JPH0741129Y2 - Sheet coil - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial application] The present invention relates to a sheet coil.

[Problems to be solved by conventional techniques and devices]

Recently, as a stator of a brushless motor or the like, a sheet coil without winding work has been used. This sheet coil has a structure in which a copper foil coil portion is printed on a base plate and a cover film is coated on it, but the thickness dimension of the sheet coil is smaller than that of the copper foil coil portion. Therefore, there is a drawback that the magnetic permeability is reduced. Further, there is a problem that the heat radiation effect is small when the copper foil coil portion is overheated.

The present invention has been made in view of the above problems existing in the prior art, and the problem is that the temperature rise is small, the efficiency is high, and the size of the sheet coil can be reduced. To provide.

[Means for Solving the Problems]

In order to achieve the above-mentioned subject, the sheet coil of the present invention is
A sheet coil used by sandwiching a copper foil coil portion in a sandwich shape with a base plate 12 and a cover film, and using a plurality of windings in a cylindrical shape, in the vicinity of the copper foil coil portion,
A gap is formed in a hermetically sealed manner between the base plate and the cover film, and a non-conductive magnetic fluid is sealed in the gap,
The non-conductive magnetic fluid is provided so as to intervene in the copper foil coil portion.

[Action]

A non-conductive magnetic fluid is sealed in the gap formed in a hermetically sealed manner. Therefore, the non-conductive magnetic fluid functions similarly to the ferromagnetic material (iron core), the magnetic permeability is increased with respect to the copper foil coil portion, and therefore the magnetic force of the stator coil can be increased. And, in particular, since the non-conductive magnetic fluid is provided so as to intervene in the copper foil coil portion, the non-conductive magnetic fluid is thoroughly present in the gap portion where the copper foil coil portion is provided, and thus as a magnetic body. The effective space can be maximized and the magnetic force can be increased.

Next, even if the copper foil coil portion is overheated by energization, the non-conductive magnetic fluid acts as a cooling medium for the copper foil coil portion to directly exchange heat, and the cooling effect on the copper foil coil portion is enhanced. . Moreover, in the non-conductive magnetic fluid, convection occurs between the heated portion and the non-heated portion, the thermal conductivity is improved, and the sheet coil as a whole is easily radiated. In addition, since there is no local overheating, deterioration of the member is suppressed.

Furthermore, since the non-conductive magnetic fluid is enclosed between the base plate and the cover film, the non-conductive magnetic fluid, which is a fluid, is deformable even when the sheet coil is formed into a cylindrical shape (having a continuous curved surface), and It can be easily formed. In particular, when the sheet coil is wound multiple times, the curvature of the curved surface should be changed for each winding, which is complicated, but the non-conductive magnetic fluid to be enclosed may cause troubles. The sheet coil can be easily formed without using.

〔Example〕

 Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

FIG. 4 shows a case where the sheet coil 1 according to the present invention is wound in a plurality of cylindrical shapes and used as the stator coil S of the brushless motor 2.

The brushless motor 2 includes a housing 5 including a flange portion 3 and a cylindrical portion 4, and a magnetic disk mounting hub 6 is rotatably supported on the housing 5 via a bearing. That is, the hub 6 is rotatably supported on the cylindrical portion 4 by the shaft 7.

Inside the peripheral wall of the hub 6, a cylindrical rotor magnet 8 is fitted via a yoke 9, and on the other hand, a stator coil S is fixed to the outer peripheral surface of the cylindrical portion 4, with a small cylindrical gap therebetween. , Faces the inner peripheral surface of the magnet 8.

FIG. 3 illustrates only the stator S in a perspective view.

Therefore, as shown in the plan view of the main part of FIG. 1 and FIG. 2 corresponding to the II-II enlarged sectional view of FIG.
Is a structure in which a copper foil coil portion 11 is sandwiched between a base plate 12 and a cover film 13 in a sandwich shape. Then, at least in the vicinity of the copper foil coil portion 11, the copper foil coil portion 11 is provided between the base plate 12 and the cover film 13.
A minute dimension gap portion 14 corresponding to the thickness dimension is formed. Moreover, the base plate 12 and the cover film 13 are integrated at their entire peripheral edge portions E by thermal fusion bonding (thermocompression bonding) or the like, so that the entire circumference of the gap 14 is sealed. The magnetic fluid 15 is enclosed in the space 14 thus sealed.

The magnetic fluid 15 is a non-conductive liquid (including a viscous fluid), which is shown by dots in FIGS. 1 and 2. At that time, as shown in FIGS. 1 and 2, the magnetic fluid 15 is provided so as to intervene in the copper foil coil portion 11. For this reason, the magnetic fluid 15 functions like a ferromagnetic material (iron core), the magnetic permeability is increased with respect to the copper foil coil portion 11, and therefore, the magnetic force can be increased as the stator S (stator coil). . And, in particular, since the magnetic fluid 15 is provided so as to intervene with respect to the copper foil coil portion 11, the magnetic fluid 15 exists without exception in the gap portion 14 in which the copper foil coil portion 11 is provided, and thus as a magnetic body. The effective space can be maximized. Therefore, the magnetic force can be further increased, and the output of the brushless motor 2 can be increased or the efficiency can be improved to reduce the size of the motor.

Further, even when the copper foil coil portion 11 is overheated by energization, the magnetic fluid 15 acts as a cooling medium for the copper foil coil portion 11 so as to directly exchange heat, and the cooling effect on the copper foil coil portion 11 is enhanced. . In addition, the magnetic fluid 15 causes convection between the heated portion and the non-heated portion, which improves the thermal conductivity and facilitates heat dissipation as the entire sheet coil 1 or the stator S. In addition, since there is no local overheating, deterioration of the member is suppressed.

Furthermore, the magnetic fluid 15 is the base plate 12 and the cover film.
Since it is enclosed between 13, the magnetic fluid 15, which is a fluid, is deformable even if the sheet coil 1 is formed into a cylindrical shape (having a continuous curved surface) as the stator S as shown in FIG.
Therefore, such a shape is preferable, and it can be easily formed. In particular, when the sheet coil 1 is wound a plurality of times like this, the curvature of the curved surface is normally changed for each winding, but it becomes complicated, but the enclosed magnetic fluid 15 causes troubles. Never be In the example of FIG. 1, the base plate
The case where 12 and the cover film 13 are integrated in the intermediate portion M other than the peripheral edge portion E is also shown. This is because an appropriate intermediate portion M from the viewpoint of polymerization strength between the base plate 12 and the cover film 13. It shows that it is free to integrate.

The copper foil coil portion 11 is generally printed on the base plate 12.

Although illustration is omitted, the copper foil coil portion 11 and the cover film 13 may be laminated on both surfaces of the base plate 12, and in that case, the gap portion 14 in which the magnetic fluid 15 is enclosed should be formed on both front and back surfaces. Becomes

[Effect of device]

The present invention having the above-described configuration has the following great effects.

The non-conductive magnetic fluid 15 is in the vicinity of the copper foil coil portion 11 and acts like a ferromagnetic body (iron core), and (the magnetic permeability is increased), and the magnetic force of the stator S can be increased. Therefore, the motor output can be improved or the motor can be downsized.

The non-conductive magnetic fluid 15 acts as a cooling medium on the copper foil coil portion 11, and the convection homogenizes the temperature rise to improve the thermal conductivity, so that the heat dissipation effect is excellent.

Since the non-conductive magnetic fluid 15 which is a "fluid" is enclosed in the gap portion 14, the stator S can be easily formed even if it is wound in a plurality of cylindrical shapes, and the productivity can be improved.

[Brief description of drawings]

FIG. 1 is an enlarged plan view of an essential part showing an embodiment of the present invention.
The drawing is an enlarged sectional view taken along the line II-II of FIG. 1, FIG. 3 is a perspective view showing an example of a stator coil, and FIG. 4 is a sectional view of an essential part showing an application example. 1 …… Sheet coil, 11 …… Copper foil coil part, 12 …… Base plate, 13 …… Cover film, 14 …… Gap part, 15
...... Magnetic fluid.

Claims (1)

[Scope of utility model registration request] 1. A sheet coil comprising a copper foil coil portion (11) sandwiched between a base plate (12) and a cover film (13) in a sandwich shape, and wound in a plurality of cylinders, and used in the vicinity of the copper foil coil portion (11). The above base plate 12
And a gap portion 14 is formed between the cover film 13 and the cover film 13 in a sealed manner,
A non-conductive magnetic fluid 15 is sealed in the gap portion 14, and the non-conductive magnetic fluid 15 is provided in the conductive foil coil portion 11.
A sheet coil characterized in that