JP2013251451A - Composite ferrite core of inductor and inductor using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ferrite core having high energy density capable of easily coping with high capacity of an inductor and being excellent in heat removal property of generated heat, and an inductor using the same at low cost.SOLUTION: In the ferrite core of an inductor, a plurality of E type ferrite cores 1 are placed side by side so as to make magnetic paths parallel and composited, the E type ferrite cores having a base 2 with a middle leg 3 erected a center part and having a shape expanding as the center part goes toward an end part direction, and having "a side leg 4 with an opposite face made a curved face" erected at both end parts of the base. The inductor is configured by mounting a coil having a narrow part formed so as to be fit to a shape between the middle leg 3 and the side leg 4 by pressing an oval-shaped coil from the outside between the middle leg 3 and the side leg 4 of the composite ferrite core.

Description

  The present invention can easily cope with an increase in capacity of an inductor while maintaining a good energy density (density of electric energy and magnetic energy) and is excellent in heat removal of generated heat. The present invention relates to a ferrite core and an inductor using the same.

  An inductor used as a basic element of an electronic device has a function of converting between electric energy and magnetic energy, and “a coil portion that generates magnetic flux” and “a magnetic path (core portion) made of a magnetic material through which the magnetic flux flows”. However, in order to ensure a high energy density, ferrite is often used as the magnetic material.

In addition, the energy of the inductor is proportional to the cross-sectional area of the coil part that generates magnetic flux and the magnetic path through which the magnetic flux flows. Therefore, in the ferrite core applied to it, the storage density of the coil storage part and the cross-sectional area of the magnetic path are as large as possible. The shape is devised so that
As such a ferrite core, for example, in Patent Document 1, “ferrite E-type member 11 (E-type ferrite core) is combined in a face-to-face configuration as shown in FIG. "A ferrite core in which an insulated wire winding (coil) is mounted between the leg 12 (the portion that becomes the core of the insulated wire winding) and the side leg 13" has been introduced.
This E-type ferrite core uses a middle leg 12 with a circular cross-section to ensure a uniform flow of magnetic flux, but the side face 13's "opposite surface to the middle leg" has a circular cross-section. Even if a ring-shaped coil that matches the middle leg 12 is mounted, the curved surface that is concentric with the middle leg cross section is configured so as to secure as much cross-sectional area of the side leg as a magnetic path as possible.
In general, one of the E-shaped members is an I-shaped plate member.

  By the way, in recent years, inductors with higher power capacity have been required, including those for in-vehicle use, and in order to meet such demands, studies have been made to increase the size of the inductor while maintaining a high energy density. It came to be performed actively.

  However, in order to increase the size of the inductor, it is necessary to increase the size of the ferrite core, which is a component of the inductor. However, since the ferrite core is a sintered body, it is difficult to mass-produce large-sized ones with high dimensional accuracy. was there. That is, as the ferrite core is increased in size, deformation such as warpage is more likely to occur during firing, and the manufacturing yield tends to be greatly reduced.

Therefore, the present inventor has arranged a plurality of E-type ferrite cores as shown in FIG. 6 together so that the magnetic paths are parallel as shown in FIG. However, the following problem was an obstacle to the realization of a "desired large ferrite core".
a) In order to maintain the high energy density by making the best use of the physical volume of the inductor in the electronic equipment as much as possible, the “legs that face the middle leg” of the side legs of the E-type ferrite core used It is required to have a curved surface concentric with the surface, but if a plurality of such E-type ferrite cores are arranged side by side and a common coil surrounding each middle leg is tightly routed, each side leg is The work is extremely difficult because of the shape of the inner surface of the corrugated wave, making it unsuitable for mass production.
b) Increasing the size of the inductor also increases the amount of heat generated from the middle legs and coils, and there is no concern that the performance of electronic devices to which the inductor is applied will deteriorate.

Japanese Patent Laid-Open No. 9-246060

  In view of the circumstances as described above, the present invention has made it a problem to realize an inductor having a high energy density that can easily cope with an increase in the capacity of the inductor and is excellent in the heat removal of generated heat. It is to provide an inexpensive ferrite core and an inductor using the same.

The inventor has further studied to solve the above problems and has obtained the following knowledge.
In other words, although inductors for in-vehicle use are becoming larger in size, it is still desired to make them as compact as possible while ensuring necessary functions.
However, even if a plurality of E-type ferrite cores are juxtaposed and combined to increase the size of the core, a portion smaller than the cross-sectional area of the middle leg in the magnetic flux circulation flow path in each E-type ferrite core constituting the core If this occurs, the generated magnetic flux will be difficult to flow and a loss will occur. Therefore, there is a factor that does not comply with the compact design that the “total cross-sectional area of the side legs” must be larger than the “cross-sectional area of the middle legs”. In the E-type ferrite core as shown in FIG. 6, there is a limit to the thickness reduction of the side legs, and the outer dimensions of the core cannot be reduced unnecessarily.
However, as shown in FIG. 1, the shape of the base (seat plate) 2 of the E-type ferrite core 1 has a shape like a butterfly whose width increases from the center where the middle leg 3 is erected toward the end. If the side legs 4 and 4 are erected at both ends, the width of the side legs 4 serving as a magnetic flux flow path can be increased, and the total cross-sectional area of the side legs 4 and 4 is Even if the thickness of the side leg 4 is reduced, the area can sufficiently correspond to the cross-sectional area of the middle leg 3, so that the flow of magnetic flux is not hindered. Therefore, in such a ferrite core, the thickness of the side leg 4 can be made thinner than that of an E-type ferrite core as shown in FIG. 6, and the coil capacity (insulated wire winding capacity) is increased accordingly. Therefore, the energy density can be increased, or the compactness can be achieved while ensuring a high energy density.
1A is a plan view of the E-type ferrite core, and FIG. 1B is a perspective view thereof.

  In addition, when a plurality of “core bases (seat plates) having a butterfly shape” as described above are combined so that their magnetic paths are parallel to each other, as shown in FIG. 5 is generated to form an atmospheric flow path, and an effective air cooling function of the core is obtained.

Further, even if such a “composite ferrite core having a corrugated inner surface formed by a plurality of side legs” is adopted, a common coil surrounding the plurality of middle legs 3 can be tightly packed by adopting the following method. It has also been found that it is easy to pass over to the inductor and does not harm the mass productivity of the inductor.
In other words, “an oval (elliptical) coil 6 composed of an arcuate portion in which the outer diameter of the middle leg is the inner diameter and the inner diameter of the side leg is the outer diameter” and the “parallel straight portion” shown in FIG. Although it can be made very easily by a normal method, the parallel straight portion of such an oval-shaped coil 6 is pressed from the outside as shown by an arrow, and the outer side thereof has an arc shape along the inner diameter of the side leg. By forming so as to obtain the “coil 7 having a constriction” having a shape closely fitting between the middle leg and the side leg of the composite ferrite core as shown in FIG. Therefore, it is possible to easily attach to a ferrite core as shown in FIG. 2 in which a plurality of “core bases (seat plates) are butterfly-shaped ferrite cores” are combined.

The present invention has been completed based on the above knowledge and the like, and is characterized in that the ferrite core and the inductor have the following configurations.
1) A middle leg having a circular cross section is erected at the center and has a base (seat plate) whose width increases from the center toward the end, and “medium” at both ends of the base. A feature is that a plurality of E-type ferrite cores on which side legs whose surfaces facing the legs are concentric with the cross section of the middle leg are erected are juxtaposed so that their magnetic paths are parallel. Inductor composite ferrite core.
2) Between the middle leg and the side leg of the composite ferrite core described in the above 1), “an arcuate part having the inner leg outer diameter as the inner diameter and the outer leg inner diameter as the outer diameter” and “parallel straight section” An inductor comprising: a coil having a constriction formed by pressing a parallel straight portion of an oval-shaped coil composed of "" from outside and forming an outer side thereof in an arc shape with an inner diameter of a side leg. .

The composite ferrite core according to the present invention is used as an inductor after the coil is housed and covered with a ferrite lid (may be a ferrite core having the same shape as the composite ferrite core according to the present invention). However, the magnetic flux generated by the current flowing through the coil reaches the side leg that is erected from the upper end surface of the middle leg through the lid with the middle leg serving as the core of the coil interposed therebetween. A circulation path of magnetic flux is formed that returns to the middle leg through the base (seat plate) that is a component of the above.
If there is a portion smaller than the cross-sectional area of the middle leg in the circulation path of the magnetic flux, the generated magnetic flux is difficult to flow, and loss occurs. As described above, the E-type ferrite core constituting the composite ferrite core according to the present invention has a base ( The shape of the seat plate) is “the shape of a butterfly whose width expands from the central part where the middle leg is erected toward the end part” and the side legs are erected at both ends. Therefore, even if the width of the side leg that becomes the magnetic flux flow path can be increased and the thickness of the side leg is reduced, the total cross-sectional area of the side leg can be sufficiently secured, so that the flow of magnetic flux is hindered. There is no.
Further, the E-type ferrite core has a useless space between the middle leg and the side leg because the “surface facing the middle leg” of the side leg is a “curved surface concentric with the cross section of the middle leg”. Therefore, the coil can be mounted at a high density without causing a problem, and a high energy density can be secured.
Since the ferrite core according to the present invention is a composite of a plurality of such E-type ferrite cores arranged in parallel so that the magnetic paths are parallel, the cross-sectional area of the magnetic path increases and the magnetic flux increases. Unlike the case of joining in series, the inductance increases with less electrical resistance.

  Moreover, in the composite ferrite core according to the present invention, since a plurality of E-type ferrite cores having a butterfly-shaped base (seat plate) are juxtaposed, gaps are formed between the juxtaposed bases (seat plates). An atmospheric flow path is formed, and effective air cooling from the inside of the composite core is possible.

In addition, the composite ferrite core according to the present invention has a corrugated inner side surface on the side leg side of the coil mounting portion, so that it is difficult to mount it tightly with a circular or oval coil formed by a normal means. Therefore, it was considered that an inductor using such a composite ferrite core is not suitable for mass production. However, the parallel straight part of the oval-shaped coil consisting of “the arcuate part where the outer diameter of the middle leg is the inner diameter and the inner diameter of the side leg is the outer diameter” and the “parallel straight part” is externally attached. By pressing and forming the “coil having a constriction” formed into an arc shape with the inner diameter of the side leg, the dense mounting can be smoothly performed and an inductor excellent in mass productivity can be realized.
In this case, even if a coil that integrally surrounds a plurality of middle legs is attached, the “space between the bases (seat plates)” is not blocked by the coil. The air cooling function will not be hindered.

  As described above, according to the present invention, it is possible to provide a large-sized ferrite core and inductor that have a high energy density and can avoid adverse effects due to heat generation at low cost, and have a large capacity and high performance electromagnetic energy converter (transformer). , Electrical energy conversion equipment such as an inverter).

FIG. 1 is an explanatory view of an E-type ferrite core that is a component of a composite ferrite core according to the present invention, where (a) is a plan view and (b) is a perspective view thereof. FIG. 2 is an explanatory diagram relating to one example of the composite ferrite core according to the present invention. FIG. 3 is a conceptual diagram illustrating a method for forming a coil to be attached to the inductor according to the present invention. FIG. 4 is an explanatory diagram relating to an example of a coil attached to the inductor according to the present invention. FIG. 5 is an explanatory diagram regarding an example of an inductor according to the present invention. FIG. 6 is an explanatory diagram of a known E-type ferrite core. FIG. 7 is an explanatory diagram of a state in which a plurality of E-type ferrite cores shown in FIG. 6 are juxtaposed and combined.

FIG. 2 is an explanatory view showing an example of a composite ferrite core according to the present invention.
The composite ferrite core of this inductor is formed at both ends of a butterfly-shaped base (seat plate) 2 whose width increases from the center where the middle leg 3 is erected toward the end as shown in FIG. Two E-type ferrite cores 1 ”with side legs 4 and 4 standing upright are arranged in close contact so that their magnetic paths are parallel.
The E-type ferrite core 1 which is a constituent element of the composite ferrite core according to the present invention is such that the “surface facing the middle leg 3” of the side legs 4 and 4 is “a curved surface concentric with the middle leg cross section”. Therefore, the coil can be mounted at a high density without generating a useless space between the middle leg 3 and the side leg 4, and a high energy density can be secured. In addition, the base (seat plate) 2 of the E-type ferrite core 1 has a butterfly shape that increases in width from the central portion where the middle leg 3 is erected toward the end portion. This is also very advantageous.
Thus, since the E-type ferrite core 1 which is a component of the composite ferrite core according to the present invention is compact, it has a high energy density. If the composite ferrite cores shown in FIG. 2 are combined in parallel so as to be parallel to each other, a ferrite core for an inductor having a very high inductance is realized.
In this case, the E-type ferrite cores 1 and 1 juxtaposed in parallel do not necessarily have to be in close contact with each other, and there is no problem even if some gaps are generated.

  In addition, in the composite ferrite core, two E-type ferrite cores 1 and 1 having a butterfly-shaped base (seat plate) are juxtaposed, so that a gap 5 is generated between both bases (seat plate). Through this, air cooling from the inside of the composite core becomes possible.

FIG. 5 is an explanatory view showing an example of an inductor according to the present invention created using the composite ferrite core shown in FIG.
In this inductor, the parallel linear portion of the oval-shaped coil 6 having the shape shown in FIG. 3 is pressed as shown by an arrow so that the outer side thereof is shaped into an arc along the inner diameter of the side leg. The “coil 7 having a constriction” as shown in FIG.
Since the above-mentioned “coil 7 having a constriction” can be easily produced as described above, it can be smoothly and densely attached to the coil attachment portion where the inner side surface shape of the composite ferrite core forms a wave shape. It does not become a factor that harms the productivity and performance of the inductor.
Moreover, even if the “coil 7 having the constriction shown in FIG. 4” is attached to the “composite ferrite core shown in FIG. 2,” the gap 5 is not blocked as shown in FIG. Since the air-cooling function from the inside is sufficiently maintained, a large inductor having a high energy density and capable of avoiding adverse effects due to heat generation can be obtained.

  2 and 5 show examples of a composite ferrite core in which two E-type ferrite cores are combined, and an inductor in which a coil having a cross section of 8 in a cross section with only one constriction on both sides is mounted. However, the present invention is not limited to these, and a composite ferrite core may be formed by combining three or more E-type ferrite cores, and an inductor may be combined with such a composite ferrite core. It goes without saying that a configuration in which a coil having a matching number of constrictions is mounted may be used.

  As described above, according to the present invention, a ferrite core for an inductor that has a large capacity with high energy density and can reduce inconvenience due to heat generation during use, and a high-performance inductor using this ferrite core are inexpensive. The present invention can be provided, and by applying it to various electronic devices, it is possible to greatly contribute to the miniaturization and high performance of the electronic devices and the like.

1 E-type ferrite core 2 Base (base plate)
3 Middle leg 4 Side leg 5 Gap 6 Oval coil 7 Necked coil
11 E-shaped member
12 Middle legs
13 Side legs

Therefore, the present inventor has a plurality of E-shaped ferrite core as shown in FIG. 6, the cross-sectional of the required magnetic path by parallel location combined in parallel magnetic path as shown in FIG. 7 Although the attempt was made to increase the size by securing the area, the following problem became an obstacle to realizing the "desired large ferrite core".
a) In order to maintain the high energy density by making the best use of the physical volume of the inductor in the electronic equipment as much as possible, the “legs that face the middle leg” of the side legs of the E-type ferrite core used It is required to have a curved surface concentric with the surface, but if a plurality of such E-type ferrite cores are arranged side by side and a common coil surrounding each middle leg is tightly routed, each side leg is The work is extremely difficult because of the shape of the inner surface of the corrugated wave, making it unsuitable for mass production.
b) Increasing the size of the inductor also increases the amount of heat generated from the middle legs and coils, and there is no concern that the performance of electronic devices to which the inductor is applied will deteriorate.

Moreover, if you parallel location is complexed as described above "core base (seat plate) ferrite cores butterfly shape" a parallel magnetic path a plurality of voids between the cores as shown in FIG. 2 The part 5 is generated to form an atmosphere flow path, and an effective air cooling function of the core is obtained.

The present invention has been completed based on the above knowledge and the like, and is characterized in that the ferrite core and the inductor have the following configurations.
1) A middle leg having a circular cross section is erected at the center and has a base (seat plate) whose width increases from the center toward the end, and “medium” at both ends of the base. a plurality of opposing surfaces is a curved surface and has been E-type ferrite core side leg "is erected forming the middle leg cross section and concentric with the legs, that formed by parallel location so magnetic path is parallel A composite ferrite core for inductors.
2) Between the middle leg and the side leg of the composite ferrite core described in the above 1), “an arcuate part having the inner leg outer diameter as the inner diameter and the outer leg inner diameter as the outer diameter” and “parallel straight section” An inductor comprising: a coil having a constriction formed by pressing a parallel straight portion of an oval-shaped coil composed of "" from outside and forming an outer side thereof in an arc shape with an inner diameter of a side leg. .

The composite ferrite core according to the present invention is used as an inductor after the coil is housed and covered with a ferrite lid (may be a ferrite core having the same shape as the composite ferrite core according to the present invention). However, the magnetic flux generated by the current flowing through the coil reaches the side leg that is erected from the upper end surface of the middle leg through the lid with the middle leg serving as the core of the coil interposed therebetween. A circulation path of magnetic flux is formed that returns to the middle leg through the base (seat plate) that is a component of the above.
If there is a portion smaller than the cross-sectional area of the middle leg in the circulation path of the magnetic flux, the generated magnetic flux is difficult to flow, and loss occurs. As described above, the E-type ferrite core constituting the composite ferrite core according to the present invention has a base ( The shape of the seat plate) is “the shape of a butterfly whose width expands from the central part where the middle leg is erected toward the end part” and the side legs are erected at both ends. Therefore, even if the width of the side leg that becomes the magnetic flux flow path can be increased and the thickness of the side leg is reduced, the total cross-sectional area of the side leg can be sufficiently secured, so that the flow of magnetic flux is hindered. There is no.
Further, the E-type ferrite core has a useless space between the middle leg and the side leg because the “surface facing the middle leg” of the side leg is a “curved surface concentric with the cross section of the middle leg”. Therefore, the coil can be mounted at a high density without causing a problem, and a high energy density can be secured.
Then, the ferrite core of the present invention, since a plurality of such E-type ferrite core magnetic path is obtained by the composite with parallel location in parallel so as to be parallel, the magnetic flux is increasing cross-sectional area of the magnetic path is Unlike the case of joining in series, the inductance increases with less electrical resistance.

Moreover, the composite ferrite core of the present invention, the gap portion is formed between the base of the butterfly-shaped base which is juxtaposed so in which a plurality of E-type ferrite core having a (seat plate) were co-location (seat plate) Thus, a flow path of atmosphere is formed, and effective air cooling from the inside of the composite core is possible.

FIG. 2 is an explanatory view showing an example of a composite ferrite core according to the present invention.
The composite ferrite core of this inductor is formed at both ends of a butterfly-shaped base (seat plate) 2 whose width increases from the center where the middle leg 3 is erected toward the end as shown in FIG. two side legs 4, 4 E-type ferrite core 1 which is erected "is one formed by closely parallel location so magnetic path is parallel.
The E-type ferrite core 1 which is a constituent element of the composite ferrite core according to the present invention is such that the “surface facing the middle leg 3” of the side legs 4 and 4 is “a curved surface concentric with the middle leg cross section”. Therefore, the coil can be mounted at a high density without generating a useless space between the middle leg 3 and the side leg 4, and a high energy density can be secured. In addition, the base (seat plate) 2 of the E-type ferrite core 1 has a butterfly shape that increases in width from the central portion where the middle leg 3 is erected toward the end portion. This is also very advantageous.
Thus, since the E-type ferrite core 1 which is a component of the composite ferrite core according to the present invention is compact, it has a high energy density. When the parallel location and a composite ferrite core as shown in the composite and Figure 2 in parallel so as to be parallel, inductor ferrite core with a very high inductance is realized.
In this case, between the E type ferrite core 1, 1 to parallel location in parallel may not necessarily become a close contact state, there is no harm in has occurred a little gap.

Moreover, in the composite ferrite core, the void portion 5 between the both basal (seat plate) because the two E-type ferrite core 1, 1 having a base (seat plate) of a butterfly shape is obtained by parallel location As a result, air cooling from the inside of the composite core is enabled.

Claims (2)

  A middle leg with a circular cross section is erected at the center and has a base whose width increases from the center toward the end, and the opposite surfaces of the middle leg are at both ends of the base. A composite ferrite core for an inductor, comprising a plurality of E-type ferrite cores, each having a curved side leg that is concentric with a leg cross-section and arranged so that magnetic paths are parallel to each other. .   An oval comprising an arc-shaped portion having an outer diameter of the middle leg and an inner diameter of the side leg as an outer diameter and a parallel straight portion between the middle leg and the side leg of the composite ferrite core according to claim 1. An inductor comprising: a coil having a constriction formed by pressing a parallel straight portion of a coil-like coil from the outside and forming an outer side thereof in an arc shape with an inner diameter of a side leg.

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