KR20220033166A - Static Induction Generator Without Solid Of Rotation - Google Patents

Abstract

The present invention is to provide an electrostatic induction generator without a rotating body, which can increase output. To this end, the electrostatic induction generator without a rotating body according to the present invention comprises: first capacitors (CA1, CA2), second capacitors (CA3, CA4) and third capacitors (CA5, CA6) which are provided on side A; fourth capacitors (CB1, CB2), fifth capacitors (CB3, CB4) and sixth capacitors (CB5, CB6) which are provided on side B; a first transformer (1) which is connected to the first capacitors (CA1, CA2) and the second capacitors (CA3, CA4), and is connected to the fifth capacitors (CB3, CB4) and the sixth capacitors (CB5, CB6); a second transformer (2) which is connected to the second capacitors (CA3, CA4) and the third capacitors (CA5, CA6), is connected to the fourth capacitors (CB1, CB2) and the fifth capacitors (CB3, CB4), and is connected to the first transformer (1); a side-A metal vacuum tube (7); and a side-B metal vacuum tube (10).

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: Static 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 fifth capacitors C _B3 , C provided on the B side _B4 ) and the sixth capacitor (C _B5 , C _B6 ) is connected to the first transformer (1); 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 fourth capacitors C _B1 , C provided on the B side _B2 ) and a fifth capacitor (C _B3 , C _B4 ) and connected to, the second transformer (2) connected to the first transformer (1); A-side metal vacuum tube (7) made of metal, one end connected to the third capacitor (C _A5 , C _A6 ), and the other end 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 (10) ) 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.

1 is an exemplary view showing the appearance of a metal vacuum tube applied to the electrostatic induction generator without a rotating body according to the present invention.
Figure 2 is an exemplary view showing the internal structure of the cross section AA' and B-B' of Figure 1 viewed from above.
3 is an enlarged view of the operation of the metal vacuum tube in which the side surfaces of the cross-sections CC' and D-D' of FIG. 2 are enlarged.
Fig. 4 is an explanatory view for stopping the operation of the metal vacuum tube shown in Fig. 3;
5 to 7 are exemplary views for explaining an electrostatic induction generator without a rotating body according to the present invention.
8 is an exemplary view showing the configuration of an electrostatic 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.
9 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.
10 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, first, with reference to FIGS. 1 to 7, the contents described in the registered patent (registration number 10-2031665) (hereinafter simply referred to as a registered patent) applied and registered by the present inventors will be described. That is, with reference to Figs. 1 to 7, the basic principle of the metal vacuum tube applied to the present invention and the basic principle of the present invention are described, and with reference to Figs. 8 to 9, the practical contents of the present invention are described.

1 is an exemplary view showing the external appearance of a metal vacuum tube applied to an electrostatic induction generator without a rotating body according to the present invention, FIG. 2 is an exemplary view showing the internal structure viewed from above in cross-sections AA' and B-B' of FIG. 3 is an explanatory diagram of the operation of the metal vacuum tube with enlarged side surfaces of the cross-sections CC' and D-D' of FIG. 2, and FIG. 4 is an explanatory diagram for stopping the operation of the metal vacuum tube shown in FIG.

In the electrostatic induction generator without a rotating body according to the present invention, the role of the vacuum tube is very important. However, with a conventional vacuum tube having a structure in which the anode attracts and absorbs hot electrons emitted from the cathode, the electrostatic induction generator without a rotating body according to the present invention cannot be operated.

Therefore, the present inventors have invented a metal vacuum tube of a new structure capable of operating the electrostatic induction generator without a rotating body according to the present invention as follows.

As shown in FIGS. 1 and 2, the metal vacuum tube applied to the present invention is formed of a metal that conducts electricity well instead of the glass tube of the conventional vacuum tube and forms the exterior of the metal vacuum tube (1A), the center of the metal tube provided in, for example, a metal rod 2 having a diameter of about 5 mm and a length of about 50 mm, a heat dissipating cathode 3, a heater 4, which are also disposed between the outer circumferential surface of the metal rod and the inner circumferential surface of the metal tube, It includes a heat dissipating cathode (5), a grid (6), and a metal mesh forest (7) that is electrically connected (8) and is fixed with multiple layers of metal mesh.

A circular insulating plate 9 is disposed at the lower end of the metal tube 1A, and a plurality of holes are formed in the insulating plate.

Through the hole, the terminal 13 of the metal rod, the terminal 12A of the heat dissipation type cathode, the terminals 10 and 11 of the heater, and the terminal 14 of the grid are exposed to the outside, and the hole is sealed.

The circular insulating plate 9 is sealed and fixed to the lower quay wall of the metal tube 1A so that a vacuum is well maintained.

Terminals 15A and 15B are also rolled up and placed on the outer upper end of the metal tube 1A.

The metal vacuum tube 1 has no relation to the frequency and the emission of hot electrons is important. Therefore, in order to obtain as many hot electrons as possible with the minimum heating power, a heater is inserted between the two heat dissipating cathodes in the metal vacuum tube 1 . A filament that directly emits hot electrons may be inserted instead of the heater. In addition, the cathode and the heater may be formed in a grid shape through which hot electrons can easily pass, such as a grid.

As described above, the metal vacuum tube 1 applied to the present invention is different from the conventional vacuum tube in structure, function, and role.

In order to understand the present invention, first, the function and role of the metal vacuum tube 1 should be accurately understood. Therefore, in the following, (A) the role of the metal rod, (B) the operation/stop operation of the metal rod and the metal vacuum tube of the grid, (C) the function and role of the metal mesh forest and the metal vacuum tube, etc. will be described in detail with reference to FIG. 3 do.

(A) Role of metal rods

The metal vacuum tube (1) has no anode and instead, the metal rod (2) charged with strong (-) electricity serves to push the emitted hot electrons to the metal mesh forest (7).

Here, the (-) electric force of the metal rod must extend beyond the grid (6), and the (-) electric force of the grid also serves to push the hot electrons into the metal mesh forest (7).

That is, since the positive electrode charged with (+) electricity attracts and absorbs hot electrons, in the metal vacuum tube 1 applied to the present invention, the metal rod 2 charged with (-) electricity is the center of the inside of the metal tube. It is erected on the ground and performs the function of pushing the hot electrons into the metal mesh forest.

(B) Operates and stops the metal rod and the metal vacuum tube of the grid

In order to operate and generate a static induction generator without a rotating body, the metal vacuum tube must be operated and stopped periodically.

Operating the metal vacuum tube means heating the heater 4 of the metal vacuum tube so that the hot electrons emitted from the two heat-dissipating cathodes 3 and 5 come out of the metal vacuum tube.

When stopping the metal vacuum tube, the principle method is to cut off the heating power of the heater so that hot electrons are not emitted. However, even if the heating power is cut off, since the heater and the cathode are maintained at high temperature for a while, the hot electron emission continues even though it is slightly reduced. Therefore, unless an innovative material that responds immediately to heating power is developed, a method for preventing hot electrons from flowing into the metal mesh forest 7 must be selected for now.

For example, as shown in FIG. 4 , if the (-) electricity of the grid is left as it is and the (-) electricity of the metal rod 2 is removed, the emitted hot electrons are pushed by the (-) electricity of the grid 6 . Since the grid cannot be crossed, the result is that the hot electrons are not emitted.

That is, the grid plays a role in pushing out the hot electrons emitted with the metal rods closer to the metal mesh forest than the metal rods into the metal mesh forest and preventing them from coming out of the metal mesh forest. However, the more important role of the grid is to stop the operation of the metal vacuum tube by preventing hot electrons from flowing into the metal mesh forest 7 . That is, the grid of the metal vacuum tube serves as the control grid of the existing three-pole vacuum tube.

As such, by adjusting the (-) electric force of the metal rod 2 and the grid 6, the metal vacuum tube 1 can be operated or stopped.

There is also a method to prevent the emission of hot electrons while maintaining the negative (-) electricity of the metal rod without removing it. The method is separately described in a section related to the method in the following description. That is, since the role of the metal rod has been described above, the method is separately described below.

(C) Role and function of metal mesh forest and metal vacuum tube (metal tube)

Before explaining the role and function of the metal mesh forest and the metal pipe, an example will be described to aid understanding.

When it rains on a bare mountain without a single grass, part of the rain seeps into the ground, but the rest flows down the mountain. However, when it rains on a mountain with a thick forest of trees, the rain soaks most of the leaves and trunks and seeps into the ground.

The metal mesh forest functions like a dense forest of trees in the mountains. In this sense, the name Metal Mesh Forest was created.

Therefore, when the hot electrons emitted from the two heat dissipating cathodes 3 and 5 are pushed by the (-) electricity of the metal rod 2 as shown in FIG. 3 and jump into the metal mesh forest 7 over the grid 6, the hot electrons are, the metal mesh forest It is attached to the metal mesh forest while passing through the first, second, and third metal meshes in turn.

The hot electrons that have not yet been able to stick to the metal mesh forest are pushed by the (-) electric force of the metal rods and grids, so they cannot come out of the metal mesh forest. come out

In other words, because of the characteristic that electricity exists only on the surface of the conductor, after the hot electrons jump into the metal mesh forest, they come out of the metal tube 1A by themselves without any help (an example of using this characteristic of electricity well is the Van der Graf device), This is why a metal tube should be used instead of a glass tube.

Hereinafter, an electrostatic induction generator without a rotating body according to the present invention using the metal vacuum tube 1 as described above will be described in detail.

5 to 7 are exemplary views for explaining an electrostatic induction generator without a rotating body according to the present invention. In particular, Fig. 5 shows a method of generating power when the A-side DC power supply 20A operates, Fig. 6 shows a method of generating power by the operation of the A-side metal vacuum tube, and Fig. 7 shows the operation of the B-side metal vacuum tube. Shows how development is made by

For convenience of explanation, hereinafter, eight electrodes constituting four capacitors of the same type/equivalent amount are denoted as C _A1 , C _A2 , C _A3 , C _A4 , C _B1 , C _B2 , C _B3 , C _B4 , and C _A1 The side of , C _A2 , C _A3 , C _A4 is described as the A side, and the side of C _B1 , C _B2 , C _B3 , C _B4 is described as the B side.

The direction marks of '←' and '→', marked on the two metal vacuum tubes 1 and 1', mean the direction in which hot electrons flow when the metal vacuum tube operates. In the description of FIGS. 1 to 4, reference numeral 1 is used because one metal vacuum tube is used. It is denoted by reference numeral 1, and the other metal vacuum tube, that is, the B-side metal vacuum tube, is denoted by reference numeral 1'.

The metal vacuum tube through which hot electrons flow in the '→' direction is called the A-side metal vacuum tube (1), and the metal vacuum tube in the '←' direction is called the B-side metal vacuum tube (1'). Here, the terminal 12A of the cathode of the A-side metal vacuum tube 1 is connected to C _A4 , the upper terminal 15A is connected to C _B4 , and the terminal 12B of the cathode of the B-side metal vacuum tube 1' is It is connected to C _B4 , and the external terminal 15B is connected to C _B4 .

In this case, the terminal of the metal rod, the terminal of the heater, and the terminal of the grid are connected to a separate device.

That is, the metal vacuum tubes on the A and B sides are connected to C _A4 and C _B4 with different directions, and C _A1 and C _B1 are connected with one conductor 16 .

C _A2 and C _A3 are connected to the primary coil 18A of the A-side transformer 17A, and C _B2 and C _B3 are connected to the primary coil 18b of the B-side transformer 17B.

That is, the primary coils of the A and B side transformers also serve as the primary coils of the transformer. However, the more important role of the primary coil of the A and B side transformers is to connect the A and B side capacitors in series, so that the electricity generated from the A and B side capacitors is transferred to the secondary coils of the A and B side transformers (19A, 19B) to deliver it.

Finally, the (+) pole of the A-side DC power supply (20A) is connected to C _A1 , the (-) pole is connected to C _A4 , and the (+) pole of the B-side DC power supply (20B) is connected to C _B1 . and (-) pole is connected to C _B4 .

As shown in Fig. 5, when the _A -side DC power supply is turned on and C _A1 is charged with (+) electricity and C _A4 with (-) electricity, (-) electricity and ( +) electricity, C _A3 generates (+) electricity and (-) electricity. In this case, the (-) electricity of C _A2 and the (+) electricity of C _A3 are attracted to the (+) electricity of C _A1 and the (-) electricity of C _A4 and remain, but the (+) electricity of C _A2 and C _A3 The (-) electricity of are attracted to each other, and accordingly, a current flows in the direction of C _A2 to C _A3 in the primary coil 20A of the A-side transformer.

This phenomenon continues until the voltage of the A-side capacitor is equal to the voltage of the A-side DC power supply 20A. When charging is finished, open the A-side DC power switch 21A and operate the A-side metal vacuum tube 1 as shown in FIG. 6 to generate (-) electricity from C _A4 outside the A-side metal vacuum tube (1). When it flows to _B4 and is charged, the (+) electricity of C _A3 , which was receiving the (-) electric attraction of C _A4 , escapes from the (-) electric attraction of C _A4 , and draws the (-) electricity of C _A2 , and the (-) electricity of C _A2 The (+) electricity of C _A1 , which was receiving (-) electrical attraction, escapes from _{the (-) electrical attraction of C A2} and flows to C _B1 along the conductor (16).

In this case, the (+) electricity of C _A3 deviating from the (-) electric attraction of C _A4 and the (-) electricity of C _A2 deviating from the (+) electric attraction of C _A1 are attracted to each other and the primary coil of the A-side transformer In (18A), the current flows in the direction from C _A3 to C _A2 opposite to the previous one, so the current flowing in the primary coil is alternating current.

While the A-side metal vacuum tube continues to operate, the (-) electricity of C _A4 flows to C _B4 and the (+) electricity of C _A1 flows to C _B1 and is charged. Accordingly, as shown in FIG. 6, (+) electricity and (-) electricity in C _B3 , which receives (-) electricity of C _B4 , and (-) electricity and (+) electricity in C _B2 , which receives (+) electricity of C _B1 . Occurs due to induction. In this case, the (+) electricity of C _B3 and the (-) electricity of C _B2 are attracted to the (-) electricity of C _B4 and the (+) electricity of C _B1 , but the (-) electricity of C _B4 and C _B1 The (-) electricity of C _B3 and the (+) electricity of _{C B2} , _pushed by the (+) electricity of

By the way, if you open the sluice gate of a lake full of water, the water flows out violently for a while, but it gets weaker over time, and it takes a long time for it to flow completely.

Similarly, when operating the A-side metal vacuum tube (1), for the first time, the (-) electricity of C _A4 and the (+) electricity of C _A1 flow strongly to C _B4 and C _B1 , but as time passes, it becomes weaker. It takes a long time (thousands or tens of thousands of seconds in an electronic circuit is a long time) until it flows completely. Therefore, it is more efficient in terms of output to generate new electricity by operating the B-side metal vacuum tube 1' when there is little electricity left in the A-side capacitor.

Therefore, when there is some electricity left in the A-side capacitor, the A-side metal vacuum tube 1 is stopped, the _B -side DC power switch _21B is closed, and the insufficient amount of (+) electricity and (-) Add electricity first and then open the B-side DC power switch. In this case, as shown in FIG. 7 , when the B-side metal vacuum tube is operated, the (-) electricity of C _B4 flows to C _A4 , so the (+) electricity of C _B3 deviating from the (-) electrical attraction of C _B4 is The (-) electricity of C _B2 is drawn, and the (+) electricity of C _B1 , which escapes from the (-) electricity of C _B2 , flows to C _A1 .

In this case, the (-) electricity of C _B4 and the (+) electricity of C _B1 are attracted to each other and the (+) electricity of C _B3 and (-) electricity of C _B2 , which escapes from the attractive force of C B1, are attracted to the primary coil (18B) of the B-side transformer. ), the current flows in the direction from C _B3 to C _B2 opposite to the previous one, so the current flowing in the primary coil is alternating current.

On the other hand, while the B-side metal vacuum tube 1' is operating, in the A-side vacuum tube, the (-) electricity of C _B4 and the (+) electricity of C _B1 flow to C _A4 and C _A1 and charge, and the (-) of C _A4 In C _A3 receiving electric force, (+) electricity and (-) electricity are generated, and in C _A2 receiving (+) electric attraction of C _A1 , (-) electricity and (+) electricity are generated by electrostatic induction. In this case, the (+) electricity of C _A3 and the (-) electricity of C _A2 are attracted to the (-) electricity of C _A4 and (+) electricity of C _A1 and remain, but the (-) electricity of C _A3 and C _A2 The (+) electricity of (+) is attracted to each other, and current flows in the direction of C _A2 to C _A3 in the primary coil (18A) of the A-side transformer opposite to the previous one.

This phenomenon occurs simultaneously in the capacitors on the A and B sides while the B-side metal vacuum tube 1' is operating, and also simultaneously occurs in the A and B-side capacitors when the A-side metal vacuum tube 1 is operated.

However, since neither A nor B side is initially charged, it is different in that the A side DC power supply 20A is first charged, and the insufficient amount is supplemented with the B side DC power supply 20B.

Therefore, once power generation starts, the already charged electricity is generated by going back and forth between the A and B capacitors due to the periodic operation/stop action of the A and B side metal vacuum tubes. , it should be supplemented little by little with the B-side DC power supply (20A, 20B).

In the above, it has been described that the (-) _electricity of the metal _rod must be removed to stop the metal vacuum tube. The vacuum tube may be stationary. That is, the metal vacuum tube can also be stopped by putting a switch between C _A4 and 12A and between C _B4 and 12B to block electrons from flowing into the A and B side metal vacuum tubes.

As described above, in the present invention, the A and B side metal vacuum tubes, the A and B side capacitors, and the A and B side transformers become a trinity, so that the electrostatic induction generator according to the present invention is a rotor, that is, a rotating body can develop without it.

In order to explain the electrostatic induction generator without a rotating body, it is necessary to understand the metal vacuum tube first, so the metal vacuum tube was explained in detail. However, the transformer is equally important.

Accordingly, the transformer is described in detail below.

In general, a transformer serves to increase or decrease the AC voltage. However, the transformer applied to the electrostatic induction generator without a rotating body according to the present invention does not play a role of raising or lowering the AC voltage, but uses the mutual induction action of the primary and secondary coils to generate electricity from the A and B side capacitors. It serves as an external transmission.

Therefore, electricity generated from the A and B side capacitors must flow well without any resistance in the primary coils of the A and B side transformers, so that the electrostatic induction action occurs well so that a large output can be transmitted to the outside. This can be easily understood through the example below.

When exhaust gas generated from combustion is well discharged from the cylinder (cylinder) of the power engine of the vehicle, the power engine can generate output properly and the driving speed can be increased. However, if the exhaust gas is not well discharged, combustion (burning of fuel) in the cylinder does not work well, so the output of the power engine is reduced and the running speed of the vehicle is also slowed down.

The same is true for electrostatic induction generators without a rotating body. That is, in the electrostatic induction generator without a rotating body, electricity generated by the electrostatic induction action must flow through the primary coils of the A and B side transformers well, so that the electrostatic induction action occurs well and a large output can be obtained.

However, when alternating current flows through the coil, inductive reactance (the resistance of the coil to the alternating current) occurs, and thus the coil prevents the alternating current from flowing. In particular, since the inductive reactance increases in proportion to the frequency, it is difficult for a high-frequency alternating current to flow through the coil.

Therefore, since the electrostatic induction generator without a rotating body generates high-frequency power to obtain a large output, the inductive reactance generated in the primary coils 18A and 18B of the A and B-side transformers must be solved. This problem can be solved through various methods.

For example, if capacitors 22A and 22B of suitable capacity are connected in series with the primary coil of a transformer to generate series resonance, the inductive reactance and capacitive reactance themselves are not extinguished, but may be extinguished. Accordingly, the problem of inductive reactance that prevents alternating current from flowing in the coil can be solved without difficulty.

In addition, the electrical resistance of the conductor wire of the coil can also be zero when a superconductor is used. By doing this, the combined resistance (impedance) of the coil to alternating current can be zero. In this case, the impedance does not necessarily have to be zero, and the impedance can be made zero without difficulty by the methods as described above.

As the impedance approaches 0, the efficiency of the transformer applied to the present invention may be improved, and when the impedance becomes 0, the efficiency of the transformer becomes the maximum. In addition, even if the conductor is not a superconductor, the thickness of the conductor wire of the coil is formed as thick as possible, and when the temperature is lowered as much as possible, the electrical resistance of the conductor wire of the coil may also be close to zero.

In addition, the impedance of the secondary coils 19A, 19B of the transformer is also preferably zero or minimized through this method.

Hereinafter, a formula for calculating the output generated by the electrostatic induction generator as described above is described.

In the electrostatic induction generator as described above, four capacitors of the same type/same quantity are divided into A and B side by two and connected in series, and if the capacity of one of the capacitors is C, the combined capacity of the capacitors connected in series is C/2 am. Therefore, below, by citing the formula of the amount of electrical energy stored in the capacitor (W = ½ CV ² [J]), the basic formula of the output of the electrostatic induction generator according to the present invention is derived.

Because neither A nor B side is charged before power generation starts, the capacitor must be charged using DC power first. Therefore, if (+) and (-) electricity are charged to C _A1 and C _A4 with the A-side DC power supply (20A) with a voltage of V, the A and B side Since the combined capacity of the capacitor is C/2, the amount of electrical energy stored in the A-side capacitor is

W _A =¼ CV ² [J].

In this case, for convenience of explanation, it is assumed that (+) electricity and (-) electricity charged from the A side DC power supply 100% of the A and B side without loss due to the operation of the A and B side metal vacuum tubes (1, 1'). Assume

Looking closely at the A side of FIG. 5, when charging with the A-side DC power source, the (+) electricity of C _A2 and the (-) electricity of C _A3 are pushed by the (+) and (-) electricity of C _A1 and C _A4 . Since the amount of electrical energy can be considered as 1/2 of the amount of electrical energy stored in the A-side capacitor, the amount of electrical energy flowing through the primary coil 18A of the A-side transformer is,

W _A =½ x ¼CV ² = ⅛CV ² [J].

Next, by operating the A-side metal vacuum tube (1), the (-) electricity of _CA4 and the (+) electricity of _CA1 all flow to C _B4 and C _B1 , then the (-) electricity of C _A4 and the (+) electricity of C _A1 The (+) electricity of C _A3 and the (-) electricity of C _A2 , which escape from the electric force, also flow in the primary coil of the A-side transformer. That is, 1/2 of the amount of electrical energy stored in the A-side capacitor flows to the B side, and the amount of electrical energy flowing into the primary coil of the A-side transformer is also 1/2,

W _A =½ x ¼CV ² = ⅛CV ² [J].

Therefore, when charging the A-side capacitor with A-side DC power and operating the A-side metal vacuum tube, the sum of the amount of electrical energy through the primary coil 18A of the A-side transformer is,

W _A =⅛CV ² + ⅛CV ² = ¼CV ² [J].

Then, when the A-side metal vacuum tube is operated, the (-) electricity of C _A4 and the (+) electricity of C _A1 flow to C _B4 and C _B1 and are charged. When charging the A-side capacitor with the A-side DC power supply (19A) Similarly, the amount of electric energy flowing through the primary coil (18B) of the B-side transformer is,

W _B = ½ x ¼CV ² = ⅛CV ² [J].

And, if the B-side metal vacuum tube 1B is operated after the B-side is charged, 1/2 of the amount of electrical energy stored in the B-side capacitor flows to the A-side as in the case of operating the A-side metal vacuum tube 1A, The amount of electric energy flowing through the primary coil of the B-side transformer is also 1/2,

W _B =½ x ¼CV ² = ⅛CV ² [J].

Therefore, the sum of the amount of electrical energy flowing twice through the primary coil 18B of the B-side transformer is,

W _B =⅛CV ² + ⅛CV ² = ¼CV ² [J].

And, while the metal vacuum tube on the B side is operating, the (-) electricity of C _B4 and the (+) electricity of C _B1 flow to C _A4 and C _A1 and are charged. amount flows through the primary coil (18A) of the A-side transformer. That is, before starting power generation, electricity is initially charged from the A-side DC power supply. However, when power generation starts, the charged electricity periodically moves back and forth between A and B sides due to the operation/stop action of the A and B side metal vacuum tubes. Accordingly, power generation occurs while electrostatic induction occurs on the A and B sides.

Therefore, when the A and B side metal vacuum tubes operate once, the total amount of electric energy flowing through the primary coils 18A and 18B of the A and B side transformers is,

W _A+B = ¼CV ² + ¼CV ² = ½CV ² [J].

Therefore, if the number of times that the A and B side metal vacuum tubes operated per second is N, respectively, and expressed in units of power,

P = ½CV ² N [W].

However, this is only a basic formula, and there are issues to consider when applying it in practice. That is, the output formula was derived under the assumption that the charged electricity flows 100% to and from A and B sides without loss, but as described above, in order to increase power generation efficiency, before 100% of the electricity stored in the A and B side capacitors flows. As it is a new development, these points must be taken into account.

The present applicant applied for an electrostatic induction generator without a rotating body and continued research even after being registered as Registration No. 2031665 (2019.10.07), dramatically increasing the output of the electrostatic induction generator without a rotating body, and using two transformers A method that can be shared as one was newly identified, 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. 8 to 10 .

8 is an exemplary view showing the configuration of an electrostatic induction generator without a rotating body according to the present invention, and in particular, is an exemplary view showing a method of generating power when the switch of the A-side high voltage DC power supply is closed. 9 is an exemplary view showing a method in which power is generated 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. 10 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. Accordingly, 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. In addition, 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. 8, six capacitors of the same type and of the same amount are divided into three on the A and B sides 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 bottom of the B side. Let's call them C _B1 , C _B2 , C _B3 , C _B4 , C _B5 , C _B6 .

The iron core and secondary coil of the A-side and B-side transformers are shared. And, in the present invention, although the A and B side primary coils of the upper and lower first and second transformers are separated from each other, this can also be shared.

As shown in FIG. 8 , the upper transformer is referred to as a first transformer 1 , and the lower transformer is referred to as a second transformer 2 . In Figs. 8, 9 and 10, the iron cores of the first transformer 1 and the second transformer 2 are separated from each other, but in reality, the iron cores are not separated and become one.

8, C _A2 and C _A3 are connected in series with the A-side primary coil 3 of the first transformer, and C _A4 and C _A5 are connected in series with the A-side primary coil 4 of the second transformer connected, C _B5 and C _B4 are connected in series with the B-side primary coil 5 of the first transformer, and C _B3 and C _B2 are connected in series with the B-side primary coil 6 of the second transformer .

In addition, the terminal 8 of the heat dissipation cathode (cathode) of the A side metal vacuum tube 7 is connected to C _A6 , the external terminal 9 is connected to C _B6 , and the heat dissipation type cable of the B side metal vacuum tube 10 is connected to C A6. The terminal 11 of the sword (cathode) is connected to C _B6 , the external terminal 12 is connected to C _A6 , and C _A1 and C _B1 are connected with the conducting wire 13 .

And, the + pole of the A-side high-voltage DC power source 14 is connected to C _A1 , the - pole is connected to C _A6 , the + pole of the B-side high-voltage DC power supply 15 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 8, when the switch 16 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 the electrostatic induction action, -Electricity is attracted to C _A1 's + electricity and remains in C _A2 , and + electricity flows along the A-side primary coil (3) of the first transformer while being pushed to C _A3 to be 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 + electricity of C _A4 that is pushed by + electricity of C _A3 , current flows in the direction of C _A4 to C _A5 in the A-side primary coil 4 of the second transformer.

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, the switch 16 of the A-side high-voltage DC power supply is turned off as shown in FIG. 9 . At the same time, the A-side metal vacuum tube (7) 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 7). 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 primary coil 4 of the second transformer and is neutralized with the - electricity of C _A4 , the -electric attraction of C _A4 The + electricity of C _A3 deviating from ? flows to C _A2 along the A side primary coil 3 of the first transformer, and is neutralized with - electricity of C _A2 . Therefore, since the direction of the current flowing in the A-side primary coils 4 and 3 of the second and first transformers is opposite to the previous one, it is AC.

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 13 and is charged. Therefore, -, + electricity is generated in C _B2 due to electrostatic induction, 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 second transformer. If it flows along the B-side primary coil (6) to C _B3 and is charged, electrostatic induction also occurs in C _B4 , so -electricity remains in C _B4 , and +electricity is the B-side primary coil of the first transformer. According to (5), 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 7 and operate the B-side metal vacuum tube 10 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 small amount of -,+ electricity remains in C _A6 and C _A1 , stop the A-side metal vacuum tube and close the switch 17 of the B-side high-voltage DC power supply 15 (on) to remain 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 10 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 force of C _B6 flows to C _B4 along the B-side primary coil 5 of the first transformer and is neutralized with the - electricity of C _B4 , the - electricity of C _B4 The + electricity of C _B3 escaping from the attractive force flows to C _B2 along the B-side primary coil 6 of the second transformer, and is neutralized with - electricity of C _B2 .

Accordingly, the + electricity of C _B1 escaping from the -electric attraction of C _B2 flows to C _A1 along the conductor 13 and is charged. In this case, too, in order to increase the power generation efficiency, when a little - and + electricity remain in C _B6 and C _B1 , the operation of the B-side metal tube 10 is stopped and the A-side metal vacuum tube 7 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.

In addition, the direction of the current flowing in the A-side primary coils 3 and 4 of the first and second transformers is the same as the direction of the current flowing in the B-side primary coils 5 and 6 of the first and second transformers. It is expressed in the above description and in FIGS. 9 and 10 . Since the direction of the current is the same as described above, the iron core and the secondary coils 18 and 19 of the first and second transformers may be shared, and the primary coil may also be shared.

Like the output formula described above with reference to FIGS. 1 to 7, in the present invention, the formula for the amount of electrical energy stored in the capacitor, that is,

By citing W =½CV ² [J], the basic formula of the output is derived and organized.

If the capacity of one of the six capacitors of the same type and the same amount constituting the electrostatic induction generator without a rotating body according to the present invention is C, the three capacitors are divided into A and B sides and connected in series, so the A and B side Each capacitor has a combined capacity of C/3.

When a voltage of V is applied by connecting the + pole to C _A1 and the - pole to C _A6 of the A-side high voltage DC power supply 14 of FIG. 8 , the amount of electrical energy stored in the A-side capacitor in which three capacitors are connected in series is,

CV² [J] 이다. W _A =⅓ x ½CV ² =

CV ² [J].

And, the + and - electricity charged in C _A1 and C _A6 with the A-side high-voltage DC power supply, for convenience of explanation, all of the electricity of C _A1 and C _A6 is converted to C _B1 and C _B6 by the operation of the A and B side metal vacuum tubes. It is assumed that electricity flows without loss and is charged, and then all of the electricity of C _B1 and C _B6 flows to C _A1 and C _A6 without loss as well, and the charging action is repeated to generate power.

If + and - electricity are charged to C _A1 and C _A6 with A-side high-voltage DC power supply, electrostatic induction occurs in C _A2 and C _A5 , and - electricity of C _A2 is attracted by the + electricity of C _A1 and remains in C _A2 . , C _A2 + electricity is pushed by + electricity of C _A1 , flows along the A-side primary coil 3 of the first transformer, and flows to C _A3 to be charged. In this case, -, + electricity is generated by electrostatic induction in C _A4 as well, so - electricity is attracted by + electricity of C _A3 , and + electricity is pushed by + electricity of C _A3 .

And, when -electricity is charged in C _A6 , + and - electricity is generated in C _A5 by electrostatic induction, and + electricity is attracted by - electricity of C _A6 and remains in C _A5 , and - electricity is transferred to - electricity of C _A6 . As they are pushed, the + electricity of C _A4 and the + electricity are attracted to each other, so the + electricity of C _A4 flows along the A side primary coil 4 of the first transformer in the direction of C _A5 and is neutralized with the - electricity of C _A5 .

At this time, one of the two electricity of + and - generated by electrostatic induction on each plate remains in each plate and the other flows to the outside. That is, 1/2 remains in each pole plate and 1/2 flows to the outside along the A-side primary coils 3 and 4 of the first and second transformers, so the amount of electrical energy flowing to the outside is, [Equation 1 ] is the same as

This phenomenon continues until the voltage of the A-side high-voltage DC power supply is equal to the voltage charged in the A-side capacitor. After charging is completed, turn off the switch 16 and simultaneously operate the A-side metal vacuum tube 7 to flow - and + electricity from C _A6 and C _A1 to C _B6 and C _B1 to charge C _A2 , C _A3 , The + and - electricity of 1/2 remaining in C _A4 , C _A5 also flows in the opposite direction to the previous one along the A-side primary coils 4 and 3 of the first and second transformers. At this time, the amount of electrical energy flowing to the A-side primary coil of the first and second transformers is as [Equation 2].

Therefore, the total of the electric energy flowing in the A-side primary coils 3 and 4 of the first and second transformers is as shown in [Equation 3].

This phenomenon continues while the metal vacuum tube 7 on the A side is operating, and when all the - and + electricity of C _A6 and C _A1 flows to C _B6 and C _B1 and is charged, the A side high voltage DC power supply C _A1 and C As in the case of charging _A6 , the amount of electrical energy flowing to the B-side primary coils 5 and 6 of the first and second transformers is the same as [Equation 4].

10, when the B-side metal vacuum tube 10 is operated, the amount of electrical energy flowing to the B-side primary coils 6 and 5 of the first and second transformers is also [ Equation 5].

Therefore, the total amount of electric energy flowing through the B-side primary coil of the first and second transformers is also the same as [Equation 6].

Therefore, the sum of the amount of electrical energy flowing through the primary coils 3, 4, 5, and 6 of the A and B sides of the first and second transformers is,

W _A+B = [Equation 3] + [Equation 6] = 1/6 CV ² + 1/6 CV ² = 1/3 CV ² [J].

If this is expressed in units of power (P) as N is the number of times that the metal vacuum tubes on the A and B sides operate per second,

P = 1/3 CV ² N[W].

Therefore, if 2n capacitors of the same type and the same amount are divided in half on the A and B sides, that is, divided by n and connected in series, the power (P) is,

P = 1/n CV ² N[W]. This is the basic formula for calculating the power (output) of the electrostatic induction generator without a rotating body of the present invention.

However, for convenience of explanation, when the A-side metal vacuum tube is operating, all _-electricity of C _A6 flows to C _B6 without loss and is _charged . The basic formula for power (output) was derived by assuming that electricity is generated by repeating the action of flowing and charging, but in reality, in order to increase the power generation efficiency, when a little electricity remains in C _A6 and C _B6 , Since electricity is generated by periodically operating metal vacuum tubes alternately, the basic formula must be applied in consideration of these points.

However, looking at the basic formula alone, if n capacitors of the same type and quantity are connected in series, it is easy to mistakenly think that the power (output) decreases to 1/n because the capacity is reduced to 1/n. However, considering that the capacitance is reduced to 1/n when n capacitors are connected in series, the reduced capacitance can be compensated by connecting capacitors having a sufficiently large capacity in series or in series and parallel. Also, since the frequency can be raised when the capacity is reduced, the reduced capacity can be compensated for by these various methods such as raising the frequency. And, the voltage of the output formula is the voltage applied by increasing the total voltage when n capacitors are connected in series with a high voltage DC power supply. Therefore, unlike the output formula alone, the actual output is proportional to the capacity and frequency, and in particular, the output is larger than expected because it is proportional to the square of the total voltage (V ² ) applied to the high voltage DC power supply.

As such, the role of voltage in the output of an electrostatic induction generator without a rotating body is very important. Therefore, the voltage will be described in more detail.

In order to increase the voltage, the insulating ability of the insulator (dielectric) of the capacitor must be strengthened. However, there is a limit to the current insulating ability of the insulator to increase the voltage without fear of breaking the insulation no matter how much the insulating ability is strengthened. Therefore, it is currently possible to apply a high voltage without worrying about insulation breakdown by connecting n capacitors in series and distributing a high voltage to each capacitor along with strengthening the insulating ability of the insulator to reduce the voltage across each n capacitors to 1/n. the most ideal way possible. Therefore, by applying a very high voltage in this way, no matter how large an output can be obtained as desired.

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: A side metal vacuum tube (or metal vacuum tube) 1': B side metal vacuum tube
1A: metal tube 2: metal rod
3: Cathode 4: Heater
5: heat dissipation cathode 6: grid
7: Metal Mesh Forest

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 fifth capacitors C _B3 , C provided on the B side _B4 ) and the sixth capacitor (C _B5 , C _B6 ) is connected to the first transformer (1);
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 fourth capacitors C _B1 , C provided on the B side _B2 ) and a fifth capacitor (C _B3 , C _B4 ) and connected to, the second transformer (2) connected to the first transformer (1);
A-side metal vacuum tube (7) made of metal, one end connected to the third capacitor (C _A5 , C _A6 ), and the other end connected to the sixth capacitor (C _B5 , C _B6 ) ; and
B-side metal vacuum tube (10) made of metal, one side connected to the sixth capacitor (C _B5 , C _B6 ), and the other side 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 primary coil 3 of the first transformer 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 primary coil 4 of the second transformer 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 primary coil 5 of the first transformer 1,
A rotating body in which 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 primary coil 6 of the second transformer 2 . No static induction generator. The method of claim 1,
The terminal 8 of the heat-dissipating cathode (negative electrode) of the A-side metal vacuum tube 7 is connected to the second terminal C _A6 of the third capacitor, and the external terminal 9 is the second terminal of the sixth capacitor connected to terminal (C _B6 ),
The terminal 11 of the heat dissipation type cathode (negative electrode) of the B-side metal vacuum tube 10 is connected to the second terminal C _B6 of the sixth capacitor, and the external terminal 12 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 (13). The method of claim 1,
The + pole of the A-side high voltage DC power supply 14 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 source 15 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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