JP2008172414A - Antenna assembly - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enable an antenna assembly having a sharp directional characteristic to be easily assembled and installed by simply constituting the antenna assembly. <P>SOLUTION: A reception antenna 1 includes a waveguide 10, a reflector 12, and a radiator 30 each of which is formed like a rod, and the waveguide 10, the radiator 30 and the reflector 12 are supported in this order on a boom 4 via brackets 6 and 8 in parallel with one another so as to be orthogonal to the arrival direction of electric waves. Each of the waveguide 10, the radiator 30 and the reflector 12 comprises a nonconductive pipe, a nonconductive long-sized substrate, and a cap supporting the substrate in the pipe, and the substrate has a plurality of conductive patterns functioning as waveguide elements, reflecting elements, or radiating elements formed thereon. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an antenna device in which a plurality of antennas including a radiating element and an inductive element including a waveguide element, a reflecting element, and the like for guiding radio waves to the radiating element are arranged in parallel.

Conventionally, in terrestrial digital broadcasting, an orthogonal frequency division multiplexing (OFDM) system has been adopted as a modulation system.
In such an OFDM system, if there is a difference of a predetermined level or more between the desired wave and the jamming wave, even if the jamming wave is in the same frequency band, it is not affected by the jamming wave, and an appropriate demodulation result is obtained. In terrestrial digital broadcasting, all of the same frequency is broadcast between adjacent transmitting stations such as a master station and a relay station in order to make effective use of frequency resources by taking advantage of the characteristics of the OFDM system. A single frequency network (SFN) system for transmitting signals is adopted.

  Therefore, in an area where the desired wave transmitted from one transmitting station and the disturbing wave transmitted from another transmitting station reach at substantially the same level, the desired wave signal component obtained by the receiving antenna and the disturbing wave signal In order to increase the level difference from the component, it is necessary to sharpen the directivity characteristics of the receiving antenna.

Therefore, in order to sharpen the directivity characteristics of the receiving antennas, an antenna apparatus has been proposed in which a plurality of receiving antennas having the same characteristics are arranged in a horizontal or vertical direction at a predetermined interval and the received signals from the receiving antennas are combined. (For example, see Patent Document 1).
JP 2004-320454 A

  However, when a plurality of so-called Yagi-Uda antennas each including a radiating element connected to a feeder line, a waveguide element, and a reflective element are arranged in parallel as in the proposed antenna device, the directivity characteristics are sharp. Thus, although the reception level of the desired wave can be improved, there is a problem that the assembly and installation of the antenna device becomes difficult because the number of parts increases and the configuration becomes complicated.

  The present invention has been made in view of these problems, and an object of the present invention is to simply configure an antenna device with sharp directivity so that it can be easily assembled and installed.

The invention according to claim 1, which has been made to achieve the object,
An antenna device in which a plurality of antennas including a radiating element and an inductive element for guiding a radio wave to the radiating element are arranged in parallel at a predetermined interval corresponding to the frequency of the radio wave in the radio wave radiation direction. There,
A plurality of inductive elements constituting each antenna are formed on a long first support member made of a non-conductive material.

  According to a second aspect of the present invention, in the antenna device according to the first aspect, the first support member is a non-conductive rod-shaped member, and each of the induction elements is applied to a surface of the rod-shaped member. It consists of a plating part.

  On the other hand, according to a third aspect of the present invention, in the antenna device according to the first aspect, the first support member is a non-conductive first long substrate, and the inductive elements are the first inductive elements. It consists of a conductive pattern formed on one substrate.

  According to a fourth aspect of the present invention, in the antenna device according to the third aspect, at least one of the inductive elements formed on the first substrate includes a conductive pattern divided into two parts, It is characterized in that it is formed by a loading coil arranged so as to connect between conductive patterns.

  According to a fifth aspect of the present invention, in the antenna device according to the third or fourth aspect, the first support member is housed in a pipe made of a non-conductive material. .

  Next, the invention according to claim 6 is the antenna device according to any one of claims 1 to 5, wherein the plurality of radiating elements constituting each of the antennas are long shapes made of a non-conductive material. The second support member is integrally formed.

  According to a seventh aspect of the present invention, in the antenna device according to the sixth aspect of the present invention, the second support member is connected to a coaxial power feeding member, and feed patterns for feeding power to the radiating elements are provided. The non-conductive long second substrate is formed, and each of the radiating elements is formed of a conductive pattern formed on the second substrate.

  Furthermore, the invention according to claim 8 is the antenna device according to claim 7, wherein the second substrate includes a first radiation composed of two conductive patterns having a length of a quarter of a wavelength of a radio wave. Three radiating elements are formed: an element and two second radiating elements that are connected to both sides of the radiating element via phase coils and have a conductive pattern having a length that is half the wavelength of the radio wave. The power supply pattern is connected to the coaxial power supply member via a balanced-unbalanced conversion circuit and is configured to supply power to the first radiating element.

  On the other hand, according to a ninth aspect of the present invention, in the antenna device according to the sixth aspect, the second support member is connected to a coaxial power feeding member, and feed patterns for feeding power to the radiating elements are provided. Each of the radiating elements is a coaxial element formed in a length corresponding to the frequency of the radio wave, and a plurality of radiating elements are connected in series. A coaxial collinear array antenna is configured by being fixed on the second substrate in a connected state.

  The invention according to claim 10 is the antenna device according to any one of claims 7 to 9, wherein the second substrate is housed in a pipe made of a non-conductive material, An insertion hole for inserting the coaxial power feeding member is formed in the pipe.

In the antenna device according to the first aspect, the plurality of inductive elements constituting each antenna are formed on a long first support member made of a non-conductive material.
Therefore, according to the antenna device of the first aspect, since the plurality of antennas are arranged at predetermined intervals in the radio wave radiation direction, the antenna device having sharp directivity can be obtained. Further, since a plurality of inductive elements are formed on the long first support member, the number of parts can be reduced as compared with the conventional antenna device in which each inductive element is individually formed, and assembly and installation can be performed. Can be easily. The inductive element of the present invention refers to a waveguide element that guides radio waves to the radiating element or a reflective element that reflects radio waves to the radiating element.

  Next, in the antenna device according to claim 2, the first support member is a non-conductive rod-shaped member, and each induction element is constituted by a plating portion applied to the surface of the rod-shaped member. Therefore, according to the antenna device of the second aspect, the plurality of inductive elements can be easily formed integrally by plating the non-conductive rod-shaped member at a predetermined interval. In addition, since the deterioration status can be easily determined from the appearance, it is possible to easily grasp the defective part.

  In the antenna device according to claim 3, the first support member is a non-conductive long first substrate, and each inductive element includes a conductive pattern formed on the first substrate. ing. Therefore, according to the antenna device of the third aspect, the plurality of inductive elements can be easily formed integrally by forming the plurality of conductive patterns on the non-conductive substrate.

  Furthermore, in the antenna device according to claim 4, at least one of the inductive elements formed on the first substrate is arranged so as to connect the conductive pattern divided into two and the conductive pattern. Because of the loading coil characteristics, the length of the conductive pattern can be shortened and the entire substrate can be reduced due to the characteristics of the loading coil, compared to the case where the inductive element is formed only with the conductive pattern. Is possible.

  Each inductive element may be formed separately from the first support member, and the first support member may be constituted by a long non-conductive member capable of supporting a plurality of inductive elements in series. According to such an antenna device, for example, a long styrofoam having a plurality of grooves formed linearly is used as a first support member, and a metal rod as an induction element is engaged with the groove of the first support member. The plurality of inductive elements can be easily formed integrally with the first support member.

  Next, in the invention according to claim 3 or claim 4, as in the antenna device according to claim 5, the first support member may be housed in a pipe made of a non-conductive material. Well, in this way, since the first support member is housed inside a pipe made of a non-conductive material such as FRP, the inductive element can be protected without deteriorating the characteristics, and the durability is improved. it can.

  On the other hand, in the antenna device according to claim 6, since the plurality of radiating elements constituting each antenna are integrally formed on the long second support member made of a non-conductive material, The number of parts can be reduced as compared with the conventional antenna device formed individually, and assembly and installation can be easily performed.

  Next, in the antenna device according to claim 7, the second support member is connected to a coaxial power supply member, and a non-conductive length in which a power supply pattern for supplying power to each radiating element is formed. Since each of the radiating elements is composed of a conductive pattern formed on the second substrate, a plurality of conductive patterns and power feeding patterns are formed on the non-conductive substrate. These radiating elements can be easily formed integrally.

  In the antenna device according to claim 8, the second substrate includes a first radiating element including two conductive patterns having a length of a quarter of the wavelength of the radio wave, and both sides of the radiating element. Three radiating elements are formed, each of which is connected via a phase coil and is composed of two second radiating elements each having a conductive pattern having a length of one half of the wavelength of the radio wave. -Since it is connected to the coaxial power supply member via the unbalance conversion circuit and is configured to supply power to the first radiation element, the power supply member is connected to the power supply pattern for supplying power to the first radiation element. Then, the second radiating element is also fed through the first radiating element, and the plurality of radiating elements can be fed with one feeding pattern.

  On the other hand, in the antenna device according to claim 9, the second support member is connected to the coaxial power supply member, and is a non-conductive long member on which a power supply pattern for supplying power to each radiation element is formed. Each of the radiating elements is a coaxial element formed in a length corresponding to the frequency of the radio wave. And since the coaxial type | mold collinear array antenna is comprised by being fixed on the said 2nd board | substrate in the state in which the several radiation element was connected in series, a several radiation element can be easily formed integrally and directivity The sharp antenna device can be obtained. In addition, since the mechanical length is shortened according to the shortening rate of the coaxial element, the radiating element can be made small.

  In the invention according to any one of claims 7 to 9, as in the antenna device according to claim 10, the second substrate is accommodated in a pipe made of a non-conductive material. In this case, since the second substrate is housed in a pipe made of a non-conductive material such as FRP, the inductive element can be protected without deteriorating the characteristics, and the durability is improved. it can.

Embodiments of the present invention will be described below with reference to the drawings.
[First Embodiment]
FIG. 1 is an external view showing a configuration of a receiving antenna 1 of the first embodiment, FIG. 2A is a top view of the receiving antenna 1 (an arrow A in FIG. 1), and FIG. It is a front view (sectional view BB of Drawing 2 (a)) of vessel 30.

  The receiving antenna 1 of the first embodiment is an antenna device for receiving a terrestrial digital broadcast signal broadcast using a single frequency network (SFN), and as shown in FIGS. The waveguide 10, the reflector 12, and the radiator 30 are formed in parallel with each other in the order of the director 10, the radiator 30, and the reflector 12, and are orthogonal to the arrival direction of the radio wave. The boom 4 is supported by the brackets 6 and 8 and is installed vertically, and is supported by the rod-like mast main body 2a so that the boom 4 is horizontal with respect to the ground plane, and the central portion of the mast main body 2a. And mast 2 that supports both ends of radiator 30 with two arms 2b provided obliquely upward.

  As shown in FIGS. 3A to 3C, the director 10 includes a non-conductive FRP pipe 22, a rubber cap 24 that covers both ends of the pipe 22, and the pipe 22. And a long substrate 26 housed in the housing. Since the reflector 12 has the same configuration as that of the director 10, the description of the configuration of the reflector 12 is omitted.

The pipe 22 is formed to have a diameter and a length (for example, a diameter of 22 mm, a thickness of 1.5 mm, and a length of 1.5 m) that can accommodate the substrate 26 therein.
As shown in FIGS. 3D and 3E, a rib 24 a for holding the substrate 26 is provided inside the cap 24, and the substrate 26 is fixed in the pipe 22 by the cap 24. The

  The substrate 26 is a printed circuit board made of a non-conductive material. As shown in FIG. 4A, the substrate surface has a plurality of conductive patterns 26a each having a length approximately half the wavelength λ of the radio wave. (In this embodiment, it is formed at three places). Each conductive pattern 26a is arranged at a predetermined interval at a position corresponding to each of three radiating elements provided in the radiator 30 to be described later, and a waveguide element (in the case of the reflector 12). It functions as a reflective element) and constitutes an antenna together with the radiating element.

  3A is an external view showing the configuration of the director 10, FIG. 3B is an exploded perspective view showing the internal configuration of the director 10, and FIG. FIG. 3D is a cross-sectional view showing the internal configuration of the waveguide 10 (cross-sectional view CC in FIG. 3C), and FIG. FIG. 4 is a cross-sectional view (cross-sectional view DD of FIG. 3C) showing the configuration of the end portion of the director 10, and FIG. 4A is an external view showing the configuration of the substrate 26. FIG.

  Next, as shown in FIG. 6A, the radiator 30 includes a non-conductive FRP pipe 32 and a rubber cap 34 that covers both ends of the pipe 32, as with the waveguide 10. And a long substrate 36 accommodated in the pipe 32.

  In this embodiment, the pipe 32 is formed to have the same diameter as the director 10 and the reflector 12, and is slightly longer than the director 10 and the reflector 12 in order to provide a support portion by the arm 2 b. Is formed. In addition, an insertion hole 32 a into which a power supply member 70 described later can be inserted is formed in the center portion of the pipe 32.

Like the director 10 and the reflector 12, the cap 34 is provided with ribs inside and configured to support the end portion of the substrate 36.
The board 36 is a printed board made of a non-conductive material. As shown in FIG. 6B, conductive patterns are formed on the front and back surfaces of the board body 38, respectively. A pair of conductive patterns (hereinafter referred to as first radiation patterns 40a hereinafter) having a length of about one quarter of the wavelength λ of the radio wave in the longitudinal direction of the substrate 36 in the longitudinal direction of the substrate 36 at a central portion of the surface of the substrate 36. In each first radiation pattern 40a, a length of approximately half the wavelength λ of the radio wave is provided at a predetermined interval on the end side in the longitudinal direction of the substrate 36 in each first radiation pattern 40a. A conductive pattern (hereinafter also referred to as a second radiation pattern 40b) is formed.

  On the other hand, through holes 40c are respectively provided at the end portions of the first radiation patterns 40a on the center side of the substrate 36, and the first radiation patterns 40a are formed on the back surface conductive patterns through the through holes 40c. Connected with. The first radiation pattern 40a and the second radiation pattern 40b are connected via a phase coil 40d for inverting the phase of the radio wave.

  Next, a balanced-unbalanced conversion circuit 44 (hereinafter also referred to as a balun 44) is provided at the center of the back surface of the substrate 36, and the first radiation is transmitted to the input side of the balun 44 through the through hole 40c. The pattern 40a is connected. In addition, a power supply pattern 42 made of a conductive pattern and serving as a contact point with a coaxial power supply member 70 described later is also formed at the center of the back surface of the substrate 36. The power supply pattern 42 is composed of a power supply pattern 42b to which an output terminal of the balun 44 is connected and a signal received by each radiation pattern is supplied, and a ground pattern 42a for grounding. Yes.

  In the radiator 30 configured as described above, a pair of first radiation patterns 40a having a length approximately one half of the wavelength λ of the radio wave are respectively transmitted to the wavelength λ of the radio wave via the phase coil 40d. Since the second radiation pattern 40b having a length of approximately one half is connected, as shown in FIG. 6C, the standing wave current generated in each radiation pattern has the same phase and is connected in series. In addition, a so-called three-element collinear array antenna is formed in which each radiation pattern functions as a radiation element. Since this antenna is a balanced antenna, it is connected to a power feeding pattern 42 via a balun 44 in order to connect to an unbalanced 75Ω coaxial cable.

  When the substrate 36 is accommodated in the pipe 32, the gap that is not on the power feeding side among the gaps between the substrate 36 and the pipe 32 (that is, the gap on the surface side where the radiation pattern is formed on the substrate 36). A block-shaped holding member 66 made of a non-conductive material such as resin is inserted on the side, and the holding member 66 allows the substrate 36 on which the power feeding pattern 42 is formed in the central portion to bend without bending in the central portion. It is supported so as to be fixed at a predetermined position.

  Here, FIG. 6A is an external view showing the configuration of the radiator 30, and FIG. 6B is an external view showing the configuration of the substrate 36 (viewed from the top, side, and bottom). FIG. 6C is a schematic diagram showing an electrical configuration of the substrate 36.

  Next, the structure of the bracket 6 for fixing the director 10 and the reflector 12 (hereinafter simply described as the director 10) to the boom 4 will be described with reference to FIG. 8A and 8B are cross-sectional views showing the configuration of the bracket 6. FIG. 8A is a cross-sectional view EE of FIG. 2A, and FIG. 8B is a cross-sectional view F of FIG. It is a figure which shows -F.

As shown in FIG. 8, the bracket 6 includes a bracket body 6a, a mounting adapter 6b, a mounting bolt 6c, and a mounting screw 6d.
The bracket body 6a is composed of a substantially rectangular parallelepiped block, and has a circular through hole into which the director 10 can be inserted at the center. In addition, a substantially semicircular groove that can be engaged with the outer periphery of the boom 4 is formed in one of the surfaces parallel to the axial direction of the through hole in a direction parallel to and perpendicular to the through hole. Yes. In addition, a round hole penetrating the through hole is formed from the opposite surface parallel to the surface on which the semicircular groove is formed, and the surface on which the semicircular groove is formed and the bottom surface of the round hole are formed. An insertion hole through which the mounting bolt 6c can be inserted is formed so as to penetrate.

The mounting adapter 6b is a substantially rectangular parallelepiped block formed so that its outer shape matches the bracket body 6a, and an insertion hole through which the mounting bolt 6c is inserted is formed at the center.
When the waveguide 10 is fixed to the boom 4 by the bracket 6, first, the mounting bolt 6c is inserted from the side where the round hole is formed in the insertion hole of the bracket body 6a, and then the waveguide 10 Is inserted through the through hole.

  Next, the mounting bolt 6c is inserted into the insertion hole formed in the boom 4, and the boom 4 is engaged with the groove formed in the bracket body 6a, while the boom 4 is sandwiched between the opposite side of the bracket body 6a. Then, the boom 4 is engaged with the groove while the mounting adapter 6b is inserted through the mounting bolt 6c. In this state, the mounting screw 6 d is fastened, whereby the boom 4 is clamped by the bracket 6, and the director 10 is fixed to the boom 4 via the bracket 6.

  Next, the structure of the bracket 8 for fixing the radiator 30 to the boom 4 will be described with reference to FIG. 9A is a cross-sectional view (cross-sectional view GG of FIG. 2A) showing the configuration of the bracket 8, and FIG. 9B is a cross-sectional view showing the detailed configuration of the power feeding member 70. is there.

  As shown in FIG. 9, the bracket 8 includes a bracket body 8a, a mounting adapter 8b, a mounting bolt 8c, a mounting screw 8d, a power supply member 70, a waterproof pedestal 62, and a waterproof packing 64. It is configured.

  The bracket body 8a is formed of a substantially rectangular parallelepiped block, and includes a circular through hole into which the radiator 30 can be inserted at the center. In addition, a substantially semicircular groove that can be engaged with the outer periphery of the boom 4 is formed in one of the surfaces parallel to the axial direction of the through hole in a direction parallel to and perpendicular to the through hole. Yes.

  In addition, a round hole is formed so as to penetrate the through hole from the opposite surface parallel to the surface on which the semicircular groove is formed, and the front side of the through hole of the round hole is a power supply member. A screw hole into which the mounting screw portion 76a of 70 is screwed is formed. Further, a counterbore for fitting the waterproof packing 64 is formed around the screw hole. An insertion hole through which the mounting bolt 8c can be inserted is formed so as to penetrate the bottom surface of the round hole and the surface on which the semicircular groove is formed.

The mounting adapter 8b is a substantially rectangular parallelepiped block formed so that its outer shape matches the bracket body 8a, and an insertion hole through which the mounting bolt 8c is inserted is formed at the center.
As shown in FIG. 9B, the power supply member 70 includes a disk part and a metal power supply pin 72 made up of a pin suspended from the center of the disk part, and a mounting screw for coupling to the bracket body 8a. A cylindrical outer tube portion 76 having a cable connecting screw portion 76 b to which the portion 76 a and the coaxial cable are coupled, and an end portion of the mounting screw portion 76 a of the outer tube portion 76, are arranged around the power feed pin 72. A ground pin 74, a contact 78 into which a connector pin of a coaxial connector coupled to a coaxial cable is inserted, one end of which is connected to the contact 78, and the other end is a side on which a pin of the disk portion of the power feed pin 72 is suspended. A coil spring 80 connected to the opposite side to support the power feed pin 72 substantially horizontally, and an inner cylinder part 82 for fixing the contact 78 in the outer cylinder part 78 in a state insulated from the outer cylinder part 76. Has been. The power feeding pin 72, the coil spring 80, and the contact 78 are electrically connected. Further, the power supply pin 72 is always urged outward in the axial direction by the coil spring 80.

  The waterproof pedestal 62 is a substantially rectangular parallelepiped block formed so that its outer shape matches the bracket body 8a, and has an insertion hole through which the mounting screw portion 76a of the power supply member 70 is inserted. A circumferential groove 62a is formed around the insertion hole for fitting a waterproof cap that covers the coaxial connector when the coaxial cable is connected via the coaxial connector.

  When the radiator 30 is fixed to the boom 4 by the bracket 8, first, the mounting bolt 8c is inserted from the side where the round hole is formed in the insertion hole of the bracket body 6a, and then the radiator 30 is The bracket body 8a is inserted through the through hole, and fixed at a position where the insertion hole 32a of the radiator 30 and the screw hole of the bracket body 8a overlap.

  Next, a waterproof packing 64 made of a rubber ring is fitted into the spotted portion of the bracket body 8a, and the pedestal 62 is placed on the insertion hole of the pedestal 62 so as to overlap the screw hole of the bracket body 8a. To do. Then, the power feeding member 70 is inserted from the pedestal 62 side, the mounting screw portion 76a and the screw hole of the bracket main body 8a are screwed together, and the power feeding member 70 is coupled to the bracket main body 8a.

  At this time, the end of the attachment screw portion 76a of the power supply member 70 is inserted into the insertion hole 32a of the radiator 30 and engaged with the side surface of the insertion hole 32a, and the position is fixed to the bracket 8 with respect to the radiator 30. Is done. In addition, the ground pin 74 provided at the tip of the mounting screw portion 76a contacts the ground pattern 42a of the radiator 30. On the other hand, the power feed pin 72 is urged by the coil spring 80 to ensure that the radiator 30 The power supply pattern 42b is contacted, and the power supply pattern 42b and the contact 78 are electrically connected.

  Next, the mounting bolt 8c is inserted into the insertion hole formed in the boom 4, and the boom 4 is engaged with the groove formed in the bracket body 8a, while the boom 4 is sandwiched between the opposite side of the bracket body 8a. Then, the boom 4 is engaged with the groove while the mounting adapter 8b is inserted through the mounting bolt 8c. In this state, by fastening the mounting screw 8d, the boom 4 is clamped by the bracket 8, and the radiator 30 is fixed to the boom 4 via the bracket 8.

  As described above, the receiving antenna 1 according to the first embodiment includes the director 10, the reflector 12, and the radiator 30 each formed in a rod shape. The radiator 30 and the reflector 12 are supported by the boom 4 via the brackets 6 and 8 so as to be parallel to each other and orthogonal to the arrival direction of the radio wave. Each container includes a non-conductive pipe, a non-conductive long substrate, and a cap that supports the substrate in the pipe. Each substrate includes a waveguide element. A plurality of conductive patterns functioning as reflective elements or radiating elements are formed.

  Therefore, according to the receiving antenna 1 of the first embodiment, a plurality of antennas composed of a waveguide element, a reflecting element, and a radiating element are arranged at predetermined intervals in the radio wave radiation direction. The sharp receiving antenna 1 can be obtained, and since the waveguide element, the reflecting element, and the radiating element are integrally formed on the substrate, it is a component compared to the conventional receiving antenna in which each element is individually formed. The number can be reduced, and assembly and installation can be facilitated.

  Further, by forming the waveguide element, the reflection element, and the radiation element by the conductive pattern on the substrate, the waveguide 10, the reflector 12, and the radiator 30 in which a plurality of elements are integrally formed are provided. It can be formed easily.

  In particular, the substrate 36 constituting the radiator 30 has a first radiation pattern 40a composed of two conductive patterns having a length of approximately one quarter of the wavelength λ of the radio wave, and phases on both sides of the radiation pattern. Three radiating elements are formed by two second radiating patterns 40b, each of which is connected via a coil 40d and is made of a conductive pattern having a length approximately half the wavelength λ of the radio wave. 42 is connected to the coaxial power supply member 70 via the balun 44 and is formed so as to supply power to the first radiation pattern 40a. Therefore, when the power feeding member 70 is connected to the power feeding pattern 42, power is also fed to the second radiation pattern 40 b through the first radiation pattern 40 a, so that one power feeding member 70 applies to a plurality of radiation elements. Power can be supplied.

Furthermore, since each board | substrate is accommodated in the pipe made from FRP, each element can be protected without deteriorating a characteristic, and durability can be improved.
In the first embodiment, the receiving antenna 1 corresponds to the antenna device of the present invention, the substrate 26 corresponds to the first support member and the first substrate of the present invention, and the substrate body 38 corresponds to the second support member of the present invention. The conductive pattern formed on the substrate 26 of the director and reflector corresponds to the inductive element of the present invention, and the first radiation pattern 40a formed on the substrate body 38 of the radiator 30 corresponds to the second substrate. The second radiation pattern 40b formed on the substrate body 38 of the radiator 30 corresponds to the first radiation element of the present invention, and corresponds to the second radiation element of the present invention.

  By the way, in the said 1st Embodiment, you may comprise the director 10 with the board | substrate 28 shown in FIG.4 (b) instead of the board | substrate 26 as the modification 1. As shown in FIG. FIG. 4B is an external view showing the configuration of the substrate 28 of the first modification.

  Similarly to the substrate 26, the substrate 28 is a printed circuit board made of a non-conductive material. As shown in FIG. 4B, the substrate 28 has a plurality of conductive patterns 28a at predetermined intervals (this embodiment). It is formed in three places). Each conductive pattern 28a is divided into two, and the divided conductive patterns 28a are connected by a loading coil 28b.

  In the receiving antenna 1 of the modified example 1 configured as described above, the conductive pattern 28a formed on the surface of the substrate 28 of the director 10 is divided into two parts, and the space between the divided conductive patterns 28a is divided. Since the connection is made by the loading coil, the length can be shortened by the characteristics of the loading coil as compared with the case where the waveguide element is formed only by the conductive pattern, and the substrate 28, and hence the waveguide 10 can be made smaller. It is possible to configure.

In the first modification of the first embodiment, the substrate 28 corresponds to the first substrate of the present invention, and the conductive pattern 28a formed on the substrate 28 corresponds to the inductive element of the present invention.
Moreover, in the said 1st Embodiment, although the waveguide 10 was comprised by inserting the board | substrate 26 in which the conductive pattern 26a was formed inside the pipe 22 made from FRP, the waveguide 10 is shown in FIG. As in Modification 2 shown in FIG. 5, a plurality of metal rods may be arranged in series inside the FRP pipe 22. Hereinafter, the waveguide 10 of the modification 2 is demonstrated using FIG.

  5A is an external view showing the configuration of the director 10 of the second modification, FIG. 5B is an exploded perspective view showing the internal configuration of the director 10, and FIG. FIG. 5D is an exploded perspective view showing the internal configuration of the element portion 14, and FIG. 5D is a top view showing the configuration of the holding member 18 (an arrow view H in FIG. 5C).

  The director 10 according to the second modification includes an FRP pipe 22, a rubber cap 20 that covers both ends of the pipe 22, and a columnar element portion 14 that is housed inside the pipe 22. ing.

  The element portion 14 holds a plurality of element members 16 (three in this modification 2) made of a thin metal rod having a length approximately one-half the wavelength λ of the radio wave, and the element member 16. And a pair of holding members 18.

  The holding member 18 is made of a long foamed polystyrene having a semicircular cross section, and has three engaging grooves 18a that can engage the element member 16 in series in the longitudinal direction. Then, the element member 16 is engaged with the engagement groove 18a of one holding member 18, and the surface on which the element member 16 is engaged and the surface on which the engagement groove 18a of the other holding member 18 is formed match each other. Then, the element member 16 is sandwiched inside to form the columnar element portion 14. Note that the outer diameter of the element portion 14 is formed to be substantially equal to the inner diameter of the pipe 22.

  In the receiving antenna 1 of the modified example 2 configured in this way, by arranging a plurality of element members 16 made of a thin metal rod of a predetermined length in a holding member 18 made of foamed polystyrene, Since each element member 16 constitutes the waveguide 10 that functions as a waveguide element, the waveguide 10 in which a plurality of waveguide elements are integrally formed can be easily formed.

In Modification 2 of the first embodiment, the element member 16 corresponds to the induction element of the present invention, and the holding member 18 corresponds to the first support member of the present invention.
By the way, in the said modification 2, although the element member 16 was formed from the metal thin round bar, if it is the length of the half of a wavelength, it does not necessarily need to be a thin round bar, and may be square, It may be plate-shaped.

  Further, in the director 10 of the second modification, the element member 16 is supported by the holding member 18 made of expanded polystyrene, but the element member 16 is directly bonded to a predetermined position inside the pipe 22. May be. Furthermore, for example, each element member 16 is connected by a wire made of a non-conductive material, and both ends of the wire are fixed at the ends of the pipe 22, so that the element member 16 is spaced from the pipe 22 by a predetermined interval. It may be fixed.

  Moreover, in the said 1st Embodiment, you may comprise the radiator 30 with the board | substrate 46 with which the coaxial element as shown in FIG. FIG. 7A is an external view (viewed from the top, side, and bottom) of the configuration of the substrate 46 of Modification 3. FIG. 7B is an external view of the configuration of the substrate main body 48. (C) is a schematic diagram showing an electrical configuration of the substrate 46. The substrate 46 is an example in which four radiating elements are formed on the substrate. When the radiator 30 according to the third modification is used, the director 10 and the reflector 12 include the four radiators 30. A material in which four conductive patterns functioning as waveguide elements or reflecting elements are formed at positions corresponding to the radiating elements is used.

  As shown in FIG. 7A, the board 46 is disposed on each of the long board body 48, the radio wave synthesizer 50 provided in the center of the board body 48, and both sides of the radio wave synthesizer 50. And a pair of coaxial element portions 52 (52a, 52b).

  The board body 48 is a printed board made of a non-conductive material. As shown in FIG. 7A, the board surface includes a mixing circuit 60 and two input terminals made of coaxial connectors. A radio wave synthesizer 50 is provided. On the other hand, a power supply pattern 54 that is a contact point with the power supply member 70 is formed on the back surface of the substrate. , And a ground pattern 54a for grounding. Further, as shown in FIG. 7B, the board body 48 is formed with insertion holes 48 a through which the coaxial element portion 52 can be inserted on both sides of the radio wave synthesizer 50.

  The coaxial element portion 52 is configured by a coaxial cable having a predetermined diameter, and has a first coaxial element 52a whose one end is coupled to the input terminal of the radio wave synthesizer 50, and a length that is approximately one half of the wavelength λ of the radio wave. The second coaxial element 52b is connected to the opposite end of the first coaxial element 52a.

  As shown in FIG. 7A, the first coaxial element 52a and the second coaxial element 52b are connected by soldering so that the center conductor is connected to the outer conductor of the other coaxial element. The first coaxial element 52a is provided with a cylindrical conductor having a length of approximately one quarter of the wavelength λ of the radio wave, leaving the second coaxial element 52b side on the side of the second coaxial element 52b. A sleeve 56 is coated. The sleeve 56 is connected to the outer conductor of the coaxial cable on the second coaxial element 52a side, and is open on the other end side to prevent current leaking to the radio wave synthesis unit 50 side.

  The pair of coaxial element portions 52 are respectively inserted into the insertion holes 48a of the substrate body 48 with the first coaxial elements 52a facing the radio wave synthesizer 50, and are fixed to the substrate body 48 by adhesion. The first coaxial element 52a is coupled to the input terminal of the radio wave synthesizer 50.

  In the radiator 30 of the modification 3 configured as described above, each coaxial element portion 52 forms a coaxial collinear array antenna having two elements. Here, as shown in FIG. 7C, the lengths of the feeding paths L1 and L2 (the sum of L21 and L22) to each coaxial element portion 52 are equal to each other. Since the phase circuit 58 for reversing the phase is provided in the power feeding path L2, the stationary circuit generated in each coaxial element unit 52 arranged in the direction different by 180 degrees around the radio wave synthesizer 50 is provided. Wave currents have the same phase, and as a whole, a four-element coaxial collinear array antenna is formed with each coaxial element as a radiating element.

  As described above, in the receiving antenna 1 of the third modification, the radiator 30 has the coaxial element portion 52 in which the first coaxial element 52a and the second coaxial element 52b are connected in series fixed on the substrate body 38 in series. Since each coaxial element is constituted by a coaxial collinear array antenna that functions as a radiating element by being connected to the power feeding member 70 via a power feeding pattern 54, a plurality of radiating elements are integrally formed. The formed radiator 30 can be easily formed.

In the third modification of the first embodiment, the first coaxial element 52a and the second coaxial element 52b correspond to the radiating element of the present invention, and the substrate body 48 corresponds to the second support member of the present invention.
In addition, in the radiator 30 according to the third modification, the phase circuit 58 is provided in one power supply path L2 so that the standing wave current generated in each coaxial element portion 52 has the same phase. The length of one power supply path L2 may be approximately one-half wavelength longer than the length of the other power supply path L1, so that the current generated in each coaxial element section 52 has the same phase. .
[Second Embodiment]
Next, another form of receiving antenna 90 will be described. The receiving antenna 1 of the second embodiment is configured in the same manner as in the first embodiment except for the director and the reflector. For this reason, the same code | symbol is attached | subjected about the location similar to 1st Embodiment, description is abbreviate | omitted, and only a different location is demonstrated.

  FIG. 10 is an overall configuration diagram showing the configuration of the receiving antenna 90 of the second embodiment. FIG. 10A is an external view showing the configuration of the receiving antenna 90, and FIG. It is a front view (arrow J figure of Fig.10 (a)) which shows a structure.

  The director 92 of the second embodiment is made of a non-conductive FRP pipe, and the surface of the pipe is plated with a length of approximately one-half of the wavelength λ of the radio wave at a predetermined interval. Is applied to a plurality of places (three places in the present embodiment).

  As described above, the receiving antenna 90 according to the second embodiment includes the waveguide 92, the reflector 94, and the radiator 30 each formed in a rod shape. The radiator 30 and the reflector 94 are supported by the boom 4 via the brackets 6 and 8 so as to be parallel to each other and orthogonal to the arrival direction of the radio wave. The waveguide 92 and the reflector 94 are made of FRP pipes, and plating portions 92a and 94a that function as waveguide elements or reflection elements are provided on the surface of the pipes.

  Therefore, according to the receiving antenna 90 of the second embodiment, a plurality of antennas composed of a waveguide element, a reflecting element, and a radiating element are arranged at predetermined intervals in the radiation direction of the radio wave. The sharp receiving antenna 90 can be obtained, and the waveguide element, the reflecting element, and the radiating element are integrally formed on the substrate or the FRP pipe, so that each element is individually formed. Compared to a conventional receiving antenna, the number of parts can be reduced, and assembly and installation can be facilitated.

  In addition, by plating the FRP pipe at a predetermined interval, a waveguide 92 or a reflector 94 in which a plurality of waveguide elements and reflection elements are integrally formed can be easily formed. Since the deterioration status can also be easily determined, it is possible to easily grasp the defective part.

In the second embodiment, the waveguide 92 and the reflector 94 made of a pipe correspond to the first support member of the present invention, and the plating portions 92a and 94a correspond to the induction element of the present invention.
[Third Embodiment]
Next, another form of receiving antenna 100 will be described. The receiving antenna 100 of the third embodiment is configured in the same manner as in the first embodiment except for the radiator and the mounting configuration of each device. For this reason, the same code | symbol is attached | subjected about the location similar to 1st Embodiment, description is abbreviate | omitted, and only a different location is demonstrated.

  FIG. 11 is an overall configuration diagram illustrating the configuration of the receiving antenna 100 according to the third embodiment. FIG. 11A is an external view illustrating the configuration of the receiving antenna 100, and FIG. 11B illustrates the configuration of the receiving antenna 100. It is a front view (arrow K view of Fig.11 (a)) shown.

  The radiator 102 of the third embodiment includes a plurality (three in this embodiment) of dipole antenna elements 104 (hereinafter also referred to as dipole elements 104) and a non-conductive FRP pipe 106 that supports the dipole elements 104. And is composed of. In addition, a radio wave synthesizer 108 for mixing and outputting signals received by the dipole elements 104 is attached to the mast 2 and connected to the dipole elements 104 by coaxial cables.

  In the radiator 102 configured in this manner, a bracket 96 is fixed to the central portion of the surface of the pipe 106 opposite to the side on which the dipole element 104 is fixed. 4 is fixed. In addition, brackets 96 are fixed to the central portions of the waveguide 10 and the reflector 12, respectively, and are fixed to the boom 4 via the brackets 96.

  As described above, in the receiving antenna 100 of the third embodiment, the director 10, the reflector 12, and the radiator 102 are each formed in a rod shape, and the radiator 102 includes a plurality of dipole elements 104. The pipe 106 is installed at a predetermined interval. In addition, the director 10 and the reflector 12 include a non-conductive pipe 22, a non-conductive substrate 26, and a cap 24 that supports the substrate in the pipe 22. A plurality of conductive patterns functioning as waveguide elements or reflecting elements are formed.

  Therefore, according to the receiving antenna 100 of the third embodiment, a plurality of antennas composed of a waveguide element, a reflecting element, and a radiating element are arranged at a predetermined interval in the radiation direction of the radio wave. The sharp receiving antenna 100 can be obtained, and the waveguide element and the reflection element are integrally formed on the substrate, and the dipole element 104 is installed on one pipe 106, so that each element is individually formed. Compared to the conventional receiving antenna, the number of parts can be reduced, and assembly and installation can be facilitated.

As mentioned above, although one Embodiment of this invention was described, it cannot be overemphasized that this invention can take a various form.
For example, in each of the above embodiments, three waveguide elements, reflecting elements, and radiating elements are formed in the director, the reflector, and the radiator, respectively, but the number of elements is not limited to three, and is installed. The number of elements can be set as appropriate according to the location and required performance.

It is an external view which shows the structure of the receiving antenna 1 of 1st Embodiment. It is the top view and front view which show the structure of the receiving antenna 1 of 1st Embodiment. It is the external view and the exploded view which show the structure of the director. It is an external view which shows the structure of the board | substrate 26 of the director. It is the external view and the exploded view which show the structure of the director 10 of the modification 2. It is an external view which shows the structure of the radiator 30 and the board | substrate 36. FIG. It is an external view which shows the structure of the board | substrate 46 of the radiator 30 of the modification 3. FIG. 4 is a cross-sectional view showing a configuration of a bracket 6. FIG. It is an external view which shows the structure of the electric power feeding member 70 of the bracket 8 and the bracket 8. FIG. It is an external view which shows the structure of the receiving antenna 90 of 2nd Embodiment. It is an external view which shows the structure of the receiving antenna 100 of 3rd Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Reception antenna, 2 ... Mast, 4 ... Boom, 6, 8 ... Bracket, 10 ... Waveguide, 12 ... Reflector, 14 ... Element part, 16 ... Element member, 18 ... Holding member, 20 ... Cap, 22 ... pipe, 24 ... cap, 26 ... substrate, 26a ... conductive pattern, 28 ... substrate, 28a ... conductive pattern, 28b ... loading coil, 30 ... radiator, 32 ... pipe, 34 ... cap, 36 ... substrate, 38 ... substrate Main body, 40a ... first radiation pattern, 40b ... second radiation pattern, 40c ... through hole, 40d ... phase coil, 42 ... feed pattern, 44 ... balun, 46 ... substrate, 48 ... substrate body, 50 ... radio wave synthesis 52 ... Coaxial element part, 54 ... Power feeding pattern, 56 ... Sleeve, 58 ... Phase circuit, 60 ... Mixing circuit, 62 ... Base, 64 ... Waterproof packing, 66 ... Holding member DESCRIPTION OF SYMBOLS 70 ... Feed member, 72 ... Feed pin, 74 ... Ground pin, 76 ... Outer cylinder part, 78 ... Contact, 80 ... Coil spring, 82 ... Inner cylinder part, 90 ... Reception antenna, 92 ... Waveguide, 94 ... Reflection 96 ... Bracket, 100 ... Receiving antenna, 102 ... Radiator, 104 ... Dipole element, 106 ... Pipe, 108 ... Radio wave synthesizer

Claims (10)

An antenna device in which a plurality of antennas including a radiating element and an inductive element for guiding a radio wave to the radiating element are arranged in parallel at a predetermined interval corresponding to the frequency of the radio wave in the radio wave radiation direction. There,
A plurality of inductive elements constituting each of the antennas are formed on a long first support member made of a non-conductive material. The first support member is a non-conductive rod-shaped member;
The antenna device according to claim 1, wherein each inductive element includes a plated portion provided on a surface of the rod-shaped member. The first support member is a non-conductive long first substrate,
The antenna device according to claim 1, wherein each inductive element includes a conductive pattern formed on the first substrate.   At least one of the inductive elements formed on the first substrate is formed of a conductive pattern divided into two and a loading coil arranged to connect between the conductive patterns. The antenna device according to claim 3.   The antenna device according to claim 3 or 4, wherein the first support member is housed in a pipe made of a non-conductive material.   The plurality of radiating elements constituting each antenna are integrally formed on a long second support member made of a non-conductive material. Antenna device. The second support member is a non-conductive second long substrate that is connected to a coaxial power supply member and has a power supply pattern for supplying power to the radiating elements.
The antenna device according to claim 6, wherein each of the radiating elements includes a conductive pattern formed on the second substrate. The second substrate is connected to a first radiating element composed of two conductive patterns having a length of one-fourth of the wavelength of the radio wave, and to both sides of the radiating element via a phase coil. Three radiating elements, two second radiating elements made of a conductive pattern having a length of ½ of
The power feeding pattern is connected to the coaxial power feeding member via a balanced-unbalanced conversion circuit and configured to feed power to the first radiating element. Antenna device. The second support member is a non-conductive second long substrate that is connected to a coaxial power supply member and has a power supply pattern for supplying power to the radiating elements.
Each of the radiating elements is a coaxial element formed in a length corresponding to the frequency of the radio wave, and is fixed on the second substrate in a state where a plurality of radiating elements are connected in series, and is coaxial collinear. The antenna apparatus according to claim 6, wherein an array antenna is configured.   8. The second substrate is housed in a pipe made of a non-conductive material, and the pipe is formed with an insertion hole for inserting the coaxial power supply member. The antenna device according to claim 9.

Images