KR101473177B1 - transmission line for capacitively coil with planar structure - Google Patents

Abstract

A transmission line of a capacitive coil having a flat plate-like structure according to the present invention includes: a plurality of first conductive plates arranged in a horizontal axis and a vertical axis; A plurality of second conductive plates disposed on upper, lower, right, and left sides of the plurality of first conductive plates, respectively, and arranged alternately with a plurality of first conductive plates arranged in the horizontal axis and the vertical axis; A plurality of dielectrics disposed on each layer in a structure in which the plurality of first conductive plates and the plurality of second conductive plates are alternately arranged alternately in the horizontal axis and the vertical axis direction and stacked in multiple layers; And a plurality of second conductive plates disposed between the plurality of first conductive plates and the plurality of second conductive plates so as to surround the plurality of first conductive plates and the plurality of second conductive plates, And an insulator for insulating the plurality of second conductor plates from each other. According to the present invention, by using the transmission line of the capacitive coil having the dielectric and the insulator having the capacitance (C) component in the line itself, it is possible to generate the resonant frequency without installing a separate capacitor as in the conventional method, The loss of the current can be minimized by compensating the line voltage drop due to the inductance L on the capacitor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission line for a capacitive coil having a planar structure,

The present invention relates to a transmission line of a capacitive coil having a planar structure, and more particularly to a transmission line of a capacitive coil having a planar structure. More particularly, the present invention relates to a transmission line of a capacitive coil having a planar structure, And a transmission line of the capacitive coil.

As an alternative to pollution prevention and reliance on petroleum energy, hybrid cars have been developed that selectively use electricity-driven electric vehicles and electric and internal combustion engines.

However, the electric vehicles and plug-in hybrid vehicles developed so far must be connected to an external power supply device for a long time by using a plug or the like in order to charge the battery, and the distance that can be operated by only one charge is very limited .

Therefore, in recent years, as an alternative to an electric vehicle using a battery, a magnetic induction type electric vehicle has been highlighted.

A self-induction type electric vehicle essentially requires a feed path (or a feed rail) for supplying electricity. In order to charge the electric power required for the electric vehicle (or electric train) of this type, it is sufficient to travel on the power supply road. That is, when electric power of high frequency is supplied to the feeder line while the vehicle runs on the feeder road, electric power is supplied to the electric vehicle by the principle of electromagnetic induction between the feeder cable and the current collector installed in the electric vehicle.

In order to supply electric power to such a feeder road, a large number of inverters must be provided. Since the inverter has a large price depending on the capacity, it is necessary to efficiently wire the feeder line so as to supply a small amount of electric power to one inverter.

On the other hand, if the feeder line is long, the self-inductance of the feeder line increases and the resistance becomes large. Therefore, the current does not flow well even if the same current flows, and it is not economical to send a large voltage to flow the target current. Therefore, in order to solve the problem caused by the length of the feeder line, a plurality of resonant capacitors are installed, thereby compensating for the voltage due to the inductance in the feeder line and lowering the voltage.

However, in order to install a plurality of resonance capacitors, it is difficult to arrange the resonance capacitors and the wiring becomes complicated. As a result, processes for installing the resonance capacitors are increased, and the operation time is greatly increased. Moreover, there is also a problem that the resonance capacitor is required to have a space as much as the size of the resonance capacitor, and the cost is increased by the amount.

KR 10-1133517 B1

SUMMARY OF THE INVENTION The present invention has been made to overcome the above problems, and it is an object of the present invention to provide a transmission line of a capacitive coil having a dielectric and an insulator having a capacitance C component in a line itself to generate a resonance frequency, And to compensate the line voltage drop due to the voltage drop (L) of the capacitive coil.

According to an aspect of the present invention, there is provided a transmission line of a capacitive coil having a planar structure, comprising: a plurality of first conductive plates disposed in a transverse axis and a longitudinal axis; A plurality of second conductive plates disposed on upper, lower, right, and left sides of the plurality of first conductive plates, respectively, and arranged alternately with a plurality of first conductive plates arranged in the horizontal axis and the vertical axis; A plurality of dielectrics disposed on each layer in a structure in which the plurality of first conductive plates and the plurality of second conductive plates are alternately arranged alternately in the horizontal axis and the vertical axis direction and stacked in multiple layers; And a plurality of second conductive plates disposed between the plurality of first conductive plates and the plurality of second conductive plates so as to surround the plurality of first conductive plates and the plurality of second conductive plates, And an insulator for insulating the plurality of second conductor plates from each other.

According to the present invention, by using the transmission line of the capacitive coil having the dielectric and the insulator having the capacitance (C) component in the line itself, it is possible to generate the resonant frequency without installing a separate capacitor as in the conventional method, The loss of the current can be minimized by compensating the line voltage drop due to the inductance L on the capacitor.

1 is a perspective view showing a power line of a capacitive coil having a planar structure according to an embodiment of the present invention;
Fig. 2 is a front view of a power line of a capacitive coil having a planar structure in Fig. 1; Fig.
3 is a view showing an equivalent circuit of a power line of a capacitive coil having a planar structure in Fig.
Fig. 4 is a diagram showing an example of a capacitance simulation result for a power line of a capacitive coil having a planar structure in Fig. 1; Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

FIG. 1 is a perspective view showing a power line of a capacitive coil having a planar structure according to an embodiment of the present invention, FIG. 2 is a front view of a power line of a capacitive coil having a planar structure in FIG. 1, 1 shows an equivalent circuit of a power line of a capacitive coil having a flat plate-like structure.

As shown, the power line of the capacitive coil having the planar structure of the present invention includes a plurality of first conductive plates 10, a plurality of second conductive plates 20, a dielectric 30, an insulator 40 ).

The plurality of first conductor plates 10 and the second conductor plates 20 are arranged vertically and horizontally to each other. The thicknesses of the first conductor plates 10 and the second conductor plates 20, The width can be varied and placed.

That is, the plurality of first conductor plates 10 and the second conductor plates 20 are alternately arranged alternately at a predetermined interval in the horizontal axis and the vertical axis direction, and have a laminated structure. The plurality of first conductive plates 10 and the second conductive plates 20 may be made of a metal plate, for example. In addition, a series-parallel circuit can be combined at a connection portion where a plurality of first conductor plates 10 and second conductor plates 20 are connected to each other.

A plurality of first conductor plates 10 and second conductor plates 20 are separated from each other. In order to reduce (alleviate) the skin effect of the power line of the capacitive coil having a planar structure, The width and thickness of the inner and outer conductor plates can be configured differently. For example, the width of the conductor plate located at the inner side in the horizontal axis direction of the power line of the capacitive coil having the flat plate-like structure is narrowed, the width of the conductor plate located at the outer side is widened, The thickness of the conductive plate located at the inner side in the longitudinal axis direction is made thinner and the thickness of the conductive plate located at the outer side is made thick, thereby reducing (alleviating) the skin effect and making the current density uniform.

The dielectric body 30 is disposed between the layers in the laminated structure of the first conductor plate 10 and the second conductor plate 20 arranged alternately in the horizontal axis and the vertical axis direction and is made of aluminum oxide, Barium, potassium dihydrogenphosphate, tantalum, polyester, polypropylene, and the like. This dielectric 30 increases the capacitance value of the capacitive coil.

The first conductor plate 10 and the second conductor plate 20 are surrounded by the insulator 40 and the insulator 40 includes the first conductor plate 10 and the second conductor plate 20 , And between the plurality of dielectrics 30. This insulator 40 serves to increase the capacitance value of the capacitive coil as well as the dielectric 30.

As shown in Fig. 3, the equivalent circuit of the power line of the capacitive coil having the flat plate-like structure is represented by L ₁ L _{2 ...} L _{n -1} L _n denotes the inductance of n first conductor plates 10, and L ₁ 'L ₂ ' _... L _{n -1} 'L _n ' represents the inductance of the n second conductive plates 20, and C _{1 ...} C _2n represents the inductances of the n first conductive plates 10 and the n second And the capacitance due to the dielectric 30 or the insulator 40 disposed between the conductor plates 20. Here, each C value is calculated by the following equation (1).

Where A is the cross-sectional area of the conductor plate, d is the distance between the conductor plates, and? _R is the dielectric constant of the dielectric (30) or insulator (40) between the conductor plates.

The power line of the capacitive coil having the planar structure of the present invention having such a structure is different from the prior art in which a capacitor is separately installed in the line for compensating the line voltage drop due to the inductance L on the line, A transmission line of a capacitive coil provided with a dielectric 30 and an insulator 40 having a capacitance C component is used to generate a resonance frequency without installing a separate capacitor as in the prior art, The loss of the current can be minimized by compensating the line voltage drop due to the inductance (L).

FIG. 4 is a graph showing an example of a capacitance simulation result for a power line of a capacitive coil having a planar structure in FIG. 1, wherein the length of a power line of the capacitive coil used in the simulation is 45 cm, (4 cm * 2 cm).

As shown, the horizontal axis represents frequency (unit: [MHz]) and the vertical axis represents reactance (unit: [Ohm]).

In the figure, the black line A represents the amount of change of the reactance component of a conventional power line composed of the same size metal conductor, and the red line B represents the amount of change of the reactance component of the capacitive coil of the planar type of the present invention Represents the amount of change of the reactance component of the power line of the capacitive coil.

In the following, a black line A indicating a change amount of a reactance component of a conventional power line composed of a metal conductor of the same size and a black line A indicating a change amount of a reactance component of a power line of a planar type capacitive coil The red line B representing the change amount of the red line B is compared and the result will be described.

As described in the power line structure of the planar type capacitive coil of the present invention, capacitive reactance (X _C ) having a minus (-) component by a dielectric and an insulator disposed between a plurality of conductor plates, Is added to the power line of the capacitive coil, the black line A indicating the change amount of the reactance component is lowered to the red line B. At this time, the resonance frequency at which the reactance value becomes 0 in the red line B is 3.1 [MHz], and the change amounts of the reactance components of the black line A and the red line B at the resonance frequency 3.1 [MHz] Represents a change in capacitive reactance (X _C ) of -13.8 [OMEGA], which is a negative value since the line A falls to the red line B.

That is, the capacitive reactance (X _C ) of the power line of the capacitive coil of the present invention can be expressed by the following equation (1).

The total capacitance of the power line of the capacitive coil of the present invention, which is calculated by substituting the resonance frequency in Equation (1), is shown in Equation (2).

As can be seen from the simulation results, it is possible to calculate the capacitive reactance component value and the resonant frequency, and thereby it is possible to calculate the capacitance value of the power line of the capacitive coil.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

10: first conductor plate
20: second conductor plate
30: Dielectric
40: Insulator

Claims (5)

As a transmission line of a capacitive coil having a flat plate-like structure,
A plurality of first conductive plates arranged in a horizontal axis and a vertical axis;
A plurality of second conductive plates disposed on upper, lower, right, and left sides of the plurality of first conductive plates, respectively, and arranged alternately with a plurality of first conductive plates arranged in the horizontal axis and the vertical axis;
A plurality of dielectrics disposed on each layer in a structure in which the plurality of first conductive plates and the plurality of second conductive plates are alternately arranged alternately in the horizontal axis and the vertical axis direction and stacked in multiple layers; And
A plurality of first conductive plates and a plurality of second conductive plates disposed between the plurality of first conductive plates and the plurality of second conductive plates so as to surround the plurality of first conductive plates and the plurality of second conductive plates, Each of the first and second conductor plates being insulated from each other,
Wherein the plurality of first conductive plates and the plurality of second conductive plates have different thicknesses and widths to reduce the skin effect of the transmission line.
The method according to claim 1,
Wherein the dielectric and the insulator disposed between the plurality of first conductor plates and the plurality of second conductor plates increase the capacitance value of the transmission line
And a transmission line of the capacitive coil having a flat plate-like structure.
The method of claim 2,
The dielectric and the insulator disposed between the plurality of first conductor plates and the plurality of second conductor plates act as a capacitive reactance (X _C ) component to increase the capacitance value of the transmission line
And a transmission line of the capacitive coil having a flat plate-like structure.
delete The method according to claim 1,
The width of the first conductor plate and the second conductor plate located at the inner side in the horizontal direction of the transmission line is narrow and the widths of the first conductor plate and the second conductor plate located at the outer side are wide, When the thicknesses of the first conductor plate and the second conductor plate are thin and the thicknesses of the first conductor plate and the second conductor plate located at the outer side are thick, the skin effect of the transmission line is reduced, and the current density of the transmission line is made uniform
And a transmission line of the capacitive coil having a flat plate-like structure.

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