[0001] This invention relates to Fe-based, soft magnetic alloys and a dust core of said
alloy.
[0002] Conventionally, iron cores of crystalline materials such as permalloy or ferrite
have been employed in high frequency devices such as switching regulators. However,
the resistivity of permalloy is low, so it is subject to large core loss at high frequency.
Also, although the core loss of ferrite at high frequencies is small, the magnetic
flux density is also small, at best 5,000 G. Consequently, in use at high operating
magnetic flux densities, ferrite becomes close to saturation and as a result the core
loss is increased.
[0003] Recently, it has become desirable to reduce the size of transformers that are used
at high frequency, such as the power transformers employed in switching regulators,
smoothing choke coils, and common mode choke coils. However, when the size is reduced,
the operating magnetic flux density must be increased, so the increase in core loss
of the ferrite becomes a serious practical problem.
[0004] For this reason, amorphous magnetic alloys, i.e., alloys without a crystal structure,
have recently attracted attention and have to some extent been used because they have
excellent soft magnetic properties such as high permeability and low coercive force.
Such amorphous magnetic alloys are typically base alloys of Fe, Co, Ni, etc., and
contain metalloids as elements promoting the amorphous state, (P, C, B, Si, Al, and
Ge, etc.).
[0005] However, not all of these amorphous magnetic alloys have low core loss in the high
frequency region. Iron-based amorphous alloys are cheap and have extremely small core
loss, about one quarter that of silicon steel, in the frequency region of 50 to 60
Hz. However, they are extremely unsuitable for use in the high frequency region for
such applications as in switching regulators, because they have an extremely large
core loss in the high frequency region of 10 to 50 kHz. In order to overcome this
disadvantage, attempts have been made to lower the magnetostriction, lower the core
loss, and increase the permeability be replacing some of the Fe with non-magnetic
metals such as Nb, Mo, or Cr. However, the deterioration of magnetic properties due
to hardening, shrinkage, etc., of resin, for example, on resin moulding, is large
compared to Co-based alloys, so satisfactory performance of such materials is not
obtained when used in the high frequency region.
[0006] Co-based, amorphous alloys also have been used in magnetic components for electronic
devices such as saturable reactors, since they have low core loss and high squareness
ratio in the high frequency region. However, the cost of Co-based alloys is comparatively
high making such materials uneconomical.
[0007] As explained above, although Fe-based amorphous alloys constitute cheap soft magnetic
materials and have comparatively large magnetostriction, they suffer from various
problems when used in the high frequency region and are inferior to Co-based amorphous
alloys in respect of both core loss and permeability. On the other hand, although
Co-based amorphous alloys have excellent magnetic properties, they are not industrially
practical due to the high cost of such materials.
[0008] In the technical field of dust cores, use is made of iron powder, Mo permalloy, etc.
for dust cores in noise filters and choke coils, since they can be produced in a variety
of shapes more easily than can thin strips. However, there are problems in their use
in power sources at high frequency owing to the comparatively large core loss.
[0009] As described above, Fe-based amorphous alloys constitute an inexpensive soft magnetic
material, but their magnetostriction is comparatively large, and they are inferior
to Co-based amorphous alloys in respect of core loss and permeability, so that there
are problems in using these materials in the high frequency region. On the other hand,
although Co-based amorphous alloys have excellent magnetic properties, as hereinbefore
pointed out, the high price of the raw material makes them commercially disadvantageous.
Such materials also suffer disadvantages where used for dust cores since they too
have comparatively large core losses, causing problems in their use in power sources
of high frequency.
[0010] Consequently, having regard to the above problems, the object of this invention is
to provide an Fe-based soft magnetic alloy having high saturation magnetic flux density
in the high frequency region, with attractive soft magnetic characteristics.
[0011] Another object of this invention is to provide an Fe-based dust core capable of being
produced in various shapes and also having attractive soft magnetic characteristics
with high saturation magnetic flux density in the high frequency region.
[0012] According to a first aspect of the invention, there is provided an Fe-based soft
magnetic alloy having fine crystal grains and defined by formula (I):
Fe
100-a-b-cCu
a M
b Y
c; (I)
wherein
"M" is at least one element from:
Groups IVa, Va, VIa of the periodic table, Mn, Co, Ni, Al and the Platinum group;
"Y" is at least one element from:
Si, B, P, and C;
and wherein "a", "b", and "c", expressed in atomic % are 3 < a ≦ 8
0.1 < b ≦ 8
3.1 ≦ a+b ≦ 12
15 ≦ c ≦ 28.
[0013] In accordance with a second aspect, the invention provides a dust core made from
a copper-containing alloy having fine grains and defined by formula (II)
Fe
100-a-b-c-d-eCu
a M′
bM˝
cSi
dB
e (II)
wherein
"M′" is at least one element selected from:
Groups IVa, Va, VIa of the periodic table;
"M˝" is at least one element from:
Mn, Co, Ni, Al, and the Platinum group;
and wherein "a", "b", "c", "d" and "e", expressed in atomic % are as follows:
3 < a ≦ 8
0.1 < b ≦ 8
0 ≦ c ≦ 15
8 ≦ d ≦ 22
3 ≦ e ≦ 15
15 ≦ d+e ≦ 28.
[0014] In preferred embodiments, it is desirable that fine crystal grains are present to
the extent of at least 30% in terms of the area ratio in the alloy. it is further
desirable that at least 80% of the fine crystal grains be of a size in the range of
50Å to 300Å. The term "area ratio" of fine crystal grains as used herein means the
ratio of the surface of the fine grains to the total surface in a plane of the alloy
as measured, for example, by photomicrography or by microscopic examination of ground
and polished specimens.
[0015] In order to attain the above objects, and desired properties it is important to control
the composition of the alloy and to balance the constituents as hereinafter described.
In particular, it is desirable that fine crystal grains should be present to the extent
of 30% or more in terms of area ratio in the alloy. It is further desirable that 80%
or more of the fine crystal grains be of a size in the range of 50Å to 300Å.
[0016] In the second aspect of the invention it was also discovered that an alloy powder
having fine crystal grains and defined by formula (II) can also possess excellent
properties and is especially suitable for manufacture of dust cores:
Fe
100-a-b-c-d-e Cu
a M′
b M˝
c Si
d B
e (II)
where "M′" is at least one element from:
Groups IVa, Va, VIa of the periodic table;
"M˝" is at least one element from:
Mn, Co, Ni, Al, and the Platinum group; and
"a","b", "c", "d", and "e", expressed in atomic % are as follows
3 < a ≦ 8,
0.1 < b ≦ 8,
0 ≦ c ≦ 15,
8 ≦ d ≦ 22,
3 ≦ e ≦ 15,
15 ≦ d + e ≦ 28.
[0017] Optimum properties of such alloy powders can also be achieved when the fine crystal
grains are present to th extent of at least 30% in terms of area ratio in the alloy
and it is further preferable that, of these fine crystal grains, at least 80% should
be crystal grains of 50Å to 300Å.
[0018] In order that the invention may be illustrated and readily carried into effect, preferred
embodiments of first and second aspects will now be described by way of non-limiting
examples only, with reference to the accompanying drawings, wherein:
Fig. 1 is a graph of the variation of corrosion resistance and saturation magnetization
resulting form the addition of Cu to an alloy of this invention;
Fig. 2 is a graph showing the effect of changes in the amount of Cu on packing ratio;
Fig. 3 is a graph showing the µ′, Q-F characteristics of embodiments of the invention
and of comparative examples;
Fig. 4 is a graph showing the DC superposition characteristic of embodiments of the
invention and of comparative examples; and
Fig. 5 is a graph showing the effect of changes in the amount of Cu on saturation
magnetization.
[0019] In accordance with the invention, it is important that the alloy components are within
the proportions indicated. Copper is especially important because it is effective
in increasing corrosion resistance, preventing coarsening of the crystal grains, and
improving soft magnetic characteristics such as core loss and permeability. However,
if too little Cu is present, the benefit of the addition is not obtained. On the other
hand, if too much Cu is present, the magnetic characteristics are adversely affected.
A range of more than 3 and less than 8 atomic % is therefore selected. This is particularly
desirable in the use of the alloy for dust cores, since the packing ratio is increased
by increased amounts of Cu. Preferably, the amount of Cu is more than 3 and less than
5 atomic %.
[0020] In the first aspect "M" is at least one element from: Groups IVA, Va, VIA of the
periodic table, Mn, Co, Ni, Al and the Platinum group, i.e., Ru, Rh, Pd, Os, Ir and
Pt as elements of the Platinum group. These elements are effective in making the crystal
grain size uniform, and in improving the soft magnetic properties by reducing magnetostriction
and magnetic anisotropy. It is also effective in improving the magnetic properties
in respect of temperature change. However, if the amount of "M" is too small, the
benefit of addition is not obtained and if the amount is too large, the saturation
magnetic flux density is lowered. An amount in the range 0.1 to 8 atomic % is selected.
Preferably the amount is 1 to 7 atomic %, and even more preferably 1.5 to 5 atomic
%. In addition to the above-mentioned effects, the various elements comprising "M"
have the following respective effects: in the case of Group IV elements, increase
of the range of heat treatment conditions for obtaining optimum magnetic properties;
in the case of Group Va elements, increase in the resistance to embrittlement and
in workability such as by cutting; in the case of Group VIa elements, improvement
of corrosion resistance and surface morphology; in the case of Al, increased fineness
of the crystal grains and reduction of magnetic anisotropy, thereby improving magnetostriction
and soft magnetic properties.
[0021] The elements Nb, Mo, Cr, Mn, Ni and W are desirable to lower core loss, and Co is
desirable in particular to increase saturation magnetic flux density.
[0022] In the second aspect "M′" is at least one element from : Groups IVa, Va, VIa of the
periodic table. These elements are effective in making the crystal grain size uniform,
and in improving the soft magnetic properties by lowering magnetostriction and magnetic
anisotropy. They also improve the magnetic properties with respect to change of temperature.
However, if too little is used, the benefit of the addition is not obtained. On the
other hand, if too much is used, the saturation magnetic flux density is lowered.
An amount of 0.1 to 8 atomic % is therefore selected. Preferably the range is 1 to
7 atomic %, and even more preferably 1.5 to 5 atomic %. In this connection, the additive
elements in M′ have, in addition to the aforementioned benefits, the following benefits:
in the case of Group IVa elements, an expansion of the range of heat treatment conditions
that are available in order to obtain optimum magnetic properties; in the case of
the Group Va elements, increase in resistance to embrittlement and increase in workability
such as cutting; in the case of the Group VIa elements, increase in corrosion resistance
and improvement in surface configuration, resulting in improvement in magnetostriction
and soft magnetic properties.
[0023] The elements Nb, Mo, Ta, W, Zr and Hf are particularly preferable in lowering core
loss.
[0024] In the second aspect "M˝" is at least one element from: Mn, Co, Ni, Al, and the Platinum
group. These elements are effective in improving soft magnetic characteristics. However,
it is undesirable to use too much, since this results in lowered saturation magnetic
flux density. An amount of less than 15 atomic % is therefore specified. Preferably
the amount is less than 10 atomic %.
[0025] Preferably the total amount of Cu, M′ and M˝ is 3.1 to 25 atomic %. If the total
amount is too small, the benefit of the addition is slight. on the other hand, if
it is too large, the saturation magnetic flux density tends to be reduced.
[0026] In the first aspect "Y" is at least one element from: Si, B, P and C. These elements
are effective in making the alloy amorphous during manufacture, or in directly segregating
fine crystals. If the amount is too small, the benefit of superquenching in manufacture
is difficult to obtain and the above condition is not obtained but if the amount is
too large saturation magnetic flux density becomes low, making the above condition
difficult to obtain, with the result that superior magnetic properties are not obtained.
An amount in the range 15 to 28 atomic % is therefore selected. Preferably the range
is 18 to 26 atomic %. In particular, the ratio of (Si,C) / (P,B) is preferably more
than 1.
[0027] Thus the atomic ratio Si:B or C:P is preferably > 1, whichever is present.
[0028] In the second aspect, Si is effective in obtaining the amorphous state of the alloy
during manufacture or in directly segregating fine crystals. If the amount of Si used
is too small, there is little benefit from superquenching during manufacture and the
aforementioned condition is not obtained but if the amount is too large, the saturation
magnetic flux density is lowered and the aforesaid condition becomes difficult to
obtain, so that superior magnetic properties are not obtained. An amount in the range
8 to 22 atomic % is therefore selected. Preferably the range is 10 to 20 atomic %,
and even more preferably 12 to 18 atomic %. Boron, like silicon, is an element that
is effective in obtaining the amorphous condition of the alloy, or in directly segregating
fine crystals. If the amount is too small, the benefit of superquenching in manufacture
is difficult to obtain an aforementioned condition is not obtained. On the other hand,
if the amount used is too large, problems with magnetic characteristics result. An
amount in the range 3 to 15 atomic % is therefore selected. Preferably, the range
is 5 to 10 atomic %. If the total of Si and B is too small, the benefit of their addition
is not obtained. On the other hand, if the total amount is too large, the benefit
is likewise difficult to obtain, and there is a lowering of saturation magnetic flux
density. A total amount in the range 15 to 28 at. % is therefore preferable.
[0029] Fe-based soft magnetic alloys and alloy powders of this invention may be obtained
by the following method.
[0030] An amorphous alloy thin strip is obtained by liquid quenching. A quenched powder
is obtained by grinding, or by an atomizing method or by mechanical alloying method,
etc.. The alloy is heat treated for from one minute to 10 hours preferably 10 minutes
to 5 hours at a temperature of from 50C
o below the crystallization temperature to 120C
o above the crystallization temperature preferably 30C
o to 100C
o above the crystalization temperature of the amorphous alloy, to segregate the fine
crystal grains. Alternatively, segregation of the fine crystals may be obtained by
controlling the quenching speed in the quenching method.
[0031] With respect to the importance of the fine crystal grains, it has been determined
that if there are too few fine crystal grains in the alloy of this invention i.e.
if there is too much amorphous phase, an adverse effect on the magnetic properties
during moulding is increased, with increased core loss, lower permeability and higher
magnetostriction. It is therefore preferable that the fine crystal grains in the alloy
should be present to the extent of at least 30% in terms of area ratio.
[0032] Furthermore, if the crystal grain size in the aforementioned fine crystal grains
is too small, maximum improvement in magnetic properties is not obtained. On the other
hand, if too large, the magnetic properties are adversely affected. It is therefore
preferable that, in the fine crystal grains, crystals of grain size 50Å to 300Å should
be present to the extent of that least 80%.
[0033] Fe-based soft magnetic alloys according to this invention can have exellent soft
magnetic properties at high frequency. They are useful as alloys for magnetic materials
for magnetic components such as for example magnetic heads, thin film heads, radio
frequency transformers including transformers for high power use, saturable reactors,
common mode choke coils, normal mode choke coils, high voltage pulse noise filters,
and magnetic switches used in laser and other power sources, magnetic cores, etc.
used at high frequency, and for sensors of various types, such as power source sensors,
direction sensors, and security sensors, etc.
[0034] As indicated previously, alloys according to the second aspect of the invention are
also particularly useful for dust cores. However in this application, if the size
of the particles is too small, the packing ratio is lowered. On the other hand, if
the particle size is too large, losses become considerable, making the core unfit
for high frequency use. A particle size 1 to 100 µm is therefore preferable.
[0035] The shape of the particles is not prescribed, which could be, for example, spherical
or flat. These shapes depend on the method of manufacture. For example, in the case
of the atomizing method, spherical powder is obtained, but if this is subjected to
rolling treatment, flat powder is obtained.
[0036] The alloy powders, can be subjected to ordinary press forming and sintering is advantageously
carried out while performing heat treatment for 10 minutes to 10 hours at 450°C to
650°C.
[0037] In this process, an inorganic insulating material such as a metallic alkoxide, water
glass, or low melting point glass is used as a binder.
[0038] The following examples further illustrate the invention.
Examples of First Aspect
[0039] Amorphous alloy thin strips of about 15 µm were obtained by the single rolling method
from master alloy consisting of Fe
75-aCu
aNb₃Si₁₂B₁₀, for a = 0, 2, 4, 6, 8, and 10.
[0040] These thin strips were then subjected to heat treatment for about 80 minutes at a
temperature about 20C
o higher than the crystallization temperature of this alloy (measured with a rate of
temperature rise 10C
o/min).
[0041] The corrosion resistance of the thin strip that was obtained was measured as the
loss in initial weight on immersion for 100 hours in 1N HCl. The results are described
in Fig. 1. The amorphous alloy strip was then wound to form a toroidal magnetic core
of external diameter 18 mm, internal diameter 12 mm, and height 4.5 mm, which was
then subjected to heat treatment in the same way as above.
[0042] The saturation magnetization of the magnetic core obtained was measured by a vibrating
sample magnetometer (VSM). These results are also shown in Fig. 1.
[0043] It can be seen from Fig. 1 that the corrosion resistance is greatly improved by the
Cu addition; the value falling to below 0.5% when the Cu addition exceeds 3 atomic%.
Also, if the Cu addition exceeds 8 atomic%, the saturation magnetization becomes 7.5
KG, which is a value equal to that of Co-based amorphous alloy. To satisfy corrosion
resistance and saturation magnetization, the value of the Cu content should therefore
be more than 3 atomic % and less than 8 atomic %.
[0044] When the core loss was measured at B = 2 KG, f = 100 KHz, low core loss of 290 to
330 mW/cc was found except at X = 0 at. %.
[0045] Thin alloy strips of the above alloy compositions Fe
71.5Cu
3.5Nd₁₃Si₁₃B₉ were wound to form a toroidal core of external diameter 18 mm, internal
diameter 12 mm, and height 4.5 mm, which was then subjected to heat treatment under
the conditions shown in Table 1. For comparison, a core was manufactured by performing
heat treatment at about 430°C for about 80 min. It was found by TEM observation that
fine crystal grains had not segregated in the magnetic core that was obtained.
[0046] Five samples of the magnetic core material according to this invention in which fine
crystal grains were present, were prepared for evaluation with five samples of comparative
magnetic core material in which fine crystal grains were not present. The core loss
after heat treatment at B = 2 KG and f = 100 KHz and the core loss and magnetostriction
after epoxy resin moulding were measured, and the permeability and saturation flux
density at 1 KHz, 2mOe were measured. The mean values are shown in Table I.
TABLE I
Alloy Composition |
Whether fine crystal grains are present |
Core loss (mw/cc) |
Magnetostriction (X10⁻⁴) |
Permeability µ′IKHz (X10⁴) |
Saturation magnetic flux density (kG) |
|
|
Before moulding |
After moulding |
|
|
|
Fe71.5Cu3.5Nd₃Si₁₃B₉ |
Yes |
210 |
250 |
1.1 |
12.8 |
11.7 |
Fe71.5Cu3.5Nd₃Si₁₃B₉ |
No |
670 |
2860 |
13.5 |
1.2 |
11.7 |
[0047] As is clear from the above Table I, in comparison with the magnetic cores consisting
of amorphous alloy thin strip of the same composition, the alloy of this invention,
owing to the presence of fine crystal grains, shows excellent soft magnetic properties
at high frequencies, has high permeability with low core loss, in particular, after
resin moulding, and low magnetostriction.
[0048] With the present invention, an Fe-based soft magnetic alloy can be provided having
excellent soft magnetic properties, owing to the presence of fine crystal grains in
the desired alloy composition and high saturated magnetic flux density in the high
frequency region.
Examples of the Second Aspect
[0049] With an alloy system consisting of Fe
75-xCu
xNb₃Si₁₅B₇, spherical powders of 10 to 50 µm were manufactured by the atomizing method
for X = 1, 2, 3, 4, 5, 6, and 7.
[0050] Toroidal cores of 38 X 19 X 12.5 mm were pressure formed from these powders using
water glass as a binder. Sintering was then performed at 550°C for 60 minutes in the
case of X = 1 to 3
o; 530
oC and 60 minutes in the case of X = 4 and 5, and 550°C and 60 minutes in the case
of X = 6 and 7.
[0051] The packing ratio for these cores was then examined. As shown in Fig. 2, it was found
that the packing ratio increased with increasing amounts of Cu.
[0052] Also, for X = 2 and X = 4 of these samples, the µ′, Q - f characteristics were measured.
In this measurement, an LCR meter was used, winding 20 turns onto the magnetic core
and using a voltage of 1 V. The results are shown in Fig. 3. As is clear from Fig.
3, the alloy of this invention performed much better than another alloy where (X =
2) shown for comparison, and would be effective as a magnetic core for a choke core
transformer or the like.
[0053] The DC superposition characteristic was also measured using the same samples. The
results are shown in Fig. 4. It is clear from these results that the magnetic core
of this invention is superior.
[0054] The various alloy powders shown in Table II were manufactured by the atomizing method.
The powders obtained were spherical powders, of powder size 10 to 50 µm.
[0055] The powders were pressure formed into toroidal cores of 38 X 19 X 12.5 mm, using
water glass as binder. The cores were subjected to heat treatment at 540°C for 60
minutes in the case of samples 1 to 6, and used for carrying out the measurements.
[0056] For comparison, a sample 7 was manufactured in the same way and an Fe₇₉Si₁₀B₁₁ amorphous
thin strip. Evaluations were performed also for an iron powder dust core of the same
shape, and for a toroidal core sample 8 which was wound to the same shape, and subjected
to heat treatment, resin impregnation and gap forming.
[0057] Table II shows the results obtained by measuring µ′10 kHz and q10 kHz for these cores.
It can be seen that high µ′ and high Q values are obtained with the cores of this
invention.
TABLE II
Sample |
Composition |
µ′ 1KHz |
Q100KHz |
1 |
Fe₇₂Cu₄Ta₃Si₁₄B₇ |
160 |
50 |
2 |
Fe₇₂Cu₄W₃Si₁₄B₇ |
160 |
50 |
3 |
Fe₇₂Cu₄Mo₃Si₁₄B₇ |
157 |
48 |
4 |
Fe₇₂Cu₄Nb₃Si₁₄B₇ |
165 |
53 |
5 |
Fe₇₂Cu₄Nb₂Cr₂Si₁₄B₆ |
165 |
52 |
6 |
Fe₇₂Cu₄Nb₂Ru₂Si₁₄B₆ |
167 |
55 |
7 |
Fe₇₁Cu₁Mo₃Si₁₃B₁₂ |
105 |
28 |
8 |
Fe₇₉Si₁₀B₁₁ (cut core) |
100 |
25 |
9 |
Iron powder dust |
30 |
11 |
[0058] Alloy powder of the composition Fe₇₉-xCuxNb₂Si₁₃B₆ was manufactured by the atomization
method. The powder obtained was a spherical powder of particle size 10 to 50 µm.
[0059] This powder was pressure formed into toroidal cores of 38 X 19 X 12.5 mm, using water
glass as binder, and measurement samples were prepared by carrying out heat treatment
at 500°C for 90 mintes.
[0060] Saturation magnetization for the samples obtained was measured, using a VSM, in a
magnetic field of 10 KOe. The results are shown in Fig. 5.
[0061] It is clear from Fig. 5 that saturation magnetization is reduced by replacing Fe
by Cu, and there are practical problems when the Cu exceeds 8 at. %.
[0062] As described above, this invention makes it possible to provide an Fe-based dust
core that has a high saturation magnetic flux density, excellent soft magnetic characteristics
at high frequency and that is capable of being made in various shapes.
[0063] The foregoing description and examples have been set forth merely to illustrate the
invention and are not intended to be limiting. Since modifications of the described
embodiments incorporating the spirit and substance of the invention may occur to persons
skilled in the art, the scope of the invention should be limited only by the appended
claims and equivalents.
1. An Fe-based soft magnetic alloy having fine crystal grains and defined by formula
(I)
Fe100-a-b-cCuaMbYc; (I)
wherein
"M" is at least one element from the following:
Groups IVa, Va, VIa of the periodic table, Mn, Co, Ni, Al and the Platinum group;
"Y" is at least one element from the following:
Si, B, P, and C;
and wherein "a", "b", and "c", expressed in atomic % are as follows:
3 < a ≦ 8
0.1 < b ≦ 8
3.1 ≦ a+b ≦ 12
15 ≦ c ≦ 28.
2. An alloy according to claim 1 wherein the area ratio of the fine crystal grains
present in the alloy is at least 30%.
3. An alloy according to claim 1 or 2 wherein at least 80% of fine crystal grains
present in the alloy are in the range of 50 Å to 300 Å.
4. An alloy according to any preceding claim wherein the amount of Cu is more than
3 and less than 5 atomic %.
5. An alloy according to any preceding claim wherein the amount of "M" is 1 to 7 atomic
%, preferably 1.5 to 5 atomic %.
6. An alloy according to any preceding claim wherein the amount of "Y" is 18 to 26
atomic %.
7. An alloy according to any preceding claim wherein the ratio of (Si and/or C) to
(B and/or P) is more than 1.
8. A dust core made from an alloy powder having fine crystal grains and defined by
formula (II),
Fe100-a-b-c-d-eCuaM′bM˝cSidBe (II)
wherein
"M′" is at least one element from the following:
Groups IVa, Va, VIa of the periodic table;
"M˝" is at least one element from the following:
Mn, Co, Ni, Al, and the Platinum group;
and wherein "a", "b", "c", "d" and "e", expressed in atomic %, are as follows:
3< a≦ 8
0.1< b≦ 8
0≦ c≦ 15
8≦ d≦ 22
3≦ e≦ 15
15 ≦ d+e ≦ 28.
9. A dust core according to claim 8 wherein the area ratio of the fine crystal grains
present in the alloy is at least 30%.
10. A dust core according to claim 8 or 9 wherein at least 80% of the fine crystal
grains are 50 Å to 300 Å.
11. A dust core according to any one of claims 8 to 10 wherein the amount Cu is more
than 3 less than 5 atomic %.
12. A dust core according to any one of claims 8 to 11 wherein the amount of M′ is
1 to 7 atomic %, preferably 1.5 to 5 atomic %.
13. A dust core according to any one of claims 8 to 12 wherein the amount of M˝ is
less than 10 atomic %.
14. A dust core according to any one of claims 8 to 13 wherein the amount of Cu, M′
and M˝ is 3.1 to 25 atomic %.
15. A dust core according to any one of claims 8 to 14 wherein the amount of Si is
10 to 22 atomic %, preferably 12 to 18 atomic %.
16. A dust core according to any one of claims 8 to 15 wherein the amount of B is
5 to 10 atomic %.
17. A dust core according to any one of claims 8 to 16 wherein the particle size of
the alloy powder is in the range 1 to 100 µm.
18. A method of treatment an Fe-based soft magnetic alloy according to any one of
claims 1 to 7 comprising heat treating said alloy for from one minute to ten hours
at a temperature of from 50Co below the crystallization temperature to 120Co above the crystallization temperature to segregate the fine crystal grains; said
heat treatment preferably being carried out for from ten minutes to five hours.