JP2017022452A - Antenna device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an antenna device capable of controlling a direction in which an electromagnetic wave is strengthened or a direction in which an electromagnetic wave is suppressed.SOLUTION: An injection height of a conductive liquid A to be injected from an aperture plane 3a of a nozzle 3 is controlled into a height of a 1/4 wavelength in a frequency (f) of an electromagnetic wave subjected to radiation. An injection height of a conductive liquid B to be injected from an aperture plane of a nozzle 5 that is disposed in a hole 2 at a position of the 1/4 wavelength in the frequency (f) away from a hole 2 where the nozzle 3 is disposed, among a plurality of nozzles 5 is controlled into a height that is higher than the 1/4 wavelength in the frequency (f).SELECTED DRAWING: Figure 1

Description

  The present invention relates to an antenna device using a conductive liquid (hereinafter referred to as “conductive liquid”) as a radiating element.

2. Description of the Related Art In recent years, an antenna device using a conductive liquid as a radiating element has been attracting attention because an antenna having an arbitrary shape can be formed by passing a current through the conductive liquid.
Patent Document 1 below discloses an antenna device that operates as a monopole antenna or a dipole antenna by supplying power to a conductive liquid ejected linearly. In this antenna device, the operating frequency is adjusted by controlling the momentum at which the conductive liquid is ejected.

US2012 / 539834

  Since the conventional antenna device is configured as described above, it operates as a monopole antenna or a dipole antenna. However, basically, a non-directional radiation pattern is formed on the horizontal plane, and the directional radiation pattern is not formed in a desired direction. There was a problem that it was not possible.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain an antenna device capable of controlling the direction in which electromagnetic waves are strengthened and the direction in which the electromagnetic waves are suppressed.

  The antenna device according to the present invention has a ground conductor provided with a plurality of holes and an outer diameter smaller than a diameter of the plurality of holes provided in the ground conductor, and any one of the plurality of holes. A first conductor hollow tube that is arranged coaxially with the first hole and provided with a feeding point on the opening surface of the tip, and has an outer diameter equal to or larger than the diameter of the plurality of holes provided in the ground conductor A plurality of holes, the opening surface of the tip being arranged at a position that covers a hole different from the hole in which the first conductor hollow tube is arranged, and the plurality of second electrodes electrically connected to the ground conductor. 2 conductor hollow tubes are provided, and the liquid ejection control unit ejects the conductive liquid from the opening surfaces of the first and second conductor hollow tubes to the outside.

  According to the present invention, the outer conductor has an outer diameter that is thinner than the diameter of the plurality of holes provided in the ground conductor, and is arranged coaxially with any one of the plurality of holes, on the opening surface at the tip. The first conductor hollow tube provided with the feeding point and the outer diameter equal to or larger than the diameter of the plurality of holes provided in the ground conductor, and the first conductor hollow among the plurality of holes A liquid ejection control unit provided with a plurality of second conductor hollow tubes in which an opening surface at a tip is disposed at a position covering a hole different from the hole in which the tube is disposed and electrically connected to the ground conductor; However, since the conductive liquid is ejected to the outside from the opening surfaces of the first and second conductor hollow tubes, there is an effect that it is possible to control the direction in which the electromagnetic wave is strengthened or the direction in which the electromagnetic wave is suppressed.

It is a block diagram which shows the antenna apparatus by Embodiment 1 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 2 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 3 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 4 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 5 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 6 of this invention. It is a block diagram which shows the antenna apparatus by Embodiment 7 of this invention.

  Hereinafter, in order to describe the present invention in more detail, modes for carrying out the present invention will be described with reference to the accompanying drawings.

Embodiment 1 FIG.
1 is a block diagram showing an antenna apparatus according to Embodiment 1 of the present invention.
In FIG. 1, the ground conductor 1 is provided with a plurality of holes 2. In the example of FIG. 1, seven holes 2 are provided in a row.
The nozzle 3 is a first conductive hollow tube having an outer diameter smaller than the diameter of the hole 2 provided in the ground conductor 1, and is arranged coaxially with the hole 2 provided in the ground conductor 1.
Further, a feeding point 4 is provided on the opening surface 3 a of the nozzle 3.

  In FIG. 1, the feeding point 4 is schematically drawn in order to show the position to which the high-frequency voltage that is the source of the electromagnetic wave radiated from the antenna device is applied. It is not formed as a component. There are various methods for applying an actual high-frequency voltage. For example, an internal conductor (not shown) of a coaxial cable that transmits a high-frequency voltage output from a voltage source (not shown) is connected to the nozzle 3, A method of applying a high-frequency voltage by connecting an outer conductor (not shown) of the coaxial cable to the ground conductor 1 can be considered.

The nozzle 5 is a second conductor hollow tube having the same outer diameter as the hole 2 provided in the ground conductor 1, and has a tip at a position covering the hole 2 different from the hole 2 in which the nozzle 3 is disposed. The opening surface is arranged and is electrically connected to the ground conductor 1.
In the example of FIG. 1, the nozzle 5 has the same outer diameter as the hole 2 provided in the ground conductor 1, but if the hole 2 provided in the ground conductor 1 can be covered. Therefore, the outer diameter of the nozzle 5 may be larger than the diameter of the hole 2.

The pump 6 is a machine that supplies the conductive liquid A to the nozzle 3.
The pump 7 is a machine that supplies the conductive liquid B to the nozzle 5.
The pump drive unit 8 controls the supply amount of the conductive liquid A supplied from the pump 6 to the nozzle 3 and selects the pump 7 that supplies the conductive liquid B to the nozzle 5 from the plurality of pumps 7. This is an apparatus for controlling the supply amount of the conductive liquid B supplied from the selected pump 7 to the nozzle 5.
The pumps 6 and 7 and the pump drive unit 8 constitute a liquid ejection control unit.

Next, the operation will be described.
In the first embodiment, an example in which the conductive liquid A operates as a radiating element and suppresses electromagnetic waves radiated from the conductive liquid A to the conductive liquid B side will be described.
In the first embodiment, for convenience of explanation, among the plurality of holes 2 in which the nozzles 5 are arranged, the distance between the second hole 2 from the right in the figure and the hole 2 in which the nozzles 3 are arranged is as follows. It is assumed that the length is a quarter wavelength at the frequency f (operation frequency) of the electromagnetic wave to be radiated.
For this reason, in the following description, an example in which the conductive liquid B is ejected from the opening surface of the nozzle 5 disposed in the second hole 2 from the right in the figure will be described. If the distance between the first and third holes 2) and the hole 2 where the nozzle 3 is disposed is a length of a quarter wavelength at the frequency f of the electromagnetic wave to be radiated, the other holes 2 The conductive liquid B may be ejected from the opening surface of the nozzle 5 arranged in the nozzle.

The pump drive unit 8 drives the pump 6 to eject the conductive liquid A from the nozzle 3 to the outside.
At this time, since a high-frequency voltage is applied between the ground conductor 1 and the nozzle 3 from the feeding point 4, high-frequency power is supplied to the conductive liquid A operating as a radiating element.
In addition, the pump drive unit 8 controls the supply amount of the conductive liquid A supplied from the pump 6 to the nozzle 3, so that the ejection height of the conductive liquid A that is ejected from the opening surface 3 a of the nozzle 3 is the target of radiation. The height is adjusted to a quarter wavelength with the frequency f of the electromagnetic wave.
By adjusting the ejection height of the conductive liquid A to a height of a quarter wavelength at the frequency f, the conductive liquid A is in a resonance state, and therefore, an electromagnetic wave having a frequency f is emitted from the conductive liquid A.

The electromagnetic wave radiated from the conductive liquid A is radiated in each direction and also radiated to the conductive liquid B side. In this Embodiment 1, in order to suppress the electromagnetic wave radiated | emitted from the electroconductive liquid A to the electroconductive liquid B side, the pump drive part 8 is the hole 2 in which the nozzle 3 is arrange | positioned among the some pumps 7. FIG. Then, the pump 7 that supplies the conductive liquid B to the nozzle 5 disposed in the hole 2 at the position of the quarter wavelength at the frequency f of the electromagnetic wave to be radiated is selected. In the example of FIG. 1, the second pump 7 from the right is selected.
When the pump drive unit 8 selects the pump 7 that supplies the conductive liquid B to the nozzle 5, the pump drive unit 8 controls the supply amount of the conductive liquid B that is supplied from the pump 7 to the nozzle 5. The ejection height of the conductive liquid B ejected from is adjusted to a height higher than a quarter wavelength at the electromagnetic wave frequency f.

Since the conductive liquid B is a quarter wavelength away from the conductive liquid A at the frequency f of the electromagnetic wave, the electromagnetic wave radiated from the conductive liquid A is compared with the phase at the position of the conductive liquid A. The phase at the position of the conductive liquid B is delayed by about 90 degrees.
Moreover, since the ejection height of the conductive liquid B ejected from the opening surface of the nozzle 5 is higher than a quarter wavelength at the frequency f of the electromagnetic wave, the conductive liquid B becomes inductive. For this reason, the phase of the current flowing through the conductive liquid B due to the coupling with the conductive liquid A is delayed by about 90 degrees with respect to the conductive liquid A.
As a result, the conductive liquid B is subjected to a reverse phase current of −180 degrees at a maximum as compared with the conductive liquid A. Therefore, the conductive liquid B is radiated from the conductive liquid A to the conductive liquid B side. Acts to cancel out electromagnetic waves.

In this Embodiment 1, in order to suppress the electromagnetic wave radiated | emitted from the conductive liquid A to the conductive liquid B side, from the hole 2 in which the nozzle 3 is arrange | positioned among several pumps 7, the electromagnetic wave of radiation | emission object The pump 7 for supplying the conductive liquid B to the nozzle 5 disposed in the hole 2 at the position of the quarter wavelength with the frequency f is selected.
However, this is only an example. For example, when it is necessary to suppress electromagnetic waves radiated from the conductive liquid A in the left direction in the figure, among the plurality of pumps 7, from the hole 2 where the nozzle 3 is disposed. A pump 7 (second pump 7 from the left in the figure) for supplying the conductive liquid B to the nozzle 5 arranged in the hole 2 at the position of the quarter wavelength at the frequency f of the electromagnetic wave to be radiated By selecting and controlling the supply amount of the conductive liquid B supplied from the pump 7 to the nozzle 5, the ejection height of the conductive liquid B ejected from the opening surface of the nozzle 5 is set to 4 minutes at the frequency f of the electromagnetic wave. It may be adjusted to a height higher than one wavelength.

  As apparent from the above, according to the first embodiment, the liquid ejection control unit sets the ejection height of the conductive liquid A ejected from the opening surface 3a of the nozzle 3 to 4 minutes at the frequency f of the electromagnetic wave to be radiated. The opening of the nozzle 5 that is controlled to the height of one wavelength and is arranged in the hole 2 at the position of the quarter wavelength at the frequency f from the hole 2 in which the nozzle 3 is arranged among the plurality of nozzles 5. Since the ejection height of the conductive liquid B ejected from the surface is controlled to be higher than a quarter wavelength at the frequency f, the direction of suppressing the electromagnetic wave radiated from the conductive liquid A is controlled. There is an effect that can.

Embodiment 2. FIG.
2 is a block diagram showing an antenna apparatus according to Embodiment 2 of the present invention. In FIG. 2, the same reference numerals as those in FIG. 1 denote the same or corresponding parts.
In the first embodiment, the example of suppressing the electromagnetic wave radiated from the conductive liquid A to the conductive liquid B is shown. However, in the second embodiment, the conductive liquid A radiates from the conductive liquid C to the conductive liquid C side. An example of strengthening the electromagnetic waves that are generated will be described.

Next, the operation will be described.
The pump drive unit 8 drives the pump 6 to eject the conductive liquid A from the nozzle 3 to the outside.
At this time, since a high-frequency voltage is applied between the ground conductor 1 and the nozzle 3 from the feeding point 4, high-frequency power is supplied to the conductive liquid A operating as a radiating element.
In addition, the pump drive unit 8 controls the supply amount of the conductive liquid A supplied from the pump 6 to the nozzle 3, so that the ejection height of the conductive liquid A that is ejected from the opening surface 3 a of the nozzle 3 is the target of radiation. The height is adjusted to a quarter wavelength with the frequency f of the electromagnetic wave.
By adjusting the ejection height of the conductive liquid A to a height of a quarter wavelength at the frequency f, the conductive liquid A is in a resonance state, and therefore, an electromagnetic wave having a frequency f is emitted from the conductive liquid A.

The electromagnetic wave radiated from the conductive liquid A is radiated in each direction and is also radiated to the conductive liquid C side. In this Embodiment 2, in order to strengthen the electromagnetic wave radiated | emitted from the electroconductive liquid A to the electroconductive liquid C side, the pump drive part 8 is from the hole 2 in which the nozzle 3 is arrange | positioned among the some pumps 7. The pump 7 that supplies the conductive liquid C to the nozzle 5 disposed in the hole 2 at the position of the quarter wavelength at the frequency f of the electromagnetic wave to be radiated is selected. In the example of FIG. 2, the second pump 7 from the left is selected.
When the pump drive unit 8 selects the pump 7 that supplies the conductive liquid C to the nozzle 5, the pump drive unit 8 controls the supply amount of the conductive liquid C that is supplied from the pump 7 to the nozzle 5. The ejection height of the conductive liquid B ejected from is adjusted to a height lower than a quarter wavelength at the electromagnetic wave frequency f.

Since the conductive liquid C is a quarter wavelength away from the conductive liquid A at the frequency f of the electromagnetic wave, the electromagnetic wave radiated from the conductive liquid A is compared with the phase at the position of the conductive liquid A. The phase at the position of the conductive liquid C is delayed by about 90 degrees.
Moreover, since the ejection height of the conductive liquid C ejected from the opening surface of the nozzle 5 is lower than a quarter wavelength at the frequency f of the electromagnetic wave, the conductive liquid C becomes capacitive. For this reason, since the phase of the current flowing through the conductive liquid C due to the coupling with the conductive liquid A is a current close to the same phase as the conductive liquid A, the conductive liquid C is changed from the conductive liquid A to the conductive liquid C. It works to strengthen the electromagnetic wave radiated to the side.

In this Embodiment 2, in order to strengthen the electromagnetic waves radiated from the conductive liquid A to the conductive liquid C, the frequency of the electromagnetic waves to be radiated from the holes 2 in which the nozzles 3 are arranged among the plurality of pumps 7. The pump 7 that supplies the conductive liquid C to the nozzle 5 arranged in the hole 2 at the position of the quarter wavelength by f is selected.
However, this is only an example. For example, when it is necessary to strengthen the electromagnetic wave radiated from the conductive liquid A in the right direction in the figure, among the plurality of pumps 7, from the hole 2 where the nozzle 3 is disposed, Select the pump 7 (second pump 7 from the right in the figure) that supplies the conductive liquid C to the nozzle 5 arranged in the hole 2 at the position of the quarter wavelength at the frequency f of the electromagnetic wave to be radiated. Then, by controlling the supply amount of the conductive liquid C supplied from the pump 7 to the nozzle 5, the ejection height of the conductive liquid C ejected from the opening surface of the nozzle 5 is reduced to a quarter at the electromagnetic wave frequency f. The height may be adjusted to be lower than the wavelength.

  As apparent from the above, according to the second embodiment, the liquid ejection control unit sets the ejection height of the conductive liquid A ejected from the opening surface 3a of the nozzle 3 to 4 minutes at the frequency f of the electromagnetic wave to be radiated. The opening of the nozzle 5 that is controlled to the height of one wavelength and is arranged in the hole 2 at the position of the quarter wavelength at the frequency f from the hole 2 in which the nozzle 3 is arranged among the plurality of nozzles 5. Since the ejection height of the conductive liquid C ejected from the surface is controlled to be lower than the quarter wavelength at the frequency f, the direction in which the electromagnetic wave radiated from the conductive liquid A is strengthened can be controlled. There is an effect that can be done.

Embodiment 3 FIG.
3 is a block diagram showing an antenna apparatus according to Embodiment 3 of the present invention. In FIG. 3, the same reference numerals as those in FIGS. 1 and 2 denote the same or corresponding parts.
In the first embodiment, the electromagnetic wave radiated from the conductive liquid A to the conductive liquid B side is suppressed, and in the second embodiment, the electromagnetic wave radiated from the conductive liquid A to the conductive liquid C side is strengthened. An example is described.
In the third embodiment, an example will be described in which the electromagnetic wave radiated from the conductive liquid A to the conductive liquid B side is suppressed and the electromagnetic wave radiated from the conductive liquid A to the conductive liquid C side is strengthened.

Next, the operation will be described.
In order to suppress the electromagnetic wave radiated from the conductive liquid A to the conductive liquid B side, the pump drive unit 8 is a hole in which the nozzles 3 are arranged among the plurality of pumps 7 as in the first embodiment. 2, the pump 7 that supplies the conductive liquid B to the nozzle 5 disposed in the hole 2 at the position of the quarter wavelength at the frequency f of the electromagnetic wave to be radiated is selected. In the example of FIG. 3, the second pump 7 from the right is selected.
When the pump drive unit 8 selects the pump 7 that supplies the conductive liquid B to the nozzle 5, the pump drive unit 8 controls the supply amount of the conductive liquid B that is supplied from the pump 7 to the nozzle 5. The ejection height of the conductive liquid B ejected from is adjusted to a height higher than a quarter wavelength at the electromagnetic wave frequency f.
Thereby, the electromagnetic wave radiated from the conductive liquid A to the conductive liquid B side is suppressed by the conductive liquid B.

Since the pump drive unit 8 strengthens the electromagnetic wave radiated from the conductive liquid A to the conductive liquid C side, the hole 2 in which the nozzles 3 are arranged among the plurality of pumps 7 as in the second embodiment. From this, the pump 7 that supplies the conductive liquid C to the nozzle 5 disposed in the hole 2 at the position of the quarter wavelength at the frequency f of the electromagnetic wave to be radiated is selected. In the example of FIG. 3, the fourth pump 7 from the left is selected.
When the pump drive unit 8 selects the pump 7 that supplies the conductive liquid C to the nozzle 5, the pump drive unit 8 controls the supply amount of the conductive liquid C that is supplied from the pump 7 to the nozzle 5. The ejection height of the conductive liquid C to be ejected from is adjusted to a height lower than a quarter wavelength at the electromagnetic wave frequency f.
Thereby, the electromagnetic waves radiated from the conductive liquid A to the conductive liquid C side are strengthened by the conductive liquid C.

In the third embodiment, the pump driving unit 8 further selects the second pump 7 from the left in the drawing that is present from the conductive liquid A to the conductive liquid C side.
In the figure, the second pump 7 from the left passes the conductive liquid D from the hole 2 in which the nozzle 3 is disposed to the nozzle 5 disposed in the hole 2 located at a half wavelength at the frequency f. This is a pump 7 to be supplied.
When the pump drive unit 8 selects the pump 7 that supplies the conductive liquid D to the nozzle 5, the pump drive unit 8 controls the supply amount of the conductive liquid D that is supplied from the pump 7 to the nozzle 5. The ejection height of the conductive liquid D to be ejected from is adjusted to a height lower than a quarter wavelength at the electromagnetic wave frequency f.
Thereby, like the conductive liquid C, the conductive liquid D acts to strengthen the electromagnetic waves radiated from the conductive liquid A to the conductive liquid C.
As a result, the directivity of the electromagnetic wave radiated from the conductive liquid A to the conductive liquid C side becomes sharper than that in the second embodiment, so that the gain can be increased.

Embodiment 4 FIG.
In the first to third embodiments, the plurality of holes 2 provided in the ground conductor 1 are arranged in a line. However, the holes 2 in which the nozzles 3 are arranged are centered on the concentric circles. A plurality of holes 2 may be provided in the ground conductor 1.
4 is a block diagram showing an antenna apparatus according to Embodiment 4 of the present invention. In FIG. 4, the same reference numerals as those in FIG. 1 denote the same or corresponding parts.
In FIG. 4, the pumps 6 and 7 and the pump drive unit 8 are omitted for simplification of the drawing, but the pump 6 is connected to the nozzle 3, and the pump 7 is connected to each nozzle 5. The pump drive unit 8 is connected to the pumps 6 and 7.

In the fourth embodiment, a plurality of holes 2 are concentrically provided in the ground conductor 1 with the hole 2 in which the nozzle 3 is disposed as a central axis, and the frequency from the hole 2 in which the nozzle 3 is disposed. There are also a plurality of nozzles 5 arranged concentrically in the hole 2 at the position of the quarter wavelength of f.
Therefore, the nozzle 5 arranged in the direction in which the electromagnetic wave needs to be suppressed is selected from the plurality of concentric nozzles 5 arranged in the hole 2 at the position of the quarter wavelength with the frequency f. If the pump 7 for supplying the conductive liquid B to the nozzle 5 is controlled and the ejection height of the conductive liquid B is adjusted to a height higher than a quarter wavelength by the frequency f of the electromagnetic wave, any horizontal plane can be obtained. The electromagnetic wave in the direction can be suppressed.
Further, among the plurality of nozzles 5 on the concentric circle, the nozzle 5 arranged in the direction in which the electromagnetic wave needs to be strengthened is selected, and the pump 7 that supplies the conductive liquid C to the nozzle 5 is controlled, and the conductivity If the ejection height of the ionic liquid C is adjusted to a height lower than a quarter wavelength at the frequency f of the electromagnetic wave, the electromagnetic wave in an arbitrary direction on the horizontal plane can be strengthened.

Embodiment 5. FIG.
5 is a block diagram showing an antenna apparatus according to Embodiment 5 of the present invention. In FIG. 5, the same reference numerals as those in FIG.
The ground conductor 11 is provided with a hole 12 (first hole) in the central axis of the concentric circle, and a hole 13 (second hole) in which a plurality of divided holes 13a are arranged on the line of the concentric circle.
FIG. 5 shows an example in which the holes 13 are provided on two concentric lines, but the holes 13 may be provided on three or more concentric lines.
The outer diameter of the nozzle 3 is smaller than the diameter of the hole 12 and is arranged coaxially with the hole 12.
The nozzle 15 is a flat nozzle and is a second conductor hollow tube having the same outline as the divided hole 13 a provided in the ground conductor 1. The nozzle 15 is electrically connected to the ground conductor 1 with an opening surface at the tip disposed at a position covering the divided hole 13a.
In the example of FIG. 5, the nozzle 15 has the same outline as the divided hole 13 a provided in the ground conductor 1. However, the nozzle 15 covers the divided hole 13 a provided in the ground conductor 1. Since it should just be possible, the outline of the nozzle 15 may be larger than the dividing hole 13a.
In FIG. 5, the pumps 6 and 7 and the pump drive unit 8 are omitted for simplification of the drawing, but the pump 6 is connected to the nozzle 3, and the pump 7 is connected to each nozzle 15. The pump drive unit 8 is connected to the pumps 6 and 7.

Next, the operation will be described.
In the fifth embodiment, an example will be described in which the conductive liquid A operates as a radiating element, and an electromagnetic wave radiated from the conductive liquid A to the opposite side of the conductive liquid E is strengthened.
In the fifth embodiment, the holes 13 are provided on two concentric circle lines. For convenience of explanation, the distance from the central axis of the inner concentric circle is a quarter wavelength at the frequency f of the electromagnetic wave to be radiated. It is assumed that the length is
For this reason, in the following description, an example in which the conductive liquid E is ejected from the opening surface of the nozzle 15 disposed in the inner concentric dividing hole 13a will be described. However, the distance from the central axis of the outer concentric circle is As long as the frequency f of the electromagnetic wave to be radiated is a quarter wavelength, the conductive liquid E may be ejected from the opening surface of the nozzle 15 disposed in the outer concentric dividing hole 13a. .

The pump drive unit 8 drives the pump 6 to eject the conductive liquid A from the nozzle 3 to the outside.
At this time, since a high-frequency voltage is applied between the ground conductor 1 and the nozzle 3 from the feeding point 4, high-frequency power is supplied to the conductive liquid A operating as a radiating element.
In addition, the pump drive unit 8 controls the supply amount of the conductive liquid A supplied from the pump 6 to the nozzle 3, so that the ejection height of the conductive liquid A that is ejected from the opening surface 3 a of the nozzle 3 is the target of radiation. The height is adjusted to a quarter wavelength with the frequency f of the electromagnetic wave.
By adjusting the ejection height of the conductive liquid A to a height of a quarter wavelength at the frequency f, the conductive liquid A is in a resonance state, and therefore, an electromagnetic wave having a frequency f is emitted from the conductive liquid A.

The electromagnetic wave radiated from the conductive liquid A is radiated in each direction and is also radiated to the conductive liquid E side. In the fifth embodiment, in order to increase the electromagnetic wave radiated from the conductive liquid A to the opposite side of the conductive liquid E, the pump drive unit 8 relates to the nozzle 15 disposed in the inner concentric division hole 13a. Among the plurality of pumps 7, two or more pumps 7 related to the nozzles 15 arranged in the divided holes 13a on the conductive liquid E side are selected. In the example of FIG. 5, six pumps 7 in the right direction in the drawing are selected.
When the pump drive unit 8 selects the pump 7 that supplies the conductive liquid E to the nozzle 15, the pump drive unit 8 controls the supply amount of the conductive liquid E that is supplied from the pump 7 to the nozzle 15. The ejection height of the conductive liquid E to be ejected from is adjusted to a height higher than a quarter wavelength at the electromagnetic wave frequency f.

Since the conductive liquid E is a quarter wavelength away from the conductive liquid A at the frequency f of the electromagnetic wave, the electromagnetic wave radiated from the conductive liquid A is compared with the phase at the position of the conductive liquid A. The phase at the position of the conductive liquid E is delayed by about 90 degrees.
Moreover, since the ejection height of the conductive liquid E ejected from the opening surface of the nozzle 15 is higher than a quarter wavelength at the frequency f of the electromagnetic wave, the conductive liquid E becomes inductive. For this reason, the phase of the current flowing through the conductive liquid E due to the coupling with the conductive liquid A is delayed by about 90 degrees with respect to the conductive liquid A.
As a result, the conductive liquid E is subjected to a maximum reverse phase current of −180 degrees as compared with the conductive liquid A. Therefore, the conductive liquid E is emitted from the conductive liquid A to the conductive liquid E side. It acts to reflect the electromagnetic wave.

If there is only one nozzle 15 that ejects the conductive liquid E, the action of canceling out the electromagnetic waves radiated from the conductive liquid A to the conductive liquid E side is limited as in the first embodiment. Since there are a plurality of nozzles 15 that eject the conductive liquid E, when the wall-shaped conductive liquid E is formed, the action of simply canceling the electromagnetic waves radiated from the conductive liquid A to the conductive liquid E side The electromagnetic wave radiated from the conductive liquid A to the conductive liquid E side is reflected so as to reflect.
Since the electromagnetic wave reflected by the conductive liquid E is in phase with the electromagnetic wave radiated from the conductive liquid A to the opposite side of the conductive liquid E, the electromagnetic wave is emitted from the conductive liquid A to the opposite side of the conductive liquid E. The electromagnetic wave is strengthened.
Therefore, according to the fifth embodiment, by appropriately selecting the nozzle 15 that ejects the conductive liquid E, the direction in which the electromagnetic wave radiated from the conductive liquid A is strengthened can be controlled in an arbitrary direction on the horizontal plane. There is an effect that can be done.
When only one nozzle 15 is ejecting the conductive liquid E, the area where the conductive liquid E is formed is small, so that the electromagnetic wave reflection action is small, but the area of the opening surface of the nozzle 15 is large. Thus, even when only one nozzle 15 is ejecting the conductive liquid E, the electromagnetic wave reflection effect can be increased. Therefore, in this case, the electromagnetic wave can be reflected even if the number of pumps 7 selected by the pump driving unit 8 is one.

Embodiment 6 FIG.
In Embodiments 1 to 5 described above, the antenna device capable of controlling the direction in which the electromagnetic wave is strengthened and the direction in which the electromagnetic wave is suppressed has been described. However, the usable band of the radiated electromagnetic wave may be widened.

6 is a block diagram showing an antenna apparatus according to Embodiment 6 of the present invention. In FIG. 6, the same reference numerals as those in FIG.
The ground conductor 21 is provided with a hole 22 (first hole) and a hole 23 (second hole). The distance between the hole 22 and the hole 23 is equal to or shorter than the length of 1/8 wavelength at the frequency f of the electromagnetic wave to be radiated.
The outer diameter of the nozzle 3 is smaller than the diameter of the hole 22 and is arranged coaxially with the hole 22.
The nozzle 5 has the same outer diameter as the hole 23, and an opening surface at the tip is disposed at a position covering the hole 23 and is electrically connected to the ground conductor 21.
In the example of FIG. 6, the nozzle 5 has the same outer diameter as the hole 23, but the outer diameter of the nozzle 5 is larger than the diameter of the hole 23 as long as the hole 23 can be covered. It may be.

Next, the operation will be described.
The pump drive unit 8 drives the pump 6 to eject the conductive liquid A from the nozzle 3 to the outside.
At this time, since a high-frequency voltage is applied between the ground conductor 1 and the nozzle 3 from the feeding point 4, high-frequency power is supplied to the conductive liquid A operating as a radiating element.
In addition, the pump drive unit 8 controls the supply amount of the conductive liquid A supplied from the pump 6 to the nozzle 3, so that the ejection height of the conductive liquid A that is ejected from the opening surface 3 a of the nozzle 3 is the target of radiation. The height is adjusted to a quarter wavelength with the frequency f of the electromagnetic wave.
By adjusting the ejection height of the conductive liquid A to a height of a quarter wavelength at the frequency f, the conductive liquid A is in a resonance state, and therefore, an electromagnetic wave having a frequency f is emitted from the conductive liquid A.

The pump drive unit 8 drives the pump 7 to eject the conductive liquid F from the nozzle 5 to the outside.
In addition, the pump drive unit 8 controls the supply amount of the conductive liquid F supplied from the pump 7 to the nozzle 5, thereby setting the ejection height of the conductive liquid F ejected from the opening surface of the nozzle 5 to the electromagnetic wave to be radiated. The frequency f is adjusted to a height lower than a quarter wavelength. For example, the electromagnetic wave frequency f is adjusted to a height range of 1/8 wavelength or higher and less than 1/4 wavelength.
Alternatively, the ejection height of the conductive liquid F ejected from the opening surface of the nozzle 5 is adjusted to a height higher than a quarter wavelength at the frequency f of the electromagnetic wave to be radiated. For example, the frequency f of the electromagnetic wave is adjusted to be higher than a quarter-wave height and less than a three-quarter wavelength height.

In the sixth embodiment, since the distance between the hole 22 and the hole 23 is equal to or shorter than the length of one-eighth wavelength at the frequency f of the electromagnetic wave, the electrical coupling between the conductive liquid A and the conductive liquid F is The conductive liquid F becomes in a resonance state and operates as a radiating element.
As a result, the operating frequency band from the resonance frequency of the conductive liquid A to the resonance frequency of the conductive liquid F becomes an operable frequency band, and a wider band is achieved.
In addition, the ejection height of the conductive liquid F ejected from the opening surface of the nozzle 5 is adjusted with the frequency f of the electromagnetic wave to be radiated in the range of 1/8 wavelength to 3/4 wavelength. Thus, the usable bandwidth can be varied.

  In the sixth embodiment, the ground conductor 21 provided with the hole 22 and the hole 23 is shown. However, the combination of the hole 22 and the hole 23 is regarded as one hole 2 and, for example, the antenna shown in FIGS. If a plurality of pairs of holes 22 and 23 are arranged in a row as in the apparatus, or a plurality of pairs of holes 22 and holes 23 are concentrically arranged as in the antenna apparatus of FIG. Similarly to ˜4, it is possible to control the direction in which the electromagnetic wave is strengthened or the direction in which it is suppressed.

Embodiment 7 FIG.
FIG. 7 is a block diagram showing an antenna apparatus according to Embodiment 7 of the present invention. In FIG. 7, the same reference numerals as those in FIG.
The ground conductor 31 is provided with a hole 32 (first hole) on the center axis of the circle and an annular hole 33 (second hole) on the circumference of the circle.
The outer diameter of the nozzle 3 is smaller than the diameter of the hole 32 and is arranged coaxially with the hole 32.
The nozzle 34 is a flat nozzle and is a second conductor hollow tube having the same outline as the annular hole 33 provided in the ground conductor 1. The nozzle 34 is electrically connected to the ground conductor 31 with an opening surface at the tip disposed at a position covering the hole 33.
In the example of FIG. 7, the nozzle 34 has the same outline as the hole 33 provided in the ground conductor 31, but it is only necessary to cover the hole 33 provided in the ground conductor 31. Therefore, the outer contour of the nozzle 34 may be larger than the hole 33.

Next, the operation will be described.
The pump drive unit 8 drives the pump 6 to eject the conductive liquid A from the nozzle 3 to the outside.
At this time, since a high-frequency voltage is applied between the ground conductor 1 and the nozzle 3 from the feeding point 4, high-frequency power is supplied to the conductive liquid A operating as a radiating element.

The pump drive unit 8 drives the pump 7 to eject the conductive liquid G from the nozzle 34 to the outside.
The conductive liquid G ejected from the nozzle 34 is ejected so as to surround the conductive liquid A, and operates as a non-excitation element.

The pump drive unit 8 controls the supply amounts of the conductive liquids A and G supplied from the pumps 6 and 7 to the nozzles 3 and 34, thereby causing the conductive liquids A and G to be ejected from the opening surfaces of the nozzles 3 and 34. In the seventh embodiment, the ejection height of the conductive liquid A ejected from the opening surface 3a of the nozzle 3 is set to the ejection height of the conductive liquid G ejected from the opening surface of the nozzle 34. Thus, the height is adjusted to a height of a quarter wavelength or a length longer than a quarter wavelength at the frequency of the electromagnetic wave to be radiated.
Thereby, it operates as a coaxial line at the height of the conductive liquid G from the ground conductor 31, and a high frequency can be emitted at a height higher than the conductive liquid G.

  In the seventh embodiment, the ground conductor 31 provided with the hole 32 and the hole 33 is shown. However, the combination of the hole 32 and the hole 33 is regarded as one hole 2 and, for example, the antenna shown in FIGS. If a plurality of pairs of holes 32 and holes 33 are arranged in a row as in the device, or a plurality of pairs of holes 32 and holes 33 are concentrically arranged as in the antenna device of FIG. Similarly to ˜4, it is possible to control the direction in which the electromagnetic wave is strengthened or the direction in which it is suppressed.

Embodiment 8 FIG.
In the first to seventh embodiments, the pump is connected to each nozzle. However, a valve capable of adjusting the opening degree is connected to each nozzle, and one pump is provided for each of the plurality of valves. May be connected.
In this case, the pump drive unit 8 controls the supply amount of the conductive liquid from the pumps 6 and 7 and simultaneously adjusts the opening degree of each valve, as in the first to seventh embodiments. The supply amount of the conductive liquid supplied to the nozzles can be controlled.
In the eighth embodiment, the number of pumps can be reduced by connecting nozzles.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  DESCRIPTION OF SYMBOLS 1 Ground conductor, 2 holes, 3 nozzles (1st conductor hollow tube), 3a The opening surface of the nozzle 3, 4 Feeding point, 5 Nozzles (2nd conductor hollow tube), 6, 7 Pump (liquid ejection control) Part), 8 pump drive part (liquid ejection control part), 11 ground conductor, 12 holes (first hole), 13 holes (second hole), 13a split hole, 15 nozzle (second conductor hollow tube) ), 21 Ground conductor, 22 holes (1st hole), 23 holes (2nd hole), 31 Ground conductor, 32 holes (1st hole), 33 holes (2nd hole), 34 nozzle (1st hole) 2 conductor hollow tube).

Claims (10)

A ground conductor provided with a plurality of holes;
The outer conductor has an outer diameter that is smaller than the diameter of the plurality of holes provided in the ground conductor, is arranged coaxially with any of the plurality of holes, and a feeding point is provided on the opening surface at the tip A first conductor hollow tube being formed;
A position having an outer diameter equal to or larger than the diameter of the plurality of holes provided in the ground conductor, and covering a hole different from the hole in which the first conductor hollow tube is arranged among the plurality of holes. A plurality of second conductor hollow tubes, each having an opening surface at a tip thereof and electrically connected to the ground conductor;
An antenna device comprising: a liquid ejection control unit that ejects a conductive liquid to the outside from the opening surfaces of the first and second conductor hollow tubes. The liquid ejection control unit
Controlling the ejection height of the conductive liquid ejected from the opening surface of the first conductor hollow tube to a quarter wavelength height at the frequency of the electromagnetic wave to be radiated;
Of the plurality of second conductor hollow tubes, a second one disposed from a hole where the first conductor hollow tube is disposed to a hole located at a quarter wavelength at the frequency. 2. The antenna device according to claim 1, wherein the height of ejection of the conductive liquid ejected from the opening surface of the conductor hollow tube is controlled to be higher than a quarter wavelength at the frequency. The liquid ejection control unit
Controlling the ejection height of the conductive liquid ejected from the opening surface of the first conductor hollow tube to a quarter wavelength height at the frequency of the electromagnetic wave to be radiated;
Of the plurality of second conductor hollow tubes, a second one disposed from a hole where the first conductor hollow tube is disposed to a hole located at a quarter wavelength at the frequency. 2. The antenna device according to claim 1, wherein the height of ejection of the conductive liquid ejected from the opening surface of the conductor hollow tube is controlled to a height lower than a quarter wavelength at the frequency. A plurality of holes provided in the ground conductor are arranged in a row,
The liquid ejection control unit
Controlling the ejection height of the conductive liquid ejected from the opening surface of the first conductor hollow tube to a quarter wavelength height at the frequency of the electromagnetic wave to be radiated;
Two of the plurality of second conductor hollow tubes are disposed in a hole at a position of a quarter wavelength from the hole in which the first conductor hollow tube is disposed. The second conductive hollow tube is selected, and the ejection height of the conductive liquid ejected from the opening surface of one of the selected second conductive hollow tubes is set to a height higher than a quarter wavelength at the frequency. And controlling the ejection height of the conductive liquid ejected from the opening surface of the other selected second conductor hollow tube to be lower than a quarter wavelength at the frequency. The antenna device according to claim 1.   4. The ground conductor is provided with a plurality of holes concentrically around a hole in which the first conductor hollow tube is disposed as a central axis. The antenna device according to claim 1. A ground conductor provided with a first hole in a central axis of a concentric circle and a second hole in which a plurality of divided holes are arranged on the line of the concentric circle;
A first conductor having an outer diameter smaller than that of the first hole provided in the ground conductor, disposed coaxially with the first hole, and provided with a feeding point on the opening surface at the tip. A hollow tube,
A plurality of second conductors having an outer shape larger than the divided holes provided in the ground conductor, and having an opening surface at a tip disposed at a position covering the divided holes and electrically connected to the ground conductor. Two conductor hollow tubes;
An antenna device comprising: a liquid ejection control unit that ejects a conductive liquid to the outside from the opening surfaces of the first and second conductor hollow tubes. A ground conductor provided with a first hole and a second hole;
The first conductor has an outer diameter smaller than the diameter of the first hole provided in the ground conductor, is arranged coaxially with the first hole, and is provided with a feeding point on the opening surface at the tip. A conductor hollow tube,
It has an outer diameter equal to or larger than the diameter of the second hole provided in the ground conductor, and an opening surface at the tip is disposed at a position covering the second hole, and is electrically connected to the ground conductor. A second conductor hollow tube being formed;
A liquid ejection control unit for ejecting a conductive liquid to the outside from the opening surfaces of the first and second conductor hollow tubes,
The antenna device according to claim 1, wherein a distance between the first hole and the second hole is equal to or less than a length of 1/8 wavelength at an operating frequency of an electromagnetic wave to be radiated. A ground conductor provided with a first hole in the center axis of the circle and an annular second hole on the circumference of the circle;
The first conductor has an outer diameter smaller than the diameter of the first hole provided in the ground conductor, is arranged coaxially with the first hole, and is provided with a feeding point on the opening surface at the tip. A conductor hollow tube,
The outer surface of the ground conductor is larger than the second hole, and an opening surface at the tip is disposed at a position covering the second hole, and is electrically connected to the ground conductor. A second conductor hollow tube;
A liquid ejection control unit for ejecting a conductive liquid to the outside from the opening surfaces of the first and second conductor hollow tubes,
The liquid ejection control unit ejects the conductive liquid ejected from the opening surface of the second conductor hollow tube to the ejection height of the conductive liquid ejected from the opening surface of the first conductor hollow tube. An antenna device, wherein the height is controlled by adding a height of a quarter wavelength or more at a frequency of an electromagnetic wave to be radiated to a height.   The said liquid ejection control part is provided with the pump which supplies the said electroconductive liquid to the said 1st or 2nd conductor hollow tube, The any one of the Claims 1-8 characterized by the above-mentioned. The antenna device according to item.   The said liquid ejection control part is provided with the valve | bulb which adjusts the supply amount of the said electroconductive liquid supplied to the said 1st or 2nd conductor hollow tube from the said pump. Antenna device.

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