JPS6135501A - Rotor magnet and manufacture of the same - Google Patents

Abstract

PURPOSE:To prevent generation of crack of magnet by forming a plated layer to the surface of magnet, engaging an axial engaging part where the axial grooves are formed at the external circumference thereof into such plated magnet, and executing the plating thereto. CONSTITUTION:Before insertion of axial inserting part 2, a magnet 1 is subjected to the plating processing and is covered with the plated layer at the entire part thereof. The axial inserting part 2 is formed by the extruded molding within a resin molding die, providing with many grooves 2a, 2a... in the axial direction at the external surface and the center thereof is provided with an axial hole 3 to which a shaft of device is inserted. This axial inserting part 2 is inserted in the axial direction of the plated magnet 2 and is assembled to the magnet. After the axial inserting part 2 is inserted into the magnet 1, as the second plating process, the plating process is further conducted. Thereby, strength of magnet is enhanced in the first plating process eliminating generation of crack and missing and coupling between the axial inserting part and the magnet becomes more reliable in the second plating process.

Description

【発明の詳細な説明】 〈産業上の利用分骨〉 本発明はモータ用回転センサ、タイマーあるいはクロッ
ク等に装着されるロータ磁石及びその製造方法（ζ関す
る。DETAILED DESCRIPTION OF THE INVENTION <Industrial Application> The present invention relates to a rotor magnet attached to a motor rotation sensor, a timer, a clock, etc., and a method for manufacturing the same.

〈従来技術〉 ロータ磁石は各機器への組み立て工程を容易にするため
、従来から、円環状の磁石部と、この磁石部内に形成さ
れた合成ａｍ製の軸挿通部とからなり、該軸挿通部にシ
ャフトが挿入して組付けられていた。そして、この四−
夕磁石の製造は従来、磁石部を樹脂成形金型内にセット
し、合成樹脂を磁石部内に射出成形して前記軸挿通部を
形成することで行われていた。しかしながら、磁石部が
セラミックで形成されている場合には、セラミックの欠
片や破片が成形金型内に付着して金型が破損していたり
、あるいは合成樹脂の射出圧力で磁石部にクラックを生
じていた。このため、射出圧力を調整して軸挿通部を形
成する試みがなされているが、この場合には圧力不足１
ζよって軸挿通部が歪んだり、変形するという欠点を有
していた。さらには、磁石部の成形金型内へのセットに
手間取り、主産効率の低下を余儀なくされていに０く問
題点を解決するための手段〉 本発明は磁石部のクラック発生を防止するため、磁石部
表面に、まずメッキ層を施すと共に、軸方向の溝が外周
面に形成された軸挿通部をこのメッキされた磁石部内に
嵌入させ、さらに、この我人後にメッキを施して軸挿通
部の溝内にメッキ層を充填して磁石体と軸挿通部との結
合を確実にし、これにより、上述の欠点を解決したもの
である。<Prior art> In order to facilitate the assembly process into various devices, rotor magnets have conventionally consisted of an annular magnet part and a shaft insertion part made of synthetic am formed in this magnet part. The shaft was inserted into the section and assembled. And this four-
Conventionally, evening magnets have been manufactured by setting a magnet part in a resin mold, and injection molding synthetic resin into the magnet part to form the shaft insertion part. However, if the magnet part is made of ceramic, ceramic pieces or fragments may adhere to the inside of the mold and cause damage to the mold, or cracks may occur in the magnet part due to the injection pressure of the synthetic resin. was. For this reason, attempts have been made to adjust the injection pressure to form the shaft insertion part, but in this case, the pressure is insufficient.
This has the drawback that the shaft insertion portion is distorted or deformed. Furthermore, it takes time to set the magnet part into the molding die, which inevitably reduces the main production efficiency. Means for Solving the Problem> The present invention prevents cracks from occurring in the magnet part. First, a plating layer is applied to the surface of the magnet part, and a shaft insertion part with an axial groove formed on the outer peripheral surface is inserted into the plated magnet part. The groove is filled with a plating layer to ensure the connection between the magnet body and the shaft insertion portion, thereby solving the above-mentioned drawbacks.

〈実施例〉 以下、本発明を添付の図面及び工程を参照して具体的に
説明する。<Example> Hereinafter, the present invention will be specifically described with reference to the accompanying drawings and steps.

第１図及び第２図は本発明の一実施例の斜視図及び断面
図、第４図はその製造工程を示しており、１は円環状の
磁石部、２はこの磁石部１内に嵌入される軸挿通部であ
る。前記磁石部１は、例えばセラミック磁石からなり、
外径が５〜１０鴫、内径が２〜５■、厚さ３〜６■程度
の円°環状をなしてお９、軸挿通部２が嵌入される以前
に予め、メ、生処理が施され、全面がメッキ層で覆われ
ている。、このメッキ処理は銅あるいはニッケル等を無
電解メッキ、することで行われるが、この無電解メ、キ
にさらに電解メッキを行ってもよく、形成されるメッキ
層は例えば２〜５μ程度である。このメッキ層の形成に
より磁石部は強度が向上してクラックの発生、あるいは
破損等の不都合が解消される。一方、前記軸挿通部２は
樹脂成形金型内で射出成形等によって成形されるが、こ
の場合、外周面には軸方向の多数の溝２ａ、２ａ・・・
が形成され、又、中心部には機器のシャフトが挿入され
る軸孔３が開設されている。この軸挿通部２はメッキが
施された前記磁石部２の軸方向に嵌入されて磁石部に組
付けられるが、この組付けを確実にするなめ、その外径
が磁石部１の内径に対して５／１００〜５０／１００程
度大きくなるように成形されて磁石部部内に圧入せしめ
られる。従って、我人後は０．５〜２　ｋｇ　−ａｍの
押圧力が磁石部内面に作用している。1 and 2 are a perspective view and a cross-sectional view of an embodiment of the present invention, and FIG. 4 shows the manufacturing process, in which 1 is an annular magnet portion, and 2 is a magnet portion fitted into this magnet portion 1. This is the shaft insertion part. The magnet part 1 is made of, for example, a ceramic magnet,
It has an annular shape with an outer diameter of 5 to 10 cm, an inner diameter of 2 to 5 cm, and a thickness of 3 to 6 cm.Before the shaft insertion part 2 is inserted, it has been subjected to mechanical and raw treatment in advance. The entire surface is covered with a plating layer. This plating process is performed by electroless plating of copper or nickel, but electrolytic plating may be further performed on this electroless metal, and the plated layer formed is, for example, about 2 to 5 μm thick. . Formation of this plating layer improves the strength of the magnet portion, eliminating problems such as cracking or breakage. On the other hand, the shaft insertion part 2 is molded by injection molding or the like in a resin molding die, but in this case, the outer peripheral surface has a large number of axial grooves 2a, 2a...
is formed, and a shaft hole 3 into which the shaft of the equipment is inserted is opened in the center. This shaft insertion part 2 is fitted in the axial direction of the plated magnet part 2 and assembled to the magnet part, but in order to ensure this assembly, the outer diameter of the shaft insertion part 2 must be set relative to the inner diameter of the magnet part 1. The magnet is molded to be about 5/100 to 50/100 larger and press-fitted into the magnet portion. Therefore, a pressing force of 0.5 to 2 kg-am is acting on the inner surface of the magnet portion after the application.

このようにして軸挿通部２が磁石部１内に嵌入された後
は、第２メツキ工程として、さらにメッキ処理が施され
る。かかるメッキ処理は前述のメ、キ材と同材質の銅あ
るいはニッケルを使用して行い、電解メッキによって行
われる。従って、不導体である合成樹脂の軸挿通部表面
にはメッキ層が形成されずに磁石部の表面に厚さ１０〜
２０μのメッキ層が形成されるが、第３図に示すように
軸挿通部２の溝ｚａ内にもメッキＨ４が形成され、かつ
、このメッキＭ４ば磁石部１表面に形成されたメッキ層
と同一であるため、該メッキ層４の介在で軸挿通部２と
磁石部１との結合が強化される。After the shaft insertion part 2 is fitted into the magnet part 1 in this manner, a plating process is further performed as a second plating process. This plating process is performed using copper or nickel, which is the same material as the foregoing metal material, and is performed by electrolytic plating. Therefore, a plating layer is not formed on the surface of the shaft insertion part of the synthetic resin, which is a non-conductor, and the surface of the magnet part has a thickness of 10 to 10 mm.
A plating layer of 20μ is formed, but as shown in FIG. 3, plating H4 is also formed in the groove za of the shaft insertion part 2, and this plating M4 is different from the plating layer formed on the surface of the magnet part 1. Since they are the same, the coupling between the shaft insertion part 2 and the magnet part 1 is strengthened by the interposition of the plating layer 4.

これにより、軸挿通部２と磁石部１との結合力が１０〜
３０ｋｇ−（至）以上に強化され軸挿通部２の抜は止め
が防止される。As a result, the bonding force between the shaft insertion part 2 and the magnet part 1 is 10~
It is strengthened to over 30 kg (up to) and prevents the shaft insertion portion 2 from being pulled out.

また、第５図（ａ）、（ｂ）は時計用ロータ磁石の軸挿
通部２０を示す正面図、側面図である。5(a) and 5(b) are a front view and a side view showing the shaft insertion portion 20 of the rotor magnet for a timepiece.

この実施例の軸挿通部２０はローレット部２１及び軸２
２が形成され、該ローレット部２１に前述の磁石部１が
嵌入される。前記軸？！！通部２０を使用した時計用ロ
ータ磁石も上記と同様な製造方法により製造されるもの
である。The shaft insertion portion 20 of this embodiment includes a knurled portion 21 and a shaft 2.
2 is formed, and the above-mentioned magnet part 1 is fitted into the knurled part 21. Said axis? ! ! A rotor magnet for a watch using the passage portion 20 is also manufactured by a manufacturing method similar to that described above.

く効　果〉 従って、このような本発明によると、第１のメッキ工程
で磁石部の強度が向上してクラックの発生や欠片の発生
がなくなると共に、第２のメッキ工程で軸挿通部と磁石
部との結合が確実となっており、モータ用回転センサ等
の各種機器に組み立てる際にも欠けたり、分解すること
がない。又、本発明の製造方法は軸挿通部を単独で射出
成形して磁石部に嵌入させるものであり、磁石部と一体
的に射出成形しないから、磁石部の金型内への面倒なセ
ット操作が省略できると共に生産効率の向上を図ること
ができる、という効果がある。Therefore, according to the present invention, the strength of the magnet part is improved in the first plating process, eliminating the occurrence of cracks and fragments, and the shaft insertion part and the magnet are strengthened in the second plating process. It is securely connected to the parts, and will not chip or disassemble when assembled into various devices such as motor rotation sensors. Furthermore, in the manufacturing method of the present invention, the shaft insertion part is individually injection molded and fitted into the magnet part, and the shaft insertion part is not injection molded integrally with the magnet part, so there is no troublesome setting operation of the magnet part into the mold. This has the effect that it is possible to omit this process and to improve production efficiency.

【図面の簡単な説明】 第１図及び第２図は本発明の一実施例の分解斜視図、第
３図はその完成後の断面図、第４図は製造方法を示すブ
ロック図、第５図（ａ）、（ｂ）は時計用ロータ磁石の
軸挿通部の正面図、側面図、である。 １　・磁石部、２・・・軸挿通部、２ａ・・溝、４　・
メッキ層 特許出願人　ティーディーケイ株式会社代理人　弁理士
　佐　藤　英　昭 づｒ５ｅ ｔＱ） （ｂつ[Brief Description of the Drawings] Figures 1 and 2 are exploded perspective views of one embodiment of the present invention, Figure 3 is a sectional view after completion, Figure 4 is a block diagram showing the manufacturing method, and Figure 5 is a block diagram showing the manufacturing method. Figures (a) and (b) are a front view and a side view of a shaft insertion portion of a rotor magnet for a timepiece. 1. Magnet part, 2... Shaft insertion part, 2a... Groove, 4.
Plating layer patent applicant TDC Co., Ltd. agent Patent attorney Hide Sato Shozur5e tQ) (btsu

Claims (2)

【特許請求の範囲】[Claims] （１）メッキされた円環状の磁石部と、外周面に軸方向
の溝が刻設され前記磁石部の軸方向に嵌入される合成樹
脂からなる軸挿通部とからなり、前記溝内にメッキ層が
形成されて磁石部と軸挿通部とが結合されてなることを
特徴とするロータ磁石。(1) Consists of a plated annular magnet part and a shaft insertion part made of synthetic resin with an axial groove carved in the outer circumferential surface and fitted in the axial direction of the magnet part, and the groove is plated. A rotor magnet characterized in that a layer is formed and a magnet part and a shaft insertion part are combined. （２）磁石部表面をメッキする第１のメッキ工程と、外
周面に軸方向の溝が刻設された合成樹脂からなる軸挿通
部を前記磁石部の軸方向に嵌入する工程と、この嵌入後
にさらにメッキを施して磁石部と軸挿通部とを結合させ
る第２のメッキ工程とからなることを特徴とするロータ
磁石の製造方法。(2) A first plating step of plating the surface of the magnet part, a step of fitting a shaft insertion part made of synthetic resin with an axial groove carved into the outer peripheral surface in the axial direction of the magnet part, and this fitting. A method for manufacturing a rotor magnet, comprising a second plating step in which the magnet part and the shaft insertion part are combined by further plating afterwards.