JPH05190367A - Production of laminated magnetic material parts - Google Patents

Abstract

PURPOSE:To produce magnetic material parts having non-magnetic material section made of different materials by applying a sheet method. CONSTITUTION:In a forming process of green sheet 10, non-magnetic paste is filled in a through hole 11 formed on the sheet surface to form a non- magnetic material section 12 constituting a non-magnetic material layer and after a conductive pattern 13 is formed to comprise a coil section, a plurality of sheets 10 are backed as being piled. Thus, the non-magnetic material layer to control the magnetic routes of coil section is formed as one body inside a parts body while they are interposed among the turns of the coil section.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention mounts not only individual components such as a multilayer chip type inductor and transformer but also other electronic components such as an L portion forming a composite component such as an LC filter or a DC-DC converter. The present invention relates to a method for manufacturing a laminated magnetic body component including a substrate used for manufacturing.

[0002]

2. Description of the Related Art Generally, in the above-described various magnetic parts, the whole of the part base body containing the coil portion is formed of a ferrite material having a high magnetic permeability. However, in this magnetic component, since the base body itself is a structure made of a magnetic material, it is difficult to control the magnetic path linking the coil portion,
Therefore, it is impossible to suppress the generation of leakage magnetic flux. Permeability is significantly involved in the electrical characteristics such as L, Q, temperature characteristics and IDC of this magnetic component. To further improve the electrical characteristics, the magnetic path of the coil is controlled by a non-magnetic member. The magnetic flux leakage can be suppressed by doing so (Japanese Patent Publication No. 63-
No. 61766, Japanese Patent Publication No. 1-2610, Japanese Patent Publication No. 2-4
No. 5358, Japanese Examined Patent Publication No. 3-58164).

Conventionally, in order to manufacture this magnetic part, a screen printing method is applied, and each part of a magnetic material layer serving as a component base, a nonmagnetic material layer serving as an insulator, and a conductive pattern serving as a coil portion is formed into a predetermined pattern. In this way, the laminated printing is sequentially performed. However, according to the screen printing method, a large number of plate makings and types corresponding to each layer are required, and the process becomes complicated because of the large number of printings, plate replacements, and the like.
When printing, there are many institutional restrictions such as difficulty in obtaining the edge precision of the boundary between the magnetic material layer and the non-magnetic material layer, and it is necessary to secure sufficient clearances or overlapping parts, thus reducing the size of parts. There is a limit to the conversion.

Compared with this printing method, the sheet method can shorten the lead time and improve the productivity. With the progress of image processing technology and mechanical control technology, the sheet can be thinned to make the parts smaller. Since it is possible to improve the stacking accuracy, it is extremely effective in manufacturing magnetic parts. However, filling and forming a foreign material such as a non-magnetic material into the green sheet is a major obstacle to improving the productivity of the component manufacturing by the sheet method.

[0005]

SUMMARY OF THE INVENTION The present invention provides a method for producing a laminated magnetic component by which a laminated magnetic component having excellent characteristics can be easily and efficiently produced by applying a sheet method. With the goal.

[0006]

In a method of manufacturing a laminated magnetic component according to the present invention, a green sheet forming a component base is formed from a magnetic material paste, and a predetermined pattern is formed on the sheet surface of the green sheet. To form a green sheet having a non-magnetic material portion by filling a non-magnetic material paste into the hole, and forming a coil portion on a predetermined sheet surface of the green sheet. A pattern is formed of a conductive paste, and a plurality of green sheets on which the conductive pattern is formed are laminated and fired to form a coil portion continuously formed from the conductive pattern and a non-magnetic member interposed between turns of the coil portion. According to the sheet method, the laminated magnetic component having the non-magnetic material layer according to the above is provided integrally inside the component base.

[0007]

In the method of manufacturing a laminated magnetic component according to the present invention, the sheet method is applied, and a hole is formed in the sheet surface of the green sheet in the step of forming the green sheet of the magnetic material.
A non-magnetic material portion is formed by filling the inside of the punched hole with a non-magnetic material paste, a conductive pattern is formed at a position corresponding to the non-magnetic material portion, and then a plurality of green sheets are laminated and fired. The non-magnetic material layer is formed on the green sheet by interposing the non-magnetic material layer between the turns of the coil portion, so that the entire component including the component base, the coil portion, and the non-magnetic material layer can be efficiently manufactured and produced. In addition to improving the property, sufficient precision can be ensured when forming a punched hole and laminating non-magnetic material portions, and the non-magnetic material layer can be accurately positioned inside the component substrate and easily formed. In addition, since the leakage magnetic flux can be suppressed by controlling the porcelain that interlinks the coil section with the non-magnetic material layer having a low magnetic permeability, it can be manufactured as a laminated magnetic body component with excellent electrical characteristics, and in pattern design. Since the tolerance of can be reduced accurately, the parts can be sufficiently downsized.

[0008]

EXAMPLE A sheet method is applied to this method of manufacturing a laminated magnetic component, and after forming a green sheet from each step described below, a plurality of sheets are laminated and fired to form an inductor, a transformer, an L part of an LC filter, It is applied to manufacture magnetic parts including a component mounting board.

During the manufacturing process, in addition to the green sheet forming the component base and the conductive pattern forming the coil portion, the non-magnetic material paste is filled in the holes formed in the sheet surface of the green sheet to form the non-magnetic material. The non-magnetic material portion forming the layer is formed on the green sheet. This hole is formed by applying a photolithography method or a photoetching method described later.

Ferrite or the like having a high magnetic permeability is used as the magnetic material forming the component base, and non-magnetic ferrite or oxidizable with the magnetic material is used as the non-magnetic material forming the non-magnetic material layer. Titanium, alumina, etc. can be used.

FIG. 1 shows a case where a photolithography method is applied, and shows each step of forming a green sheet for one layer including the step of forming a conductive pattern forming a coil portion. In the figure, 10 is a green sheet of a magnetic material that constitutes a component base, 11 is a hole formed in the green sheet, 12 is a non-magnetic material portion that constitutes a non-magnetic material layer, and 12a is a non-magnetic material portion 12. A non-magnetic material sheet, a conductive pattern 13 forming a coil portion, and a green sheet 1
A carrier sheet such as a polyethylene terephthalate film serving as a base for forming 0, 21 is photomasking for forming the holes 11 in the green sheet, and 22 is photomasking for forming the non-magnetic material portion 12.

When the photolithography method is applied, the green sheet 10 is made of a magnetic paste containing a ceramic powder of a magnetic material and a photosensitive resin.
Is formed on the sheet surface of the
An acrylic or butyral binder is mixed in to impart toughness.

After the green sheet 10 is formed on the sheet surface of the carrier sheet 20 by a normal sheet method, a photomasking 21 having a predetermined light transmitting pattern is formed on the green sheet 1.
A light ray irradiation process is performed by covering the sheet surface of No. 0. The light-transmitting pattern of the photomasking 21 substantially corresponds to the shape of a conductive pattern formed in a later step, and
The rays to be irradiated here are ultraviolet rays, deep ultraviolet rays, g rays,
i-line, EB, excimer laser, etc. can be used.
By the irradiation of the light, the exposed surface 1 of the sheet surface of the green sheet 1 is exposed.
0a is formed, and the exposed portion 10a is developed with a solvent such as 1-1-1 trichloroethane or alkali, and is removed and dried to form a hole 11. Since the photolithography method is applied to the hole 11 by irradiating the light beam with the photomasking 21, the hole 11 can be formed at high speed and with high precision as compared with laser processing and punching processing. There are a positive type and a negative type in the photomasking 21, and since the exposed portion is left or the unexposed portion is left, any of them can be applied to the light treatment including the following steps.

The green sheet 10 is provided in the hole 11.
The non-magnetic material portion 12 is formed by filling the non-magnetic material paste that can be co-fired with. In forming the non-magnetic material portion 12, the same photolithography method as that for forming the punched hole 11 can be applied. In that case, a non-magnetic paste containing a photosensitive resin and an acrylic or butyral binder mixed therein is used. The non-magnetic material sheet 12a is formed by applying the non-magnetic material paste to the surface of the green sheet 10 in which the holes 11 are formed. The sheet surface is covered with photomasking 22, and the non-magnetic material portion 12 filled in the punched hole 11 is formed by irradiating light rays in the same manner as described above. As this photomasking 22, a photomask having a light transmissive pattern opposite to that of the photomasking 22 for forming a hole is used.
The exposed portion 10a of the green sheet 10 by the light irradiation by 2
The exposed portion 12b opposite to that is formed. This exposure unit 12b is 1
The developer is removed with a solvent such as 1-1 solvent such as trichloroethane or alkali and dried to form the non-magnetic material portion 12 in the sheet portion remaining inside the punched hole 11.

After the formation of the non-magnetic material portion 12, a conductive pattern 13 corresponding to approximately one turn, preferably 3/4 turn, which constitutes the coil portion is formed at a predetermined portion of the green sheet 10 including the non-magnetic material portion 12. Form. The conductive pattern 13 can also be formed by screen printing by using a conductive paste containing a conductive material. An ethyl cellulose-based binder is added to the conductive paste in order to impart printability.

Instead of screen printing, the conductive pattern 13 can be formed by photolithography as in the process of forming the holes 11 and the nonmagnetic material portion 12. FIG. 2 shows a step of forming the conductive pattern 13 by a photolithography method. Here, by using a conductive material paste containing a photosensitive resin, a green sheet on which the non-magnetic material portion 12 is formed is attached to the surface of the green sheet. Conductive material sheet 13a
To form. The conductive material sheet 13a is covered with photomasking 23 to form an exposed portion 13b by light irradiation. As the photomasking 23, it is possible to form an exposed portion 13b having substantially the same light-transmitting pattern as that of the photomasking 22 for forming the non-magnetic material portion and having substantially the same pattern as the exposed portion 12b of the nonmagnetic material sheet 12a. Also,
The exposed portion 13b is similarly developed and removed, and the conductive pattern 13 overlapping the non-magnetic material portion 12 in the remaining sheet portion.
Can be formed as.

According to this process, all the processes including the conductive pattern can be processed by the sheet method, so that the lead time can be shortened and the productivity can be improved by a common processing system. In particular, when the conductive pattern 13 is formed by a sheet method, it is possible to apply a thickness of several tens of μm or more, and a pattern accuracy of 20 to 30 μm and a sheet thickness of about 30 μm can be achieved to form a fine pattern. Further, as a binder added to the conductive material paste, like the binder of each paste forming the green sheet 10 and the non-magnetic material portion 12,
Since the binder removal temperature can be made common by using the same type of acrylic type and butyral type, peeling and internal destruction of the green sheet 10, the non-magnetic material portion 12 and the conductive patterns 13 or between sheets during firing can be prevented. Can be prevented.

After the conductive pattern 13 is formed in this manner, the green sheet 10 is peeled from the carrier sheet 20 to obtain a layer for forming a ceramic laminate component. A plurality of the green sheets 10 are laminated, compression molded, and then fired at a predetermined temperature to form a magnetic multilayer substrate or chip component.

FIG. 3 shows a manufacturing process of a green sheet having a non-magnetic material portion by a photoresist method. In this case, after the green sheet 10 is formed on the sheet surface of the carrying sheet 20, the resist agent layer 14 is formed on the sheet surface of the green sheet 10 using a resist agent. Then, a photomasking 21 having a predetermined light-transmitting pattern similar to that described above is covered on the sheet surface of the green sheet 10 to perform a light irradiation process. As the light rays, like the photolithography method, ultraviolet rays, deep ultraviolet rays, g rays, i rays, E
B, an excimer laser, etc. can be used.

Depending on the light irradiation, the resist agent layer 14
The exposed portion 14a is formed on a predetermined sheet surface of the green sheet 10 covered with, and the exposed portion 14a is removed by a developing treatment with a solvent such as 1-1-1 trichloroethane or an alkali to remove the residual resist agent layer. A hole 11 is formed in the sheet surface of the green sheet 1 covered with 14. For the etching, a wet etching method can be applied when applied to a green sheet containing a photosensitive resin binder, or a dry etching method can be applied when applied to an ordinary green sheet.

The holes 11 formed in the sheet surface of the green sheet 10 have the same shape as the green sheet 1 as described above.
The non-magnetic material portion 12 is formed by filling a non-magnetic material paste that can be co-fired with 0. A sheet method is also applied to form the non-magnetic material portion 12, and the non-magnetic material paste is applied to the sheet surface of the green sheet 10 in which the punched hole is formed so that the non-magnetic material portion 12 is formed in the punched hole 11. Can be formed by filling.

After forming the non-magnetic material portion 12, the resist agent layer 14 remaining on the sheet surface of the green sheet 10 is peeled off. Along with the removal of the resist agent layer 14, the non-magnetic material paste applied unnecessarily can be removed. After obtaining the green sheet 10 having the non-magnetic material portion 12, the conductive pattern 1 to be an electrode portion at a predetermined portion of the green sheet 10 including the non-magnetic material portion 12 as described above.
3 is formed.

After forming the conductive pattern 14 in this manner, the green sheet 10 is peeled from the carrier sheet 20 to obtain a layer for forming a ceramic laminate component. A plurality of the green sheets 1 may be laminated, compression molded, and then fired at a predetermined temperature to form a ceramic multilayer substrate or a chip component.

In connecting the conductive pattern 14, a through hole having a relatively small diameter similar to the through hole 11 is provided by laser irradiation, punching or the like in the above-described process, and the conductive material filled in the through hole is used for turning. The coil portion can be formed by connecting the components to each other. Further, even when configuring the LC filter, the electrodes may be connected to each other by filling and forming the through hole with a conductive material.
The filling of the conductive paste can be performed in the step of forming the non-magnetic member 12 made of the non-magnetic material paste, separately from the filling of the non-magnetic paste in order.

FIGS. 4 to 10 show specific examples of laminated magnetic material parts which can be manufactured by the above-mentioned steps. In the drawings, 1 is a part substrate made of a magnetic material, and 2 (2a, 2b) are A coil portion 3 formed inside the component base 1 and a coil portion 2
A non-magnetic material layer formed of a non-magnetic material is interposed between turns (2a, 2b).

4 and 5 show an inductor, FIG. 6 shows a mixer transformer, FIG. 7 shows a rotary transformer, and FIG. 8 shows a step-up transformer. Each of these electronic components is configured as a single magnetic component,
The component base 1 is made of a magnetic material, and the non-magnetic material layers 3 are provided so as to be interposed between the turns of the coil portions 2 (2a, 2b) formed inside the component base 1. The shield type inductor shown in FIG. 5 has an external magnetic body portion 1a and an internal magnetic body portion 1b forming the component base 1.
The internal magnetic body portion 1b can be formed by forming a hole in the non-magnetic material portion 12 in the above-described process.

FIG. 9 shows an LC filter, which is integrally formed by forming the L part as a magnetic part and compounding it with the dielectric part of the C part. Further, FIG. 10 shows DC-DC
1 shows a substrate of a converter, and this substrate is formed as a magnetic body portion which constitutes a DC-DC converter by mounting other components. The L part of the LC filter and the substrate of the DC-DC converter have magnetic component bases 1, and the non-magnetic material layer 3 is interposed between the turns of the coil portions 2 formed inside each of the component bases 1. Is provided.

In this magnetic component, the non-magnetic material layer 3 having a low magnetic permeability is interposed between the turns of the coil portion 2 (2a, 2b), so that the coil portion 2 (2a, 2b) is interlinked. The magnetic flux leakage from the magnetic path can be controlled to be suppressed. Since the magnetic permeability is high enough to suppress the leakage magnetic flux, the electrical characteristics of each magnetic body component can be improved. For example, in the inductor and L network, the L value, the Q value, and the IDC can be increased, and the temperature characteristic can be decreased. In the transformer and rotary transformer, the L value, Q value, and coupling coefficient can all be increased, and in the LC filter, the L value. The Q value and IDC can be increased and it can be configured to take measures against electrostatic breakdown.

As in the inductor shown in FIG. 4, the L part of the LC filter shown in FIG. 9, and the substrate of the DC-DC converter shown in FIG. It is preferable to provide a magnetic gap portion 4 made of a non-magnetic material. In this void portion 4, L of each magnetic material part
The values and Q values may change significantly depending on the conditions of use and aging, which is preferable from the viewpoint of stability.

[0030]

As described above, according to the method for manufacturing a laminated magnetic component according to the present invention, the non-magnetic material portion is formed by the sheet method by forming the holes in the green sheet of the magnetic material. Since the magnetic material layer is integrally provided inside the component base, lead time can be shortened, productivity can be improved, and overall high-precision formation can be achieved to improve characteristics and reduce size. It is a thing.

[Brief description of drawings]

FIG. 1 is an explanatory diagram sequentially showing each step of manufacturing a green sheet by a method of manufacturing a laminated magnetic component according to the present invention.

FIG. 2 is an explanatory view showing a conductive pattern forming step applicable in the method for manufacturing a laminated magnetic component according to the present invention.

FIG. 3 is an explanatory diagram sequentially showing each step of manufacturing a green sheet by a method of manufacturing a laminated magnetic component according to another embodiment of the present invention.

FIG. 4 is an explanatory diagram showing an internal structure of an inductor that can be manufactured by applying a manufacturing method as a laminated magnetic component according to the present invention.

FIG. 5 is an explanatory diagram showing an internal structure of a shielded inductor according to a modified example that can be manufactured by the same method.

FIG. 6 is an explanatory diagram showing an internal structure of a mixer transformer that can be manufactured by the same method.

FIG. 7 is an explanatory diagram showing an internal structure of a rotary transformer that can be manufactured by the same method.

FIG. 8 is an explanatory diagram showing the internal structure of a step-up transformer that can be manufactured by the same method.

FIG. 9 is an explanatory diagram showing the internal structure of an LC filter that can be manufactured by the same method.

FIG. 10 is an explanatory diagram showing the internal structure of a DC-DC converter that can be manufactured by the same method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 (1a) Component base 2 (2a, 2b) Coil part 3 Nonmagnetic material layer 10 Magnetic material green sheet 11 Perforation hole 12 Nonmagnetic material part 13 Conductive pattern

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Junichi Sudo 1-13-1, Nihonbashi, Chuo-ku, Tokyo Inside TDC Corporation

Claims (1)

[Claims] 1. A green sheet forming a component substrate is formed of a magnetic material paste, and a punching hole corresponding to a predetermined pattern is formed on the sheet surface of the green sheet, and the non-magnetic material paste is formed inside the punching hole. To form a green sheet having a non-magnetic material portion, a conductive pattern forming a coil portion is formed on a predetermined sheet surface of the green sheet with a conductive paste, and a plurality of sheets on which the conductive pattern is formed are formed. A laminated magnetic component in which a green sheet is laminated and fired, and a coil portion continuously formed from a conductive pattern and a non-magnetic material layer made of a non-magnetic member interposed between turns of the coil portion are provided inside a component base. Is formed integrally by a sheet method.