The present invention contains subject matter related to Japanese Patent Application JP2012-200091 filed in the Japanese Patent Office on Sep. 12, 2012, the entire contents of which being incorporated herein by reference.
1. Field of the Invention
The present invention relates to a magnetic core having a winding core portion and a flange portion, a magnetic component using such a magnetic core, and a design method of a magnetic core.
2. Description of the Related Art
In the past, there have been known a magnetic core provided with flange portions at both end portions of a winding core portion around which a conductive wire is wound, and a magnetic component using such a magnetic core. For example, in Patent Document 1 (Japanese unexamined patent publication No. 2007-173573), there is disclosed a magnetic component (inductor) using a magnetic core provided with disk-like flange portions at both end portions of a cylindrical winding core portion.
With regard to this kind of magnetic component, there are many cases in which the magnetic component is mounted on a circuit board of electronic equipment such as a mobile-phone, portable music media equipment, a portable game machine, a small-sized video camera or the like in which miniaturization request thereof is high. At that time, a region given for mounting the magnetic component (hereinafter, referred to arbitrarily as “mounting region”) on the circuit board is restricted, so that miniaturization of the magnetic component is required such that it is possible to accommodate the component within the given mounting region.
The magnetic component described in the Patent Document 1 achieves miniaturization by employing a constitution in which a portion of a terminal placed on the flange portion bottom surface, which extends outward from the flange portion contour line, is to be accommodated within a space (hereinafter, referred to arbitrarily as “excess space”) which occurs between a contour line of a flange portion when orthographically-projecting this magnetic component toward the axis line direction of the winding core portion and a square shape circumscribed with this contour line (hereinafter, referred to arbitrarily as “circumscribed square shape”).
As the mounting region on the circuit board is more narrowed and decreased, it becomes difficult to secure a useful excess space in which it is possible, within the mounting region, to arrange the extended portion of the terminal such as described above or the like while securing a necessary space for placing the flange portion (hereinafter, referred to arbitrarily as “space for placing the flange portion”).
In order to secure a necessary space for placing the flange portion and a useful excess space within a narrow mounting region, it becomes necessary to utilize the space inside the mounting region efficiently. Specifically, it becomes important to employ a configuration in which a wasted space will not occur within the mounting region while heightening the area ratio of the space for placing the flange portion, which is occupied within the mounting region (hereinafter, referred to arbitrarily as “flange portion occupation-area ratio”).
With regard to the magnetic component described in the abovementioned Patent Document 1, in case of setting the inside of the aforementioned circumscribed square shape to be the mounting region, it becomes a situation in which excess spaces having mutually equal sizes & shapes will be formed respectively at the four corners of the mounting region thereof. However, when the mounting region is narrowed and decreased, the areas of the respective excess spaces become small in response thereto and therefore, there is a fear that it becomes impossible to effectively utilize these excess spaces as the spaces for arranging extended portions of the terminals or the like. Also, since the flange portion is formed to be disk-like, it is also difficult to heighten the flange portion occupation-area ratio with respect to the mounting region.
The present invention was invented in view of such a situation and is addressed to provide a magnetic core, a magnetic component and a design method of such a magnetic core in which it is possible to secure a necessary space for placing the flange portion and a useful excess space even within a narrow mounting region.
The magnetic core, the magnetic component and the design method of magnetic core relating to the present invention are provided with the following features.
The magnetic core relating to the present invention is a magnetic core including a winding core portion; and a flange portion provided on the axial end side of at least one of the winding core portion, wherein
The flange portion is formed such that contour line OL1 of cross-section P, of the flange portion, which becomes perpendicular with respect to the axis line of the winding core portion forms a shape of a first irregular convex polygon which is substantially a non-regular polygon and also a convex polygon, and
the contour line OL1 contacts with respect to all of side Sb1, side Sb2, side Sb3 and side Sb4 which are the four sides of a first circumscribed rectangle which becomes minimum within imaginary rectangles circumscribed with the contour line OL1 and also, the contour line OL1 includes side Sa1 and side Sa2 which respectively overlap with portions of respective ones of the side Sb1 and the side Sb2 which are mutually parallel within the four sides.
According to a magnetic core having such a characterized structure, it becomes possible, by adjusting the shape of the contour line OL1 of the cross-section P of the flange portion corresponding to the shape of the abovementioned first circumscribed rectangle, to secure a useful excess space within the mounting region, in which a terminal or the like is arranged while heightening the flange portion occupation-area ratio in case of setting the inside of the first circumscribed rectangle to be the mounting region.
It should be noted that the word “substantially” in the wording “substantially a non-regular polygon and also a convex polygon” means that even such a drawing which does not become a polygon in a strict sense for the reason that a chamfering process by Radius (R)-chamfering or the like is applied to the corner portions of a polygon is to be treated as a polygon in the present invention.
It is possible for the magnetic core relating to the present invention to be constituted such that for one end portion and the other end portion of one diagonal line Db1 of the first circumscribed rectangle, the cross-section P includes corner cutting portion Ca1 and corner cutting portion Ca2 respectively which are formed such that corner portion Cb1 and corner portion Cb2 positioned on the diagonal line Db1 of the first circumscribed rectangle are removed obliquely.
According to the magnetic core having this aspect, it becomes possible to secure the regions in which the corner portion Cb1 and the corner portion Cb2 are removed as excess spaces for terminals or the like to be arranged therein.
In addition, it is possible for the magnetic core relating to the present invention to be constituted such that for one end portion and the other end portion of the other diagonal line Db2 of the first circumscribed rectangle, the cross-section P includes corner cutting portion Ca3 and corner cutting portion Ca4 respectively which are formed such that corner portion Cb3 and corner portion Cb4 positioned on the diagonal line Db2 of the first circumscribed rectangle are removed obliquely, and which have ½ or less sizes of the corner cutting portion Ca1 and the corner cutting portion Ca2.
According to the magnetic core having this aspect, it becomes possible to heighten the flange portion occupation-area ratio with respect to the mounting region efficiently by setting the sizes of the corner cutting portion Ca3 and the corner cutting portion Ca4 to be sizes of ½ or less of the corner cutting portion Ca1 and the corner cutting portion Ca2.
In addition, in the magnetic core relating to the present invention, it is possible for the contour line OL1 to be formed to have a shape which becomes point-symmetric with regard to the gravity center of the first circumscribed rectangle.
According to the magnetic core having this aspect, it is possible for the flange portion to be made as a point-symmetrical shape, so that it becomes possible to carry out the manufacture of the flange portion easily compared with a case in which the flange portion is made to have a non-point-symmetrical shape.
In addition, in the magnetic core relating to the present invention, it is possible for the winding core portion to be formed such that contour line OL2 of cross-section Q of the winding core portion, which becomes perpendicular with respect to the axis line, forms a shape of a second irregular convex polygon which is substantially a non-regular polygon and also a convex polygon.
According to the magnetic core having this aspect, it becomes possible, by adjusting the shape of the contour line OL2 of the cross-section Q of the winding core portion, to adjust the space between the contour line OL1 and the contour line OL2, which is utilized as a region in which a conductive wire is wound, properly if required.
In addition, in the magnetic core relating to the present invention, it is possible for the cross-section Q to include, at a position corresponding to the corner cutting portion Ca1 of the cross-section P, corner cutting portion Cc1 constituted by corner cutting line Lc1 which becomes parallel with respect to corner cutting line La1 constituting the corner cutting portion Ca1; and for the cross-section Q to include, at a position corresponding to the corner cutting portion Ca2 of the cross-section P, corner cutting portion Cc2 constituted by corner cutting line Lc2 which becomes parallel with respect to corner cutting line La2 constituting the corner cutting portion Ca2.
According to the magnetic core of this aspect, it becomes possible to properly secure the region in which the conductive wire is wound even between the corner cutting line La1 constituting the corner cutting portion Ca1 and the corner cutting line Lc1 constituting the corner cutting portion Cc1 and between the corner cutting line La2 constituting the corner cutting portion Ca2 and the corner cutting line Lc2 constituting the corner cutting portion Cc2.
In addition, in the magnetic core relating to the present invention, it is possible for the winding core portion to be applied, for a predetermined convex corner portion within all convex corner portions in the cross-section Q, with chamfering of ½ or less size with respect to the corner cutting portion Cc1 and the corner cutting portion Cc2.
According to the magnetic core of this aspect, it becomes possible to reduce the possibility in which the conductive wire wound around the winding core portion will be broken by being damaged at a predetermined convex corner portion. Also, by making the chamfering sizes be ½ or less of the sizes of the corner cutting portion Cc1 and the corner cutting portion Cc2, it becomes possible also to prevent the area of the cross-section Q of the winding core portion from decreasing considerably caused by the chamfering.
The magnetic component relating to the present invention is a magnetic component including a magnetic core relating to the present inventions mentioned above and includes:
a winding portion formed by a configuration in which a conductive wire covered by insulation coating is wound around the winding core portion; and
a first terminal and a second terminal which are respectively connected to the respective end portions of the winding portion and which are formed by plate-like metals.
In the magnetic component relating to the present invention, it is possible for each of the first terminal and the second terminal to be provided with amount portion abutted to the mounting face of the magnetic core with respect to the substrate and provided with a coupling portion formed integrally with the mount portion, and
for the coupling portion of the first terminal and the coupling portion of the second terminal to be connected to one end portion and the other end portion of the winding portion respectively and also, are arranged at the corner cutting portion Ca1 and the corner cutting portion Ca2 of the flange portion respectively.
In addition, in the magnetic component relating to the present invention, it is possible for the coupling portion of the first terminal and the coupling portion of the second terminal to be provided with rising portions formed so as to go respectively along the side surface of the corner cutting portion Ca1 and the side surface of the corner cutting portion Ca2 at the flange portion positioned on the mounting face side of the magnetic core, and provided with extended portions extended in parallel with respect to the mounting face from one end sides of the rising portions respectively; and
for the extended portion for the first terminal and the extended portion for the second terminal to be formed so as to be accommodated within a space between the corner cutting portion Ca1 and the first circumscribed rectangle and within a space between the corner cutting portion Ca2 and the first circumscribed rectangle respectively.
The manufacturing method of the magnetic core relating to the present invention is a design method of a magnetic core which includes a winding core portion and a flange portion provided on at least one of the axial end sides of the winding core portion, including the steps of:
setting, on the same design-plane, a first circumscribed rectangle circumscribed to contour line OL1 of cross-section P, of the flange portion, which becomes perpendicular with respect to the axis line of the winding core portion and a second circumscribed rectangle circumscribed to contour line OL2 of cross-section Q which becomes perpendicular with respect to the axis line of the winding core portion;
setting, on the design-plane, an initial shape of the cross-section P and an initial shape of the cross-section Q;
setting, on the design-plane, corner cutting line La1 and corner cutting line La2 which respectively and obliquely remove corner portion Cb1 and corner portion Cb2, of the first circumscribed rectangle, which are positioned on one diagonal line Db1 of the first circumscribed rectangle, to be portions of the contour line OL1;
reducing, on the design-plane, the shape of the cross-section Q at the corner portion Cd1 and the corner portion Cd2, of the second circumscribed rectangle, which correspond to the corner portion Cb1 and the corner portion Cb2 of the first circumscribed rectangle such that a predetermined width of the winding frame is to be secured between the corner cutting line La1 & the corner cutting line La2 and the contour line OL2; and
increasing, on the design-plane, the shape of the cross-section Q at other corner portion Cd3 and corner portion Cd4 of the second circumscribed rectangle as much as the reduced degree of the shape of the cross-section Q at the corner portion Cd1 and the corner portion Cd2.
According to a magnetic core and a magnetic component relating to the present invention, it becomes possible, by being provided with the aforementioned characterized structure, to secure a necessary space for placing the flange portion and a useful excess space even within a narrow mounting region.
In addition, according to a design method of a magnetic core relating to the present invention, it becomes possible to design a magnetic core in which there can be secured a necessary space for placing the flange portion and a useful excess space even within a narrow mounting region.
Hereinafter, there will be explained exemplified embodiments of a magnetic core, a magnetic component and a design method of the magnetic core relating to the present invention in detail while referring to the abovementioned drawings.
As shown in
Also, the magnetic core 10 is formed, for example, by a ferrite of a soft magnetic material (other than “ferrite”, it is also possible to use a material such as permalloy, sendust, iron carbonyl and the like or to use a dust core formed by compression-molding the fine powders thereof). It should be noted that in case of forming the magnetic core 10 by an Ni—Zn-based ferrite or by an Mn—Zn-based ferrite, it becomes possible to miniaturize the magnetic core 10 compared with a case in which the magnetic core 10 is formed by an Fe—Si-based alloy or by an Fe—Ni-based alloy.
Next, while referring to
Also, in
As shown in
Also, the abovementioned cross-section P includes corner cutting portion Ca1 and corner cutting portion Ca2 at one end portion and the other end portion of one diagonal line Db1 of the abovementioned first circumscribed rectangle RC1 respectively. The corner cutting portion Ca1 is constituted by corner cutting line La1 which is formed so as to obliquely remove one corner portion Cb1 positioned on the diagonal line Db1 of the first circumscribed rectangle RC1. Similarly, the corner cutting portion Ca2 is constituted by corner cutting line La2 which is formed so as to obliquely remove the other corner portion Cb2 positioned on the diagonal line Db1 of the first circumscribed rectangle RC1. It should be noted in this exemplified embodiment that both of the inclination angle of the corner cutting line La1 with respect to the sides Sa1, Sa3 of the abovementioned contour line OL1 and the inclination angle of the corner cutting line La2 with respect to the abovementioned sides Sa2, Sa4 are constituted so as to become 45 degrees (it is possible to employ other inclination angles).
Further, the abovementioned cross-section P includes corner cutting portion Ca3 and corner cutting portion Ca4 at one end portion and the other end portion of the other diagonal line Db2 of the abovementioned first circumscribed rectangle RC1 respectively. The corner cutting portion Ca3 is constituted by corner cutting line La3 which is formed so as to obliquely remove one corner portion Cb3 positioned on the diagonal line Db2 of the first circumscribed rectangle RC1. Similarly, the corner cutting portion Ca4 is constituted by corner cutting line La4 which is formed so as to obliquely remove the other corner portion Cb4 positioned on the diagonal line Db2 of the first circumscribed rectangle RC1. It should be noted in this exemplified embodiment that both of the inclination angle of the corner cutting line La3 with respect to the sides Sa2, Sa3 of the abovementioned contour line OL1 and the inclination angle of the corner cutting line La4 with respect to the abovementioned sides Sa1, Sa4 are constituted so as to become 45 degrees (it is possible to employ other inclination angles).
It should be noted that the size of the corner cutting portion Ca1 (area of the removed region of the corner portion Cb1) and the size of the corner cutting portion Ca2 (area of the removed region of the corner portion Cb2) are constituted to become equal to each other. Also, the corner cutting line La1 constituting the corner cutting portion Ca1 and the corner cutting line La2 constituting the corner cutting portion Ca2 are constituted to be in parallel with each other and also to have the same isometries.
Similarly, the size of the corner cutting portion Ca3 (area of the removed region of corner portion Cb3) and the size of the corner cutting portion Ca4 (area of the removed region of corner portion Cb4) are constituted so as to become equal to each other, and the corner cutting line La3 constituting the corner cutting portion Ca3 and the corner cutting line La4 constituting the corner cutting portion Ca4 are constituted to be in parallel with each other and also to have the same isometries.
Also, the corner cutting portion Ca3 and the corner cutting portion Ca4 are constituted so as to have sizes of 1/10 or more and ½ or less (preferably, ⅕ or more and ½ or less) with respect to the sizes of the corner cutting portion Ca1 and the corner cutting portion Ca2.
Further, the contour line OL1 of the abovementioned cross-section P is formed to have a shape which becomes point-symmetric with regard to the gravity center of the first circumscribed rectangle RC1 (intersection point between the two lines of diagonal lines Db1, Db2). By employing the point-symmetrical shape, the process when forming the first flange portion 12 (second flange portion 13) becomes easy.
On the other hand, the contour line OL2 of the cross-section Q of the winding core portion 11 forms a shape of a second irregular convex polygon (this becomes irregular convex hexagon in case of counting each of the after-mentioned convex corner portions Cc3, Cc4 as one corner) which is an non-regular polygon and also a convex polygon substantially. Also, this contour line OL2 contacts with respect to all of side Sd1, side Sd2, side Sd3 and side Sd4 which are four sides of the abovementioned second circumscribed rectangle RC2. Further, the contour line OL2 includes side Sc1 and side Sc2 which respectively overlap with portions of respective ones of the abovementioned side Sd1 and the abovementioned side Sd2 which are mutually parallel and side Sc3 and side Sc4 which respectively overlap with portions of respective ones of the abovementioned side Sd3 and the abovementioned side Sd4 within the abovementioned four sides.
Also, the abovementioned cross-section Q includes, at the position corresponding to the corner cutting portion Ca1 of the abovementioned cross-section P, corner cutting portion Cc1 constituted by the corner cutting line Lc1 which becomes parallel with respect to the abovementioned corner cutting line La1 constituting this corner cutting portion Ca1. Similarly, the cross-section Q includes, at the position corresponding to the corner cutting portion Ca2 of the abovementioned cross-section P, corner cutting portion Cc2 constituted by the corner cutting line Lc2 which becomes parallel with respect to the abovementioned corner cutting line La2 constituting this corner cutting portion Ca2.
Also, for the winding core portion 11, Chamfer (C)-chamfering is applied (Radius (R)-chamfering is also possible) at the convex corner portion Cc3 formed at the position corresponding to the corner cutting portion Ca3 of the abovementioned cross-section P and at the convex corner portion Cc4 formed at the position corresponding to the corner cutting portion Ca4 of the abovementioned cross-section P within all the convex corner portions in the abovementioned cross-section Q. This chamfering size (size of the region which is cut-out by the chamfering in the cross-section Q) is made to be ½ or less (preferably, ⅕ or less) of the size of the aforementioned corner cutting portion Cc1 and the corner cutting portion Cc2.
By applying such a chamfering, it becomes possible to prevent the conductive wire from being damaged and disconnected at the convex corner portions Cc3, Cc4 when winding the conductive wire around the winding core portion 11.
Also, in the magnetic core 10, a space region which is formed among the circumference surface of the winding core portion 11, the lower surface of the first flange portion 12 (surface on the side faced to the second flange portion 13) and the upper surface of the second flange portion 13 (surface on the side faced to the first flange portion 12) is formed as a region in which a conductive wire can be wound around the winding core portion 11 (see
It should be noted that the aforementioned corner cutting portions Ca1, Ca2, Ca3, Ca4, Cc1, Cc2 and convex corner portions Cc3, Cc4 are the portions defined for the contour line OL1 of the cross-section P and for the contour line OL2 of the cross-section Q, both of which are shown in
A magnetic component 20 relating to one exemplified embodiment of the present invention is provided, as shown in
The first terminal 40A is provided with a mount portion 41A which is abutted on amounting face (bottom surface of the second flange portion 13 shown in
The coupling portion 42A of the abovementioned first terminal 40A is provided with a rising portion 43A which is formed so as to be along the side surface of the corner cutting portion Ca1 of the flange portion 13 and an extended portion 44A which is extended in parallel with respect to the abovementioned mounting face from one end side of this rising portion 43A. Also, this extended portion 44A is connected with one end portion 31 of the abovementioned winding portion 30 by welding or the like (it is allowed to employ a configuration of connection by soldering or thermo-compression bonding, or a configuration of connection by soldering after twisting one end portion 31 of the winding portion 30 around the extended portion 44A).
Similarly, the coupling portion 42B of the abovementioned second terminal 40B is provided with a rising portion 43B which is formed so as to be along the side surface of the corner cutting portion Ca2 of the flange portion 13 and an extended portion 44B which is extended in parallel with respect to the abovementioned mounting face from one end side of this rising portion 43B. Also, this extended portion 44B is connected with the other end portion 32 of the abovementioned winding portion 30 by welding or the like (it is allowed to employ a configuration of connection by soldering or thermo-compression bonding, or a configuration of connection by soldering after twisting the other end portion 32 of the winding portion 30 around the extended portion 44B).
Also, as shown in
Next, while referring to
(1) As shown in
(2) As shown in
Also, in the design method of this exemplified embodiment, the initial shape of the cross-section Q is set such that the contour line OL2 thereof is designed to have a shape of a convex octagon provided with four corner cutting portions Cc11, Cc12, Cc13 and Cc14 which have mutually the same sizes at the positions corresponding to the respective ones of the four corner cutting portions Ca11, Ca12, Ca13 and Ca14 of the abovementioned contour line OL1. It should be noted that the sizes of the corner cutting portions Cc11, Cc12, Cc13 and Cc14 are set, for example, such that a predetermined width of the winding frame is to be secured between the contour line OL1 and the contour line OL2 over the whole circumference of the contour line OL2 (widths of the winding frames D1 to D8 shown in
(3) As shown in
(4) As shown in
(5) As shown in
(6) As shown in
According to the procedures described above, the design of the respective cross-sections P, Q of the first flange portion 12 and the winding core portion 11 in the magnetic core 10 mentioned above is completed. It should be noted that it is unnecessary for the increase of the cross-section P in the aforementioned flange-portion increasing step to be carried out in a case in which predetermined widths of the winding frames D7 and D8 are secured beforehand between the convex corner portion Cc3 and the corner cutting portion Ca13 and between the convex corner portion Cc4 and the corner cutting portion Ca14. It is possible for the magnetic core 10 designed in this manner to possess a magnetic property equivalent to or more than the magnetic property in comparison with the magnetic core having the initial shape shown in
As described above, there were explained exemplified embodiments of the present invention, but the present invention is not to be limited by the aforementioned exemplified embodiments and it is possible to change the aspect variously.
For example, in the aforementioned exemplified embodiments, the first circumscribed rectangle RC1 and the second circumscribed rectangle RC2 are respectively designed to be rectangles each of which has a non-square shape, but it is also possible for one or both thereof to be made in square shape.
Also, in the aforementioned exemplified embodiment, the contour line OL1 of the cross-section P and the contour line OL2 of the cross-section Q are formed so as to become irregular convex octagon-shapes respectively, but it is also possible for those lines to be formed in shapes of other irregular convex polygons.
Also, in the aforementioned exemplified embodiments, the width of the winding frame between the contour line OL1 of the cross-section P and the contour line OL2 of the cross-section Q is constituted to be isometric over the whole circumference of the winding core portion 11 (see
Also, in the exemplified embodiments of the design method of the aforementioned magnetic core, the initial shape of the contour line OL1 of the cross-section P and the initial shape of the contour line OL2 of the cross-section Q are set to be convex octagons respectively, but it is allowed to employ initial shapes having other arbitrary shapes. For example, there can be cited a case, as one example, in which the initial shape of the contour line OL1 is designed to have the same shape as that of the first circumscribed rectangle RC1 or the initial shape of the contour line OL2 is designed to have the same shape as that of the second circumscribed rectangle RC2.
Also, in the aforementioned exemplified embodiments, there is explained the magnetic core (magnetic core 10) including two flange portions (first flange portion 12 and second flange portion 13) in which those two portions have shapes & sizes identical to each other, but it is possible for the present invention to be applied also with respect to a magnetic core including two flange portions which have shapes different from each other or a magnetic core including a flange portion only on one single axial-end side of the winding core portion.
Also, in the aforementioned exemplified embodiment, the shapes of the contour lines OL1, OL2 are designed to be irregular convex polygons, but it is also possible for the shapes of the contour lines OL1, OL2 to use various irregular convex shapes, for example, convex shapes which resemble ellipses or the like if they do not depart from the gist of the present invention.
Having described preferred embodiments of the invention with reference to the accompanying drawings, it is to be understood that the invention is not limited to those precise embodiments and that various changes and modifications could be effected therein by one skilled in the art without departing from the spirit or scope of the invention as defined in the appended claims.
Number | Date | Country | Kind |
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2012-200091 | Sep 2012 | JP | national |
Number | Date | Country | |
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Parent | 14025371 | Sep 2013 | US |
Child | 14716067 | US |