US1792021A - Metallurgical furnace - Google Patents

Metallurgical furnace Download PDF

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US1792021A
US1792021A US464227A US46422721A US1792021A US 1792021 A US1792021 A US 1792021A US 464227 A US464227 A US 464227A US 46422721 A US46422721 A US 46422721A US 1792021 A US1792021 A US 1792021A
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air
gas
furnace
mixing chamber
chamber
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Fred H Loftus
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F23COMBUSTION APPARATUS; COMBUSTION PROCESSES
    • F23DBURNERS
    • F23D14/00Burners for combustion of a gas, e.g. of a gas stored under pressure as a liquid

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  • This invention relates more articularly to a regenerative or reverbatory rnace and in particular to a furnace em loying the general characteristics of a enturi port ar- 6 rangement shown and described in my copending application filed March 22, 1921, Serial No. 454,496.
  • One of the characteristic features of the invention described in my co-pending appli- 10 cation is the Venturi gas port arrangement in combination with the mixing chamber whereby relatively all of the air on the incoming end is automaticall caused to pass through the mixing cham er without the necessity of using valves,
  • I increase the velocity and pressure ⁇ by passing a small volume of pre-heated air from the air up-take by means of a booster fan or blower through the gas nozzle and release it near the discharge end of the gas nozzle where it imparts an increased velocity to the stream of fuel gas.
  • This arrangement also provides, which is a further object of my invention, a more thorough co-mingling of the gas and air by bringing each portion of the carbonaceous material or gas in contact with its required amount of oxygen in order to form more perfectv combustion.
  • Another object of my present invention is the introduction of free oxygen into the mixing chamber through regulated valves whereby the reducing qualities or powers of the throttles or the like, i the auxiliary air air at the reversing valves which 4are located flame are controlled to such an extent that the process of decarbonization of the heat is entirely at the command of the operator, as carbon has a great aliinity for oxygen at high temperatures.
  • the drawing shows a vertical sectional view of one of the ends of a regenerative furnace similar to the furnace shown and de- ⁇ scribed in my said co-pending application, embodying one form of my invention.
  • the furnace is provided with the usual hearth 11 and checker chambers below the charging floor not shown.
  • the roof 10 as before stated,is flat instead of being arched and extends across the hearth from one end to the other.
  • the furnace is provided at each end with a combined fuel and air port or mixing chamber 12.
  • This chamber 1s formed preferably of sheet steel approxlmatelyfiths of an inch thick and is of a hollow cyhndrical formation opening into the air port 13 at one end and the hearth 11 at the opposite end.
  • the inner wall of the mixing chamber has its smallest diameter or area at approximately the point 14 and from that pomt towards the intake end is curved outwardly and backwardly and from the point 14 flared gradually to the discharging end.
  • the combined fuel and air port or mixing chamber is preserved by means of a circulation of water or other cooling element which circulation is introduced preferably in the lower portion through the pipe 15 and out the pipe 16, which pipe is protected by means of a brick pier 166, extending through the auxiliary channel 17, which channel opens into the furnace and upper end of the air llue 13.
  • the gas flue 18 leading from the checker chambers is provided near its upper end with channel beams 19 and 20, which are rigidly secured to and supported on a substantial steel structure (not shown) surrounding the gas uptake.
  • Supported on these channel beams is a stream line fluid cooled elbow 23 ⁇ which forms a part of the gas flue.
  • This elbow comprises two heads, 23 and 24, which are integrally provided with a pair of circular flanges 25 and 26 spaced apart. Tightly and rigidly secured to these flanges by any well known means, such as welding, are sheets, preferably of steel, three eighths of an inch thick.
  • the head 23 is provided with openings for receiving bolts or screws 27 or the like for detachably securing the elbow in place at one end.
  • the oppositehead, of the elbow 23a, is provided with an extension 29 to which is tightly but detachably secured the gas nozzle 30.
  • This nozzle is provided with a head 31 having a central opening with a pair of circular flanges adjacent thereto, to which flanges are rigidly and tightly fixed by welding or any other suitable means, a steel sheet forming the hollow body of the nozzle which is gradually restricted from its intake to its discharging end.
  • the head 31 also has a flange 33 corresponding with the flange 29 which flanges are provided with registerin openings for receiving bolts or the like for securing the parts tightly together.
  • a gasket of any suitable material may be placed between the heads.
  • the nozzle 30 as will be seen in the drawing, has its greatest diameter or area at the point where it joins the elbow 23a and that it tapers gradually inwardly or rather is gradually restricted towards its discharging end, which end terminates in the mixing chamber at about the point where the' diameter or area of the mixing chamber is the smallest. Both the nozzle and elbow are preserved by the circulation of Water or other cooling element in any satisfactory manner.
  • the gas nozzle 30 is provided with an inlet tap 34 near its lower portion and a similar outlet tap 35 at its upper portion, both outside the wall 36 to which taps may be secured in any well known manner, suitable inlet and outlet pipes.
  • the elbow 23a is similarly provided with an inlet tap 37 and an outlet tap 38 to which inlet and outlet tap pipes may be secured by being screw-threaded therein or by any other suitable means. It will be noted that by having the inlet and outlet pipes for both the nozzle and elbow entirely outside the walls of the furnace that these parts can be readily and quickly removed by simply unscrewing the bolts which hold them in place and swung out of the way by means of a crane and new ones substituted Without in any wise disrupting or interfering with the walls or brick work.
  • the pipe 39 Passing through the outer shell of the elbow and extending inwardly to the end of the gas nozzle is arelatively small Water cooled or fluid cooled pipe 39.
  • the pipe 39 is detachably mounted in and through the elbow 23, b v means of a casing 40 which casing is provided with a circular flange 41 against which the flange 42 on the pipe 39 is tightly pressed by means of a disc 43 and bolts 44.
  • Thedisc 43 is a part of the pipe 45 which has a connection with the booster fan 46 and another connection 47 leading to an oxygen producer or other Ysource of supply.
  • the connection leading to the booster fan is provided with a valve 48 of any well known construction and the pipe leading to the oxygen producer is likewise ⁇ provided with a valve 49.
  • Running from the fan 46 to the air port is a pipe 50 provided with an intake 51.
  • the pre-heated gas is forced through the gas port into and through the water cooled elbow and nozzle thence discharged into the combined fuel and air port or mixing chamber.
  • the preheated gas upon entering the throat or restricted portion of the combined fuel and air port or mixing chamber shall consider a vacuum and causes relatively all of the air from the incoming air flue to be drawn g into the mixing chamber where the air and gas are mixed.
  • relatively all of the air is automatically caused to pass through the combined fuel and mixing chamber notwithstandin the fact that the auxiliary air channel l? is constantly open.
  • relatively all of the air on the incoming end is automatically caused to pass into the mixing chamber without the necessity of using llU pro-
  • ⁇ carbon has valves,-throttles or the like, to wholly orv partially close the auxiliary air channel on the incoming .end as has heretofore been attempted.
  • One of the disadvantages or objections to the valve construction is that 1t calls for close attention and the manipulation of valves or throttles to wholly or partially close the auxiliary air channel on the incoming end and open it on the outgoing end every time the furnace is turned over or reversed,
  • the furnace is provided with a combined fuel and air port or mixing chamber and a substantial auxiliary air channel in both ends of v substantially equal area all of which are constantly open, but because of my venturi system of as port and mixing chamber the auxiliary air channel which is constantly open is on the incoming end ren-dered practically idle, that is, there is relatively little air passing through the auxiliary channel on the incoming end.
  • the amount depends somewhat on the force behind the fuel gas or air and the vacuum produced in the mixing chamber.
  • the air that does pass through the auxiliary channel is desirable as it forms a blanket or protection for the roof'and upper portions of 'the side-walls. While this operation is going on and in order to bring about a quicker and more positive co-mingling of the products of combustion I have provided a booster supply of pre-heated air at the center of the stream of fuel gas in the mixing chamber and as the products of combustion enter the mixing chamber there is an outer stratum of pre-heated air, a middle stratum of preheated fuel gas and on inner core of p reheated air.
  • This arrangement accelerates the co-mingling of the air and fuel gas as it brings about a better exposure of the particles of carbon to the required amount of oxygen to form complete combustion.V
  • This arrangement is brought about through the booster fan drawing a supof pre-heated air from the air port or flue, and shooting it through the connections including the fluid cooled pipe/39 where it is discharged in the mixing chamber at or near the end of the gas nozzle.
  • the free oxygen may be introduced wholly under the control of the operator, for the purpose of controlling the reducing qualities or powers of the flame to such an extent that the process of decarbonization of the heat of steel is entirely at the command of the operator, for
  • Another important feature of my present invention is its iiexibility or rather wide range of application.
  • a furnace can be lreadily and quickly cut over for using coke oven gas.
  • the pipe 39 and connections can be removedand a feed line for introducing coke oven gas in the mixing chamber can be used.
  • the ⁇ pre-heating has a tendency to break up certain parts of the gas which causes a material loss in eiciency, therefore it is burned without being pre-heated.
  • the furnace can be cut over to coke oven gas in less than thirty minutes.
  • the increased velocity and pressure on the fuel gas and burner of this type can be eiected by introducing a stream of gas or air in the region of the nose of the fuel gas nozzle, that is, the booster fan may be connected for discharging either pre-heated air or gas near the nose of the gas nozzle by simply having the intake 51 open either into the air or gas iiue. While I have illustrated it opening into the air flue it may connect only with the gas iue and produce satisfactory results, so far as increasing the velocity and pressure in-the region of the nose of the nozzle.
  • combustion chamber air and gas ports communicating with sald chamber, a separate relatively small channel opening into said chamber at one end and the air flue at theo posite end and means connecting with said air and gas ports for drawing air or gas thereto and discharging it into the combustion chamber for the purpose v:set forth.
  • a regenerative open hearth furnace the combination of a melting chamber, regenerators for said furnace, a relatively restricted mixing chamber at each end of said furnace'leading to and from said melting chamber, and means for passing into said mixing chamber under major pressure before the melting chamber is reached, a mixture comprising a core of preheated air, a ring of gas and an envelope of preheated air.

Description

Feb. 10, 1931.
F. H. LoF'rus METALLURGICAL FURNACE Filed April 25, 1921 hunted Feb. 1o, 1931 rama.' forros, or PITTSBURGH, rmsnvnru xn'rnmnercu. rumanos Applicationled April 25, 1921. Serial No. 464,227.
This invention relates more articularly to a regenerative or reverbatory rnace and in particular to a furnace em loying the general characteristics of a enturi port ar- 6 rangement shown and described in my copending application filed March 22, 1921, Serial No. 454,496.
One of the characteristic features of the invention described in my co-pending appli- 10 cation is the Venturi gas port arrangement in combination with the mixing chamber whereby relatively all of the air on the incoming end is automaticall caused to pass through the mixing cham er without the necessity of using valves,
to wholly or partially close channel on the incoming end as fore been attempted.
With my present invention, as is true in the invention disclosed in my co-pending application, it is ,necessary to introduce the gas or air under pressure in order to obtain the best results. With the form of furnace now in general use the pressure is applied to the has heretobelow the charging floor. This is accomplished by the 4use of a large blower which requires considerable power to operate and is very expensive and too, by applying the ressure at the valves the regenerators are p aced under extra strain, wear and tear, which materially shortens the campaign or life of the brick work. With my present invention I increase the velocity and pressure` by passing a small volume of pre-heated air from the air up-take by means of a booster fan or blower through the gas nozzle and release it near the discharge end of the gas nozzle where it imparts an increased velocity to the stream of fuel gas. This arrangement also provides, which is a further object of my invention, a more thorough co-mingling of the gas and air by bringing each portion of the carbonaceous material or gas in contact with its required amount of oxygen in order to form more perfectv combustion.
Another object of my present invention is the introduction of free oxygen into the mixing chamber through regulated valves whereby the reducing qualities or powers of the throttles or the like, i the auxiliary air air at the reversing valves which 4are located flame are controlled to such an extent that the process of decarbonization of the heat is entirely at the command of the operator, as carbon has a great aliinity for oxygen at high temperatures.
It 's a further object of my present invention to provide means which will more quickly and eiliciently reduce the metal to the molten sta e and which will more quickly carry out t e process of decarbonization.
It is a further object of my present linvention to provide a port construction for a furnace of this class which can be readily and quickly, at a small expense, cut over for burning coke oven gas or oil, in other words to provide a readily convertible furnace.
The above and other features of novelty, advantages and capabilities will become apparent from a detailed description of the accompanying drawings, in which I have illustrated one embodiment of my invention, but the construction there ,shown is to be understood as illustrative only and not as dening the limits of my invention.
The drawing shows a vertical sectional view of one of the ends of a regenerative furnace similar to the furnace shown and de-` scribed in my said co-pending application, embodying one form of my invention.
In view of my co-pending application and the construction there illustrated I have not deemed it necessary in this case to show the entire furnace construction but only so much of the furnace as is necessary in order to illustrate the application of my present invention. However, so far as the furnace construction proper is concerned the one here is substantially identical with that of my co-pending. application except in this case theroof 10 extending across and above the hearth 11 'is flat instead of arched as heretofore shown.
As the construction for each is identical in all respects it was thought unnecessary to show the application of both ends as this would be well understood by those skilled in this art.
Referring to the drawings in detail, the furnace is provided with the usual hearth 11 and checker chambers below the charging floor not shown. The roof 10 as before stated,is flat instead of being arched and extends across the hearth from one end to the other. The furnace is provided at each end with a combined fuel and air port or mixing chamber 12. This chamber 1s formed preferably of sheet steel approxlmatelyfiths of an inch thick and is of a hollow cyhndrical formation opening into the air port 13 at one end and the hearth 11 at the opposite end.
The inner wall of the mixing chamber has its smallest diameter or area at approximately the point 14 and from that pomt towards the intake end is curved outwardly and backwardly and from the point 14 flared gradually to the discharging end. The combined fuel and air port or mixing chamber is preserved by means of a circulation of water or other cooling element which circulation is introduced preferably in the lower portion through the pipe 15 and out the pipe 16, which pipe is protected by means of a brick pier 166, extending through the auxiliary channel 17, which channel opens into the furnace and upper end of the air llue 13.
The gas flue 18 leading from the checker chambers is provided near its upper end with channel beams 19 and 20, which are rigidly secured to and supported on a substantial steel structure (not shown) surrounding the gas uptake. Supported on these channel beams is a stream line fluid cooled elbow 23 `which forms a part of the gas flue. This elbow comprises two heads, 23 and 24, which are integrally provided with a pair of circular flanges 25 and 26 spaced apart. Tightly and rigidly secured to these flanges by any well known means, such as welding, are sheets, preferably of steel, three eighths of an inch thick. The head 23 is provided with openings for receiving bolts or screws 27 or the like for detachably securing the elbow in place at one end. The oppositehead, of the elbow 23a, is provided with an extension 29 to which is tightly but detachably secured the gas nozzle 30. I This nozzle is provided with a head 31 having a central opening with a pair of circular flanges adjacent thereto, to which flanges are rigidly and tightly fixed by welding or any other suitable means, a steel sheet forming the hollow body of the nozzle which is gradually restricted from its intake to its discharging end. The head 31 also has a flange 33 corresponding with the flange 29 which flanges are provided with registerin openings for receiving bolts or the like for securing the parts tightly together. In order to more securely insure an air tight joint a gasket of any suitable material may be placed between the heads. The nozzle 30 as will be seen in the drawing, has its greatest diameter or area at the point where it joins the elbow 23a and that it tapers gradually inwardly or rather is gradually restricted towards its discharging end, which end terminates in the mixing chamber at about the point where the' diameter or area of the mixing chamber is the smallest. Both the nozzle and elbow are preserved by the circulation of Water or other cooling element in any satisfactory manner. In the modification shown,the gas nozzle 30 is provided with an inlet tap 34 near its lower portion and a similar outlet tap 35 at its upper portion, both outside the wall 36 to which taps may be secured in any well known manner, suitable inlet and outlet pipes. The elbow 23a is similarly provided with an inlet tap 37 and an outlet tap 38 to which inlet and outlet tap pipes may be secured by being screw-threaded therein or by any other suitable means. It will be noted that by having the inlet and outlet pipes for both the nozzle and elbow entirely outside the walls of the furnace that these parts can be readily and quickly removed by simply unscrewing the bolts which hold them in place and swung out of the way by means of a crane and new ones substituted Without in any wise disrupting or interfering with the walls or brick work.
Passing through the outer shell of the elbow and extending inwardly to the end of the gas nozzle is arelatively small Water cooled or fluid cooled pipe 39. The pipe 39 is detachably mounted in and through the elbow 23, b v means of a casing 40 which casing is provided with a circular flange 41 against which the flange 42 on the pipe 39 is tightly pressed by means of a disc 43 and bolts 44. Thedisc 43 is a part of the pipe 45 which has a connection with the booster fan 46 and another connection 47 leading to an oxygen producer or other Ysource of supply. The connection leading to the booster fan is provided with a valve 48 of any well known construction and the pipe leading to the oxygen producer is likewise` provided with a valve 49. Running from the fan 46 to the air port is a pipe 50 provided with an intake 51.
In operation, in the particular modification shown, the pre-heated gas is forced through the gas port into and through the water cooled elbow and nozzle thence discharged into the combined fuel and air port or mixing chamber. The preheated gas upon entering the throat or restricted portion of the combined fuel and air port or mixing chamber duces a vacuum and causes relatively all of the air from the incoming air flue to be drawn g into the mixing chamber where the air and gas are mixed. With this arrangement relatively all of the air is automatically caused to pass through the combined fuel and mixing chamber notwithstandin the fact that the auxiliary air channel l? is constantly open. In other words, with my arrangement in this and my co-pending application relatively all of the air on the incoming end is automatically caused to pass into the mixing chamber without the necessity of using llU pro-
` carbon has valves,-throttles or the like, to wholly orv partially close the auxiliary air channel on the incoming .end as has heretofore been attempted. One of the disadvantages or objections to the valve construction is that 1t calls for close attention and the manipulation of valves or throttles to wholly or partially close the auxiliary air channel on the incoming end and open it on the outgoing end every time the furnace is turned over or reversed, Whereas with the invention shown in this and my co-pending application the furnace is provided with a combined fuel and air port or mixing chamber and a substantial auxiliary air channel in both ends of v substantially equal area all of which are constantly open, but because of my venturi system of as port and mixing chamber the auxiliary air channel which is constantly open is on the incoming end ren-dered practically idle, that is, there is relatively little air passing through the auxiliary channel on the incoming end. lThe amount depends somewhat on the force behind the fuel gas or air and the vacuum produced in the mixing chamber. However the air that does pass through the auxiliary channel is desirable as it forms a blanket or protection for the roof'and upper portions of 'the side-walls. While this operation is going on and in order to bring about a quicker and more positive co-mingling of the products of combustion I have provided a booster supply of pre-heated air at the center of the stream of fuel gas in the mixing chamber and as the products of combustion enter the mixing chamber there is an outer stratum of pre-heated air, a middle stratum of preheated fuel gas and on inner core of p reheated air. This accelerates the co-mingling of the air and fuel gas as it brings about a better exposure of the particles of carbon to the required amount of oxygen to form complete combustion.V This arrangement is brought about through the booster fan drawing a supof pre-heated air from the air port or flue, and shooting it through the connections including the fluid cooled pipe/39 where it is discharged in the mixing chamber at or near the end of the gas nozzle.
When desired with my present invention, by manipulating the valve 49 the free oxygen may be introduced wholly under the control of the operator, for the purpose of controlling the reducing qualities or powers of the flame to such an extent that the process of decarbonization of the heat of steel is entirely at the command of the operator, for
temperatures. Thus introducing free oxygen also causes a more complete combustion, promotes the rapid co-mingling of the components of the combustible mixture and produces aflame whose temperature is extremely high, therefore the metal can be reduced to a molten stage very quickly and after the agreat affinity for oxygen at high metal reaches such a stage the process of decarbonization can be accomplished in a very short time.
Another important feature of my present invention is its iiexibility or rather wide range of application. By this I mean a furnace can be lreadily and quickly cut over for using coke oven gas. When so using the furnace the pipe 39 and connections can be removedand a feed line for introducing coke oven gas in the mixing chamber can be used. In burningv coke oven gas in the open hearth furnace it is not passed through the gas regenerators as the` pre-heating has a tendency to break up certain parts of the gas which causes a material loss in eiciency, therefore it is burned without being pre-heated. Under the old method it requires considerable time to rebuild a furnace in order to adapt it for burning coke oven gas while with my present inventionthe furnace can be cut over to coke oven gas in less than thirty minutes. The same applies to the-burning of liquid fuel such as oil. This is accomplished somewhat in the same fashion by simply withdrawing the pipe arrangement 39, and introducing the usual oil burner instead. The flexibility of this arrangement is extremely importantbecause of these and other inherent advantages. With the construction now in use a furnace can not be cut over for, these different purposes without practically rebuilding at a loss,of considerable time and expense. 4
The increased velocity and pressure on the fuel gas and burner of this type can be eiected by introducing a stream of gas or air in the region of the nose of the fuel gas nozzle, that is, the booster fan may be connected for discharging either pre-heated air or gas near the nose of the gas nozzle by simply having the intake 51 open either into the air or gas iiue. While I have illustrated it opening into the air flue it may connect only with the gas iue and produce satisfactory results, so far as increasing the velocity and pressure in-the region of the nose of the nozzle.
Having thus described my invention, I claim:
1. In a furnace of the class described the -combination of a combustion chamber and means for introducing into said combustion chamber a core of pre-heated air, under superior pressure to that of the air regenerator, an envelope of pre-heated gas and an outer envelope of pre-heated air.
2. In the method of operating a regenerative furnace which consists in 'comtemporaneously delivering to a mixing chamber a core of pre-heated air, under superior pressure to that of the air regenerator, an envelope of pre-heated gas and an outer envelope of pre-heated air.
3. In a 'furnace of the class described, va
combustion chamber, air and gas ports communicating with sald chamber, a separate relatively small channel opening into said chamber at one end and the air flue at theo posite end and means connecting with said air and gas ports for drawing air or gas thereto and discharging it into the combustion chamber for the purpose v:set forth.
4. In a furnace of the class described, the combination of an air and gas port or mixing chamber, an air flue, communicating with said chamber, a gas iue having a restricted discharge enterin said mixing chamber and separate means o delivering a relatively small volume of air or gas through the gas flue into the mixing chamber.
5. In a furnace of the class described a mixing chamber, an air flue communicating therewith, a gas flue having a restricted discharge into the mixin chamber and readily controllable means or introducin preheated airy into the mixing chamber or the purpose set forth.
6. In a, heating furnace, the combination of entering gas and air ports, auxiliary gas discharge ports, means for supplying a jet of gaseous medium at a velocity to direct the combustible gases into the furnace through the entering ports and prevent said gases from entering the furnace through the dischar e ports.
7 n a regenerative open hearth furnace, the combination of a melting chamber, regenerators for said furnace, a relatively restricted mixing chamber at each end of said furnace'leading to and from said melting chamber, and means for passing into said mixing chamber under major pressure before the melting chamber is reached, a mixture comprising a core of preheated air, a ring of gas and an envelope of preheated air.
In Witness whereof, I hereunto subscribe my name to this specification.
FRED H. LOFTUS.
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Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2446511A (en) * 1946-08-21 1948-08-03 Air Liquide Open-hearth steelmaking
US2515670A (en) * 1946-10-22 1950-07-18 Air Reduction Manufacture of open-hearth steel
US2587900A (en) * 1948-10-28 1952-03-04 Robiette Alfred Gordon Evans Heat-treatment of metals
US2627398A (en) * 1949-11-30 1953-02-03 Surface Combustion Corp Combustion apparatus using preheated air
US2639910A (en) * 1949-11-30 1953-05-26 Surface Combustion Corp Combustion apparatus using preheated air
US3169159A (en) * 1958-02-21 1965-02-09 United Steel Companies Ltd Open-hearth furnace
EP0164872A1 (en) * 1984-05-09 1985-12-18 Kawasaki Steel Corporation Low load burning burner

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2446511A (en) * 1946-08-21 1948-08-03 Air Liquide Open-hearth steelmaking
US2515670A (en) * 1946-10-22 1950-07-18 Air Reduction Manufacture of open-hearth steel
US2587900A (en) * 1948-10-28 1952-03-04 Robiette Alfred Gordon Evans Heat-treatment of metals
US2627398A (en) * 1949-11-30 1953-02-03 Surface Combustion Corp Combustion apparatus using preheated air
US2639910A (en) * 1949-11-30 1953-05-26 Surface Combustion Corp Combustion apparatus using preheated air
US3169159A (en) * 1958-02-21 1965-02-09 United Steel Companies Ltd Open-hearth furnace
EP0164872A1 (en) * 1984-05-09 1985-12-18 Kawasaki Steel Corporation Low load burning burner
US4626195A (en) * 1984-05-09 1986-12-02 Kawasaki Steel Corporation Low load burning burner

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