[0001] The invention relates generally to a method for adding alloying elements to molten
metals. More particularly, however, it relates to the addition of elements which normally
dissolve slowly and with difficulty in molten metals, particularly aluminum.
[0002] Many different methods have been employed to add alloying elements to molten metals.
Conventional methods typically add the elements directly to the melt in theform of
a lump, a bar orthe like. In some cases, they are added directly to molten metal being
tapped into a ladle, and in other cases, they may be placed in the ladle prior to
tapping.
[0003] Another method for adding alloying elementsto molten metals, particularly molten
steel, is disclosed in U.S. Patent 3,768,999 ro Ohkubo et al. In Ohkubo, alloying
is accomplished by feeding a wire rod into the molten metal. The rod is coated with
additives for the molten metal and an organic binder which decomposes into gaseous
products in the molten metal. The generated gas stirs the molten metal and thus uniformly
incorporates the added components throughout the molten metal.
[0004] U.S. Patent 3,729,309 to Kawawa also discloses a method for adding alloying elements
in the form of a wire rod to molten metals. The rod has a controlled size and is added
to a molten metal bath by inserting it at a controlled speed, so as to produce a refined
and purified metal alloy.
[0005] The above methods of adding alloying elements to molten metal work fairly well with
alloying elements which dissolve and disperse easily in the molten metal. However,
such methods do not work so well with elements having limited liquid solubility such
as Pb, Bi and Sn and high oxidizing potential such as Mg and Zn.
[0006] U.S. Patent 3,947,265 to Guzowski et al proposes a solution to the problem of adding
such "hard-to- alloy" materials to molten metal. The process employs a high current
arc which is formed between the molten base metal and the alloying addition. The alloying
addition is passed through the arc where it is melted and converted into a spray of
finely divided superheated molten particles. In such a condition, the particles are
able to rapidly dissolve in the molten metal upon contact therewith. While the Guzowski
concept of alloying is certainly an interesting one, a need still exists for a process
capable of providing improved results.
[0007] In accordance with the present invention, there is provided a process for adding
material to a molten metal media comprising the steps of:
(a) providing a body of molten media;
(b) providing a chamber means having an open discharge end positioned within said
media body;
(c) supplying said chamber means with a gas comprising an ionizable gas under sufficient
pressure to maintain an interior molten media surface substantially at said chamber's
discharge end region;
(d) supplying said material to a site within said chamber above said interior molten
media surface;
(e) conducting an electric arc between said material at said site and said interior
molten media surface and maintaining a plasm substantially extending from said site
within said chamber to said interior molten media surface; and
(f) maintaining said plasma at a sufficient energy to convert said material into a
superheated spray substantially within said plasma projected toward said interior
molten media surface;
(g) said supplying of said gas to said chamber being of sufficient rate to project
said material into said media so as to enhance entry of said material into said media.
[0008] In an embodiment of the invention, the chamber means is elongate and has an upper
inlet, at least a portion of which is located above the upper surface of the molten
media, the material being fed into the chamber through said inlet, and the interior
surface of the body of molten media being maintained at a depth below said exterior
surface such that at least 50% of material being added to the molten media is recovered
in the molten media.
[0009] In accordance with the present invention, a method is provided for adding alloying
material to a molten metal media, such as molten aluminum. The method includes the
step of converting the alloying material into a spray of superheated alloy material
and directing the spray into the molten metal media at a predetermined depth below
the media's surface, the depth having been determined beforehand to enhance dissolution
and dispersion of the alloying material into the molten media.
[0010] In a preferred embodiment, the alloying material is converted into the spray of superheated
alloy material in a spark cup means which is at least partially immersed in the molten
media body. The spark cup has a lower open end which is exposed to the molten media
and an upper inlet, at least a portion of which is located above the exposed or exterior
surface of the molten media. The lower open end of the spark cup is maintained or
immersed a predetermined depth below the surface of the molten media. The alloying
material, preferably in the form of an elongated element having a free end, is continually
fed into the spark cup through its upper inlet, and an electrical arc discharge between
the submerged molten metal surface and the alloying element in the spark cup is maintained
with a current that exceeds the globular/spray transition current density of the alloying
material. At such a cu rrent, the free or exposed end of the alloying element is converted
into a spray of superheated material. Arc shielding gas is continually supplied to
the spark cup through its upper inlet also. In addition to shielding the arc discharge,
the gas slightly pressurizes the spark cup and thereby prevents molten media from
entering its open end. As such, a submerged interior surface of molten metal media
is created in the spark cup's open end at the aforementioned predetermined depth.
The shielding gas also carries or projects the superheated spray of alloy material
into the molten media through the submerged molten metal surface so as to permit dissolution
and dispersion of the alloy material in the media. The predetermined depth of immersion
has been found to significantly enhance dispersion and dissolution of the alloying
material into the media.
[0011] The present invention also provides a lead alloyed, aluminum based article having
high machinability. The article is produced by converting lead alloy material into
a spray of superheated alloy material which is injected into a bath of molten aluminum
at a predetermined depth below the molten bath's surface. The spray is formed by establishing
an electrical arc discharge between a submerged surface of the molten media and the
alloying material. The discharge is maintained with a current that exceeds the globular/spray
transition current density of the alloying material. The spray of superheated alloying
material is directed onto the submerged interior surface of the media where dissolution
and dispersion of the alloy material into the media take place. The submerged surface
is maintained at the predetermined depth below the bath's surface having been found
to enhance said dissolution and dispersion of the lead into molten aluminum bath.
The article so produced has acicular shaped particles of lead which are smaller and
more uniformly sized and dispersed than those which are made by adding lead at the
surface of the molten aluminum or at a depth above the aforesaid predetermined depth.
Figure 1 illustrates an embodiment of the present invention.
Figure 2 illustrates the spark cup depicted in Figure 1.
Figure 3 is a graph plotting alloy dissolution rate in pounds per minute versus spark
cup immersion depth.
Figure 4 is a graph illustrating the relationship of actual recovery in percentages
versus immersion depth in inches.
[0012] Figure 1 illustrates the addition of a wire 10 of alloying material into a bath or
melt 12 of molten media in a flow-through furnace 14. The surface of melt 12 is referred
to herein as exposed or exterior surface 16. Wire 10 is being fed by a feeder 18 which
passes it through a triplex feed cable 20 into a spark cup 22, the spark cup being
partially immersed in melt 12. In spark cup 22, alloy wire 10 is converted into a
spray 24 of superheated alloy material by passing it through a plasma arc discharge
(not numbered). The plasma arc discharge is established between a submerged surface
26 of the molten metal which is maintained within an open end 28 of spark cup 22 and
a free end 30 of alloy wire 10. The arc discharge is shielded with a shielding gas
32, preferably argon, which is provided via feed cable 20 by an arc shielding gas
source 34. In addition to providing a shielding atmosphere for the arc in the spark
cup, the shielding gas source 34 pressurizes the spark cup at a pressure which is
sufficient to prevent molten metal from entering open end 28 of the spark cup. Such
pressurization also facilitates maintenance of the aforementioned submerged surface
at a certain predetermined depth below exposed surface 16 (more on this, infra). Returning
to Figure 1, it will be seen that the arc discharge is powered by a constant current
power supply source 36 (more on this, infra). Melt 12 serves as an anode with wire
10 serving as a consumable electrode. The electrical circuit leading back to current
source 36 is completed by a return wire 38 which is attached to a rod 40 immersed
in melt 12. The superheated spray produced by the arc discharge is directed or projected
by the supply of shielding gas onto submerged surface 26 where the alloy material
rapidly dissolves and disperses in melt 12. The gas is preferably supplied at a flow
rate that maximizes the projection of the spray into the melt. An impeller 42 or agitating
means is also provided to further enhance dispersion of the alloy material throughout
the melt. Spray 24 can be maintaiined as long as is desired by continually advancing
or feeding the alloying wire into the spark cup. Feeder 18 can also be controlled
to maintain or vary the rate at which wire 10 is fed into the spark cup.
[0013] The alloying material can be provided in wire form, as described above, or in the
form of rod, tube, strip or in powdered form wherein the powders are encased in a
hollow tube made from a suitable metal which has been swaged or otherwise worked to
reduce its diameter and compact the powdered material in the tube. The only real limitation
on the form of the alloying is that it should have a form which permits it to be fed
into the feed cable in a seal-tight fashion, thereby enabling the pressurized atmosphere
in the spark cup to be maintained. If the pressurized atmosphere in the spark cup
is not maintained, molten metal will, quite obviously, enter the spark cup through
its open end 28, thereby raising submerged surface 26 to a depth above its predetermined
depth. Such raising of submerged surface 26 will result in lower dissolution and dispersion
rates. (The importance of maintaining submerged surface 26 at its predetermined depth
will be discussed in more detail, infra.) While no means for sealing the wire is depicted
in Figure 1, those skilled in the art will be aware of numerous means having the capability
of providing an effective seal. Such means could include elastomer and pneumatic seals.
In addition, feeder 18 is preferably a consistent feed rate tractor drive.
[0014] Constant current source 36 is preferably of the type which maintains a relatively
constant current regardless of voltage fluctuations. The arc produced thereby has
self-stabilizing characteristics and is relatively insensitive to changes in arc length
which might be caused by fluctuations in the submerged molten metal depth. It may
also be desirable in certain situations to further enhance arc stability by seeding
the plasma discharge with certain additives, such as alkali metals which are known
to promote arc stability. Arc stability can also be enhanced by using various fluxes
known to those skilled in the relevant art.
[0015] As mentioned in U.S. Patent 3,947,265 to Guzowski, it may be desirable to add a high
frequency, high voltage component to the arc which is particularly useful if AC current
is used. This apparently reduces the tendency of the arc to extinguish every time
the voltage passes through zero, increases the stability of the arc and makes initiation
of the arc less difficult.
[0016] An important aspect of the present invention requires that the current supplied by
power source 36 exceed the globular/spray transition current density of the alloyed
material. As used herein, the globular/spray transition current density defines the
boundary line separating the two different types of metal transfer that are capable
of occurring in the plasma arc discharge. (As pointed out by Guzowski in U.S. Patent
3,947,265, this transition point can vary with such factors as alloy type, wire size
and wire speed.) In cases with current densities below the transition point, alloy
material being transferred through the arc detached into large drops which dissolve
and disperse slowly in the molten metal media. At current densities above the transition
point, the transfer mechanism changes causing the alloy material to convert a fine
spray of superheated alloy material. In this condition, the alloy material rapidly
dissolves and disperses in the molten media upon contact with submerged surface 26.
[0017] Shielding gas 32 carrying or projecting spray 24 into the melt also typically enters
the melt. This, however, should not introduce or cause any melt contamination since
such gas simply escapes from the melt by bubbling through the melt to exterior surface
16. As previously mentioned, the preferred shielding gas is argon; however, other
shielding gases, such as helium, carbon monoxide and carbon dioxide, may also be used
in appropriate situations.
[0018] The spark cup is preferably cylindrically shaped. Such a shape provides a relatively
high spark cup surface area to volume ratio which facilitates conductive heat transfer
from the spark cup to the melt. It is important to facilitate such heat transfer to
prevent the spark cup from overheating. Moreover, those skilled in the relevant art
will appreciate that such heat transfer to the melt is advantageous in that it provides
a convenient way of adding heat to the melt, thereby reducing furnace fuel needs.
Conventional alloy adding processes such as that disclosed in Guzowski et al U.S.
Patent No. 3,947,265 do not add much, if any, heat to their respective melts. For
example, most of the heat generated during melting of the alloy material in Guzowski
et al is lost to the atmosphere since the superheated spray is formed entirely above
the melt surface.
[0019] The spark cup's cylindrical shape also enhances projection of the shielding gas carrying
the superheated spray into the melt. Such projection is important in that it enhances
dissolution and dispersion of the alloying material into the melt. While a cylindrical
shape is preferred, other shapes, such as an inverted frustoconical shape, which provide
enhanced projection and heat transfer are considered to be within the purview of the
present invention.
[0020] The spark cup's composition is another important aspect of the present invention.
Preferably, it is made from material having the following characteristics:
1. High radiation heat transfer so as to maximize the transfer of radiation heat from
the arc discharge to the melt, thereby reducing the possibility of overheating in
the spark cup.
2. High resistance to thermal and mechanical shock.
3. High thermal and chemical stability in the melt. Borosilicate, alumina, mullite
and silica are some materials known to possess the desired characteristics.
[0021] Another briefly alluded to but important aspect of the present invention is directed
to immersing the spark cup and maintaining submerged surface 26 in the open end of
the spark cup at its predetermined depth below exposed surface 16. Such depth will
be referred to hereinafter as the predetermined immersion depth. It has been found
that a difference of one or two inches in the immersion depth can have a significant
impact upon the rate at which alloying material dissolves and disperses in the molten
media. Figures 3 and 4 set forth test data from experiments conducted to determine
the effects of immersion depth upon dissolution and dispersion. Figure 3 sets forth
data respecting dissolution rate versus immersion depth, and Figure 4 shows actual
recovery in percentages versus immersion depth. The goal of the experiments was to
add 0.5% lead to a substantially lead-free body of molten aluminum. The experiments
were conducted with a setup similar to that disclosed in Figure 1 except that a constant
voltage supply source was used instead of the preferred constant current supply source.
The flow-through furnace used in the experiments contained approximately 454 Kgs (1000
pounds) of aluminum. The bath of molten aluminum in the furnace had a depth of approximately
76 cm (30 inches) with a diameter of approximately 58 cm (23 inches). Lead wire of
3.175 mm (8 inch) diameter was fed into a borosilicate spark cup at a feed rate of
about 76 cm (30 inches) per minute via a triplex feed cable. The spark cup was cylindrically
shaped and had a lower opening similar to that described in Figure 1 with a diameter
of approximately five centimeters. The spark cup's length to diameter ratio was approximately
6 to 1. Argon shielding gas was fed into the spark cup via the feed cable at a flow
rate of about 0.28 standard m
3/hr (10 standard ft
3/hr). A plasma arc discharge was established in the spark cup between the free end
of the lead wire and the submerged molten metal surface at a voltage of about 35 volts
and a current of about 125 amperes, which translates into a current density of about
1550 amps/cm
2 (10,000 amp/ in
2). As such, the free end of the wire melted and converted into an axial spray of superheated
alloy material upon entering the arc discharge. The spray was directed onto the submerged
melt surface by the shielding gas. After adding an appropriate amount of lead wire
to the bath of molten aluminum, the alloyed molten aluminum was continuously cast
into several ingots having dimensions of 15 cm x 15 cm x 91 cm (6 in. x 6 in. x 36
in.).
[0022] From Figure 3, those skilled in the art will appreciate that a dramatic increase
in lead's dissolution rate (that is, the rate at which lead dissolved into the molten
media) resulted when the spark cup immersion depth was increased from 12.7 to 15 cm
(5 to 6 inches). It will be noted that further increases in immersion depth did not
seem to have much of an effect upon the dissolution rate. Similarly, in Figure 4,
it can be seen that actual recovery in percentages increased dramatically when the
immersion depth was increased from 10 to 15 cm (4 to 6 inches). Moreover, further
increases in the immersion depth showed further increases in actual recovery; however,
not nearly as dramatic as those that occurred from 10 to 15 cm (4 to 6 inches). Actual
recovery was measured by optical emission spectroscopy. Metallographic examination
revealed that the particles of lead in the cast ingot were smaller, more acicular
shaped and more uniformly sized and dispersed than those added by conventional methods.
Moreover, it is believed that such ingot provided by the present invention has improved
machinability.
[0023] While the immersion depth providing enhanced dissolution and dispersion in accordance
with the present invention will vary with the material being added, bath size, bath
flow rate, alloy feed rate and size, inter alia, and will have to be determined for
each setup, those skilled in the relevant art will appreciate that the method and
apparatus of the present invention can result in greatly increased dissolution rates,
particularly for alloy material with limited solubility, such as lead, bismuth and
tin and for high oxidizable materials such as magnesium and zinc.
[0024] Those skilled in the art will also appreciate that the present invention is amenable
to continuous casting processes. Continuous casting processes are those that permit
the continual flow of metal from a melting furnace into a casting mold. Since continuous
casting usually proceeds at a uniform rate, it will be easy to calculate the desired
alloy feed rate with the method of the present invention. The invention, however,
is particularly amenable to continuous casting processes wherein the casting rate
varies. Suitable instrumentation can be installed on the casting line to detect any
changes in the casting rate which can then be used to make adjustments in the alloy
feed rate.
1. A process for adding material to a molten metal media comprising the steps of:
(a) providing a body of molten media;
(b) providing a chamber means having an open discharge end positioned within said
media body;
(c) supplying said chamber means with a gas comprising an ionizable gas under sufficient
pressure to maintain an interior molten media surface substantially at said chamber's
discharge end region;
(d) supplying said material to a site within said chamber above said interior molten
media surface;
(e) conducting an electric arc between said material at said site and said interior
molten media surface and maintaining a plasma substantially extending from said site
within said chamber to said interior molten media surface; and
(f) maintaining said plasma at a sufficient energy to convert said material into a
superheated spray substantially within said plasma projected toward said interior
molten media surface;
(g) said supplying of said gas to said chamber being of sufficient rate to project
said material into said media so as to enhance entry of said material into said media.
2. A process according to claim 1, in which the chamber means is elongate and has
an upper inlet, at least a portion of which is located above the upper surface of
the molten media, the material being fed into the chamber through said inlet, and
the interior surface of the body of molten media being maintained at a depth below
said exterior surface such that at least 50% of material being added to the molten
media is recovered in the molten media.
3. A process according to claim 1 or 2, wherein said interior molten media surface
is maintained at a predetermined depth below the upper surface of the molten media,
said depth being sufficient to enhance dissolution and dispersion of the material
into said media.
4. A process according to any one of the preceding claims, wherein substantial heat
is transmitted to the molten media through the chamber portion submerged in the media.
5. A process according to any one of the preceding claims in which the molten media
comprises aluminum.
6. A process according to any one of the preceding claims in which the added material
is supplied to the chamber means in the form of solid wire or rod.
7. A process according to any one of the preceding claims in which the gas comprises
a nonreactive gas.
8. A process according to claim 7 in which the gas is seeded with at least one additive
to promote arc stability or oxygen scavenging.
9. A process according to any one of the preceding claims, in which the electric arc
is formed by a direct current.
10. A process according to any one of the preceding claims, in which the length of
the chamber along the direction of projection into the molten media exceeds the transverse
dimension of the chamber outlet.
11. A process according to any one of the preceding claims in which material added
comprises one or more of lead, bismuth, antimony, magnesium, zinc or copper.
12. A process according to any one of the preceding claims, in which the chamber means
is made from alumina, borosilicate, mullite or silica.
13. A process according to any one of the preceding claims, in which the molten media
is agitated to further enhance dispersion of the material within said media.
1. Verfahren zum Versetzen einer Metallschmelze mit einen Gut, mit folgenden Schritten:
(a) es wird ein aus einer Schmelze bestehender Körper gebildet;
(b) es wird eine Kammeranordnung geschaffen, die ein in der Schmelze offenes Austrittsende
hat;
(c) die Kammeranordnung wird mit einem Gas beschickt, das mindestens teilweise aus
einem ionisierbaren Gas unter einem so hohen Durch besteht, daß im wesentlichen in
dem Austrittsendbereich der Kammer eine innere Schmelzefläche aufrechterhalten wird;
(d) das genannte Gut wird einer in der Kammer oberhalb der inneren Schmelzefläche
gelegenen Stelle zugeführt;
(e) zwischen dem an der genannten Stelle befindlichen Gut und der inneren Schmelzefläche
wird ein Lichtbogen gezogen, und in der Kammer wird ein Plasma aufrechterhalten, das
sich im wesentlichen von der genannten Stelle bis zu der inneren Schmelzefläche erstreckt;
und
(f) des genannte Plasma wird mit einem so hohen Energiegehalt aufrechterhalten, daß
das genannte Gut in einen überhitzten Sprühnebel umgewandelt wird, der im wesentlichen
in dem Plasma zu der inneren Schmelzefläche vorgetrieben wird;
(g) die Kammer wird mit dem Gas in einer solchen Menge beschickt, daß durch den Vortrieb
des genannten Gutes in der Schmelze der Eintritt des genannten Gutes in die Schmelze
unterstützt wird.
2. Verfahren nach Anspruch 1, dadurch gekennzeichnet, daß die Kammeranordnung langgestreckt
ist und einen oberen Eintritt besitzt, der sich mindestens zum Teil oberhalb der oberen
Fläche der Schmelze befindet und durch den hindurch das Gut in die Kammer eingeleitet
wird, und daß die innere Fläche des aus der Schmelze bestehenden Körpers in einer
solchen Tiefe unterhalb der genannten oberen Fläche gehalten wird, daß mindestens
50% des der Schmelze zugesetzten Gutes in dieser gewonnen wird.
3. Verfahren nach Anspruch 1 oder 2, dadurch gekennzeichnet, daß die innere Schmelzefläche
in einer solchen vorherbestimmten Tiefe unter der oberen Schmelzefläche gehalten wird,
daß das Auflösen und Dispergieren des Gutes in der Schmelze unterstützt wird.
4. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
über den in der Schmelze untergetauchten Kammerteil der Schmelze eine beträchtliche
Wärmemenge zugeführt wird.
5. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
die Schmelze mindestens teilweise aus Aluminium besteht.
6. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
das zuzusetzende Gut der Kammeranordnung in Form von massivem Draht- oder Stabmaterial
zugeführt wird.
7. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
das Gas mindestens teilweise aus einem reaktionsunfähigen Gas besteht.
8. Verfahren nach Anspruch 7, dadurch gekennzeichnet, daß das Gas mit mindestens einem
Zusatzstoff geimpft wird, um den Lichtbogen zu stabilisieren oder Sauerstoff zu entfernen.
9. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
der Lichtbogen mit Gleichstrom erzeugt wird.
10. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
die Länge der Kammer in der Richtung des Vortriebes in die Schmelze größer ist als
die Querabmessung am Austritt der Kammer.
11. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
das hinzuzufügende Gut mindestens teilweise aus einer oder mehreren der nachstehenden
Substanzen besteht: Blei, Wismut, Antimon, Magnesium, Zink oder Kupfer.
12. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
die Kammeranordnung aus Aluminiumoxid, Borsilikat, Mullit oder Siliciumdioxid besteht.
13. Verfahren nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, daß
zum weiteren Unterstützen des Dispergierens des Gutes in der Schmelze diese bewegt
wird.
1. Procédé d'addition d'un matériau dans un milieu métallique en fusion, dans lequel:
(a) on prépare une masse de milieu en fusion;
(b) on met en place une chambre comportant une extrémité d'évacuation ouverte, disposée
dans cette masse de milieu;
(c) on introduit, dans la chambre, un gaz comprenant un gaz ionisable, sous une pression
suffisante pour maintenir une surface intérieure du milieu en fusion, à peu près au
niveau de la partie d'extrémité d'évacuation de la chambre;
(d) on introduit le matériau dans la chambre, au niveau d'une zone située au-dessus
de la surface intérieure du milieu en fusion;
(e) on établit un arc électrique entre le matériau au niveau de ladite zone et de
la surface intérieure du milieu en fusion, et on maintient un plasma s'étendant à
peu près à partir de ladite zone dans la chambre jusqu'à la surface intérieure du
milieu en fusion; et
(f) on maintient le plasma à une énergie suffisante pour convertir le matériau en
un jet pulvérisé surchauffé, s'étendant à peu près dans le plasma en direction de
la surface intérieure du milieu en fusion;
(g) l'introduction du gaz dans la chambre, étant effectuée à une vitesse suffisante
pour projeter le matériau dans le milieu en fusion de façon à favoriser la pénétration
du matériau dans ce milieu.
2. Procédé selon la revendication 1, dans lequel la chambre est allongée et comporte
un orifice d'entrée supérieur, au moins une partie de celle-ci étant située au-dessus
de la surface supérieure du milieu en fusion, le matériau étant introduit dans la
chambre, à travers l'orifice d'entrée, et la surface intérieure de la masse de milieu
en fusion étant maintenue à une profondeur située en-dessous de la surface extérieure,
de telle façon qu'au moins 50% du matériau additionné dans le milieu en fusion, soient
récupérés dans le milieu en fusion.
3. Procédé selon la revendication 1 ou 2, dans lequel la surface intérieure du milieu
en fusion, est maintenue à une profondeur prédéterminée sous la surface supérieure
du milieu en fusion, cette profondeur étant suffisante pour favoriser la dissolution
et la dispersion du matériau dans ce milieu.
4. Procédé selon l'une quelconque des revendications précédentes, dans lequel une
quantité importante de chaleur est transmise au milieu en fusion, à travers la partie
de la chambre, immergée dans le milieu.
5. Procédé selon l'une quelconque des revendications précédentes, dans lequel le milieu
en fusion, comprend de l'aluminium.
6. Procédé selon l'une quelconque des revendications précédentes, dans lequel le matériau
additionné, est introduit dans la chambre sous la forme d'un fil ou d'une tige plein.
7. Procédé selon l'une quelconque des revendications précédentes, dans lequel le gaz
comprend un gaz non réactif.
8. Procédé selon la revendication 7, dans lequel on disperse dans le gaz au moins
un additif destiné à favoriser la stabilité de l'arc ou l'absorption de l'oxygène.
9. Procédé selon l'une quelconque des revendications précédentes, dans lequel l'arc
électrique est formé à partir d'un courant continu.
10. Procédé selon l'une quelconque des revendications précédentes, dans lequel la
longueur de la chambre, le long de la direction de projection dans le milieu en fusion,
est supérieure à la dimension transversale de l'orifice de sortie de la chambre.
11. Procédé selon l'une quelconque des revendications précédentes, dans lequel le
matériau additionné, comprend un ou plusieurs éléments choisis parmi le plomb, le
bismuth, l'antimoine, le magnésium, le zinc et le cuivre.
12. Procédé selon l'une quelconque des revendications précédentes, dans lequel la
chambre est réalisée en alumine, en borosilicate, en mullite ou en silice.
13. Procédé selon l'une quelconque des revendications précédentes, dans lequel le
milieu en fusion est agité pour favoriser encore la dispersion du matériau dans le
milieu.