JP3757203B2 - Small receiving antenna - Google Patents

Description

【００１８】
積層磁芯の両端部のスペーサ１４により、本発明は従来例に比べ電波の受信感度の指数となるＱ特性が高く、しかも、インダクタンス値の劣化がなく、電波受信アンテナとして優れ、電波受信アンテナの小型化を可能とするものである。
【００１９】
【００２０】
【表２】
【００２１】
【００２２】
（実施例２）Ｃｏ基アモルファス薄帯より、図２に示す略Ｈ形の中央のコイル巻回部である直状部１７が１．４ｍｍ×１５ｍｍ、両端部１８はそれぞれ２．２ｍｍ×４．５ｍｍのアモルファス片１５を作製し、Ｃｏ基アモルファスの軟磁気特性が得られる熱処理、磁場中熱処理を施し、前記略Ｈ形のアモルファス片１５を４０枚積層して積層厚１．１ｍｍの積層磁芯１６とした。積層磁芯１６の直状部１７に０．１φ−１１９５ターンのコイルを設けた。この時の４０ｋＨｚにおけるインダクタンスは２０ｍＨであった。本発明の実施例２は図２に示すくさび状で最大厚０．５ｍｍのスペーサ１９を前記積層磁芯１６の両端部１８の積層を２分割するよう挿入したもの（スペーサ有）とし、従来技術である積層磁芯１６の両端部１８にスペーサ１９を設けないもの（スペーサ無）とのＱ特性の比較を図３に示す。
【００２３】
図３に示すとおり、本発明であるスペーサ有の積層磁芯１６の両端部１８にスペーサ１９を設けたものは、スペーサ１９を使用しない従来技術であるスペーサ無のものに対して、明らかにＱ特性が優れており、小型の電波受信アンテナの提供を可能とするものである。
【００２４】
以上記載のとおり、本発明は標準電波を受信する電波ウォッチに内蔵する電波受信アンテナの小型化を可能としたものであるが、本発明は前記時計に限定するものでなく、例えば車、各種モバイル機器、認証カード等へ内蔵し、所定の電波を受信する小型の受信アンテナに使用できるものである。
【００２５】
【発明の効果】
本発明は、金属系軟磁性材であるアモルファス片の積層体からなる受信アンテナ用磁芯の特性を向上させることができ、受信アンテナの小型化、電波受信感度の向上がはかれ、電波ウォッチ等の商品の小型化、受信性能アップを可能とした。
【図面の簡単な説明】
【図１】本発明の小型受信アンテナの第１の実施形態を示すアンテナの断面図
【図２】本発明の小型受信アンテナに第２の実施形態を係るアモルファス片からなる積層磁芯の斜視図
【図３】本発明の小型受信アンテナのＱ特性図
【図４】従来のフェライト受信アンテナの斜視図
【符号の説明】
１１ アモルファス片
１２ コイル
１３ ボビン
１３ａ フランジ
１４ スペーサ
θ スペース１４による積層磁芯両端の空間角度 [0001]
BACKGROUND OF THE INVENTION
The present invention relates to a small-sized antenna for a watch that receives a long-wave standard wave and a small antenna that receives a radio wave that carries data.
[0002]
[Prior art]
In recent years, radio clocks have attracted attention in the watch industry. This radio-controlled timepiece is a long-wave standard radio wave transmitted from the standard radio transmitting station in Otakadoya and Mt. Fukushima and the standard radio transmitting station in Mt. It is a watch with an automatic time correction function that uses (hereinafter referred to as a standard radio wave). The standard radio wave is a long wave band in which the data of Japan Standard Time is superimposed. 40 kHz is transmitted from Otakado and Mt., and 60 kHz is transmitted from Mt. Hagane. Each standard radio wave is received by the antenna built in the watch, The time of the clock is corrected to the correct time based on Japan Standard Time data.
[0003]
Radio clocks can be divided into watch watches, table clocks, and wall clocks. Radio receiving antenna 23 of the clock has a structure in which the coil 22 is wound around the rod-shaped magnetic core 21 made of inexpensive ferrite, as shown in FIG. On the other hand, a radio wave receiving antenna for a watch needs to be stored in a limited space, and is required to have a small size, a thin shape, and a necessary reception sensitivity.
[0004]
Conventional wristwatch radio receiving antenna, but those with core rod-shaped ferrite shown in FIG. 4 were common, for make reduce the occupied volume of the antenna in the watch, the shape other than a bar-like be used Yes. (For example, see Patent Document 1)
[0005]
In addition, there is amorphous as a magnetic core material for a receiving antenna that is replaced by ferrite. Amorphous compared to ferrite, excellent soft magnetic properties, having a flexibility for deformation, compact and radio receiving antenna which enables thinner. (For example, see Patent Document 2)
[0006]
[Patent Document 1]
Japanese Patent Laying-Open No. 2001-102832 (second page, FIG. 1)
[Patent Document 2]
JP-A-7-278763 (page 2, pages 5-8)
[0007]
[Problems to be solved by the invention]
A radio wave receiving antenna made of a ferrite magnetic core is vulnerable to impacts, and when a watch incorporating the radio wave receiving antenna is dropped , the ferrite magnetic core is cracked, cracked, etc., thereby hindering the function as a radio timepiece. On the other hand, a radio wave reception antenna using an amorphous magnetic core is strong against impact, but has a lower Q characteristic that affects radio wave reception sensitivity than ferrite, making it difficult to reduce the size of the radio wave reception antenna. Was enlarged.
[0008]
The present invention improves the Q characteristic of the amorphous magnetic core, and enables the miniaturization of the radio wave antenna, it is an object to provide a compact radio watch.
[0009]
[Means for Solving the Problems]
The present invention relates to an antenna using a laminated magnetic core formed by laminating amorphous pieces produced by punching or cutting an amorphous ribbon, and a coil is wound around the center of the laminated magnetic core , and the winding axis direction of the coil is A small receiver that inserts spacers that divide the laminations at both ends of the laminated magnetic core, and that both ends of the laminated magnetic core protrude outward in the lamination direction from the lamination thickness of the coil winding part in which the lamination direction at the center of the laminated magnetic core is fixed It is an antenna.
[0010]
Further, the present invention is an antenna using a laminated magnetic core formed by laminating amorphous pieces produced by punching or cutting an amorphous ribbon, and compared with the magnetic core cross-sectional area of the coil winding portion in which the lamination direction is fixed , the core cross-sectional area of the laminated magnetic core end portions are small receiving antenna size Kushida described above.
[0011]
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a sectional view of a receiving antenna showing a first embodiment of the present invention . A bobbin 13 having a hollow bore of an insulating resin, a laminated magnetic core consisting of strip-like amorphous piece 11 that fits into the hollow hole is the radio receiving antenna consisting of the coil 12 which is wound between the flanges 13a of the bobbin 13 . At both ends of the laminated magnetic core by spacer 14 to divide the amorphous piece 11 to be stacked, as compared to the laminated portion of the coil winding portion which is fixed by the hollow hole of the amorphous strip 11 is the bobbin 13 to be stacked in the laminated magnetic core end portions forming a shape projecting downward Te.
[0013]
The laminated magnetic core formed by laminating the amorphous pieces 11 can maintain a shape in which both ends of the laminated magnetic core shown in FIG. 1 protrude downward according to the shape of the hollow hole of the bobbin 13 by providing the spacers 14. The spacer 14 is a non-magnetic material that does not affect the soft magnetic properties of the amorphous amorphous magnetic core material. The shape of the spacer 14 is not particularly specified, but if it is a substantially wedge shape as shown in FIG. The amorphous pieces 11 to be laminated are not suddenly deformed. In FIG. 1, both ends of the laminated magnetic core protrude downward only, but both ends of the laminated magnetic core may protrude in the vertical direction by changing the shape of the hollow hole of the bobbin 13 . Furthermore, a large extent the projection of the laminated magnetic core ends by spacers 14 may, the spatial angle θ for dividing a stack of laminated magnetic core ends by spacer 14 is preferably at least 30 degrees, preferably more if space angle θ is 45 degrees or more .
[0014]
The laminated magnetic core made of the amorphous piece 11 in FIG. 1 improves the focusing property of the magnetic flux of the laminated magnetic core . By providing the spacers 14 that divide the lamination at both ends of the laminated magnetic core, both ends of the laminated magnetic core protrude outward, and the convergence of the magnetic flux can be improved. That is, it means that the convergence is improved even for the radio wave to be received , and the reception performance as an antenna can be improved .
[0015]
FIG. 2 shows a second embodiment of the present invention, which is a laminated magnetic core 16 for a radio wave receiving antenna in which substantially H-shaped amorphous pieces 15 are laminated . To the cross-sectional area of the straight portion 17 of the laminated magnetic core 16 serving as a winding axis of the coil, the cross-sectional area of both end portions 18 of the laminated magnetic core 16 is large, divide the stack of both end portions 18 of the laminated core 16 The non-magnetic spacer 19 forms a shape in which both end portions 18 of the laminated magnetic core 16 protrude vertically, and both end portions 18 protrude in the left and right and up and down directions compared to the straight portion 17 of the laminated magnetic core 16. Thus, it has a shape that improves the reception performance of radio waves to be received. Although not shown, the straight portion 17 which is a coil winding portion has a structure in which the stacking direction is fixed and deformation due to the spacer 19 is not generated.
[0016]
Examples of the present invention are shown below.
(Example 1) A 3 mm x 21 mm amorphous piece 11 is prepared from a Co-based amorphous ribbon, subjected to heat treatment and magnetic field heat treatment to obtain soft magnetic properties of the Co-based amorphous, and the hollow holes of the bobbin 13 shown in FIG. 30 layers were laminated to form a laminated magnetic core having a laminated thickness of 0.8 mm . Thereafter, the coil 12 was formed by winding 660 turns of 0.13φ UEW wire between the flanges 13 a of the bobbin 13 . Finally, in wedge-shaped heat-resistant resin-made spacer 14 of maximum thickness 0.5mm to multilayer magnetic core ends, both ends of the laminated magnetic core divided into two parts at 35 ° spatial angle theta, the lower side as shown by FIG. 1 Protrusions were provided. As a comparison, a characteristic comparison was made with Example 1 of the present invention using a conventional example in which the spacers 14 were not used and both ends of the laminated magnetic core were straight . The characteristics to be compared were inductance and Q characteristics, and the measurement frequencies were 40 kHz and 60 kHz.
[0017]
[Table 1]

[0018]
The spacers 14 at both ends of the laminated magnetic core, the present invention has a high Q characteristic as the index of the reception sensitivity of radio waves compared with the conventional example, moreover, there is no deterioration of the inductance value, excellent as radio receiving antenna, the radio receiving antenna It is possible to reduce the size.
[0019]
[0020]
[Table 2]
[0021]
[0022]
(Example 2) From the Co-based amorphous ribbon, the straight portion 17 which is a substantially H-shaped central coil winding portion shown in FIG. 2 is 1.4 mm × 15 mm, and both end portions 18 are 2.2 mm × 4. A 5 mm amorphous piece 15 is manufactured, heat treatment for obtaining a soft magnetic property of a Co-based amorphous material, and heat treatment in a magnetic field are performed, and 40 of the substantially H-shaped amorphous pieces 15 are laminated to obtain a laminated magnetic core having a laminated thickness of 1.1 mm. It was set to 16. A coil of 0.1φ - 1195 turns was provided on the straight portion 17 of the laminated magnetic core 16 . Inductance definitive to 40kHz at this time was 20mH. In the second embodiment of the present invention, a wedge-shaped spacer 19 having a maximum thickness of 0.5 mm shown in FIG. 2 is inserted (the spacer is provided) so as to divide the lamination of both end portions 18 of the laminated magnetic core 16 into two parts. FIG. 3 shows a comparison of Q characteristics with those in which the spacers 19 are not provided at both end portions 18 of the laminated magnetic core 16 (no spacers) .
[0023]
As shown in FIG. 3, the structure in which the spacers 19 are provided at both ends 18 of the laminated magnetic core 16 with spacers according to the present invention is clearly different from the conventional one without spacers 19 without spacers. characteristic is excellent, and makes it possible to provide a small radio receiving antenna.
[0024]
As described above, the present invention has made it possible to miniaturize the radio receiving antenna incorporated in the radio watch receives the standard radio, the present invention is not limited to the clock, for example a car, various mobile It can be used as a small receiving antenna that is built into a device, an authentication card, etc. and receives a predetermined radio wave.
[0025]
【The invention's effect】
The present invention can improve the characteristics of the receiving antenna magnetic core made of a stack of amorphous strip is a metal soft magnetic material, size of the receiving antenna, to improve the radio wave reception sensitivity Hakare, radio watch, etc. The product can be downsized and reception performance can be improved.
[Brief description of the drawings]
FIG. 1 is a sectional view of an antenna showing a first embodiment of a small receiving antenna of the present invention. FIG. 2 is a perspective view of a laminated magnetic core made of amorphous pieces according to a second embodiment of the small receiving antenna of the present invention. FIG. 3 is a Q characteristic diagram of a small receiving antenna of the present invention. FIG. 4 is a perspective view of a conventional ferrite receiving antenna.
11 Amorphous piece 12 Coil 13 Bobbin
13a Flange 14 Space angle at both ends of laminated magnetic core by spacer θ space 14

Claims (2)

In the antenna using a layered magnetic core with amorphous ribbon formed by laminating amorphous pieces made by stamping or cutting, turning coil winding in the center of the laminated core, the laminated magnetic core both ends of the winding axis direction of the coil A spacer for dividing the laminated portion is inserted, and both end portions of the laminated magnetic core protrude outward in the lamination direction from the laminated thickness of the coil winding portion in which the lamination direction at the center of the laminated magnetic core is fixed. Small receiving antenna. In an antenna using a laminated magnetic core formed by laminating amorphous pieces produced by punching or cutting an amorphous ribbon, both ends of the laminated magnetic core are compared with the magnetic core cross-sectional area of the coil winding portion in which the lamination direction is fixed small receiving antenna according to claim 1, wherein the core cross-sectional area of, wherein the size.

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