JPH0426203A - Helical antenna - Google Patents

Abstract

PURPOSE:To make assembly easy by constituting a 3dB directional coupler and/or balloon as microstrip lines formed on a printed circuit board corresponding to the fitting board of a helical element. CONSTITUTION:On a printed circuit board 10 composed of upper and lower printed circuit boards 30 and 20, a cylindrical helical element 70 is installed and on the outer peripheral surface of this helical element 70, a helical line 71 is formed. On the upper and lower surfaces of the lower printed circuit board 20, solid ground patterns are respectively formed and on the other hand, a 3dB directional coupler 40 is formed as the microstrip line on the inner layer. On the lower printed circuit board 20, a terminal insert port 23a and through holes 23b-23d are respectively formed and connected to a land formed as one part of the microstrip line of the 3dB directional coupler 40. After installing the helical element 70 on this printed circuit board, a connecting member is fitted between the helical line on the helical element side and the terminal of the microstrip line on the printed circuit board side. Thus, the helical antenna can easily be assembled with simple structure.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a helical antenna that can be used as a four-wire fractional winding helical antenna.

Conventionally, a four-line fractional-turn helical antenna is widely known as a circularly polarized antenna with an Ω and a generally wide beam width.

Part 5 about the structure of the conventional 4-wire fractional winding helical antenna
This will be explained with reference to the figures. Reference numeral 90 denotes a four-wire fractional-wound helical antenna 90, in which four helical lines 92, which are the main parts, are formed by winding them in a spiral shape at the same intervals on the outer surface of a cylindrical holder 91. . A quarter-wavelength branching conductor type balloon 93 supported at the center of the holder 91 is connected to each end of the spiral line 92 .

Furthermore, a hybrid 94 is connected to the other end of the balloon 93, and is a 3 dB directional coupler configured with a coaxial line or a strip line. In the figure, 95 is a coaxial connector for input/output terminals, and 96 is a terminating resistor.

However, in the case of the above conventional example, the balloon 93 of the coaxial line is used, so the overall structure of the antenna is complicated, and the assembly is very troublesome. It is also difficult to connect the balloon 93 and the spiral line 92, which is a major obstacle in promoting cost reduction.

The present invention has been devised in view of the above circumstances, and its purpose is to provide a helical antenna that has a much simpler structure and can be assembled easily compared to conventional antennas.

The helical antenna according to the present invention comprises a printed circuit board on which a 3 dB directional coupler and/or balloon is patterned as a microstrip line, and a printed circuit board that is erected on the printed circuit board. The present invention includes a spiral element having a spiral line, and a connecting member for connecting the end of the microstrip line and the printed circuit board side of the spiral line.

” Form a microstrip line pattern on a printed circuit board and create a 3 dB directional coupler and/or balloon. After the helical element is mounted vertically on this printed circuit board, a connecting member is attached between the helical line on the helical element side and the end of the microstrip line on the printed circuit board side.

The 3 dB directional coupler and/or balloon and the spiral line are now electrically connected via the connecting member.

1. Hereinafter, the helical antenna according to the present invention will be described with reference to the drawings, taking a four-line helical antenna as an example.

FIG. 1 is a side view of a four-wire fractional winding helical antenna, and FIG. 2 is a diagram for explaining the lower printed circuit board, (a
) is a back view, (b) is an inner layer pattern diagram showing the microstrip line of the 3dB directional coupler, (C) is a front view,
FIG. 3 is a diagram for explaining the upper printed circuit board, in which (a) is a back view, (b) is an inner layer pattern diagram showing the microstrip line of the balloon, (C) is a front view, and FIG. FIG. 2 is a circuit diagram of a four-wire fractional turn helical antenna.

The four-wire fractional winding helical antenna listed here has a cylindrical helical element 70 erected on a printed circuit board 10 consisting of an upper printed circuit board 30 and a lower printed circuit board Fi 20, as shown in FIG. It has a structure in which a total of four spiral lines 71 are formed on the outer peripheral surface of 70, and the circuit configuration is as shown in FIG. First, the lower printing base Fi, 20 will be explained with reference to FIG.

Heter earth patterns 21 and 22 are respectively formed on the upper and lower surfaces of the lower printed circuit board 20 (see FIG. 2(a)).
(C)), and a 3 dB directional coupler 40 is formed as a microstrip line in the inner layer (see Fig. 2 (B)).
)reference).

The lower printed circuit board 20 also includes terminal insertion holes 23a,
Through holes 23b, 23c, and 23d are formed, respectively, and 23a, 23b, 23c, and 23d are the runs F'a, b, c, and d formed as part of the microstrip line of the 3dB directional coupler 40. (However, the size of the terminal insertion hole 23a in FIG. 2(a) is inaccurate).

This terminal insertion hole 23a is for attaching the input/output connector 23 (see FIG. 1) to the printed circuit board 20.
It is attached using the method described below. First, the terminal portion of the human output forceps 23 is inserted into the terminal insertion hole 23a. 5. Then, solder the surface of the ground pattern 22 onto the tip of the terminal of the input/output connector 23 coming out from the opposite side of the terminal insertion hole 23a, and at the same time solder the ground of the input/output connector 23 on the opposite side. The side and the surface of the heter earth pattern 21 are directly soldered. Then, the input/output connector 23 is attached to the printed circuit board 20.

Furthermore, a thousand-knob type termination resistor 41 is soldered between the solid earth pattern 21 and the through hole 23b, and one end of the former termination resistor is connected to the through hole 23b.
It is electrically connected to runt b via.

Note that this is used as the printed circuit board 30 for the printed circuit board 20.
A total of four through holes 25, which are also holes for screwing, are formed, thereby electrically connecting the ground pattern 21 and the ground pattern 22. Further, a total of four holes 24 are formed in the center of the printed circuit board 20, and the reason why these holes are provided will be described later.

Next, the upper printed circuit board 30 will be explained with reference to FIG.

Solid earth patterns 32 and 31 are formed on the upper and lower surfaces of the upper printed circuit board 30, respectively (Fig. 3(C)).
(see (a)), balloons 51 and 52 are formed as microstrip lines in the inner layer (see FIG. 3 (1)).

The upper printed circuit board 30 also has a through hole 33e.
- 33j are formed respectively, and through holes 33e
, 33f , 33g , 33h , 33i , 33
j are adapted to be electrically connected to lands e, f, g, h, i, and j formed as part of the pattern of balloons 51, 52, respectively. In addition, through hole 33f,
33g, 331.33j and hole 2 on the printed circuit board 20 side
The positional relationship with 4 is the same.

Furthermore, the printed circuit board 30 has holes 3 in the printed circuit board 20.
A tapped hole 35 is formed in a positional relationship with the through holes 23a and 23b, and a hole 34 is formed in a positional relationship with the through holes 23a and 23b.

The upper printed circuit board 30 and the lower printed circuit board 20 having the above-described structure are aligned and overlapped, and the screws (not shown) are passed through the through holes 25 of the 20 examples of the lower printed circuit board M to each of the 30 examples of the upper printed circuit board. When screwed into the screw holes 35, the upper printed circuit board 30 and the lower printed circuit board 20 are now attached to each other.

Then, the --taarth pattern 3 on the upper printed circuit board side
1 and the heter ground pattern 22 on the lower printed circuit board side come into surface contact and have the same potential.
Since the hole 24 is provided on the side, the through holes 33f, 33g, 33i, 33j provided on each board
, the through holes 23a, 23b will not come into contact with the outer ground pattern 22 and the outer ground pattern 31 and cause a short circuit.

In addition, through holes 33e, 33 on the upper printed circuit board side
h and through holes 23d and 23c on the lower printed circuit board side
are aligned respectively. And between through holes 33e and 23d, through holes 33h and 23c
Conductor wires 71a and 71b (1 not shown in Figure 1)
After inserting and soldering the 3 dB directional generator 40, the runs) "c, d" and the balloon 50 runs "h,"
e are electrically connected to each other.

Further, conductive wires 60 (corresponding to connection members) are inserted into through holes 33f, 33g, 33i, and 33j formed in the upper printed circuit board 30 and soldered, and a part of the conductive wire 60 is inserted as shown in FIG. is made to protrude from the upper printed circuit board 30.

Note that the protruding conducting wire 60 is in a positional relationship that allows it to come into contact with the outer circumferential surface of a helical element 70, which will be described later.

The helical element 70 has a structure in which a flexible board on which a helical line 71 has been formed as a pattern is wound and pasted on the outer peripheral surface of a cylindrical holder made of resin or the like. It is installed vertically in the center. To explain in more detail, the spiral line 71
In this example, a total of four line patterns are formed at a predetermined angle and at the same intervals from each other using etching technology on a flexible substrate having approximately the same length as the outer circumference of the holder. When the flexible substrate on which the helical element 71 is formed is attached to a holder using an adhesive or the like, a helical cord element 71 as shown in FIG. 1 is created.

Then, the lower end of the helical element 71 is sandwiched between a total of four conductive wires 60 protruding from the upper printed circuit board 30, and the conductive wire 6
By soldering the tip of the spiral line 71 and the lower end of the spiral line 71, the helical element 70 is fixed to the upper printed board 30, and at the same time, the spiral line 71 and the balloons 51 and 52 are electrically connected.

In the 4-cotton fractional-wound helical antenna constructed as described above, the 3 dB direction generator 10 and the balloon 50 and the helical element 70 are attached by using a microstrip line formed on the substrate 10. As a result, the structure is much simpler than the conventional S model, and assembly is also easier. In particular, the connection between the helical element 70 and the balloon 50 can be easily made without any problem.

Therefore, it is of great significance in promoting cost reduction.

Note that the helical antenna according to the present invention is not limited to application only to a 4-wire fractional winding helical antenna, but can also be applied to a helical antenna with N wire fractional windings, and in conjunction with this, a combination of a 3 dB directional coupler and a balloon can also be used. It can change.

Furthermore, instead of dividing the printed circuit board into two sheets as in this embodiment, by using a multilayer printed circuit board, it becomes possible to use only one printed circuit board.

Furthermore, a ring-shaped groove may be formed in the printed circuit board, and the lower end of the helical element may be fitted into this groove. An example of the connecting member in such a case is a pattern formed on the inner wall surface of the groove.

As described above, in the case of the helical antenna according to the present invention, the attachment of the 3 dB directional coupler and/or balloon spiral element is configured as a microstrip line formed on a printed circuit board corresponding to a board. Therefore, the structure is much simpler than the conventional one, and assembly is accordingly easier. In particular, it is possible to easily connect the helical element to a balloon or the like. Therefore, there are great benefits in promoting cost reduction and productivity improvement.

[Brief explanation of the drawing]

1 to 4 are diagrams for explaining one embodiment of the helical antenna according to the present invention, in which FIG. 1 is a side view of a four-wire, several-turn helical antenna, and FIG. 2 is a lower printed circuit board. FIG. 3 is a diagram for explaining the following: (a) is a back view, (b) is an inner layer pattern diagram showing the microstrip line of a 3 dB directional coupler, (C) is a front view, and FIG. 3 is a diagram showing the upper printed circuit board. These are diagrams for explanation, (a) is a back view, (b) is an inner layer pattern diagram showing the microstrip line of the balloon, (C) is a front view, and Figure 4 is a circuit diagram of a 4-wire fractional winding helical antenna. It is. FIG. 5 is a diagram for explaining a conventional helical antenna, and is a perspective view including a partial circuit diagram of a four-wire fractional winding helical antenna. 10... Printed circuit board 40... 3 dB directional coupler 50... Horn 60, 70, 7I... Conductor wire (connection member, spiral element, spiral line)

Claims (1)

[Claims] (1) A printed circuit board on which a 3 dB directional coupler and/or balloon is patterned as a microstrip line, a helical element installed upright on the printed circuit board and having a helical line on its outer surface, and a microstrip line. A helical antenna characterized by comprising a connecting member for connecting an end and a printed circuit board side of a spiral line.