JP2009010268A - Planal coil and manufacturing method therefor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a planar coil having in resistance for coil conductors and a high inductance value. <P>SOLUTION: The inductance value of the coil is improved, by applying magnetic plating to surfaces of the conductors formed by an electrolytic plating method. The pattern conductors with magnetic plating applied are bonded, holding an insulating material therebetween, and plating is reapplied from the backside, and the cross-sectional areas of the conductors can be enlarged. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a planar coil made of a conductor embedded in an insulator, and more particularly to a planar coil that can achieve high inductance and a method for manufacturing the same.

In recent years, with the demand for miniaturization and thinning of portable devices, there has been an increasing demand for miniaturization and thinning of coils used in power supply circuits.
The coil used in the power supply circuit of the portable device needs to have a large inductance in order to stabilize the output voltage, and at the same time, it is necessary to reduce the DC resistance in order to cope with a high current.
Conventionally, attempts have been made to achieve high inductance and low resistance by sandwiching a coil embedded in an insulator between multilayer magnetic materials (see Patent Document 1). Alternatively, high inductance can be realized by configuring slits in both the longitudinal direction of the multilayer magnetic layer formed on the inner wall of the through hole and in the in-plane direction of the multilayer magnetic layer disposed on the upper and lower surfaces of the coil. (See Patent Document 2).
JP-A-9-223636 JP 2005-317604 A

However, in the former, eddy currents are generated in the surface direction of the coil and in the circumferential direction of the through hole. Therefore, there is a problem that the magnetic flux penetrating the through hole vertically is erased and the inductance cannot be increased sufficiently.
In the latter case, slits are provided to prevent eddy currents from being generated. However, in order to form slits by electrolytic magnetic plating, it is necessary to go through a photolithography process, for example. There was a problem that became high. Further, since the coil conductor and the magnetic material are interposed via an insulator, the distance is increased, and the magnetic flux collecting effect is not sufficient.
An object of the present invention is to solve the above problems and to provide a planar coil having an increased inductance without increasing the DC resistance value of the coil.

In order to solve the above problems, a planar coil according to claim 1 is a planar coil made of a conductor embedded in an insulator, wherein the conductor is formed on the surface of the electrolytic copper plating layer and the electrolytic copper plating layer. And an electrolytic magnetic plating layer.
The planar coil according to claim 2 is the planar coil according to claim 1, wherein the electrolytic magnetic plating layer is formed on both surfaces of the electrolytic copper plating layer.
According to a third aspect of the present invention, in the planar coil according to the first or second aspect, a terminal for mounting an electronic component is formed on the surface of the planar coil via an insulator, and the terminal and the conductor are electrically connected. It is characterized by being connected to.

  In order to manufacture such a planar coil, a planar coil manufacturing method according to claim 4 includes a resist forming step of forming a resist on a metal underlayer, and a conductor forming portion is developed from the resist by a photolithography method. A lithography process for forming a pattern, an electrolytic copper plating process for forming an electrolytic copper plating layer on the conductor pattern by electrolytic copper plating, and an electromagnetism for forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating A plating step, a laminating step for bonding a plurality of conductors made of the electrolytic copper plating layer and the electrolytic magnetic plating layer via an insulator, and an etching step for removing the metal base layer. To do.

  The planar coil manufacturing method according to claim 5 includes a resist forming step of forming a resist on a metal underlayer, and a lithography step of developing a conductor forming portion from the resist by a photolithography method to form a pattern, An electrolytic copper plating step of forming an electrolytic copper plating layer on the conductive pattern by electrolytic copper plating; an electrolytic magnetic plating step of forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating; and the electrolytic copper plating layer. And a step of laminating the conductor made of the electrolytic magnetic plating layer through an insulator, a through hole forming step of forming a through hole between the plurality of conductors, and conducting metal catalyst treatment on the inner wall of the through hole to conduct electricity A conductive step, an etching step for removing the metal underlayer, and the electrolysis after the etching step. A second electrolytic copper plating step of forming copper plating layer at the same time on the opposite side of the through hole of the Ki Tsu layer and having a.

  The planar coil manufacturing method according to claim 6 includes a resist forming step of forming a resist on a metal underlayer, a lithography step of developing a conductor forming portion from the resist by a photolithography method, and the conductor An electrolytic copper plating step for forming an electrolytic copper plating layer on the pattern by electrolytic copper plating, an electrolytic magnetic plating step for forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating, the electrolytic copper plating layer and the A copper foil laminating step in which a copper foil layer is bonded to a conductor surface made of an electrolytic magnetic plating layer via an insulator; a through hole forming step of forming a through hole penetrating the copper foil layer and the conductor; and Conductive process of conducting metal catalyst treatment on the inner wall of the through-hole and making it conductive on the surface of the copper foil layer and the inner wall of the through-hole at the same time A panel plating step for forming a plating layer, a second resist forming step for providing a resist on the surface of the copper plating layer, a lithography step for forming a wiring pattern by photolithography, and the etching based on the wiring pattern It has the wiring formation process which forms a wiring pattern in a copper foil layer, and the peeling process which peels the said resist.

  The method for manufacturing a planar coil according to claim 7 includes a resist forming step of forming a resist on a metal underlayer, a lithography step of developing a conductor forming portion from the resist by a photolithography method, and the conductor An electrolytic copper plating step for forming an electrolytic copper plating layer on the pattern by electrolytic copper plating, an electrolytic magnetic plating step for forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating, the electrolytic copper plating layer and the A lamination process in which a conductor made of an electrolytic magnetic plating layer is bonded via an insulator, a through hole formation process in which a through hole is formed between the plurality of conductors, and a metal catalyst treatment is applied to the inner wall of the through hole to make it conductive. A conductive process, an etching process for removing the metal underlayer, and the electrolytic process after the etching process. A second electrolytic copper plating step in which a copper plating layer is simultaneously formed on the opposite side of the layer and the through hole, and copper is provided on the surface of the copper plating layer formed in the second electrolytic copper plating step with an insulator interposed therebetween. A copper foil laminating step for bonding the foil layer, a through hole forming step for forming a through hole penetrating the copper foil layer and the plurality of conductors, and a conductive process for conducting the metal catalyst treatment on the inner wall of the through hole A panel plating step of simultaneously forming a third copper plating layer on the surface of the copper foil layer and the inner wall of the through hole, a resist forming step of providing a resist on the surface of the third copper plating layer, A lithography process for forming a wiring pattern by a lithography method; a wiring forming process for forming a wiring pattern on the copper foil layer based on the wiring pattern by etching; And having a peeling step of peeling the strike, the.

According to the present invention, since the inductance can be increased without increasing the number of turns of the coil, only the inductance can be improved without increasing the DC resistance value of the coil. Therefore, it is possible to provide a planar coil that can cope with downsizing, thinning, and large current of portable devices. Further, by forming electronic component mounting terminals on the surface of the planar coil via an insulator, mounting on the planar coil is possible, and it is possible to cope with space saving of the substrate.
Moreover, in a planar coil made of a conductor embedded in an insulator, the conductor is formed by subjecting an electrolytic copper plating pattern to electrolytic magnetic plating directly, so that a photolithography process for electrolytic magnetic plating is not required. By forming the electrolytic magnetic plating layer directly on the surface of the electrolytic copper plating layer, the distance between the coil conductor and the magnetic body can be eliminated, and the magnetic flux collecting effect can be maximized.
Further, since the magnetic plating is directly applied to the coil conductor, the generation of eddy currents in the coil surface is suppressed, and therefore there is an effect that the inductance is not reduced.

Embodiments of the present invention will be described below with reference to the drawings.
<Embodiment 1>
1 and 2 are diagrams showing an embodiment of a planar coil and a method for manufacturing the same according to the present invention.
In the figure, reference numeral 1 is a substrate, 2 is a resist pattern of a planar coil, 3 is an electrolytic copper plating layer, 4 is an electrolytic magnetic plating layer, 5 is an insulator, 6 is a through hole, 7 is a metal catalyst, and 8 is a copper plating layer. , 9 is a resist pattern, and 13 is an insulator.
In FIG. 1A, a photosensitive photoresist is coated on the surface of a substrate 1 having, for example, copper or aluminum as a metal underlayer. The substrate 1 can be simultaneously formed with a double-sided pattern by welding the peripheral portion with ultrasonic waves or bonding them together with an adhesive.

As the photosensitive photoresist, for example, a negative liquid resist or a positive liquid resist can be used. The substrate 1 is immersed in the liquid resist, or the liquid resist is spin coated on the surface of the substrate 1 and applied. . Alternatively, a dry film resist in which a photosensitive photoresist is applied to the film surface is laminated on the substrate and applied to the surface.
Subsequently, the resist is exposed by irradiating ultraviolet rays through a photomask. At this time, as a photomask, a glass or PET film as a base material with Cr or Ag salt as a pattern and an emulsion coated on the surface is generally used. Further, it is possible to draw a fine pattern by directly irradiating the resist with ultraviolet rays using a laser drawing apparatus.
The exposed substrate is developed to form a resist pattern 2 in which a conductor forming portion of the planar coil is opened in a pattern. The developing solution is a weakly alkaline aqueous solution such as a 1-5% sodium carbonate solution or a 3-15% triethanolamine aqueous solution, but an organic solvent can also be used. The development is carried out by immersing and swinging the substrate or passing through a shower device.

Subsequently, as shown in FIG. 1B, an electrolytic copper plating layer 3 (primary plating) is deposited on the opening of the resist pattern 2 by an electrolytic copper plating method to form a planar coil wiring. The electrolytic copper plating solution is processed using a chemical solution containing general copper sulfate or a chemical solution containing copper pyrophosphate. For example, as a composition of a copper sulfate plating chemical solution, CuSO ₄ .5H ₂ O 30 to 200 g / L, H ₂ SO ₄ 100 to 200 g / L, Cl ⁻ 30 to 80 mg / L, and a trace amount of organic sulfur compound of about 0 to 10 ppm ( For example, bis (3-propanesulfonesan) disulfide), an organic nitrogen compound (for example, a quaternary polyamine having a molecular weight of about 1,000), and a surfactant (for example, a mixture containing polypropylene glycol or polyethylene glycol). Preferably, CuSO ₄ .5H ₂ O may be used in the range of 100 to 180 g / L, H ₂ SO ₄ in the range of 120 to 200 g / L, and Cl ⁻ in the range of 40 to 70 mg / L.

Next, as shown in FIG. 1 (c), an electrolytic magnetic plating layer 4 of a metal material having magnetism containing at least one of Fe, Ni, or Co is formed on the surface of the electrolytic copper plating layer 3.
For example, a magnetic material plating solution made of ferrous sulfate, nickel chloride, nickel sulfate, boric acid, sodium chloride, sodium saccharin is used as the magnetic plating solution, and ferrous sulfate heptahydrate 1-10 g / L Nickel chloride hexahydrate 30-100 g / L, nickel sulfate hexahydrate 10-50 g / L, boric acid 10-50 g / L, thorium chloride 10-50 g / L, saccharin sodium 0.5-5 g / L Process within range.
The resist pattern 2 may be peeled off after the formation of the electrolytic magnetic plating layer 4. For the peeling, an organic solvent stripping solution containing an alkaline aqueous solution such as 1 to 10% NaOH aqueous solution or cellosolve is used.

Next, as shown in FIG.1 (d), a board | substrate is isolate | separated and it adhere | attaches so that the insulator 5 may be inserted | pinched between several coil pattern board | substrates. As the insulator 5, a glass cloth coated with an adhesive resin having a functional group such as epoxy, acrylate, phenol or the like, a coating of these adhesives on the surface of an aramid film, or an adhesive film on the surface of an imide film, What coated imide varnish etc. is used. Further, these insulators are bonded under high temperature and high pressure, for example, in an environment of 150 ° C. or higher and 5 kgf / cm ² or higher.
Next, as shown in FIG. 1E, the metal underlayer is removed by etching, and the metal underlayer is bonded (laminated) to the upper and lower layers via an insulator.

Next, as shown in FIG. 1 (f), through holes 6 are formed in the connection portions of the upper and lower layers of the pattern. A mechanical device such as a drill, a punch, or a laser can be used for the through hole, but it is preferable to select a method according to the laminated material.
Next, as shown in FIG. 1 (g), the substrate is immersed in a chemical solution containing a metal catalyst such as a palladium salt, and the metal catalyst 7 is adsorbed on the inner wall of the through hole.
Next, as shown in FIG. 1 (h), electrolytic copper plating 8 (panel plating) is applied to form an electrolytic copper plating layer. An electrolytic plating method combined with electroless plating that does not require electricity as copper plating can also be used. Although the thickness can be arbitrarily adjusted as copper plating, it is preferable to form a thickness of 5 μm or more in consideration of the reliability of the through hole.

Next, as shown in FIG. 1 (i), using the lithography method using a photoresist on the formed copper plating layer, for example, the copper plating is performed while leaving the resist pattern 9 at a necessary place such as a through hole portion. The layer is etched away to obtain an electrical connection between the plurality of conductor layers (FIG. 1 (j)). For etching the copper plating layer, an aqueous solution containing iron chloride, copper chloride, sulfuric acid / hydrogen peroxide solution, persulfates, or the like can be used, and a chemical solution is appropriately selected according to the etching rate.
Next, as shown in FIG. 1 (k), an insulator 13 is printed and covered at an arbitrary position for electrical insulation. As the insulator 13, a thermosetting resin that is cured by heat, a photocurable resin, a photo solder resist that is cured in a pattern by light, or the like can be used. To the terminal portion of the planar coil wiring, there is a connection reliability with a solder material containing Sn and at least one metal among Sn, Ag, Cu, Ni, Zn, Sb, and In, or an electronic component such as Au / Ni. It can process with a high material and can obtain a magnetic plating coil.
In the planar coil obtained by the above manufacturing method, a planar coil made of a conductor is embedded in an insulator, and the conductor includes an electrolytic copper plating layer and an electrolytic magnetic plating layer formed on the surface of the electrolytic plating layer. Therefore, high resistance can be realized with low resistance.

<Embodiment 2>
FIG. 2 is a view showing another embodiment of the planar coil and the manufacturing method thereof according to the present invention, and an electroplating layer can be formed on the opposite side of the resist pattern to increase the cross-sectional area of the conductor. According to this manufacturing method, a planar coil having two constricted portions in the conductor cross-sectional shape is obtained.
The second embodiment is the same as the first embodiment from (a) to (e) in FIG. 1, and is omitted, and the subsequent steps are shown in FIG.
First, in the same manner as in the first embodiment, a plurality of planar coils are bonded so as to sandwich an insulator (FIGS. 1A to 1E), and a plurality of layers are connected as shown in FIG. A through hole 6 is formed in the same manner as described above. Further, the metal catalyst 7 is applied to the metal underlayer exposed on the surface and the inner wall of the through hole.

Next, as shown in FIG. 2B, the back surface of the wiring pattern is exposed by removing the metal base layer. At this time, the metal underlayer is removed by peeling or etching depending on the material. For example, the etching uses 3 to 15% hydrochloric acid or 5 to 20% persulfate aqueous solution.
Next, as shown in FIG. 2C, a second electrolytic copper plating (secondary plating) is applied to the wiring pattern exposed on the surface, and the electrolytic copper plating layer 10 is formed on the opening of the resist pattern 2 and the inner wall of the through hole. Form. As a result, the cross-sectional area of the copper wiring can be increased and the through-hole portion can be electrically connected. As the plating solution, a chemical solution containing copper sulfate or copper pyrophosphate is used as described above. By performing electrolytic copper plating on both sides of the resist pattern 2, a planar coil having two constricted portions in the conductor cross-sectional shape is obtained.
Next, as shown in FIG. 2 (d), in order to obtain electrical insulation, the planar coil wiring surface layer portion is printed with an insulator 13 at an arbitrary place to produce a planar coil having a large conductor cross-sectional area. Can do.

Here, at the stage of FIG. 2C, the magnetic plating 11 can be applied to the secondary plating surface or the through-hole conductor surface, and the copper wiring can be covered with a magnetic material. The magnetic plating solution used is the same as described above. By doing so, it is possible to manufacture a planar coil in which electrolytic magnetic plating layers are formed at a plurality of locations of the conductor as shown in FIGS. 2 (f), 2 (g), and 2 (h). .
Further, at the stage of FIG. 2 (c), the terminal portion of the planar coil wiring is provided with a solder material or Au containing Sn, Sn, Ag, Cu, Ni, Zn, Sb, In and at least one other metal. When processed with a material having high connection reliability such as / Ni, a magnetic plating coil as shown in FIG. 2D can be obtained.

If magnetic plating is not performed at the stage of FIG. 1 (c) but magnetic plating is performed at the stage of FIG. 2 (c), the magnetic plating is applied only to the secondary plating side of the planar coil as shown in FIG. 2 (e). Can be applied.
Accordingly, the planar coils shown in FIGS. (D) to (h) having different characteristics can be formed by arbitrarily setting the locations to be subjected to magnetic plating.
Tables 1 (d), (g), (h) and the magnetic plating untreated product show the magnetic plating thickness and the measurement results of the magnetic characteristics (inductance value) depending on the magnetic plating treatment site. In Table 1, “TH” indicates that the inner wall of the through hole and the terminal portion are plated with magnetic material.

<Embodiment 3>
FIG. 3 is a diagram showing another embodiment of the planar coil and the manufacturing method thereof according to the present invention. In Embodiment 3, a planar coil with a built-in planar coil is formed in which a planar coil having an electrolytic magnetic plating layer is formed on the surface of an electrolytic copper plating layer, and terminals for mounting electronic components are arranged on the surface.
In the same manner as in the first embodiment, a metal base layer is bonded to the surface layer of the coil layer via an insulator (FIGS. 1A to 1E).
Next, as shown in FIG. 3A, in addition to the through-hole 6 for connecting a plurality of coil layers, a through-hole 14 (for mounting portion connection) for connecting to the coil layer is formed, and metal catalyst treatment is performed. And copper plating treatment.

Next, as shown in FIG.3 (b), a copper plating layer is formed in the surface layer of a through hole and an insulator.
Next, as shown in FIG. 3C, by using a lithography method using a photoresist, a resist pattern 15 of a connection wiring to the through hole portion and the coil is formed, and the conductor is etched away, A wiring pattern to the coil was formed at the same time as terminals for mounting electronic components. Copper etching uses the above-described general chemical solution. The coil terminal was treated with a solder material containing Sn and at least one metal among Sn, Ag, Cu, Ni, Zn, Sb, and In, or a material having high connection reliability such as Au / Ni. . The mounting terminals were processed with the above-mentioned solder material, Au / Ni, Ag, Al, or the like, or a rust preventive liquid to form terminals suitable for mounting, and a printed wiring board with a flat coil with mounting terminals was obtained. (FIG. 3 (d)).

<Embodiment 4>
FIG. 4 is a view showing another embodiment of the planar coil according to the present invention, in which an electrolytic magnetic plating layer is disposed on the surface of the electrolytic copper plating layer, and the conductor cross-sectional shape has two constricted portions. This is a printed wiring board with a built-in planar coil in which electronic component mounting terminals are arranged on the surface layer.
In the same manner as in the second embodiment, an electrolytic copper plating layer is formed on both sides of the resist pattern 2, and the metal base layer is bonded so that the insulator is sandwiched between the surface layers of the planar coil having two constrictions in the conductor cross-sectional shape. .
Then, as in the third embodiment, a through hole for connecting to the coil layer is formed, a metal catalyst layer is applied to the metal underlayer exposed on the surface and the inner wall of the through hole, and then electrolytic copper plating is applied. A copper plating layer is formed on the through hole and the surface layer (panel plating).

By using a lithography method using a photoresist, a resist pattern for connection wiring to the coil is formed, and the conductor is etched away, thereby simultaneously forming a wiring pattern for terminals for mounting electronic components on the coil. Copper etching can be processed using the aforementioned general chemicals. The coil terminal is treated with a solder material containing Sn and at least one metal among Sn, Ag, Cu, Ni, Zn, Sb, and In or a material with high connection reliability such as Au / Ni.
Terminals for mounting are Sn, Ag, Cu, Ni, Zn, Sb, In soldering material containing Sn and at least one other metal, Au / Ni, Ag, Al, etc. plating or rust prevention liquid By processing with the above, a terminal with high connection reliability can be formed, and a printed wiring board with a built-in planar coil can be obtained. By setting the location to which the magnetic plating is applied arbitrarily, it is possible to obtain a printed wiring board with a planar coil as shown in FIGS. 5 (a) to 5 (e) having different characteristics.

It is a figure which shows embodiment of the manufacturing method of the planar coil which concerns on this invention. It is a figure which shows embodiment of the planar coil which concerns on this invention, and its manufacturing method, and is a continuation of FIG. It is a figure which shows Embodiment 2 of the planar coil which concerns on this invention, and its manufacturing method. It is a figure which shows Embodiment 3 of the planar coil which concerns on this invention, and its manufacturing method. It is a figure which shows other embodiment of the planar coil which concerns on this invention.

Explanation of symbols

1 Substrate 2 Resist Pattern 3 Electrolytic Copper Plating Layer 4 Electromagnetic Magnetic Plating Layer 5 Insulator (Laminated Material)
6 Through hole 7 Metal catalyst 8 Copper plating layer (panel plating)
9 Resist pattern 10 Electrolytic copper plating layer (secondary plating)
11 Electrolytic magnetic plating layer 12 Magnetic plating (TH)
13 Insulator 14 Through-hole 15 Resist pattern 16 Wiring pattern 17 Magnetic plating layer

Claims (7)

  A planar coil comprising a conductor embedded in an insulator, wherein the conductor includes an electrolytic copper plating layer and an electrolytic magnetic plating layer formed on a surface of the electrolytic copper plating layer.   The planar coil according to claim 1, wherein the electrolytic magnetic plating layer is formed on both surfaces of the electrolytic copper plating layer.   3. A flat surface in which a terminal for mounting an electronic component is formed on the surface of the planar coil according to claim 1 or 2 via an insulator, and the terminal and the conductor are electrically connected. coil.   A resist forming step for forming a resist on the metal underlayer, a lithography step for developing a conductor forming portion from the resist by a photolithography method to form a pattern, and forming an electrolytic copper plating layer on the conductor pattern by electrolytic copper plating An electrolytic copper plating step, an electrolytic magnetic plating step of forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating, and a plurality of conductors comprising the electrolytic copper plating layer and the electrolytic magnetic plating layer as insulators A method for producing a planar coil, comprising: a laminating step for bonding via a metal layer; and an etching step for removing the metal base layer.   A resist forming process for forming a resist on a metal underlayer, a lithography process for developing a conductor formation portion from the resist by photolithography, and forming a pattern, and forming an electrolytic copper plating layer on the conductor pattern by electrolytic copper plating An electrolytic copper plating step, an electrolytic magnetic plating step of forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating, a through hole forming step of forming a through hole between the plurality of conductors, and the through Conductive process of conducting metal catalyst treatment on the inner wall of the hole, etching process of removing the metal underlayer, and a copper plating layer on the opposite side of the electrolytic plating layer and the through hole at the same time after the etching process And a second electrolytic copper plating step to be formed.   A resist forming step for forming a resist on the metal underlayer, a lithography step for developing a conductor formation portion from the resist by photolithography, and forming a pattern, and forming an electrolytic copper plating layer on the conductor pattern by electrolytic copper plating An electrolytic copper plating step, an electrolytic magnetic plating step of forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating, and an insulator on the conductor surface comprising the electrolytic copper plating layer and the electrolytic magnetic plating layer. A copper foil laminating step for adhering the copper foil layer, a through hole forming step for forming a through hole penetrating the copper foil layer and the conductor, and conducting the metal catalyst treatment on the inner wall of the through hole to make it conductive. A panel plating step of simultaneously forming a copper plating layer on the surface of the copper foil layer and the inner wall of the through hole, and the copper plating A second resist forming step of providing a resist on the surface of the layer, a lithography step of forming a wiring pattern by a photolithography method, and a wiring forming step of forming a wiring pattern on the copper foil layer based on the wiring pattern by etching. And a stripping step for stripping the resist.   A resist forming process for forming a resist on a metal underlayer, a lithography process for developing a conductor formation portion from the resist by photolithography, and forming a pattern, and forming an electrolytic copper plating layer on the conductor pattern by electrolytic copper plating An electrolytic copper plating step, an electrolytic magnetic plating step of forming a magnetic plating layer on the surface of the electrolytic copper plating layer by electrolytic plating, and a plurality of conductors comprising the electrolytic copper plating layer and the electrolytic magnetic plating layer as insulators A second step of simultaneously forming a second copper plating layer on the opposite side of the electrolytic plating layer and in the through hole after the etching step; A copper foil layer through an insulator on the surface of the copper plating layer formed in the electrolytic copper plating step and the second electrolytic copper plating step A copper foil laminating step for bonding, a conductive step for conducting metal catalyst treatment on the inner wall of the through hole, and a panel for simultaneously forming a third copper plating layer on the surface of the copper foil layer and the inner wall of the through hole A plating process; a resist forming process for providing a resist on the surface of the third copper plating layer; a lithography process for forming a wiring pattern by photolithography; and a wiring pattern on the copper foil layer based on the wiring pattern by etching. A method for manufacturing a planar coil, comprising: a wiring forming step for forming a resist; and a peeling step for peeling the resist.

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