KR20060084972A - New vibration generator - Google Patents

Abstract

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. The vibration generator is a hollow type in which both sides of a certain length are blocked. A freely movable move having a predetermined gap between the case, a winding part formed by winding a predetermined thickness on the inner circumferential surface of the case, a spring installed at a predetermined length on both sides of the case, and a spring installed in the case; The present invention comprises a permanent magnet and a movement guide shaft penetrating a center of the movable permanent magnet and having a fixed length spring at both ends thereof. The present invention provides a vibration generator to convert energy from light vibration into electrical energy and charge the battery to use the battery. Long-term outdoor activities, long-distance business trip And in the event of distress and similar emergencies in fishing and hiking, there is an excellent effect of using the battery to charge using the power generation function provided in the self.

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

Description

New vibration generator             

1 is a cross-sectional view provided with a spring inside the vibration generator according to a preferred embodiment of the present invention,

2 is a cross-sectional view provided with a permanent magnet in the vibration generator according to an embodiment of the present invention,

3 is a magnetic flux distribution diagram of a cylindrical permanent magnet according to a preferred embodiment of the present invention,

Figure 4 is a magnetic flux waveform and electromotive force waveform graph by the reciprocating linear motion of the permanent magnet according to an embodiment of the present invention,

Figure 5 is a cross-sectional view of the vibration generator in series connecting several coils in accordance with a preferred embodiment of the present invention,

6 is an electromotive force graph of a vibration generator according to a preferred embodiment of the present invention,

7 is a cross-sectional view illustrating a case in which a plurality of coil bundles are provided on an inner surface of a cylinder according to a preferred embodiment of the present invention, and a vibration generator in which current directions of neighboring coil bundles are opposite to each other;

8 is a structural diagram winding a winding in the vibration generator of FIG.

9 is a total electromotive force graph obtained by connecting in series to the vibration generator of FIG.

10 is a circuit diagram for charging a portable information device according to a preferred embodiment of the present invention;

11 is a sectional view of a vibration generator without a motion guide shaft according to a preferred embodiment of the present invention.

Description of the main parts of the drawing

1 case 2 winding part

3: movable permanent magnet 4: void

5: spring 6: motion guide shaft

7: spaced apart 8: fixed permanent magnet

9: movable permanent magnet reciprocating space

10: battery 20: charging circuit

30: load 40: vibration generator

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.

The Li-ion battery used in mobile phones, which is one of the representative portable information devices of today, is driven at a voltage of about 4.2V ± 0.05V, and these mobile phones are gradually decreasing power consumption due to technology development, In order to reduce power consumption, the voltage is being reduced.

On the other hand, the general portable information device used by the known technology has a charging terminal that charges using a charger to charge regardless of the model, but it is provided in convenience stores, airports, terminals, etc. that people frequently find, fishing, climbing, distress In the event of a natural disaster, isolation, crisis, etc., there was a problem that the rescue request signal could not be transmitted due to the complete discharge of the battery.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to increase the battery usage time by charging the battery by converting the energy by natural vibration, such as vibration or walking by hand movement into electrical energy It is an object of the present invention to provide a vibration generator that can provide power even in a weak vibration to the information equipment discharged in the situation.

The object of the present invention is a vibration generator is a hollow case, both sides of a certain length is blocked, a winding portion formed by winding a predetermined thickness on the inner circumferential surface of the case, and a spring installed at a predetermined length on both sides blocked in the case, It provides a vibrating oscillator consisting of a movable permanent magnet freely movable with a predetermined gap between the spring installed in the case, and a movement guide shaft penetrating the center of the movable permanent magnet and attached to a fixed length spring at both ends, In order to obtain energy even in the weak vibration, instead of the spring of the vibrating generator, it provides a spring-less vibrating diaphragm with fixed permanent magnets facing each other in the same direction as the pole direction of the movable permanent magnet on both sides of the case. If the case is made of non-magnetic material in a vibration generator without The load reduction was achieved by providing a vibration generator capable of converting the micro vibration energy by removing the shaft.

Hereinafter, the configuration of the present invention will be described in detail with reference to the accompanying drawings for a preferred embodiment.

First of all, the concept of the present invention relates to a vibration generator for converting vibration energy into electric energy. At present, a technology or a product for converting energy by magnitude into useful electric energy has not been announced yet. Although the present invention consists of a linear generator by linear reciprocating motion and also the present invention is manufactured in one piece or separate type as an emergency or auxiliary auxiliary charging means of a portable information device and its shape is in various forms such as AA, AAA size of cylindrical battery It can be manufactured in various forms such as rectangular shape.

1 is a cross-sectional view with a spring provided inside a vibration generator according to a preferred embodiment of the present invention (a) is a hollow case (1) is blocked on both sides of a predetermined length, and a constant on the inner peripheral surface of the case (1) A predetermined air gap 4 is formed between the winding part 2 formed to be wound to a thickness, a spring 5 installed at a predetermined length on both sides of the case 1, and a spring 5 installed in the case 1. It consists of a movable permanent magnet (3), which is freely embedded in the movement, and a movement guide shaft (6) penetrating the center of the movable permanent magnet (3) and attached to a fixed length spring at both ends.

More specifically, the case 1 is a hard material that serves to protect the internal parts by the body of the entire vibration generator and is well magnetized, and the case 1 is cylindrical or square according to the shape of the movable permanent magnet 3. It is produced in various ways.

The winding portion 2 formed by winding a predetermined thickness on the inner circumferential surface of the case 1 generates an electromotive force according to Faraday's law by the reciprocating motion of the movable permanent magnet 3 vibrating by an external force. The magnitude of the 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 movable permanent magnet 3, and the reciprocating separation distance of the movable permanent magnet 3 and is the terminal of the winding part 2. When connected to a battery or an electrical load, the kinetic energy of the reciprocating motion or vibration of the movable permanent magnet (3) is converted into electrical energy to transfer power. Therefore, the winding is preferably a conductor such as copper or the like and the winding must be insulated.

The movable permanent magnet (3), which is freely embedded with a predetermined gap (4) between the springs (5) installed in the case (1), moves along the motion guide shaft (6) by drilling a hole in the center in accordance with the direction of movement. In addition, it is preferable to form a space 4 between the movable permanent magnet 3 and the winding part 2 so that the movable permanent magnet 3 is attached to the winding part 2 inside the case 1 so that no load is generated. Do. Preferably, the shaft consists of nonmagnetic (nonmagnetic) material.

The spring 5 installed at a predetermined length on both sides of the case 1 stores the kinetic energy of the movable permanent magnet 3 as spring energy when the movable permanent magnet 3 reverses the direction of movement according to the reciprocating motion. In order to smooth the change of direction and to protect the noise and the movable permanent magnet (3) by the collision with the side of the case (1). Therefore, both ends of the case (1) and the material of the spring (5) is preferably a non-magnetized material and the spring coefficient is a limited movable permanent magnet according to the length of the case (1) together with the mass value of the movable permanent magnet (3) It is preferable to select such that the maximum power is generated in an external motion frequency band applied to the case 1 under the constraint of the separation distance of (3).

The movable permanent magnet 3 freely embedded with a predetermined gap 4 between the springs 5 installed in the case 1 has a mass for storing kinetic energy and a magnetic flux that changes with time. ) Acts to feed. 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 movable permanent magnet (3) is possible in a variety of forms, such as cylindrical, square pillars with a case, and the movable permanent magnet (3) is magnetized in the height direction of the cylinder or square pillar. In order to increase the mass of the movable permanent magnet 3, it is preferable to combine the material with a large specific gravity.

Next, a movable permanent magnet reciprocating space 9 is formed in the case 1 to allow the movable permanent magnet 3 to reciprocate, and the movable permanent magnet reciprocating space 9 is formed on the movable permanent magnet 3. In the reciprocating process, the voids 4 are formed.

(B) shown in FIG. 1 is a cross-sectional view taken along the line A-A to help understanding the cross-sectional view (a) shown in FIG. 1, and (c) shown in FIG. 1 is a cross-sectional view taken along the line B-B. In particular, the separation space 7 shown in (b) is a micro-spaced separation space (7) in order to reduce the frictional force generated during the movement of the first permanent magnet 3 along the motion guide axis (6) It is formed.

2 is a cross-sectional view of a permanent magnet provided in a vibration generator according to a preferred embodiment of the present invention. The vibration generator includes a fixed permanent magnet in the same magnetization direction as the magnetization direction of the movable permanent magnet (3). It attaches to the role of the spring (5). That is, the movable permanent magnet 3 and the fixed permanent magnet 8 have the same polarity facing each other and the pushing force acts so that the movable permanent magnet 3 is in a very unstable state and easily moves even in a small vibration. Due to such a shape, the case 1 is made of a material having no magnetization, so that the motion guide shaft 6 can be removed to easily generate energy even in the small vibration.

3 is a magnetic flux distribution of a cylindrical permanent magnet according to a preferred embodiment of the present invention, when the case 1 is made of a material that is well magnetized, the magnetic flux is precious and the movable permanent magnet 3 ) Reciprocates linearly in the case (1), and the magnetic flux linking to the coil is changed by Faraday's law to generate induced electromotive force, and the magnetic flux path is very short compared to the case of the nonmagnetic (nonmagnetic) case (1). The size of M is much improved and the electromotive force induced in the coil is increased. As shown in FIG. 3, the magnetic flux distribution viewed from the position of the coil based on the direction in which the movable permanent magnet 3 moves is the same as the graph (a) shown in FIG. 4. The magnitude of the magnetic flux is determined by the magnetic flux density of the movable permanent magnet (3) and the cross-sectional area of the first permanent magnet (3), and the voltage induced by the movable permanent magnet on one coil is determined by the Faraday law. Since it is different from, it is similar to (b) graph shown in FIG. 4, and (b) graph shows a realistic actual waveform considering theoretical square wave and leakage magnetic flux.

In this case, 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, and the period of the waveform is determined by the length and diameter of the permanent magnet and the air gap (4). The electromotive force has a wavy waveform.

5 is a cross-sectional view of a vibrating generator in which several coils are connected in series according to a preferred embodiment of the present invention, in order to increase the magnitude of the electromotive force, the number of windings that can be connected in series with the diameter of the copper wire, the length of the movable permanent magnet, and the like. It is determined by the diameter and the length of the voids 4 and also gives a layer to the winding part 2 to be made in a one-, two- or three-layer structure, which layer is called a coil bundle.

Figure 6 is a graph of the electromotive force of the vibration generator according to a preferred embodiment of the present invention (a) shows the electromotive force induced in each coil in an approximate sinusoidal waveform and (b) is shown in connecting each coil in series One synthetic electromotive force is shown. The magnitude of the combined electromotive force is determined by the magnetic flux density of the movable permanent magnet, the radius of the cross section and the vibration frequency, and the number of series windings, and the period of the combined electromotive force is wound in one direction and the period of the electromotive force by one coil in one winding. Equal to the sum of the coil spacings.

FIG. 7 is a cross-sectional view illustrating a case in which a plurality of coil bundles are provided on an inner surface of a cylinder according to a preferred embodiment of the present invention, and a vibration generator in which current directions of neighboring coil bundles are opposite to each other. The currents are all in the same direction but the neighboring coils are in opposite directions. When the winding part 2 is made of a single-layer winding, as shown in FIG. 8, only the direction is continuously wound without winding the copper wire and wound around the cylinder. Even in the case of a three-layer winding, as shown in Fig. 8, when the coil is wound around the cylinder and one coil bundle length is completed, the coil is continuously wound in the same direction and the horizontal direction is continuously wound in the opposite direction to reach the original position. If you reverse the horizontal direction while winding the coil in the same direction again, one-way winding of one coil bundle is produced. If the coil bundle is reversed only in the coil winding direction, the above operation may be repeated to complete a coil bundle having a different current direction. By repeating this method, you can easily wind the winding continuously without breaking or connecting the coil.

9 is a graph of the total electromotive force obtained by connecting in series to the vibration generator of FIG. 7 shows that the electromotive force of neighboring coil bundles overlap each other, and thus the magnitude of the electromotive force is almost doubled and is increased by several coil bundles. The effective voltage of one cycle reciprocated by the first permanent magnet is greatly increased, and when the coil bundle is connected in series, the total synthesized electromotive force is generated. Accordingly, the terminal electromotive voltage of the vibration generator 40 is represented by an alternating voltage, and the alternating voltage is charged through the rectifying circuit and the charging circuit 20 to charge the battery 10, which is a direct current voltage, as shown in FIG. 10. ) Or is delivered to the load 30.

11 is a cross-sectional view of a vibrating generator without a motion guide shaft according to a preferred embodiment of the present invention. The vibrating generator is a case 1 of a nonmagnetic material in which both sides of a predetermined length are blocked and hollow, and a predetermined thickness on an inner circumferential surface of the case 1. A movable permanent magnet (3) freely movable with a predetermined gap (4) between the winding part (2) which is formed by winding to a fixed permanent magnet (8) installed in the case (1), and the case ( 1) shows a vibration generator capable of converting micro-vibration energy is composed of a fixed permanent magnet (8) having the same polarity that opposes the movable permanent magnet (3) on both sides blocked.

As described above, the present invention has the effect of increasing the battery usage time by charging the battery by converting the energy from the light vibration into electrical energy, and the distress in long-term outdoor activities, long-distance business trips and fishing, hiking, etc. In a similar emergency, it is a very excellent invention in the battery industry using a mobile phone because it has an effect of charging and using a battery using its own power generation function.

Claims (7)

The vibration generator includes a hollow case 1 having both sides of a predetermined length blocked, a winding portion 2 formed by winding a predetermined thickness on the inner circumferential surface of the case 1, and a predetermined length on both sides of the case 1 blocked. A movable permanent magnet 6 freely embedded with a predetermined gap 4 between the spring 5 and the spring 5 installed in the case 1, and the center of the movable permanent magnet 6. A new vibration generator, characterized in that consisting of a movement guide shaft (6) attached to the both ends and a constant length spring (5). The vibration generator of claim 1, wherein the movable permanent magnet (3) is reciprocated by an external force so that electromotive force is generated in the cavity (4) and the winding part (2). The new vibration generator according to claim 1, wherein the vibration generator is applied to a portable information communication device. The new vibration generator according to claim 1, wherein the winding part (2) has a coil bundle wound in a layer structure. 5. The new vibration generator as set forth in claim 4, wherein the coil bundle repeatedly winds the coil winding in a reverse direction. The vibrating generator includes a hollow case 1 in which both sides of a predetermined length are blocked, a winding part 2 formed by winding a predetermined thickness on an inner circumferential surface of the case 1, and a fixed permanent magnet installed in the case 1. 8) a movable permanent magnet 3 freely embedded with a predetermined gap 4 therebetween, and a fixed permanent magnet 8 having the same polarity facing the movable permanent magnet 3 on both sides blocked in the case 1. And a movement guide shaft (6) penetrating the center of the movable permanent magnet (3) and inserted into and fixed to the center of the fixed permanent magnet (8) installed at both sides. The vibrating generator is a case (1) of the non-magnetic material of the hollow and non-blocking both sides of a predetermined length, a winding portion (2) formed by winding a predetermined thickness on the inner circumferential surface of the case (1), and fixed in the case (1) A fixed permanent magnet (3) freely movable with a certain gap (4) between the permanent magnets (8), and fixed with the same polarity that opposes the movable permanent magnet (3) on both sides blocked in the case (1). New vibration generator, characterized in that consisting of a permanent magnet (8).

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