KR20000025169A - Generator for performing simultaneously input and output and increasing output - Google Patents

Abstract

PURPOSE: A generator for performing simultaneously an input and an output and increasing an output is provided to perform simultaneously an input and an output by forming an input portion and an output portion of a generator with one body. CONSTITUTION: A generator for performing simultaneously an input and an output and increasing an output comprises a rotator(16), a shaft(18), a gear portion(9), a housing(2), a slip ring(6), and a brush(7). The rotator comprises a rectifier(11) having an input portion(11a) and an output portion(11b) of one body. The shaft combined with the rotator is rotated by a support(110,110'). The gear portion is combined with one end of the shaft. The housing is combined with one end of the gear portion and it is rotated toward an opposite direction of the shaft. The slip ring comprises a power input terminal(6a) and a power output terminal(6b). The brush is adhered to a slip ring housing fixed on the support and it supplies the power to the slip ring or charges output power to a battery.

Description

Generator that can simultaneously input and output and increase output

The present invention relates to a generator capable of simultaneously input and output and increasing output. Conventional generators generate power using a single generator. In other words, even if the power is produced by a number of generators, it is just a collection of electricity generated from each generator. The power generation principle of the conventional generator transmits the rotational force obtained by hydraulic power or thermal power or other various powers to the shaft of the generator, and generates electricity by breaking the magnetic flux of the stator while the rotor rotates by the rotational force transmitted to the shaft. It is outputted by a commutator to a brush and filled in a rechargeable battery, or has a structure for transmitting power.

In addition, as shown in Figure 10, the stator of the generator is attached to the housing fixed to the bottom, only the rotor has a structure that rotates inside the stator. This is the structure that is the most distinguished from the present invention, the stator is fixed as described above, there is a limit to increase the current and voltage by a conventional generator that rotates only the rotor. In other words, since the voltage is proportional to the rotational speed of the rotor, there is a limit to increasing the rotational speed of the rotor in the structure of the conventional generator, there is a limit to increase the number of windings indefinitely, or increase the number of poles.

The generator according to the present invention includes a commutator having a commutator in which an input piece and an output piece of the generator are integrally formed in a generator in which an input and an output of a power are made by a slip ring, and at the same time, the rotor rotates by an input power source. The shaft is to rotate the housing coupled to interlock by the gear portion in the opposite direction of the rotor, the output is made from the output of the commutator.

At this time, the rotor as well as the stator rotates in the opposite direction of the rotor, despite the rotation of the rotor 1, the same result as the two rotations during the same time by the opposite rotation of the stator, the number of revolutions is doubled. This means that the rotation speed and the rotation speed of the rotor with respect to the stator, or the shortening and the rotation speed of the rotation speed of the stator with respect to the rotor. In other words, the generator of the present invention does not change the cross-sectional area and the magnetic flux of the conductor, but the rotation speed per revolution of the rotor is reduced to 1/2, so that the rotational speed of the power generator rotor without increasing the number of windings or the number of poles is increased. The output voltage can be increased.

Furthermore, in the present invention, the rotational speed of the power generator rotor is increased from the point of time out of the synchronous speed, but in the present invention, the speed can be reduced by a speed control means when the speed is higher than a certain speed. This is in consideration of the practicality and durability of the generator of the present invention.

In addition, since the ratio of the input piece to the output piece of the commutator formed integrally with the commutator part of the power generator rotor is arranged in a range of 1: 1 ^to 1: 7, the output of 1 ^to 7 is output ^{from the} output piece while 1 is input to the input piece. This results in an increase in the cross-sectional area of the conductor, resulting in an increase in output.

At this time, the ratio of input and output pieces of each commutator can be adjusted by the manufacturer, but the most preferable ratio of input pieces to output pieces is 1: 3, 1: 5, 1: 7. This is because when the rotor is connected in series with the shaft, the output ratio can be increased more than the input ratio of the commutator by increasing the number of rotors. That is, in the case of 1: 3, when 1 input is made from the commutator of one rotor, the output of 3 is made in the other commutator.

Of course, the ratio may be higher than 1: 7, but in this case, since the number of rotors coupled to the shaft increases, the initial generator starting input voltage should be relatively large, which is more mechanical and electrical than increasing the rotor capacity. It is because it has a closed end which becomes difficult of a structure.

This will be described in detail with reference to FIGS. 7 to 9 as follows. In other words, when the ratio of the input side to the output side of the commutator is 1: 3, when there are 16 commutator pieces, the commutator input pieces are four and the remaining 12 are output pieces.

At this time, the power input brush is connected to the input side of the commutator to drive the generator of the present invention, and at the same time, the power generated in the output side is charged to the rechargeable battery by the output brush connected to the output side of each commutator.

1 is a schematic cross-sectional view showing the structure of the generator of the present invention.

2 is a cross-sectional view for showing an operating state of the present invention.

3 is a cross-sectional view taken along the line A-A of FIG.

4 is a cross-sectional view taken along the line B-B in FIG.

5 is a perspective view of the rotor in the present invention.

6 is a schematic cross-sectional view of FIG.

7, 8, and 9 are exploded reference views of the commutator portion and the rotor for showing the winding state of the rotor to show that the input of the power and the output of the power are made at the same time in the present invention.

10 is an explanatory diagram for showing a relationship between a conventional stator and a rotor;

11 is an explanatory diagram for showing a relationship between a stator and a rotor in the generator of the present invention.

* Explanation of symbols for main parts of the drawings

DESCRIPTION OF SYMBOLS 1 Invention generator 2 housing 3 power supply 4 rechargeable battery

5: wire 6: slip ring 6a: power input terminal 6b: output terminal

7 brush 7a input brush 7b output brush 8 slip ring housing

9: Gear portion 9a, 9b, 9c, 9d: Bevel gear (hereinafter referred to as gear) 9c ', 9d': Bearing

10 gear housing 10 'gear shaft 11 commutator 11a input piece

11b: output 12: brush 12a: input brush

12b: output brush 15: stator 16: power generation rotor 26a: iron piece

26b: slot 26c: copper wire 26d: insulator 18: shaft

100: support plate 110,110 ': pedestal 111,111': bearing

The configuration of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic cross-sectional view showing the structure of the generator of the present invention, the present invention is the input piece (11a) and the output piece (11b) in the generator (1) in which the input and output of the power is made by the slip ring (6) One or more power generating rotors 16 including the integrally formed commutator 11 are coupled to the shaft 18 in series, and one end of the shaft 18 is beveled with a bevel gear 9b and bolted. To be combined by Therefore, the gear 9b is again coupled to the gears 9c and 9d rotatably coupled to the gear shaft 10 'by the bearings 9c' and 9d ', and again the gears 9c and 9d are housed. It is coupled to the gear 9a coupled to one end of (2).

As shown in FIG. 3, the gear shaft 10 'protrudes from the gear housing 10 fixed to the pedestal 110', and the gears 9c and 9d and the bearings 9c 'and 9d'. It has a structure bonded by).

At this time, since the shaft 18 passes through the gear 9a as shown in FIG. 2, the rotation of the shaft does not directly affect the gear 9a.

Both ends of the shaft 18 are coupled to the pedestals 110 and 110 'by the bearings 111 and 111', and the center portion is coupled to the shaft supporting plate 2a by the bearing 2b.

At this time, the power supply of the power generator rotor 16 is fixed to one end of the housing 2 of the generator 1 of the present invention, the power input terminal 6a connected to the brush 12 and the wire 5 of the commutator 11 And a slip ring 6 of cylindrical shape having an output terminal 6b, and the slip ring 6 has a slip ring housing 8 as shown in FIG. The formed brush 7 is connected so that power is supplied and output simultaneously while the slip ring 6 is rotated. This is made possible by the commutator 11 which supplies and cuts power by itself by the rotation of the power generator rotor 16. That is, the commutator 11 of the rotor 16 of the present invention is connected to the input piece 11a. While the output piece 11b is integrally formed and the power is input by the input brush 11a, the output brush 11b outputs power.

At this time, the ratio of the input quantity and the output quantity can be adjusted by the difference in the arrangement number of the input piece 11a to the output piece 11b of the commutator 11, and the most preferable ratio is 1: 3, 1: 5 of the input piece to the output piece. , 1: 7. 7 to 9 are diagrams for showing the connection state with the winding of the copper wire of the commutator 11, only the case where the ratio between the input piece and the output piece of 1: 1 to 1: 3.

If two or more power generating rotors 16 are arranged on the shaft 18, the commutator input pieces and output pieces of one side and the other power generating rotor should be arranged so as to cross each other. In other words, the commutator of both rotors has the same arrangement of input pieces and output pieces, and when the brush is connected to the input piece of one commutator, the brush of the other commutator is connected to the output piece. Therefore, while the rotor of one power generation rotor is being supplied with power, the output of the other power generation rotor is made.

For example, as shown in FIG. 7, when the input pieces and the output pieces of the commutator of one rotor and the other rotor are arranged in a ratio of 1: 1, the brushes of either rotor are connected to the input pieces of the commutator. If present, the brush of the other rotor is connected to the output of the commutator.

Therefore, power is produced in the rotor connected to the output side of the commutator, and electricity is output through the output terminal 6b of the brush and the slip ring for output and stored in the rechargeable battery 4.

8 and 9, when the input pieces and the output pieces of the commutator of one rotor and the other rotor are arranged in a ratio of 1: 2, the first input piece is connected after the two output pieces are connected. In the case where the ratio is 1: 3, the first input piece is connected after the third output piece is connected.

In this way, when the brush of one rotor is connected to the input face of the commutator and the rotor starts to rotate, the brush of the other rotor is always connected to the output of the commutator. It is arranged so that it is not located at the input terminal. Therefore, the rotor does not start at the same time, and in the case of the ratio of 1: 2, the simultaneous output is made once, and in the case of 1: 3, it is made twice. It is independent of the rotation of the rotor and has no effect on the operation of the generator.

In addition, the inputs or outputs of the commutator of each rotor are not all connected to the same winding.In the case of 1: 1, if the winding of the input is made, the winding of the output is made, and the input and output are repeated again. To be wound.

In the case of 1: 2, when the winding of the input piece is made, the winding of the two output pieces is made, the winding of the input piece is made again, and the winding of the two output pieces is repeated.

In the case of 1: 3, when the winding of the input piece is made, the winding of the three output pieces is made next, and when the winding of the input piece is made again, the winding of the three output pieces is repeated again. This arrangement is the same for the commutator of one rotor and the other rotor, except that the input pieces are arranged so that they are not connected to the brush at the same time.

The installation number and output ratio of the rotor also vary according to the ratio difference between the input and output pieces of the commutator. In the case of 1: 3, two rotors can be operated. In the case of 1: 5, three rotors can be operated. In the case of 1: 7, four rotors can be operated. This is because the rotor of the present invention has the power to rotate itself by the input power, the energy that can drive one motor or a generator in the present invention has the effect of driving two or more power generators will be.

At this time, even if the four rotors are driven according to the present invention, since the supply and interruption of the power is made by the rotating brush itself, even if each rotor is rotated, the total input amount is not significantly different. This is possible because the rotor is rotated only when power is input to the commutator input side of each rotor.

Referring to the operation principle of the generator 1 of the present invention as described above with reference to the embodiment shown in FIG.

When the power source 3 is supplied by the power input terminal 6a of the slip ring 6, the input piece 11a of the commutator 11 of the rotor 16 by the wire 5 arranged in the housing 2 is provided. Therefore, when either brush of the two power generating rotors is connected to the input side of the commutator, rotation is made from the rotor connected to the input side, and when the rotor rotates, the other rotor also rotates. It is rotated at the same time. Accordingly, the shaft 18 also rotates in the rotational direction of the rotor 16, and first rotates the gear 9b fixed to the shaft 18 among the gears 9 formed at one end of the shaft 18. 9b) rotates the gears 9c and 9d engaged to both sides, and the gears 9c and 9d rotate the gears 9a engaged. Since the gear 9a is fixed to one end of the housing 2, the gear 9a causes the housing 2 to rotate in the rotational direction of the gear 9a. Thus, the shaft 18 and the housing 2 They will rotate in opposite directions. This means that the rotor 16 and the stator 15 rotate in opposite directions. Thus, the generator rotor of the present invention is the same as two revolutions during the same time. The speed is reduced to 1/2 so that the voltage is increased by increasing the speed of the rotor.

As described above, the generator of the present invention interlocks two generators in which the input piece and the output piece of the commutator are integrally rotated in the opposite direction of the rotor to the housing to which the stator is attached, thereby reducing the rotational speed to 1/2. By arranging the ratio of the output pieces to 1: 1 ^to 1: 3, the cross-sectional area of the conductor is increased, and the speed per revolution is reduced to 1/2, so that the power with increased voltage and current can be produced.

Claims (2)

In the generator 1, a power generation rotor 16 including a commutator 11 having an input piece 11a and an output piece 11b integrally formed therein, and coupled to the rotor by a pedestal 110.110 '. A shaft 18 coupled to be rotatable, a gear portion 9 coupled to one end of the shaft 18, and a housing 2 coupled to one end of the gear portion and interlocked with the shaft and rotating opposite to the rotation direction of the shaft And a slip ring (6) having a power input terminal (6a) and an output terminal (6b) coupled to the other end of the housing, and a slip ring housing (8) fixed to the pedestal (110). 6) Generator which can be input and output simultaneously and increase the output, characterized in that it consists of a brush (7) for supplying power (3) to the power supply or to charge the charger (4). 2. The gear unit (9) according to claim 1, wherein the gear unit (9) is formed on the gear (9b) fixed to the shaft (18), the gear unit housing (10) fixed to the pedestal (110 '), and the gear unit housing (10). The gears 9c and 9d rotatably coupled to the gear shaft 10 'and engaged to both sides of the gear 9b, the shaft 18 penetrates and is coupled to one end of the housing 2, and the gear 9c. And a generator (9a) which is engaged with the gear (9d), characterized in that the input and output is made at the same time, the generator capable of increasing the output.