JP2007158880A - Antenna - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an antenna which is excellent in mass-productivity and can be made compact while suppressing the influence of a cable. <P>SOLUTION: In the antenna 1, an antenna element is formed as a dipole antenna by arranging a long first conductive pattern 11 and a second conductive pattern 12. A cable 4 connected to a second conductive pattern connecting part 121 being a base part of the second conductive pattern 12 is wired toward a front part. The second conductive pattern 12 is provided with a notch part 13 along the cable 4. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an antenna in which an antenna element is formed by arranging a long conductive pattern on a printed circuit board, and a cable connected to the base of the conductive pattern is wired toward the front.

Patent Document 1 discloses an antenna in which an antenna element is formed by arranging a long conductive pattern on a printed board. In the antenna unit described in Patent Document 1, a strip dipole pattern is formed on the surface of a printed circuit board, a hole is formed in the vicinity of the gap portion, and a coaxial cable is stripped from the back side of the printed circuit board through this hole. It is connected to a dipole pattern. Thus, the coaxial cable is wired on the back side opposite to the surface on which the strip dipole pattern is formed, so that the influence of the coaxial cable is not given to the antenna element.
JP-A-11-234027

  However, in the antenna unit described in Patent Document 1, since the coaxial cable is wired from the back side and connected to the pattern that forms the strip dipole through the hole, the end of the coaxial cable is extracted from the hole and bent. The soldering work is inefficient. Therefore, it is difficult to improve the mass productivity, or the solder may adhere to the conductive pattern which is the adjacent antenna element, resulting in a failure, and the yield may be reduced.

  In addition, it is necessary to form a hole that is large enough to allow the cable to be inserted. However, if the antenna is small, the width of the printed circuit board will also be narrowed, which may cause cracking when opening the hole. Miniaturization is difficult.

  Accordingly, an object of the present invention is to provide an antenna that is excellent in mass productivity and can be downsized while suppressing the influence of a cable.

  In the antenna of the present invention, an antenna element is formed by arranging a long conductive pattern on a printed circuit board, and the cable connected to the base of the conductive pattern is routed toward the front. The pattern is characterized in that a notch is provided along the cable.

  The present invention can suppress the influence of the cable even if the cable is wired along the conductive pattern formed on the printed circuit board, so that the cable can be connected from the surface side on which the conductive pattern is formed. . Therefore, it is more efficient and more mass-productive than the work of passing the cable through the hole from the back side. In addition, there is no need to add a new manufacturing process such as providing a cutout in the conductive pattern or a process for forming a hole in the printed circuit board, preventing an increase in manufacturing costs and enabling a reduction in size. is there.

According to a first invention of the present application, in an antenna in which an antenna element is formed by arranging a long conductive pattern on a printed circuit board, and a cable connected to the base of the conductive pattern is wired toward the front part, The pattern is characterized in that a notch is provided along the cable.

  The conductive pattern that forms the antenna element is provided with a notch along the cable, so that a distance can be secured between the cable and the conductive pattern by wiring the cable along the notch. it can. Therefore, since the influence which generate | occur | produces when a cable and a conductive pattern adjoin can be suppressed, wiring of a cable can be performed from the surface side in which the conductive pattern of the printed circuit board was formed.

  According to a second aspect of the present invention, the antenna element is characterized in that a cutout portion is formed so as to branch into a bifurcated shape from the base portion to the tip portion of the conductive pattern.

  For example, if the notch is formed on a long conductive pattern so as to be close to one side, the electric field intensity characteristic of the conductive pattern operating as an antenna element is biased, and the directivity is biased. In the antenna of the present invention, the notch is formed so as to branch into a bifurcated shape from the base of the conductive pattern toward the tip, so that by directing the cable along the notch, directivity characteristics can be obtained. Can be suppressed.

  The third invention of the present application is characterized in that the antenna element is branched into equal widths by the notch.

  When forming the cutout portion so as to branch into a bifurcated shape from the base portion to the tip portion of the conductive pattern, it is desirable to form the cutout portion so that the conductive pattern branches at an equal width. This is because, when the cable is arranged along the notch, a conductive pattern having an equal width is formed on both sides along the cable, so that the electric field strength characteristics can be the same in the conductive patterns on both sides. Because. Therefore, by forming the antenna element so as to branch at equal widths by the notch portion, it is possible to prevent a deviation in directivity.

  According to a fourth aspect of the present invention, the antenna element is provided with a spacer for ensuring a gap between the cable and the conductive pattern.

  When routing the cable along the notch, it is desirable to route the cable as far as possible from the conductive pattern in order to reduce the influence of the cable on the conductive pattern. Therefore, the degree of the influence can be reduced by providing a spacer that secures a gap between the cable and the conductive pattern in the cable wired from the base portion of the conductive pattern toward the tip portion.

  The fifth invention of the present application is characterized in that a resist film is formed on the antenna element except for a base portion to which a cable is connected and a notch portion.

  When forming a resist film to protect the conductive pattern, not only the base part of the conductive pattern to which the cable is connected but also the cutout part is formed. Can be provided. If the cable is routed along the notch, the cable can be routed along the step, so that the workability of the cable routing is improved.

(Embodiment 1)
An antenna according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a front view for explaining an antenna according to an embodiment of the present invention. FIG. 2 is a front view showing a conductive pattern on a printed circuit board constituting the antenna, and shows a state before applying a resist film. FIG.
It is a side view which shows the state which connected the cable to the antenna shown in FIG. FIG. 4 is a perspective view showing a base unit of the cordless telephone apparatus with a facsimile function using the antenna according to the embodiment of the present invention. FIG. 5 is a pattern diagram showing a resist film provided on a printed circuit board. In FIG. 1, cables are omitted for convenience of explanation.

  As shown in FIG. 1 to FIG. 3, the antenna 1 according to the present embodiment is linearly arranged on a long printed board 10 with a first conductive pattern 11 and a second conductive pattern 12 as antenna elements, respectively. This is a 2.4 GHz dipole antenna. The antenna 1 is housed in a cover 3 so as to protrude from the side surface of the base unit 2 of the cordless telephone apparatus with a facsimile function shown in FIG. Cables 4 are connected to the bases of the respective antenna elements of the antenna 1, and are wired into the main unit 2 along one of the antenna elements.

  The printed circuit board 10 is a single-sided printed circuit board formed of glass epoxy resin and having only the first conductive pattern 11 and the second conductive pattern 12 formed on one side. The size of the printed circuit board 10 is about 75 mm in the longitudinal direction and about 5 mm in the width direction.

  The first conductive pattern 11 is a long rectangular pattern. The first conductive pattern 11 has a longitudinal direction of about 24 mm and a width direction of about 4 mm, and is formed of a copper foil. When the antenna 1 is arranged vertically, the first conductive pattern 11 is positioned above the second conductive pattern 12.

  The second conductive pattern 12 is long and has a notch 13 formed so as to branch bifurcated from the base toward the tip. The second conductive pattern 12 is approximately 24 mm in the longitudinal direction and approximately 4 mm in the width direction, and is formed of a copper foil.

  The notch 13 is formed in a rectangular shape toward the tip, leaving about 2 mm of the base of the second conductive pattern 12, and is formed so that the branched second conductive pattern 12 has a uniform width.

  A resist film 14 is formed on the printed circuit board 10 on which the first conductive pattern 11 and the second conductive pattern 12 are formed (see FIG. 5).

  As shown in FIG. 5, the resist film 14 is formed on almost the entire surface of the printed circuit board 10, but is formed in a “+” shape at the position of the base of the first conductive pattern 11 in order to connect the cable 4. The first conductive pattern connection portion 111 and the second conductive pattern connection portion 121 formed in a “□” shape at the base position of the second conductive pattern 12 are excluded. The first conductive pattern connection part 111 and the second conductive pattern connection part 121 have different shapes, thereby making it easy to identify the connection position of the cable 4.

  In addition, the concave portion 101 is formed on the printed circuit board 10 by forming the resist film 14 by partially excluding the notch 13 portion continuously with the second conductive pattern connection portion 121.

  The recess 101 is formed in a rectangular shape, and is not formed with the resist film 14, thereby forming a recess corresponding to the thickness of the second conductive pattern 12 and the resist film 14. An alignment portion 102 for aligning a spacer, which will be described later, is provided at the tip of the recess 101 by not forming the resist film 14.

When the alignment unit 102 connects the cable 4 to the first conductive pattern connection unit 111 and the second conductive pattern connection unit 121 and performs wiring toward the tip of the second conductive pattern 12,
The position when the spacer 15 (see FIG. 3) is arranged is shown. The alignment portion 102 is formed in a rectangular arrangement portion 102a indicating the position of the end where the spacer 15 is arranged, a narrow portion 102b formed by narrowing the width from the arrangement portion 102a, and the arrangement portion 102a. An adhesive portion 102c is formed.

  The spacer 15 is formed of an elongated rectangular parallelepiped sponge. The spacer 15 can be made of other materials as long as the space between the second conductive pattern 12 and the cable 4 can be secured when the cable 4 is wired. However, when the cable 4 is placed, the spacer 15 is elastically deformed. The material is desirable because the cable 4 can be stabilized when wiring. For example, soft rubber or resin can be used.

  The cable 4 is less susceptible to external influences and is less likely to affect the outside, so the coaxial cable is used in the present embodiment. However, the cable 4 is connected to the first conductive pattern 11 and the second conductive pattern 12 and is If the signal can be wired, it can be used other than the coaxial cable. The core wire of the cable 4 is connected to the first conductive pattern connecting portion 111 and the mesh wire is connected to the second conductive pattern connecting portion 121, and is wired to the main unit 2 main body.

  A method for attaching the cable 4 to the antenna 1 according to the embodiment of the present invention configured as described above will be further described with reference to FIGS. 6A to 6D are views for explaining a method of attaching a cable to the antenna according to the embodiment of the present invention. FIG. 7 is an enlarged view of a portion A in FIG.

  6A, first, an antenna 1 is prepared in which a first conductive pattern 11 and a second conductive pattern 12 are formed on a printed board 10 and a resist film 14 is formed.

  In the antenna element of the antenna 1, the first conductive pattern 11 and the second conductive pattern 12 can be formed by etching on the surface of the printed board 10 on which the copper foil surface is formed. Therefore, even if the second conductive pattern 12 has a shape branched from the base portion to the front portion, a special manufacturing process can be performed only by producing a mask pattern to be etched according to this shape. It can be formed without adding. Therefore, it can be formed without increasing the manufacturing cost. Moreover, since it is a single-sided printed circuit board, it can be manufactured inexpensively.

  As shown in FIG. 6B, the core wire of the cable 4 is soldered to the first conductive pattern connecting portion 111 of the first conductive pattern 11 and the mesh wire is soldered to the second conductive pattern connecting portion 121 of the second conductive pattern 12. . Since the soldering operation of the cable 4 can be performed from the surface side on which the first conductive pattern 11 and the second conductive pattern 12 connecting the cable 4 are formed, the workability is not deteriorated.

  As shown in FIG. 6C, after connecting the cable 4, a spacer 15 is inserted between the cable 4 and the printed board 10. In inserting the spacer 15, first, an adhesive is applied to the bonding portion 102c. Since the second conductive pattern 12 is not formed by the cutout portion 13 and the resist film 14 is not formed, the bonding portion 102 c is a depression that is one step lower than the surface of the resist film 14. Therefore, it is difficult for the adhesive to flow out of the recess when the adhesive is applied, and thus the variation in the application of the adhesive by the operator can be suppressed.

  And after apply | coating an adhesive agent to the adhesion part 102c, the spacer 15 is arrange | positioned. Here, the alignment of the spacer 15 will be described in detail with reference to FIG.

As shown in FIG. 7, the spacer 15 is mounted with the end of the spacer 15 aligned with the center position (L1 indicated by a one-dot chain line in the drawing) of the arrangement portion 102 a of the alignment portion 102. Even if no mark is provided on the printed circuit board 10 to recognize the center position of the arrangement portion 102a, which is the arrangement position of the spacer 15, to the operator, the narrow portion 102b is formed. By recognizing the arrangement portion 102a using the narrow portion 102b as a mark, the center position can be easily identified. In this way, the cable 4 is wired to the antenna 1 from the second conductive pattern connecting portion 121 toward the tip of the second conductive pattern 12 (see FIG. 6D).

  When connecting the cable 4 to the second conductive pattern connecting portion 121, the mesh wire is connected in a state where the outer cover of the cable 4 is peeled off. Therefore, while the diameter of the cable 4 is thin in the second conductive pattern connection portion 121, the warp is thicker at the position of the cutout portion 13 where the outer skin is not peeled off. Therefore, a bending stress is applied to the connection portion of the cable 4 due to the inclination from the second conductive pattern connection portion 121 to the spacer 15. However, since the notch 13 is provided with the concave portion 101 in which the resist film 14 is not formed, the outer cover of the cable 4 is slightly formed at the step corresponding to the thickness of the resist film 14 and the thickness of the second conductive pattern 12. Although it fits. Therefore, the inclination can be relaxed to the spacer 15 and the workability is improved because the wiring of the cable 4 is guided.

  Since the concave portion 101 and the alignment portion 102 are provided by not forming the resist film 14, it can be dealt with only by changing the plate when the resist film 14 is formed. Therefore, since it is not necessary to perform special printing with silk or the like, it can be formed without increasing the manufacturing cost.

  Thus, since the notch 13 is provided along the cable 4 in the second conductive pattern 12 forming the antenna element, the cable 4 and the cable 4 can be connected to the notch 13 along the cable 4. A distance can be secured between the second conductive pattern 12 and the second conductive pattern 12. Accordingly, it is possible to prevent the deterioration of characteristics that occur when the cable 4 and the second conductive pattern 12 are close to each other. Further, since the space between the cable 4 and the second conductive pattern 12 is further secured by the spacer 15, the characteristics can be further improved. Further, since the second conductive pattern 12 is bifurcated from the second conductive pattern connecting portion 121 and each is formed with an equal width, it is possible to prevent the deviation of directivity.

  As mentioned above, although embodiment of this invention has been described, this invention is not limited to embodiment. For example, in the present embodiment, a dipole antenna in which a pair of conductive patterns are arranged linearly has been described as an example. However, an antenna element is used in which a conductive pattern is arranged on a printed circuit board and a cable is wired along the conductive pattern. Any antenna can be used.

  Since the present invention is excellent in mass productivity and can be reduced in size, an antenna element is formed by arranging a long conductive pattern on a printed circuit board, and a cable connected to the base of the conductive pattern is a leading portion. It is suitable for an antenna wired toward

The front view explaining the antenna which concerns on embodiment of this invention The front view which shows the conductive pattern on the printed circuit board which comprises the antenna which concerns on embodiment of this invention The side view which shows the state which connected the cable to the antenna shown in FIG. The perspective view which shows the main | base station of the cordless telephone apparatus with a facsimile function using the antenna which concerns on embodiment of this invention Pattern diagram showing the resist film provided on the printed circuit board The figure explaining the method to attach a cable to the antenna which concerns on embodiment of this invention Part A enlarged view in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Antenna 2 Base unit 3 Cover 4 Cable 10 Printed circuit board 11 1st conductive pattern 12 2nd conductive pattern 13 Notch part 14 Resist film 15 Spacer 101 Concave part 102 Positioning part 102a Arrangement part 102b Narrow part 102c Adhesion part 111 1st Conductive pattern connection part 121 Second conductive pattern connection part

Claims (5)

In an antenna in which an antenna element is formed by arranging a long conductive pattern on a printed circuit board, and a cable connected to the base of the conductive pattern is wired toward the front part,
The antenna, wherein the conductive pattern is provided with a notch along the cable. 2. The antenna according to claim 1, wherein the antenna element is formed with the notch so as to branch into a bifurcated shape from a base portion to a tip portion of the conductive pattern. The antenna according to claim 2, wherein the antenna element is branched at an equal width by the notch. The antenna according to any one of claims 1 to 3, wherein the antenna element is provided with a spacer that secures a gap between the cable and the conductive pattern. 5. The antenna according to claim 1, wherein a resist film is formed on the antenna element except for a base portion to which the cable is connected and the notch portion.

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