JP2011077302A - Coil and transformer - Google Patents

Coil and transformer Download PDF

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JP2011077302A
JP2011077302A JP2009227297A JP2009227297A JP2011077302A JP 2011077302 A JP2011077302 A JP 2011077302A JP 2009227297 A JP2009227297 A JP 2009227297A JP 2009227297 A JP2009227297 A JP 2009227297A JP 2011077302 A JP2011077302 A JP 2011077302A
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magnetic material
material substrate
air gap
coil
conductor
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JP5219975B2 (en
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Kazunori Kidera
和憲 木寺
Yoshiki Hayazaki
嘉城 早崎
Masanao Kamakura
將有 鎌倉
Yoshio Mitsutake
義雄 光武
Tomoji Suzuki
智士 鈴木
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Panasonic Electric Works Co Ltd
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a coil and a transformer that are not easy to get magnetically saturated while made compact and lightweight. <P>SOLUTION: The coil 1 includes a lower magnetic material substrate 2, a looped conductor 3 formed on the lower magnetic material substrate 2, a magnetic material core layer 4 provided at a periphery of the looped conductor 3, and an upper magnetic material substrate 5. Further, an air gap 6 is formed between the looped conductor 3 and magnetic material core layer 4. A gap length of the air gap 6 in a direction perpendicular to the lower magnetic material substrate 2 varies to be larger toward the looped conductor 3 and to be smaller away therefrom, and a thickness of the magnetic material core layer 4 has an in-plane distribution. Consequently, magnetic resistance of a path extending nearby the looped conductor is substantially equal to that of a path passing far away therefrom, so that magnetic flux density in a core part becomes uniform and magnetic saturation is not easily caused. The transformer includes a pair of the coils 1, and is constituted by joining each loop conductor and the core part together opposite each other. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

本発明は、磁性材基板上に形成されるコイル及びトランスに関する。   The present invention relates to a coil and a transformer formed on a magnetic material substrate.

近年、小型・軽量の電子機器に用いられる電源の小型・軽量化が求められており、電源回路の中で比較的大きな部品であるコイルやトランス等の磁気素子の小型・軽量化が課題となってきている。このために、磁性材基板上に平面コイルを形成し、平面コイルを磁性樹脂層で覆い、その上から上部磁性材基板で挟み込むような構造とした磁気素子が知られている(例えば、特許文献1参照)。   In recent years, there has been a demand for miniaturization and weight reduction of power supplies used in small and lightweight electronic devices, and there has been an issue of miniaturization and weight reduction of magnetic elements such as coils and transformers, which are relatively large components in the power supply circuit. It is coming. For this purpose, a magnetic element is known in which a planar coil is formed on a magnetic material substrate, the planar coil is covered with a magnetic resin layer, and sandwiched between upper magnetic material substrates from above (see, for example, Patent Documents). 1).

しかしながら、このような磁気素子は、平面コイルの近傍を通る経路における磁気抵抗が、平面コイルの遠くを通る経路の磁気抵抗より小さいので、平面コイルの導体近辺に磁束が集中する。このために、平面コイルの導体に大電流が流れると、導体から離れたところでは磁束密度があまり高くないにも拘らず、導体付近では磁束密度が高くなって磁気飽和するので、インダクタンスが低下するという問題がある。   However, in such a magnetic element, the magnetic resistance in the path passing through the vicinity of the planar coil is smaller than the magnetic resistance in the path passing through the distance of the planar coil, so that the magnetic flux concentrates near the conductor of the planar coil. For this reason, when a large current flows through the conductor of the planar coil, the magnetic flux density is not so high at a distance from the conductor, but the magnetic flux is high in the vicinity of the conductor and magnetic saturation occurs, so that the inductance decreases. There is a problem.

特開2007−173384号公報JP 2007-173384 A

本発明は、上記問題を解消するものであり、小型・軽量化を図りつつ磁気飽和し難いコイル及びトランスを提供することを目的とする。   An object of the present invention is to solve the above-described problems, and to provide a coil and a transformer that are difficult to be magnetically saturated while achieving a reduction in size and weight.

上記目的を達成するために請求項1の発明は、磁性材基板と、前記磁性材基板上に形成されたループ状導体と、前記ループ状導体の周辺に設けられ前記ループ状導体に通電されたときに発生する磁束が通る磁性体から成るコア部と、を備えたコイルにおいて、前記コア部は、前記ループ状導体との間にエアギャップを有し、前記エアギャップは、前記磁性材基板に垂直な方向のギャップ長が前記ループ状導体に近づく程大きくなり、前記ループ状導体から離れる程小さくなるように変化しているものである。   In order to achieve the above object, the invention according to claim 1 is the magnetic material substrate, the loop conductor formed on the magnetic material substrate, and the loop conductor provided around the loop conductor to energize the loop conductor. A coil made of a magnetic material through which a magnetic flux generated sometimes passes, and the core has an air gap between the loop-shaped conductor, and the air gap is formed on the magnetic material substrate. The gap length in the vertical direction increases so as to approach the loop-shaped conductor and changes so as to decrease as the distance from the loop-shaped conductor increases.

請求項2の発明は、請求項1に記載のコイルにおいて、前記エアギャップは、前記コア部と磁性材基板との間に形成されるものである。   According to a second aspect of the present invention, in the coil according to the first aspect, the air gap is formed between the core portion and the magnetic material substrate.

請求項3の発明は、請求項1又は請求項2に記載のコイルにおいて、前記エアギャップが、前記磁性材基板及びコア部の材質よりも透磁率の低い材質によって置換されたものである。   According to a third aspect of the present invention, in the coil according to the first or second aspect, the air gap is replaced with a material having a lower magnetic permeability than materials of the magnetic material substrate and the core portion.

請求項4の発明は、請求項1乃至請求項3のいずれか一項に記載のコイルを一対備え、前記一対のコイルは、各磁性材基板が外側に位置し、各ループ状導体とコア部同士が対面するように接合されたものである。   A fourth aspect of the invention comprises a pair of the coils according to any one of the first to third aspects, wherein each of the pair of coils has each magnetic material substrate positioned outside, and each loop-like conductor and core portion. They are joined so that they face each other.

請求項1の発明によれば、エアギャップ長が位置によって変化していて、コア部の磁性材基板に垂直な方向の厚みが面内分布を持つことにより、ループ状導体の近くを通る経路における磁気抵抗と、遠くを通る経路における磁気抵抗とを略同一とすることができる。このため、コア部内の磁束密度が均一になって磁気飽和し難くなり、全体の小型・軽量化を図ることができる。   According to the first aspect of the present invention, the air gap length varies depending on the position, and the thickness of the core portion in the direction perpendicular to the magnetic material substrate has an in-plane distribution. The magnetoresistance and the magnetoresistance in the path passing through a distance can be made substantially the same. For this reason, the magnetic flux density in the core portion becomes uniform, and magnetic saturation is difficult to occur, and the overall size and weight can be reduced.

請求項2の発明によれば、エアギャップが磁性材基板とコア部との間に位置するので、磁性材基板の上に材料を積層していくMEMS(Micro Electro Mechanical System)技術によってエアギャップを作り易くなり、コイルを容易に製造することができる。   According to the invention of claim 2, since the air gap is located between the magnetic material substrate and the core portion, the air gap is formed by a MEMS (Micro Electro Mechanical System) technology in which materials are stacked on the magnetic material substrate. It becomes easy to make and the coil can be manufactured easily.

請求項3の発明によれば、エアギャップが透磁率の低い材質によって置換されるので、エアギャップを形成する手間が省かれ、コイルを容易に製造することができる。   According to the invention of claim 3, since the air gap is replaced with a material having a low magnetic permeability, the trouble of forming the air gap is saved, and the coil can be easily manufactured.

請求項4の発明によれば、トランスを構成するそれぞれのコイルが磁気飽和し難いので、トランスも磁気飽和し難くなり、請求項1と同等の効果が得られる。   According to the invention of claim 4, since each coil constituting the transformer is hardly magnetically saturated, the transformer is also hardly magnetically saturated, and the same effect as that of claim 1 can be obtained.

(a)は本発明の第1の実施形態に係るコイルの分解構成図、(b)は同コイルの斜視図。(A) is a disassembled block diagram of the coil which concerns on the 1st Embodiment of this invention, (b) is a perspective view of the same coil. (a)は同コイルの断面図、(b)は(a)における断面図の部分拡大図。(A) is sectional drawing of the coil, (b) is the elements on larger scale of the sectional view in (a). 本発明の第2の実施形態に係るトランスの断面図。Sectional drawing of the trans | transformer which concerns on the 2nd Embodiment of this invention.

(第1の実施形態)
第1の実施形態について図1及び図2を参照して説明する。本実施形態に係るコイル1は、下部磁性材基板(磁性材基板)2と、下部磁性材基板2上に形成されたループ状導体3と、ループ状導体3の周辺に設けられループ状導体3に通電されたときに発生する磁束が通る磁性体から成る磁性材コア層(コア部)4と、ループ状導体3上に配置される上部磁性材基板5とを備えている。また、ループ状導体3と磁性材コア層4との間にエアギャップ6が形成されている。下部磁性材基板2及び上部磁性材基板5はフェライトを、ループ状導体3は銅を、磁性材コア層4はNiFeをそれぞれ用いることができる。 (First embodiment)
A first embodiment will be described with reference to FIGS. 1 and 2. The coil 1 according to the present embodiment includes a lower magnetic material substrate (magnetic material substrate) 2, a loop conductor 3 formed on the lower magnetic material substrate 2, and a loop conductor 3 provided around the loop conductor 3. Are provided with a magnetic material core layer (core portion) 4 made of a magnetic material through which a magnetic flux generated when current is passed through and an upper magnetic material substrate 5 disposed on the loop-shaped conductor 3. An air gap 6 is formed between the loop conductor 3 and the magnetic material core layer 4. The lower magnetic material substrate 2 and the upper magnetic material substrate 5 can use ferrite, the loop conductor 3 can use copper, and the magnetic material core layer 4 can use NiFe.

ループ状導体3、磁性材コア層4、上部磁性材基板5、及びエアギャップ6は、例えばMEMSプロセスを用いて、下部磁性材基板2の上に形成することができる。ループ状導体3は、下部磁性材基板2、磁性材コア層4及び上部磁性材基板5が絶縁体でない場合には、全表面を酸化膜等の絶縁層で覆って絶縁分離する。磁性材コア層4は、ループ状導体3の内周側と外周側に設けられる。この磁性材コア層4を通る磁束密度を均一にするために、磁性材コア層4の厚み(磁性材基板に垂直方向の厚み)が面内分布を持つように、エアギャップ6における下部磁性材基板2に垂直な方向のギャップ長を、ループ状導体3に近づく程大きくなり、ループ状導体3から離れる程小さくなるように変化させている。   The loop-shaped conductor 3, the magnetic material core layer 4, the upper magnetic material substrate 5, and the air gap 6 can be formed on the lower magnetic material substrate 2 by using, for example, a MEMS process. When the lower magnetic material substrate 2, the magnetic material core layer 4 and the upper magnetic material substrate 5 are not insulators, the loop-shaped conductor 3 is insulated and separated by covering the entire surface with an insulating layer such as an oxide film. The magnetic material core layer 4 is provided on the inner peripheral side and the outer peripheral side of the loop conductor 3. In order to make the magnetic flux density passing through the magnetic material core layer 4 uniform, the lower magnetic material in the air gap 6 is set such that the thickness of the magnetic material core layer 4 (thickness in the direction perpendicular to the magnetic material substrate) has an in-plane distribution. The gap length in the direction perpendicular to the substrate 2 is changed so as to be closer to the loop conductor 3 and to be smaller as the distance from the loop conductor 3 is increased.

エアギャップ6の形成は、エアギャップ6を形成する箇所に一旦、SiO等の部材を形成し、その後に形成した部材を除去することによって行う。エアギャップ6の下部磁性材基板2に垂直な方向における位置は、下部磁性材基板2と上部磁性材基板5の間ならば、いずれの位置に形成してもよい。しかしながら、磁性材コア層4の上部磁性材基板5側にエアギャップ6を形成すると、エアギャップ6を形成した後に上部磁性材基板5を磁性材コア層4に接合するときに接着剤等によってエアギャップ6が埋まってしまう虞がある。そこで、ループ状導体3や磁性材コア層4がMEMSプロセスによって下部磁性材基板2の上に積層して作られるので、エアギャップ6を下部磁性材基板2と磁性材コア層4との間に設けることにより、コイル1を製造し易くなる。   The formation of the air gap 6 is performed by once forming a member such as SiO at a position where the air gap 6 is formed and then removing the formed member. The position of the air gap 6 in the direction perpendicular to the lower magnetic material substrate 2 may be formed at any position between the lower magnetic material substrate 2 and the upper magnetic material substrate 5. However, when the air gap 6 is formed on the upper magnetic material substrate 5 side of the magnetic material core layer 4, the air is bonded by an adhesive or the like when the upper magnetic material substrate 5 is joined to the magnetic material core layer 4 after the air gap 6 is formed. There is a possibility that the gap 6 is filled. Therefore, since the loop conductor 3 and the magnetic material core layer 4 are formed on the lower magnetic material substrate 2 by the MEMS process, an air gap 6 is formed between the lower magnetic material substrate 2 and the magnetic material core layer 4. By providing, it becomes easy to manufacture the coil 1.

次に、上記のように構成されたコイル1の作用効果について、図2を参照して説明する。ループ状導体3に通電されると、発生した磁束が下部磁性材基板2、磁性材コア層4、上部磁性材基板5及びエアギャップ6を通る。このときの、ループ状導体3に近い位置を通る経路Iと、ループ状導体3から離れた位置を通る経路IIとにおけるそれぞれの磁気抵抗を、エアギャップ6が無い場合と比較して簡易的に求める。ここで、下部磁性材基板2及び上部磁性材基板5の比透磁率μ1=1000、磁性材コア層4の比透磁率μ2=500、エアギャップ6の比透磁率μ3=1としている。また、経路Iにおいて、下部磁性材基板2及び上部磁性材基板5を通る経路相当の長さをd2、ギャップ長をh1とし、経路IIにおいて、下部磁性材基板2及び上部磁性材基板5を通る経路Iと経路IIとの差に相当する距離をd1、ギャップ長をh2としている。   Next, the function and effect of the coil 1 configured as described above will be described with reference to FIG. When the loop conductor 3 is energized, the generated magnetic flux passes through the lower magnetic material substrate 2, the magnetic material core layer 4, the upper magnetic material substrate 5, and the air gap 6. At this time, the respective magnetic resistances in the path I passing through the position close to the loop-shaped conductor 3 and the path II passing through the position away from the loop-shaped conductor 3 are simply compared with the case where there is no air gap 6. Ask. Here, the relative magnetic permeability μ1 = 1000 of the lower magnetic material substrate 2 and the upper magnetic material substrate 5, the relative magnetic permeability μ2 = 500 of the magnetic material core layer 4, and the relative magnetic permeability μ3 = 1 of the air gap 6 are set. In the path I, the length corresponding to the path passing through the lower magnetic material substrate 2 and the upper magnetic material substrate 5 is d2, and the gap length is h1, and in the path II, the lower magnetic material substrate 2 and the upper magnetic material substrate 5 are passed. The distance corresponding to the difference between the route I and the route II is d1, and the gap length is h2.

エアギャップ6が無い場合は、
経路Iの磁気抵抗HI=2×d2/μ1+2×h3/μ2
経路IIの磁気抵抗HII=2×(d2+2×d1)/μ1+2×h3/μ2=2×d2/μ1+4×d1/μ1+2×h3/μ2
となり、経路Iの磁気抵抗のほうが、(4×d1/μ1)分、経路IIの磁気抵抗より小さくなる。このように、エアギャップ6が無い場合には、磁気抵抗が、ループ状導体3に近い位置を通る経路の方が遠い位置を通る経路より小さくなるので、磁束はループ状導体3に近い方に集中する。 If there is no air gap 6,
Magnetoresistance HI of path I = 2 × d2 / μ1 + 2 × h3 / μ2
Magnetoresistance HII of path II = 2 × (d2 + 2 × d1) / μ1 + 2 × h3 / μ2 = 2 × d2 / μ1 + 4 × d1 / μ1 + 2 × h3 / μ2
Thus, the magnetic resistance of the path I is smaller than the magnetic resistance of the path II by (4 × d1 / μ1). Thus, when there is no air gap 6, the magnetic resistance is smaller in the path passing through the position close to the loop conductor 3 than in the path passing through the far position, so that the magnetic flux is closer to the loop conductor 3. concentrate.

エアギャップ6が有る場合は、
経路Iの磁気抵抗HI=2×d2/μ1+2×(h3−h1)/μ2+2×h1/μ3=2×d2/μ1+2×h3/μ2+2×h1(1/μ3−1/μ2)
経路IIの磁気抵抗HII=2×(d2+2×d1)/μ1+2×(h3−h2)/μ2+2×h2/μ3=2×d2/μ1+2×h3/μ2+2×h2(1/μ3−1/μ2)+4×d1/μ1
となる。
ここでd1=(h1−h2)×(1/μ3−1/μ2)×μ1/2=499×Δh (ただしΔh=h1−h2)
であれば、経路Iの磁気抵抗HIと経路IIの磁気抵抗HIIが同じになる。例えば、d1=1mm、h2=0μmとすると、h1=1000/499≒2μmのときに、磁気抵抗HIと磁気抵抗HIIが同じになる。従って、エアギャップ6の断面を底辺1mmで高さ2μmの直角三角形状にすると、ループ状導体3から1mmの距離までの位置における磁気抵抗が略同一になるので、その範囲における磁束密度が均一になる。 If there is an air gap 6,
Magnetic resistance HI of path I = 2 × d2 / μ1 + 2 × (h3−h1) / μ2 + 2 × h1 / μ3 = 2 × d2 / μ1 + 2 × h3 / μ2 + 2 × h1 (1 / μ3-1 / μ2)
Magnetoresistance HII of path II = 2 × (d2 + 2 × d1) / μ1 + 2 × (h3-h2) / μ2 + 2 × h2 / μ3 = 2 × d2 / μ1 + 2 × h3 / μ2 + 2 × h2 (1 / μ3-1 / μ2) +4 × d1 / μ1
It becomes.
Where d1 = (h1-h2) × (1 / μ3-1 / μ2) × μ1 / 2 = 499 × Δh (where Δh = h1-h2)
If so, the magnetic resistance HI of the path I and the magnetic resistance HII of the path II are the same. For example, if d1 = 1 mm and h2 = 0 μm, the magnetic resistance HI and the magnetic resistance HII are the same when h1 = 1000 / 499≈2 μm. Therefore, when the cross section of the air gap 6 is a right triangle having a base of 1 mm and a height of 2 μm, the magnetic resistance at the position from the loop conductor 3 to a distance of 1 mm is substantially the same, so the magnetic flux density in that range is uniform. Become.

このように、エアギャップ長を変化させ、磁性材コア層4の厚みに面内分布を持たせることによって、ループ状導体3の近くを通る経路と遠くを通る経路とにおける磁気抵抗を略同一にすることができるので、磁性材コア層4内の磁束密度が均一になって磁気飽和し難くなり、コイル1の小型・軽量化を図り易くなる。   In this way, by changing the air gap length and giving the thickness of the magnetic material core layer 4 an in-plane distribution, the magnetic resistance in the path passing near the loop-like conductor 3 and the path passing far is substantially the same. As a result, the magnetic flux density in the magnetic material core layer 4 becomes uniform and magnetic saturation is difficult, and the coil 1 can be easily reduced in size and weight.

また、エアギャップ6の形成には、μm単位の厚み制御が必要になるが、図2(a)、(b)に示すような断面が直角三角形形状でなく、斜辺部分の断面が階段状の形状であっても底辺と高さの関係が保たれていれば、略同等の効果を得ることができる。   In addition, the formation of the air gap 6 requires a thickness control in units of μm. However, the cross section shown in FIGS. 2A and 2B is not a right triangle, and the cross section of the hypotenuse is a stepped shape. Even if it is a shape, if the relationship between the base and the height is maintained, substantially the same effect can be obtained.

本実施形態において、一対の下部磁性材基板2と上部磁性材基板5とでループ状導体3と磁性材コア層4とを挟持する構成のものを示したが、磁性特性が若干低下してもよい場合は、上部磁性材基板5を省略することもできる。   In the present embodiment, the configuration in which the loop-shaped conductor 3 and the magnetic material core layer 4 are sandwiched between the pair of the lower magnetic material substrate 2 and the upper magnetic material substrate 5 is shown. If it is good, the upper magnetic material substrate 5 can be omitted.

次に、本実施形態の変形例について説明する。上記実施形態では、エアギャップ6が空隙そのものの例を示したが、このエアギャップ6部分に、下部磁性材基板2、上部磁性材基板5、及び磁性材コア層4の材質よりも透磁率の低い材質である、例えば、SiO等を形成することによりエアに置換したギャップとしてもよい。この透磁率の低い材質の比透磁率は、1乃至10の範囲がよい。このギャップの長さを調整することによって、磁性材コア層4における磁気抵抗が略同一になるので、磁束密度が均一になる。このように、エアギャップ6を透磁率の低い部材によって置換したギャップにすることにより、エアギャップ6を形成する手間が省かれ、コイル1の製造を容易にすることができる。   Next, a modification of this embodiment will be described. In the above embodiment, the air gap 6 is an example of the air gap itself. However, the air gap 6 has a permeability higher than that of the material of the lower magnetic material substrate 2, the upper magnetic material substrate 5, and the magnetic material core layer 4. A gap that is replaced with air by forming, for example, SiO, which is a low material, may be used. The relative magnetic permeability of the material having low magnetic permeability is preferably in the range of 1 to 10. By adjusting the length of the gap, the magnetic resistance in the magnetic material core layer 4 becomes substantially the same, so that the magnetic flux density becomes uniform. As described above, by replacing the air gap 6 with a member having a low magnetic permeability, the trouble of forming the air gap 6 can be saved and the coil 1 can be easily manufactured.

(第2の実施形態)
第2の実施形態について図3を参照して説明する。本実施形態は、第1の実施形態に係るコイル1を用いてトランスを構成したものである。トランス7は、一対のコイル1,1を備えている。各コイル1は、上部磁性材基板5を除いた構成であり、トランス7は、各コイル1の下部磁性材基板2を外側に位置させて、ループ状導体3と磁性材コア層4同士が対面するように接合されている。このような構成にすることにより、各コイル1が磁気的に結合してトランス7として動作し、各コイル1が磁気飽和し難く、トランス7も磁気飽和し難くなる。 (Second Embodiment)
A second embodiment will be described with reference to FIG. In the present embodiment, a transformer is configured using the coil 1 according to the first embodiment. The transformer 7 includes a pair of coils 1 and 1. Each coil 1 has a configuration excluding the upper magnetic material substrate 5, and the transformer 7 has the lower magnetic material substrate 2 of each coil 1 positioned outside, and the loop conductor 3 and the magnetic material core layer 4 face each other. Are joined together. With such a configuration, each coil 1 is magnetically coupled to operate as a transformer 7, and each coil 1 is hardly magnetically saturated, and the transformer 7 is also difficult to be magnetically saturated.

なお、本発明は、上記実施形態の構成に限られず、発明の趣旨を変更しない範囲で種々の変形が可能である。例えば、ループ状導体3は、1ターンでなく複数ターンとしてもよい。   In addition, this invention is not restricted to the structure of the said embodiment, A various deformation | transformation is possible in the range which does not change the meaning of invention. For example, the loop conductor 3 may have a plurality of turns instead of one turn.

1 コイル
2 下部磁性材基板(磁性材基板)
3 ループ状導体
4 磁性材コア層(コア部)
5 上部磁性材基板
6 エアギャップ
7 トランス 1 Coil 2 Lower magnetic material substrate (magnetic material substrate)
3 Loop conductor 4 Magnetic material core layer (core part)
5 Upper magnetic material substrate 6 Air gap 7 Transformer

Claims (4)

磁性材基板と、前記磁性材基板上に形成されたループ状導体と、前記ループ状導体の周辺に設けられ前記ループ状導体に通電されたときに発生する磁束が通る磁性体から成るコア部と、を備えたコイルにおいて、
前記コア部は、前記ループ状導体との間にエアギャップを有し、
前記エアギャップは、前記磁性材基板に垂直な方向のギャップ長が前記ループ状導体に近づく程大きくなり、前記ループ状導体から離れる程小さくなるように変化していることを特徴とするコイル。 A magnetic material substrate; a loop-shaped conductor formed on the magnetic material substrate; and a core portion made of a magnetic material provided around the loop-shaped conductor and through which a magnetic flux generated when the loop-shaped conductor is energized passes. In a coil comprising
The core portion has an air gap between the loop-shaped conductor,
The coil is characterized in that the air gap changes such that a gap length in a direction perpendicular to the magnetic material substrate increases as it approaches the loop conductor and decreases as it moves away from the loop conductor. 前記エアギャップは、前記コア部と磁性材基板との間に形成されることを特徴とする請求項1に記載のコイル。   The coil according to claim 1, wherein the air gap is formed between the core portion and the magnetic material substrate. 前記エアギャップが、前記磁性材基板及びコア部の材質よりも透磁率の低い材質によって置換されたことを特徴とする請求項1又は請求項2に記載のコイル。   The coil according to claim 1 or 2, wherein the air gap is replaced with a material having a lower magnetic permeability than materials of the magnetic material substrate and the core portion. 請求項1乃至請求項3のいずれか一項に記載のコイルを一対備え、
前記一対のコイルは、各磁性材基板が外側に位置し、各ループ状導体とコア部同士が対面するように接合されたことを特徴とするトランス。 A pair of the coils according to any one of claims 1 to 3,
The transformer is characterized in that the pair of coils are joined such that each magnetic material substrate is located outside and each loop-shaped conductor and the core portion face each other.
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JP2014110394A (en) * 2012-12-04 2014-06-12 Mitsumi Electric Co Ltd Inductor
JP2016082187A (en) * 2014-10-22 2016-05-16 日本圧着端子製造株式会社 Electrical connection device
CN109997205A (en) * 2016-11-29 2019-07-09 松下知识产权经营株式会社 Compound coil module and magnetic piece
KR20190092144A (en) * 2018-01-30 2019-08-07 엘에스산전 주식회사 Zero phase current transformer with multi-layer printed circuit boards configuration

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JPH02194506A (en) * 1989-01-23 1990-08-01 Matsushita Electric Works Ltd Choke coil
JPH02260508A (en) * 1989-03-31 1990-10-23 Mitsumi Electric Co Ltd Transformer circuit board
JP2007157983A (en) * 2005-12-05 2007-06-21 Taiyo Yuden Co Ltd Multilayer inductor

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JPH02194506A (en) * 1989-01-23 1990-08-01 Matsushita Electric Works Ltd Choke coil
JPH02260508A (en) * 1989-03-31 1990-10-23 Mitsumi Electric Co Ltd Transformer circuit board
JP2007157983A (en) * 2005-12-05 2007-06-21 Taiyo Yuden Co Ltd Multilayer inductor

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2014110394A (en) * 2012-12-04 2014-06-12 Mitsumi Electric Co Ltd Inductor
JP2016082187A (en) * 2014-10-22 2016-05-16 日本圧着端子製造株式会社 Electrical connection device
CN109997205A (en) * 2016-11-29 2019-07-09 松下知识产权经营株式会社 Compound coil module and magnetic piece
KR20190092144A (en) * 2018-01-30 2019-08-07 엘에스산전 주식회사 Zero phase current transformer with multi-layer printed circuit boards configuration
WO2019151623A1 (en) * 2018-01-30 2019-08-08 엘에스산전 주식회사 Zero-phase current transformer having dual-layered printed circuit board structure
KR102169820B1 (en) 2018-01-30 2020-10-26 엘에스일렉트릭(주) Zero phase current transformer with multi-layer printed circuit boards configuration

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