DUST CORE

Abstract
A dust core includes a metal magnetic material, a resin, and an insulation film. The insulation film contacts with a surface of the metal magnetic material and covers the metal magnetic material. The insulation film includes a first film and a second film. The first film contacts with the surface of the metal magnetic material. The second film contacts with a surface of the first film. A density of the first film is higher than a density of the second film.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention

The present invention relates to a dust core.


2. Description of the Related Art

Motors and coil devices, such as inductors, choke coils, and transformers, have been required to be downsized, and widely used is thereby a metal magnetic material whose saturation magnetic flux density is larger than that of ferrite and whose DC superposition characteristics are maintained until high magnetic field. Here, pressure molding is needed to mold the metal magnetic material into a desired shape. When pressure molding is carried out, however, distances among the metal magnetic material become uneven, and some of the metal magnetic material are excessively close to each other. As a result, magnetic saturation is easily generated during magnetic application, and DC superposition characteristics deteriorate relatively.


Thus, considered have been various measures to prevent some of the metal magnetic material from being excessively close to each other.


Patent Document 1 discloses that a metal magnetic material is covered with inorganic coat (phosphate), but phosphate has a low toughness, and a coating film may be broken when molding pressure is increased.


Patent Document 2 discloses that a surface of a metal magnetic material is coated with resin, but resin has softness, and it thereby moves during heat treatment after molding, and the metal magnetic material may excessively be close to each other.


Patent Document 3 discloses that MgO particles as spacing materials are contained so as to increase distances among a metal magnetic material, but MgO particles are extremely fine, have a high aggregability, and are thereby hard to be dispersed uniformly in a dust core. When MgO particles are not dispersed uniformly, the metal magnetic material may excessively be close to each other in part where less MgO particles are present.

  • Patent Document 1: JP2009120915 (A)
  • Patent Document 2: JP5190331 (B2)
  • Patent Document 3: JP3624681 (B2)


SUMMARY OF THE INVENTION

The present invention has been achieved under such circumstances. It is an object of the invention to provide a dust core excelling in DC superposition characteristics.


To achieve the above object, the dust core according to the present invention comprises:


a metal magnetic material;


a resin; and


an insulation film contacting with a surface of the metal magnetic material and covering the metal magnetic material,


wherein the insulation film comprises:


a first film contacting with a surface of the metal magnetic material; and


a second film contacting with the surface of the first film, and


wherein a density of the first film is higher than a density of the second film.


The dust core according to the present invention has the above features, and is thereby excellent in DC superposition characteristics.


Preferably, each of the first film and the second film comprises a Si—O based oxide.


The first film and the second film may comprise different contrasts from each other observed by TEM.


Preferably, 1.25<I1/I2<10.0 is satisfied, where I1 is a Si detection intensity of the first film, and I2 is a Si detection intensity of the second film, in TEM-EDS analysis of the first film and the second film.


Preferably, 0.075<D1/D2<10.0 is satisfied, where D1 is a thickness of the first film, and D2 is a thickness of the second film.


The metal magnetic material may comprise a main component of Fe.


The metal magnetic material may comprise a main component of Fe and Si.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a schematic view of a cross section of a dust core according to an embodiment of the present invention.



FIG. 2 is a schematic view near a surface of a metal magnetic material constituting the dust core shown in FIG. 1.



FIG. 3 is a TEM image obtained by TEM observation near a surface of a metal magnetic material.





DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Hereinafter, an embodiment of the present invention is described based on figures.


As shown in FIG. 1, a dust core 1 according to the present embodiment includes a metal magnetic material 11 and a resin 12. Moreover, the dust core 1 includes an insulation film 13 contacting with a surface 11a of the metal magnetic material 11 and covering the metal magnetic material 11.


The metal magnetic material 11 comprises any component, but preferably comprises a main component of Fe because high saturation magnetization is obtained. Preferably, the metal magnetic material 11 includes a main component of Fe and Si because a high permeability is obtained. Incidentally, “a main component is included” in the present embodiment means that an amount of the main component is 80 wt % or more in total provided that the amount of the entire metal magnetic material is 100 wt %. That is, when Fe is included as a main component, a Fe content is 80 wt % or more. When Fe and Si are included as a main component, a Fe and Si content is 80 wt % or more in total. Fe and Si may be included at any ratio, but Si/Fe=0/100 to 10/90 is preferably satisfied by weight ratio because high saturation magnetization is obtained. Incidentally, any other components other than the main component, such as Ni and Co, may be included in the metal magnetic material of the present embodiment.


The resin 12 may be any resin, such as epoxy resin of cresol novolac etc. and/or imide resin of bismaleimide etc.


Any amount of the metal magnetic material 11 and the resin 12 may be contained in the dust core 1. With respect to the whole of the dust core 1, the amount of the metal magnetic material 11 is preferably 90 wt % to 98 wt %, and the amount of the resin 12 is preferably 2 wt % to 10 wt %.


As shown in FIG. 1, the insulation film 13 is characterized by contacting with the surface 11a of the metal magnetic material 11 and covering the metal magnetic material 11.


The insulation film 13 may not cover the whole of the surface 11a of the metal magnetic material 11, but should cover 90% or more of the whole of the surface 11a of the metal magnetic material 11. This feature can enhance rust-proof effect.



FIG. 2 is an enlarged schematic view near the surface of the metal magnetic material 11 of FIG. 1. The insulation film 13 according to the present embodiment comprises a first film 13a and a second film 13b. The first film 13a is in contact with the surface 11a of the metal magnetic material 11, and the second film 13b is in contact with a surface of the first film 13a.


In the metal magnetic material 11 according to the present embodiment, a density of the first film 13a is higher than a density of the second film 13b. That is, the first film 13a is a “dense film”, and the second film 13b is a “sparse film”. It is normally considered that a “space film” has a high cushioning property and a “dense film” has a high uniformity. The insulation film 13 according to the present embodiment comprises a “dense film” in contact with the metal magnetic material 11 and a “sparse film” outside the “dense film”, and thereby achieves both cushioning property and uniformity. This is considered to allow each distance among the metal magnetic material 11 to be maintained at a relatively regular interval. As a result, it is considered that magnetic saturation during application of magnetic field is generated comparatively uniformly, and that DC superposition characteristics are favorable.


The first film 13a may not contact with the whole of the surface 11a of the metal magnetic material 11, but should contact with 90% or more of the whole of the surface 11a of the metal magnetic material 11. The second film 13b may not contact with the entire surface of the first film 13a, but should contact with 90% or more of the entire surface of the first film 13a.


The first film 13a and the second film 13b are made of any material. Preferably, both of the first film 13a and the second film 13b comprise a Si—O based oxide. Hereinafter, described are both of the first film 13a and the second film 13b comprising the same type of Si—O based oxide.


Incidentally, the Si—O based oxide may be any oxide, such as a Si oxide like SiO2 and a composite oxide including Si and other elements.


The first film 13a and the second film 13b can be distinguished from each other when they are observed by Transmission Electron Microscopy (TEM) and have different contrasts. Even if the first film 13a and the second film 13b are made of the same material, they have different contrasts when they have different densities. Then, when the first film 13a and the second film 13b are made of the same material, they have a comparatively darker visual field as their density is higher, and they have a comparatively brighter visual field as their density is lower. In the dust core 1 according to the present embodiment, the first film 13a has a relatively darker visual field.


Moreover, a Si detection intensity can be measured by observation of the first film 13a and the second film 13b with Energy Dispersive X-ray Spectroscopy (TEM-EDS). The Si detection intensity reflects an abundance ratio of Si. That is, when the first film 13a and the second film 13b are made of the same material, the Si detection intensity is higher as their density is higher. In the dust core 1 according to the present embodiment, 1.25<I1/I2<10.0 is preferably satisfied, where I1 is a Si detection intensity of the first film 13a, and I2 is a Si detection intensity of the second film 13b, because DC superposition characteristics are further improved while both of cushioning property and uniformity are achieved. When I1/I2 is too low, it is hard to achieve cushioning property and uniformity at the same time, and DC superposition characteristics easily deteriorate. When I1/I2 is too high, the dense film (first film 13a) is easily broken during die molding, and DC superposition characteristics thereby easily deteriorate. Moreover, 1.26≤I1/I2≤9.92 may be satisfied. Incidentally, I1 and I2 are an average Si detection intensity measured by randomly determining at least five or more, preferably 10 or more, measurement points on each film.


The first film 13a and the second film 13b have any thickness, but 0.075<D1/D2<10.0 is preferably satisfied, where D1 is a thickness of the first film 13a, and D2 is a thickness of the second film 13b. When D1/D2 is within the above numerical range, distances among the metal magnetic material 11 easily become uniform, and DC superposition characteristics are further favorable. Incidentally, D1 and D2 are an average thickness measured by randomly determining at least five or more, preferably 10 or more, measurement points on each film.


A method of manufacturing a dust core 1 according to the present embodiment is described below, but the dust core 1 is not limited to being manufactured by the following method.


First, metal particles to be a metal magnetic material 11 are manufactured. The metal particles are manufactured by any method, such as gas atomization method and water atomization method. The metal particles have any particle size and any circularity, but their particle size preferably has a median (D50) of 1 μm to 100 μm because a high permeability is obtained.


Next, the metal magnetic material 11 is coated to form a first film 13a comprising a Si—O based oxide. The metal magnetic material 11 is coated by any method, such as a method of applying an alkoxysilane solution to the metal magnetic material 11. The alkoxysilane solution is applied to the metal magnetic material 11 by any method, such as wet spray. The alkoxysilane is any kind, such as trimethoxysilane. The alkoxysilane solution has any concentration, but preferably has a concentration of 50 wt % to 95 wt %. The alkoxysilane solution has any solvent, such as water and ethanol.


The powder after wet spray is heated at 750 to 1000° C. for 3 to 12 hours, and the first film 13a comprising a Si—O based oxide is thereby formed.


Next, the alkoxysilane solution used for formation of the first film 13a is once again wet sprayed. Then, the powder after wet spray is once again heated at 400 to 600° C. for 0.5 to 2 hours, and a second film 13b comprising a Si—O based oxide is thereby formed.


At this time, controlling the heating temperature and time can control densities of the first film 13a and the second film 13b to be obtained, and can further control I1/I2. Specifically, the densities are higher as the heating temperature is higher, and the densities are higher as the heating time is longer. Incidentally, when the heating time for formation of the first film 13a and/or the second film 13b is short, the density of the first film 13a and/or the second film 13b decreases, but the film thickness of the first film 13a and/or the second film 13b does not change greatly, and the volume of the first film 13a and/or the second film 13b does not change greatly either. This shows that not all amount of a Si—O based oxide contained the alkoxysilane solution applied becomes the first film 13a and/or the second film 13b.


Next, a resin solution is prepared. The resin solution may be added with a curing agent in addition to the above-mentioned epoxy resin and/or imide resin. The curing agent may be any agent, such as epichlorohydrin. The resin solution has any solvent, but preferably has a volatile solvent, such as acetone and ethanol. Preferably, a total concentration of the resin and the curing agent is 0.01 to 0.1 wt % with respect to 100 wt % of the whole of the resin solution.


Next, the resin solution and the powders with the first film 13a and the second film 13b are mixed, and granules are obtained by volatilizing the solvent of the resin solution. The resulting granules may be filled in a die as they are, but may be filled in a die after being sized. The resulting granules may be sized by any method, such as a method using a mesh whose mesh size is 45 to 500 μm.


Next, the resulting granules are filled in a die having a predetermined shape and are pressed, and a pressed powder is obtained. The granules are pressed at any pressure, such as 600 to 1500 MPa.


The manufactured pressed powder is subjected to a heat curing treatment, and a dust core is obtained. The heat curing treatment is carried out with any conditions. For example, the heat curing treatment is carried out at 150 to 220° C. for 1 to 10 hours. Moreover, the heat curing treatment is carried out in any atmosphere, such as air.


The dust core according to the present embodiment and a method of manufacturing it are described above, but the dust core and the method of manufacturing it of the present invention are not limited to the above-mentioned embodiment. Incidentally, the dust core of the present invention may be a soft magnetic dust core.


The dust core of the present invention is used for any purpose, such as for coil devices of inductors, choke coils, transformers, etc.


EXAMPLES

Hereinafter, the present invention is described based on more detailed examples, but is not limited thereto.


Experimental Example 1

As a metal magnetic material, manufactured were Fe—Si based alloy particles where Si/Fe=4.5/95.5 was satisfied by weight ratio and the total amount of Fe and Si was 99 wt %. Incidentally, the median (D50) of particle sizes of the Fe—Si based alloy particles was 30


In order that a first film was formed on the metal magnetic material, a wet application was subsequently carried out by wet spraying an alkoxysilane solution against the metal magnetic material. Incidentally, the alkoxysilane solution was 50 wt % solution of trimethoxysilane.


Here, the wet spray was carried out by 5 mL/min, and the application time was adjusted as necessary.


The powder after the wet spray was subjected to a heat treatment at 800° C. for 1 to 12 hours in air, and a first film comprising a Si—O based oxide was formed.


Next, a wet application was carried out by once again wet spraying the alkoxysilane solution, which had been used to form the first film, against the metal magnetic material with the first film. The wet spray was carried out by 5 mL/min, and the application time was adjusted as necessary. Then, the powder after the wet spray was subjected to a heat treatment at 500° C. for 0.5 to 2 hours in air, and a second film comprising a Si—O based oxide was formed.


To obtain film thickness of each example shown in Table 1 to Table 3, the spray amount (application amount) of the alkoxysilane solution during the wet spray was controlled by spray time (application time) in the formation of the first film and the second film mentioned above. Incidentally, the second spray of the alkoxysilane solution and the second heat treatment were not carried out in Comparative Example “A”.


Next, a resin solution was formed by mixing an epoxy resin, a curing agent, an imide resin, and an acetone. The epoxy resin was cresol novolac. The curing agent was epichlorohydrin. The imide resin was bismaleimide. Each of the components was mixed so that a weight ratio of the epoxy resin, the curing agent, and the imide resin was 96:3:1, and that a total of the epoxy resin, the curing agent, and the imide resin was 4 wt % with respect to 100 wt % of the whole of the resin solution.


The above-mentioned metal magnetic material with the first film and the second film was mixed with the above-mentioned resin solution. Next, granules were obtained by volatilizing the acetone. Next, the granules were sized using a mesh whose mesh size was 355 The resulting granules were filled in a toroidal die whose outer diameter was 17.5 mm and inner diameter was 11.0 mm and were pressed at 980 MPa, and a pressed powder was obtained. The granules were filled so that the weight of the pressed powder was 5 g. Next, a heat curing treatment was carried out by heating the resulting pressed powder at 200° C. for 5 hours in air, and a dust core was obtained. The curing treatment was carried out so that the amount of the metal magnetic material was about 97 wt % with respect to 100 wt % of the entire dust core finally obtained.


<Distinction Between First Film and Second Film>

The resulting dust core was cut and polished, and a cross section of the dust core was exposed. The exposed cross section was drilled by Focused Ion Beam (FIB) so as to cut out a flake whose area was 1 μm×1 μm and thickness was 100 nm. The resulting flake was observed by TEM and subjected to an image analysis in a visual field of 500 nm×500 nm. FIG. 3 is an actual result of image analysis (TEM observation) of Example 30 of Table 2.


First, it was confirmed by TEM-EDS observation that there was an insulation film containing Si and O and covering the metal magnetic material. Moreover, it was confirmed by TEM observation that the insulation film comprised two films having different contrasts.


Here, among the two films, a film contacting with the surface of the metal magnetic material was considered to be a first film, and a film contacting with the surface of the first film was considered to be a second film.


In all Examples of the present application, including Example 30, the first film was a relatively dark visual field, and the second film was a relatively bright visual field. Incidentally, as understood from FIG. 3, the metal magnetic material had the darkest visual field and the resin had the brightest visual field in the image obtained by TEM observation. That is, the metal magnetic material, the first film, the second film, and the resin were darker in this order in the image obtained by TEM observation. On the other hand, no second film was present and only a metal magnetic material, a first film, and a resin were observed in Comparative Example “A”.


<Measurement of Si Detection Intensity Ratio>

Si detection intensities of the first film and the second film were measured by TEM-EDS analysis. Si detection intensities of the first film were measured randomly at 10 points of the first film. An average of the Si detection intensities at the 10 points was considered to be I1. Likewise, Si detection intensities of the second film were measured randomly at 10 points of the second film, and an average of the Si detection intensities at the 10 points was considered to be I2. Then, I1/I2 was calculated.


<Measurement of Film Thickness>

Film thicknesses of the first film and the second film were measured by TEM observation. A measurement point was set on the surface of the metal magnetic material. Then, a perpendicular line was drawn from the measurement point toward the first film and the second film, and a length of the perpendicular line in the first film was considered to be a thickness of the first film at the measurement point. Likewise, a length of the perpendicular line in the second film was considered to be a thickness of the second film at the measurement point. 10 measurement points were set, and thicknesses of the first film and the second film were measured at each measurement point. Then, an average of the thicknesses of the first film was defined as D1, and an average of the thicknesses of the second film was defined as D2. Then, D1/D2 was calculated.


<Measurement of DC Superposition Characteristics>

In the toroidal dust core obtained in each example, the winding number was set to 50 turns, and initial permeability was measured by LCR meter (LCR428A manufactured by HP). The change in initial permeability was observed by changing a DC magnetic field to be applied between 0 to 20000 A/m. A value (Hμi*0.8) of DC magnetic field when initial permeability became μi*0.8 was evaluated, where μi was initial permeability when no DC magnetic field was applied. When Hμi*0.8≥4500 A/m was satisfied, DC superposition characteristics were considered to be good. When Hμi*0.8≥10000 A/m was satisfied, DC superposition characteristics were considered to be better. When Hμi*0.8≥12000 A/m was satisfied, DC superposition characteristics were considered to be still better.



















TABLE 1






wet spray time
heating time
wet spray time
heating time




total film




of first film
of first film
of second film
of second film

D1
D2

thickness
Hμi*0.8



h
h
h
h
I1/I2
nm
nm
D1/D2
nm
A/m

























Comp. Ex. “A”
0.3
6
0
0

12
0

12
2375


Ex. 1
5.0
6
0.1
1
1.77
198
3
66.0
201
10714


Ex. 2
4.8
6
0.3
1
1.76
190
9
21.1
199
11111


Ex. 3
4.3
6
0.4
1
1.79
172
17
10.1
189
11538


Ex. 4
4.6
6
0.6
1
1.75
182
19
9.58
201
12821


Ex. 5
3.9
6
1.3
1
1.75
156
42
3.71
198
12195


Ex. 6
3.0
6
2.5
1
1.77
119
82
1.45
201
12800


Ex. 7
1.9
6
3.5
1
1.72
75
117
0.64
192
13120


Ex. 8
1.6
6
4.0
1
1.75
63
132
0.48
195
13540


Ex. 9
1.0
6
4.7
1
1.80
41
156
0.26
197
14286


Ex. 10
0.9
6
4.9
1
1.77
34
162
0.21
196
14200


Ex. 11
0.5
6
5.2
1
1.80
21
173
0.12
194
14286


Ex. 12
0.4
6
5.3
1
1.77
14
183
0.077
197
12245


Ex. 13
0.3
6
5.5
1
1.75
13
184
0.071
197
11111


Ex. 14
0.2
6
5.7
1
1.80
9
192
0.047
201
10520


Ex. 15
0.1
6
5.9
1
1.77
6
196
0.031
202
10310


























TABLE 2






wet spray time
heating time
wet spray time
heating time




total film




of first film
of first film
of second film
of second film

D1
D2

thickness
Hμi*0.8



h
h
h
h
I1/I2
nm
nm
D1/D2
nm
A/m

























Ex. 21
0.3
6
0.1
1
1.78
11
3
3.667
14
12195


Ex. 22
0.3
6
0.2
1
1.75
12
6
2.000
18
12640


Ex. 23
0.3
6
0.3
1
1.77
13
9
1.444
22
12821


Ex. 24
0.3
6
0.4
1
1.77
12
14
0.857
26
12195


Ex. 25
0.3
6
0.8
1
1.76
13
27
0.481
40
12821


Ex. 26
0.3
6
1.2
1
1.79
15
39
0.385
54
12941


Ex. 27
0.3
6
2.0
1
1.75
16
65
0.246
81
13514


Ex. 28
0.3
6
2.4
1
1.77
15
81
0.185
96
12195


Ex. 29
0.3
6
2.7
1
1.77
12
91
0.132
103
13095


Ex. 30
0.3
6
3.6
1
1.77
12
121
0.099
133
12766


Ex. 31
0.3
6
4.3
1
1.75
13
143
0.091
156
13043


Ex. 32
0.3
6
5.2
1
1.78
13
174
0.076
187
12500


Ex. 33
0.3
6
5.3
1
1.80
13
176
0.074
189
10976


Ex. 34
0.3
6
5.6
1
1.78
12
186
0.065
198
10588


Ex. 35
0.3
6
5.7
1
1.80
13
191
0.068
204
10239


Ex. 36
0.3
6
6.0
1
1.80
13
201
0.065
214
10540


Ex. 37
0.3
6
9.0
1
1.78
12
300
0.040
312
10671


























TABLE 3






wet spray time
heating time
wet spray time
heating time




total film




of first film
of first film
of second film
of second film

D1
D2

thickness
Hμi*0.8



h
h
h
h
I1/I2
nm
nm
D1/D2
nm
A/m

























Ex. 41
0.2
6
1.9
1
1.75
6
62
0.097
68
12326


Ex. 42
0.3
6
3.6
1
1.80
13
120
0.108
133
12245


Ex. 43
0.5
6
6.9
1
1.77
20
230
0.087
250
12162


Ex. 44
0.8
6
9.8
1
1.76
31
326
0.095
357
12045


Ex. 45
1.1
6
13.8
1
1.78
42
461
0.091
503
13043









Examples 1 to 15 of Table 1 were examples where D1/D2 was changed while a total film thickness (D1+D2) was fixed to around 200 nm. Examples 21 to 37 of Table 2 were examples where D2 was changed while D1 was fixed to around 12 nm. Examples 41 to 45 of Table 3 were examples where a total film thickness was changed while D1/D2 was fixed to around 0.09. In all of the examples, the density of the first film was higher than the density of the second film. Since the density of the first film was higher than the density of the second film, the first film had a dark visual field compared to the second film. Moreover, since 1.25<I1/I2<10.0 was satisfied, DC superposition characteristics were better. On the other hand, DC superposition characteristics were poor in Comparative Example “A” of Table 1, where no second film was present.


Moreover, DC superposition characteristics were still better in Examples 4 to 12, 21 to 32, and 41 to 45, where 0.075<D1/D2<10.0 was satisfied.


Experimental Example 2

In the present experimental example, I1/I2 was changed by changing heat treatment conditions after wet spray of an alkoxysilane solution, and examples and comparative examples were manufactured. The results are shown in Table 4 and Table 5. In Table 4, the wet application time of the first film was fixed to 0.3 hours, and the wet application time of the second film was fixed to 6.1 hours. In Table 5, the wet application time of the first film was fixed to 4.3 hours, and the wet application time of the second film was fixed to 5.2 hours.



















TABLE 4






wet spray time
heating time
wet spray time
heating time




total film




of first film
of first film
of second film
of second film

D1
D2

thickness
Hμi*0.8



h
h
h
h
I1/I2
nm
nm
D1/D2
nm
A/m

























Ex. 50a
0.3
12
6.1
0.5
10.32
11
205
0.054
216
8696


Ex. 51
0.3
12
6.1
1
9.92
12
200
0.060
212
10714


Ex. 52
0.3
12
6.1
2
5.43
13
202
0.064
215
11111


Ex. 53
0.3
9
6.1
0.5
3.32
11
193
0.057
204
11950


Ex. 54
0.3
9
6.1
1
2.66
13
208
0.063
221
11890


Ex. 54a
0.3
9
6.1
2
2.32
13
204
0.064
217
11850


Ex. 55
0.3
6
6.1
0.5
2.25
12
198
0.061
210
11750


Ex. 56
0.3
6
6.1
1
1.80
12
188
0.064
200
10345


Ex. 57
0.3
6
6.1
2
1.56
12
194
0.061
206
10215


Ex. 59
0.3
3
6.1
0.5
1.26
13
195
0.069
208
11500


Ex. 50b
0.3
3
6.1
1
1.22
13
196
0.066
209
6667


Ex. 50c
0.3
3
6.1
2
1.20
11
199
0.055
210
4762


Comp. Ex. 4
0.3
1
6.1
0.5
1.00
12
190
0.063
202
2941


Comp. Ex. 6
0.3
1
6.1
2
0.85
10
192
0.052
202
1235


























TABLE 5






wet spray time
heating time
wet spray time
heating time




total film




of first film
of first film
of second film
of second film

D1
D2

thickness
Hμi*0.8



h
h
h
h
I1/I2
nm
nm
D1/D2
nm
A/m

























Ex. 60a
4.3
12
5.2
0.5
10.32
23
174
0.134
197
9696


Ex. 61
4.3
12
5.2
1
9.92
24
173
0.136
197
12214


Ex. 62
4.3
12
5.2
2
5.43
24
173
0.137
197
12611


Ex. 63
4.3
9
5.2
0.5
3.32
23
172
0.135
196
13450


Ex. 64
4.3
9
5.2
1
2.66
24
174
0.137
198
13390


Ex. 64a
4.3
9
5.2
2
2.52
23
172
0.134
195
13350


Ex. 65
4.3
6
5.2
0.5
2.25
24
173
0.136
196
13250


Ex. 66
4.3
6
5.2
1
1.80
24
172
0.137
195
13998


Ex. 67
4.3
6
5.2
2
1.56
23
172
0.136
196
13730


Ex. 69
4.3
3
5.2
0.5
1.26
24
173
0.139
196
13000


Ex. 60b
4.3
3
5.2
1
1.22
24
173
0.138
196
8167


Ex. 60c
4.3
3
5.3
2
1.20
23
173
0.134
196
6262


Comp. Ex. 14
4.3
1
5.2
0.5
1.00
24
172
0.137
196
4441


Comp. Ex. 16
4.3
1
5.2
2
0.85
23
172
0.133
195
2735









In each example of Table 4 and Table 5, the density of the first film was higher than the density of the second film. Since the density of the first film was higher than the density of the second film, the first film had a dark visual field compared to the second film. Moreover, I1/I2>1.00 was satisfied. Then, DC superposition characteristics were good. In Examples 51 to 59 and 61 to 69, where 1.25<I1/I2<10.0 was satisfied, DC superposition characteristics were better. In Examples 61 to 69, where 1.25<I1/I2<10.0 and 0.075<D1/D2<10.0 were satisfied, DC superposition characteristics were still better. On the other hand, Comparative Examples 4 and 14, where the density of the first film and the density of the second film were similar to each other, I1/I2=1.00 was satisfied. In Comparative Examples 6 and 16, where the density of the second film was higher than the density of the first film, I1/I2≤1.00 was satisfied, and the second film had a dark visual field compared to the first film. Then, DC superposition characteristics of Comparative Examples 4, 6, 14, and 16 were inferior to those of Examples.


Experimental Example 3

The present experimental example was carried out in a similar manner to Experimental Example 1 except that no alkoxysilane solution was wet sprayed against the metal magnetic material, and that no insulation film was formed. As a result, when no insulation film was present, the metal magnetic material was hard to be molded, and a dust core could not be manufactured.


NUMERICAL REFERENCES




  • 1 . . . dust core


  • 11 . . . metal magnetic material


  • 11
    a . . . surface of metal magnetic material 11


  • 12 . . . resin


  • 13 . . . insulation film


  • 13
    a . . . first film


  • 13
    b . . . second film


Claims
  • 1. A dust core comprising: a metal magnetic material;a resin; andan insulation film contacting with a surface of the metal magnetic material and covering the metal magnetic material,wherein the insulation film comprises:a first film contacting with the surface of the metal magnetic material; anda second film contacting with a surface of the first film, andwherein a density of the first film is higher than a density of the second film.
  • 2. The dust core according to claim 1, wherein each of the first film and the second film comprises a Si—O based oxide.
  • 3. The dust core according to claim 2, wherein the first film and the second film comprise different contrasts from each other observed by TEM.
  • 4. The dust core according to claim 2, wherein 1.25<I1/I2<10.0 is satisfied, where I1 is a Si detection intensity of the first film, and I2 is a Si detection intensity of the second film, in TEM-EDS analysis of the first film and the second film.
  • 5. The dust core according to claim 3, wherein 1.25<I1/I2<10.0 is satisfied, where I1 is a Si detection intensity of the first film, and I2 is a Si detection intensity of the second film, in TEM-EDS analysis of the first film and the second film.
  • 6. The dust core according to claim 1, wherein 0.075<D1/D2<10.0 is satisfied, where D1 is a thickness of the first film, and D2 is a thickness of the second film.
  • 7. The dust core according to claim 2, wherein 0.075<D1/D2<10.0 is satisfied, where D1 is a thickness of the first film, and D2 is a thickness of the second film.
  • 8. The dust core according to claim 3, wherein 0.075<D1/D2<10.0 is satisfied, where D1 is a thickness of the first film, and D2 is a thickness of the second film.
  • 9. The dust core according to claim 4, wherein 0.075<D1/D2<10.0 is satisfied, where D1 is a thickness of the first film, and D2 is a thickness of the second film.
  • 10. The dust core according to claim 5, wherein 0.075<D1/D2<10.0 is satisfied, where D1 is a thickness of the first film, and D2 is a thickness of the second film.
  • 11. The dust core according to claim 1, wherein the metal magnetic material comprises a main component of Fe.
  • 12. The dust core according to claim 2, wherein the metal magnetic material comprises a main component of Fe.
  • 13. The dust core according to claim 3, wherein the metal magnetic material comprises a main component of Fe.
  • 14. The dust core according to claim 4, wherein the metal magnetic material comprises a main component of Fe.
  • 15. The dust core according to claim 6, wherein the metal magnetic material comprises a main component of Fe.
  • 16. The dust core according to claim 1, wherein the metal magnetic material comprises a main component of Fe and Si.
  • 17. The dust core according to claim 2, wherein the metal magnetic material comprises a main component of Fe and Si.
  • 18. The dust core according to claim 3, wherein the metal magnetic material comprises a main component of Fe and Si.
  • 19. The dust core according to claim 4, wherein the metal magnetic material comprises a main component of Fe and Si.
  • 20. The dust core according to claim 6, wherein the metal magnetic material comprises a main component of Fe and Si.
Priority Claims (2)
Number Date Country Kind
2017-045489 Mar 2017 JP national
2018-039968 Mar 2018 JP national