JPH08222927A - Mount method for helical antenna and mount structure - Google Patents

Abstract

PURPOSE: To attain the mount job quickly and easily without the use of a metal- made material for mount at all by improving the mechanical mount method and the mount structure. CONSTITUTION: A λ/2 helical antenna element 31 is screw-fitted to a terminal member 45 and they are contained in an antenna cover 43 and locked by an inner flange 43d. A couple of hooks 43a, 43b are integrally formed to a base end (lower end) of the antenna cover 43 and inserted and fitted to an antenna mount hole 44a provided to a case of a radio equipment.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna element which is electromagnetically connected to a main body of a radio unit housed in a housing of a mobile communication unit without mechanically contacting or conducting the antenna element. In order to obtain a wide range of tuning characteristics without the need to expand and contract, the above antenna is mechanically supported with respect to the housing of the mobile communication device, and the antenna is used in the high frequency circuit of the mobile communication device. In particular, the present invention relates to a technique for electrically connecting in a non-contact manner. Particularly, an antenna cover housing an antenna element can be quickly constructed with a simple structure without using a metal coupling member (a male screw member or a nut member). ， It was improved so that it could be installed easily and cheaply.

[0002]

2. Description of the Related Art An antenna of a mobile communication device (for example, a mobile phone) is housed in a main body case when it is not used, or has a short length protruding from the main body case when not in use. Therefore, a structure that telescopically expands and contracts is generally used. A structure to stand up and store by tilting is also used, but the penetration rate is not high. If the antenna is rotatably pivotally supported and undulated without expanding or contracting the antenna or in combination with the expansion or contraction of the antenna, there are technical difficulties as described below. a. [Problems with maintaining contact and continuity] In order to connect a retractable antenna or retractable antenna to a circuit on the side of the communication device, it is necessary to maintain contact continuity between members that slide with each other. However, there is a possibility that a contact failure may occur. FIG. 7 is a cross-sectional view showing a conventional antenna support / mounting structure in which a non-telescopic antenna can be projected and housed. A sleeve-shaped connection fitting 2 is connected to the printed circuit board 1 for conduction, and a rod-shaped antenna 3 having an insulating coating is inserted therein. The metal fittings 4 and 5 are attached to both ends of the rod-shaped antenna 3, respectively. When the metal fittings 4 and 5 are pulled out to the position of the insulating coated antenna 3 drawn by a solid line to stand up, the connection metal fittings 2 and 4 are electrically connected. To do. Reference numeral 6 is a contact spring interposed to ensure the above-mentioned conduction. If such mechanical contact and sliding parts are present, there are problems such as wear and stain, and as a result, there is a possibility that troubles such as poor contact may occur. b. [Problem concerning size] For example, in the case of an antenna for a 800 MHz mobile phone, the λ / 2 antenna has a length of about 18 cm, and the λ / 4 antenna has a length of about 9 cm, which is too long and inconvenient to handle as a portable type. It should be noted that if a λ / 4 antenna is used, the length of the antenna can be reduced, but λ / 2 is said to be desirable because it is easily affected by the ground. c. [Problem when semi-standing] When the insulation-coated antenna 3 in the conventional example shown in FIG. 7 is housed in a case as indicated by 3'indicated by a broken line and fully lowered, the connection fitting 5 conducts to the connection fitting 2. In the half-pushed-in or half-pulled-out state, the antenna connection is cut off and the antenna does not function at all. d. [Problem Concerning Frequency Bandwidth] Since the conventional antenna support / connection structure as shown in FIG. 7 has a narrow frequency bandwidth, the sensitivity is lowered when a wide band property is required as in a car telephone, for example. Cannot be put to practical use.

In order to eliminate the above problems a to d, FIG.
An antenna support / connection structure as shown in Fig. 1 has also been proposed. Reference numeral 7 denotes a helical antenna (λ / 2 radiator), which is slidably fitted in the spiral coil 8. The core wire of the transmission line 12 made of a coaxial cable is connected to the spiral coil 8, and the outer conductor of the transmission line 12 is connected to the λ / 4 radiator 9. A conductive coating 11 is applied to the inner surface of the housing 10. In the antenna support / connection structure having the configuration shown in FIG. 8, the antenna (λ
(2/2 radiator) 7 is put into use or housed, and the operation of the antenna 7 is limited to sliding the antenna 7 in the direction of arrow ab. For example, it is not possible to tilt the antenna 7 like a reciprocating arc arrow cd. Can not.

On the other hand, recent technical research on mobile communication devices, including portable telephones, is aimed at the practical application of a digital cordless telephone system commonly referred to as a second-generation cordless telephone. In this system, for example, 1.9
It is predicted that a frequency, such as GHz, that is twice or more that of the conventional method will be used. In response to such technological development trends, it is easy to store and stand up in any form without requiring conduction by mechanical contact.
As a suitable antenna support and connection technology for 9 GHz,
The antenna element that resonates at λ / 2 and the antenna element that resonates at λ / 4
An exciter for coupling / matching the antenna element with a feeder line is provided, and a ground plane having an electric length of λ / 4 is arranged at a connecting portion between the exciter and the feeder line. It is effective to guide the antenna element so that the antenna element can move with respect to the exciter while maintaining a distance within a range where a minute electrostatic capacitance is formed between the exciter and the exciter. According to the above configuration, the antenna element resonating at λ / 2 is guided (allowing pushing / pulling out, tilting / standing up) with respect to the main body of the communication device, allowing a remarkably large degree of freedom. Since they are connected in a non-contact manner, there is no risk of poor conduction due to poor contact. Moreover, it is configured in a small size,
Moreover, excellent tuning characteristics can be obtained in a high frequency band (for example, near 1.9 GHz). The above-described technique is an invention created by the present inventor and will be referred to as a prior invention hereinafter.

Next, the preceding invention will be described with reference to FIGS. 9 and 10. FIG. 10 is a perspective view schematically showing one embodiment of the antenna support / connection structure according to the prior invention. Further, FIG. 9 is shown for explaining the basic principle of the invention of the prior application, and is a diagram showing an electrical system. As shown in FIG. 9 (principle diagram), with respect to the open end of the λ / 4-length exciter 14 connected to the signal source 6, λ / When the antenna element 13 of 2 is electrically connected,
Broadband tuning characteristics can be obtained in the vicinity of the wavelength λ without requiring mechanical contact. Even if the position and / or orientation of the antenna element 13 is changed, excellent tuning characteristics can be obtained within the range where the minute coupling capacitance 15 exists. Therefore, the antenna element 13 can be moved in the expansion / contraction direction as indicated by the reciprocating arrows a-b, and can be tilted as indicated by the reciprocating arc arrows cd, so that the antenna function is exhibited even during the movement and tilting. You can The minute coupling capacitance 15 varies depending on various conditions, but as an example in the case of 1.9 GHz, it is 0.1 p.
About F is sufficient, and there is no particular difficulty in specific means for forming this minute coupling capacitance. In the configuration shown in FIG. 10 (embodiment of the preceding invention), the exciter 14A has a zigzag shape in order to make the device compact. As a result, the wavelength λ /
The external dimensions of the exciter that resonates with the radio wave of No. 4 can be made shorter than λ / 4. Then, the antenna element 13 is positioned within a range of a distance that forms a small electrostatic capacitance with respect to the open end of the exciter 14A, and the antenna element 13 is reciprocated by the arrow ab.
, So that it can be slid in the longitudinal direction. Further, as an embodiment different from the above, an arc arrow c-
You may guide so that tilting is possible like d. In any case, guidance is provided so that a small capacitance can be maintained between the antenna element 13 and the exciter 14A. The antenna element 13
As shown by the solid line, the best performance is obtained when it is upright. However, even if the position and posture are any, the function as an antenna can be achieved if the coupling capacitance 15 is present. it can. For example, the antenna functions as an antenna even when it is tilted in the direction of the arc arrow d and has the posture shown in FIG. 13 '.

The core wire of the power supply line 16 made of a coaxial cable is connected to the exciter 14A, and the outer conductor of the power supply line 16 is connected to the ground plane 17. Ground plate 17 in this example
Is a rectangular metal plate whose long side has a length dimension of λ / 4.
FIG. 11 is an RFL SWR for explaining a tuning characteristic in one embodiment of the support / connection structure according to the preceding invention.
It is a characteristic graph. From these graphs, it is understood that the above-mentioned embodiment 1.9 has excellent wideband tuning performance in the vicinity of GHz.

[0007]

The inventor of the present invention, after creating the invention according to the above-mentioned precedent described with reference to FIGS. 9 to 11, and further continuing the practical application test, found that the desired practical effect was obtained. Although it was confirmed that it could be exhibited, on the other hand, it was discovered that there is room for improvement so as to make handling and operation easier in practical use. That is, [Problems concerning handling and operation] The operation of pushing or pulling the antenna element into or out of the housing (communication device case) is not necessary. In particular, it is inconvenient to handle the antenna element if it is pulled out in the "waiting for reception" state. Considering these aspects, the antenna for a mobile communication device does not require an operation of pulling out or pushing between a carrying state and a communicating state, and the length dimension of the portion protruding from the housing in the carrying state is short, Moreover, it is desired to have wide-range tuning performance.

[Problems Related to Productivity] In the embodiment of FIG. 10 according to the preceding invention, the antenna element 13, the exciter 14 A, the ground plane 17, and the feeder line 16 shown by the solid line in FIG. One set of antenna device assembly is constituted by the above, and is supplied to the market as a minimum unit product and distributed. The wireless device manufacturer designs and manufactures the communication device main body 31 housed in the housing 26 and purchases the above antenna device assembly, and draws the main plate 17 and the exciter 14A as shown in phantom lines in FIG. The antenna element 13 is housed and installed in the body 26, and the antenna element 13 is displaceably supported with respect to the housing 26, and the feeder line (coaxial cable) 16 is connected to the output end 30 of the communication device body 31. In this way, the division of labor between antenna manufacturers and communication equipment manufacturers
It has the advantage of being a modern industrial production system, but on the other hand it is wasteful and unreasonable. The antenna support / connection structure according to the invention of the prior application has room for further rationalization, even if it is not wasteful or irrational. Examples of two items that should be considered as targets for rationalization → cost reduction are a. A printed circuit board (not shown) is usually provided in the wireless device main body 31, and the cost effect is exhibited in mass production of ten thousand units. If a ground plane and an exciter are built in this printed circuit board, significant cost reduction can be expected. B. As described above, if the ground plane and the exciter are built in the communication device main body 31, the power supply line 16 shown in FIG. 11 may be made a part of the circuit pattern on the printed circuit board instead of being a separate component. Conceivable. This reduces the component cost,
And it is expected that the number of man-hours for assembly work will be reduced. C. In the configuration of FIG. 11, the main plate 17 and the exciter 14
A is mechanically connected and electrically connected to a circuit (not shown) of the communication device main body 31 via the power supply line 16, and the antenna element 13 is not in contact with these members. Therefore, when the configuration of FIG.
If the part that conducts is shared by the communication device manufacturer, and the antenna element 13 is separated by the non-contact part (the part that is coupled by electrostatic capacitance) and the antenna manufacturer allocates it,
It is rational because it does not require a step for conduction at least in assembly. In view of the above-mentioned circumstances, it is excellent in productivity without sacrificing the antenna characteristics (wide-range tunability) shown in FIG. 11, suitable for division of labor manufacturing, and high in the entire mobile communication device including the radio main body and the antenna device. A quality product can be produced at low cost, and it does not require an operation of pulling out or pushing in between the carrying state and the communication state of the mobile communication device,
Moreover, in order to reduce the length of the antenna projecting from the casing of the communication device, in the method of connecting the antenna to the wireless device main body housed in the casing of the mobile communication device, it is approximately λ / 2. Most of the helical antenna element that resonates with is protruded to the outside of the housing, and one end of the helical antenna element is fixed to the housing, and one end of the exciter that resonates at approximately λ / 4 is attached to the main body of the radio device. The connected end is connected to the output end, and the open end of the exciter is opposed to or separated from one end of the helical antenna element to form a coupling capacitance between the two, so that the coupling capacitance is substantially critical. It is effective to set the opposed / separated states so as to be coupled to each other so that the helical antenna element and the exciter exhibit a state of multiple resonance so that wideband tuning is possible. This technique is an invention (Japanese Patent Application No. 6-250753) created by the present inventor and applied for separately by the present applicant. Hereinafter, this is an unknown invention related to the prior application (abbreviated to the prior invention)
Say. According to the previously unknown invention of the above-mentioned prior application, λ
The substantial length of the helical antenna element that resonates at / 2 becomes much shorter than λ / 2, and there is a particular problem in carrying or storing this with the case protruding from the housing. Absent. Moreover, by making one end of this λ / 2 helical antenna element face and separate from the open end of the exciter, a resonating resonance state can be revealed and a wideband tuning characteristic can be obtained. Next, an example of an unknown invention of the prior application will be described. FIG. 12 is a schematic perspective view thereof. The λ / 2 helical antenna element 31 is fixed to the housing 26 of the mobile communication device, and most of it projects outside the housing. This λ / 2 dimension is, for example, about 18 cm in the case of 800 MHz, as described above.
It is inconvenient to handle if the 8 cm rod-shaped member is projected from the housing 26. However, the helical antenna element 3 of this example
1 is configured to resonate at λ / 2 and is molded in a helical shape, so its substantial length dimension L is about 4 cm, and even if it protrudes from the housing 26, it causes another trouble. Does not happen. Reference numeral 29 shown in the drawing is a radio device main body, and a high frequency circuit (not shown) is formed on a substrate 27 of the radio device and is covered with a shield case 28. 23 is the substrate 2
It is a ground plate laminated on one side of No. 7. An exciter 22 having a zigzag conduction pattern is formed on a portion of the one surface of the substrate 27 where the ground plane 23 is not formed. The exciter 22 is configured to resonate at λ / 4, and the open end 22a thereof has the open end 2 of the exciter 22.
2a is an open end 3 of the λ / 2 helical antenna element 22.
A coupling electrostatic capacitance 25 is formed between the two, facing and spaced from 1a. The substrate 27 is fixedly mounted on the housing 26, so that the position of the λ / 4 exciter 22 is fixed with respect to the housing 26. This relative position is set so that the above-mentioned coupling capacitance is in a substantially critical coupling state. As a result, a wide band tuning characteristic is obtained as will be described later in detail with reference to FIG. The mounting structure of the helical antenna element 22 suitable for obtaining the above-mentioned critical coupling state will be described later in detail with reference to various embodiments shown in FIGS.

The λ / 2 helical antenna element 31 is attached by covering the antenna cover 32. Since the above-mentioned helical antenna element is originally a flexible member, if the antenna cover 32 is made of a flexible material,
Even if it collides with an obstacle, it will not bend or bend, and will recover elastically, making it easy to handle. The feeding end 22b of the λ / 4 exciter 22 is connected to the output end of the high frequency circuit of the radio main body 29 by a microstrip line 24 so as to be electrically connected. The microstrip line 24 is constituted by a conductive pattern formed on the surface of the substrate 27 (specifically, on the surface opposite to the ground plate 23).
Is an output connector for connecting a measuring device to measure (if necessary, adjust) the characteristics of the wireless device.

FIG. 13 is a sectional view of the connection structure of the mobile communication antenna according to the above embodiment. However, for convenience of reading, the dimensional relationship of each component is appropriately modified, and is not necessarily an accurate projected figure.
The part that overlaps with the leader line is broken and drawn. The antenna cover 32 of this example is made of a flexible synthetic resin material and is molded into a cylindrical shape with a bottom and has a λ / 2 helical antenna element 31.
Is press-fitted and fixed. However, in the present invention, “cylindrical” and “tubular” are synonymous. Above antenna cover 3
A flange 32a is integrally formed at a position slightly apart from the opening end of 2 (the lower end in FIG. 13). The opening end side is fitted into a through hole formed in the housing 26 and penetrated, and the flange 32 a is brought into contact with the outer surface of the wall of the housing 26. Then, a snap ring 32b is attached to a portion of the end of the antenna cover 32 on the opening side that protrudes inward of the wall of the housing 26 to prevent it from coming off. In carrying out the present invention, the retaining means need not be the flange and the snap ring. Although not shown, it is recommended to use a wedge instead of the snap ring 32b. When the wedge is used, the backlash in the length direction of the antenna cover 32 is not generated as compared with the snap ring, so that the watertightness is improved. According to the configuration shown in FIG. 13, the sliding of the antenna cover 32 in the direction of the center line (vertical direction in the drawing) is locked, but the rotation around the center line is not locked. Therefore, it is necessary to take measures so that the antenna characteristics do not change even if the antenna cover 32 and the λ / 2 helical antenna element 31 fixed to the antenna cover 32 rotate. This will be described later in detail with reference to FIG.

FIG. 14 is shown for explaining an embodiment different from the above, and is an exploded perspective view in which a main part is extracted and drawn, and (A) is a mounting structure part of a λ / 2 helical antenna element. And (B) shows an embodiment having a mounting structure portion different from the above. (Fig. 14
(See (A)) The λ / 2 helical antenna element 31 is electrically connected and fixed to one end of the λ / 2 helical antenna element 31, the female screw hole 26c is formed in the housing 26, and the male screw member 31b is screwed into the female screw hole 26c. Set. The embodiment shown in FIG.
Instead of providing the female screw hole 26c in the housing 26, the nut member 2
6b was embedded and fixed. With this configuration, the housing 26
Dies can be easily removed when molding with a synthetic resin material,
Moreover, since the screw thread strength is large, the mounting state is reliable.
The antenna cover 32 in this FIG. 14 is formed in a tubular shape having an inner diameter dimension D ₂ smaller than the outer diameter dimension D ₁ of the λ / 2 helical antenna element 31 in the free state, and λ / 2 Helical antenna element 3
The elasticity of 1 is used to press-fit and fix. Experiments by the present inventor have confirmed that there is no risk of escaping under normal use conditions.

FIG. 15 is an RFL SWR characteristic graph in the embodiment shown in FIG. 1 and is a table corresponding to FIG. 11 in the prior invention. When both figures are made symmetrical, it can be seen that a remarkably wide range of tuning characteristics can be obtained by the appearance of multiple resonance states even by the antenna connection technique of this embodiment.

As described above, according to the previously unknown invention of the prior application, the substantial length dimension of the helical antenna element resonating at λ / 2 is much shorter than λ / 2, and this is the case. There is no particular problem in carrying or storing with a sash projected from the body. In addition, by making one end of this λ / 2 helical antenna element face and separate from the open end of the resonator, a backward resonance state can be revealed, and wideband tuning characteristics can be obtained. The present inventor, after creating an unknown invention relating to the above-mentioned prior application, has promoted research on cost reduction by simplifying the structure while promoting industrial mass production. In the embodiment of the previously unknown invention relating to the prior application shown in FIG. 14 shown in FIG. 13 above, a metal member (for fixing the λ / 2 helical antenna element 31 to the housing 26) is used. For example, the male screw fitting 31b and the snap ring 32b) had to be used. This member functions as an antenna, and when the used frequency is high, a considerable part of the antenna is included in the case, which increases the radio wave loss. Further, the structure is complicated, the number of constituent parts is large, and the parts cost and the assembly cost are increased. The present invention is an improvement of the previously unknown invention of the above-mentioned prior application, which is a characteristic effect thereof. Have wideband tuning characteristics, b. No need to pull out or push in the antenna, c. The length of the antenna protruding from the housing is not large,
And d. It is suitable for the division of labor production system between the antenna manufacturer and the radio manufacturer, without damaging the need for mechanical contact / conduction for connecting the antenna.
An object of the present invention is to enable quick and easy assembly without using a metal member for mounting the antenna device assembly to the radio housing.

[0014]

In order to achieve the above-mentioned object (no metal mounting bracket is required), the mounting technique of the helical antenna according to the present invention is such that most of the helical antenna element resonating at λ / 2 is used. The exciter, which resonates at approximately λ / 4, is supported by projecting it out of the housing, and the open end of the exciter is opposed to and separated from the helical antenna element, and a coupling static is provided between the exciter and the helical antenna element. In a method of connecting an antenna to form a capacitance, the helical antenna element is housed in a capped bottomless cylindrical antenna cover,
The concavo-convex formed on the housing and the concavo-convex formed on the antenna cover are engaged with each other to fix them to each other, and a conductive terminal member is attached to one end of the helical antenna so as to conduct electricity. The terminal member of (1) and the open end of the exciter face each other and are spaced apart from each other to form a coupling capacitance.

[0015]

According to the above construction, the characteristic effect of the previously unknown invention (Japanese Patent Application No. 6-250753),
a. Have wideband tuning characteristics, b. No need to pull out or push in the antenna, c. The length of the antenna protruding from the housing is not large, d. All antenna elements are installed outside the case to eliminate unnecessary radio wave loss, and e. It does not impair the need for mechanical contact and conduction to connect the antenna.
Moreover, the helical antenna element is housed in a cylindrical antenna cover with a bottom and is a single assembly. Since it is organized in this way, it has independence as a product shipped from the antenna manufacturer and distributed in the market, and it is also possible to easily provide compatibility as an antenna device assembly, It is possible to adapt to the diversification of mobile radio specifications while ensuring the cost reduction effect of mass production. Further, since the above antenna cover is mounted on the housing by the engagement of the concavities and convexities, a separate member for coupling is not required, which reduces the number of component parts and facilitates quick and easy assembly work. Can be done When the bayonet is used as the unevenness, it can be attached simply by inserting it and twisting it, and it is easy to remove it by the reverse procedure, so if you need it quickly, It can also be replaced easily. In addition, the quick and easy attachment / detachment property is convenient for inspecting finished products, and the operation of attaching / testing / removing the tester can be efficiently performed. In addition, when a pair of hooks formed integrally with the antenna cover is used as the above-mentioned unevenness, when the antenna cover housing the helical antenna is attached to the housing of the wireless device, the angular position around the axial center of the antenna cover is fixed. Since there is no need to regulate the mounting work, the mounting work can be easily controlled, which is suitable for automating the mounting work, and the automation can further reduce the assembly cost. As described above, when the antenna cover is engaged with the housing by the pair of hooks, the stopper can be stabilized by mounting the stopper that prevents the pair of hooks from bending, but the stopper member in this case is It does not need to be made of metal.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Next, referring to FIGS.
An embodiment of the present invention will be described. FIG. 1 is a schematic sectional front view showing a part of a helical antenna mounting structure configured to carry out a method of mounting a helical antenna according to the present invention, with a part broken away. The present invention, as described above, is an improved invention of an unknown invention according to the prior application,
The basic electrical structure is the same as that of the prior invention, and the λ / 2 helical antenna element 31 shown in FIG. 1 is the same as that shown in FIG.
14 to FIG. 14 (embodiments of the invention of the prior application), which are the same or similar constituent members as the λ / 2 helical antenna element 31. Reference numeral 43 denotes an antenna cover formed by applying the present invention, in which the λ / 2 helical antenna element 31 is housed. One end (lower end in the figure) of the λ / 2 helical antenna element 31 is closely wound (formed into a so-called zero pitch.
When this is viewed as a screw, its pitch is not strictly zero, and the zero pitch is commonly known as “close pitch”, and the close-wound portion 31c is formed. On the other hand, 4
Reference numeral 5 denotes a terminal member made of a conductive material, the upper end of which is formed in a male thread shape. FIG. 2 is a perspective view showing the vicinity of the lower end portion of the antenna cover and the terminal member in the helical antenna mounting structure according to the embodiment shown in FIG. As shown in FIG. 2, a male thread portion 45a is formed on the terminal member 45, and the close-wound portion 31c of the λ / 2 helical antenna element 31 described above with reference to FIG. It is screwed on.

The antenna cover 43 is made of a synthetic resin material having elasticity and has a cylindrical shape with a top and a bottom. A pair of hooks 43a and 43b are integrally formed at the lower end of the antenna cover 43, and the hook-shaped projections are formed. Facing outwards. The pair of hooks 43
Positioned between a and 43b, vertical split 43c
Is provided to facilitate bending of the pair of hooks. As shown in FIG. 1, the terminal member 45 screwed with the λ / 2 helical antenna element 31 is connected to the antenna cover 43.
Is press-fitted into the lower end portion of the antenna cover 43, the small diameter portion of the inner flange 43d formed at the lower end portion of the antenna cover 43 is expanded and inserted, and the inner flange 43d prevents the inner flange 43d from coming off. When the pair of hooks 43a and 43b formed at the lower end of the antenna cover 43 is bent and inserted into the antenna cover mounting hole 44a formed in the housing 44 and engaged,
Quick and easy to install.

In order to ensure the above-mentioned mounted state, the stopper 56 shown in FIG. 2 is provided in this embodiment. This stopper 56 is essentially a pair of hooks 43.
It is configured so as to prevent a and 43b from approaching each other. Furthermore, it is stable in the inserted state,
The stopper 56 is configured as follows so that the stopper 56 does not fall off even if it receives an impact such that it is removed during use. 56c is an arc-shaped outer periphery that forms the main body of the stopper 56, and is configured to fit with the inner periphery of the antenna cover 43 that is a tubular member. The slot-shaped notch 56a is cut along the diameter of the arc-shaped outer periphery 56c. Further, a pair of beak-shaped projections 56b are formed so as to sandwich the slot-shaped notch 56a, and the width dimension W thereof is set so as to fit with the width dimension of the slit 43c. As a result, the beak-shaped projection 56b can be inserted into the slit 43c as shown by the arrow e, and the arc-shaped outer periphery 56c can be inserted while bending the pair of hooks 43a and 43b in the pushing-opening direction using this as a guide. .
To remove the stopper 56, a hand tool may be applied to the through hole 56d and pulled out. Since the stopper 56 can be freely attached and detached like this, the antenna cover 43 can be attached and detached to and from the housing 44 quickly and easily. Since the antenna cover 43 accommodates the λ / 2 helical antenna element 31, the attaching / detaching operation of the entire antenna device can be performed quickly and easily. As a result, not only is communication equipment manufacturer easy to assemble, but it is also convenient for the user to replace the antenna with one with different antenna specifications, and since the antenna manufacturer tests the complete product, it is easy to attach and detach to the tester. , Reduce costs. FIG. 3 is a cross-sectional side view schematically showing the helical antenna mounting structure of the embodiment shown in FIG. 1 mentioned above by cutting along a vertical plane perpendicular to FIG. 1 for easy reading. Since it is schematic, it is not necessarily a realistic projected figure. (Figs. 1 and 3
(See contrast). A substrate 55 for an exciter is formed separately from the wireless device substrate 27, and an exciter 46 (FIG. 3) is formed on one surface of the exciter substrate 55. In this figure, the exciter 4
Although the cross section of No. 6 appears, its plane figure is shown in FIG.
3, similar to the λ / 4 exciter 22 shown in FIG. 14,
It is configured to resonate at approximately λ / 4. The notch provided in the exciter board 55 and the terminal member 45.
The rectangular hook formed at the lower end of the exciter is engaged with each other and positioned relative to each other, and the electrostatic capacitance between the open end of the exciter 46 and the terminal member is regulated so as to be a substantially critical coupling.
In this embodiment, the exciter board 55 is the radio board 27.
Since it is configured separately from (Fig. 1), the exciter substrate 5
The exciter 46 (FIG. 2) formed on the cable 5 and the high-frequency circuit of the main body of the communication device are connected and conducted by the coaxial cable 47. FIG. 4 shows a helical antenna mounting structure according to an embodiment different from the above-described FIGS. 1 to 3, and is a sectional front view schematically corresponding to FIG. 1 in the embodiment and partially cut away. . The embodiment shown in FIG. 4 corresponds to the above-mentioned embodiment (FIG.
-(A) The exciter 46 is formed on one side of the radio device substrate 51 and the dedicated exciter substrate is omitted, and (b) ) As a means for attaching the antenna cover 48 to the housing 50, the bayonet 4
8a is provided. Next, the above (a) and (b)
The detailed structure of the configuration will be described. FIG. 5 is a sectional side view schematically showing the mounting structure of the helical antenna according to the present embodiment, which is cut along a vertical plane orthogonal to the cutting plane in FIG. 4 and is partially broken. As can be easily understood by comparing both FIGS. 5 and 4, the location where the wireless device substrate 51 and the terminal member 49 face each other, and the wireless device substrate 51 faces and contacts the terminal member 49. An exciter 46 is formed on the surface opposite to the rotating surface. When the exciter is formed on the radio device substrate in this manner, it is not necessary to form a separate substrate for the exciter, so that the number of constituent members is small, and moreover, the circuit pattern of the radio device substrate 51 (not shown). Since it is possible to form a pattern that functions as the exciter 46 at the same time as the film forming, exposure, and development operations, the manufacturing cost is effectively reduced. 6 is an exploded perspective view of a bayonet mechanism for mounting the antenna cover in the housing in the helical antenna mounting structure according to the embodiment shown in FIGS. 4 and 5 above, and a chain line showing the assembling operation. It is the figure which added the arrow. An inner flange 50b is formed at the lower end of an antenna mounting hole 50c formed in the housing 50, and the antenna cover 48 is mounted in the mounting hole 50 in the direction of arrow f.
When it is inserted into c, it acts as a stopper. On the other hand, the lower end of the antenna cover 48 is provided with a bayonet 48 having a fan-shaped divided flange, and the antenna mounting hole 50 of the housing 50 is correspondingly provided with the bayonet 48.
On the inner peripheral surface of c, a bayonet 50a having a fan-shaped divided inner flange is provided. As a result, the antenna cover is inserted as shown by the arrow f and the inner flange 50b is inserted.
Then, the antenna cover 48 is mounted by turning it in the direction of arrow g, and the antenna cover 48 is removed in the reverse procedure. This Figure 6
What is surrounded by a chain line frame is a modification of the above-mentioned embodiment, and the same operation and effect can be obtained.

As shown in FIGS. 4 and 5, the antenna cover 48 and the terminal member 49 are prevented from coming off by a coupling pin 52. The retaining pin 52 does not need to be made of metal because it has no electrical role. Further, the coupling pin 52 is not a member for mounting the antenna cover 48 on the housing 50. In the embodiment shown in FIGS. 4 and 5, one end of the λ / 2 helical antenna element 31 is screwed to the terminal member 49, and the antenna is inserted from the other end side of the λ / 2 helical antenna element 31. When inserted into the cover 48, the terminal member 49 is fitted into the open end of the antenna cover 48 and is prevented from coming off by the coupling pin 52, one antenna device assembly is formed, and is used for counting, storage and transportation. It is convenient and has the form of a product shipped from the antenna manufacturer. Then, the wireless communication device manufacturer immediately attaches the helical antenna by connecting the supplied antenna cover 48 of the above-described antenna device assembly to the housing 50 by bayonet coupling.

It is possible to quickly and easily use the output connector 53 shown in FIG. 4 to measure the characteristics of the antenna with the antenna device assembly mounted on the housing 50. The output connector 53 has a built-in switch function, is connected to a high-frequency circuit (not shown) via the microstrip line 24, and has an exciter 46.
Is connected by a solder bridge 54 to the input end of. When a plug of a tester (not shown) is inserted into the output connector 53, the exciter 46 and the microstrip line 24 are automatically disconnected, and the exciter 46 is connected to the tester. It is unlikely that the antenna device assembly manufactured by the antenna manufacturer under the high quality control and shipped after the inspection has a performance defect. However, when the antenna device assembly is mounted on the housing 50, the terminal member 49 and the exciter are installed. The output connector 53 is used to confirm whether or not the combined capacitance value formed between the output connector 53 and 46 is appropriate.
By connecting a tester (not shown) to the tester, it is possible to perform a test with a high degree of reliability. After the test, if the tester is unplugged, the conductive state of the output connector 53 is restored.

[0021]

When the present invention is applied, which is a characteristic effect of the previously unknown invention (Japanese Patent Application No. 6-250753), a. Have wideband tuning characteristics, b. No need to pull out or push in the antenna, c. The length of the antenna protruding from the housing is not large,
d. All antenna elements are installed outside the case to eliminate unnecessary radio wave loss, and e. The helical antenna element is housed in a cylindrical antenna cover having a bottom without a mechanical contact / conduction not required for connecting the antenna, thereby forming one assembly. Since it is organized in this way, it has independence as a product shipped from the antenna manufacturer and distributed in the market, and it is also possible to easily provide compatibility as an antenna device assembly, It is possible to adapt to the diversification of mobile radio specifications while ensuring the cost reduction effect of mass production. Further, since the above antenna cover is mounted on the housing by the engagement of the concavities and convexities, a separate member for coupling is not required, which reduces the number of component parts and facilitates quick and easy assembly work. Can be done When the bayonet is used as the unevenness, it can be attached simply by inserting it and twisting it, and it is easy to remove it by the reverse procedure, so if you need it quickly, It can also be replaced easily. In addition, the quick and easy attachment / detachment property is convenient for inspecting finished products, and the operation of attaching / testing / removing the tester can be efficiently performed. In addition, when a pair of hooks formed integrally with the antenna cover is used as the above-mentioned unevenness, when the antenna cover housing the helical antenna is attached to the housing of the wireless device, the angular position around the axial center of the antenna cover is fixed. Since there is no need to regulate the mounting work, the mounting work can be easily controlled, which is suitable for automating the mounting work, and the automation can further reduce the assembly cost. As described above, when the antenna cover is engaged with the housing by the pair of hooks, the stopper can be stabilized by mounting the stopper that prevents the pair of hooks from bending, but the stopper member in this case is Since it does not need to be made of metal, the object of the present invention of attaching the antenna cover to the housing without using a metal attachment member is achieved, and a practical effect is achieved.

[Brief description of drawings]

FIG. 1 is a schematic sectional front view showing a partial embodiment of a helical antenna mounting structure configured to carry out a method of mounting a helical antenna according to the present invention, with a part broken away.

FIG. 2 is a perspective view in which a stopper is added to a perspective view showing a lower end portion of an antenna cover and a terminal member in the helical antenna mounting structure according to the embodiment shown in FIG. 1 above.

FIG. 3 is a cross-sectional side view schematically showing the helical antenna mounting structure of the embodiment shown in FIG. 1 mentioned above, which is cut along a vertical plane perpendicular to FIG. 1 for easy reading. It is not necessarily a realistic projection figure because it is modeled in.

FIG. 4 is a sectional front view schematically showing a helical antenna mounting structure according to an embodiment different from the above-described FIGS. 1 to 3 and corresponding to FIG. is there.

5 is a cross-sectional side view schematically showing the mounting structure of the helical antenna according to the present embodiment, which is cut along a vertical plane orthogonal to the cutting plane in FIG. 4 and is partially broken.

FIG. 6 is an exploded perspective view of a bayonet mechanism for mounting the antenna cover in the housing in the helical antenna mounting structure according to the embodiment shown in FIGS. It is the figure which added.

FIG. 7 is a cross-sectional view showing a conventional antenna support / mounting structure in which a non-telescopic antenna can be projected and housed.

FIG. 8 is a known antenna support, which is an improved version of the above conventional example.
It is a typical perspective view showing an attachment structure.

FIG. 9 is a view for explaining the basic principle of the prior invention and is a diagram depicting an electrical system.

FIG. 10 is a perspective view schematically showing an embodiment of the antenna support / connection structure according to the prior invention.

FIG. 11 is an RF for explaining tuning characteristics in one embodiment of the antenna support / connection structure according to the preceding invention.
It is a L SWR characteristic graph.

FIG. 12 is a schematic perspective view showing an example of an antenna connection structure for a mobile communication device according to the prior invention.

FIG. 13 is a cross-sectional view of the connection structure of the mobile communication antenna according to the above embodiment. However, for the sake of convenience of reading, the dimensional relationship of each constituent member is appropriately changed, and it is not necessarily an accurate projected figure, and further, a portion overlapping the leader line is broken and drawn.

FIG. 14 is an exploded perspective view showing an essential part extracted for illustrating an embodiment different from the above.
(A) shows an embodiment characterized by a mounting structure portion of a λ / 2 helical antenna element, and (B) shows an embodiment having a mounting structure portion different from the above.

15 is an RFL in the embodiment shown in FIG. 1 above.
FIG. 11 is a SWR characteristic graph shown in FIG.
It is a chart corresponding to.

[Explanation of symbols]

2 ... Conventional connection fittings, 3, 3 '... Similarly insulating coated antenna, 5 ... Same connection fitting, 6 ... Similarly contact spring, 7 ... Known example antenna, 8 ... Similar spiral coil, 9
... also λ / 4 radiator, 13 ... antenna element according to the preceding invention, 14, 14A ... similarly exciter, 15 ... also coupling capacity, 16 ... feeding line, 17 ... ground plate, 19
... radio device main body, 22 ... λ / 4 exciter, 22a ... exciter open end, 22b ... exciter feed end, 23 ... base plate, 24 ... microstrip line, 25 ... coupling capacitance, 26 ... housing, 26b ... nut member, 26c ... female screw hole, 27 ... radio device substrate, 28 ... shield case, 29 ... radio device main body,
31 ... λ / 2 helical antenna element, 31a ... Antenna open end, 31c ... Zero pitch part, 32 ... Antenna cover, 32a ... Flange, 32b ... Snap ring, 43
... antenna cover, 43a, 43b ... a pair of hooks, 4
3c ... Cutting, 43d ... Inner flange, 44 ... Housing, 44a
... Antenna mounting hole, 45 ... Terminal member, 46 ... Exciter, 4
7 ... Coaxial cable, 48 ... Antenna cover, 48a ... Bayonet, 49 ... Terminal member, 50 ... Housing, 50a ... Bayonet, 50b ... Inner flange, 50c ... Antenna mounting hole, 51 ... Radio device main body, 52 ... Coupling pin, 53 ... Output connector, 54 ... Solder bridge, 55 ... Exciter board, 56
... stopper, 56a ... slot-shaped notch, 56b ... beak-shaped projection,
56c ... Circular arc-shaped outer periphery, 56d ... Through hole, a, b ... Arrow indicating the expansion / contraction direction of the antenna according to the conventional example, c, d ... Arc arrow indicating the tilting direction of the antenna according to the conventional example, e ... Mounting direction of stopper , F ... an arrow indicating the insertion direction of the antenna cover, g ... an arrow indicating the direction in which the antenna cover is rotated to connect the bayonet, W ... the width of the beak-like protrusion of the stopper.

Claims (22)

[Claims] 1. A large portion of a helical antenna element that resonates at approximately λ / 2 is supported by being projected outside the housing, and an open end of an exciter that resonates at approximately λ / 4 is opposed to the helical antenna element. , A method of connecting an antenna which is spaced apart to form a coupling capacitance between the exciter and the helical antenna element, wherein the helical antenna element is housed in a capped bottomless cylindrical antenna cover. Then, the irregularities formed on the casing and the irregularities formed on the antenna cover are engaged with each other to fix them to each other, and a conductive terminal member is attached to one end of the helical antenna to conduct electricity, A method of mounting a helical antenna, characterized in that a conductive terminal member is opposed to and spaced apart from the open end of the exciter to form a coupling capacitance. 2. The method of mounting a helical antenna according to claim 1, wherein the concavities and convexities formed on and engaged with the casing and the antenna cover are formed by a bayonet mechanism. 3. The antenna cover is made of an elastic material, and a pair of hooks having a shape protruding toward the outer peripheral side are integrally formed near the lower end portion of the antenna cover, and It is positioned between a pair of hooks to form a vertical slit, and the hook is engaged with the edge of a mounting hole formed in the housing to prevent the groove width of the slit from decreasing. The method of attaching a helical antenna according to claim 1, wherein a stopper is attached near the lower end of the antenna cover. 4. A slot-shaped notch that slidably fits with the terminal member, an outer periphery that fits with the inner diameter of the antenna cover, and a slit with the antenna cover that fit in the stopper. 4. A beak-shaped protrusion is formed, and the beak-shaped protrusion is inserted into the slit from the side of the antenna cover, and is fitted to the antenna cover as a guide. How to install the helical antenna described in. 5. The antenna cover is made of an elastic material, an inner flange-shaped small-diameter portion is formed on the inner peripheral surface of the lower end of the antenna cover, and the terminal member is fixed to one end of the helical antenna. In this state, the helical antenna is inserted into the antenna cover, the antenna cover is elastically bent, the terminal member is press-fitted inside the small diameter portion, and the terminal member to which the helical antenna is fixed is fixed to the antenna. The helical antenna mounting method according to claim 1, wherein the helical antenna is mounted on a cover. 6. The antenna cover, wherein the terminal member is fixed to one end of the helical antenna, and the other end of the helical antenna is inserted from a lower end portion of an antenna cover and housed in the antenna cover. 4. The helical antenna according to claim 1, wherein a pin-shaped member is inserted through the terminal member and the terminal member to fix the terminal member to the antenna cover. How to install. 7. A substrate for an exciter is provided separately from a substrate forming a high-frequency circuit to which the helical antenna element is connected, the exciter is formed on the substrate, and the terminal member is the above-mentioned exciter. And a coupling capacitance is formed between the terminal member and the open end of the exciter by engaging with the circuit board.
A method for mounting the helical antenna according to any one of claims 1 to 6. 8. The exciter substrate is arranged substantially at right angles to the helical antenna element, and a hook-shaped portion is formed on the terminal member, and the hook-shaped portion is engaged with the exciter substrate. 8. The method for mounting a helical antenna according to claim 7, wherein the helical structure is positioned, and the input end of the exciter and the high frequency circuit are connected by a coaxial cable. 9. The exciter is formed on a substrate forming a high-frequency circuit to which the helical antenna element is connected, and the terminal member is made to face the exciter so that the terminal member and 7. The method of mounting a helical antenna according to claim 1, wherein a coupling capacitance is formed between the exciter and an open end of the exciter. 10. The method for mounting a helical antenna according to claim 9, wherein the open end of the exciter and the high frequency circuit are connected by a microstrip line via an output connector with a switch. . 11. The densely wound portion of the helical antenna element is formed by forming the input end of the helical antenna element in a tightly wound shape and forming a male screw-shaped spiral groove in an upper portion of the terminal member. The lower end of the terminal member faces the open end of the exciter so that the value of the electrostatic capacitance formed between them becomes substantially critical. The method for mounting the helical antenna according to claim 1, wherein the both are relatively positioned. 12. A helical antenna element that resonates at approximately .lamda. / 2 is supported by projecting it out of the housing, and an open end of an exciter that resonates at approximately .lamda. / 4 is opposed to the helical antenna element. , In an antenna connection structure in which the exciter and the helical antenna element are separated from each other to form a coupling electrostatic capacitance, the helical antenna element is housed in a capped bottomless cylindrical antenna cover. The projections and depressions formed on the housing and the projections and depressions formed on the antenna cover are engaged with each other so that the two are fixed to each other. A conductive terminal member is attached to one end of the helical antenna so as to conduct electricity. A mounting structure for a helical antenna, characterized in that a coupling capacitance is formed by making the conductive terminal member and the open end of the exciter face each other and away from each other. 13. The mounting structure for a helical antenna according to claim 12, wherein the concavities and convexities formed on and engaged with the housing and the antenna cover are made of a bayonet mechanism. 14. The antenna cover is made of an elastic material, and a pair of hooks having a shape protruding toward the outer peripheral side are integrally formed near the lower end portion of the antenna cover, and A vertical slit is formed by locating the hook between a pair of hooks, and the hook engages with an edge of a mounting hole formed in the housing to reduce the groove width of the slit. 13. The attachment structure for a helical antenna according to claim 12, wherein a stopper having a blocking shape is attached near the lower end of the antenna cover. 15. The stopper is fitted into a slot-like notch slidably fitted to the terminal member, an outer circumference fitted to the inner diameter of the antenna cover, and a notch of the antenna cover. The mounting structure for a helical antenna according to claim 14, wherein a beak-shaped protrusion is formed. 16. The antenna cover is made of an elastic material, and an inner flange-shaped small diameter portion is formed on an inner peripheral surface of a lower end portion of the antenna cover, and the terminal member is press-fitted inside the small diameter portion. The mounting structure for a helical antenna according to any one of claims 12 to 14, wherein: 17. The terminal member is fixed to one end of the helical antenna, and the other end of the helical antenna is inserted from the lower end portion of the antenna cover and housed in the antenna cover. The pin-shaped member is inserted through the antenna cover and the terminal member to fix the terminal member to the antenna cover, according to any one of claims 12 to 14. Helical antenna mounting structure. 18. A substrate for an exciter is provided separately from a substrate forming a high frequency circuit to which the helical antenna element is connected, and the exciter is formed on the substrate. The terminal member is engaged with the exciter substrate,
18. The helical antenna mounting structure according to claim 12, wherein a coupling capacitance is formed between the terminal member and the exciter open end. 19. The substrate for the exciter is disposed substantially at right angles to the helical antenna element, and a hook-shaped portion is formed on the terminal member, and the hook-shaped portion engages with the substrate for the exciter. 19. The mounting structure for a helical antenna according to claim 18, wherein the exciter input end and the high-frequency circuit are connected by a coaxial cable. 20. The exciter is formed on a substrate forming a high frequency circuit to which the helical antenna element is connected, and the terminal member is made to face the exciter, and the terminal is provided. 18. The mounting structure for a helical antenna according to claim 12, wherein a coupling capacitance is formed between the member and the open end of the exciter. 21. The helical antenna according to claim 20, wherein the open end of the exciter and the high frequency circuit are connected by a microstrip line via an output connector with a switch. Connection structure. 22. The input end of the helical antenna element is formed in a close-wound shape, and a male screw-shaped spiral groove is formed in an upper portion of the terminal member. The portion is screwed into the spiral groove to be electrically connected and fixed, and the lower end portion of the terminal member is opposed to the open end of the exciter, so that the capacitance value formed between them is substantially critical. 22. The mounting structure for a helical antenna according to claim 12, wherein the both are relatively positioned so as to be coupled.