JP5113268B2 - Communication antenna - Google Patents

Description

  The present invention relates to a communication antenna mainly used for a base station of a mobile communication system, and conceptually relates to a communication antenna that can be used when a signal is radiated or received in a horizontal direction.

  In this type of communication antenna, each of the cylindrical radiator and the cylindrical reflector is arranged in parallel so that there is a gap between the radiator and the reflector. The first support frame positioned above and the second support frame positioned below are connected to form a communication antenna, and the upper and lower support frames are connected to a structure such as a column so that they can be used. Such communication antennas are generally known.

  In the conventional example, in particular, with respect to the element in the cylindrical reflector, the element at the top and bottom of the reflector so that the element becomes a highly reliable antenna that does not break or crack due to vibration caused by wind or the like. For attachment to the first support frame and the second support frame, a reflector cover having a downward recess is fixed to the first support frame, and a reflector receiver having an upward recess is fixed to the second support frame. The upper and lower ends of the reflector are inserted and inserted in the respective recesses, and between the outer peripheral surfaces of the upper and lower ends of the reflector and the inner peripheral surfaces of the recesses facing the same. Always maintain the cylindrical reflector at the center position of each recess, and when the cylindrical reflector bends like a bow, it is inserted into the recess with respect to the inner peripheral surface of each recess. In addition, the outer peripheral surface of the end of the reflector has a hollow cylindrical shape to enable tilting Communication antenna configuration where the elastic member is interposed are introduced (e.g., see Patent Document 1).

JP 2004-129031 A

  However, when considering a conventional antenna, for example, a PHS antenna for communication, there is a method of increasing the number of antennas when expanding the service area, but the gain is high and the directivity of the horizontal plane has desired characteristics. If the method uses an antenna, the system cost can be reduced even if it takes time for installation work or the like.

  Therefore, if the antenna element of the antenna radiator is composed of, for example, a collinear antenna, it is conceivable to increase the number of stages of the collinear antenna to increase the gain and improve the directivity. .

However, such a multi-stage configuration results in an extremely long dimension in the axial direction of the antenna, and as a result, the reflector needs to be configured to be correspondingly long.
Furthermore, in order to reduce the cost increase as a communication antenna, it is important to make the antenna slimmer and lighter, or to make parts common, and it is necessary to use a protective frame or radiation that covers the support frame or radiator used in conventional antennas. Coaxial wires that make up the element, metal pipes used in reflectors, metal fittings such as receivers / covers and fasteners for fixing them, elastic materials, etc. are used as common parts. As a result, an antenna having a very long axial length compared to the respective diameters is obtained.

  Accordingly, in order to prevent the entire antenna and each element from being vibrated due to, for example, a strong wind, the vibration within a predetermined range generated by the wind using a vibration tester or the like is not damaged or broken. On the other hand, it is necessary to guarantee the vibration resistance so that the entire antenna and each element are not damaged or broken.

  However, each element is constructed so that its axial dimension is very long with respect to its diameter, so that when a specific frequency is reached within the standard range of vibration resistance of this antenna (strong wind blows). In the same state as in the case, the entire antenna or the radiator or reflector may not only bend like a bow but also resonate with its frequency.

  That is, for example, a state in which the reflector vibrates abnormally greatly occurs (for example, the reflector is bent in a bow and vibrates so that the upper and lower support frames are “nodes” and the middle portion is “belly”). In this situation, as in the conventional example, the elastic bodies provided on the upper and lower support frames alone cannot withstand the vibrations and flexures. Problems such as cracks in the vessel and breakage occur.

  Similarly, in a radiator, when the radiator is vibrated or bent like a bow, a protective pipe placed on the radiator or an antenna element constituting the radiator (for example, a coaxial line or a coaxial cable in a collinear antenna) It is expected that problems such as breaking the assembly part of will occur.

  The present invention has been made to solve these problems, and the object thereof is to connect the upper and lower portions of the elements to each other and also connect the predetermined positions of the intermediate portions to each other. An object of the present invention is to provide a communication antenna having a strong structure.

The invention according to claim 1, which has been made to achieve the object,
The upper and lower sides of the antenna element are connected by a first support frame positioned above and a second support frame positioned below to constitute an antenna, and the upper and lower support frames are connected to a structure such as a column. In the communication antenna that can be used by
A third support frame that holds the element at a predetermined position between the first support frame and the second support frame and can be used by being connected to a structure such as a support column,
The third support frame is
A base having a first through hole larger than the outer diameter of the element and formed concentrically with the element being aligned with the axis;
A convex portion that protrudes so as to be able to be inserted into the first through hole at a position facing the first insertion hole, and that has a cylindrical peripheral wall concentrically so as to have a space inside, and the convex portion And a second metal fitting having a second insertion hole having an inner diameter smaller than the inner diameter of the projection and slightly larger than the outer diameter of the element, ,
A fitting hole having an inner diameter with which the convex portion is fitted, and a fitting hole concentrically connected to the fitting hole at a position facing the first through hole with the second stepped portion interposed therebetween, A fitting having a third through hole having an inner diameter that is smaller than the inner diameter of the joint hole and slightly larger than the outer diameter of the antenna;
It is the same as or slightly larger than the inner diameter of the space formed inside the convex part, and the axial dimension is the same as or slightly smaller than the axial dimension of the space. An elastic material having a fourth through hole with an inner diameter equal to or slightly smaller than the diameter dimension;
And the elastic material is housed between the first step portion and the second step portion in the space by sandwiching the base body between the holding fitting and the abutting fitting. The first through-hole, the second through-hole, the third through-hole, and the fourth through-hole coincide with each other to form an insertion hole for the element, When the element is inserted into the insertion hole, the elastic material always maintains the element at the center position of the insertion hole, and restricts the movement within a predetermined range when the element is bent like a bow. It is comprised so that it may do.

  According to the communication antenna of the present invention, the upper and lower elements are connected by the first support frame positioned above and the second support frame positioned below to constitute the antenna, and the upper and lower support frames are It can be used by being connected to a structure such as a column.

A predetermined position between the first support frame and the second support frame is provided with a third support frame that holds the element and can be used by being connected to a structure such as a support column. Yes.
For this reason, even with a communication antenna having a high gain and desired directivity, and having an axial dimension of the element that is very long compared to the outer diameter in the direction perpendicular to the axial line of the element. The upper part of the element, the lower part, and a predetermined position in the middle part can be connected to each other by a supporting frame, and the upper, middle and lower supporting frames are also connected and integrated. The whole antenna has a strong structure.

  The third support frame is composed of a base, a clamping bracket, a mounting bracket, and an elastic material. By sandwiching the base between the clamping bracket and the mounting bracket, the elastic material is placed inside the projection. In the space formed between the first step portion and the second step portion, and the axes of the first to fourth through holes coincide with each other in the third support frame. When an insertion hole is formed and an antenna element is inserted into this insertion hole, the elastic material always maintains this element at the center of the insertion hole, and when the element bends like a bow, its movement Is limited within a predetermined range.

  For this reason, according to this invention, it is cheap and can provide the communication antenna which has high reliability with respect to a vibration and bending.

It is explanatory drawing showing the structure of the communication antenna of embodiment, (a) is a front view of the communication antenna which fractured | ruptured one part, (b) is a top view of a communication antenna, (c) is the 1st 3 is a plan view of a support frame 3. FIG. It is explanatory drawing showing the structure of a 3rd support frame, (a) is the fragmentary sectional view which disassembled the 3rd support frame, (b) is when a 3rd support frame is attached to a cylindrical element. FIG. It is a partially broken sectional view which shows the relationship between the cylindrical element in a radiator, and its attaching part. It is a partially broken sectional view for showing the relation between the cylindrical element in a reflector, and its attaching part.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1A is a front view of a communication antenna with a part thereof broken, FIG. 1B is a plan view of the communication antenna, and FIG. 1C is a plan view of a third support frame. . FIG. 2A is a partial cross-sectional view in which the third support frame is disassembled, and FIG. 2B is a partial cross-sectional view when the third support frame is attached to the cylindrical element. FIG. 3 is a partially broken cross-sectional view showing the relationship between the cylindrical element in the radiator and the attachment portion thereof. FIG. 4 is a partially cutaway cross-sectional view for showing the relationship between the cylindrical element in the reflector and its attachment portion.

  In these drawings, reference numeral 1 denotes the radiator 4, the first reflector 5, the third reflector 7, and the second reflector 6 (on the near side in FIG. 1A). (Not shown). Note that the number and position of the reflectors may be arbitrarily increased or decreased depending on the environment of the communication means, or the positions may be set according to the directivity desired.

  The cylindrical body (also referred to as an element) in the radiator 4 and the cylindrical body (also referred to as an element) of the reflectors 5, 6 and 7 are used between the radiator 4 and the reflectors 5, 6 and 7. It is configured to be in a juxtaposed state in a state where a gap 8 necessary in terms of frequency is generated corresponding to the frequency.

  The upper and lower ends of each of the radiator 4 and the plurality of reflectors 5, 6, 7 are, as shown in the drawing, the first support frame 2 positioned above and the second positioned below. The third support frame 60 holds the gap 8 while maintaining the gap 8 at a predetermined position of the intermediate position of the element. In this way, the communication antenna 1 is configured.

  The three support frames 2, 60, 3 in the communication antenna 1 may be directly connected by an arbitrary hard member to constitute the communication antenna 1, but any structure, for example, a veranda of a building Are attached to the handrail member, a pillar (pole) 10 of arbitrary height, etc. in a vertical state or in a forward-tilted state.

Reference numerals 2a, 60a, and 3a denote connecting portions of the support frames 2, 60, and 3 formed of an iron plate material, and are provided with connecting through holes 2b, 60b, and 3b (3b does not appear in the drawing). Yes.
The connecting portions 2a, 60a, 3a are superposed on the mounting member 11 in a state of being taken out from the column 10 side (having through holes corresponding to the connecting through holes 2b, 60b, 3b), and The connecting through holes 2b, 60b, 3b are detachably fixed by a fastener (for example, a bolt) 12.

Next, attachment of the radiator 4 and the reflectors 5, 6, and 7 will be described.
First, the cylindrical element of the radiator 4 is inserted into the insertion hole 84 formed in the third support frame, and the cylindrical elements of the reflectors 5, 6, 7 are inserted into the insertion holes 85, 86, 87. .

Here, the detailed structure of the third support frame 60 will be described.
In the embodiment of the present application, the third support frame 60 is formed of a base 61, a holding metal fitting 62 formed so as to hold the base 61 in a vertical direction, and an abutting metal fitting 63.

  The base body 61 is extended to the connecting portion 60a, and the base element 61 includes the cylindrical element of the radiator 4 and the cylindrical elements of the reflectors 5, 6, and 7 in the upper and lower support frames 2, 3 is larger than the outer diameter of the cylindrical element of the radiator 4, which is formed with the central axis coincided with each other so as to be in a parallel state while maintaining the same dimension as the predetermined gap 8. 1B through-holes 51a, 61a, 71a (61a, 71a are not shown in the drawing, the same applies hereinafter) that are larger than the outer diameter of the 1A through-hole 41a and the cylindrical elements of the reflectors 5, 6, 7 are formed. Has been.

  Next, the clamping metal fitting 62 has the first A through hole 41a and the first B through holes 51a, 61a, 71a at positions facing the first A through hole 41a and the first B through holes 51a, 61a, 71a. And a space 42d and a space 52d, 62d, 72d (62d, 72d are not shown in the figure, the same applies hereinafter) and are formed so as to concentrically form a cylindrical peripheral wall. A portion 42c and convex portions 52c, 62c, 72c (62c, 72c are not shown in the figure, the same applies hereinafter) are provided, and the convex portions 42c and the convex portions 52c, 62c, 72c are respectively arranged in the upward direction. Inner diameter of the convex portion connected concentrically through the first A step portion 42b and the second B step portions 52b, 62b, 72b (62b, 72b are not shown in the drawing, the same applies hereinafter). Smaller, In addition, a 2A through hole 42a and a 2B through hole 52a, 62a, 72a (62a, 72a are not shown in the drawing, the same applies hereinafter) having an inner diameter slightly larger than the outer diameter of each element are formed. .

  Next, the metal fitting 63 has a second A stepped portion 43b and a second B stepped portion 53b, 63b, 73b at positions facing the first A through hole 41a and the first B through holes 51a, 61a, 71a. (63b and 73b are not shown in the figure. The same applies hereinafter), with the convex portion 42c and the convex portions 52c, 62c and 72c on the upper side, a fitting hole 43c and a fitting hole 53c. , 63c, 73c (63c, 73c are not shown in the drawing, the same applies hereinafter), and the lower side is contiguous with the fitting hole, and is smaller than the fitting hole inner diameter, and A 3A through-hole 43a and a 3B through-hole 53a, 63a, 73a (63a, 73a are not shown in the drawing, the same applies hereinafter) having an inner diameter slightly larger than the outer diameter of each element are formed.

  That is, when the base body 61 is sandwiched between the holding metal fitting 62 and the abutting metal fitting 63, the second A through-hole 42a and the second B through-holes 52a, 62a, 72a, the first A through-hole 41a and the first The 1B through holes 51a, 61a, 71a, the 3A through holes 43a, and the 3B through holes 53a, 63a, 73a are arranged so that their respective axes coincide with each other, and at this time, the convex portions 42c and projections 52c, 62c, 72c are fitted through the first support hole 41a and the first B through-holes 51a, 61a, 71a, and the tip portion is formed in the third support frame. It is comprised so that it may fit with the hole 43c and the fitting holes 53c, 63c, and 73c.

  Further, the space 42d and the spaces 52d, 62d, 72d formed inside the convex portion have dimensions that are the same or slightly larger than the inner circumference of the space, and the axial dimension is the same as the axial dimension of the space. It is formed to be the same as or slightly smaller than the dimensions and is mounted in the space, and at the center thereof is the same as or slightly smaller than the outer diameter of each cylindrical element, and the axis of the cylindrical element is made to coincide. An element holding member made of an elastic material made of synthetic rubber, plastic material or the like in which element holding holes 64a and element holding holes 65a, 66a, 67a (66a, 67a are not shown in the drawing, the same applies hereinafter) are formed. 64 and element holding members 65 and 66 (66 is not shown in the drawing, the same applies hereinafter) and 67 are the space, the first A step portion 42b, and the first B step portions 52b and 6b. b, 72b and the second 2A step portion 43b and the stepped portion 53b of the first 2B, 63 b, are accommodated with in the 73b.

The element holding hole is the fourth through-hole described in the claims.
As shown in FIG. 2B, for example, the base 61, the holding metal fitting 62, and the abutting metal fitting 63 configured in this way use fixing means composed of, for example, bolts 100 and nuts 101 arranged appropriately. Thus, the third support frame 60 is configured to be firmly fixed.

  In this assembled state, the radiation element insertion hole 84 and the reflection element insertion holes 85 and 86 include the first through hole, the second through hole, the third through hole, and the fourth through hole. 87, and this element insertion hole is the insertion hole of the support frame described in the claims. The element holding members 64, 65, 66, and 67 are elastic members according to claims.

  The cylindrical elements are inserted into the insertion holes formed in the third support frame 60 assembled in this way, so that each element is inserted and aligned with the insertion hole by the element holding member. It is done.

  And these element holding members 64, 65, 66, and 67 always maintain the said cylindrical radiator 4 and the reflectors 5, 6, and 7 in the center position of the said insertion holes 84, 85, 86, 87. Then, the distance 8 depending on the exact frequency of the radiator 4 and the reflectors 5, 6, 7 is maintained, and when the cylindrical radiator or the reflectors 5, 6, 7 vibrates due to strong wind, An intermediate between the radiator and the reflector inserted and placed in the insertion holes 84, 85, 86, 87 with a slight gap with respect to the inner peripheral surfaces of the second and third through holes. The element holding member absorbs the force to move the outer peripheral surface at the position, and the movement converges within a predetermined range.

  In the embodiment of the present invention, the third support frame 60 is an example in which the base 61 is tightly clamped by the holding metal fitting 62 and the abutting metal fitting 63, but the elastic material is provided between the antenna and the third support frame. However, the present invention is not limited to this embodiment.

Further, the holding metal fitting and the fitting metal may be exchanged upside down.
Next, attachment to the first support frame 2 and the second support frame 3 at the upper and lower ends is performed.
As shown in FIG. 3 with respect to the first support frame 2, the radiator 4 fixes a downward facing tool 36 made of a metal material such as an aluminum material to the second support frame 3. On the other hand, as shown in FIGS. 1 and 3, a receiver 15 having an upward concave portion formed of a metal material such as an aluminum material is fixed by a stopper 17 such as a nut, and the radiator 4 is placed in each of them. The upper and lower ends of the protective pipe 35 are respectively inserted, and are inserted and placed by an arbitrary fastening member such as a screw (not shown).

  As the configuration of the elements of the radiator 4, an arbitrary configuration such as a ground plane antenna, a collinear antenna, a sleeve antenna, a whip antenna, or the like is selected depending on a use band to be used, an urban environment, and the like. Shows an example using the collinear antenna 30 shown in FIGS.

  Reference numeral 31 denotes a coaxial line (coaxial cable) constituting each of the radiating elements, which is formed to have a half wavelength length. For example, an insulator is provided around the brass pipe as the outer conductor 31b. The center conductor 31a provided is configured to be inserted.

These have a structure in which coaxial conductors 31a and outer conductors 31b of coaxial lines adjacent to each other are alternately connected as shown in the figure.
The radiating element 31 is supported by an insulating material arranged at an appropriate interval between the radiating element 31 and the inner peripheral surface of the protective pipe 35, and is configured to maintain the interval between the radiating elements.

The protective pipe 35 indicates a protective pipe (radome) made of a general synthetic resin (for example, FRP: glass fiber reinforced plastic may be used).
The pipe 35 protects the mechanically weak radiating element 30. The radiating element 30 is inserted into the pipe 35, and the circumference thereof is elastic with an appropriate interval in the longitudinal direction. Inclusions (not shown) such as foamed polystyrene are interposed so that the radiating element 30 is always located at the center position of the protective pipe 35.

Reference numeral 19 shown in FIGS. 1 and 2 denotes a waterproof cylinder that protects the connection point with the plug 24 of the coaxial connector connected to the radiator from rain.
Next, attachment to the first support frame 2 and the second support frame 3 above and below the reflectors 5, 6 and 7 will be described.

In the following, for the sake of simplicity, the reflector 5 will be described (the reflectors 6 and 7 have the same configuration, and the description thereof will be omitted unless otherwise specified).
The first support frame 2 is fixed with an aluminum alloy material having a downward-facing recess 50c, for example, a die-casting reflector fixture 50, and the second support frame 3 is symmetrical with the reflector fixture 50. The reflector receiver 41 having the upward concave portion 41 </ b> C configured to be compatible with each other is fixed, and the upper and lower ends of the reflector 5 are inserted and fixed in the respective concave portions.

  In that case, between the outer peripheral surface of each of the upper and lower end portions of the reflector and the inner peripheral surface of each of the concave portions opposed thereto, the downward concave portion 50c and the upward concave portion 41c are respectively inserted and placed. A resilient member that is elastic and formed of a hollow cylindrical synthetic rubber, plastic material or the like for absorbing vibrations of the element 5 that is a tubular member of the reflector, particularly vibrations due to resonance. The members 45A and 45B (the holding members 46 and 47 are not shown in the drawing) are fixed.

  The holding member 45 always maintains the cylindrical reflector 5 at the center position of each of the recesses 41c and 50c, and maintains an interval 8 depending on the exact frequency with the radiator 4, When the cylindrical reflector 5 vibrates due to a strong wind or the like, the end of the reflector inserted and placed in the recess with a slight gap with respect to the inner peripheral surface of each recess 41c, 50c. The outer peripheral surface of the can be tilted.

Assembling work for the above-described structure is as shown in the figure using the stopper 15 such as a nut for the receiver 15 and the fastener 42 for the reflector receiver 41 for the second support frame 3. Stick.
In the case of the mounting, the lower end of the protective pipe 35 in which the radiating element 30 is preliminarily inserted is inserted into the upward concave portion of the receiver 15, and a well-known fastening member such as a screw not shown in the drawing or bonding It is advisable to fix it using an agent or the like. In addition, a well-known waterproof O-ring or the like is interposed, or a sealing material is applied. Further, the end of the reflective element 5 with the holding member 45 is inserted into the upward concave portion 41 c of the reflector receiver 41.

  Next, the cover 36 is fixed to the upper end of the protection pipe 35 and the upper ends of the reflection elements 5, or the reflector cover 50 is attached thereto. In that case, a holding member 45 is put on the upper end of the reflective element 5 in advance.

  Next, a cap 38 is fixed from above to the work piece 36 inserted from below in the first support frame 2 by using, for example, fixing means such as screwing. Moreover, the fastening tool 53 is inserted into the reflector cover 50 from above and fixed by being screwed together.

  In the communication antenna 1 integrated in this manner, the steel material 10 is connected or integrated between the three connecting portions 2a, 60a, and 3a at the upper, middle, and lower portions as necessary. Without being brought to the site, and the upper, middle position, and lower three connecting portions 2a, 60a, 3a are directly or indirectly attached to the structural support 10 installed in the site in advance and transmitted (or Used for reception).

The example of assembly described above shows an example of work, but depending on the convenience of work, the work order may be partially reversed.
In the embodiment of the present application, the mounting position of the third support frame 60 is a predetermined intermediate position of each element. As a suitable example of the position, for example, the third support frame shown in FIG. If the length in the axial direction of the element located above 60 is L1, and the length in the axial direction located below the third support frame 60 is L2, basically a long element with both ends fixed vibrates. In this case, the third support frame 60 is preferably positioned so as to be an intermediate portion that becomes an “antinode” of vibration, that is, L1 = L2.

Further, as described above, when the third support frame is provided at the intermediate position of the element, it is conceivable that the L1 portion and the L2 portion vibrate simultaneously due to strong winds or the like.
In such a case, for example, L1 = L2, so that the third support frame 60 is positioned at a position where the upper dimension is L1 ′ and the lower dimension is L2 ′. By shifting the timing at which the 'portion and the L2' portion vibrate due to strong winds or the like (in other words, the L1 'portion and the L2' portion are not vibrated simultaneously), the energy of the vibration is dispersed, and the antenna has a synergistic force. You may comprise so that it may not join.

  In the state of use of the above structure, the positional relationship is fixed when the three connecting portions 2a, 60a, 3a of the upper portion, the middle portion, and the lower portion are directly or indirectly attached to the structural support 10. Thus, the radiator 4 and the reflectors 5, 6, and 7 are stably supported by a rigid structure even in a strong wind.

  That is, like a communication antenna in the present invention, a conventional collinear antenna having a 17-stage configuration and having a gain of approximately 16 dBi and a horizontal plane directivity of approximately 90 ° (the length in the axial direction is approximately 1, 2 m). In order to expand the service area, the radiating element is, for example, a collinear antenna having a 36-stage configuration, and an antenna (in the axial direction) having a gain of approximately 18.5 dBi and a horizontal plane directivity of 120 °. When a communication antenna having a high gain and a desired directivity is to be provided by developing a length of approximately 2.5 m), the radiating element (for example, the collinear antenna) 30 constituting the radiator 4 is the conventional 2 Since the multistage configuration is about double, the antenna is very long in the axial direction. Similarly, the reflectors 5, 6, and 7 associated therewith have a very long axial length.

  However, in order to reduce the cost increase as a communication antenna, it is important to make the antenna slim and light, or to make parts common, and the support frames 2 and 3 used for the conventional antenna and the protection pipe of the radiator 4 ( For example, Φ = 25 mm) 35, radiating elements, metal pipes used for the reflectors 5, 6, and 7 (for example, Φ = 13.5mm), and coverings, receivers, and fasteners for fixing these elements. Thus, an antenna having a very long axial length compared to the thickness of each diameter is obtained.

  In the radiator 4, even if a relatively strong protection pipe 35 is formed, the structure of the conventional example in which the upper and lower sides are connected by the first support frame 2 and the second support frame 3 is generated by strong wind or the like. If the vibration to be generated is generated, the vibration width and the bending width of the entire radiator 4 which are bent like a bow become larger, so that the protection pipe 35 and the collinear antenna 30 constituting the radiator 4 may be damaged, It may occur that a vibration force is applied to the connecting portion with the second support frame, and that the connecting portion is broken or cracked.

  Furthermore, even if the entire radiator 4 bends in a bow shape, even if no strength problem occurs, it corresponds to the frequency used between the radiator 4 and the reflectors 5, 6, and 7. It is considered that the necessary gap 8 changes excessively and adversely affects the high frequency characteristics.

  Therefore, a predetermined position in a predetermined intermediate portion between the radiating element 4 and the reflective elements 5, 6, 7 is connected by the third support frame 60, and these support frames 2, 60, 3 and the structural support 10 are connected to each other. By this, the cylindrical element is held so as not to be bent like a bow due to strong winds, etc.In particular, in the present invention, when the vibration is generated, the portion of the cylindrical element that generally becomes the `` belly '' of vibration, The radiator 4 is normally fixed to the insertion hole 84 by the element holding member 64 attached to the insertion hole 84 formed in the third support frame 60 instead of being directly mechanically fixed using the third support frame 60. If the vibration is generated by strong wind or the like while maintaining the center position, the vibration is not damaged, and within a predetermined range in which the high frequency characteristics are not affected by the change of the interval 8. Since the radiator 4 is configured to be held so as to absorb the movement, the entire radiator 4 is not bent in a large bow shape, and thus the protection pipe 35 and the radiation element 30 constituting the radiator 4 are damaged, Excessive vibration force is applied to the connecting portion with the second support frame, and the problem that the connecting portion is broken or cracked is eliminated.

  Further, as described above, since the reflectors 5, 6, and 7 are also held in the third support frame, the radiator 4 is converged by the vibration within the predetermined range, and the radiator 4 and the reflector 5 are converged. , 6 and 7 can change the predetermined gap 8 without affecting the characteristics of the antenna.

  On the other hand, the reflectors 5, 6, and 7 associated therewith have a lower bending strength than that of the mechanical protective pipe because of the relationship typically made of aluminum pipes, and are greatly affected by strong winds. Although it vibrates by itself while bending, the length of the axial direction of the antenna of the configuration of the present invention is about twice as long as that of the conventional antenna, and the metal pipe used is a member used for the conventional antenna. Since it is processed into a predetermined size and used, the length in the axial direction becomes extremely long with respect to the diameter, so that it bends further in a bow shape due to strong wind or the like, and the reflector cover 50 and the reflector receiver 41 are bent. The provided holding members 45, 46, 47 alone cannot suppress the vibration, and the element may fall off, or the generation of a break or a crack may occur.

  Furthermore, even if each of the reflectors 5, 6, 7 is bent as a whole or has no strength problem, it corresponds to the frequency used between the radiator 4 and the reflectors 5, 6, 7. As a result, the gap 8 necessary for high frequency changes excessively, and it is considered that the high frequency characteristics are adversely affected.

  Therefore, the predetermined intermediate portions of the reflective elements 5, 6, 7 are connected by the third support frame 60 as described above, and these support frames 2, 60, 3 and the structural support 10 are connected to each other, The reflective element is used to hold the reflective element so that it does not bend in a strong wind or the like. In particular, in the present invention, the portion of the reflective element that is generally a “belly” of vibration when the vibration is generated is provided on the third support frame. The reflectors 5, 6 are always fixed by the element holding members 65, 66, 67 attached to the insertion holes 85, 86, 87 formed in the third support frame 60, instead of being directly mechanically fixed using the 60. , 7 is maintained at the center position of the insertion holes 85, 86, 87, and if vibration is generated by strong winds, the reflector 5, 6, 7 is not damaged, and the interval 8 High frequency by change of Since it is configured to be held so as to absorb vibration within a predetermined range that does not affect the performance, the reflectors 5, 6, 7 do not bend in the shape of a bow, thereby reflecting the reflectors 5, 6, 7. The metal pipe made of, for example, an aluminum material is damaged, or the force due to excessive vibration is applied to the holding parts of the reflector holder 50 and the reflector holder 41 in the first and second support frames, and the element falls off Or problems such as the occurrence of nicks and cracks.

  Further, since the radiator 4 is also held in the third support frame, each element converges with vibration within a predetermined range, and the radiator 4 and the reflectors 5, 6, 7 are connected. It is possible to prevent a change in the predetermined gap 8 between them from affecting the characteristics of the antenna.

  In the embodiment of the present application, the mounting position of the third support frame 60 is a predetermined intermediate position of each element. However, as a preferable example of the position, a long length basically fixed at both ends. When the object is vibrated, the third support frame 60 is configured to be positioned at an intermediate portion that becomes the “antinode” of vibration, that is, where L1 and L2 are substantially the same, thereby effectively preventing vibration. it can.

  In addition, when the third support frame is provided in the middle part of the element as described above, depending on the length of the element, the L1 part and the L2 part may vibrate simultaneously due to strong winds or the like. For example, by disposing the third support frame 60 at a position where the dimension positioned on the upper side is L1 ′ and the dimension positioned on the lower side is L2 ′ so that L1 = L2 is not satisfied, the L1 ′ portion and the By shifting the timing of the L2 ′ portion to vibrate due to strong winds or the like (in other words, the L1 ′ portion and the L2 ′ portion do not vibrate simultaneously), the vibration energy is dispersed and a synergistic force is not applied to the antenna. By configuring, the load on each element can be reduced.

  As described above, according to the present invention, the length in the axial direction (approximately 2.5 m) is the dimension of each element diameter (Φ = 25 mm for the radiator and Φ = 13.5 mm for the reflector) as in the embodiment of the present application. In a communication antenna having a long, high gain and desired directivity, the radiator element 4 and the reflector elements 5, 6, 7, which are arranged side by side, The middle part is connected to each other by a support frame, and the upper, middle, and lower support frames are also connected and integrated, so the whole antenna has a strong structure. is there.

  In addition, in the present invention, the radiator element 4 having a relatively strong structure and the reflector elements 5, 6, and 7 having a weaker structure than the radiator element 4 are mutually connected. Even if they are connected, the upper and lower ends of the reflector elements 5, 6, and 7, which are weak structures, are respectively inserted into the downward concave portion and the upward concave portion, and the inner surfaces of these concave portions In addition, between the upper and lower ends of the reflector element, elastic holding members 45, 46, 47 configured to absorb vibrations of the elements 5, 6, 7 are interposed, Even if the reflector elements 5, 6, and 7 move due to strong winds, the ends thereof may float in the air, and there is a risk that at the mouth of the recess, the wound may be damaged by twisting or cracking may occur due to twisting. There is no.

  In addition, a third support frame 60 is disposed at a predetermined position in the middle portion of the upper and lower support frames of the element, and the third support frame 60 is made of an elastic material formed so as to absorb the vibration of each element. Even if the element holder 64, 65, 66, 67 is interposed and the middle part is in a state of floating in the air, the radiator element 4 and the reflector elements 5, 6, 7 are moved by a strong wind. The range of movement can be converged within a predetermined range while absorbing the force to cause the bending, and the radiator 4 and the reflectors 5, 6, 7 are prevented from bending in the middle in the middle part, There is no risk of abnormal stress being applied to each element, and vibrations to the connecting parts at the top and bottom can be suppressed slightly, and the elements are connected to each other by a support frame. In addition, it is configured so that it can be used in conjunction with the structure, so that even if the timing at which the radiator and reflector start to vibrate due to strong winds is deviated, the vibration should be kept within a predetermined range. Therefore, this vibration does not cause other elements to resonate or the entire antenna starts resonant vibration, so that no load is applied to the other element. There is an effect that can be used as a life-span.

It should be noted that the present invention is not limited to the above-described embodiment, and can be implemented by appropriately changing the configuration of each part without departing from the spirit of the present invention, as exemplified below.
First, in the embodiment of the present application, the upper and lower ends of the reflector elements 5, 6, 7 are fixed by inserting each end into a downward concave portion and an upward concave portion, and the inner surfaces of these concave portions. Between the upper and lower ends of the reflector element and elastic holding members 45, 46, 47 configured to absorb vibrations of the elements 5, 6, 7, respectively. Although shown, the present invention is not particularly limited to this embodiment, and the support frame at the upper and lower end portions is set by installing the third support frame 60 in the use standard range (for example, wind resistance speed and vibration resistance test) of the communication antenna. If the stress on the connecting portion satisfies the desired standard without impairing the reliability of the element, the holding member may be omitted, and the element may be fixed by a known fixing means. Good.

  Moreover, although the example which equips the 3rd support frame with the insertion hole corresponding to each of a radiator and a reflector, and the elastic material inserted and inserted in this insertion hole was shown, three insertion holes are connected. One insertion hole is formed so that the radiator and the reflector can be inserted through the insertion hole, and an elastic member in which an element insertion hole is formed at a position facing the radiator and the reflector in the one insertion hole. May be configured to be inserted.

  Furthermore, although the antenna for communication provided with the radiator and the reflector was used as the Example of an antenna, it is not limited to the antenna for communication. Further, the present invention is not particularly limited to the embodiments, such as a vertically polarized omnidirectional antenna that does not include a reflector.

  DESCRIPTION OF SYMBOLS 1 ... Communication antenna, 2 ... 1st support frame, 3 ... 2nd support frame, 4 ... Radiator, 5 ... 1st reflector, 6 ... 2nd reflector, 7 ... 3rd reflector, 8 ... gap | interval, DESCRIPTION OF SYMBOLS 10 ... Column, 11 ... Mounting member, 12 ... Fastener, 15 ... Receiver, 17 ... Stopper, 19 ... Waterproofing cylinder, 24 ... Plug, 30 ... Collinear antenna, 31 ... Coaxial line, 31a ... Center conductor, 31b ... Coating conductor, 32 ... Sleeve, 35 ... Protective pipe, 36 ... Cover, 38 ... Cap, 41 ... Reflector receiver, 42 ... Clamp, 45/46/47 ... Holding member, 50 ... Reflector Cover: 53 ... Fastening tool, 60 ... Third support frame, 61 ... Base, 62 ... Holding metal fitting, 63 ... Holding metal fitting, 64 ... Radiation element holder, 65, 66, 67 ... Reflective element holder, 84 ... Radiator insertion holes, 85, 86, 87 ... Reflector insertion holes

Claims (1)

The upper and lower sides of the antenna element are connected by a first support frame positioned above and a second support frame positioned below to constitute an antenna, and the upper and lower support frames are connected to a structure such as a column. In the communication antenna that can be used by
A third support frame that holds the element at a predetermined position between the first support frame and the second support frame and can be used by being connected to a structure such as a support column,
The third support frame is
A base having a first through hole larger than the outer diameter of the element and formed concentrically with the element being aligned with the axis;
A convex portion that protrudes so as to be able to be inserted into the first through hole at a position facing the first insertion hole, and that has a cylindrical peripheral wall concentrically so as to have a space inside, and the convex portion And a second metal fitting having a second insertion hole having an inner diameter smaller than the inner diameter of the projection and slightly larger than the outer diameter of the element, ,
A fitting hole having an inner diameter with which the convex portion is fitted, and a fitting hole concentrically connected to the fitting hole at a position facing the first through hole with the second stepped portion interposed therebetween, A fitting having a third through hole having an inner diameter that is smaller than the inner diameter of the joint hole and slightly larger than the outer diameter of the antenna;
It is the same as or slightly larger than the inner diameter of the space formed inside the convex part, and the axial dimension is the same as or slightly smaller than the axial dimension of the space. An elastic material having a fourth through hole with an inner diameter equal to or slightly smaller than the diameter dimension;
And the elastic material is housed between the first step portion and the second step portion in the space by sandwiching the base body between the holding fitting and the abutting fitting. The first through-hole, the second through-hole, the third through-hole, and the fourth through-hole coincide with each other to form an insertion hole for the element, When the element is inserted into the insertion hole, the elastic material always maintains the element at the center position of the insertion hole, and restricts the movement within a predetermined range when the element is bent like a bow. It is comprised so that it may carry out. The communication antenna characterized by the above-mentioned.

Images