Magnetic field stabilized transferred arc furnace

A DC electric arc furnace utilizing a magnetic field stabilized electric arc. A DC magnetic field is employed to cause rotation and angular deflection of the electric arc about the surface of the melt. In one embodiment the DC magnetic field is induced by a field coil. In an alternate embodiment a specially shaped electrical insulating member can be positioned in the melt so that the flow of arc current through the melt creates a magnetic field which is used to cause arc rotation. In a further embodiment a plurality of coil sets are located about the periphery of the furnace are used in conjunction with current reversing and current sequencing means to create a rotating DC magnetic field which is used to rotate the arc. A ceramic electric insulator can also be supplied in the chamber of the furnace to prevent arc fixation in the region wherein the DC magnetic field is substantially parallel to the flow of arc current. Another embodiment utilizes a center insulator having an arm radially extending arm to the sidewall. Current flow through the melt to an electrode therein creates a magnetic field for precession of the arc. The arm prevents reversal of current flow in the melt to assure unidirectional arc precession. A split-ring electrode having an insulating ceramic insert can also be used in place of the center insulator and arm to produce precession.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to a DC electric arc furnace for the heating and 
melting of materials. 
2. Description of the Prior Art 
In certain metallurgical applications it is advantageous to use a DC 
electric arc furnace in which the electric arc is transferred either to an 
electrode, typically the anode, located close to the material to be heated 
or melted or to the material itself. One application is where metallic 
oxides are used in these furnaces. In practice, carbon is added for their 
reduction and valuable metals are produced as a result of the electric arc 
reducing the melt, i.e., the material in the furnace to be melted. A 
stationary attachment of the arc to the reacting melt layer would produce 
strong temperature non-uniformities in the melt, and consequently, locally 
varying rates of reaction and possibly local failure of the refractory 
wall of the furnace. Non-uniformity of the product or product quality and 
possible disruption of the process may also be a consequence. 
Various attempts have been made to prevent the stationary attachment of the 
arc to the material being heated. In U.S. Pat. No. 4,154,972, movement of 
the arc about the surface of the material to be melted was attempted by 
the precession of the arcing electrode. This furnace has the disadvantage 
that the arc motion is controlled at the arcing electrode whereas control 
of the motion of the arc at the arc attachment surface or the melt itself 
is desired. With this scheme, if the arc or the arc attachment at the melt 
is exposed to any disturbance the control of the arc motion is diminished. 
In U.S. Pat. No. 4,110,546, a rotating magnetic field generated by a 
variable frequency AC source is used to angularly deflect and rotate the 
arc within the furnace enclosure. There the melt forms the anode and the 
arcing electrode is the cathode in the DC circuit. By increasing the 
frequency of the AC supply to the coils, the speed of rotation of the arc 
is increased. A disadvantage with this arrangement is that both an 
expensive variable frequency AC power supply and a DC power supply must be 
provided to the furnace. 
SUMMARY OF THE INVENTION 
The present invention is a DC electric arc furnace utilizing a DC magnetic 
field to stabilize and precess the arc existing between the arcing 
electrode and the melt. The DC magnetic field is positioned such that the 
maximum interaction between the magnetic lines of flux thereof and the 
current flowing in the arc occurs at the point of arc attachment on the 
arc attachment surface or the melt. This point of arc attachment is termed 
the arc root. This interaction of the magnetic field and the arc current 
flowing through the arc root can produce rotation of the arc root due to 
the Lorentz force, the maximum force being generated when the magnetic 
field lines are in a direction perpendicular to the flow of arc current. 
Various means are employed in the present invention to generate this DC 
magnetic field. In one embodiment of the invention, a field coil having 
multiple turns of wire is provided beneath the bottom of the furnace 
chamber. In a second embodiment of the invention, sets of field coils are 
disposed about the periphery of the furnace chamber. Each set is comprised 
of two coils connected in series and is connected to a current reversing 
means and a current switching means such that a rotating DC magnetic field 
may be created by these coil sets. A third embodiment of the invention 
utilizes the flow of current through the melt to generate the required 
magnetic field. There an electrical insulating member is provided in the 
melt to ensure that the current flow therethrough is in only one 
direction. 
With the first two embodiments of the invention, an electrical insulating 
means can be provided at the point of minimum Lorentz force, i.e., where 
the magnetic field lines being substantially parallel to the flow of arc 
current. This insulating means is used to prevent arc fixation in this 
region due to the lack of available rotative force with which to move the 
arc. The insulating means may be further modified to include a core of 
highly magnetically permeable material. The purpose of the core is to 
strengthen and focus the magnetic field lines to cause the angular 
deflection of the arc from the longitudinal axis of the arcing electrode. 
The permeable core and the insulating means may be of any shape. However, 
the minimum radial dimension of the insulating means should correspond to 
a distance from the point of minimal Lorentz force, typically, about the 
vertical center line of the chamber, to a point on the plane formed by the 
arc attachment surface where the Lorentz force created by the interaction 
of the magnetic field and the current flowing at the arc root is 
sufficient to maintain the continual rotation of the arc root about a 
closed path on the arc attachment surface. Smaller radial dimensions for 
the electrical insulating means can result in arc fixation. 
Positioning means may also be supplied for the field coils and for the 
arcing electrode. When employed, these means provide for variation in the 
arc path and the arc length, respectively. The DC power means which is 
used for the furnace may also be adjustable. In addition, the same power 
supply may be used for both the field coils and the arcing electrodes or 
they may each have their own separate DC power supply. Further 
modifications of the present invention include the use of feed means for 
delivering material to charge the furnace and melt collection means for 
the removal of the heated or melted material from the furnace chamber.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The DC electric arc furnaces embodying the present invention utilize a DC 
magnetic field to cause the precession of the electric arc inside the 
furnace chamber. The DC magnetic field is positioned so that it controls 
the motion of the arc at the arc attachment surface and not at the tip of 
the arcing electrode. Referring now to FIG. 1, a DC electric arc furnace 1 
is shown having a chamber 2 in which the material to be heated or melted 
M, known as melt, is contained. Disposed with the chamber 2 is an arcing 
electrode 3, the arcing electrode 3 being in communication with the 
interior of the chamber 2. An arc attachment surface 4 is provided in the 
interior of the chamber 2. This arc attachment surface 4 can be formed by 
either the melt M or an electrode. If an electrode is provided for this 
purpose, typically, an annular graphite or an annular internally 
water-cooled copper electrode is used with this electrode being positioned 
in or proximate the melt M. As shown schematically in FIG. 1, a DC power 
supply 5 is electrically connected to the arcing electrode 3 and the arc 
attachment surface 4. The DC power supply 5 is used to establish a 
potential between the arcing electrode 3 and the arc attachment surface 4 
and for providing current for flowing in an electrical arc 6. The electric 
arc 6 is established between the arcing electrode 3 and the arc attachment 
surface 4 by conventional arc starting means (not shown) such as a fusible 
link or by decreasing the gap between the tip of the arcing electrode 3 
and the arc attachment surface 4. 
The electric arc 6 allows current to flow through the arcing electrode 3 
and the arc attachment surface 4. The point of electric arc attachment 
upon the arc attachment surface 4 is termed the arc root 7. The current 
flowing in the electric arc 6 is designated I.sub.A. The direction of 
current flow is dependent upon the connection of the arcing electrode 3 
and the arc attachment surface 4 to the DC power supply 5. Preferably, the 
arcing electrode 3 is the cathode and the arc attachment surface 4 is the 
anode. When the furnace 1 is in operation, the electric arc 6 heats or 
melts the melt M at the arc root 7. 
The electrode 3 may be either a conventional graphite electrode or a 
non-consumable electrode as disclosed in U.S. Pat. Nos. 3,530,223; 
3,561,029; and 3,680,163, each of these patents being assigned to the 
present assignee of the instant invention. These non-consumable electrodes 
are water-cooled and utilize an electrode tip coil to rotate the arc over 
the tip of the electrode to prevent tip erosion due to localized 
overheating caused by the electric arc. When the arcing electrode is 
connected as the cathode preferably the tip of the electrode is made of a 
thermionically emitting material such as tungsten. 
A field coil 8 is disposed with the chamber 2 such that a magnetic field F 
induced by the flow of DC current through the field coil 8 interacts with 
the electric arc 6 at the arc root 7 to cause the precession of the 
electric arc 6 over the arc attachment surface 4. Various configurations 
for the field coil are possible. Typically, the field coil is an annular 
ring having an outer diameter generally corresponding to the outside 
dimensions of the chamber 2. 
Preferably, the arcing electrode 3 is mounted on the top of the chamber 2 
and has its longitudinal axis substantially parallel to the vertical 
center line of the chamber 2. Also the arc attachment surface 4 is 
positioned in the interior of the chamber 2 proximate the bottom thereof 
and is substantially perpendicular to the vertical center line of the 
chamber 2. This arrangement of the arcing electrode 3 and arc attachment 
surface 4 is shown in FIGS. 1 and 2. With this arrangement, the field coil 
8 is located beneath the chamber 2 and is also substantially perpendicular 
to the vertical center line of the chamber 2. As shown in FIGS. 1 and 2, 
the field coil 8 may be provided with conventional positioning means 9 to 
allow the axial positioning of the field coil 8 with respect to the bottom 
of the chamber 2 as indicated by the double headed arrow. This arrangement 
allows the point of interaction between the induced magnetic field F of 
the field coil 8 and the electric arc 6 to be axially adjusted within the 
furnace, this point of interaction being dependent upon the level of the 
melt M contained within the chamber 2. 
In FIG. 1, an electrical insulating member 10 is provided within the 
chamber 2 proximate the arc attachment surface 4. The electrical 
insulating member 10 is located in the region where the magnetic field F 
from the field coil 8 is substantially parallel in direction to the 
current IA flowing in the electric arc 6. The electrical insulating member 
10 is used to prevent the formation of the electric arc 6 between the 
arcing electrode 3 and the arc attachment surface 4 in the central region 
of the melt M; thereby, avoiding arc fixation in this region of minimal 
rotative force. Another effect of the electrical insulating member 10 upon 
the electric arc 6 is that the electric arc 6 is angularly deflected from 
a line which passes through the longitudinal center line of the arcing 
electrode 3 and which is also perpendicular to the arc attachment surface 
4. This angular deflection of the electric arc 6 also helps to prevent arc 
fixation. 
Preferably, the electrical insulating member 10 is positioned at the bottom 
of the interior of the chamber 2 along a line substantially parallel to 
the vertical center line of the chamber 2, with the electrical insulating 
member 10 also being in alignment with the longitudinal axis of the arcing 
electrode 3. The electrical insulating member 10 extends in a generally 
upward direction from the bottom of the chamber 2, a distance which is 
above the plane formed by the surface of the melt M or the arc attachment 
surface 4; whichever is greater. The minimum radial dimension R of the 
electrical insulating member 10 corresponds to a distance from the 
vertical center line of the chamber 2 to a point on the plane formed by 
the arc attachment surface 4 where the force created by the interaction of 
the applied magnetic field F and the current I.sub.A flowing at the arc 
root 7 is sufficient to maintain the continual rotation of the arc root 
about a closed path, usually circular, on the arc attachment surface 4. 
The electrical insulating member 10 is normally constructed of a ceramic 
material in order to withstand the high temperatures encountered within 
the chamber 2 of the electric arc furnace 1. 
Shown in FIG. 2 is an alternate embodiment for the insulating member. There 
the electrical insulating member 12 is provided with a highly permeable 
magnetic core 14. In this arrangement, the electric insulating member 12 
has an exterior insulating portion 16 in contact with the melted material 
and a passageway 18 therein for receiving the highly permeable core member 
14. The core member 14 may extend through a passageway 20 provided in the 
bottom of the chamber 2. This external portion of the core member 14 can 
extend into the central opening 11 of the field coil 8 and is used to 
strengthen the magnetic field lines in a direction radially outward from 
the vertical center line of the chamber 2; thus, aiding in the angular 
deflection of the electric arc 6 from the vertical center line as well as 
in the precession of the arc root 7. Also, positioning means 19 for 
adjusting the distance between the melt M and the tip of the arcing 
electrode 3 can be provided. 
The magnetic field F which is used to rotate the arc root 7 may also be 
induced by the use of a plurality of coil sets 30 as shown in FIGS. 3A, 
3B, and 4. Each coil set 30 has at least two coils electrically connected 
in series and being diametrically disposed opposite one another about the 
periphery of the chamber means 2. For example, where three coil sets are 
used, as shown in FIGS. 3B and 4, coil sets 30A, 30B and 30C are comprised 
of coils 30-1 and 30-4, 30-2 and 30-5, 30-3 and 30-6, respectively. These 
coil sets are electrically connected to a current reversing means 32 and a 
current sequencing means 34. In a continuing sequence, the DC current is 
applied to coil set 30-A through coils 30-1 and 30-4. These coils are then 
removed from the DC current source by the current sequencing means 34 and 
the current directed to coil set 30-B through coils 30-2 and 30-5. In 
turn, this coil set is removed from the DC source through the sequencing 
means 34 and the current applied to coil set 30-C through coils 30-3 and 
30-6. At this point the direction of current flow through the coil sets is 
reversed via the current reversing means 32 and the current is applied to 
coil set 30-A through coils 30-4 and 30-1, respectively, the current is 
then removed from this coil set via the sequencing means 34 and 
sequentially connected to coil sets 30B and 30C in a similar manner. This 
continuing sequence creates a rotating DC magnetic field. The direction of 
current flow through the coil sets is reversed so that the direction of 
arc root rotation within the chamber is maintained in the same direction. 
The speed of rotation of the DC magnetic field is controlled by the speed 
of sequencing the coil sets. If the DC magnetic field is rotated too 
rapidly the arc will not follow the movement of the field. Therefore, the 
speed of rotation of the DC magnetic field is maintained such that the 
electric arc will follow it with a minimum of velocity modulation. 
Again, positioning means (not shown) for these coil sets may also be 
provided. Here the coils may be adjustable axially and radially, so that 
the furnace may be able to accommodate various levels of melt M therein 
while being able to maximize the interaction of the magnetic field and the 
arc current. The electrical insulating member can also be provided. The 
sequencing means 34 can use electro-mechanical contactors or switches or 
solid-state electronic switches. 
In FIGS. 5 and 6, another embodiment of the present invention is 
illustrated. There the arcing electrode 3 is disposed with the chamber 2 
and is in communication with the interior portion thereof, the 
longitudinal axis of the arcing electrode 3 being positioned in a line 
substantially parallel to the vertical center line of the chamber 2. The 
arc attachment surface 4 is located proximate the bottom of the interior 
of the chamber 2 and is formed by the melt M. A connector 40 is disposed 
with the chamber 2 and is also in communication with the interior portion 
thereof. The connector 40 is in electrical connection with the melt M and 
is in a radially offset position from the vertical center line of the 
chamber 2. A DC power supply 5 is electrically connected to the arcing 
electrode 3 and the connector 40 creating a potential between the arcing 
electrode 3 and the arc attachment surface 4, i.e., the surface of the 
melt M, and provides current I.sub.A for flowing through an electric arc 6 
formed therebetween. This current further flows through the melt M to the 
connector 40 inducing a magnetic field which interacts with the current 
flowing in the electric arc at the arc root 7. The direction of the 
magnetic flux of this induced magnetic field is substantially transverse 
to the direction of current flow at the arc root 7, thereby, creating a 
force which acts to rotate the electric arc root 7 about a closed path on 
the surface of the melt M. 
An electrical insulating member 42 is also provided on the bottom of the 
chamber 2. This electrical insulating member 42 has a columnar portion 44 
and a radially extending arm 46 with the height H of the insulating member 
being higher than the arc attachment surface 4 of the melt M. The columnar 
portion 44 is positioned along the line substantially parallel to the 
vertical center line of the chamber 2 and has a minimum radial dimension 
R' corresponding to a distance from the vertical center line to a point on 
the arc attachment surface 4 of the melt M where the force created by the 
interaction of the magnetic field induced by the flow of current through 
the melt M and the current in the electric arc 6 at the arc root 7 is 
sufficient to maintain the continual rotation of the arc root 7 about a 
closed path on the arc attachment surface 4 of melt M. The arm 46 extends 
between the columnar portion 44 and an interior wall of the chamber 2. The 
thickness T of the arm 46 is such that the flow of current cannot occur 
therethrough while also allowing the electric arc 6 to cross over or jump 
the arm 46 without being extinguished. This arm 46 is located adjacent the 
connector 40 so that the current flowing through the material will be in 
only one direction. 
In FIG. 5, two points, A and B, are indicated to show various positions of 
the arc root 7 as it rotates about the arc attachment surface 4 of the 
melt M. Because current tends to flow in the path of least resistance and 
assuming essentially uniform resistivity of the melt M, it can be seen 
that the current flowing from the connector 40 through the melt to point B 
would be opposite in direction from the current flowing from the connector 
40 through the melt M to point A. If the arm 46 were not present, the 
current would flow from the connector 40 directly to point B through the 
shortest path available causing a reversal in the current flow. This in 
turn reverses the direction of the DC magnetic field which is induced as a 
result of the current flowing through the melt M, thus, causing a reversal 
in the rotation of the arc root 7. With the insertion of the electrically 
insulating arm 46 between point B and the connector 40, current is usable 
to flow along this path. Because of the electrical insulating arm 40, the 
current at point B flows from the connector 40 in the same direction as 
the current flowing to point A thereby maintaining the rotation of the arc 
in the same direction. In this embodiment, rotation of the electric arc 6 
at the arc root 7 on the arc attachment surface 7 of the melt M is 
obtained without the use of field coil. Again, the arcing electrode 3 may 
be of the types previously described hereinabove. 
The insulating member having the radially extending arm as shown in FIGS. 5 
and 6 can be replaced with the split ring electrode 48 shown in FIG. 7 
without effecting the operation of the furnace. The split ring electrode 
48 which forms the arc attachment surface has an annular shape having an 
outer diameter which is less than the interior dimension of the chamber 
and is constructed of an electrically conductive material having a 
resistivity which is less than that of the melt. A graphite or 
water-cooled copper electrode may be used. A gap 50 is provided between 
the ends of the split ring electrode 48 with the ends being adapted to 
receive and hold an electric insulator 52. The insulator 52, usually 
ceramic, preferably has the same cross-sectional shape as the split-ring 
electrode 48, and serves the same function as the radially extending arm 
46. Accordingly, the electric insulator 52 is dimensioned such that the 
electric arc can jump or cross the insulator without being extinguished, 
yet prevents the flow of current to the connector 40 across the gap 50. 
The gap 50 and insulator 52 are positioned proximate connector 40 in order 
to maintain current flow in one direction about the split-ring electrode 
48. Again the connector 40 is radially offset from the vertical center 
line of the chamber in order to make electrical connection with the 
split-ring electrode 48. The preferred location for this electrode is a 
short distance above the melt M in a plane substantially perpendicular to 
the vertical center line of the chamber. The current flowing through the 
split-ring electrode 48 to the connector 40 induces a DC magnetic flux 
field which causes the rotation of the arc root about the surface of the 
split-ring electrode 48. 
Feed means and melt collection means (not shown) can also be provided with 
the various embodiments of the present invention. Both means are in 
communication with the interior of the chamber 2 for the charging and 
removal of material, respectively. Where the field coils are used, any 
shape may be used for these coils; with an annular shape being preferred. 
The distance between the coil means and the arc attachment surface is 
typically made as close as possible, however, this distance is adjustable. 
The field coils can be separate from the chamber or can be incorporated in 
the structure thereof. In addition, the DC power supply for the arcing 
electrode and arc attachment surface may be separate from the DC power 
supply used to energize the field coils. The DC power supply can also be 
made adjustable through conventional techniques. With all the embodiments 
of the present invention, the arcing electrode is normally connected as 
the cathode with the arc attachment surface being the anode; however, this 
may be reversed without affecting the operation of these furnaces. 
It should also be understood that the furnaces of the present invention can 
be operated at atmospheric conditions. In addition, either a vacuum or a 
reducing atmosphere employing an inert gas such as argon or a hydrogen 
carbon monoxide mixture can also be used. For example, where only clean 
melting is desired, an argon atmosphere can be employed. Whereas, for the 
production of oxides, the hydrogen/CO mixture can be used. 
The present invention as exemplified by the above embodiments has the 
advantage of controlling the rotation of the electric arc at the surface 
of the melt by use of only a DC power supply. This eliminates the need to 
provide the AC power supply or complex mechanical devices utilized in the 
prior art designs. A further advantage is that because the arc rotation is 
controlled at the melt surface irregularities of the melt do not diminish 
control of the arc movement thus avoiding problems including arc fixation, 
temperature nonuniformities, or refractory failure.