KR20060078288A - Vibration generator - Google Patents

Abstract

The present invention relates to a vibration generator, a hollow case (1) of which both sides of a predetermined length is blocked, a winding portion (2) formed by winding a predetermined thickness on the inner peripheral surface of the case (1), and the winding portion (2) ) Between the separation membrane 3 formed in a thin film on the inner circumferential surface, a spring 5 installed at a predetermined length to face both sides of the case 1 and a spring 5 installed in the case 1. By providing a vibrating generator composed of permanent magnets 6, which are freely moved with a space 4, by converting energy from light vibration into electrical energy to charge the battery to increase the battery usage time and discharge in emergency situations There is a very good effect of saving the lives through emergency rescue by supplying energy to use the information equipment.

Vibration, generator, electromotive force, portable information equipment, battery

Description

Vibration generator

1 is a structural diagram showing the appearance and overall configuration of a vibration generator of the present invention.

2 is a side view of the vibration generator of the present invention.

3 is a front view of the vibration generator of the present invention.

Figure 4 shows the magnetic flux distribution of the rod-shaped permanent magnet. Permanent magnets reciprocate linearly in the cylinder, and the magnetic flux that links to the coil is changed by Faraday's law to generate induced electromotive force.

FIG. 5 (a) shows the magnetic flux chained to one coil by the reciprocating linear motion of the permanent magnet with respect to the linear position. Fig. 5 (b) shows the theoretical and actual electromotive force waveforms on the time axis by the Faraday law with the magnetic flux waveform according to the position of Fig. 5 (a).

FIG. 6 shows that the number of coils can be increased to increase the magnitude of the electromotive force, and the number of windings in the same direction is determined by the dimensions and voids of the permanent magnet.

FIG. 7A shows the electromotive force induced in each coil in the same direction as in FIG. 6. The phase difference of the electromotive force generated in a neighboring coil is determined by the diameter of the coil and the margin required for winding. Significant phase difference occurs between the electromotive force generated at the kth coil with respect to the electromotive force generated at the coil in the initial position, and the combined electromotive force is reduced by adding the electromotive forces of the coils having a phase difference of more than 180 ° to each other. Fig. 7 (b) shows the combined electromotive force obtained by connecting one bundle of coils in series.

8 illustrates a case where a plurality of coil bundles are provided on an inner surface of a cylinder, and current directions of neighboring coil bundles are opposite to each other.

FIG. 9 shows the combined electromotive force of each coil bundle under the conditions of FIG. 8. If the number of turns of the coil and the length of the coil bundle are the same, the waveform has almost the same shape. The phase difference of the combined electromotive force of each coil bundle is related to the width of the coil bundle. These coil bundles can be connected in series to achieve full electromotive force.

FIG. 10 charges energy generated from a vibration generator to a battery through a rectification or charging circuit, and the battery supplies energy to a portable information device load such as a mobile phone, a PDA, and an MP3.

* Explanation of symbols for main parts of the drawings

1: case 2: winding

3: Movement guide of separator or permanent magnet 4: Air gap

5: spring or cushion 6: permanent magnet

The present invention relates to a vibration generator, and more particularly to a vibration generator that can be used as an emergency or auxiliary charging means such as portable information equipment by converting vibration energy into electrical energy.

Modern portable information devices are gradually decreasing power consumption due to technological advances, and are decreasing the magnitude of voltage in order to increase arithmetic speed and reduce power consumption.

In addition, the demand for consumers to use the information devices for a long time with a single charge is gradually increasing, especially in the application of the computer to wear the battery size is limited, it is very difficult to meet these requirements.

In view of the above, the present inventors convert energy from natural vibrations such as vibration or walking by hand motion into electrical energy to charge the battery to increase the battery usage time, and also to discharge energy from information equipment discharged in an emergency situation. Completed the present invention by manufacturing a vibration generator that can supply.

Accordingly, an object of the present invention is to provide a vibration generator that can be used as an emergency or auxiliary charging means such as a portable information device.

The object of the present invention is a hollow case (1) with both sides of a predetermined length is closed, the winding portion (2) is formed by winding a predetermined thickness on the inner peripheral surface of the case (1), and the inner peripheral surface of the winding portion (2) A constant air gap 4 is provided between the separation membrane 3 formed of a thin film, the spring 5 installed at a predetermined length to face both sides of the case 1 and the spring 5 installed in the case 1. It was achieved by providing a vibration generator consisting of a permanent magnet (6) embedded to move freely.                         

Hereinafter, the configuration of the present invention.

The present invention relates to a vibration generator for converting vibration energy into electrical energy. Currently, no technology or product has been published to convert energy from vibration into useful electric energy. Most of the generators are in the form of a rotor, but the present invention is a linear generator form by a linear reciprocating motion. The present invention can be manufactured in one piece or separate type as an emergency or auxiliary charging means of a portable information device. The shape can be manufactured in various forms such as AA and AAA sizes of the cylindrical battery, and can be produced in various forms such as a rectangular parallelepiped.

The present invention is a hollow case (1) is blocked on both sides of a certain length,

Winding part 2 is formed by winding a predetermined thickness on the inner peripheral surface of the case (1),

Separation membrane 3 formed of a thin film on the inner peripheral surface of the winding part 2,

A spring 5 installed at a predetermined length to face both sides of the case 1 and blocked;

It provides a vibration generator consisting of a permanent magnet (6) built to move freely with a certain gap (4) between the spring (5) installed in the case (1).

In the present invention, the vibration generator is characterized in that the permanent magnet 6 generates electricity by generating an electromotive force in the winding part 2 by reciprocating in the cavity 4 by an external force.

The vibration generator of the present invention can be used in all electronic products using a battery, but more preferably can be used as a generator for portable information devices.

Hereinafter, with reference to the drawings the specific configuration and operation of the present invention will be described in detail.

1 illustrates a vibration generator manufactured in a cylindrical shape as an embodiment of the present invention. As shown in Figure 1, the vibration generator of the present invention is composed of the main accessories of permanent magnets, coils, springs. FIG. 2 is a side view of FIG. 1 and FIG. 3 shows a front view of FIG.

As can be seen in Figures 1 to 3, the vibration generator of the present invention is composed of a case (1), a winding portion (2), a separation membrane (3), a cavity (4), a spring (5) and a permanent magnet (6). .

Case (1) serves to protect the internal parts to the body of the entire vibration generator and may be made of a hard material that is not magnetized or weakly magnetized. According to the shape of the permanent magnet (6) can be made in various ways, such as cylindrical or square.

Due to the reciprocating motion of the permanent magnet 6 vibrating by an external force, an electromotive force is generated in the winding part 2 according to Faraday's law. The magnitude of this electromotive force or generated voltage is proportional to the frequency of the reciprocating motion, the number of turns of the winding, the magnetic flux density of the permanent magnet, and the reciprocating distance of the permanent magnet. When the terminal of the winding part 2 is connected to a battery or an electrical load, the kinetic energy of the reciprocating motion or vibration of the permanent magnet 6 is converted into electrical energy, thereby transmitting power. Therefore, the windings can be made of conductors such as copper, and each winding must be insulated.

Separation membrane (3) and the void (4) serves to enable the movement of the permanent magnet (6) freely by the weak external force or movement. Therefore, the separation membrane 3 must be made of a non-magnetized and smooth material. In addition, it is possible to maximize the efficiency of the separation membrane 3 and the pore 4 to be as small as possible in the range that does not interfere with the movement of the permanent magnet.

The spring 5 stores the kinetic energy of the permanent magnet 6 as spring energy when the permanent magnet reverses the direction of movement according to the reciprocating motion to smooth the change of direction, and also makes noise and permanent by collision with the side surface of the case 1. It serves to protect the magnet (6). Therefore, the material of the spring 5 is made of a material that is not magnetized. The spring coefficient is the maximum power in the external kinetic frequency band applied to the case 1 under the constraint of the distance of the permanent magnet 6 along the length of the case 1 together with the mass value of the permanent magnet 6. Select this to occur.

The permanent magnet 6 serves to supply the winding part 2 with the magnetic flux that changes with time as a mass for accumulating kinetic energy. Therefore, in order to maximize the kinetic energy, the specific gravity must be high, and in order to maximize the magnetic flux supplied to the winding part 2, the magnetic flux density is made of a material. The shape of the permanent magnet may have a variety of shapes, such as a cylindrical, square pillar shape with the case. Permanent magnets should be magnetized in the direction of the height of the cylinder or square pillar. To increase the mass of the permanent magnet, it can be composed of a combination of materials with high specific gravity, and shoes can be attached to both ends of the permanent magnet to reduce the average pore length.

Figure 4 shows the magnetization direction and the external magnetic flux distribution of the cylindrical permanent magnet. The magnetic flux distribution seen from the position of the coil with respect to the direction in which the permanent magnet moves is shown in FIG. The magnitude of the magnetic flux is determined by the magnetic flux density of the permanent magnet and the cross-sectional area of the permanent magnet. The dotted line curve of FIG. 5 (a) shows a magnetic flux distribution in consideration of non-ideal elements such as magnetic flux through the side surface of the magnet. The voltage induced by the moving permanent magnet to one coil has a triangular waveform of FIG. 5 (b) because the magnetic flux distribution is differentiated with time by Faraday's law. The magnitude of the induced voltage is determined by the magnetic flux density, the radius of the permanent magnet cross section and the vibration frequency. In addition, the period of the waveform is determined by the length and diameter of the permanent magnet and the voids. If the leakage magnetic flux or the like is taken into consideration, the induced electromotive force has a waveform of a dotted line.

In order to increase the magnitude of the electromotive force, several coils may be connected in series as shown in FIG. 6. The number of windings that can be connected is related to the diameter of the copper wire, the length and diameter of the permanent magnet and the length of the pores. The windings can also be layered to create single, two or three layers. This is referred to as a coil bundle. FIG. 7 (a) shows the electromotive force induced in each coil as a sine wave waveform. When each coil is connected in series, the synthesized electromotive force is as shown in FIG. The magnitude of the combined electromotive force is determined by the magnetic flux density of the permanent magnet, the radius and vibration frequency of the cross section, and the number of series windings. The period of the combined electromotive force is equal to the sum of the period of the electromotive force by one coil in one winding and the coil spacing wound in one direction.

8 shows a vibration generator composed of several coil bundles. In one coil bundle the currents are all in the same direction, but the neighboring coil bundles are in opposite directions. 9 shows the combined electromotive force of each coil bundle. This shows that the electromotive force of neighboring coil bundles overlap each other. Therefore, the magnitude of the electromotive force is nearly doubled and the effective voltage of one round trip cycle of the permanent magnet is considerably increased by several coil bundles. As shown in FIG. 9, when the coil bundles are connected in series, the total synthesized electromotive force is generated.

The terminal electromotive voltage of the vibration generator is an alternating voltage as shown in FIG. This voltage is charged to the battery or transferred to the load through the rectifying circuit and the charging circuit as shown in FIG.

As described above, in the present invention, the vibration generator converts energy due to light vibration into electrical energy to charge a battery to increase battery usage time and to supply energy for using a discharged information device in an emergency situation. The structure is very useful for the electrical and electronics industry because it has a very good effect of saving lives.

Claims (3)

Hollow case (1) blocked at both sides of a certain length, Winding part 2 is formed by winding a predetermined thickness on the inner peripheral surface of the case (1), Separation membrane 3 formed of a thin film on the inner peripheral surface of the winding part 2, A spring 5 installed at a predetermined length to face both sides of the case 1 and blocked; Vibration generator consisting of a permanent magnet (6) built to move freely with a certain gap (4) between the spring (5) installed in the case (1). The vibration generator as set forth in claim 1, wherein the vibration generator generates electric power by generating electromotive force in the winding part (2) by reciprocating motion in the cavity (4) by the permanent magnet (6). The vibration generator of claim 1, wherein the vibration generator is used as a generator for a portable information device.

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