KR20220064489A - Static Induction Generator Without Solid Of Rotation - Google Patents

Abstract

The present invention relates to an electrostatic induction generator without a rotating body. The electrostatic induction generator without a rotating body comprises: first capacitors (CA1, CA2), second capacitors (CA3, CA4), and third capacitors (CA5, CA6) installed on A side; fourth capacitors (CB1, CB2), fifth capacitors (CB3, CB4), and sixth capacitors (CB5, CB6) installed on B side; a first rectifier (1) connected to the first capacitors (CA1, CA2), the second capacitors (CA3, CA4), the fourth capacitors (CB1, CB2), and the fifth capacitors (CB3, CB4); a second rectifier (2) connected to the first rectifier (1); an A-side metal vacuum tube (4A) having the outside made of a metal; and a B-side metal vacuum tube (4B) having the outside made of a metal. According to the present invention, the electrostatic induction generator without a rotating body can be manufactured and manufacturing processes can be simplified.

Description

Static Induction Generator Without Solid Of Rotation

The present invention relates to an electrostatic induction generator.

The present inventor has registered a static induction generator without a rotating body (registration number 10-2031665).

Even after the applicant received the registration of the electrostatic induction generator without a rotating body, the applicant continued his research on the electrostatic induction generator without a rotating body, and, in particular, studied a method to dramatically increase the output.

1. Registration No. 10-2031665: Electrostatic induction generator without rotating body

An object of the present invention, which has been proposed to solve the above-described problems, is to provide an electrostatic induction generator without a rotating body, which can increase the output.

Electrostatic induction generator without a rotating body according to the present invention for achieving the above-described technical problem, three capacitors provided on the A side (first capacitor (C _A1 , C _A2 ), second capacitor (C _A3 , C _A4 ) ), the third capacitor (C _A5 , C _A6 )); three capacitors provided on the B side (fourth capacitors C _B1 , C _B2 , fifth capacitors C _B3 , C _B4 , sixth capacitors C _B5 , C _B6 ); Among the six capacitors, the first capacitors C _A1 , C _A2 and the second capacitors C _A3 , C _A4 provided on the A side are connected, and the fourth capacitors C _B1 , C provided on the B side _B2 ) and a first rectifier (1) connected to the fifth capacitors (C _B3 , C _B4 ); Among the six capacitors, the second capacitors C _A3 , C _A4 and the third capacitors C _A5 , C _A6 provided on the A side are connected, and the fifth capacitors C _B3 , C provided on the B side _B4 ) and the sixth capacitor (C _B5 , C _B6 ) and connected to, the second rectifier (2) connected to the first rectifier (1); A-side metal vacuum tube (4A) made of metal, one side connected to the third capacitor (C _A5 , C _A6 ), and the other side connected to the sixth capacitor (C _B5 , C _B6 ) ; And the outside is formed of metal, one side is connected to the sixth capacitor (C _B5 , C _B6 ), the other side is connected to the third capacitor (C _A5 , C _A6 ) B-side metal vacuum tube (4B) ) is included.

According to the present invention, an electrostatic induction generator without a rotating body can be manufactured, and thus, the manufacturing process of the generator can be simplified.

In particular, according to the present invention, the output of the electrostatic induction generator without a rotating body can be increased more than in the prior art, and the present invention using a rectifier is much lighter than using a transformer and has a small area or volume, which is very excellent in space utilization. , When multiple capacitors are connected in series, the number of transformers is as many as the number of capacitors, and since the number of capacitors for series resonance of the primary and secondary coils of the transformer is twice that of the number of transformers, it is lightweight compared to using a transformer in terms of assembly and connection. , miniaturization, work simplification and cost reduction, etc., have various advantages and effects.

1 is an exemplary view showing the configuration of a static induction generator without a rotating body according to the present invention, in particular, an exemplary view showing a method of generating power when the switch of the A-side high voltage DC power supply is closed.
Figure 2 is an exemplary view showing a method of generating power by the operation of the A-side metal vacuum tube in the electrostatic induction generator without a rotating body according to the present invention.
3 is an exemplary view showing a method of generating power by the operation of the B-side metal vacuum tube in the electrostatic induction generator without a rotating body according to the present invention.

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

Hereinafter, a detailed description of the basic principle of the metal vacuum tube described in the registered patent (registration number 10-2031665) (hereinafter simply referred to as a registered patent) applied and registered by the present inventor and basic components shared with the present invention will be omitted. and with reference to FIGS. 1 to 3, the practical contents of the present invention will be described.

The present applicant applied for an electrostatic induction generator without a rotating body and, while continuing research after being registered as registration number 2031665 (2019.10.07), dramatically increased the output of the electrostatic induction generator without a rotating body, and ) A method using a rectifier was newly confirmed, and the present invention relates to this. Hereinafter, the power generation process will be described in detail by showing the structure of the electrostatic induction generator without a rotating body according to the present invention in FIGS. 1 to 3 .

1 is an exemplary view showing the configuration of a static induction generator without a rotating body according to the present invention, in particular, an exemplary view showing a method of generating power when the switch of the A-side high voltage DC power supply is closed. 2 is an exemplary view showing a method in which power generation is made by the operation of the A-side metal vacuum tube in the electrostatic induction generator without a rotating body according to the present invention, and FIG. 3 is a B-side metal vacuum tube in the electrostatic induction generator without a rotating body according to the present invention. It is an exemplary diagram showing how power generation is made by the operation of

As described above, in the registered patent, the output formula of an electrostatic induction generator without a rotating body, in which four capacitors of the same type and the same capacity are divided into two on the A and B sides and connected in series,

P = ½ CV ² N[W]).

From the above output formula, it can be seen that increasing the voltage is the most effective method to obtain a large output. Therefore, when as many capacitors as possible are connected in series, a larger output than expected can be obtained.

However, when capacitors are connected in series, a problem arises that the capacity decreases. However, if capacitors having a sufficiently large capacity are connected in series or in parallel, the reduced capacity can be compensated. Also, since the frequency can be raised when the capacity is reduced, the capacity reduced by these various methods such as raising the frequency can be sufficiently compensated.

In the present invention, as shown in FIG. 1, six capacitors of the same type and of the same amount are divided into three A-side and B-side, which are the left and right sides of the drawing, and will be described. In this case, the electrodes of the three capacitors on the A side are called C _A1 , C _A2 , C _A3 , C _A4 , C _A5 , C _A6 from the top of the A side, and the electrodes of the three capacitors on the B side are from the top down on the B side They are called C _B1 , C _B2 , C _B3 , C _B4 , C _B5 , C _B6 .

In addition, the silicon rectifier formed as a bridge circuit is abbreviated as a rectifier for convenience, and the A-side and B-side circuits of the first rectifier 1 on the upper part are called 1A and 1B, respectively, and the A-side of the second rectifier 2 on the lower part, The B-side circuit is called 2A and 2B, respectively.

1, C _A2 and C _A3 are connected in series with the A-side circuit 1A of the first rectifier 1, and C _A4 and C _A5 are the A-side circuit 2A of the second rectifier 2 and connected in series, C _B5 and C _B4 are connected in series with the B-side circuit 2B of the second rectifier 2, and C _B3 and C _B2 are connected to the B-side circuit 1B of the first rectifier 1 and connected in series

In addition, the terminal 5A of the heat dissipation cathode (cathode) of the A side metal vacuum tube 4A is connected to C _A6 , the external terminal 6A is connected to C _B6 , and the heat dissipation type cable of the B side metal vacuum tube 4B A terminal 5B of the sword (cathode) is connected to C _B6 , an external terminal 6B is connected to C _A6 , and C _A1 and C _B1 are connected by a conducting wire 7 .

And, the + pole of the A-side high-voltage DC power supply 3A is connected to C _A1 , the - pole is connected to C _A6 , the + pole of the B-side high-voltage DC power supply 3B is connected to C _B1 , and the - pole is When connected to C _B6 , the configuration of the electrostatic induction generator without a rotating body according to the present invention is completed.

As shown in Figure 1, when the switch (9A) of the A side high voltage DC power supply is closed (on) and + electricity is charged to C _A1 and - electricity is charged to C _A6 , - and + electricity are generated in C _A2 due to electrostatic induction, -Electricity is attracted by + electricity of C _A1 and remains in C _A2 , and + electricity flows to C _A3 along the A-side primary circuit 1A of the first rectifier while being pushed and charged. Then, -, + electricity is generated by electrostatic induction in C _A4 , and - electricity is attracted by + electricity of C _A3 and remains, and + electricity is pushed.

And, when -electricity is charged in C _A6 by the high voltage DC power from A side, + and - electricity is generated in C _A5 by electrostatic induction, the + electricity is attracted by the - electricity of C _A6 and remains in C _A5 , - Since electricity attracts the + electricity of C _A4 that is pushed by the + electricity of C _A3 , a current flows in the A-side circuit (2A) of the second rectifier in the direction of C _A4 to C _A5 .

This phenomenon continues until the voltage of the A-side high-voltage DC power supply and the voltages of C _A1 and C _A6 on the A-side are the same, and when charging is complete, turn off the switch 9A of the A-side high-voltage DC power supply as shown in FIG. 2 . At the same time, the A-side metal vacuum tube (4A) is operated to flow -electricity from C _A6 to C _B6 to charge it. Then, + and - electricity are generated by electrostatic induction in C _B5 , + electricity is attracted by - electricity of C _B6 and remains in C _B5 , and - electricity is pushed (by the arrow of the A-side metal vacuum tube 4A). Direction indicates the direction in which hot electrons flow).

And, when the + electricity of C _A5 deviating from the _-electric attraction of C _A6 flows to C _A4 along the A side circuit 2A of the second rectifier and is neutralized with the - electricity of C _A4 , The + electricity of C _A3 flows to C _A2 along the A-side circuit 1A of the first rectifier, and is neutralized with the - electricity of C _A2 . Therefore, the direction of the current flowing in the A-side circuits 1A and 2A of the first and second rectifiers is opposite to the previous one, so it is alternating current.

And, when the -electricity of C _A2 is neutralized with the +electricity of C _A3 , the +electricity of C _A1 escaping from the -electric attraction of C _A2 flows to C _B1 along the conductor 7 and is charged. Therefore, -, + electricity is generated by electrostatic induction in C _B2 , and - electricity remains in C _B2 , and + electricity of C _A1 flows to C _B1 to help charge it, and + electricity of C _B2 is the first rectifier. If it flows along the B-side circuit (1B) to C _B3 and is charged, electrostatic induction occurs in C _B4 as well, so -electricity remains in C _B4 , and +electricity connects the B-side circuit (2B) of the second rectifier. Thus, it flows into C _B5 and is neutralized with the negative electricity of C _B5 that is pushed by C _B6 .

At this time, since it takes a long time to charge by flowing all (100%) of the - and + electricity charged in C _A6 and C _A1 to C _B6 and C _B1 , there may be some - and + electricity remaining in C _A6 and C _A1 . At this time, it is more efficient to stop the A-side metal vacuum tube 4A and operate the B-side metal vacuum tube 4B to generate new power in terms of the output of power generation. That is, it is more efficient in terms of the output of power generation to alternately operate the metal vacuum tubes on the A and B sides as often as possible at the same time. Therefore, when a little -,+ electricity remains in C _A6 and C _A1 , stop the metal vacuum tube on the A side, close the switch 9B of the B side high voltage DC power supply 3B, and close (on) the remaining in C _A6 and C _A1 . After replenishing - and + electricity to C _B6 and C _B1 by the amount of - and + electricity, turn off the B side high voltage DC power switch and at the same time connect the B side metal vacuum tube (4B) as shown in FIG. Operate it and charge it by flowing the -electricity of C _B6 to C _A6 (the direction indicated by the arrow on the B side metal vacuum tube also means the direction in which hot electrons flow). Accordingly, when the + electricity of C _B5 escaping from the -electric attraction of C _B6 flows to C _B4 along the B side circuit (2B) of the second rectifier and is neutralized with the - electricity of C _B4 , in the -electric attraction of C _B4 The escaping + electricity of C _B3 flows to C _B2 along the B-side circuit 1B of the first rectifier, and is neutralized with the - electricity of C _B2 .

Therefore, the + electricity of C _B1 escaping from the -electric attraction of C _B2 flows to C _A1 along the conductor 7 and is charged. In this case, again, in order to increase the power generation efficiency, when a little - or + electricity remains in C _B6 and C _B1 , the operation of the B-side metal tube 4B is stopped and the A-side metal vacuum tube 4A is operated at the same time. As described above, power generation continues if the A and B side metal vacuum tubes are operated alternately and periodically. And, at the beginning, - and + electricity were supplemented to C _B6 and C _B1 by the amount of electricity remaining in C _A6 and C _A1 , but after this, you do not need to replenish any more. However, although it is a very small amount due to short circuit and heat generation, - and + electricity decreases little by little.

The above phenomenon continues while the A-side metal vacuum tube 4A operates, and as described in the invention of Patent Registration No. 2031665, when a little electricity remains on the A-side to increase the power generation efficiency, the A-side metal vacuum tube 4A At the same time as stopping the operation of the B side, close (on) the switch 9B of the B side high voltage DC power supply (3B) to replenish the B side by the amount of electricity remaining on the A side first, and then turn off the B side high voltage DC power switch ( off) and at the same time as shown in Figure 3, by operating the B-side metal vacuum tube (4B) to allow the -electricity of C _B6 to flow into C _A6 and charging it, the + electricity of C _B5 , which escapes from the -electric attraction of C _B6 2 It flows into C _B4 through the _B side circuit (2B) of the rectifier (2) and is neutralized _{with the - electricity of C B4 .} It flows to C _B2 through the side circuit (1B) and is _neutralized with - electricity of C _B2 . Since it flows in the direction of C _B4 , the current flowing through the B-side circuit 1B of the first rectifier 1 and the B-side circuit 2B of the second rectifier 2 is also alternating current.

Therefore, this alternating current is converted into direct current due to the rectification action of the two rectifier circuits on the B side, and the + current of the B side circuit 1B of the first rectifier 1 and the B side circuit 2B of the second rectifier 2 is the load ( 8) flows to the + pole, and the - current flows to the - pole of the load (8). Accordingly, alternating current is changed to direct current (pulsating current) due to the rectification action of the first rectifier 1 and the second rectifier 2 , and the four conductors are merged into two and flow to the + pole and the - pole of the load 8 .

As such, the power generation method when using a rectifier is much lighter than using a transformer instead of a rectifier, and it occupies a small area or volume, so it is excellent in space utilization. Since the number of capacitors for series resonance of the primary and secondary coils is twice as large as the number of transformers, compared to using a transformer in assembly and connection, there are various advantages and effects such as weight reduction, miniaturization, work simplification and cost reduction.

Those skilled in the art to which the present invention pertains will understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential characteristics thereof. Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive. The scope of the present invention is indicated by the following claims rather than the above detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

1: first rectifier 2: second rectifier
1A: A-side circuit of the first rectifier (1) 2A: A-side circuit of the second rectifier (2)
1B: B-side circuit of the first rectifier (1) 2B: B-side circuit of the second rectifier (2)
3A: A side high voltage DC power supply 3B: B side high voltage DC power supply
4A: A side metal vacuum tube 4B: B side metal vacuum tube

Claims (4)

three capacitors provided on the A side (first capacitors C _A1 , C _A2 , second capacitors C _A3 , C _A4 , and third capacitors C _A5 , C _A6 );
three capacitors provided on the B side (fourth capacitors C _B1 , C _B2 , fifth capacitors C _B3 , C _B4 , sixth capacitors C _B5 , C _B6 );
Among the six capacitors, the first capacitors C _A1 , C _A2 and the second capacitors C _A3 , C _A4 provided on the A side are connected, and the fourth capacitors C _B1 , C provided on the B side _B2 ) and a first rectifier (1) connected to the fifth capacitors (C _B3 , C _B4 );
Among the six capacitors, the second capacitors C _A3 , C _A4 and the third capacitors C _A5 , C _A6 provided on the A side are connected, and the fifth capacitors C _B3 , C provided on the B side _B4 ) and the sixth capacitor (C _B5 , C _B6 ) and connected to, the second rectifier (2) connected to the first rectifier (1);
A-side metal vacuum tube (4A) made of metal, one side connected to the third capacitor (C _A5 , C _A6 ), and the other side connected to the sixth capacitor (C _B5 , C _B6 ) ; and
B-side metal vacuum tube (4B) made of metal, one end connected to the sixth capacitor (C _B5 , C _B6 ), and the other end connected to the third capacitor (C _A5 , C _A6 ) A static induction generator without a rotating body comprising a. The method of claim 1,
The second terminal C _A2 of the first capacitor and the first terminal C _A3 of the second capacitor are connected in series with the A-side circuit 1A of the first rectifier 1,
The second terminal C _A4 of the second capacitor and the first terminal C _A5 of the third capacitor are connected in series with the A-side circuit 2A of the second rectifier 2,
The second terminal C _B4 of the fifth capacitor and the first terminal C _B5 of the sixth capacitor are connected in series with the B-side circuit 2B of the second rectifier 2,
The second terminal C _B2 of the fourth capacitor and the first terminal C _B3 of the fifth capacitor are connected in series with the B-side circuit 1B of the first rectifier 1 without a rotating body induction generator. 3. The method of claim 2,
The terminal 5A of the heat dissipation cathode (negative electrode) of the A-side metal vacuum tube 4A is connected to the second terminal C _A6 of the third capacitor, and the external terminal 6A is the second terminal of the sixth capacitor connected to terminal (C _B6 ),
The terminal 5B of the heat dissipation type cathode (negative electrode) of the B-side metal vacuum tube 4B is connected to the second terminal C _B6 of the sixth capacitor, and the external terminal 6B is the second terminal of the third capacitor It is connected to terminal (C _A6 ),
The first terminal (C _A1 ) of the first capacitor and the first terminal (C _B1 ) of the third capacitor are connected to each other by a conductive wire (7). 4. The method of claim 3,
The + pole of the A-side high voltage DC power supply 3A is connected to the first terminal C _A1 of the first capacitor, and the - pole is connected to the second terminal C _A6 of the third capacitor,
The + pole of the B-side high voltage DC power supply 3B is connected to the first terminal C _B1 of the fourth capacitor, and the - pole is connected to the second terminal C _B6 of the sixth capacitor without a rotating body. electrostatic induction generator.

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