply to the sensor or transmitter constituting the tire pressure monitoring system, the tire pressure monitoring system needs to replace the battery There is an advantage that long-term use is possible without.

In addition, the power generating apparatus according to the present invention has the advantage of generating more power and supplying power to various systems by providing a link means of various forms or by attaching a plurality of power generating apparatuses to the wheels.

In addition, since the power generator of the present invention is simply mounted on one side of the rim of the wheel, if the mounting of the power generator is required or if a trouble occurs, the power generator can be easily replaced even without removing all the systems required for the wheel. It is also easy to change the installation position.

In addition, the power generator of the present invention has the effect of supplying power using not only automobiles, but also other devices (eg, bicycles, trains, airplanes, etc.) that generate vibration.

The terms used in the present invention were selected as general terms as widely used as possible, but in some cases, the terms arbitrarily selected by the applicant are included. In this case, the meanings described or used in the detailed description of the present invention are considered, rather than simply the names of the terms. The meaning should be grasped.

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

However, the present invention is not limited to the embodiments described herein but may be embodied in other forms.

1A and 1B are a front view and a perspective view of a power generator according to an embodiment of the present invention, Figure 2 is a view showing a wheel with a power generator according to an embodiment of the present invention.

1A and 1B, the power generator 100 connects the main body 110 to a panel 120 deformed by the transmitted energy, and connects the main body 110 and the panel 120. At least one link means 130 for transmitting vibration energy generated when the main body 110 rotates to the panel 120 and electrical energy corresponding to pressure generated as the panel 120 is deformed. The piezoelectric element 140 and the load means 150 which generate | occur | produce are comprised.

First, the main body 110 serves to fix the power generator 100 to a predetermined portion of the wheel, and rotates together as the wheel rotates. In this case, the main body 110 may be attached to a part of the rotating object or the rotating object. For example, the body 110 may be a part of the rim of the wheel, or may be a fixing means attached to a portion of the rim of the wheel.

The panel 120 is disposed on the upper side of the main body 110 at regular intervals and is connected by the link means 130. The panel 120 is provided with a piezoelectric element 140 in a predetermined portion, in particular, a central portion thereof, and the deformation of the panel 120 is caused by a force applied through the link means 130. As a result, the piezoelectric element 140 is changed. Apply a predetermined pressure. Deformation of the panel 120 may be made in various forms. When the panel 120 is connected by the link means 130, the deformation occurs in a bent or unfolded form.

The piezoelectric element 170 may be implemented in various ways, such as a known piezoelectric power generation method in which electrical polarization occurs on the outer surface of the crystal due to the applied pressure to generate a voltage, and corresponds to the pressure applied by the deformation of the panel 120. To generate electrical energy.

In this case, the material of the panel 120 may be one of the known elastic members having a predetermined elastic force. In one embodiment of the present invention, a steel material is used, but the present invention is not limited thereto.

The link means 130 connects and supports the main body 110 and the panel 120. When the vibration energy is generated by the rotation of the wheel, the link means 130 converts the vibration energy into the vibration energy so that the panel 120 is deformed. It serves to deliver to the panel 120.

At this time, the link means 130 is the first link means 131 for connecting one side of the main body 110 and one side of the panel 120, the other side of the main body 110 and the panel 120 It may be provided as a second link means 132 for connecting the other side.

The first link means 131 is composed of a first link means body 131-1 and a first pin 131-2. The first link means body 131-1 is fixed to one side of the main body 110, and the first pin 131-2 is a hole formed at the other side of the first link means body 131-1. Is rotatably inserted in to connect one side of the panel 120. That is, the panel 120 is installed to only rotate by the first pin 131-2.

The second link means 132 is composed of a second link means body 132-1, a second pin 132-2, and a third pin 132-3. The second pin 132-2 is inserted to be rotatable in a hole formed at one side of the second link means body 132-1 to connect the other side of the panel 120, and the third pin 132- 3) is inserted into the hole formed in the other side of the second link means main body 132-1 to be rotatable to connect the other side of the main body 110. That is, the panel 120 is installed to be rotated by the second pin 132-2 while being constrained to the main body 110 by the third pin 132-3. The second link means body 132-1 may be provided in plurality, if necessary, so that the panel 420 and the second link means body, the main body 410 and the second link means body, and the second link means body and It is also possible to design by connecting the second link means body.

As a result, the panel 120 is deformed by a link structure between the link means bodies and the first pin 131-2, the second pin 132-2, and the third pin 132-3. The middle part of the panel 120, that is, the installation part of the piezoelectric element 140 is designed to make the maximum deformation.

That is, the panel 120 is connected to the main body 110 and a predetermined interval by the link means 130, and when the main body 110 rotates to generate vibration energy, the link means 130 Vibration energy is transmitted to the panel 120 through, the panel 120 is deformed (bent or unfolded) by the vibration energy to apply pressure to the piezoelectric element 140 to generate electrical energy.

The load means 150 is installed at both ends of the panel 120 to maximize the deformation of the panel 120, it may be implemented in a variety of materials (for example, iron, steel, etc.) having a certain mass. have.

At this time, the installation position of the main body 110, the panel 120 and the link means 130 is a structure that can minimize the energy escape to the outside in the boundary condition, that is, a structure that can maximize the energy efficiency It is preferable to install. For example, energy efficiency may be maximized by placing the pins at a node point of the resonance mode among the deformed modes of the panel 120. Through this structure, the deformation of the panel 120 may be maximized, thereby maximizing the electrical energy generated by the piezoelectric element 140. In addition, a structure capable of maximizing energy efficiency, for example, electrical energy generated by adjusting the load means (m, 150) to operate at the natural frequency (f) in the relationship between the natural frequency (f) and the transmission rate Can be maximized. Detailed description will be made with reference to FIG. 5. On the other hand, the structure of the main body 110, the panel 120, the link means 130, the piezoelectric element 140 and the load means 150 is not limited to the embodiment of the present invention in various ways Of course it can.

The power generator 100 of the present invention can supply power using not only automobiles but also other devices (eg, bicycles, trains, airplanes, etc.) in which vibrations are generated.

Referring to Figure 2, the power generator 100 according to an embodiment of the present invention shows a structure attached to the rim of the wheel. The power generator 100 may be connected to and fixed to the nipple of the wheel. On the other hand, the power generator 100 may be installed so that the longitudinal direction is the same as the rotational direction of the wheel, it may be installed so that the longitudinal direction is perpendicular to the rotational direction of the wheel. That is, the power generator 100 may generate electric energy while rotating together as the wheel rotates.

3 is a block diagram of a tire pressure monitoring system including a power generator according to an embodiment of the present invention.

Referring to FIG. 3, the tire pressure monitoring system includes a power generator 100, a rectifier 20, a battery 30, a sensor 40, a transmitter 50, and the like.

The sensor 40 may use various sensors such as a pressure sensor as a sensor for measuring the pressure of the tire. The transmitter 50 serves to transmit data such as tire pressure measured from the sensor 40.

1A, 1B and 2, the power generator 100 is fixed to a predetermined portion of the rim of the wheel and generates power (electrical energy) when the wheel is rotated. In this case, the power generator 100 may be installed on one side (for example, the outer ring surface) of the rim of the vehicle, but the present invention is not necessarily limited thereto and may be attached to the other side, the inner ring, the tire, or the like. Can be.

The rectifier 20 rectifies power (electrical energy) generated by the power generator 100 into a direct current based on a known rectification method.

The battery 30 charges the DC current rectified by the rectifier 20 and supplies a DC current to the sensor 40 or the transmitter 50.

In addition, since the power generator 100 of the present invention is simply mounted on one side of the rim of the wheel, it is not necessary to change the mounting of the power generator 100 or to separate all the systems required for the wheel when a trouble occurs. It can be easily replaced even if not, and the installation location can be easily changed.

4A to 4D are perspective and front views of a power generator according to another embodiment of the present invention.

4A and 4B, the power generator 400 connects the main body 410, a panel 420 deformed by the transmitted energy, and connects the main body 410 and the panel 420. At least one link means 430 for transmitting vibration energy generated when the main body 410 rotates to the panel 420 and electrical energy corresponding to pressure generated as the panel 420 is deformed. The piezoelectric element 440 and the load means 450 which generate | occur | produce are comprised.

Power generating device 400 according to another embodiment of the present invention is different from the power generating device 100 shown in Figures 1a, 1b and 2 only the structure of the link means 430, the other components Since the same is the description of the same components will be omitted.

The link means 430 connects and supports the main body 410 and the panel 420. When the vibration energy is generated by the rotation of the wheel, the link means 430 converts the vibration energy into the vibration energy so that the panel 420 is deformed. It serves to deliver to the panel 420.

In this case, the link means 430 is the first link means 431 for connecting one side of the main body 410 and one side of the panel 420, the other side of the main body 410 and the panel 420 It may be provided as a second link means 432 for connecting the other side.

The first link means 431 is composed of a first link means body 431-1 and a first pin 431-2. The first link means body 431-1 is fixed to one side of the main body 410, and the first pin 431-2 is a hole formed at the other side of the first link means body 431-1. Is rotatably inserted in to connect one side of the panel 420. That is, the panel 420 is installed to only rotate by the first pin 431-2.

The second link means 432 is composed of a second link means body 432-1 and a second pin 432-2. The second link means body 432-1 is fixed to the other side of the body 410, and the second pin 432-2 is formed in the other side of the second link means body 432-1. Inserted to enable rotation and horizontal movement in the other side of the panel 420 is connected. That is, the panel 420 is installed to be rotated and horizontally moved by the second pin 432-2 while being constrained to the main body 210 by the second pin 432-2.

As a result, the panel 420 is deformed by the connection structure between the link means bodies and the first pin 431-2 and the second pin 432-2.

4A and 4B, when vibration energy is not applied to the panel 420, the panel 420 is not deformed and no electric energy is generated. At this time, the second pin 432-2 is located at the far end of the hole formed on the other side of the second link means main body 432-1.

Referring to FIG. 4C, it can be seen that vibration energy generated by the rotation of the main body 410 is transmitted to the panel 420 to cause deformation of the panel 420. In this case, the second pin 432-2 connected to the panel 420 rotates in the hole formed in the second link means body 432-1 and horizontally moves to the left, thereby allowing the panel 420 to be moved. It can be seen that the bending occurs in this downward direction.

Referring to FIG. 4D, vibration energy is continuously applied to the panel 420 so that the panel 420 is bent upward. At this time, the second pin 432-2 connected to the panel 420 rotates in the hole formed in the second link means main body 432-1, moves horizontally to the right, and rotates again to the left. By moving horizontally, it can be seen that the deformation of the panel 420 is bent upward.

That is, in the power generator 400 according to the embodiment of the present invention, it can be seen that the panel 420 vibrates according to the rotation period of the wheel. For example, when there is a vibration source of 10 Hz in the wheel, the vibration is applied 10 times per second in the power generator 400, the panel 420 is generated 10 times in the upper and lower direction per second The electrical energy (power source) can be obtained. In this case, assuming that the maximum voltage generated when the panel 420 is deformed in the upper direction is + V, an AC voltage of −V may be obtained when the panel 420 is deformed in the lower direction. DC current can be obtained through

5 is a graph showing a relationship between a natural frequency and a transmission rate for generating a maximum voltage. That is, it is a graph explaining the relationship between the natural frequency f and the transmission rate when the load means 450 is provided at both ends of the panel 420. The description is omitted.

Here, the transmission rate refers to the amount of vibration of the output with respect to the amount of vibration input to the power generator (400, hereinafter referred to as a system), in the power generator 400 according to an embodiment of the present invention the transmission rate If the size of is large, the generated voltage is also large.

Referring to FIG. 5, when vibration is applied at a frequency of f4 in a system (corresponding to a solid line) operating at a natural frequency f1 (transmission rate = 10), the transmission rate (= 0.2) is lowered, thus operating at a natural frequency f1. It is difficult to expect high generated voltage. This means that the generated voltage is high when the excitation vibration source, that is, the frequency of the panel 420 is input to an element close to the natural frequency. Here, if the mass of the load means 450 installed in the piezoelectric power supply unit 400 as in the embodiment of the present invention is M1, the first inherent of the panel 420 in which the piezoelectric element 440 is installed The frequency is f1, and the natural frequency of the system can be adjusted by adjusting the mass of the load means 450 small (M2) or large (M3). At this time, the relationship between the mass (M) and the natural frequency (f) of the load means 450 is shown in Figure 5, it can be expressed as follows. When the mass M of the load means 450 is M2 < M1 < M3, the natural frequency f is f3 < f1 < f2. (At this time, the natural frequency of the load means mass (M2) is f2, and the natural frequency of the load means mass (M3) is f3.)

Therefore, the power generating device 400 according to the embodiment of the present invention, when the transmission rate is the same (the damping ratio is constant), the mass of the load means 450 in consideration of the vehicle model, the driving state of the vehicle, the main road conditions, etc. The maximum voltage can be obtained by adjusting (M) to operate at natural frequency (f).

As described above, the present invention has been described with reference to preferred embodiments, but is not limited to the above-described embodiments, and various modifications may be made by those skilled in the art without departing from the gist of the present invention. Changes and corrections will be possible.

1A and 1B are front and perspective views of a power generator according to an embodiment of the present invention.

2 is a view showing a wheel with a power generator according to an embodiment of the present invention.

3 is a block diagram of a tire pressure monitoring system including a power generator according to an embodiment of the present invention.

4A to 4D are perspective and front views of a power generator according to another embodiment of the present invention.

5 is a graph showing a relationship between a natural frequency and a transmission rate for generating a maximum voltage.

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

10: wheel rim 100, 400: power generator

110, 410: main body 120, 420: panel

130, 430: link means 140, 440: piezoelectric element

150, 450: load means

Claims (8)

main body; A panel disposed on an upper side of the main body and deformed by the transmitted energy; At least one link means connecting the main body to the panel and transmitting vibration energy generated when the main body rotates to the panel; And And a piezoelectric element installed at a predetermined portion of the panel and generating electrical energy corresponding to the pressure generated as the panel is deformed. The method of claim 1, The link means is connected to each other while maintaining the main body and the panel at a predetermined interval. The method of claim 1 or 2, wherein the link means First link means for connecting one side of the main body and one side of the panel; Second link means for connecting the other side of the main body and the other side of the panel, The first link means includes a first link means fixed to one side of the main body and a first pin which is rotatably inserted in a hole formed in the other side of the first link means main body to connect one side of the panel. , The second link means is rotatably inserted in a hole formed in one side of the second link means main body and the second link means main body is formed on the other side of the second link means body and the second link connecting the other side of the panel And a third pin inserted to be rotatable in the hole and connecting the other side of the main body. The method of claim 1 or 2, wherein the link means First link means for connecting one side of the main body and one side of the panel; Second link means for connecting the other side of the main body and the other side of the panel, The first link means includes a first link means fixed to one side of the main body and a first pin which is rotatably inserted in a hole formed in the other side of the first link means main body to connect one side of the panel. , The second link means is inserted into the second link means main body fixed to the other side of the main body and the hole formed in the other side of the second link means main body is rotatable and horizontally movable second to connect the other side of the panel Power generating device characterized in that consisting of a pin. The method according to claim 1 or 2, The main body is a power generating device, characterized in that the fixed portion attached to a predetermined portion of the rim of the wheel or the wheel. The method according to claim 1 or 2, The panel is a power generating device characterized in that it comprises a load means having a certain mass on one side or both sides. A sensor for measuring the pressure of the tire; A power generator fixed to a predetermined portion of the rim of the wheel and generating power when the wheel is rotated; A rectifier for rectifying the power generated by the power generator; And And a battery for charging the DC current rectified by the rectifier and supplying the DC current to the sensor. The power generator is A body attached to a portion of the rim of the wheel; A panel disposed on an upper side of the main body and deformed by the transmitted energy; At least one link means connecting the main body to the panel and transmitting vibration energy generated when the main body rotates to the panel; And And a piezoelectric element installed at a predetermined portion of the panel, the piezoelectric element generating electric energy corresponding to the pressure generated as the panel is deformed. The method of claim 7, wherein The link means is connected to each other while maintaining the body and the panel at a predetermined interval tire pressure monitoring system.

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