JPH0731613Y2 - Two-wire conical helix antenna with a truncated cone shape - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial field of application) The present invention relates to a truncated conical two-wire conical helix antenna having excellent vibration resistance.

(Prior Art) In recent years, a communication system in which information is exchanged by wireless communication between a moving vehicle and a fixed base station or between moving vehicle pairs has become widespread. It is desirable that a wide communication area can be secured in both the vehicle and the fixed base station in order to reliably exchange information.

Therefore, as a result of repeated research and experiments, the inventors improved the conical two-wire conical helix antenna that radiates a circularly polarized signal, and obtained a wide communication area with the truncated-conical two-wire conical helix antenna. It was made clear. Briefly describing the structure of this truncated cone-shaped two-wire conical helix antenna, the conical apex angle is about 2.5 degrees with respect to the axis, and the two antenna arms are wound in a uniform angle spiral with a pitch angle of 45 degrees. A coaxial cable is used to feed power to the top of the truncated cone of the antenna arm, and the bottom of the truncated cone is used as the free end. As described above, the circular truncated cone suppresses the radiation of the circularly polarized signal to the top side of the truncated cone and increases the radiation in the lateral direction orthogonal to the axis. Therefore, by installing the axis in the vertical direction, the circularly polarized signal can be efficiently radiated in a wide hemisphere in the horizontal direction, and the communication area can be expanded accordingly.

(Problems to be solved by the invention) By the way, in the structure of the above-mentioned truncated cone-shaped two-wire conical helix, only the end on the truncated cone top side of the antenna arm is connected and fixed to the coaxial cable, and cantilevered. The beam is structurally weak. In particular, when it is mounted on a vehicle or the like, violent vibration is applied, and therefore a reinforced structure is required.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a truncated conical two-wire conical helix antenna having excellent vibration resistance and easy to manufacture.

(Means for Solving the Problems) In order to achieve the above object, the truncated cone-shaped two-wire conical helix antenna of the present invention is configured as follows.

First, arm support members are arranged at the tip and middle of a cylindrical pole that stands upright on the antenna base, insert a semi-rigid cable into this pole, and connect the end to the tip of this semi-rigid cable. At the same time, the two antenna arms are fixedly supported by the arm supporting member and are wound in a truncated cone shape with an equiangular spiral, and the other ends of these antenna arms are fixed to the antenna base, and these antenna arms are further fixed. A frusto-conical cap-shaped radome for covering is fixed to the antenna base, and the tip of the pole is supported by the radome.

Further, the antenna base, the pole, and the arm support member may be integrally formed of resin having a low dielectric constant. The antenna base, the pole, and the arm support member may be divided into two in the axial direction of the pole, and each of them may be integrally formed of a resin having a low dielectric constant. Further, the antenna arm and the semi-rigid cable may be integrally molded with the antenna base, the pole and the arm supporting member by insert molding. In addition, it is desirable that the intervals between the arm supporting members arranged on the poles be made denser as the truncated cone has a larger diameter. Further, it is preferable that an engaging insertion portion, into which an arm supporting member provided at a tip end portion of the pole fits, is provided inside a truncated cone top portion of the radome.

Further, instead of the semi-rigid cable, the inner peripheral wall of the pole may be metal-plated, and the center conductor may be covered with an insulating material to insert a wire into the pole. Then, the tip of the pole is provided on both sides orthogonal to the axial direction and grooves are provided in the direction of the protrusion, and further, metal plating electrically connected to the metal plating on the inner peripheral wall of the pole is provided in these grooves. It is also possible to form the arm mounting portions by soldering the ends of the antenna arms to the metal plating of these arm mounting portions.

Then, a conical cage-shaped arm winding member is arranged on the antenna base, a semi-rigid cable is arranged on the axis of the arm winding member, and the end is connected to the tip of this semi-rigid cable and Two antenna arms are fixedly supported by an arm winding member and are wound in a truncated cone shape in an equiangular spiral, the other ends of these antenna arms are fixed to the antenna base, and a cone covering these antenna arms is further provided. A radome in the form of a base cap may be fixed to the antenna base, and the tip of the arm winding member may be supported by this radome.

In addition, the tip of the metal tube of the semi-rigid cable is axially divided into two and bent in the lateral direction, and one end of one antenna arm is fixed by caulking with one of the divided pieces.
It is desirable that the other end of the antenna arm is fixed by caulking with the other split piece. Further, the end of the antenna arm on the bottom side of the truncated cone may be fixed to the semi-rigid cable via the pole or the insulating material.

(Operation) The semi-rigid cable is inserted into the pole, the antenna arm is fixed and supported by the arm support member, and the end of the antenna arm on the bottom side of the truncated cone is fixed to the antenna base, so the antenna arm is firmly supported. To be done.
Moreover, since the tip of the pole is supported by the radome, the tip of the pole does not shake laterally due to vibration or the like.

Further, if the antenna base, the pole, and the arm support member are integrally formed, the accuracy of the position where the antenna arm is provided is improved. Then, the antenna base, the pole, and the arm support member are divided into two parts in the axial direction and integrally molded, and the semi-rigid cable is easily joined into a tubular shape by sandwiching the semi-rigid cable between the divided poles and joining the two. Can be placed in the pole of the. Furthermore, if the antenna arm and the semi-rigid cable are arranged by insert molding, the work of assembling them can be saved. Further, if the spacing between the arm support members is made smaller as the truncated cone becomes larger in diameter, the current flowing through the antenna arm becomes smaller in the larger diameter portion, so that the influence on the antenna characteristics can be reduced and at the same time the large diameter portion can be made smaller. The antenna arm on the bottom side of the truncated cone can be reliably supported. Further, if the arm support member at the tip of the pole is fitted into the engaging insertion portion at the top of the truncated cone of the radome, the tip of the pole can be easily supported to prevent lateral shake.

If the inner peripheral wall of the pole is metal-plated and the center conductor wire covered with the insulating material is inserted into the pole, a balun can be formed by forming a slit in the tip end portion of the pole in the axial direction. If an arm attachment portion is formed at the tip of the pole and the antenna arm is soldered to this, the assembly process of the wire rod to be inserted into the antenna arm and the pole can be performed separately, which is convenient for manufacturing.

When the antenna arm is wound around the truncated cone-shaped arm winding member, the aggregate forming the arm winding member can be thinned to reduce the influence on the antenna characteristics.

Also, if the tip of the metal tube of the semi-rigid cable is axially divided into two parts and bent in the lateral direction and the antenna arm is crimped and fixed with these divided pieces, the assembly process is more difficult than fixing by soldering. It is easy to mechanize and automate. Furthermore, if the end of the antenna arm on the bottom side of the truncated cone is fixed to the semi-rigid cable via a pole or an insulating material, both ends of the antenna arm will be fixed to the pole, etc. and integrated, resulting in excellent vibration resistance. .

(Embodiment) An embodiment of the present invention will be described below with reference to FIGS. 1 to 4. FIG. 1 is a side view of a truncated cone-shaped two-wire conical helix antenna of the present invention in which a radome is vertically cut out, and FIG. 2 is an A of FIG. 1 in a state where the radome is not cut out. FIG. 3 is a sectional view taken along the line A-A, FIG. 3 is a sectional view taken along the line B-B, and FIG. 4 is a sectional view taken along the line C-C.

In FIGS. 1 to 4, a cylindrical pole 2 made of a resin material is erected on an antenna base 1 made of a resin material, and a resin material having a low dielectric constant is provided at a tip portion and an intermediate portion of the pole 2, respectively. The substantially disk-shaped arm supporting members 3 and 4 are fixed by adhesion or the like. The distance P ₁ between the arm support members 3 and 4 fixed to the tip portion and the middle portion of the pole 2 may be wider than the distance P ₂ between the arm support member 4 and the antenna base ₁ in the middle portion. Then, the semi-rigid cable 5 is inserted into the pole 2, the antenna base 1 side is appropriately connected to the antenna connector 6, and the tip side is slightly projected from the pole 2. Further, for example, the antenna arms 7, 7 made of 2φ copper wire are appropriately formed in the arm supporting members 3, 4, and the holes 3 _a , 3 _a ,
4 is inserted into and supported on _a, 4 _a, is wound equiangular spiral at a pitch angle of 45 degrees with a conical apex angle 2.5 degrees. Instead of the arm hole 3 _a, which is formed in the support member _{3,4, 3 a, 4 a,} 4 a, with grooves cut into the outer peripheral portion may be supported antenna arms 7,7. Also, arm support members 3 and 4 fixed to the pole 2
The antenna arms 7 and 7 may be attached to the holes 3 _a , 3 _a , 4 _a and 4 _a of the antenna while rotating them around the axis, but first attach the arm support members 3 and 4 to the antenna arms 7 and 7, The pole 2 may be assembled and fixed. Then, the ends of the antenna arms 7, 7 on the truncated cone top side are soldered to the metal cylinder 5 _b at the tip of the semi-rigid cable 5, respectively. Center line 5 _b of the distal end portion of the semi-rigid cable 5 is connected to the metal tube 5 _b with an end of one antenna arm 7. Further, the ends of the antenna arms 7, 7 on the bottom side of the truncated cone are inserted and fixed in holes 1 _a , 1 _a formed in the antenna base 1.

Further, a radome 8 in the shape of a truncated cone and made of a resin material having a low dielectric constant is fixed to the antenna base 1 with screws 9, 9 so as to cover the antenna arms 7, 7. Inside the top of the truncated cone of the radome 8, there are provided a plurality of engaging protrusions 8 _a , 8 _a, ... As engaging insert portions into which the arm supporting member 3 fixed to the tip portion of the pole 2 is fitted by elastic deformation. It is projected downward. Then, when the radome 8 is fixed to the antenna base 1, the arm supporting member 3 at the tip portion of the pole 2 is simultaneously fitted and supported by the engaging projections 8 _a , 8 _a ,. Further, ribs 8 _b , 8 _b ... Are axially provided on the inner surface of the side wall of the radome 8 and engage with recesses 4 _b , 4 _b ... Provided on the outer periphery of the arm support member 4 in the middle portion of the pole 2. The rotation of the arm support member 4 about the axis is restricted. Similarly, the stepped portion 1 _b and the recesses 1 _c in the step portion 1 _b, 1 _c ... is provided which fits into the radome 8 to the antenna base 1, position regulation of the radome 8 is made. Further, through holes 10, 10 ... For attachment are formed in the flange portions of the antenna base 1 and the radome 8.

In this configuration, the distal end portion of the pole 2 horizontal deflection is prevented by the engagement projection 8 _a of the radome 8, 8 _a ..., also the intermediate portion is prevented from rotating in the radome 8 through the arm supporting member 4. Therefore, the pole 2 is strongly fixed to the antenna base 1. Then, the semi-rigid cable 5 is inserted into the pole 2, and the antenna arms 7 and 7 are supported and fixed by the arm supporting members 3 and 4 and the antenna base 1, so that the antenna arms 7 and 7 are easy to be subjected to vibration or the like. There is no fear of vibration or deformation. Further, by fixing the radome 8 to the antenna base 1, with the antenna supporting member 3 of the tip portion of the pole 2 is fitted to the engaging protrusion 8 _a, 8 _a ... At the same time, the concave portion 4 _b of the arm technology member 4 The ribs 8 _b , 8 _b of the radome 8 are inserted into the 4, 4 _b , so that the assembly is easy.

By the way, since the antenna arms 7 and 7 are fed from the top side of the truncated cone, the smaller the diameter of the top side is, the larger the current flowing and the stronger the emitted radio wave. The larger the diameter of the bottom of the truncated cone, the smaller the current, and no current flows at the ends. Therefore,
The distance P ₁ between the arm supporting members 3 and 4 fixed to the tip portion and the middle portion of the pole 2 is made large and rough to reduce the influence of the arm supporting member 4 on the antenna characteristics. Even if the distance P ₂ between the arm support member 4 and the antenna base 1 is made small and dense, the antenna characteristics are not affected so much and the large diameter portions of the antenna arms 7 and 7 can be fixed more reliably.

In the above-mentioned embodiment, the antenna base 1, the pole 2, and the arm supporting members 3 and 4 are finally integrated by adhering separate members, but like the second embodiment shown in FIG. The antenna base 1, the pole 2, and the arm support member 3,
The 4 may be integrally formed of a resin material having a low dielectric constant. Then, the antenna arms 7 and 7 are wound around the integrally molded product as shown by the chain line in FIG. Incidentally, in FIG. 5, the same members and the same structures as those in FIGS. 1 to 4 are designated by the same reference numerals, and the duplicated description is omitted.

According to the structure of the second embodiment in which the antenna base 1, the pole 2 and the arm supporting members 3 and 4 shown in FIG. 5 are integrally molded, their positional accuracy is integrated by fixing other members. It is higher than the one that you did, that's just the antenna arm 7,
The position accuracy where 7 is arranged is also improved, and the antenna characteristics are stable.

FIG. 6 further shows a third embodiment, which is divided into two in the axial direction, and antenna bases 1 ', 1', poles 2 ', 2', and arm support members 3 ', 3', 4 ', 4'is integrally molded with a resin having a low dielectric constant.

According to the structure of the third embodiment shown in FIG. 6, if the semi-rigid cable 5 is sandwiched by the divided poles 2'and 2'from both sides and the two are appropriately joined by adhesion or fusion, The semi-rigid cable 5 can be easily inserted into the pole 2, which may be advantageous in manufacturing.

A fourth embodiment is shown in FIGS. 7 and 8. 7th
In Fig. 8 and Fig. 8, a cylindrical pole made of resin material
A metal plating 21 is provided on the inner peripheral wall of 20, and further arm mounting portions 22, 22 are provided by projecting the tip end portions on both sides orthogonal to the axial direction. Grooves 23, 23 are formed on the upper end surfaces of the arm attachment portions 22, 22 in the projecting direction, and metal platings 21, 21 are provided on the inner peripheral surfaces of the grooves 23, 23. The metal platings 21, 21 of the arm attachment portions 22, 22 are electrically connected to the metal platings 21 on the inner peripheral wall of the pole 2. Further, the tip of the pole 20 is provided with a slit in the axial direction to form the baluns 24, 24.

Then, a wire 26 having the center conductor 25 covered with an insulating material is inserted into the pole 20. Further, the end of one antenna arm 7 and the center conductor 25 are soldered to the metal plating 21 of the groove 23 of the one arm mounting portion 22, and the groove of the other arm mounting portion 22 is soldered.
The end of the other antenna arm 7 is soldered to the metal plating 21 of 23.

In such a configuration, the metal plating 21 on the inner peripheral wall of the pole 20
And the wire rod 26 perform the same operation as a semi-rigid cable. Then, the antenna arms 7, 7 are previously attached to the pole 20.
After assembling the
26 may be inserted and the center conductor 25 may be soldered, which may be beneficial in manufacturing. Further, it is easy soldering of the end of the antenna arms 7, 7, as compared to soldered to the metal tube 5 _b Semi-rigid cable 5 can be reliably fixed with the working is easy, the variation of the more antenna characteristics It has less vibration and has excellent vibration resistance. Furthermore, by providing a slit at the tip of the pole 20 at the time of molding, the baluns 24, 24 can be formed, and a special work process for forming the baluns 24, 24 is unnecessary, and
The dimensional accuracy of the baluns 24, 24 can be increased. In addition, pole 20
Needless to say, the slit may be cut after the molding.

FIG. 9 and FIG. 10 are views showing a fifth embodiment of the truncated cone-shaped two-wire conical helix antenna of the present invention. FIG. 9 is a side view of a fifth embodiment of the truncated cone-shaped two-wire conical helix antenna of the present invention in which the remudo is vertically cut out, and FIG. 10 is a state in which the remood is not cut out. FIG. 9 is a sectional view taken along the line DD of FIG. In FIGS. 9 and 10, the same members as those in FIGS. 1 to 4 are designated by the same reference numerals, and a duplicate description will be omitted.

9 and 10, the points different from those in FIGS. 1 to 4 are that instead of the pole 2 and the arm support member 4, a truncated cone-shaped arm winding made of a resin material having a low dielectric constant is used. This is because the antenna arms 7 and 7 are wound around the rotating member 30. Then, the bottom of the truncated cone of the arm winding member 30 is appropriately positioned and fixed to the antenna base 1, and the arm support member 3 at the top of the truncated cone is engaged as an engagement insertion portion inside the top of the truncated cone of the radome 8. Fitted and supported by the projections 8 _a , 8 _a .

In such a configuration, by thinning the aggregate of the arm winding member 30, the influence on the antenna characteristics can be reduced. Moreover, since the antenna arms 7 and 7 can be supported at many points,
Vibration and deformation of the antenna arms 7 and 7 can be prevented against vibration and the like.

Further, FIG. 11 shows a sixth embodiment of the antenna arm.
7, 7 and the semi-rigid cable 5 and the antenna connector 6 (not shown) are insert-molded, and the antenna base 1, the pole 2 and the arm supporting members 3 and 4 are integrally molded.

In this way, the antenna arms 7, 7 and the semi-rigid cable 5, etc. are integrally formed with the antenna base 1, the pole 2, and the arm supporting members 3, 4, so that the antenna arms 7, 7 can be formed.
Position accuracy is further improved, and variations in antenna characteristics are eliminated. Moreover, the work of assembling or inserting the antenna arms 7 and 7 and the semi-rigid cable 5 into the arm supporting members 3 and 4 and the pole 2 becomes unnecessary, which is suitable for mass production. Insert molding of the antenna arms 7 and 7 makes the molding die extremely complicated and expensive. Therefore, only the semi-rigid cable 5 may be insert-molded.

FIG. 12 shows _a seventh embodiment in which the metal arms 5a of the semi-rigid cable 5 are used to support and fix the antenna arms 7,7. In FIG. 12, the metal tube 5 _b at the tip of the semi-rigid cable 5 protruding from the arm support member 3 at the tip of the pole 2 is axially divided into two pieces and bent laterally to form two pieces 60. , 60 are formed. Also, the metal tube 5
_{In b} , a slit is further provided in the axial direction from the bending position of the divided pieces 60, 60 to form a balun 61. Furthermore, the split piece 6
Insulating material is removed at a bending position of 0, 60 center conductors 5 _a is exposed to. The end of one of the antenna arm 7 with one split piece 60 is fixed by caulking, the edge and the center conductor 5 _a of the other antenna arm 7 with the other split piece 60 are secured together by caulking.

In this configuration, the connection to the metal tube 5 _b of the antenna arms 7,7 is made by crimping, easily mechanized and automated compared to soldering. Further, since soldering is not required for fixing, there is no variation in antenna characteristics due to differences in the amount of solder, etc., and performance is stabilized.

FIG. 13 shows an eighth embodiment in which the ends of the antenna arms 7, 7 on the bottom side of the truncated cone are fixed to the pole 2 or the semi-rigid cable 5.
An example of is shown. In FIG. 13, the antenna arms 7,7
The bottom end of the truncated cone is first bent toward the pole 2 and is further formed in an arc shape around the outer circumference of the pole 2 to form arc-shaped portions 70, 70. And this arc-shaped portion 7
0 and 70 are wound around the pole 2 and the ends of the antenna arms 7 and 7 are fixed. An insulating spacer 71 is interposed between the two antenna arms 7, 7.

In such a configuration, the ends of the antenna arms 7, 7 on the truncated cone bottom side have zero current and can have any shape. Therefore, if the end is fixed to the pole 2, the antenna arms 7,7
Since both ends are fixed in relation to the pole 2, the vibration resistance of the antenna arms 7, 7 is improved.

In the eighth embodiment, if the pole 2 is not provided, the arcuate portions 70, 70 of the antenna arms 7, 7 may be directly wound around and fixed to the semi-rigid cable 5. Then, an appropriate insulating sleeve may be interposed between the antenna arms 7 and 7 and the semi-rigid cable 5.

FIG. 14 shows a ninth embodiment in which the arm supporting member 3 at the tip portion of the pole 2 is fixed by the radome 8. In FIG. 14, a cylindrical projection is formed on the inner coaxial center of the top of the truncated cone of the radome 8.
80 is drilled. A large diameter portion 81 is provided inside the opening of the cylindrical projection 80, and the opening of the large diameter portion 81 is tapered or chamfered. The diameter D ₁ of the large diameter portion 81 is slightly smaller than the diameter D ₂ of the arm support member 3 at the tip of the pole 2.

In this structure, when the radome 8 is fixed to the antenna base 1, the arm support member 3 is press-fitted into the large diameter portion 81 in the direction of arrow x in FIG. 14, and the large diameter portion 81 is arm-supported by elastic deformation of the resin. The fitting of the member 3 is allowed. As a result, the tip of the pole 2 is fixed by the radome 8 and does not shake laterally due to vibration or the like. Then, the tip portion of the more strongly the pole 2 as compared with the fixed such by the engagement projection 8 _a, 8 _a ... of the embodiment shown in Figure 1 is supported and fixed.

(Effect of the Invention) Since the conical truncated cone two-wire conical helix antenna of the present invention is configured as described above, the following effects are achieved.

The pole, the arm support member, and the radome can securely support the antenna arm, prevent lateral vibration of the top of the truncated cone of the antenna arm, and are excellent in vibration resistance.

Further, by integrally forming the antenna base, the pole, and the arm supporting member, the positional accuracy of the antenna arm is improved and variations in antenna characteristics can be eliminated.
Then, if the semi-rigid cable is divided into two in the axial direction and integrally molded, the semi-rigid cable can be easily assembled by sandwiching and joining the semi-rigid cable with the divided poles. Furthermore, if the antenna arm and the semi-rigid cable are integrated by insert molding, the assembling process can be greatly saved and the variation in the antenna characteristics can be further eliminated. Further, the larger diameter portion of the antenna arm is supported more densely by the arm support member, so that the influence on the antenna characteristics is reduced and the large diameter portion on the free end side, which is easily deformed, can be securely fixed and supported. Also, by fitting and supporting the arm support member at the tip of the pole to the engaging insertion portion of the radome, the radome is fixed and the pole is supported at the same time, the assembly is easy, and it is suitable for mass production. is there.

Also, if the inner wall of the pole is plated with metal, a slit can be provided at the tip of the pole to form a balun,
It is easier to work than forming a balun on the metal tube of a semi-rigid cable. In particular, the balun can be formed simultaneously with the molding of the pole, which is suitable for mass production. If an arm attachment part is formed at the tip of the pole, and the antenna arm is soldered by plating it with metal, the work is easier than soldering the antenna arm to the metal tube of the semi-rigid cable. Yes, the antenna characteristics can be stabilized accordingly.

By supporting the antenna arm by winding it around a truncated cone-shaped arm winding member, there is little influence on the antenna characteristics, and moreover, the antenna arm can be supported at many points, and the deformation of the antenna arm can be reduced accordingly. .

Also, if the metal arm of the semi-rigid cable is split in the axial direction and the antenna arm is caulked and fixed,
Compared to soldering etc., the characteristics tend to be constant,
Easy to mechanize the assembly process. Further, if the end of the antenna arm on the bottom side of the truncated cone is fixed to the pole or the semi-rigid cable, both ends of the antenna arm are fixed, and the vibration resistance is excellent.

[Brief description of drawings]

FIG. 1 is a side view of a truncated cone-shaped two-wire conical helix antenna of the present invention in which a radome is vertically cut out,
2 is a sectional view taken along the line AA of FIG. 1 in a state where the radome is not cut out, FIG. 3 is a sectional view taken along the line BB of FIG. 4, and FIG. FIG. 5 is a sectional view taken along the line CC, FIG. 5 is an external perspective view of the integrally formed antenna base, pole and arm support member of the second embodiment, and FIG. 6 is a third embodiment. FIG. 7 is an external perspective view of an antenna base, a pole, and an arm supporting member, which are each divided into two parts in the axial direction and integrally molded, and FIG. 7 is a partial perspective view of the tip of the pole of the fourth embodiment; FIG. 8 is an assembled vertical sectional view of the pole tip portion of FIG. 7, and FIG. 9 is a fifth embodiment of a truncated cone-shaped two-wire conical helix antenna of the present invention in which a radome is vertically cut out. FIG. 10 is a side view of the example, and FIG. 10 is a D-D arrow of FIG. FIG. 11 is a cross-sectional view, and FIG. 11 is an external perspective view in which the antenna arm, the semi-rigid cable, and the like of the sixth embodiment are integrally molded with the antenna base, the pole, and the arm support member by insert molding, and FIG. FIG. 13 is an external perspective view of an essential part of a semi-rigid cable of the seventh embodiment, in which a metal tube is used to fix the end of the antenna arm by caulking, and FIG. 13 is a truncated cone bottom side of the antenna arm of the eighth embodiment. FIG. 14 is an external perspective view of an essential part for fixing the end part of FIG. 14, and FIG. 14 is a longitudinal sectional view of the essential part for supporting the tip part of the pole of the ninth embodiment with a radome. 1,1 ': Antenna base, 2,2', 20: Pole, 3,3 ', 4,
4 ': arm support member, 5: Semi-rigid cable, 5 _a, 2
5: Center conductor, 5 _b : Metal cylinder, 7: Antenna arm, 8: Radome, 8 _a : Engagement protrusion, 21: Metal plating, 22: Arm mounting part,
23: groove, 24, 61: balun, 30: arm winding member, 660: split piece, 61: balun, 70: arc-shaped portion, 80: tubular protrusion.

Claims (11)

[Scope of utility model registration request] 1. An arm supporting member is provided at the tip and the middle of a cylindrical pole erected on an antenna base, and a semi-rigid cable is inserted into this pole, and the tip of this semi-rigid cable is The two antenna arms are connected to each other and fixedly supported by the arm supporting member, and the two antenna arms are wound into a truncated cone shape with an equiangular spiral, and the other ends of the antenna arms are fixed to the antenna base. A conical truncated cone-shaped two-wire conical helix antenna characterized in that a frusto-conical cap-shaped radome covering an antenna arm is fixed to the antenna base and the tip of the pole is supported by the radome. . 2. A truncated cone-shaped two-wire conical helix antenna according to claim 1, wherein the antenna base, the pole, and the arm support member are integrally formed of a resin having a low dielectric constant. A truncated conical two-wire conical helix antenna. 3. A truncated conical two-wire conical helix antenna according to claim 1, wherein the antenna base, the pole, and the arm support member are divided into two in the axial direction of the pole, and a resin having a low dielectric constant is used. A two-wire conical helix antenna with a truncated cone shape characterized by being integrally molded with each other. 4. The truncated conical two-wire conical helix antenna according to claim 1, wherein the antenna arm and the semi-rigid cable are integrally molded with the antenna base, the pole, and the arm support member by insert molding. A two-wire conical helix antenna with a truncated cone shape characterized by being configured as follows. 5. The truncated conical two-wire conical helix antenna according to claim 1, wherein the intervals between the arm support members arranged on the poles are set so that the larger the truncated cone is, the closer the intervals are. A two-wire conical helix antenna in the shape of a truncated cone. 6. The truncated conical two-wire conical helix antenna according to claim 1, wherein an arm support member provided at a tip end portion of the pole fits inside a truncated cone top portion of the radome. A truncated cone-shaped two-wire conical helix antenna characterized by being provided with an insertion portion. 7. The truncated conical two-wire conical helix antenna according to claim 1, wherein instead of the semi-rigid cable, the inner peripheral wall of the pole is metal-plated, and the center conductor is made of an insulating material in the pole. A truncated conical two-wire conical helix antenna, which is configured by inserting a covered wire rod. 8. A truncated conical two-wire conical helix antenna according to claim 7, wherein the tip of the pole is provided on both sides orthogonal to the axial direction, and grooves are provided in the projecting direction. The groove is plated with metal that is electrically connected to the metal plating on the inner peripheral wall of the pole to form arm mounting portions, and the end of the antenna arm is soldered to the metal plating of these arm mounting portions. A two-wire conical helix antenna with a truncated cone shape characterized by the above. 9. A frustoconical cage-shaped arm winding member is arranged on the antenna base, a semi-rigid cable is arranged at the axis of the arm winding member, and the end is connected to the tip of this semi-rigid cable. In addition, the two antenna arms are fixedly supported by the arm winding member, and the two antenna arms are wound in a truncated cone shape with an equiangular spiral, and the other ends of the antenna arms are fixed to the antenna base. A conical truncated cone-shaped two-wire conical helix having a structure in which a frusto-conical cap-shaped radome covering the above is fixed to the antenna base and the tip of the arm winding member is supported by the radome. antenna. 10. The truncated conical two-wire conical helix antenna according to claim 1 or 9, wherein the tip of the metal tube of the semi-rigid cable is axially divided into two and bent in the lateral direction. A conical trapezoidal two-wire conical helix characterized in that one end of one antenna arm is fixed by crimping with a split piece, and the other end of the antenna arm is fixed by crimping with the other split piece. antenna. 11. A truncated cone two-wire conical helix antenna according to claim 1, wherein an end of the antenna arm on the bottom side of the truncated cone is fixed to a semi-rigid cable via the pole or an insulating material. A two-wire conical helix antenna having a truncated cone shape, which is configured as described above.