RU2509388C2 - Resonant electric capacitor by strebkov-podosinnikov (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: in an electric capacitor comprising plates in the form of tapes from conducting material, a layer of a film dielectric arranged between plates, and electrodes connected to plates and external leads of the capacitor, the electric capacitor comprises two plates with three electrodes. The first electrode is connected to the middle of the first plate, and the second plate has two electrodes connected to the ends of the plate.

EFFECT: reduced energy costs for generation of electromagnetic waves and losses during transfer of electric energy.

11 cl, 4 dwg

Description

The invention relates to the field of electrical engineering, in particular to the field of resonant high-frequency electric capacitors for converting and transmitting electrical energy. Known electric capacitor, consisting of two oppositely charged conductors, while the charge that must be transferred from one conductor to another in order to charge one of them negatively, and the other positively, is called the charge of the capacitor. The potential difference U between the capacitor plates is directly proportional to the value of the charge Q located on each of them: Q = CU.

The parameters, design and scope of electric capacitors are determined by the dielectric dividing its plates, so the main classification of electric capacitors is carried out by the type of dielectric. Depending on the type of dielectric used, electric capacitors can be air, paper, mica, ceramic, electrolytic, etc.

By capacitance, electric capacitors of constant capacitance are distinguished and capacitors of variable capacitance. Variable capacitors and semi-variable capacitors are manufactured with mechanically and electrically controlled capacitance. A change in capacitance in an electric capacitor with mechanical control is most often achieved by changing the area of its plates or by changing the gap between the plates. The simplest air capacitor of variable capacity consists of two isolated systems of metal plates that enter each other when the handle is rotated: one group (rotor) can move so that its plates go into the gaps between the plates of another group (stator). By pushing and pulling one plate system into another, you can change the capacitance of the capacitor. Electric capacitors of variable capacitance with a solid dielectric (ceramic, mica, glass, film) are mainly used as semi-variable (subscript) with a relatively small change in capacitance. (Lit.: Renne V.T. Electric capacitors, 3rd ed., L., 1969).

An electric capacitor is used as a passive electronic component at frequencies f <f _p , at which its resistance is capacitive in nature, where f _p is the resonant frequency.

Typically, the maximum operating frequency of an electric capacitor is capacitive (http://m.wikipedia.org/wiki/capacitor).

A disadvantage of the known electric capacitors is the equality of voltages on the plates and the impossibility of changing the voltage at the electrodes in resonant single-wire lines.

Another disadvantage of the known electric capacitors is the impossibility of using them in resonant high-voltage high-frequency waveguide lines as a receiver, transmitter or converter of capacitive reactive currents and bias currents in a single-wire line or a single-line conducting channel in the mode of voltage resonance or current resonance.

The objective of the invention is the creation of multi-electrode electric capacitors for operation in transmitting, converting and receiving circuits and in single-wire lines. The technical result consists in reducing energy costs for the generation of electromagnetic waves and losses in the transmission of electrical energy.

The technical result is achieved by the fact that in the electric capacitor Strebkov-Podosinnikov containing plates in the form of strips of conductive material, a layer of film dielectric located between the plates, and electrodes connected to the plates and external terminals of the capacitor, the electric capacitor contains two plates with three electrodes, moreover, the first electrode is attached to the middle of the first plate, and the second plate has two electrodes attached to the ends of the plate.

In the design variant of the Strebkov-Podosinnikov electric capacitor, the first and second plates with a dielectric layer are enclosed in a shielding housing of conductive material with three holes for the external terminals of three electrodes enclosed in dielectric bosses.

In another design variant of the Strebkov-Podosinnikov electric capacitor, containing plates in the form of tapes of conductive material, insulated by a film dielectric, and electrodes connected to the plates and to the external terminals of the capacitor, the Strebkov-Podosinnikov electric capacitor contains four identical areas and sizes of wraps wound around the dielectric coil, the first and second plates have one electrode each, the electrode of the first plate is located in the inner space of the coil, and the electrode is W A swarm of plates is installed in the outer space of the coil, and the third and fourth plates have two electrodes, the second, third and fourth plates are connected in series so that the electrode of the second plate, located in the outer space of the coil, is connected to the inner electrode of the third plate with two electrodes, in which the outer electrode is connected to the inner electrode of the fourth two-electrode plate, and the inner electrode of the fourth two-electrode plate and the electrode of the first plate to external terminals for switching to single-wire line.

In the design variant of the Strebkov-Podosinnikov electric capacitor, all four plates with a film dielectric are placed in a shielded housing made of conductive material.

In a design variant of the Strebkov-Podosinnikov electric capacitor, the shielded housing has six holes for the external terminals of six electrodes enclosed in dielectric bosses.

In another design variant of the Strebkov-Podosinnikov electric resonant capacitor, containing plates in the form of tapes of a conductive material, insulated by a film dielectric, and electrodes connected to the plates and to the external terminals of the capacitor, the Strebkov-Podosinnikov electric capacitor contains four identical areas and sizes of the plate wound on the dielectric coil, the first, second and fourth plates have one electrode each, and the third plate contains two electrodes, one of which is Inonii electrode with the second electrode and the other electrode the second electrode and the first electrode plate are connected to external terminals of the capacitor for switching in the two-wire circuit, and the fourth electrode is connected to the middle electrode of the fourth electrode and connected to an external terminal of the capacitor for switching in a single line.

In the design variant of the Strebkov-Podosinnikov electric capacitor, all four plates with a film dielectric are placed in a shielded housing made of conductive material.

In yet another embodiment of the Strebkov-Podosinnikov electric capacitor design, the shielded case has five bushing insulators for the external leads of five electrodes from four capacitor plates.

In the embodiment of the design of the Strebkov-Podosinnikov electric capacitor, containing plates in the form of tapes of conductive material, insulated by a film dielectric, and electrodes connected to the plates, the Strebkov-Podosinnikov electric capacitor contains four insulated plates of the same area and size, wound on a dielectric coil , all four plates contain one electrode each, the electrodes of the first and third plates and the electrodes of the second and fourth plates are connected to external Water capacitor for switching in a two-wire circuit.

In the embodiment of FIG. 1, all four film dielectric plates are housed in a shielded housing of conductive material.

In the design variant of the Strebkov-Podosinnikov electric resonant capacitor, the shielded case has four external terminals with bushing insulators connected to four electrodes from four capacitor plates.

The essence of the proposed device is illustrated in figures 1 to 8, where figure 1 shows the General diagram of the electric resonant three-electrode capacitor Strebkov-Podosinnikov using two insulated insulator plates, one of which has two electrodes for connection to a closed electrical circuit, figure 2 presents mock-up of a resonant three-electrode capacitor in the form of two copper tapes and a film dielectric wound around a coil, Fig. 3 shows a mock-up of a resonant three-electrode capacitor a torus enclosed in a metal screen for shielding stray electromagnetic noise, figure 4 shows a block diagram of an electrical resonant capacitor Strebkov-Podosinnikov using four insulated insulator plates with six electrodes, figure 5 - design of a resonant electric capacitor Strebkov-Podosinnikov with four plates and six electrodes, Fig.6 is a block diagram of an electrical resonant capacitor Strebkov-Podosinnikov with four plates and five electrodes , Fig.7 is a diagram of the inclusion of an electric resonant capacitor with four electrical plates and five electrodes in the electric network, Fig.8 is a block diagram of an electrical resonant capacitor Strebkov-Podosinnikov with four plates and four electrodes.

The electrical resonant three-electrode capacitor Strebkov-Podosinnikov on the block diagram of figure 1 contains an electrode 1, symmetrically connected at a point 2 in the middle of the plate 3, which is isolated by a layer of film dielectric 4 from the plate 5, to the ends of which 6 and 7 are connected two electrodes 8 and 9 .

Figure 2 presents the design of the three-electrode resonant electric capacitor Strebkov-Podosinnikov. On a coil 10 made of a dielectric material with an axial hole 11 for outputting an electrode 8 connected to the beginning 6 of the two-electrode plate 5, the plates 5 and 3 are wound in the form of tapes of conductive material, separated by a film dielectric 4 connected to the ends of the plate 5 electrodes 8 and 9 and to the middle of the lining 3 of the electrode 1.

Figure 3 shows the design of the three-electrode electrical resonant capacitor Strebkov-Podosinnikov in a shielding housing 17 made of conductive material, where dielectric bosses 14 with the ends of the conductive electrodes 1, 8, 9 of the resonant capacitor plates enclosed in shielding housing to reduce spurious electromagnetic noise.

The block diagram of the resonant electric capacitor Strebkov-Podosinnikov in figure 4 contains four plates 15, 16, 17 and 18, isolated from each other by layers of film dielectric 4. The first plate 15 has one electrode 19 connected to the middle of the plate 15. The second plate 16 also has one electrode 20 attached to the end of the plate 16. The third plate 17 has two electrodes 21 and 22 connected to the ends of the plate. The fourth plate 18 also has two electrodes 23 and 24 attached to the end and to the middle of the plate 18. The second plate 16 is connected to the third plate 17 by means of a jumper 25, and the third plate 17 is connected to the fourth plate 18 by means of a jumper 26.

The design of the Strebkov-Podosinnikov resonant electric capacitor in FIG. 5 contains a dielectric coil 27, in which the beginnings of four plates 15, 16, 17 and 18 are fixed in slit-like openings 28 in the form of copper foil tapes with insulation between the plates with a dielectric layer 4 of polypropylene tapes. The electrode 29 of the first one-electrode plate 15 is located in the inner space of the electric coil 27. The second one-electrode plate 16 has an electrode 20 located in the outer space of the coil 27, which is switched by a jumper 25 with the electrode 21 of the third two-electrode plate 17, the second electrode 22 is connected by a jumper 26 with the electrode 23 the fourth two-electrode plate 18, the output electrode 24 is attached to the middle of the plate 18.

In the block diagram of the resonant electric capacitor Strebkov-Podosinnikov in Fig.6, the first, second and fourth plates 28, 29, 30 contain one electrode 31, 32 and 33, and the third plate 34 contains two electrodes 35 and 36, electrode 35 of the plate 34 connected to the electrode 32 of the second plate 29. The second electrode 36 of the plate 34 is connected to the external terminal 37 of the capacitor, the electrode 31 of the first plate 28 is connected to the external terminal 38 of the capacitor. The external terminals 37 and 38 are intended for connection to an external two-wire network 39. The electrode 33 of the fourth plate is connected to the external terminal 40 of the single-wire line 41 (Fig. 7).

Fig. 7 as an example of application shows a block diagram of the inclusion of two resonant electric capacitors 42 and 43 in the connection diagram of two two-wire lines 39 and 44 with a high-frequency generator 45 and an electric load 46 connected by a single-wire line 41.

The block diagram of the electric resonant capacitor in Fig. 8 contains four plates 47, 48, 49, 50 of the same area and size, isolated by thin layers of dielectric 4 and containing one electrode 51, 52, 53, 54. The electrode 51 of the first plate 47 and the electrode 53 of the third plate 49 are connected to the external terminals 55 and 56, and the electrode 52 of the second plate 48 and the electrode 54 of the fourth plate 50 are connected to the external terminals 57 and 58 for switching in a two-wire high-frequency line 59, at the beginning of which a high-frequency generator 60 is installed, and at the end line 59 - e electric load 61.

Example 1 of the execution of the resonant electric capacitor Strebkov-Podosinnikov

On a dielectric coil 10 with a diameter (FIG. 2) D = 100 mm, a height of 150 mm, with an axial hole of 11 3.5 mm for outputting the electrode 9, wound through a polypropylene film dielectric 4 25 micron thick plates 3 and 5 of a resonant electric three-electrode capacitor Strebkov- Podosinnikov in the form of strips 50 microns thick, 120 mm high and 600 m long made of conductive material (copper foil), with one lining having two electrodes 8 and 9 soldered to the beginning and end of this tape, and the second lining has one conductive electrode in the middle one.

Example 2 of the resonant electric capacitor Strebkov-Podosinnikov

Four tapes 15, 16, 17, 18 of length 800 m, height 0.1 m and thickness 50 microns, made of copper foil and insulated from each other by a film of propylene dielectric 4 with a thickness of 50 microns, are wound on a coil 27 of dielectric. The designs of the electric resonant capacitors are shown in detail in FIGS. 3 and 5.

The electrical resonant high-frequency multi-electrode capacitor Strebkov-Podosinnikov works as follows. An electric charge from a single-wire line or a single-line conducting channel in the mode of voltage resonance or current resonance through the input electrode (Fig. 4) accumulates on the plate 15 and through the film dielectric 4 generates a charge of the opposite sign on the plates 16, 17, 18, connected in a certain way by jumpers 25, 26. The charge transformed by sign and voltage is removed from the electrode 24.

Essentially a resonant capacitor is a device that combines the features of a transformer and a capacitor operating in resonant open circuits. The resonant electric capacitor Strebkov-Podosinnikov represents an analogue of the resonance high-frequency transformer N. Tesla and, unlike the transformer N. Tesla, has a large distributed capacitance and mutual inductance of the plates, therefore, has a lower resonant frequency.

The electrical resonant capacitors of Strebkov-Podosinnikov are designed to work in single-wire high-frequency lines (Figs. 4 and 5), in two-wire high-frequency lines (Fig. 7) and for matching and communication of single-wire and two-wire high-frequency lines (Figs. 1, 3, 6 and 7 ) The capacitor in figure 4 and 5 provides a three-fold increase in the input voltage due to a three-fold increase in the number and area of plates in the input and output circuits. When the capacitor is turned on in the opposite direction, if the input and output terminals are interchanged, the output voltage will be three times less than the input voltage. The capacitor in Fig.6 and 7 has an internal capacitive coupling between the plates 28, 29 and 34. The capacitor in Fig.8 is an analogue of a capacitive transformer for galvanic isolation of two-wire high-frequency lines.

Claims (11)

1. An electric capacitor containing plates in the form of tapes of conductive material, a layer of a film dielectric located between the plates, and electrodes connected to the plates, characterized in that the electric capacitor contains two plates with three electrodes, the first electrode being connected to the middle of the first plate and the second plate has two electrodes attached to the ends of the plate. 2. The electric capacitor according to claim 1, characterized in that the first and second plates with a dielectric layer are enclosed in a shielding housing of conductive material with three holes for outputting three electrodes enclosed in dielectric bosses. 3. An electric capacitor containing plates in the form of tapes of a conductive material, insulated by a film dielectric, and electrodes connected to the plates and to the external terminals of the capacitor, characterized in that the electric capacitor contains four identical areas and sizes of the plates wound on a dielectric coil, the first and the second plates have one electrode each, the electrode of the first plate is located in the inner space of the coil, and the electrode of the second plate is installed in the outer space of the coil, and the third and fourth plates have two electrodes each, the second, third and fourth plates are connected in series so that the electrode of the second plate located in the outer space of the coil is connected to the inner electrode of the third plate with two electrodes, in which the external electrode is connected to the inner electrode of the fourth two-electrode plate, and the inner electrode of the fourth two-electrode plate and the electrode of the first plate are connected to the external terminals of the capacitor for switching in a single-wire bottom of the line. 4. The electric capacitor according to claim 3, characterized in that all four plates with a film dielectric are placed in a shielded housing of conductive material. 5. The electric capacitor according to claim 4, characterized in that the shielded housing has six holes for the external terminals of the six electrodes enclosed in dielectric bosses. 6. An electric resonant capacitor containing plates in the form of tapes of a conductive material, insulated with a film dielectric, and electrodes connected to the plates and to the external terminals of the capacitor, characterized in that the electric capacitor contains four identical areas and sizes of the plates wound on a dielectric coil, the first, second and fourth plates have one electrode each, and the third plate contains two electrodes, one of which is connected to the electrode of the second plate, and the other electrode of the second the plates and the electrode of the first plate are connected to the external terminals of the capacitor for switching in a two-wire circuit, and the electrode of the fourth plate is connected to the middle of the fourth plate and connected to the external terminal of the capacitor for switching in a single-wire line. 7. The electric capacitor according to claim 6, characterized in that all four plates with a film dielectric are placed in a shielded housing of conductive material. 8. The electric capacitor according to claim 7, characterized in that the shielded case has five bushing insulators for the external terminals of five electrodes from four capacitor plates. 9. An electric capacitor containing plates in the form of tapes of a conductive material, insulated with a film dielectric, and electrodes connected to the plates, characterized in that the electric capacitor contains four insulated from each other plates of the same area and size, wound on a dielectric coil, all four the plates contain one electrode each, the electrodes of the first and third plates and the electrodes of the second and fourth plates are connected to the external terminals of the capacitor for switching in a two-wire circuit pi. 10. The electric resonant capacitor according to claim 9, characterized in that all four plates with a film dielectric are placed in a shielded housing made of conductive material. 11. The electric resonant capacitor according to claim 10, characterized in that the shielded case has four external terminals with bushing insulators connected to four electrodes from four capacitor plates.

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