KR20060066183A - Hand exercisers generator - Google Patents

Abstract

Most conventional generators use electricity to rotate the magnetic poles to generate electricity. This design is a linear generator that generates electricity in the stator coils by moving the magnetic poles in a straight line. The method of using only one magnet requires a lot of moving space, but the present design uses a multi-pole generator to get high electricity at a small moving distance, and it has a spring so that repeated linear motion can be performed. In addition, we have set up a charging circuit or a rechargeable battery to collect the generated electricity, or install a jack or rechargeable battery to supply power when needed along with the charging status indicator. It is also designed to put your hand in hand, compress it with the palm and finger forces and return it to the spring for hand movement.

That is, it is designed to mainly operate the linear generator while moving the hand and to turn on the LED lamp by using the generated electricity to charge the secondary battery or the capacitor or to supply power to other electronic devices.

Linear generator. Charging circuit. Secondary battery. Multi-pole generator. Grip. York. Winding, coil, bobbin, magnet, yoke, spring, coil and yoke fastening bolt, shaft, fixed plate, moving plate 'stop ring, spring shaft fixing nut, metal bearing, outer box, outer box, electronic circuit (PCB), secondary Battery Storage, LED LAMP, Connection Jack, Indicators

Description

Hand Exercisers Generator which charges while doing hand movements

1 is a basic theoretical diagram of a linear generator

    2 is a structural diagram of a two-pole linear generator using the basic theory

    3 shows the increase and decrease of the magnetic flux according to the arrangement of the magnetic poles

    4 is a structural diagram of a multipolar linear generator

    5 is a generator diagram of hand

    [Figure 6] Hand generator with an electronic component such as a charging circuit and made a hand to exercise

Fig. 7 is a view of the hand generator with a back and a tweeter

The present invention is a generator that converts linear motion directly into electrical energy. In the related art, the conventional technology is to generate power by converting linear motion into rotational motion or to generate two-pole power, that is, reciprocating motion of one magnet. There was no generator equipped.

 1. The present invention attempts to obtain a high voltage at a small linear motion distance.

2. To charge at this voltage, limit the peak voltage so that a constant voltage circuit, a charging circuit, and a secondary battery are placed to collect the generated electricity of low frequency.

3. Operate by hand and use as exercise equipment.

1. The principle of the present invention is that when the permanent magnet moves in the cylindrical coil, electricity is generated in the coil. In other words, when there is a change in magnetic flux, a current flows in the coil, which is the basic principle of the present invention, and FIG. 1 shows this.

2. When the 2-pole linear generator is constructed in accordance with the present principle, as shown in FIG. 2, the permanent magnet 3 is placed inside the bobbin 2 on which the coil 1 is wound, and the yoke constituting the magnetic path so that the magnetic flux generated from the magnet is well communicated ( 4). The spring (5) is set to return after pushing the magnet. In addition, the upper and lower iron bolts (6) were connected to form a path for connecting the upper yoke and the lower yoke. In FIG. 2, when the moving plate 9 on which the shaft 7 holding the permanent magnet 3 is fixed is pressed, the magnet 3 moves from the lower part of the yoke 4 to the upper part so that the magnetic flux flows from the magnet 3. Pass the upper yoke (4), pass the bolt, and return to the magnet along the lower yoke. When the moving plate 9 is released, the magnet is returned to its original state by the spring, and the flow of magnetic flux is reversed. When pressed once, one cycle of electricity flows into the coil, and the charging circuit can be used to charge high-capacity capacitors or secondary batteries to collect the electricity needed.

The generated voltage is proportional to the number of turns, like the basic theory of electricity, and correlates with frequency as it is pressed quickly.

3. As shown in FIG. 2, one frequency is achieved when the magnet reaches the upper yoke after passing through the lower yoke and then reaches the lower yoke again. In other words, enough efficiency can be achieved by moving from the lower yoke to the upper yoke. To this end, if the magnetic poles of the magnet are placed as shown in 1) of FIG. 3, that is, the magnetic flux flows to the NS-NS-NS as shown by the arrow shown in the figure, so that the magnetic flux is detailed in some yokes. The efficiency can only be increased if the magnet starts from the bottom yoke (D in the figure) and moves to the top yoke (A in the figure).

However, when the magnetic pole of the magnet is arranged as NS-SN-NS as shown in 2) of FIG. 3, the magnetic flux is not canceled in the yoke, thereby creating a condition of rising. That is, even if the magnet has a movement distance of only one magnet from yoke A to B, one frequency is formed.

When the magnetic pole of the magnet is arranged as shown in 2) of FIG. 3, a voltage change of many frequencies can be obtained with a small movement distance. Also, as shown in 2) of FIG. 3, if the magnetic poles of the magnets are assembled in such a way as to generate repulsive forces between the magnets in the longitudinal or transverse directions, the required electricity can be obtained at a small movement distance. 4 is a linear generator composed of nine magnets. The number of magnets can be increased or decreased as necessary.

4. Constant AC voltage can be obtained by pressing the linear generator at regular intervals. However, there are not many applications of this, and it is used as a sports equipment to rectify the generated electricity, make a constant voltage circuit, charge it to a capacitor, and discharge it slowly, or supply electricity to a small electric device through a chirp to charge a secondary battery. You can turn on the LED light to use it for emergency lighting.

5. FIG. 5 shows a block diagram of a charging circuit and an electronic circuit employing a linear power generation system.

6. If the electronic circuit is configured in the space of the enclosure with the enclosure so that the multipole linear generator of FIG. As shown in FIG. 8, the upper enclosure 13 is fixed so that when the upper enclosure 13 is held and the lower enclosure 14 is pressed, the magnets generate power after passing through the yoke and the coil bobbin, and when they are released, the power is returned by the spring. . The grip of the hand increases the movement of the hand because it must give force for the spring and generator to develop. It is possible to make a hand generator, ie a hand-held generator that operates with the power of the hand to increase the power of the hand with such a charging circuit. This allows emergency charging of MP3s or mobile phones.

7. When you exercise, put the lights on the electronic circuit to know the state of exercise and also the state of charge so that you can know the state of exercise.

1. The present invention incorporates linear power generation technology into reality, and the application direction of linear power generators will be broadened based on this.

2. The present invention has achieved a multi-pole linear power generation technology with a small movement distance, so there will be application development of the multi-pole linear power generation technology.

3. You can use it as a charger for small electric appliances and exercise and turn on emergency lights.

Claims (1)

1. Hand generator for turning on LED light by charging and raising hand grip by hand movement by assembling magnet to repel each other. 2. A hand generator configured to charge and operate a small electronic device such as an MP3 and a mobile phone by placing a rectifying circuit and a charging circuit in the multipolar linear generator of 1 above. 3. The hand generator of paragraph 1 comprising a circuit for hand movement and charge. 4. Hand-generator combining 1 and 2

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