[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

US2679389A - Furnace structure - Google Patents

Furnace structure Download PDF

Info

Publication number
US2679389A
US2679389A US343874A US34387453A US2679389A US 2679389 A US2679389 A US 2679389A US 343874 A US343874 A US 343874A US 34387453 A US34387453 A US 34387453A US 2679389 A US2679389 A US 2679389A
Authority
US
United States
Prior art keywords
furnace
hearth
section
uptake
length
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US343874A
Inventor
Leland B Luellen
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Inland Steel Co
Original Assignee
Inland Steel Co
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Inland Steel Co filed Critical Inland Steel Co
Priority to US343874A priority Critical patent/US2679389A/en
Application granted granted Critical
Publication of US2679389A publication Critical patent/US2679389A/en
Priority to US88311859 priority patent/USRE24859E/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27BFURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
    • F27B3/00Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
    • F27B3/002Siemens-Martin type furnaces

Definitions

  • This invention relates to open hearth furnaces used for the production of steel and to a new and improved structure of the end sections of such furnaces.
  • an open hearth furnace consists of a number of cooperating structures or parts which are built primarily of refractory brick and other refractory materials and, secondly, of steel which is used principally as supports for, or as binding and bracing to, the refractory constructions.
  • the actual production operations take place in the hearth section, the working surface of which is shaped somewhat like a shallow elliptical bowl.
  • This hearth is enclosed on one of its long sides by a refractory brick section known as a front-wall which is equipped with doors through which the heat materials are charged and worked by the furnace personnel.
  • the opposite long side of the hearth is enclosed by another refractory construction known as the backwall.
  • the upper limits of the front-wall and back-wall are joined together by an arched or suspended refractory brick roof over the hearth and this is commonly referred to as the main roof of the furnace.
  • the furnace construction etxends some distance past the hearth ends to provide space for air and/or gas passages and for the fuel-introducing agencies and constructions.
  • the furnace end sections and inner constructions referred to are sometimes called port-ends and sometimes simply the furnace ends.
  • the outer structure of these port-ends is formed by brickwork extensions to the front and back-walls, such extensions being commonly referred to as front and back wing-walls. These wing-walls at each end of the furnace join with a brick end-wall which marks the length limits of the furnace proper, except for the steel binding.
  • the wing-.walls and their adjacent end-wall are joined at their upper limits by an arched or suspended roof sometimes called the hood section, which in turn extends toward and joins the main roof over the hearth proper,
  • the result is to bring about an enclosed reotangularly shaped construction known as the furnace proper which contains the hearth and a substantially similar end section adjacent to each end of the hearth in which are contained the fuel-introducing equipment and constructions and substantially vertical passageways for incoming air and outgoing gases, said passageways being commonly called uptakes, and functioning principally in cooperation with adjacent passageways not here concerned, to join the functions of the regenerative system with the functions of the hearth section.
  • the refractory brick and refractory materials from which the furnace hearth is constructed are Lil supported at the hearth ends by refractory protected structural members or steel frameworks sometimes known as chill boxes. These latter constructions are situated between the ends of the hearth and the passages above referred to and the walls or arches protecting the support- ⁇ ing steelwork referred to participate in forming the inward wall of the uptake passage on its respective end, regardless of the construction detail or shape of said protecting walls or arches which may vary somewhat from furnace to furnace.
  • Fuel to support the steelmaking process is introduced through the end-walls already described. These end-walls participate in forming that part of the uptake sections opposite the chill boxes referred to.
  • the uptakes are formed on the other two sides by the lower parts of the iront and back wing-walls which are extended downwardly toward another passage leading directly to the regeneratcrs.
  • the steelmaking materials are charged through the front-wall doors into the hearth section.
  • Fuel is introduced through the end-walls and directed toward the hearth, being fired first from one end and then the other for brief periods.
  • Air to support combustion of the fuel and also to provide oxygen to support the chemical reactions which take place in the hearth is pre-heated by passing through regenerators also adapted to alternating handling of incoming air and outgoing gases.
  • the regenerators are generally located some distance away from the hearth section and usually below and/or to one side of the hearth proper. The regenerator system is not here described because it is not directly related to the teachings of this invention.
  • the air is carried by various constructions from the regenerators to the lower sections ci the uptake passages previously described which then function to carry the said pre-heated air to juncture with the fuel.
  • the Waste gases leaving the hearth section pass through the uptakes on the opposite end from the incoming air on their way back to the regenerative system.
  • the uptake passage is generally divided into two or more parts separated by a heavy refractory brick arch and wall which strengthens the structure and helps support brickwork about the chill boxes at the ends of the hearth section.
  • This center wall has been used in the past to support so called doghouses of refractory material surrounding the fuel-introducing agencies to protcot them from the high temperatures of the combustion products which pass around them in leaving the furnace. Considerable bailling and channeling of the gases resulted because of this obstruction in the furnace ends.
  • This invention contemplates rebuilding the furnace end structures without changing the outside dimensions of the furnace to secure additional furnace capacity or increased uptake capacity, or both, as required by the particular furnace. It also contemplates the construction of new furnaces within the teachings of this invention. in. accomplishing these general objectives, the furnace ends are reconstructed to provide a single uptake passage shaped in a particular manner to provide an even flow of air to the fuel-introducing agencies. At the same time erosion of the refractory elements is lessened by reduction of baffling, channeling and the like of the exiting combustion gases.
  • This invention also contemplates a series of changes to the construction of the end sections of open hearth furnaces which may be applied singly or in cooperation with one another to increase the productive capacity of existing furnaces without requiring alteration to their outside dimensions, and secondly, to construction of new furnaces capable of higher production rates than comparably sized furnaces would otherwise have.
  • the separating constructions dividing the uptake into two or more parts are eliminated to provide a single uptake passage, which is unobstructed, and therefore has a greater carrying capacity.
  • the passage is also shaped to provide a greater air capacity per square foot of cross section than the divided uptakes in addition to being free of channeling influences which tend to direct the air away from the fuel-introducing agencies.
  • Fig. 1 is a plan view of an open-hearth furnace with the roof removed and embodying the invention
  • Fig. 2 is a vertical sectional view of the furnace shown in Fig. 1;
  • Fig. 3 is a sectional view taken substantially along line 3-3 in Fig. 2;
  • Fig. 4 is a fragmentary plan view similar to Fig 1 showing another furnace end structure including the invention
  • Fig. 5 is a view similar to Fig. 2 of the furnace end structure illustrated in Fig. 4;
  • Fig. 6 is a sectional view taken substantially along line E-G in Fig 5;
  • Fig. 7 is a sectional view taken substantially along line I-l in Fig. 8 showing a preferred end structure for a single burner:
  • Fig. 8 is a fragmentary plan view with the roof removed of a third furnace structure
  • Fig. 9 is a fragmentary vertical sectional view through one end of a furnace exemplary of the invention herein and designated Furnace B in the specification;
  • Fig. i0 is a fragmentary horizontal sectional view taken substantially at the foreplate elevation of the furnace shown in Fig. 9:
  • Fig. ll is a fragmentary vertical sectional view through one end of a furnace exemplary of the invention herein and designated Furnace C in the specification;
  • Fig. l2 is a fragmentary horizontal sectional view taken substantially at the foreplate elevation of the furnace shown in Fig. 11;
  • Fig. 13 is a fragmentary vertical sectional view through one end of a furnace exemplary of the invention herein and designated Furnace D" in the specification, and
  • Figl i4 is a fragmentary horizontal sectional fifi view taken substantially at the foreplate elevation of the furnace shown in Fig. 13.
  • the open-hearth furnace illustrated in the drawings has the basic parts found in most furnaces of this type.
  • the hearth section IIJ is adapted to contain the molten material from which the steel product is tapped.
  • This hearth section is supported on a steel framework and built up of refractory and fused material to withstand the high heats of the furnaces.
  • the front wall II of the furnace is provided with a number of charging doors I2 through which the ore, scrap and other material may be charged into the hearth section.
  • a back Wall I3 (the pit side of the furnace) extends along generally parallel to the front wall of the furnace and these walls are joined by the furnace end structure comprising wing walls I4 and I5 and an end wall I6.
  • the walls of the furnace are shown diagrammatically, in that the thickness of the brick is in.. dicated and the binding or buckstays on the outside of the walls are omitted since they are of usual construction.
  • a chill box I1 is provided to form the end of the hearth section.
  • the chill box is adequately protected with refractory elements and is supported by a chill section wall IB which also serves as one of the bounding walls of the uptake passage 20.
  • the bottom portion of the furnace end is the slag pit.
  • Each end of the furnace is a duplicate of the other and as this description progresses reference to any part of the furnace end structure may refer to either end of the furnace.
  • An arched roof I9 extends between the front and back walls and joins at its ends with the end walls.
  • each end wall is provided with two burners 22, each directed generally downwardly and inwardly toward the surface of the molten mass contained within the hearth section. Fuel from the burners 22 is mixed with air brought upwardly through the uptake 2t and is fired at the burner tip.
  • Figs. 4 and 8 illustrate an open-hearth furnace having a single burner 22 located centrally in the end wall I6.
  • Open-hearth furnaces are operated by regen erating the air used to re the fuel. Thus air is passed over hot checkerwork which was previously heated by the exhaust gases from the furnace. The air is brought to a very high ternperature before mixture with the fuel, thereby increasing the temperature of the furnace.
  • the uptake passages 20 convey this heated air through a generally vertical lower portion 24 which ends at the roof I9 of the furnace and then through the upper portion or throat 25 to the furnace hearth section.
  • Previous and existing open-hearth furnaces utilize a multiple uptake passage made necessary by the existence of a heavy center wall and supporting arch which strengthened the furnace end structures and provided support for the chill boxes.
  • the brickwork under and around the chill box was of sprung arch construction with skew-backs resting against the center wall and the Wing walls.
  • this center arch and wall are dispensed with and a single uptake passage is provided.
  • the uptake passage is bounded by the wing walls, the end wall and the section wall and chill box section.
  • the passage is narrowed by the chill box protective wall 26 which may be suspended from the chill box section.
  • the throat of the open-hearth furnace here shown takes on a particular shape to convey the air from the vertical potrion 24 of the uptake passage to the hearth section.
  • each of the wing walls on the front and back of the furnace is provided with a portion 21 and 28 extending inwardly toward each other to restrict the throat.
  • This provides a Venturitype action on the air passing through the throat expanding the air to the center of the furnace and preventing the air from hugging the walls of the furnace.
  • This venturi commonly applied is not, however, required here and may be omitted provided the uptake is properly shaped in relation to the rest of the furnace. I prefer to omit this venturi.
  • the Venturi throat is positioncd above the chill box section so as to direct the air into the stream of fuel introduced by the burners.
  • the restricted throat providing the Venturi action has been omitted.
  • the restricted portion is substantially above the end of the chill box section and provides a streamlining effect to passage of gas in either direction.
  • Figs. '7 and 8 show the preferred form of end structure for a single burner at each end.
  • the portion of the uptake opposite the chill box has been made generally trapeaoidal in shape by built-in portions 34 and 35 to direct the air toward the burner.
  • portions 21 and 28 streamline the front and rear wing walls between the uptake and the hearth.
  • this recovered volume may be used for either or both of two purposes. If the uptake capacity of the furnace was inadequate, the recovered volume may be used to increase the capacity of the uptake section. or such recovered volume may be used to increase the capacity of the hearth section by moving the chill boxes closer to the end walls of the furnace. This capacity increase may be accomplished without rebuilding the major portion of the furnace and without changing its Outside dimensions.
  • the capacity of the hearth section could be increased slightly more than 5% by moving the chill boxes a total of 2 it. 1% outwardly from their former position. was done without incurring any decrees n t e. air capacity of the uptake passages. noted in Figs. i and 2, this change of capacity may be st in terms of a ratio of the length of the uptake passages to the length oi the furnace hearth. These dimensions are both measured at the mean sill plate level which is herein defined as the usual datum plane in open-hearth structures, that being the meen level of the lowest point in the charging door openings.
  • the length of the uptake passages designated A' on the drawing is taken between the end steelwork of the chill box section and the buckstays or binding at the end of the furnace.
  • the length of both uptales so measured is taken as the dimension A in the ratio.
  • the dimension B is the total length of the furnace hearth between the outside of the steelworl: of the chill boxes. The total of A plus B will equal the length of the furnace inside the binding.
  • dimension A totaled 20 ft. 3 in. and dimension B, 49 ft. l0 in. 'I'he total is 70 ft. l in. between the end buckstays of the furnace which may not be moved outwardly because of limitation in space between adjacent furnaces.
  • the ratio of A to B was 1 to 2.46 in existing furnaces of this size.
  • the chill boxes of this particular furnace were each moved outwardly 12% in., a total distance of 2 ft. 1% in. which changes dimension A to 18 ft. 11.41 in. and B was 5l ft. 11% in.
  • the ratio of A to B was thus changed to 1 to 2.87 and the resultant increase in hearth capacity was slightly over 7%. This relationship is expressed in terms of bath length, uptake size and throat size for this particular furnace and for other furnaces in the specific examples given hereafter.
  • the chill boxes may be moved outwardly toward the end Wall as much as three feet each. This may be dpne without materially changing the uptake efficiency of the furnace ends and with substantial increase in the productive capacity of the furnace itself. Life of the refractory elements is materially increased since baffling and channeling of the gases leaving the furnace are in a large part eliminated.
  • the relationship of the position of the chill i boxes and the end walls of the furnace are thus changed to eil'ect a greater capacity without changing outside dimensions of the furnace.
  • the changed position of the chill. boxes is herein dened as substantially close to the end walls to distinguish the new position from that originally found in furnaces employing multiple uptake passages.
  • the chill boxes are nearer the end walls than in comparable size furnaces em ploying multiple uptake passages.
  • the single uptake passage provides a more even iow of air to the fur nace.
  • the volumes recovered by removal of the previously present center structures may be utilized as desired, either for increasing capacity oi the furnace by lengthening the hearth section or for increasing the uptake capacity at the furnace ends.
  • This shape allows expansion of outgoing gases adjacent the end wall, thus decreasing corrosion of the end wall refractory elements.
  • the trapezoidal shape will be retained from the bottom of the chill box section to the top of the bridgewall 35 above the chill box. Incoming air is spread by this shape uptake, preventing air from hugging the walls of the furnace and providing better distribution thereof to the burners.
  • the previously mentioned increase in capacity of the hearth bed may be expressed in terms of the longitudinal length of the hearth bed inside the refractory of the bed measured at the foreplate elevation related to the total length of the furnace inside the structural binding.
  • the length of the hearth bed (between steel) before the chill boxes were moved was 44 feet 6 inches and afterward it was 46 feet 7% inches (steel to steel).
  • the new bed is approximately 66 of the total length of furnace (70 feet 1 inch) inside bindings. YFurther movement of the chill boxes toward the end walls will increase the hearth bed.
  • the uptake passage may be defined in relation to the longitudinal length of the furnace inside the bindings in terms of a ratio of the combined length of the uptakes inside brickwork measured at their narrowest section along the longitudinal axis of the furnace, to the above mentioned longitudinal dimension of the furnace.
  • the chill boxes were moved outwardly toward the end walls, thus increasing the hearth length and resulting in a combined length of uptake passage equal to approximately 16% of the total length of the furnace. Further movement of the chill boxes toward the end walls would result in a combined length of uptake passages as above defined equal to a smaller proportion of the total length of the furnace.
  • the air capacity of the furnace was improved to permit a much greater firing rate.
  • the cross sectional area in square feet of the single uptake when measured at its narrowest section was equal to 86% of the longitudinal length of the furnace inside the bindings in feet, and it is preferred not to exceed this proportion.
  • furnaces shown in Figs. 9 through 14 are examples of actual furnaces made in accordance with this invention.
  • the drawings are made to scale and may be used for determining dimensions where necessary although in the following tables the critical dimensions of the furnaces are given.
  • Each of the furnaces has a hearth bed lil formed with an end portion generally designated 4I which may be more accurately defined as a bridgewall 42 and a protective chill wall d3 about the end portion of the hearth.
  • the foreplate elevation is designated on the drawings and ordinarily the bath extends up to this elevation so that the point adjacent the bridgewall 42 which defines the end of the bath is immediately apparent.
  • An arched roof structure 44 covers the main portion of the furnace over the bath and is joined to the end wall 45 of the furnace by a section 46 referred to as a skew-back. Between this section 45 and the bridgewall 42 is an area referred to as the throat of the furnace.
  • the space between the end wall 45 and the protective chill wall 113 is referred to as an uptake here designated as 41. It will be noticed that in each of these furnaces the uptake passage is a single opening extending across the width of the furnace from the front wing wall 48 to the rear wing Wall 4a.
  • the bath length has been increased by moving the ends of the hearth bed toward the end wall of the furnace. It should be understood that the end wall cannot be moved outwardly to increase the length of the furnace and that such length is determined by the bindings I). Thus the furnace length in- 8 side these bindings (total length outside of end brickwork) is thereby fixed.
  • the changes made herein are accomplished by rearranging the internal structure of the furnace.
  • the bath length and area are thus increased.
  • the uptake section is rearranged to provide an adequate air supply.
  • This increased bath area may be used in one of several ways. Steel may be made much more rapidly if the depth of the bath is less than it might be. Most furnaces in operation throughout this country are at present overcharged so that the bath depth is greater than desirable. The increased bath area may be used to lower the bath depth.
  • Furnace A Some of the dimensions of this furnace are given in the foregoing description. A comparison is given below indicating the changes that have been made in the furnace in accordance with the invention herein.
  • Furnace B Dimensions of Furnace Before After Length of furnace outside hrlckwork 60'-0 (SW-4)".
  • Furnace D I Dimensions of Furnace pass to length of hearth betwcrri rch-'loteries 1 Approxii ly.
  • An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end wall joined together to form a furnace end section at cach end of the hearth section.
  • each furnace cud section having a single uptake passage for conducting air to the hearth section, said furnace having a throat above the ends of the hearth communicating with the uptake passage and hearth bed.
  • said hearth bed having a length measured between rei'ractories at the forep-late elevation equal to between 6D% to 75% of the total furnace length inside bindings and a combined length of uptake passages equal to between 8% to 15% of said furnace length, the ratio of said uptake passage length to said hearth length being between 1 to- 4 and l to 8.6 and said throat having an area in its narrowest section at least substantially as large as the narrowest section of said uptake passage, the minimum horizontal dimension of said throat approaching the width of the uptake passage.
  • An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end Wall joined together to form a furnace end section at each end of the hearth section, each furnace end section having a single uptake passage for conducting air to the hearth section, said furnace having a throat above the ends of the hearth communicating with thc uptake passage and hearth bed, said hearth bed having a length measured 'between refractories at the foreplate elevation such that the combined length of the uptake passages, at the same elevation taken therefrom is equivalent to more than 45% of the furnace length measured inside its bindings, said throat area at its narrowest section being at least substantially as large as the narrowest section of said uptake passage, the minimum horizontal dimension of said throat appreaching the Width of the uptake passage.
  • An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end wall joined together to form a furnace end section at each end of the hearth section, each furnace end section having a single uptake passage for conducting air to thc hearth section, said furnace having a throat above the ends of the hearth communicating with the uptake passage and hearth bed, said hearth bed being relatively long ⁇ with relation to the furnace length, the length of the hearth bed measured between rcfractories at the foreplate elevation being at least four times the combined length of the uptake passages measured between reiractories at the foreplate elevation; and said throat having an area at its narrowest section at leastj substantially as large as the narrowest section of said uptake passage, the minimum horizontal dimension of said throat approaching the width of the uptake passage.
  • An open hearth furnace comprising a hearth section having a. hearth bed and an end section at each end of the furnace having a single uptak passage for conducting air to thc hearth section, said furnace having a throat above each end of the hearth section communicating with the uptake passage and the hearth bed, said hearth bed being relatively long with relation to the furnace length and having.r a length between refractories at the foreplatc elevation in excess of of the furnace length between bindings with a combined uptake length less than 15% of said furnace length, said throat having an arca at its narrowest section at least substantially as large as the narrowest section of the uptake passage, the minimum horizontal dimension of said throat approaching the width of the uptake passage.
  • An open hearth furnace comprising a hearth section with a chill box at each end, wing Ywalls and an end Wall joined together to form a fur nace end section adjoining said hearth section, a section wall around and under each chill box and extending between said wing Walls, said walls forming a single uptake passage at each end of the furnace for conducting air to the hearth section, means for introducing air to said uptake passages, a fuel supply at each end of the furnace for directing fuel toward ⁇ the hearth section, the length of the hearth section between the metal of the chill boxes on the hearthsidc oi each measured at the sill plate elevation being about 2.8'7 times the combined length of the uptake passages between metal, the passage from the uptake passage to the hearth being at least substantially as large as the uptake passage and the minimum horizontal dimension of said throat approaching the width of the uptake passage.
  • An open hearth furnace having a hearth section and a fuel supply at each end of the furnace, a single uptake passage at each end of the furnace communicating with the hearth section and an air supply, said uptake passages having a combined length at their narrowest section inside brickwork measured in the direction along the longitudinal axis of the furnace of not more than 16 times the total length of the furnace inside bindings measured at the foreplate line.
  • An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end wall joined together to form a furnace end section at each end of the hearth section, each furnace end section having a single uptake passage for conducting air to the hearth section, said furnace having a throat above the ends of the hearth communicating with the uptake passage and hearth bed, said hearth bed having a length measured between refraetories at the foreplate elevation equal to between 60% to 75% of the total furnace length inside bindings and a combined length of uptake passages equal to between 8% to 15% of said furnace length, the ratio of said uptake passage length to said hearth length being between 1 to 4 and 1 to 8.6 and said throat having an area in its narrowest section at least substantially as large as the narrowest section of said uptake passage.

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Vertical, Hearth, Or Arc Furnaces (AREA)

Description

May 25, 1954 L. B. LUELLEN 2,679,389
FURNACE STRUCTURE Filed March 23, 1953 7 Sheets-Sheet 1 May 25, 1954 L.. B. Lur-:LLEN 2,679,389
FURNACE STRUCTURE Filed March 23, 1953 7 Sheets-Sheet 2 May 25, 1954 L. B. LUELLEN 2,679,389
FURNACE STRUCTURE Filed March 23, 1953 7 Sheetshest 3 May 25, 1954 L. B. LUELLEN 2,679,389
FURNACE STRUCTURE Filed March 23, 1953 7 Sheets-Sheet 4 L.. a. I UELLEN 2,679,389
FURNACE STRUCTURE 7 Sheets-Sheet 5 'ill'. Il l/l LII May 25, 1954 Filed March 23, 1953 May 25, 1954 l.. B. LUELLEN 2,679,389
FURNACE STRUCTURE Filed March 23, 1953 7 Sheets-Sheet 6 May 25, 1954 l.. B. LUELLEN FunNAcE STRUCTURE 7 Sheets-Sheet 7 Filed March 23, 1953 l I Will [L H H ggf/.
V// M ULI UU Y'zvefz V// uu Patented May 25, 1954 FURNACE STRUCTURE Leland B. Luellen, Highland, Ind., assigner to Inland Steel Company, a. corporation of Dela- Application March 23, 1953, Serial No. 343,874
10 Claims. 1
This invention relates to open hearth furnaces used for the production of steel and to a new and improved structure of the end sections of such furnaces.
This application is a continuation-impart of my copending application Serial No. 221,686 filed April 18, 1951, now abandoned.
In general, an open hearth furnace consists of a number of cooperating structures or parts which are built primarily of refractory brick and other refractory materials and, secondly, of steel which is used principally as supports for, or as binding and bracing to, the refractory constructions. The actual production operations take place in the hearth section, the working surface of which is shaped somewhat like a shallow elliptical bowl. This hearth is enclosed on one of its long sides by a refractory brick section known as a front-wall which is equipped with doors through which the heat materials are charged and worked by the furnace personnel. The opposite long side of the hearth is enclosed by another refractory construction known as the backwall. The upper limits of the front-wall and back-wall are joined together by an arched or suspended refractory brick roof over the hearth and this is commonly referred to as the main roof of the furnace.
The furnace construction etxends some distance past the hearth ends to provide space for air and/or gas passages and for the fuel-introducing agencies and constructions. The furnace end sections and inner constructions referred to are sometimes called port-ends and sometimes simply the furnace ends. The outer structure of these port-ends is formed by brickwork extensions to the front and back-walls, such extensions being commonly referred to as front and back wing-walls. These wing-walls at each end of the furnace join with a brick end-wall which marks the length limits of the furnace proper, except for the steel binding. The wing-.walls and their adjacent end-wall are joined at their upper limits by an arched or suspended roof sometimes called the hood section, which in turn extends toward and joins the main roof over the hearth proper, The result is to bring about an enclosed reotangularly shaped construction known as the furnace proper which contains the hearth and a substantially similar end section adjacent to each end of the hearth in which are contained the fuel-introducing equipment and constructions and substantially vertical passageways for incoming air and outgoing gases, said passageways being commonly called uptakes, and functioning principally in cooperation with adjacent passageways not here concerned, to join the functions of the regenerative system with the functions of the hearth section.
The refractory brick and refractory materials from which the furnace hearth is constructed are Lil supported at the hearth ends by refractory protected structural members or steel frameworks sometimes known as chill boxes. These latter constructions are situated between the ends of the hearth and the passages above referred to and the walls or arches protecting the support- `ing steelwork referred to participate in forming the inward wall of the uptake passage on its respective end, regardless of the construction detail or shape of said protecting walls or arches which may vary somewhat from furnace to furnace.
Fuel to support the steelmaking process is introduced through the end-walls already described. These end-walls participate in forming that part of the uptake sections opposite the chill boxes referred to. The uptakes are formed on the other two sides by the lower parts of the iront and back wing-walls which are extended downwardly toward another passage leading directly to the regeneratcrs.
In actual practice, the steelmaking materials are charged through the front-wall doors into the hearth section. Fuel is introduced through the end-walls and directed toward the hearth, being fired first from one end and then the other for brief periods. Air to support combustion of the fuel and also to provide oxygen to support the chemical reactions which take place in the hearth is pre-heated by passing through regenerators also adapted to alternating handling of incoming air and outgoing gases. The regenerators are generally located some distance away from the hearth section and usually below and/or to one side of the hearth proper. The regenerator system is not here described because it is not directly related to the teachings of this invention. After pre-heating, the air is carried by various constructions from the regenerators to the lower sections ci the uptake passages previously described which then function to carry the said pre-heated air to juncture with the fuel. The Waste gases leaving the hearth section pass through the uptakes on the opposite end from the incoming air on their way back to the regenerative system.
In existing open-hearth furnace end structures the uptake passage is generally divided into two or more parts separated by a heavy refractory brick arch and wall which strengthens the structure and helps support brickwork about the chill boxes at the ends of the hearth section. This center wall has been used in the past to support so called doghouses of refractory material surrounding the fuel-introducing agencies to protcot them from the high temperatures of the combustion products which pass around them in leaving the furnace. Considerable bailling and channeling of the gases resulted because of this obstruction in the furnace ends.
This invention contemplates rebuilding the furnace end structures without changing the outside dimensions of the furnace to secure additional furnace capacity or increased uptake capacity, or both, as required by the particular furnace. It also contemplates the construction of new furnaces within the teachings of this invention. in. accomplishing these general objectives, the furnace ends are reconstructed to provide a single uptake passage shaped in a particular manner to provide an even flow of air to the fuel-introducing agencies. At the same time erosion of the refractory elements is lessened by reduction of baffling, channeling and the like of the exiting combustion gases.
This invention also contemplates a series of changes to the construction of the end sections of open hearth furnaces which may be applied singly or in cooperation with one another to increase the productive capacity of existing furnaces without requiring alteration to their outside dimensions, and secondly, to construction of new furnaces capable of higher production rates than comparably sized furnaces would otherwise have. In accomplishing these objectives, the separating constructions dividing the uptake into two or more parts are eliminated to provide a single uptake passage, which is unobstructed, and therefore has a greater carrying capacity. The passage is also shaped to provide a greater air capacity per square foot of cross section than the divided uptakes in addition to being free of channeling influences which tend to direct the air away from the fuel-introducing agencies.
The invention will be described in connection with the accompanying drawings some of which show the furnace somewhat diagrammatically for the purposes of clarity, and in which:
Fig. 1 is a plan view of an open-hearth furnace with the roof removed and embodying the invention;
Fig. 2 is a vertical sectional view of the furnace shown in Fig. 1;
Fig. 3 is a sectional view taken substantially along line 3-3 in Fig. 2;
Fig. 4 is a fragmentary plan view similar to Fig 1 showing another furnace end structure including the invention;
Fig. 5 is a view similar to Fig. 2 of the furnace end structure illustrated in Fig. 4;
Fig. 6 is a sectional view taken substantially along line E-G in Fig 5;
Fig. 7 is a sectional view taken substantially along line I-l in Fig. 8 showing a preferred end structure for a single burner:
Fig. 8 is a fragmentary plan view with the roof removed of a third furnace structure;
Fig. 9 is a fragmentary vertical sectional view through one end of a furnace exemplary of the invention herein and designated Furnace B in the specification;
Fig. i0 is a fragmentary horizontal sectional view taken substantially at the foreplate elevation of the furnace shown in Fig. 9:
Fig. ll is a fragmentary vertical sectional view through one end of a furnace exemplary of the invention herein and designated Furnace C in the specification;
Fig. l2 is a fragmentary horizontal sectional view taken substantially at the foreplate elevation of the furnace shown in Fig. 11;
Fig. 13 is a fragmentary vertical sectional view through one end of a furnace exemplary of the invention herein and designated Furnace D" in the specification, and
Figl i4 is a fragmentary horizontal sectional fifi view taken substantially at the foreplate elevation of the furnace shown in Fig. 13.
The open-hearth furnace illustrated in the drawings has the basic parts found in most furnaces of this type. The hearth section IIJ is adapted to contain the molten material from which the steel product is tapped. This hearth section is supported on a steel framework and built up of refractory and fused material to withstand the high heats of the furnaces. The front wall II of the furnace is provided with a number of charging doors I2 through which the ore, scrap and other material may be charged into the hearth section. A back Wall I3 (the pit side of the furnace) extends along generally parallel to the front wall of the furnace and these walls are joined by the furnace end structure comprising wing walls I4 and I5 and an end wall I6. The walls of the furnace are shown diagrammatically, in that the thickness of the brick is in.. dicated and the binding or buckstays on the outside of the walls are omitted since they are of usual construction.
At each end of the hearth section I0 a chill box I1 is provided to form the end of the hearth section. The chill box is adequately protected with refractory elements and is supported by a chill section wall IB which also serves as one of the bounding walls of the uptake passage 20. The bottom portion of the furnace end is the slag pit. Each end of the furnace is a duplicate of the other and as this description progresses reference to any part of the furnace end structure may refer to either end of the furnace. An arched roof I9 extends between the front and back walls and joins at its ends with the end walls.
As will be noted in the figures of the drawings, openings are provided in the end walls for the insertion of burners which introduce the fuel into the furnace. Thus as illustrated in Fig. l, each end wall is provided with two burners 22, each directed generally downwardly and inwardly toward the surface of the molten mass contained within the hearth section. Fuel from the burners 22 is mixed with air brought upwardly through the uptake 2t and is fired at the burner tip. Figs. 4 and 8 illustrate an open-hearth furnace having a single burner 22 located centrally in the end wall I6.
Open-hearth furnaces are operated by regen erating the air used to re the fuel. Thus air is passed over hot checkerwork which was previously heated by the exhaust gases from the furnace. The air is brought to a very high ternperature before mixture with the fuel, thereby increasing the temperature of the furnace. The uptake passages 20 convey this heated air through a generally vertical lower portion 24 which ends at the roof I9 of the furnace and then through the upper portion or throat 25 to the furnace hearth section. Previous and existing open-hearth furnaces utilize a multiple uptake passage made necessary by the existence of a heavy center wall and supporting arch which strengthened the furnace end structures and provided support for the chill boxes. Thus the brickwork under and around the chill box was of sprung arch construction with skew-backs resting against the center wall and the Wing walls. In the present construction, this center arch and wall are dispensed with and a single uptake passage is provided. Thus as seen in Figs. 1 and 2, the uptake passage is bounded by the wing walls, the end wall and the section wall and chill box section.
The passage is narrowed by the chill box protective wall 26 which may be suspended from the chill box section.
The throat of the open-hearth furnace here shown takes on a particular shape to convey the air from the vertical potrion 24 of the uptake passage to the hearth section. Thus as best seen in Fig. 1, each of the wing walls on the front and back of the furnace is provided with a portion 21 and 28 extending inwardly toward each other to restrict the throat. This provides a Venturitype action on the air passing through the throat expanding the air to the center of the furnace and preventing the air from hugging the walls of the furnace. This venturi commonly applied is not, however, required here and may be omitted provided the uptake is properly shaped in relation to the rest of the furnace. I prefer to omit this venturi. In Fig. 1, using two burners in each end of the furnace, the Venturi throat is positioncd above the chill box section so as to direct the air into the stream of fuel introduced by the burners. In Fig. 4 it will be noticed that the restricted throat providing the Venturi action has been omitted. In Fig. 4 the restricted portion is substantially above the end of the chill box section and provides a streamlining effect to passage of gas in either direction. Figs. '7 and 8 show the preferred form of end structure for a single burner at each end. Here the portion of the uptake opposite the chill box has been made generally trapeaoidal in shape by built-in portions 34 and 35 to direct the air toward the burner. Above the bridgowall 35, portions 21 and 28 streamline the front and rear wing walls between the uptake and the hearth.
In removing the center arch and wall a substantial volume within the furnace end structure is recovered. In those furnaces previously using multiple uptake passages, this recovered volume may be used for either or both of two purposes. If the uptake capacity of the furnace was inadequate, the recovered volume may be used to increase the capacity of the uptake section. or such recovered volume may be used to increase the capacity of the hearth section by moving the chill boxes closer to the end walls of the furnace. This capacity increase may be accomplished without rebuilding the major portion of the furnace and without changing its Outside dimensions.
As an example, it was found that the capacity of the hearth section could be increased slightly more than 5% by moving the chill boxes a total of 2 it. 1% outwardly from their former position. was done without incurring any decrees n t e. air capacity of the uptake passages. noted in Figs. i and 2, this change of capacity may be st in terms of a ratio of the length of the uptake passages to the length oi the furnace hearth. These dimensions are both measured at the mean sill plate level which is herein defined as the usual datum plane in open-hearth structures, that being the meen level of the lowest point in the charging door openings. The length of the uptake passages designated A' on the drawing is taken between the end steelwork of the chill box section and the buckstays or binding at the end of the furnace. The length of both uptales so measured is taken as the dimension A in the ratio. The dimension B is the total length of the furnace hearth between the outside of the steelworl: of the chill boxes. The total of A plus B will equal the length of the furnace inside the binding.
e i AS i had been most severe.
Previous to the removal of the center wall and arch, dimension A totaled 20 ft. 3 in. and dimension B, 49 ft. l0 in. 'I'he total is 70 ft. l in. between the end buckstays of the furnace which may not be moved outwardly because of limitation in space between adjacent furnaces. The ratio of A to B was 1 to 2.46 in existing furnaces of this size.
The chill boxes of this particular furnace were each moved outwardly 12% in., a total distance of 2 ft. 1% in. which changes dimension A to 18 ft. 11.41 in. and B was 5l ft. 11% in. The ratio of A to B was thus changed to 1 to 2.87 and the resultant increase in hearth capacity was slightly over 7%. This relationship is expressed in terms of bath length, uptake size and throat size for this particular furnace and for other furnaces in the specific examples given hereafter.
In other furnaces of the same size having the same hearth section, the chill boxes may be moved outwardly toward the end Wall as much as three feet each. This may be dpne without materially changing the uptake efficiency of the furnace ends and with substantial increase in the productive capacity of the furnace itself. Life of the refractory elements is materially increased since baffling and channeling of the gases leaving the furnace are in a large part eliminated.
The relationship of the position of the chill i boxes and the end walls of the furnace are thus changed to eil'ect a greater capacity without changing outside dimensions of the furnace. The changed position of the chill. boxes is herein dened as substantially close to the end walls to distinguish the new position from that originally found in furnaces employing multiple uptake passages. The chill boxes are nearer the end walls than in comparable size furnaces em ploying multiple uptake passages.
It has been found that the single uptake passage provides a more even iow of air to the fur nace. The volumes recovered by removal of the previously present center structures may be utilized as desired, either for increasing capacity oi the furnace by lengthening the hearth section or for increasing the uptake capacity at the furnace ends.
It has been found that gases passing out of the furnace have eroded the brickwork most severely i in the area about the end Wall and center dividing wall intersection in multiple uptake furnaces. This erosion may be materially decreased by shaping the uptake passage to decrease the velocity of the gases in the area where erosion previously in Figs. 7 and 8, the uptake passage is shown as trapezoidel in horizontal cross section with the bese or larger parallel side formed by the end wall of the furnace. The wing walls i4 and l5 may be shaped to provide the requisite tapering at the front and back of the furnace. Above the chill box, the wing wall taper is used to provide a streamlining leading from the uptake to the hearth section which further insures the rapid mixture of fuel and air as previously described. This shape allows expansion of outgoing gases adjacent the end wall, thus decreasing corrosion of the end wall refractory elements. Generally, the trapezoidal shape will be retained from the bottom of the chill box section to the top of the bridgewall 35 above the chill box. Incoming air is spread by this shape uptake, preventing air from hugging the walls of the furnace and providing better distribution thereof to the burners.
The previously mentioned increase in capacity of the hearth bed may be expressed in terms of the longitudinal length of the hearth bed inside the refractory of the bed measured at the foreplate elevation related to the total length of the furnace inside the structural binding. In the example given above, the length of the hearth bed (between steel) before the chill boxes were moved was 44 feet 6 inches and afterward it was 46 feet 7% inches (steel to steel). The new bed is approximately 66 of the total length of furnace (70 feet 1 inch) inside bindings. YFurther movement of the chill boxes toward the end walls will increase the hearth bed.
The uptake passage may be defined in relation to the longitudinal length of the furnace inside the bindings in terms of a ratio of the combined length of the uptakes inside brickwork measured at their narrowest section along the longitudinal axis of the furnace, to the above mentioned longitudinal dimension of the furnace. In the example previously given, the chill boxes were moved outwardly toward the end walls, thus increasing the hearth length and resulting in a combined length of uptake passage equal to approximately 16% of the total length of the furnace. Further movement of the chill boxes toward the end walls would result in a combined length of uptake passages as above defined equal to a smaller proportion of the total length of the furnace.
In forming a single uptake at each end of the furnace, the air capacity of the furnace was improved to permit a much greater firing rate. In the example, the cross sectional area in square feet of the single uptake when measured at its narrowest section was equal to 86% of the longitudinal length of the furnace inside the bindings in feet, and it is preferred not to exceed this proportion.
The furnaces shown in Figs. 9 through 14 are examples of actual furnaces made in accordance with this invention. The drawings are made to scale and may be used for determining dimensions where necessary although in the following tables the critical dimensions of the furnaces are given.
Each of the furnaces has a hearth bed lil formed with an end portion generally designated 4I which may be more accurately defined as a bridgewall 42 and a protective chill wall d3 about the end portion of the hearth. The foreplate elevation is designated on the drawings and ordinarily the bath extends up to this elevation so that the point adjacent the bridgewall 42 which defines the end of the bath is immediately apparent.
An arched roof structure 44 covers the main portion of the furnace over the bath and is joined to the end wall 45 of the furnace by a section 46 referred to as a skew-back. Between this section 45 and the bridgewall 42 is an area referred to as the throat of the furnace. The space between the end wall 45 and the protective chill wall 113 is referred to as an uptake here designated as 41. It will be noticed that in each of these furnaces the uptake passage is a single opening extending across the width of the furnace from the front wing wall 48 to the rear wing Wall 4a.
In each of the furnaces shown, the bath length has been increased by moving the ends of the hearth bed toward the end wall of the furnace. It should be understood that the end wall cannot be moved outwardly to increase the length of the furnace and that such length is determined by the bindings I). Thus the furnace length in- 8 side these bindings (total length outside of end brickwork) is thereby fixed.
The changes made herein are accomplished by rearranging the internal structure of the furnace. The bath length and area are thus increased. The uptake section is rearranged to provide an adequate air supply.
This increased bath area may be used in one of several ways. Steel may be made much more rapidly if the depth of the bath is less than it might be. Most furnaces in operation throughout this country are at present overcharged so that the bath depth is greater than desirable. The increased bath area may be used to lower the bath depth.
In instances where the bath depth is not such a critical factor, a greater amount of steel may be made by simply increasing the charge. Such has been the experience with the furnaces illustrated in that the steel production per hour has greatly increased.
The following tables give a comparison of these furnaces before and after they were changed in accordance with the present invention. Certain critical features relating to relative sizes of the bath, the uptakes, and the throat are also given. It should be understood that these examples are given as illustrative and are not to be taken as limiting.
Furnace A Some of the dimensions of this furnace are given in the foregoing description. A comparison is given below indicating the changes that have been made in the furnace in accordance with the invention herein.
Dimensions of Furnace Before i After l l Length of furnace outside brickwork Yl" i 70'l".
(inside steel bindings). i
Length of hearth at fore-plate elevaiO -iV t12"-11f2".
tion inside refractory.
Uptake double single.
areanarrmvest section. 83.4 sq. fi. 60.0 sq. ft. combinedlcngth l2-1 l0-7".
Throat-narrowcst section 72.5 sq. it. Y 65.2 sq. it.
Ratios:
Percent of total length of furnace 57.l% 60.1%.
outside brickwork occupied by hearth at foreplate elevation.
Percent of total length of furnace 18.33% 15.1%.
outside brlckwork occupied by length oi' both uptakes.
Combined length of uptake pas- 11.0 3.l lto 4.
sages to length of hearth between rcfractorics. l 1
Furnace B Dimensions of Furnace Before After Length of furnace outside hrlckwork 60'-0 (SW-4)".
(inside steel bindings).
Length of hearth at foreplate clcva- 30'48" 4VWO".
tion inside refractory.
Uptake,. double single.
area-narrowcst section ft 42.75 sq it combined length -0".
Throatnarrowest section. 40 sq. ft.l
Ratios:
Percent of total length of furnace 68.3%.
outside brickwork occupied by hearth at foreplate elevation.
Percent of total lcgnth of furnace 10%.
outside brlckwork occupied by length of both uptakes.
Combined length of uptake gassagcs to length of hearth l to 2.71 l to 6.83.
etwecn rcfractories. l
l Approximately.
aovasea 9 Furnace C Dimensions of Furnace Before Leng-th of furnace outside brickwork work (inside steal bindings) Length oi' hearth at foreplaie elevation inside refractory Uptake area-narrowcst section combined length4 'Phroat-narrowest section Ratios:
Percent of total length of furnace outside brickwork occupied by hearth at foreplate clavation Percent of total length of furnace outside brickwork oecu pied by length of both uptakes. Combined length ol' uptake passages to length of hearth between telractories l to 2.46 l to 6.82.
l Approximately.
Furnace D I Dimensions of Furnace pass to length of hearth betwcrri rch-'loteries 1 Approxii ly.
While this invention is susceptible of embodiment in many different forms, there has been shown in the drawings and described in detail onlir specific embodiments with the understanding that the present disclosure is to be considered as an exemplificatio-n of the principles of the invention and is not intended to limit the invention to the embodiments illustrated. The scope of the invention will be pointed out in the appended ciaims.
I claim:
1. An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end wall joined together to form a furnace end section at cach end of the hearth section. each furnace cud section having a single uptake passage for conducting air to the hearth section, said furnace having a throat above the ends of the hearth communicating with the uptake passage and hearth bed. said hearth bed having a length measured between rei'ractories at the forep-late elevation equal to between 6D% to 75% of the total furnace length inside bindings and a combined length of uptake passages equal to between 8% to 15% of said furnace length, the ratio of said uptake passage length to said hearth length being between 1 to- 4 and l to 8.6 and said throat having an area in its narrowest section at least substantially as large as the narrowest section of said uptake passage, the minimum horizontal dimension of said throat approaching the width of the uptake passage.
Gil
2. An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end Wall joined together to form a furnace end section at each end of the hearth section, each furnace end section having a single uptake passage for conducting air to the hearth section, said furnace having a throat above the ends of the hearth communicating with thc uptake passage and hearth bed, said hearth bed having a length measured 'between refractories at the foreplate elevation such that the combined length of the uptake passages, at the same elevation taken therefrom is equivalent to more than 45% of the furnace length measured inside its bindings, said throat area at its narrowest section being at least substantially as large as the narrowest section of said uptake passage, the minimum horizontal dimension of said throat appreaching the Width of the uptake passage.
3. An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end wall joined together to form a furnace end section at each end of the hearth section, each furnace end section having a single uptake passage for conducting air to thc hearth section, said furnace having a throat above the ends of the hearth communicating with the uptake passage and hearth bed, said hearth bed being relatively long `with relation to the furnace length, the length of the hearth bed measured between rcfractories at the foreplate elevation being at least four times the combined length of the uptake passages measured between reiractories at the foreplate elevation; and said throat having an area at its narrowest section at leastj substantially as large as the narrowest section of said uptake passage, the minimum horizontal dimension of said throat approaching the width of the uptake passage.
4. An open hearth furnace comprising a hearth section having a. hearth bed and an end section at each end of the furnace having a single uptak passage for conducting air to thc hearth section, said furnace having a throat above each end of the hearth section communicating with the uptake passage and the hearth bed, said hearth bed being relatively long with relation to the furnace length and having.r a length between refractories at the foreplatc elevation in excess of of the furnace length between bindings with a combined uptake length less than 15% of said furnace length, said throat having an arca at its narrowest section at least substantially as large as the narrowest section of the uptake passage, the minimum horizontal dimension of said throat approaching the width of the uptake passage.
5. An open hearth furnace as set .forth in claim 4 in which the hearth bed as specified occupies at least of said furnace length.
6. An open hearth furnace as set forth in claim 4 in which thc hearth bed as specified occupies between 65% and 75.3% of said furnace length.
7. An open hearth furnace comprising a hearth section with a chill box at each end, wing Ywalls and an end Wall joined together to form a fur nace end section adjoining said hearth section, a section wall around and under each chill box and extending between said wing Walls, said walls forming a single uptake passage at each end of the furnace for conducting air to the hearth section, means for introducing air to said uptake passages, a fuel supply at each end of the furnace for directing fuel toward `the hearth section, the length of the hearth section between the metal of the chill boxes on the hearthsidc oi each measured at the sill plate elevation being about 2.8'7 times the combined length of the uptake passages between metal, the passage from the uptake passage to the hearth being at least substantially as large as the uptake passage and the minimum horizontal dimension of said throat approaching the width of the uptake passage.
8. An open hearth furnace as set forth in claim 7 in which the hearth bed between refractories at the foreplate elevation occupies between about 60 to 75% of the length of the furnace inside structural bindings.
9. An open hearth furnace having a hearth section and a fuel supply at each end of the furnace, a single uptake passage at each end of the furnace communicating with the hearth section and an air supply, said uptake passages having a combined length at their narrowest section inside brickwork measured in the direction along the longitudinal axis of the furnace of not more than 16 times the total length of the furnace inside bindings measured at the foreplate line.
10. An open hearth furnace comprising a hearth section having a hearth bed, wing walls and an end wall joined together to form a furnace end section at each end of the hearth section, each furnace end section having a single uptake passage for conducting air to the hearth section, said furnace having a throat above the ends of the hearth communicating with the uptake passage and hearth bed, said hearth bed having a length measured between refraetories at the foreplate elevation equal to between 60% to 75% of the total furnace length inside bindings and a combined length of uptake passages equal to between 8% to 15% of said furnace length, the ratio of said uptake passage length to said hearth length being between 1 to 4 and 1 to 8.6 and said throat having an area in its narrowest section at least substantially as large as the narrowest section of said uptake passage.
References Cited in the file of this patent UNITED STATES PATENTS Number Name Date 1,501,532 Egler July 15, 1924 1,564,049 Davies Dec. 1, 1925 2,169,163 Putnam Aug. 8, 1939 2,226,922 Chambers et al Dec. 31, 1940 2,385,261 Crowe Sept. 18, 1945 2,429,880 Hays Oct. 28, 1947 2,548,908 Pollen Apr. 17, 1951
US343874A 1953-03-23 1953-03-23 Furnace structure Expired - Lifetime US2679389A (en)

Priority Applications (2)

Application Number Priority Date Filing Date Title
US343874A US2679389A (en) 1953-03-23 1953-03-23 Furnace structure
US88311859 USRE24859E (en) 1953-03-23 1959-08-11 lu ellen

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US343874A US2679389A (en) 1953-03-23 1953-03-23 Furnace structure

Publications (1)

Publication Number Publication Date
US2679389A true US2679389A (en) 1954-05-25

Family

ID=23348059

Family Applications (1)

Application Number Title Priority Date Filing Date
US343874A Expired - Lifetime US2679389A (en) 1953-03-23 1953-03-23 Furnace structure

Country Status (1)

Country Link
US (1) US2679389A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3204938A (en) * 1962-07-16 1965-09-07 Maerz Ofenbau Hearth-type furnace, particularly siemens-martin furnace
CN104803581A (en) * 2014-01-27 2015-07-29 索尔格投资有限及两合公司 Regenerator for glass melting tank
US20210024398A1 (en) * 2018-06-21 2021-01-28 Jushi Group Co., Ltd. Glass fiber tank kiln passage crown structure

Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1501532A (en) * 1922-10-16 1924-07-15 Nickolas F Egler Furnace
US1564049A (en) * 1922-04-06 1925-12-01 Jr Caleb Davies Open-hearth furnace
US2169163A (en) * 1938-05-21 1939-08-08 Republic Steel Corp Open hearth furnace
US2226922A (en) * 1939-09-18 1940-12-31 Thomas A Chambers Regenerator furnace
US2385261A (en) * 1942-09-02 1945-09-18 Crowe John Marshall Open-hearth furnace and method of operation
US2429880A (en) * 1945-01-05 1947-10-28 Carnegie Illinois Steel Corp Method for operating sectionable heat exchangers
US2548908A (en) * 1945-05-18 1951-04-17 Detrick M H Co Port end construction for openhearth furnaces

Patent Citations (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1564049A (en) * 1922-04-06 1925-12-01 Jr Caleb Davies Open-hearth furnace
US1501532A (en) * 1922-10-16 1924-07-15 Nickolas F Egler Furnace
US2169163A (en) * 1938-05-21 1939-08-08 Republic Steel Corp Open hearth furnace
US2226922A (en) * 1939-09-18 1940-12-31 Thomas A Chambers Regenerator furnace
US2385261A (en) * 1942-09-02 1945-09-18 Crowe John Marshall Open-hearth furnace and method of operation
US2429880A (en) * 1945-01-05 1947-10-28 Carnegie Illinois Steel Corp Method for operating sectionable heat exchangers
US2548908A (en) * 1945-05-18 1951-04-17 Detrick M H Co Port end construction for openhearth furnaces

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3204938A (en) * 1962-07-16 1965-09-07 Maerz Ofenbau Hearth-type furnace, particularly siemens-martin furnace
CN104803581A (en) * 2014-01-27 2015-07-29 索尔格投资有限及两合公司 Regenerator for glass melting tank
US20150210581A1 (en) * 2014-01-27 2015-07-30 Beteiligungen Sorg Gmbh & Co. Kg Regenerator for glass melting tanks
US9815727B2 (en) * 2014-01-27 2017-11-14 Beteiligungen Sorg Gmbh & Co. Kg Regenerator for glass melting tanks
US20210024398A1 (en) * 2018-06-21 2021-01-28 Jushi Group Co., Ltd. Glass fiber tank kiln passage crown structure

Similar Documents

Publication Publication Date Title
RU2127321C1 (en) Method of steel making and device for its embodiment
US1948696A (en) Vertical shaft furnace
US2679389A (en) Furnace structure
US2084830A (en) Metallurgical process and apparatus
US3603571A (en) Apparatus for melting scrap metal
US3759699A (en) Ting means process for melting scrap with a plurality of oppositely directed hea
USRE24859E (en) lu ellen
RU2299244C2 (en) Modular furnace
US2970829A (en) Method of operation of a top-fired open hearth furnace
US2622863A (en) Rotary hearth furnace
US2182498A (en) Method of interoducing fuel into an open hearth furnace
US2788964A (en) Metallurgical furnace
US2771285A (en) Regenerator
US2661198A (en) Furnace end structure
US1991008A (en) Method and apparatus for producing low carbon metal
US3113765A (en) Melting and refining furnace and method of operation
US2176270A (en) Open hearth furnace
US2017480A (en) Metallurgical furnace
GB1427646A (en) Sub-hearth construction for metallurgical furnaces
US2534825A (en) Smelting furnace
US2866628A (en) Open hearth furnace
US769712A (en) Tilting metallurgical furnace.
US3282580A (en) Refractory bottom for open hearth furnace
US2220585A (en) Continuous heating furnace
US3438620A (en) Reveberatory copper-matte smelting furnace