KR20090107445A - Inductor - Google Patents

Abstract

PURPOSE: An inductor is provided to reduce radiation noise by forming the bottom of a magnetic core as a polygon having more than five angels. CONSTITUTION: An inductor is composed of a magnetic core(1) and a coil element(2). A magnetic core has a high-permeability or high saturation. The coil element is laid inside the magnetic core, and the magnetic core has polygon column having more than five angles. The bottom and the side of the polygon column are met at a corner so that a curve is formed at the corner, and the other bottom and side of the polygon are met at a corner so that a curve having a certain curvature is formed at the corner.

Description

Inductor

The present invention relates to an inductor in which leakage magnetic flux is reduced and magnetic flux disturbance is improved.

In the fields of various electronic devices such as AV equipment and information processing devices, lighting circuits of discharge lamps, and the like, development of inductors excellent in low loss characteristics and DC superimposition characteristics has been demanded. As an inductor in response to such a request, a choke coil in which an insulating coated ferromagnetic metal powder and a coil element are disposed in a mold and a coil element is embedded in a magnetic core by a press molding process is known (Patent Document 1).

In addition, since the leakage magnetic flux is generated by the inductance element and radiative noise is transmitted to the surrounding circuit elements, the inductance element having an almost spherical magnetic core as an inductance element with reduced radiation noise is provided. Is known (see Patent Document 2).

Furthermore, in a patent application (Japanese Patent Application No. 2006-283118) by the same applicant as the present application, an insulating coated magnetic powder and a coil element are disposed in a mold, and a coil element is provided inside the magnetic core by press molding. In an integrally embedded inductor, an inductor element whose spherical surface is spherical is described.

Patent Document 1: Japanese Patent Application Laid-Open No. 2006-13066

Patent Document 2: Japanese Patent Application Laid-Open No. 2005-109399

Although the inductor described in patent document 1 is very excellent in DC superposition characteristic, since the shape of a magnetic core is rectangular, dead space is formed in mounting space, and there existed a limit in reducing a mounting area. Moreover, when the magnetic core which encloses a coil element is rectangular, magnetic flux tends to leak in the edge part of a core. For this reason, secondary radiation may affect the peripheral circuit elements and cause malfunctions.

Since the inductor described in Japanese Patent Application No. 2006-283118 is a magnetic core having a spherical structure, almost no leakage flux and magnetic flux disturbance occur, and the problem that unnecessary dead space is formed when mounted on a circuit board is solved. However, since it is necessary to extend the two lead ends of the coil lead wires to the outside of the core to form a connection terminal, it is expensive to manufacture.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to realize an inductor that can significantly reduce radiant noise and effectively use a mounting space, which is easier to manufacture than a spherical core, and which does not cost a manufacturing cost. It is in doing it.

In an inductor having a high magnetic permeability or high saturation magnetic core and a coil element integrally embedded in the magnetic core, the magnetic core has a polygonal pillar of five or more angles as a basic shape. The problem is solved by an inductor having a structure. Since the bottom is made into the basic shape of the polygonal pillar which is a regular polygon with 5 or more corners, it has the following effects. First, since five or more regular polygons each have an angle greater than 90 degrees, the effect of reducing the occurrence of leakage magnetic flux is increased. For example, in the case of the columnar shape, there is a problem in mounting that a dead space occurs in terms of arrangement with other electronic components. However, the problem can be reduced by using a polygonal column. That is, the dead space can be reduced, so that handling on the mounting side is easy and manufacturing is easy.

As such an inductor, the problem is solved by an inductor characterized by having a curvature of a predetermined curvature at the corner formed by the bottom surface and the side surface of the polygonal pillar. Since the polygonal column has a parallel pair of regular polygonal bottoms, there are angles formed by one side bottom and side and edges formed by the other bottom and side. It is a requirement to have a curvature at least on one side of the corner. The term "having a curvature of a certain curvature" means that the curvature of such a corner has a curved curvature to the same degree as a whole. By this shape, leakage flux and magnetic flux disturbance can be reduced. The edge of the side without the influence of the leakage magnetic flux does not form a curvature, whereby the manufacturing cost can be reduced.

As such an inductor, in addition to having a curvature of a certain curvature at the corner between the bottom and side of one side of the regular polygonal pillar, the inductor is characterized by having a curvature of a certain curvature at the corner between the bottom and the side of the other side. Solve. In this inductor, both the corner formed by the bottom and side of one side and the corner formed by the other side and the side have curvature. As the curved portion increases, leakage flux and flux disturbance can be further reduced. The curvature of the corner formed by one side of the bottom and the side, and the curvature of the corner formed by the other bottom and the side may be different curvature. By setting it as a different curvature, the direction of the leakage magnetic flux can be changed into the direction which has no influence.

As such an inductor, the problem is solved by an inductor characterized by the same curvature of the curvature of the corner between the bottom and side of the regular polygonal pillar, and the curvature of the curvature of the corner between the bottom and the side of the other polygonal pillar. . In this inductor, it is a requirement that the curvature of the "curvature which the edge which one side bottom surface and a side make | forms" and the curvature of "the curvature which the edge which the other side bottom surface and a side make | forms" have the same. As a result, leakage flux and flux disturbance can be further reduced.

As such an inductor, the problem is solved by an inductor characterized by having curvature at all corners. In this inductor, the corners formed on one side of the bottom and side and the corners formed on the other side of the inductor have curvatures at the edges formed on the side as well, resulting in curvature at all corners of the inductor. Have The magnetic core acts as a yoke of the coil element and extends along the magnetic path of the magnetic flux generated from the coil element, thus shielding the outer circumference of the coil element. It acts as a strong magnetic shielding effect against external elements. Since all edges of the inductor can have a curvature, the portion where the magnetic flux is radiated to the outside from the coil element also has a curvature, thereby reducing the leakage magnetic flux and having a special effect of no magnetic flux disturbance. This invention has the effect peculiar to an inductor in which a coil element is embedded in a magnetic core. An inductor of this type is manufactured by placing an insulating coated magnetic powder and a coil element into a mold and pressing forming. Therefore, it has a structure in which the coil element is integrally embedded in the magnetic core of high permeability or high saturation characteristic.

An inductor having a magnetic core having a high permeability or a high saturation characteristic and a coil element integrally embedded in the magnetic core, wherein the magnetic core has an approximately circumferential shape having curvatures extending in a horizontal direction. The inductor solves the problem. In this inductor, the magnetic core has curvature expanded in the horizontal direction, whereby leakage magnetic flux and magnetic flux disturbance can be reduced. In addition, since the magnetic core has a planar portion instead of a spherical body, it is easy to provide a connection terminal. That is, the copper wire end part of the coil element embedded inside can be made to protrude to the planar part of a core, and can be used as a connection terminal. For this reason, a manufacturing process reduces compared with the case of a spherical body.

In the present invention, the bottom surface of the magnetic core has a structure of five or more regular polygons, which significantly reduces radiant noise and effectively uses a mounting space, making it easier to manufacture than a spherical core, and thus inducting less expensive manufacturing. It was made.

In addition, the magnetic core of the present invention can be configured not only to exhibit the magnetic shielding effect of shielding the outer circumference of the coil element, but also to reduce the magnetic flux leakage while not causing magnetic flux disturbance.

An example is shown below.

Example  One

1 to 3 show an inductor according to the first embodiment. 1 is a view showing the appearance of Embodiment 1 of an inductor according to the present invention, Figure 1a is a view from above, Figure 1b is a view from the side. In Example 1, the appearance of the inductor is an octagonal pillar with curves at all corners. On the other hand, at least one corner may have a curvature. The octagonal pillar may have an upper bottom, a lower bottom, and side surfaces. The upper and lower bottom surfaces are substantially octagonal, for example, regular octagonal. The side surface has the 1st-8th sub side surface arrange | positioned along the outer periphery of an octagonal pillar. The first to eight sublateral sides are rectangular.

Fig. 2 is a diagram showing the arrangement of coil elements integrally embedded in the magnetic core of Embodiment 1 of the inductor according to the present invention. The coil element is embedded except for both ends, and both ends protrude outward from the core bottom portion of the core 1. Both ends are bent toward the back surface of the core 1, and both ends 4 of the coil 2 along the back surface of the core 1 are used as terminals. The insulating layer of this terminal is removed, and it is reflow soldered to the printed wiring of a printed wiring board (PCB). Therefore, the inductor of Example 1 can be mounted on a printed board as a surface mounting component.

The inductor according to the present invention is prepared by arranging an insulating coated magnetic powder and a coil element 2 in a mold, and by pressing molding (compression molding). The magnetic core 1 has an octagonal pillar structure whose shape is curved at the corners. In the present invention, the corner of the octagonal pillar is, for example, a portion made between the upper bottom and the side or a portion made between the upper bottom and the side, a portion made between the bottom and the side or between the bottom and the side Corresponds to the part formed and the part made between neighboring sublateral surfaces. The outer periphery of the coil element embedded in the magnetic core 1 is shielded. Therefore, the magnetic core 1 constitutes a core having a magnetic shielding effect for shielding the magnetic flux generated from the coil element 2, and a yoke (magnetic core) formed in the inner space 3 of the coil element 2. (磁心) constitutes. The coil element 2 is an air core coil wound around a general copper wire whose outer circumference is covered with urethane or the like.

Since the inductor of this embodiment has curvature at all corners of the magnetic core 1, the problem of magnetic flux disturbance is greatly improved. In addition, radiation noise due to leakage magnetic flux is reduced.

The manufacturing method of the inductor by this invention is as follows. The inductor is manufactured by integrally press molding a dielectric coated magnetic powder and a coil element and polishing a curved angle. In the case of mass production, there is no grinding | polishing process and it press-processes using the form which consists of a final shape. Or it manufactures by press-molding the mixture powder and coil element which mixed the magnetic powder of high permeability with the electrically insulating binder. The magnetic powder is, for example, iron, iron silicide, carbonyl iron, supermalloy (Fe-Ni-Mo), permalloy (Fe-Ni), sendust (sendust), ferrous aluminum alloy , One or two or more magnetic metals selected from iron nitride, iron cobalt alloy and the like can be used. As an insulating material or insulating binder for coating the magnetic powder, an insulating material selected from various insulating inorganic materials and organic materials such as silicon oxide can be used. Specifically, it selects from silicon oxide, water glass, a silicone resin, a phenol resin, an epoxy resin, etc., for example.

Example  2

4 shows the appearance of the inductor according to the second embodiment. FIG. 4A shows the state seen from above, and FIG. 4B shows the state seen from the side. The appearance of the inductor is an octagonal pillar, and the edge of the inductor has no curvature.

Example  3

5 shows the appearance of the inductor according to the third embodiment. FIG. 5A is a view from above, and FIG. 5B is a view from the side. The appearance of the inductor is approximately circumferential in shape with the curvature of which the sides expand outwardly, ie in the horizontal direction.

Example  4

6 shows the appearance of the inductor according to the fourth embodiment. 6A is a view from above and FIG. 6B is a view from the side. The appearance of the inductor is curved at both the bottom and side edges of the octagonal pillar, and at the corners of the bottom and side of the other side, but the curvature of the curvature of the edge facing the bottom of one side and the edge of the bottom facing the other side of the octagonal pillar. The curvature of the curvature is different. Here, one side bottom is any one of an upper bottom and a bottom bottom, and the other bottom is another one of an upper bottom and a bottom bottom.

In the above-described embodiments of the present invention, the inductors have the octagonal pillar shape. Meanwhile, the inductor may have a pillar shape of an angle other than eight, for example, the inductor may have a pillar shape of five or more angles.

1A is a view showing an inductor of Embodiment 1 according to the present invention.

1B is a view showing an inductor of Embodiment 1 according to the present invention.

2A is a view showing an inductor of Embodiment 1 according to the present invention.

2B is a view showing an inductor of Embodiment 1 according to the present invention.

3 is a view showing an inductor of Embodiment 1 according to the present invention.

4A shows an inductor of Embodiment 2 according to the present invention.

4B is a view showing an inductor of Embodiment 2 according to the present invention.

5A is a view showing an inductor of Embodiment 3 according to the present invention.

5B is a view showing an inductor of Embodiment 3 according to the present invention.

6A shows an inductor of Embodiment 4 according to the present invention.

6B is a view showing an inductor of Embodiment 4 according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: magnetic core 2: coil element

3: inner space 4: connecting terminal

Claims (6)

In an inductor having a high magnetic permeability or high saturation magnetic core and a coil element embedded in the magnetic core, Inductor, characterized in that the magnetic core has a polygonal pillar shape of five or more. The method of claim 1, An edge formed by one side of the bottom surface and the side of the polygonal pillar has a curvature of a predetermined curvature. The method of claim 2, The edge formed by the bottom surface and the other side of the polygonal pillar has a curvature of a predetermined curvature. The method of claim 3, The curvature of the curvature of the corner formed by the bottom surface and the side of the side, the curvature of the curvature of the corner formed by the bottom surface and the other side is the same. The method of claim 1, Inductor, characterized in that all corners of the polygonal pillar has a curvature. An inductor having a magnetic core having a high permeability or a high saturation characteristic and a coil element embedded in the magnetic core, The magnetic core has an circumferential shape having a curved side extending in the horizontal direction.

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