Information
-
Patent Grant
-
6473446
-
Patent Number
6,473,446
-
Date Filed
Wednesday, December 13, 200024 years ago
-
Date Issued
Tuesday, October 29, 200222 years ago
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Inventors
-
Original Assignees
-
Examiners
Agents
-
CPC
-
US Classifications
Field of Search
US
- 373 71
- 373 72
- 373 73
- 373 74
- 373 75
- 373 76
- 373 77
- 373 78
- 373 79
- 373 81
- 373 83
- 373 84
- 266 44
- 266 196
- 266 200
- 266 236
- 075 1012
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International Classifications
-
Abstract
An electric furnace includes a stationary lower shell having a sloping floor extending downwardly to a tap hole to always maintain a sufficient ferrostatic head three times the tap hole for slag free tapping. The configuration of the refractory for containing a heat, is sufficient to maintain a liquid metal heel of at least 70% of the heat before tapping for maintaining flat bath operation during refining a steel melt. An upper furnace shell is supported on the lower furnace shell and a furnace roof is supported by the upper furnace shell. The entire furnace is mounted on a furnace transfer car that is anchored for stationary operation but moved to a furnace exchange position for servicing any of the components making up the furnace. The furnace roof and/or upper furnace shell may be supported at a furnace operate position while the lower furnace shell is transported to the furnace exchange position.
Description
CROSS REFERENCE TO RELATED APPLICATION
Not applicable.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a steel making furnace using electrical current as a heat source and, more particularly, to such a furnace designed and constructed to remain statically positioned through consecutive furnace cycles each cycle being characterized by always maintaining a sufficient large wet heel for flat bath operation through charging and slag free tapping.
2. Description of the Prior Art
It is known in the art of steel making to use electric current as a heat source in a steel making furnace. Arc heating furnaces are used to heat a metal charge by either heat radiation from arcs passed between electrodes above the metal charge or by arcs passing from the electrodes to the metal charge where heat is generated by the electrical resistance of the metal charge. When the furnace has an electrically conductive furnace bottom, the bottom forms part of an electrical circuit powered by direct current. When the furnace has a non-conductive furnace bottom, the electrical circuit is powered by alternating current and the circuit is limited to the electrodes and metal charge. Induction furnaces are also used to heat a metal charge by using either inductors according to a transformer principle where the secondary winding is formed by a loop of liquid metal in a refractory channel or a coreless principle where induction coils surround the furnace wall and generate a magnetic field to impart energy to the metal charge in the furnace.
The present invention is applicable to such electric furnaces and in particular to an alternating current direct arc electric furnace equipped with three electrodes powered by three phase alternating current to establish arcs passed from an electrode to a metal charge to another electrode and from electrode to electrode. The direct-arc electric-furnace as used in the steel industry is primarily a scrap-melting furnace, although molten blast-furnace iron and direct-reduction iron (DRI) are also used for charging the furnace. Combinations of scrap and minor quantities of blast furnace iron or direct reduction iron are common furnace charging compositions. A three-phase transformer, equipped for varying the secondary voltage, is used to supply electrical energy at suitable range of power levels and voltages. Cylindrical solid graphite electrodes are suspended by a mechanism from above the furnace downwardly through ports in a furnace roof to positions so that the electrodes conduct the electric current inside the furnace to maintain arcs for melting and refining a furnace charge. A side wall supports the roof on a lower shell which is provided with a refractory lining to contain the metal charge. The lower shell is pivotally support on a foundation and a furnace tilting drive is operated to tilt the furnace in each of opposite directions for de-slagging and tapping. Other drive mechanisms are provided to remove the roof from the upper shell to gain access to the furnace interior for the introduction of a metal charge.
The tonnage of liquid metal that can be refined in such tilting furnaces is limited by the load bearing capacity of the pivotal support and the furnace tilting drive and the practical limits of the geometry of the hearth. The pivotal support and the tilting drive must take the form of robust structures to sustain and pivot the weight of the entire furnace and its content of liquid steel and slag. The geometry of the hearth when tilting the furnace to tap steel and to clear the tap gate for sand cleaning of the tap hole adds stresses to the pivotal support and tilting drive that increase significantly with an increase to the furnace tilt angle. The tilting of the furnace must be sufficiently slow and carefully controlled to avoid erratic eccentric loading on the tilting mechanism due to the wave like shock loading as the liquid steel shifts back and forth in the volume of the hearth of the furnace. The drive mechanism and support structure to tilt the electric furnace represents a significant capital expenditure. Costs are also incurred by the required maintenance to prevent a serious consequence should the tilt structure fail to allow draining of the heat from a furnace. The practical limits of the geometry of a tilting furnace hearth limit the depth of steel above the tap hole and therefore limit the maximum diameter of the tap hole that can be used and still have slag free tapping. This small size tap hole results in longer tapping times. Draining most of the steel from the furnace prolongs the time between tapping of the furnace because of the need to reestablish a liquid metal bath using significant quantities of electric power for the heating the metal charge. It is known in the art to retain a quantity of the steel in the furnace after tapping which is commonly called a wet heel practice. However, the structural integrity of the furnace mandates that the slag line be inspected periodically, typically every three to twelves heats with repairs performed based on the slag line condition. Generally, gunning will be performed several times a week. Periodically, every two-three weeks, the complete furnace bottom will be exchanged with a newly rebuilt bottom and worn bottom will have its side walls in the slag line area undergo a major repair.
Accordingly, it is an object of the present invention to provide an electric furnace suitable for use in a green field installation, to revamp existing installations to form a steel making facility for supply of ladles of steel at temperatures and tonnages significantly greater than provided by known electrically heated furnaces.
It is another object of the present invention relates to a steel making method and furnace construction to improve electric furnace operating efficiency and steel making capacity of an electric furnace.
It is a further object of the present invention to provide a versatile electric furnace design to simplify furnace maintenance and to maintain a large liquid metal hot heel for promoting flat bath operation and slag free tapping of a heat.
BRIEF SUMMARY OF THE INVENTION
According to the present invention there is provided an electric furnace for steel making, the furnace including the combination of a lower furnace shell stationarily supported during charging, heating and tapping of a heat, the lower shell having a floor wall with a sloping contour to increase a liquid metal depth of a heat to at least three times the diameter of a tap hole at a site communicating with the tap hole for slag free tapping of a heat, the lower furnace shell having a liquid metal capacity to maintain a liquid metal heel of at least 70% of a heat before tapping for flat bath refining of a heat throughout the charging and heating of a heat, an upper furnace shell supported by the lower furnace shell, a furnace roof supported by the upper furnace shell, an electrically powered member for heating a metal charge in the lower furnace shell, and a control including plugging for the tap hole to control tapping of a heat form the lower furnace shell. A lower shell stationarily supported during furnace operations consisting of charging, heating and tapping of a heat, the lower shell having a floor with a sloping contour to increase liquid metal depth at a site communicating with a tap hole for tapping of a heat, an upper shell supported by the lower shell, a roof supported by the upper shell, the roof including at least one aperture for passage of an electrode to heat a metal charge in the lower, shell, an electrode positioned by electrode carrier arm relative to the aperture for heating a metal charge in the lower shell, and a plug member operatively associated with the tap hole for maintaining a liquid hot heel in the lower shell after tapping of a heat.
Accordingly, the present invention also provides a method for producing steel in an electric furnace, the method of including the steps of providing an electric furnace including a furnace shell having a sloping floor extending downwardly to a tap hole refining a steel melt in the furnace using electric current to form a first heat, tapping a sufficient quantity of steel from the first heat to a ladle while the lower shell remains stationary to maintain a liquid hot heel in the furnace consisting of at least 70% of the tapped steel, maintaining flat bath furnace operation by using electric current and latent heat of the liquid hot heel to refine charged material in the furnace for forming a second heat, and tapping a sufficient quantity of steel from the second heat while the lower shell remains stationary to maintain a liquid hot heel in the furnace consisting of at least 70% of the tapped steel.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
The present invention will be more fully understood when the following description is read in light of the accompanying drawings in which:
FIG. 1
is a front view of an electric arc furnace installation embodying the features of the present invention;
FIG. 2
is a plan view of the electric arc furnace installation shown in
FIG. 1
;
FIG. 3
is a side elevational view of the electric arc furnace illustrated in
FIG. 1
;
FIG. 4
is a sectional view taken along lines IV—IV of
FIG. 3
;
FIG. 5
is a side elevational view similar to FIG.
3
and illustrating the suspension of the roof component for servicing of underlying furnace components at a lateral side of the furnace operating position;
FIG. 6
is a fragmentary view similar to
FIG. 5
illustrating suspension of each of the furnace roof and an upper shell for servicing of the at the lateral side of the furnace operating position;
FIG. 7
is an elevational view of electric arc furnace transfer car showing the drive and anchoring mechanism for controlling movement of the furnace between an operating position and an exchange position;
FIG. 8
is a plan view taken along lines VIII—VIII of
FIG. 3
;
FIG. 9
is a sectional view taken along lines IX—IX of
FIG. 8
;
FIG. 10
is a fragmentary elevational view taken along lines X—X of
FIG. 8
showing furnace position structure;
FIG. 11
is a plan view of the structure shown in
FIG. 11
;
FIG. 12
is a sectional view taken along lines XII—XII of
FIG. 8
;
FIG. 13
is a sectional view taken along lines XIII—XIII of
FIG. 8
;
FIG. 14
is a plan view of a modified location of a tap hole in the lower shell of the furnace shown in
FIG. 1
;
FIG. 15
is a sectional view taken along lines XV—XV of FIG.
14
.
FIG. 16
is a furnace cycle comparison between a tilting electric arc furnace and an electric arc furnace according to the present invention;
FIG. 17
is a time comparison between tapping a tilting electric arc furnace and tapping an electric arc furnace according to the present invention;
FIG. 18
is a side elevational view similar to FIG.
3
and illustrating the addition of a pouring tundish for introducing a charge of liquid metal in the electric arc furnace;
FIG. 19
is a plan view of a lower shell according the a second embodiment of the present invention;
FIG. 20
is a sectional view taken along lines XX—XX of
FIG. 19
;
FIG. 21
is a sectional view taken along lines XXI—XXI of
FIG. 19
;
FIG. 22
is a sectional view taken along lines XXII—XXII of
FIG. 19
; and
FIG. 23
is a sectional view taken along lines XXIII—XXIII of FIG.
19
.
DETAILED DESCRIPTION OF THE INVENTION
There is illustrated in
FIGS. 1-4
a direct arc electric furnace installation embodying the features of the present invention and useful for practicing the method of the invention. The installation includes an electric arc furnace
10
formed by a lower furnace shell
12
an upper furnace shell
14
and a furnace roof
16
. The furnace roof
16
includes roof panels formed by an array of side-by-side coolant pipes
20
with the coolant passageways communicating with annular upper and lower water supply headers
22
and
24
, respectively, interconnected by radial distributing pipes
26
to form a water circulating system communicating with service lines
28
containing water supply and return lines. The service lines
28
include a flexible section
30
to avoid the need to disconnect the service lines
28
when it is desired to lift the furnace roof alone or combined with the upper furnace shell a short distance, e.g., 24 inches, for servicing the lower shell. The upper water supply header
22
encircles a triangular array of three apertures
32
,
34
and
36
in a roof insert
38
. The apertures are dimensional and arranged to accept the phase A, B and C electrodes
40
,
42
and
44
and supported by electrode support arms
46
,
48
and
50
, respectively. Each of the electrode support arms
46
,
48
and
50
is independently positioned vertically by a support post
52
restrained by horizontally spaced guides
54
in a superstructure for vertical displacement by actuator
56
typical in the form of piston and cylinder assembly. The electrode support arms
46
,
48
and
50
support water cooled cables for transmission of electrical current from transformers in a transformer vault
58
to the respective phase A, B and C electrodes.
A fume duct
60
extends vertically from an annular opening in the furnace roof between the upper and lower water supply headers
22
and
24
for exhausting fumes from the interior of the furnace to an enlarged and vertically spaced duct and overlying duct
62
formed by water coolant piping to provide thermal protection. The duct
62
supplies the exhaust fume to an evaporator chamber and filter equipment, not shown, to recover pollutants.
As shown in
FIG. 4
, the lower peripheral surface of the lower water supply header
24
of the furnace roof
16
bears on a circular ring
64
at the upper edge of the upper furnace shell
14
forming a load bearing surface to support the roof
16
. Vertically extended lugs
66
at annular spaced apart intervals form lateral roof restraints for maintaining the desired superimposed relation of the furnace roof on the furnace upper shell
14
. The furnace upper shell includes superimposed convolutions of coolant pipe
68
supplied with coolant from spaced apart supply headers
68
A and
68
B that are inter connected by vertical distribution pipes
68
C to form a water circulating system communicating with service lines
68
D containing water supply and return lines. Metal panels may be supported by the coolant pipe
20
of the furnace roof and the coolant pipe
68
of the furnace upper shell for confinement of the fume to the interiors of these furnace components. The service lines
68
D include a flexible section
68
E to avoid the need to disconnect the service lines
68
D when it is desired to lift the furnace roof combined with the upper furnace shell a short distance, e.g., 24 inches, for servicing the lower shell. The convolutions of coolant pipe
68
are interrupted by a scrap charge opening
70
in one quadrant and a slag discharge opening
72
as shown in
FIG. 9
in an adjacent quadrant of the annular configuration of the furnace upper shell
14
. The scrap charge opening
70
is used to continuously introduce quantities of scrap at closely spaced apart intervals throughout the major portion of the furnace operating cycle and the scrap residing in a retractable chute
74
of a scrap charger
76
serves as a media to prevent unwanted escape of the fume from the furnace in the scrap charger. A bunker
78
is used in the preferred embodiment to supply scrap to the scrap charger
76
. It is within the scope of the present invention to introduce scrap to the furnace chamber using alternative well known charging equipment. The slag discharge opening
72
is extended outwardly from the coolant pipe
68
boarding the slag opening by an inverted “U” shaped arrangement of barrier walls
80
formed by a serpentine arrangement of coolant pipes A slag door
82
is supported by side rails
84
mounted on the coolant pipe
68
form a movable closure for a slag discharge trough
86
in the refractory lining of the lower furnace shell
12
. The slag door
82
is joined by control rods to actuator discs
88
which are rotated in a conventional manner to raise the slag door
82
and allow the discharge of slag from the furnace by trough
86
beyond a threshold formed by a carbon rod insert
90
which is supported by suitable brackets
92
on the lower furnace shell
12
.
As shown in
FIGS. 4
,
8
and
9
, the upper furnace shell
14
include a circular ring
94
forming a lower boundary to the shell except where a gap exists at the slag discharge opening
86
. Apertures in the circular ring
94
are provided at annular spaced locations to receive upstanding locator pins
96
on annular segments at opposite lateral sides of the lower furnace shell
12
. These annular ring segments are discontinuous at the slag discharge trough
86
and at a bottom crescent-shaped section protruding in an eccentric fashion from the annular configuration of the overlying upper furnace shell
14
. The crescent-shaped bottom section is enclosed by a correspondingly shaped crescent roof section
98
. The crescent-shaped roof is formed by a layer of coolant pipes. The crescent-shaped bottom section is used to provide eccentric furnace tapping and is combined with the construction and operation of the lower furnace shell to achieve the benefits of flat bath operation and slag free tapping.
Turning now to FIGS.
4
and
8
-
13
there is illustrated the configuration of the refractory face surfaces in the lower furnace shell
12
for supporting a metal charge during refining of a steel heat and providing eccentric bottom tapping of the steel heat. As seen in plan view of
FIG. 8
, there is annular side wall section
100
in an area bounded by a diameter
102
with a radius R
1
struck from the center of the diameter
102
. As seen in the sectional views of
FIGS. 4 and 9
, the annular vertical side wall section
100
is bounded by a spherically-dished floor wall section
104
defined by a radius R
2
struck form a point along a line defined by intersecting vertical planes
106
and
108
containing the center of the diameter
102
. Plane
108
coincides with diameter
102
and plane
106
forms a plane of symmetry of the configuration to the lower furnace shell. A floor wall section
110
begins at vertical plane
108
and proceeds away from the spherically-dished floor wall section
104
by a linear downward-sloping contour along plane
106
with an ever increasing radius RN of curvature transverse to plane
106
forming a rolled developed plate floor wall configuration. The ever increasing radius of transverse curvature of the floor wall section
110
results in an ever increasing height to the vertical side wall
112
as can be seen by from
FIGS. 9 and 12
. The vertical side wall sections
100
and
112
form a vertical boundary to the liquid metal surface commonly called a hot metal line
114
at the start of tapping a heat. At the conclusion of the tapping of the steel heat, there is a liquid heel line
116
formed by the upper surface of the steel heat and represents a reduction to the liquid metal depth at the diameter
102
typically slightly less than one-half of the depth of the steel heat than at the start of tapping. The downwardly sloping contour of floor wall section
110
along plane
106
and the increasing shallow curvature forming the rolled developed plate floor wall configuration transverse to plane
106
dramatically increases the liquid metal heel line
116
. It can be seen from
FIG. 9
that the vertical side wall
112
is of maximum height and merges with floor wall section
110
along plane
106
at the site of a tap hole assembly
118
. The tap hole has a central vertical axis
120
lying in the vertical plane
106
. The central vertical axis
120
also lies in a transverse vertical plane
122
which intersects with plane
106
by a right angle relationship. The furnace of the present invention is operated in a manner to always maintain a liquid heel depth, at the end of tapping, overlying the tap hole of at least three times the diameter of the tap hole during the useful life the tap hole ceramic discs. As shown in
FIGS. 8 and 9
, the tap hole assembly is formed by a superimposed stack of ceramic disks
124
mounted by a refractory sleeve in the refractory of the floor wall portion
110
. A truncated conical tap hole configuration and a correspondingly shaped stopper assembly may be provided according to the disclosure by German Patent No. 198 26 085.
At the conclusion of the tapping of a heat into an underlying ladle
126
supported by a transfer car, one of two tap hole stopper assemblies
128
A and
128
B is used to fill the tap hole with sand. The provision of two stopper assemblies
128
A and
128
B enable a quick change over from one assembly to the other as needed. The assemblies
128
A and
128
B each include a desired quantity of sand in a cardboard sleeve
130
which is inserted vertically into the tap hole with metal support parts being quickly consumed in the liquid metal heel and cardboard being consumed by the thermal temperature, thus releasing the volume of sand directly into the underlying tap hole. The sleeve
130
is lowered by a chain drive
132
mounted on a platform which is pivotal between an inoperative position and an operative positioned established by a stop member. In the operative position the sleeve
130
is lowered by the chain drive through an opening provided access door
134
, shown in
FIG. 9
, in the crescent-shaped roof section
98
along the central vertical axis
120
of the tap hole. After sand replaces the flow of steel emerging from the tap hole, one of two tap hole gates
136
A and
136
B is positioned by an actuator in a manner per se well known in the art to close off the aperture at the bottom of the tap hole assembly
118
. To provide an added measure for failsafe control of the tapping of a heat, an emergency tap hole closure mechanism
138
, as shown in
FIG. 9
includes a lever arm
140
with a tap hole closure plug
142
at one end and opposite thereto the arm is supported by a pivot shaft
144
secured to spaced apart brackets carried by the outer wall of the lower shell
12
. A piston and cylinder assembly
146
is a clevis mounted to the outer wall of the shell for pivotally displacing the closure mechanism
138
from a stand by position to a closure position. In the closure position, closure plug
142
seals off the tap hole with a sufficient force exerted by the piston and cylinder assembly to maintain the seal against the ferrostatic head.
The electric arc furnace
10
is statically supported continuously throughout repeated charging and tapping of heats and this feature of the present invention is utilized to maintain the central vertical axis
120
of the tap hole constant by the provision of furnace locator guide assemblies
148
,
150
,
152
and
154
which confine horizontal movement of the lower shell due to thermal expansions to only within vertical planes that intersect at the site of the central vertical axis
120
of the tap hole. The provision of the furnace locator guide assemblies maintains the tap hole at the same location so that the underlying ladle
126
receives taped heats repeatedly at the same location. The furnace locator guide assemblies also allow the cardboard sleeve
130
to be reliably lowered into the metal bath consistently along the central vertical axis
120
of the tap hole. The furnace locator guide assemblies
148
,
150
,
152
and
154
each embody the same construction of parts which as shown in
FIGS. 10 and 11
include a vertically arranged beam
156
secured to a lower shell
12
with a rectangular shoe plate
158
fitted for only linear sliding movement in a gap between spaced apart guide bars
160
. The guide bars
160
for each furnace locator guide assembly are secured to a support beam
162
forming part of a furnace support frame
164
. The furnace locator guide assemblies
148
and
150
cooperate to confine thermal expansion of the lower furnace shell
12
to the transverse vertical plane
122
by allowing only linear sliding movement of the rectangular shoe plates
158
between the guide bars
160
along the transverse vertical plane
122
which passes through the central vertical axis
120
of the tap hole. The furnace locator guide assemblies
152
and
154
cooperate to confine thermal expansion of the lower furnace shell
12
to the vertical plane
106
by allowing only linear sliding movement of the rectangular shoe plates
158
between the guide bars
160
along the vertical plane
106
which passes through the central vertical axis
120
of the tap hole. By this strategic location of the furnace locator guide assemblies, thermal changes to the lower furnace shell take place without altering the site of the central vertical axis of the tap hole.
An important feature of the present invention resides in the maintenance of a large heel after tapping a heat to facilitate the flat bath and slag free tapping operations of the furnace. Control elements for the operation of the furnace include the provision of a load cell
166
at each of a load transfer support site for the lower furnace shell
12
on a furnace support frame
164
which in the preferred embodiment of the present invention forms part of a furnace transfer car
168
. The support relationship between the lower furnace shell and the furnace car is shown in
FIGS. 1-3
and includes struts
170
joined to a vertical side wall of the lower shell. The strut is in load bearing contact with a load cell
166
mounted on the support beam
162
extending diagonally between side beams and end beams comprising the furnace support frame
164
. The furnace transfer car
168
is supported by wheels
172
for movement in a direction parallel to vertical plane
106
upon spaced apart rails
174
between a furnace operating position
176
as shown in
FIGS. 2 and 3
and a furnace component exchange position
178
. Bearings at opposite sides of each wheel provide rotatable support for the wheels. A winch
180
is provided with a cable
182
extending between spaced apart pulleys
184
and the ends of the cable connected to the end beams of the furnace support frame
164
. As shown in
FIG. 7
, the furnace car is anchored against stops
186
by ratchet binders
188
. The rails
174
are supported on spaced apart foundations that have an extended height that is sufficient to allow passage of a ladle
126
by a transfer car.
Referring to
FIGS. 5
,
6
and
7
, the furnace roof
16
, upper furnace shell
14
and lower furnace shell
12
will require periodic repairs but at widely varying time intervals. For example, it is likely that the bottom furnace shell will require repair of the refractory and relining of the refractory more frequently than the need to repair the furnace roof and upper furnace shell. The downtime of the furnace is an important economic factor and to minimize the downtime, the furnace roof is provided with lifting lugs
190
at spaced apart intervals about the upper periphery. The upper furnace shell is provided with lifting lugs
192
at spaced apart intervals about the upper periphery thereof The lower furnace shell is provided with lifting lugs
194
secured to the upper parts of the struts
170
. When it is necessary to service the lower furnace shell, the coolant supplies provided by service lines
28
and
68
D for the furnace roof and the upper furnace shell are turned off but the supply lines remain connected. The scrap charging chute
74
is retracted from charging opening
70
in the upper furnace shell. Strands of wire rope
196
are paid out from spools operated by a winch drive
198
. Each wire rope is secured to an upper shell lifting lug
192
and then the winch drivel
98
is operated to lift the upper furnace shell
14
and the furnace roof
16
as a unit and a distance sufficient to allow movement of the furnace transfer car
168
and lower furnace shell
12
from the operating position
176
to the furnace component exchange position
178
. It is typical to lift these components of an electric arc furnace constructed to produce a 360T heat at the start for tapping a distance of about 2.0 feet.
After the lower shell is removed from the furnace transfer car
168
at the furnace component exchange position
178
, a replacement lower shell is seated in position with the struts
170
resting on the load cells
166
which is facilitated by seating of the shoe plates
158
between the spaced apart guide bars
160
. The furnace transfer car is then returned to the operating position
176
by operation of the winch
180
. The rachet binders
188
are then used to draw the car against the stop
186
. The upper furnace shell and furnace roof can then be lowered for support on the lower furnace shell. The electrodes
40
,
42
and
44
and retractable chutes
74
are the placed in their operative position and the furnace is ready to resume operation. When the upper furnace shell must be serviced, then only the furnace roof
16
is lifted the same distance of about 2.0 feet by use of the wire ropes
196
connected to the roof lifting lugs
190
and winch
198
is operated. It is necessary however, to disconnect the coolant supply provided by service lines
68
D for the water from the upper furnace shell
14
and withdraw the electrodes and charging chute to their remote positions. The furnace transfer car is then used to transport the upper furnace shell while seated on the lower furnace shell to the furnace component exchange position
178
and then return the replacement upper furnace shell operatively seated on the lower furnace shell to the furnace operative position
176
. The water service, electrodes and charging chutes are then moved to reestablish their respective operating positions. After the furnace transfer car is drawn against the stop by ratchet binders
188
, furnace operation can be resumed. When the entire furnace, only the furnace roof or the furnace roof and the upper shell and/or the lower shell require service, then the entire furnace is transferred by the furnace transfer car to the furnace component exchange position
178
and a reassembled furnace on the furnace transfer car is returned to the furnace operating position
176
. These usages of the furnace transfer car allow the use of mill cranes to transfer large furnace components without obstruction due to facilities associated with the operation of the furnace such as the fume duct, electrodes and scrap charging.
FIGS. 14 and 15
illustrate a modified arrangement of a tap hole for the electric arc furnace featuring eccentric furnace tapping described and shown in
FIGS. 1-13
according to this present invention. A tap hole insert
200
includes ceramic disks arranged in a face to face relation and mounted in the vertical side wall
112
A such that the bottom edge of the liquid steel conducting opening
202
forms an extension to the floor wall section
110
A and thereby promote slag free tapping by maintaining a ferrostatic head above the tap hole insert
200
of at least three times the diameter of the tap hole. Sanding of the tap hole to seal off the liquid metal flow at the conclusion of tapping as replaced by a conventional tap hole clay gun and drill assembly
204
moved into an operative position by lever arms
206
by a piston and cylinder assembly, not shown. The door
134
in the crescent shaped roof section
98
can be eliminated. The locations of the tap hole location guide assemblies
148
and
150
are changed to sites underlying the vertical side wall
112
A at opposites lateral sides of the tap hole insert
200
which causes a relocation of the transverse vertical plane
122
but no change to the vertical plane
106
. The central vertical axis
120
is located midway along the horizontal length of the tap hole insert
200
. The tap hole location guide assemblies
154
and
154
are unchanged from their location shown in FIG.
8
.
The electric arc furnace of the present invention offers versatility to the steel making operation. The furnace charging material for the most common steel making operation will be scrap which is preferable continuously introduced at closely spaced time increments as explained previously. In addition to the charging of the furnace with scrap, direct reduction iron may be introduced to an opening
210
, shown in
FIG. 2
, in the roof insert
38
by a chute
212
extending from a DRI storage hopper
214
as best shown in FIG.
18
. The chute
212
is arranged at an angular relation to the vertical so that the DRI impacts with the metal bath at a site proximate to the triangular array of electrodes to take advantage of the highly heated area in the metal bath for rapidly melting the pellets of DRI material. There are additional openings
216
and
218
in the furnace roof Openings
216
are used to insert carbon/oxygen lances, not shown, for slag foaming operation. Openings
218
communicate with chutes
220
extending to a plurality of flux and carbon bins
222
for introducing fluxing and carbon materials. Liquid metal may also form a furnace charge or a part thereof. Typically, the liquid metal will comprise blast furnace iron. As shown in
FIG. 18
there is provided a pouring tundish
224
with wheels arranged for supporting the tundish on the rails
174
. The tundish includes a launder
226
arranged to allow the introduction of liquid metal through openings formed by the slag discharge trough
86
. A ladle
228
is moved to the furnace exchange area
178
for introducing liquid metal to the tundish.
The operation of the furnace according to the present invention provides a larger tonnage output at a shorter furnace operating cycle.
FIGS. 16 and 17
illustrate a cycle time comparison between a standard tilting electric arc furnace and an electric arc furnace according to the present invention. The study demonstrates a time savings of 10 minutes 20 seconds per furnace cycle. There are two factors contributing to this time savings. The one factor is the size of the liquid metal heel provided by the configuration of the liquid metal cavity in the refractory of the lower shell. The heel after tapping is at least 70% preferably 100% of the heat before tapping which provides a substantial thermal benefit after tapping to maintain flat bath operation throughout the charging of scrap and/or other forms for charging material as identified hereinbefore. Melting a newly introduced scrap charge combined with the introduction of heat by operation of electrodes continues throughout the charging of the furnace.
FIG. 3
further illustrates the use of a control
167
typically located in an operator pulpit and having a summation circuit receiving input signals from the load cells
166
and providing an electrical signal corresponding to the weight of the furnace including the liquid metal heat which is modified by a signal to provide an output signal representing only the weight of the liquid metal heat. The weight of the liquid metal heat may be displayed in any convenient way such as a numerical read out
167
R. The read out will be used to control the furnace operation including start and stop of charging and tapping.
The size of a heel provides the further benefit of prolonging the life of the refractory by reducing the magnitude of the temperature fluctuations of the refractory during each cycle. Mechanical shock due to tilting of the furnace in opposite directions for tapping and slag off is eliminated throughout the furnace operation cycle. The feature of operating the furnace while completely static, serves also to shorten the operating cycle time by allowing power on the electrodes throughout tapping, slagging and charging which is not possible in the operation of a tilting furnace. Additionally cost savings occur in furnace operation according to the present invention due to the elimination of burners which are required in the operation of the tilting furnace cycle to equalize the temperature in the furnace. In tilting furnaces cold spots develop during the melting phase of a scrap charge and must be eliminated by the use of the burners. Another factor contributing to the time saving arising out of the present invention is the time needed to tap a heat. In the comparison given in
FIG. 17
, the time to tap a heat producing 180 tons of liquid metal in a ladle according to the present invention is 117 seconds less than 2 minutes using a new 9 inch diameter tap hole. This tapping operation is accomplished with the aid of a ferrostatic head of at least 3 times the tap hole diameter at the end of a tap formed by the large ferrostatic head of 180 tons of liquid metal remaining in the furnace at the conclusion of the tapping operation. In the example of
FIG. 17
, it is assumed a new 9 inch diameter tap hole which calls for a 36-inch ferrostatic head along the overlying the tap hole to accommodate enlargement of the tap hole due to erosion. Additionally the 36 inches of ferrostatic head guarantees slag free tapping even with a worn tap hole. Sanding of the tap hole consumes only 5 seconds. In a tilting furnace, the tap hole can be 6-10 inches. The times to lift electrodes, tilt to slag off, tilt to effect tapping and plug the tap hole requires about 7½ minutes. These time comparisons for tapping will change with an increase to the tap hole size due to erosion by the tapped heat but the time saving will remain essentially the same height of the ferrostatic head formed by the heel will remain sufficient to always maintain the ferrostatic head of at least three times the diameter tap hole throughout enlargements due to erosion to guarantee slag free tapping.
In the time study comparison given in
FIG. 16
, the non tilting furnace cycle of the present invention uses a liquid metal hot heel of 100% of the heat at the start of tapping which is advantageous by providing a full heat when it is desired to completely drain the furnace. The thermal inertia provided by the liquid metal hot heel to the refining process is sufficient in the present invention when the heel is 70% of the heat at the start of tapping which is sufficient to provide the necessary thermal inertia of a rapid melt down of a furnace charge and provide the additional benefit of increasing the furnace efficiency including lower electrical costs. The known practice of maintaining a heel is limited to a very small percentage of the heat usually 20 to 40% and is ineffective for maintaining flat bath operation throughout the refining period of the heat by the furnace. Additionally, 20 to 40% of the heat after tapping is an insufficient volume to maintain slag free tapping of a furnace remaining static throughout its operating cycles. Reduction of the furnace cycle time reduces the time the hot metal stream of the tapped heat can entrain nitrogen and also reduces the time the tapped heat spends in the ladle which decreases the temperature loss of the tapped steel in the ladle according to the present invention. The higher temperature of the steel in the ladle is especially beneficial for its use as a hot metal
As shown in
FIGS. 19-23
the present invention is applied to a furnace having a wholly circular vertical side wall section in a lower shell
234
. The configuration of the refractory face surfaces in the lower furnace shell
234
as seen in plan view of
FIG. 19
include annular side wall section
236
in an area bounded by a diameter
238
with a radius R
3
struck from the center of the diameter
102
. As seen in the sectional views of
FIGS. 21 and 22
, the annular vertical side wall section
238
is bounded by a spherically-dished floor wall section
240
defined by a radius R
4
struck form a point along a line defined by intersecting vertical planes
106
and
108
containing the center of the diameter
102
. Plane
108
coincides with diameter
102
and plane
106
forms a plane of symmetry of the configuration to the lower furnace shell. A floor wall section
242
begins at vertical plane
108
and proceeds away from the spherically-dished floor wall section
104
by a linear downward-sloping contour along plane
106
and an ever increasing radius RN of curvature transverse to plane
106
forming a rolled developed plate floor wall configuration. The ever increasing radius of transverse curvature of the floor wall section
2421
results in an ever increasing height to the vertical side wall
244
as can be seen by from
FIGS. 23 and 24
. The vertical side walls
238
and
244
forms a vertical boundary to the liquid metal surface commonly called a hot metal line
114
at the start of tapping a heat. At the conclusion of the tapping of the steel heat, there is a liquid heel line
116
formed by the upper surface of the steel heat and represents a reduction to the liquid metal depth at the diameter
102
typically slightly less than one-half of the depth of the steel heat than at the start of tapping. The downwardly sloping contour of floor wall section
242
along plane
106
and the increasing shallow curvature transverse to plane
106
forms a dramatic increase to the depth liquid heel line
116
. It can be seen from
FIG. 20
that the vertical side wall
244
is of maximum height and merges with floor wall section
242
along plane
106
at the site of a tap hole assembly
200
. The tap hole is constructed and arranged as shown and described in
FIGS. 14 and 15
. As in all embodiments described in hereinbefore, the furnace of the present invention is operated in a manner to always maintain a liquid heel depth overlying the tap hole, at the end of tapping, of at least three times the diameter of the tap hole during the useful life the tap hole ceramic discs.
While the present invention has been described in connection with the preferred embodiments of the various figures, it is to be understood that other similar embodiments may be used or modifications and additions may be made to the described embodiment for performing the same function of the present invention without deviating therefrom. Therefore, the present invention should not be limited to any single embodiment, but rather construed in breadth and scope in accordance with the recitation of the appended claims.
Claims
- 1. An electric furnace for steel making, said furnace including the combination of:a lower furnace shell stationarily supported during charging of a heat, heating of said heat and tapping of said heat, said lower shell having a floor wall with a sloping contour to increase a liquid metal depth to at least three times the diameter of a tap hole at a site communicating with the tap hole for slag free tapping of said heat, said lower furnace shell having a liquid metal capacity to maintain a liquid metal heel of at least 70% of said heat before tapping for flat bath refining of said heat throughout said charging and heating of said heat; an upper furnace shell supported by said lower furnace shell; a furnace roof supported by said upper furnace shell; an electrically powered member for heating a metal charge in said lower furnace shell; and a control including plugging for said tap hole to control tapping of said heat form said lower furnace shell.
- 2. The electric furnace according to claim 1 wherein said lower furnace shell includes a vertical annular side wall section with a uniform height extending to side wall sections of ever increasing vertical heights joining at a junction with said floor wall at the site of said tap hole.
- 3. The electric furnace according to claim 2 wherein said side wall sections of ever increasing vertical heights join with said floor wall in a crescent shaped area forming a protrusion extending beyond said upper furnace shell for extending bottom tapping.
- 4. The electric furnace according to claim 3 further including a crescent shaped furnace roof section for enclosing said crescent shaped area; and a door for normally closing an access opening and wherein said tap hole is located in said floor wall and; wherein said control including plugging includes a tap hole stopper moveable through said access opening for communicating with said tap hole.
- 5. The electric furnace according to claim 3 further including a crescent shaped furnace roof section for enclosing said crescent shaped area; and wherein said control including plugging includes a tap hole drill and a clay gun.
- 6. The electric furnace according to claim 1 where said furnace roof includes an aperture; and wherein said electric furnace further includes an electrode passed through said aperture for delivering electric current to heat a metal charge in said lower furnace shell.
- 7. The electric furnace according to claim 1 further including support tackle for lifting and supporting one or both of said furnace roof and upper furnace shell to a predetermined elevation sufficient to allow horizontal displacement of at least said lower furnace shell or said lower furnace shell and said upper furnace shell to a remote furnace exchanging position without by said furnace roof.
- 8. The electric furnace according to claim 4 wherein said roof has a fume opening and wherein said furnace further includes a cooling duct for receiving exhaust fume emitted from the fume opening in said roof.
- 9. The electric furnace according to claim 2 wherein said lower shell includes a refractory lining continuously sloping downwardly from a vertical side wall opposite said tap hole to said side wall sections of ever increasing vertical heights proximate to said tap hole defining a maximum ferrostatic head of liquid steel at said tap hole.
- 10. The electric furnace according to claim 1 further including a furnace transfer car supporting said lower furnace shell, rails supporting said furnace transfer car on superstructure for movement between a furnace operating position and a furnace exchange position; anda drive for linearly displacing said furnace transfer car along said rails between the furnace operating position and the furnace exchange position; and an anchor to secure said furnace transfer car at said furnace operating position.
- 11. The electric arc furnace according to claim 1 further including a plurality of anchor members for controlling said lower furnace shell due to thermal expansion thereof, wherein said tap hole is defined at the intersection of perpendicular vertical planes, said tap hole lying between spaced apart anchor members within each of said vertical planes, said allowing thermal expansion of said lower furnace shell within the vertical plane, thereof and excluding movement of the lower furnace shell perpendicularly thereto and thereby prevent movement of the tap hole from the intersection of said perpendicular vertical planes.
- 12. An electric furnace for steel making, said furnace including a combination of:a furnace transfer car; a drive for linearly displacing said furnace transfer car along rails between a furnace operating position and a furnace exchange position; an anchor to secure said furnace transfer car at said furnace operating position; a lower furnace shell supported by said furnace transfer car, said lower furnace shell having a floor with a sloping contour to form an area of every increasing liquid metal depth, the sloping contour of the floor forming a maximum metal bath depth proximate a tap hole for discharging a heat treated in the furnace; an upper shell furnace supported by said furnace lower shell; a furnace roof supported by said upper furnace shell; said furnace roof including apertures for electrodes and exhaust of fume from the interior of the furnace; electrodes extending through apertures through said furnace roof for heating said heat in said lower furnace shell; a control including plugging for said tap hole to control tapping of said heat said lower furnace shell; a cooling duct for receiving exhaust fume emitted from, an aperture in said furnace roof; and members for supporting said furnace roof or said furnace roof and said upper furnace shell at said furnace operating position to allow removal of said lower furnace shell and upper furnace shell or said furnace lower shell to said furnace exchange position.
- 13. The electric arc furnace according to claim 12 further including a plurality of anchor members each having components supported by each of said furnace car and said lower furnace shell for controlling said lower furnace shell due to thermal expansion thereof, wherein said tap hole is defined at the intersection of perpendicular vertical plies, said tap hole lying between spaced apart anchor members within each of said vertical planes, said anchor members allowing thermal expansion of said lower furnace shell within the vertical plane thereof and excluding movement of the lower furnace shell perpendicularly thereto and thereby prevent movement of the tap hole from the intersection of said perpendicular vertical planes.
- 14. A method for producing steel in an electric furnace, said method of including the steps of:providing an electric furnace including a lower furnace shell having a sloping floor extending downwardly to a tap hole; refining a steel melt in said furnace using electric current to form a first heat; tapping a sufficient quantity of steel from said first heat to a ladle while said lower furnace shell remains stationary to maintain a liquid hot heel in said furnace consisting of at least 70% of the tapped steel; maintaining flat bath furnace operation by using electric current and latent heat of said liquid hot heel to refine charged material in said furnace for forming a second heat; and tapping a sufficient quantity of steel from said second heat while said lower furnace shell remains stationary to maintain a liquid hot heel in said furnace consisting of at least 70% of the tapped steel.
- 15. The method for producing steel in an electric furnace according to claim 14 including the further step of locating said tap hole relative to said sloping floor to define a ferrostatic head of the liquid steel at said tap hole of at least three times the diameter of said tap hole including wear of said tap holed at the end of tapping.
- 16. The method for producing steel in an electric furnace according to claim 14 including the further step of selecting a furnace transfer car movable to a furnace exchange position from a furnace operating position; anchoring the furnace transfer car at the furnace operating position during said step of refining a steel melt in said furnace; and using the furnace transfer car to transfer said lower furnace shell for servicing at said furnace exchange position.
- 17. The method for producing steel in an electric furnace according to claim 14 including the further step of confining said lower furnace shell to movements along perpendicularly intersection vertical planes forming a vertical axis containing said tap hole to constrain said lower furnace shell to thermal expansion within said vertical planes and maintain the site as said tap hole constant.
- 18. The method for producing steel in an electric furnace according to claim 14 wherein said step of providing an electric furnace further includes arranging three electrodes for conducting respective phases of three phase electric current in an upper furnace shell through a furnace roof for heating a metal charge in said lower furnace shell.
- 19. The method for producing steel in an electric furnace according to claim 14 wherein said liquid hot heel is 100% of the tapped steel.
- 20. The method for producing steel in an electric furnace according to claim 14 wherein said using electric current to form a first heat further includes continuously supplying electric current to heat liquid metal in the furnace during said step of tapping.
- 21. The method for producing steel in an electric furnace according to claim 14 including the further step of continuously charging material during intermittent time intervals substantially throughout said step of maintaining flat bath furnace operation.
- 22. The method for producing steel in an electric furnace according to claim 21 including the further step of terminating said step of continuously charging material before said step of tapping.
- 23. The method for producing steel in an electric furnace according to claim 14 wherein said step of providing an electric furnace further include providing an upper furnace shell and a roof therefor, said upper furnace shell have annular side walls supported by said lower furnace shell and forming an extended part of said lower furnace shell for extended bottom tapping of a heat.
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Number |
Name |
Date |
Kind |
3767090 |
Sundberg et al. |
Oct 1973 |
A |
4423514 |
Davene |
Dec 1983 |
A |
4523747 |
Schnitzer et al. |
Jun 1985 |
A |
4552343 |
Labate et al. |
Nov 1985 |
A |