Field of the Invention
[0001] The present invention is related to products produced from Fe-based amorphous alloys
(also called bulk metallic glass), and to the application of such products, in particular
as magnetic cores.
State of the art.
[0002] The production of Fe-based bulk metallic glass (BMG) is difficult due to the low
glass forming ability shown by known Fe-alloys used for this purpose, in comparison
for example to Zr-based alloys. For this reason, a large number of elements are usually
added to Fe in order to produce Fe-based BMG's. With 'bulk' we refer to three-dimensional
bodies, wherein the smallest dimension is at least 0.3mm.
[0003] Besides the need for a large number of elements (minimum 4), the number of impurities
must be carefully controlled in order to avoid crystallization by heterogeneous nucleation
during casting. This demands the use of very pure base elements which are in fact
very expensive making the current production processes of Fe-based BMG's very costly.
Some impurities can cause in addition a decrease in the final aimed properties; therefore
their levels must be carefully controlled. Fe-based amorphous materials generally
have good soft magnetic properties, i.e. coercivity is very low and permeability shows
large values. The FeNbBSi-alloy is a known example in terms of these characteristics.
It is known in the art to fabricate ribbons of these compositions and also to apply
such ribbons for making magnetic cores. The ribbons (20µm) are wound to form a ring-shaped
product. Other techniques involve the cutting of "thick" ribbons (up to 50µm) with
a ring-shape and the stacking of them in order to form the thick ring-core. All these
steps make the production of such magnetic cores more expensive.
[0004] Also, some bulk metallic glass products, such as products obtained from sintered
powders, are not suitable for low frequency (e.g. 50Hz or 60Hz) applications.
There is currently no soft magnetic amorphous Fe-based material having a thickness
higher than 300µm with a high level of impurities (industrial ferroalloys used) and
suitable for soft magnetic applications.
Aims of the invention
[0005] The present invention aims to provide an amorphous Fe-based alloy and a process for
producing products made thereof, said alloy and products being producable from industrial
base materials, whilst yielding an end product with soft magnetic properties and being
suitable for low frequency applications.
Summary of the invention
[0006] The invention is related to a product and process, as disclosed in the appended claims.
Preferred embodiments are disclosed in combinations of the independent claims with
one or more claims dependent thereon.
[0007] In particular, the present invention is related to amorphous metallic product, formed
of an alloy having a chemical formula of
Fe
100-a-b-c-d-x-y M
aNb
bSi
cB
dI
xJ
y
wherein :
- M is Co and/or Ni,
- I is one or more elements of the group consisting of Al, Cr, Cu, Mn, C and P,
- J is one or more elements of the group consisting of Ti, S, N and O
and wherein a, b, c, d, x and y are satisfying the following conditions : 0wt.%≤a≤46.1wt.%,
5.4wt.%≤b≤12.4wt.%, 2.2wt.%≤c≤4.4wt.%, 2wt.%≤d≤6wt.%, x≤2wt.% and y≤0.2wt.%. The invention
is particularly related to a ring core for differential switchgears. The invention
is equally related to a process for producing a product according to the invention.
Brief description of the figures
[0008] Figure 1 illustrates the DSC of an amorphous rod (2mm) Fe
36CO
36Nb
4B
19.2Si
4.8 produced with raw Fe-alloys and following the present invention (curve 1). As a comparison
an example of the same composition but not amorphous is shown (curve 2). In the latter
example, the O-content in the master alloys exceeded the recommended limit, O > 300
ppm.
[0009] Figure 2 shows the XRD spectrum of an amorphous rod (2mm) of Fe
36CO
36Nb
4B
19.2Si
4.8 produced with raw Fe-alloys according to the present invention.
[0010] Figure 3 shows the B-H loop of a Fe
36CO
36Nb
4B
19.2Si
4.8 amorphous rod of 2 mm diameter.
Detailed description of the invention
[0011] The invention is related to an amorphous Fe-alloy having the chemical formula of
Fe
100-a-b-c-d-x-y M
aNb
bSi
cB
dI
xJ
y wherein :
- M is Co and/or Ni,
- I is one or more elements of the group consisting of Al, Cr, Cu, Mn, C and P,
- J is one or more elements of the group consisting of Ti, S, N and O
- and wherein a, b, c, d, x and y are satisfying the following conditions : 0wt.%≤a≤46.1wt.%,
5.4wt.%≤b≤12.4wt.%, 2.2wt.%≤c≤4.4wt.%, 2wt.%≤d≤6wt.%, x≤2wt.% and y≤0.2wt.%.
[0012] Alternatively, when the ranges of M, Nb, Si and B are expressed in at.%, a, b, c,
d, are satisfying the following conditions : 0at.%≤a≤36at.%, 3at.%≤b≤6at.%, 4at.%≤c≤7at.%,
10at.%≤d≤25at.%, with x≤1.8at.% and y≤0.15at.%.
According to a preferred embodiment, 0.05≤x≤2wt.% and 0.01≤y≤0.2wt.%. According to
another embodiment, x≤1wt.% and/or y≤0.1wt.%. According to a further embodiment, 0.05≤x≤1wt.%.
When M is both Co and Ni, the formula should be interpreted as Fe
100-a-b-c-d-x-y Co
a'Ni
a''Nb
bSi
cB
dI
xJ
y with a'+a'' = a. When the alloy comprises oxygen, the O-content is preferably lower
than or equal to 0.05wt%.
[0013] The invention is thus related to any product, and in particular to a bulk metallic
product, formed of the alloy of the invention. With 'bulk metallic product' is meant
a product with the smallest dimension (e.g. thickness in case of a cylinder-like rod)
of higher than 300µm. According to a preferred embodiment of such a product, a ring-core
for a differential switchgear is provided. The thickness of said ring core is at least
300µm, preferably at least 1mm. The properties of a product according to the invention,
such as a ring core are :
- coercivity between 0.5A/m and 10A/m, and
- relative magnetic permeability between 50000 and 500000.
The ring cores according to the invention are suitable for low frequency applications
(50Hz or 60Hz).
[0014] The invention is equally related to a process for producing an amorphous metal product
having a composition according to the alloy of the invention. The process of the invention
starts from starting materials which comprise Fe-containing alloys, i.e. non-pure
materials. The starting materials may comprise raw Fe-alloys used in the steel industry.
These materials are introduced into a melting device, and heated up to a temperature
higher than their melting temperature, preferably between 1300°C and 1600°C. In the
case for example of the Fe
36CO
36Nb
4B
19.2Si
4.8 composition it is preferred to have a temperature higher than 1350°C. The melting
can be done under air or under a protective atmosphere, e.g. Ar. The use of a controlled
atmosphere with low oxygen level can favour the cleanness of the resulting product
(i.e. a low level of impurities and oxygen). According to a preferred embodiment,
the atmosphere is controlled by creating a vacuum in the melting chamber before introducing
the starting materials. In this case, before melting, a vacuum of at least 10
-1 bar, preferably at least 10
-2 bar, is created inside the chamber in order to get a clean atmosphere. During melting,
an Ar-atmosphere can be used, for example at a pressure of 1 bar.
[0015] The material is kept in a molten state during a period of time, preferably between
100s and 300s, to promote homogenization (especially important for the dissolution
of FeB). Then the molten material is cast into a mould, preferably a Cu-mould, and
cooled down to form the product.
[0016] According to a preferred embodiment, the starting materials are one or more of the
following : electrolytic-Fe, AK-steel (Al-killed steel), FeB, FeSi, FeNb and pure
Co. The alloys FeB, FeSi and FeNb are materials used by the steel industry, which
may comprise other elements than expressed by the alloy formula.
In the context of this invention, the composition of the starting materials is defined
by the limits expressed in table 1 (all values in wt%).
Table 1 : composition of starting materials
|
Electrolytic-Fe |
Ak-steel |
FeB |
FeSi |
FeNb |
Pure Co |
C |
0.0005-0.1 |
0.0005-0.1 |
0.01-0.5 |
0.001-0.3 |
0.001-0.3 |
- |
Mn |
0.0001-0.2 |
0.001-0.5 |
0.01-2 |
0.01-1 |
0.01-1 |
- |
Si |
0.0001-0.1 |
0.0001-0.3 |
0.01-2 |
62-75 |
0.2-3 |
- |
P |
0.0005-0.03 |
0.0005-0.1 |
0.0005-0.1 |
0.0005-0.1 |
0.0005-0.1 |
- |
S |
0.0001-0.05 |
0.0005-0.01 |
0.0005-0.1 |
0.0005-0.1 |
0.0005-0.2 |
- |
Al |
0.0001-0.2 |
0.0001-0.4 |
0.001-0.8 |
0.001-0.8 |
0.001-1.2 |
- |
Ti |
0.0001-0.1 |
0.0001-0.1 |
0.0001-1 |
0.0001-1 |
0.0001-1 |
- |
Nb |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
60-74 |
- |
Cu |
0.0001-0.08 |
0.001-0.1 |
0.001-0.3 |
0.001-0.1 |
0.001-0.3 |
- |
Cr |
0.0001-0.08 |
0.001-0.1 |
0.001-0.5 |
0.001-0.1 |
0.001-0.1 |
- |
Ni |
0.0001-0.08 |
0.001-0.1 |
0.001-0.3 |
0.001-0.1 |
0.001-0.1 |
- |
As |
0.0001-0.02 |
0.0001-0.05 |
0.0001-0.1 |
0.0001-0.05 |
0.0001-0.05 |
- |
Sn |
0.0001-0.02 |
0.0001-0.05 |
0.0001-0.1 |
0.0001-0.05 |
0.0001-0.05 |
- |
O |
0.001-0.1 |
0.0005-0.1 |
0.002-0.1 |
0.001-0.05 |
0.001-0.05 |
- |
N |
0.0003-0.01 |
0.0005-0.02 |
0.0005-0.05 |
0.0005-0.02 |
0.0005-0.02 |
- |
B |
0.0001-0.001 |
0.0001-0.001 |
15-21 |
0.0001-0.001 |
0.0001-0.001 |
- |
Mo |
0.0001-0.05 |
0.001-0.1 |
0.001-0.3 |
0.001-0.1 |
0.001-0.1 |
- |
Zr |
0.001-0.05 |
0.001-0.08 |
0.001-0.2 |
0.001-0.1 |
0.001-0.1 |
- |
V |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.5 |
0.0001-0.3 |
0.0001-0.3 |
- |
Co |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
99.5-99.95 |
Fe |
Rest |
Rest |
78.3 |
22.9 |
28.9 |
- |
[0017] The total amount of impurities in the Fe-alloys used as starting materials for the
production of soft magnetic bulk according to the invention is preferably lower than
4% and more preferably lower than 2%. With impurities is meant the elements that are
not nominally present in the alloy. For example, Nb is an impurity in FeB. Moreover,
the amount of Mn in the Fe-alloys (starting materials) is preferably lower than 2%
and more preferably lower than 1%.
[0018] The melting step can be performed in a levitation melter, e.g. a 100cc levitation
melter. A levitation melter is a cold crucible induction melter. It consists of a
copper crucible cooled by a circulation of water and a coil system creating a varying
magnetic field. This magnetic field creates Foucault currents in the conductive materials
inside the crucible which have three effects : heating the metals in the crucible
up to their melting point, stirring the molten alloy, thus homogenising it, and making
the molten mass levitate. During levitation melting, there is no contact between the
molten alloy and the crucible, which can remain cold while the melt can stay clean.
[0019] When a levitation melter of 100kW power is used for the realization of the process
of the invention, it is preferred to melt the materials at a power of at least 25%
of the total power and preferably in the range 25-50% of the total power. When the
melting takes place under protective atmosphere, the pressure in the melting chamber
is preferably at least 1 atm.
[0020] According to an embodiment, the steps of the process as described above are used
to form a master alloy. These steps are then followed by a further series of steps
to form the final product, e.g. a ring core. It is important to have in the master
alloy an O-level lower than 0.05 wt.% and it is preferred that this level is lower
than 0.03 wt.%.
[0021] For a good magnetic performance, some impurities must not exceed certain values in
the master alloy or final product : Ti, S and N. The total amount of (Ti + S + N)
must be lower than 0.2% and preferably lower than 0.1%. On the other hand, other impurities
might reach higher values, being beneficial for the glass forming ability. This is
the case of Al, Ni, Cr, Cu, Mn, C and P.
However, when a certain value is exceeded, the properties of the material can be damaged.
This value can be fixed to 2% and preferably to 1%.
[0022] The further steps of producing the bulk metallic glass product from the master alloy
can be done in a melting device, like an induction melting device or a levitation
melting device. An air atmosphere can be used although a controlled atmosphere or
an atmosphere with low oxygen levels is preferable. The BMG can be cast in rods of
up to 4mm, but also in other shapes, like ring-cores.
[0023] The process to form the BMG-product from the master alloy preferably comprises the
following steps :
- A piece of master alloy is introduced in the melting device. The melting device can
be a levitation melter of 12kW. An air atmosphere can be used although it is preferable
to use of a controlled atmosphere like for example an Ar-atmosphere.
- Heating up the master alloy up to a temperature higher than its melting temperature.
This temperature is in the case of FeCoNbBSi alloy higher than 1250°C. When a 12kW
levitation melter is used, a minimum power of 50% must be used and preferably a power
of at least 60% should be used. The material must be molten for at least 5 seconds
and preferably during a time longer than 10 seconds. The heating up to the melting
temperature can be done with only one ramp, but it can be preferably done in several
heating steps. For example when a 12kW levitation melter is used, the following heating
cycle can be used: 5 seconds at 20% of the power, 5 seconds at 35 % of the power,
5 seconds at 50% of the power and 2 seconds at 60% of the total power.
- Pouring the material into a Cu-mould at a temperature higher than the melting, but
preferably not exceeding by more than 20 °C the melting temperature when the aimed
diameter is between 2 and 3 mm. It is preferred to pour the material at a "low" temperature
in order to prevent crystallization.
- Cooling the molten material, to obtain the product.
Examples - test results
[0024] The following table 2 gives an example of the composition of starting materials used
in the method of the invention (in wt.%).
Table 2
|
Electrolytic-Fe |
Ak-steel |
FeB |
FeSi |
FeNb |
Pure Co |
C |
0.0013 |
0.0010 |
0.2 |
0.008 |
0.017 |
- |
Mn |
0.0001 |
0.0500 |
0.48 |
0.063 |
0.21 |
- |
Si |
0.0005 |
- |
1.10 |
66.9 |
1.83 |
- |
P |
0.0010 |
0.0030 |
0.001 |
0.001 |
0.10 |
- |
S |
0.0001 |
0.0030 |
0.001 |
0.001 |
0.042 |
- |
Al |
0.0001 |
0.0030 |
0.10 |
0.025 |
0.60 |
- |
Ti |
- |
- |
0.026 |
0.073 |
0.35 |
- |
Nb |
- |
- |
- |
- |
63.3 |
- |
Cu |
0.0005 |
0.0080 |
0.11 |
0.004 |
0.04 |
- |
Cr |
0.0001 |
0.0150 |
0.19 |
0.009 |
0.02 |
- |
Ni |
0.0002 |
0.0100 |
0.12 |
0.007 |
0.01 |
- |
As |
0.0001 |
- |
- |
- |
- |
- |
Sn |
0.0001 |
- |
- |
- |
- |
- |
O |
0.0245 |
0.0050 |
0.0220 |
0.029 |
0.074 |
- |
N |
0.0008 |
0.0028 |
0.005 |
0.004 |
0.004 |
- |
B |
0.0001 |
- |
18.6 |
- |
- |
- |
Mo |
- |
0.0010 |
- |
- |
- |
- |
Zr |
- |
- |
- |
- |
- |
- |
V |
- |
- |
- |
- |
- |
- |
Co |
- |
- |
- |
- |
- |
99.9 |
Fe |
Rest |
Rest |
78.3 |
22.9 |
28.9 |
- |
[0025] The amorphicity of the obtained materials can be tested by means of different techniques.
DSC (differential scanning calorimetry) and XRD are two known examples. Differential
scanning calorimetry gives the evolution of heat capacity of a sample when it is heated.
The sample is heated along with a reference (an empty crucible) so that both always
have similar temperatures, controlled with accuracy. The difference between the energies
brought to the sample and reference to heat them up at the same rate is monitored
and gives the difference of behaviour. Endothermic and exothermic transformations
in the sample can be spotted because they happen when respectively more or less energy
must be brought to it to keep the same heating rate. So changes in heat capacity indicate
phase transitions such as crystallisation or even simple transformations like glass
transition.
[0026] Figure 1 gives the DSC of an Fe
36Co
36Nb
4B
19.2Si
4.8 alloy produced according to the method of the invention. A glass transition and a
first crystallization peak are clearly visible on the figure (curve 1). On the other
hand, the curve 2 on the DSC curve has no visible glass transition and a very slight
crystallisation peak at around 600. This means that the sample is not fully amorphous
and contains only a very small amount of amorphous phase. During the production of
this comparison example (curve 2), it was detected that the oxygen of the master alloy
was over the recommended limits, being higher than 300 ppm. For this reason it was
not possible to produce a bulk metallic glass.
[0027] Like all amorphous materials (e.g. polymers, silica-based glasses) and unlike crystalline
material, bulk metallic glass shows no peak of diffraction on an X-ray diffractogram
but a broad halo. This is due to the lack of long-range order and crystallinity and
to the presence of short range order. The X-ray diffraction diagram of an amorphous
sample with chemical composition Fe
36CO
36Nb
4B
19.2Si
4.8 produced according to the present invention is shown by figure 2, where no Bragg
peaks can be noticed, meaning that the sample is essentially amorphous.
[0028] The magnetic properties of the materials produced according to the present invention
have been tested, see figure 3. Figure 3 shows the B-H loop of Fe
36Co
36Nb
4B
19.2Si
4.8 as measured by means of a Vibrating Sample Magnetometer (VSM). A saturation magnetization
of 1.04T is measured together with a coercivity of 4.5A/m.
[0029] A hysteresis loop tracer was used to measure systematically the coercivity of the
bulk metallic glass products produced according to the present invention. Table 3
presents the results corresponding to two materials from the present invention and
two comparative examples. The measurements were performed on 2 mm diameter rods of
as-cast materials; no additional annealing treatments have been performed. The bulk
metallic glasses show very low values of coercivity, making these materials very suitable
for soft magnetic applications. On the other hand, when the material is only partially
amorphous the coercivity reaches very high values. In this comparative example, the
O-content of the master alloy exceeded the limits of the present invention (>300ppm).
For this reason it was not feasible to produce a bulk metallic glass with such master
alloy. The second comparative example corresponds to a bulk metallic glass product
of the same composition but prepared with pure elements. The amorphous materials produced
by the present invention, i.e. starting with standard Fe-alloys have magnetic properties
similar to those of bulk metallic glass produced with high-purity elements.
Table 3. Coercivity measurements on Fe
36CO
36Nb
4B
19.2Si
4.8
|
Base materials |
State |
Coercivity (A/m) |
Present invention 1 |
Industrial Fe-alloys |
Amorphous |
8 |
Present invention 2 |
Industrial Fe-alloys |
Amorphous |
5 |
Comparative example 1 |
Industrial Fe-alloys |
Partially amorphous |
7000 |
Comparative example 2 |
Pure elements |
Amorphous |
4.5 |
1. An amorphous metallic product, formed of an alloy having a chemical formula of
Fe
100-a-b-c-d-x-y M
aNb
bSi
cB
dI
xJ
y
wherein :
• M is Co and/or Ni,
• I is one or more elements of the group consisting of Al, Cr, Cu, Mn, C and P,
• J is one or more elements of the group consisting of Ti, S, N and O
• and wherein a, b, c, d, x and y are satisfying the following conditions : 0wt.%≤a≤46.1wt.%,
5.4wt.%≤b≤12.4wt.%, 2.2wt.%≤c≤4.4wt.%, 2wt.%≤d≤6wt.%, x≤2wt.% and y≤0.2wt.%.
2. The product according to claim 1, wherein 0.05≤x≤2wt.% and 0.01≤y≤0.2wt.%.
3. The product according to claim 1, wherein x≤lwt.% and/or y≤0.1wt.%.
4. The product of any one of claims 1 to 3, wherein the O-level is lower than or equal
to 0.05wt%.
5. The product according to any one of claims 1 to 4, wherein said product is a bulk
metallic product.
6. The product according to claim 5, wherein said product is a ring core for a differential
switchgear, said ring core having a thickness higher than 300µm.
7. The product according to claim 5 or 6, wherein said product has magnetic properties
defined by
• coercivity between 0.5A/m and 10A/m, and
• relative magnetic permeability between 50000 and 500000
8. A process for producing an amorphous Fe-based product according to any one of claims
1 to 7, the process comprising the steps of :
• Providing starting materials, comprising Fe-containing alloys,
• Melting said starting materials to a temperature above the melting temperature of
said materials,
• Keeping the materials in a molten state,
• Pouring the molten materials into a mould,
• Cooling the molten material, to obtain the product.
9. The process according to claim 8, wherein said starting materials comprise one or
more of the following : electrolytic Fe, AK-steel, FeB, FeSi, FeNb.
10. The process according to claim 9, wherein the starting materials further comprise
pure Co.
11. The process according to claim 9 or 10, wherein said starting materials are defined
by the following compositions (in wt%) :
|
Electrolytic-Fe |
Ak-steel |
FeB |
FeSi |
FeNb |
Pure Co |
C |
0.0005-0.1 |
0.0005-0.1 |
0.01-0.5 |
0.001-0.3 |
0.001-0.3 |
- |
Mn |
0.0001-0.2 |
0.001-0.5 |
0.01-2 |
0.01-1 |
0.01-1 |
- |
Si |
0.0001-0.1 |
0.0001-0.3 |
0.01-2 |
62-75 |
0.2-3 |
- |
P |
0.0005-0.03 |
0.0005-0.1 |
0.0005-0.1 |
0.0005-0.1 |
0.0005-0.1 |
- |
S |
0.0001-0.05 |
0.0005-0.01 |
0.0005-0.1 |
0.0005-0.1 |
0.0005-0.2 |
- |
Al |
0.0001-0.2 |
0.0001-0.4 |
0.001-0.8 |
0.001-0.8 |
0.001-1.2 |
- |
Ti |
0.0001-0.1 |
0.0001-0.1 |
0.0001-1 |
0.0001-1 |
0.0001-1 |
- |
Nb |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
60-74 |
- |
Cu |
0.0001-0.08 |
0.001-0.1 |
0.001-0.3 |
0.001-0.1 |
0.001-0.3 |
- |
Cr |
0.0001-0.08 |
0.001-0.1 |
0.001-0.5 |
0.001-0.1 |
0.001-0.1 |
- |
Ni |
0.0001-0.08 |
0.001-0.1 |
0.001-0.3 |
0.001-0.1 |
0.001-0.1 |
- |
As |
0.0001-0.02 |
0.0001-0.05 |
0.0001-0.1 |
0.0001-0.05 |
0.0001-0.05 |
- |
Sn |
0.0001-0.02 |
0.0001-0.05 |
0.0001-0.1 |
0.0001-0.05 |
0.0001-0.05 |
- |
O |
0.001-0.1 |
0.0005-0.1 |
0.002-0.1 |
0.001-0.05 |
0.001-0.05 |
- |
N |
0.0003-0.01 |
0.0005-0.02 |
0.0005-0.05 |
0.0005-0.02 |
0.0005-0.02 |
- |
B |
0.0001-0.001 |
0.0001-0.001 |
15-21 |
0.0001-0.001 |
0.0001-0.001 |
- |
Mo |
0.0001-0.05 |
0.001-0.1 |
0.001-0.3 |
0.001-0.1 |
0.001-0.1 |
- |
Zr |
0.001-0.05 |
0.001-0.08 |
0.001-0.2 |
0.001-0.1 1 |
0.001-0.1 |
- |
V |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.5 |
0.0001-0.3 |
0.0001-0.3 |
- |
Co |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
0.0001-0.1 |
99.5-99.95 |
Fe |
Rest |
Rest |
78.3 |
22.9 |
28.9 |
- |
12. The process according to any one of claims 8 to 11, wherein said melting step is performed
in a levitation melter.
13. The process of any one of claims 8 to 12, wherein said process is used to produce
a master alloy, and wherein said process is followed by the steps of :
• Introducing the master alloy in a melting device,
• Heating up the master alloy to a temperature above its melting temperature
• Pouring the molten material into a mould
• Cooling the molten material, to obtain the product.
14. The process according to any one of claims 8 to 13, wherein the process includes a
step of creating a vacuum in the melting chamber before introducing the starting materials
in said chamber, and wherein said melting takes place under a protective atmosphere.
15. The process according to claim 14, wherein said vacuum is defined by a pressure of
at least 10-1 bar.