US2673083A - Cooling apparatus for blast furnace hearths - Google Patents

Cooling apparatus for blast furnace hearths Download PDF

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US2673083A
US2673083A US279782A US27978252A US2673083A US 2673083 A US2673083 A US 2673083A US 279782 A US279782 A US 279782A US 27978252 A US27978252 A US 27978252A US 2673083 A US2673083 A US 2673083A
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hearth
graphite
carbon
furnace
cooling
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US279782A
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Herbert G Macpherson
Russell D Westbrook
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Union Carbide Corp
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Union Carbide and Carbon Corp
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    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21BMANUFACTURE OF IRON OR STEEL
    • C21B7/00Blast furnaces
    • C21B7/10Cooling; Devices therefor
    • C21B7/106Cooling of the furnace bottom

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  • This linvention relates to means Yfor cooling the @bottoms of carbon linedhearths of metallurgical furnaces and particularly to means for cooling carbon lined blast furnace hearths.
  • the molten metal undergoing treatment is retained ⁇ in the hearth of a furnace, such as a blast furrnace.
  • This metal in the hearth or crucible reaches temperatures ⁇ greatly in excess of its melting point.
  • Tempera- -tures in the sides and bottom of the hearth are voften higher than the melting point of the metal at points in the hearth a considerable distance from the pool of molten metal.
  • fthesides and bottom of the hearth are made of brick and in time the molten metal nds its way between these bricks. The metal will, of course, remain in the molten state until it is cooled be- -low its melting pointfby the transfer of heat to ⁇ the sides and bottom of the hearth.
  • the 'object of the invention is ⁇ accomplished by placing a block orlayer ofgraphtebetween there-clay bricks forming the bottom ci" the -l1earth and the vcarbon lining 4and providing a cooling medium in heat absorbing relationship with the periphery of the graphite. Becauseof the good thermal conductivity of ⁇ thegraphitey heat is conducted away from the center ofthe hearth rapidly'enough to lower the temperature at the carbon-graphite interface below the melt- 4ing point of the metal. The heat conducted ⁇ away from the center of the graphite is dissipated by the cooling medium.
  • rIhe hearth I of thefurnace 2 consists. of sides :and a vbottom -6 of Jlire-clay brick.
  • a carbon lining li suitably of large ⁇ carbon sectionstoricarbon bricks, extends Aacross the lbottom of lathe hearth l, and carbon bricks 5 line the sides of the hearth.
  • a layer of graphite l between the carbon lining #i and fire-clay bricks s conducts the heat transferred from the molten metal 8 to the carbon lining 4 away from the center of the hearth to the cooling coils 9 where it is dissipated by the cooling medium in the coils.
  • the advantages of the invention will be apparent from the comparisons given below.
  • the temperatures and other data on which the comparisons are based are approximate since they are calculated from experimental results obtained with a model of a blast furnace hearth.
  • the hearth for which the comparative values are calculated contains molten iron at a temperature of from about 1500" C. to about 1600 C. and has an outside diameter of twenty-six feet and an inside diameter of twenty feet. Tempera- 3 tures in the hearth are those occurring along the center line of the hearth.
  • a lining of carbon 50 inches thick on the bottom of the hearth separates the fire-clay brick and the pool of molten iron.
  • the temperature at the carbcn-reclay brick interface when the periphery of the carbon is cooled to 600 C. reaches about l300 C. This temperature is above the melting point of iron which is between 1100 C. to 1150 C.
  • the telnperature of the carbon-fireclay brick interface is about 1165 C. or slightly above the melting point of iron.
  • the temperature at the carbongraphite interface is about 900 C. and at the graphite-reclay brick interface about 800 C. if the periphery of the graphite is maintained by cooling at 600 C.
  • a temperature safely below the melting point of iron is obtained at the interface of the fty inch thick carbon lining and graphite layer installed according to the invention.
  • the temperature at the interface of the seventy-six inch carbon lining and the fire-clay brick in the absence of the cooling means of the invention is above the melting point of iron.
  • the thickness of the layers of carbon and graphite may be varied over a wide range to meet the requirements of a particular furnace.
  • the graphite should be so shaped that a considerable portion of it provides a continuous path for the heat from the center of the hearth tothe periphery. Joints or other discontinuities in the graphite will lessen its heat conductivity.
  • the dissipation of the heat conducted to the periphery of the graphite can be accomplished by several conventional procedures. Metal pipes in contact with the periphery of the graphite and through which water or steam is circulated are satisfactory.
  • the periphery of the graphite can also be cooled, for example, by passing a stream of a cooling fluid in direct contact with it.
  • heat may also be dissipated, at least in part, by
  • a cooling means for the bottom of the hearth of said furnace which comprises graphite placed between the carbon lining and bricks of the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said graphite being in contact with said carbon lining, and a cooling medium disposed in heat absorbing relationship with said graphite adjacent the periphery of said hearth.
  • a cooling means for the bottom of the hearth of said furnace which comprises graphite placed between the carbon lining and bricks of the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said graphite being in contact With said carbon lining, and cooling coils in contact with said graphite adjacent the periphery of said hearth.
  • a cooling means for the bottom of the hearth of said furnace which comprises a layer of graphite placed between the carbon lining and bricks of the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said layer of graphite being in contact with said carbon lining, and cooling coils in contact with said graphite layer .adjacent the periphery of said hearth.
  • a cooling means for the bottom of the hearth of said furnace which comprises a block of graphite placed between the carbon lining and bricks cf the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said block of graphite being in contact with said carbon lining, and cooling cooils in contact with said graphite block adjacent the periphery of said hearth.
  • HERBERT G MACPHERSON. RUSSELL D. WESTBROOK.

Description

March 23, 1954 H. G. MacPHERsoN ET AL 2,673,083
COOLING APPARATUS FOR BLAST FURNACE HEARTHS Filed April l, 1952 lNVENTORS Herber'r G.Mac Pherson Russell D. Wesbrook ATTORNEY Patented Mar. 23, 1954 1MM-f En STAT-ss TEN T iO FF ITCSE COOLING APPARATUS FORv BLAST FURNACE AAHEARTH .poration of yNew York Application April l, 1952, Serial No;'279,782
(Cl. 26S-132) 44A Claims. f1
'This linvention relates to means Yfor cooling the @bottoms of carbon linedhearths of metallurgical furnaces and particularly to means for cooling carbon lined blast furnace hearths.
"In the production or processing ofmetals,l the molten metal undergoing treatment is retained `in the hearth of a furnace, such as a blast furrnace. This metal in the hearth or crucible, as it is sometimes called, reaches temperatures `greatly in excess of its melting point. Tempera- -tures in the sides and bottom of the hearth are voften higher than the melting point of the metal at points in the hearth a considerable distance from the pool of molten metal. Conventionally. fthesides and bottom of the hearth are made of brick and in time the molten metal nds its way between these bricks. The metal will, of course, remain in the molten state until it is cooled be- -low its melting pointfby the transfer of heat to `the sides and bottom of the hearth.
In conventional furnace hearths of `hre-clay "brick, the sides are thick enough toprevent the '*heating ofthe outside bricks `above themelting pointof the metal. This measure prevents the molten metal from running out of the furnace. Similarprecautions are taken with the bottom of the hearth. Commonly, the sides of the hearth are cooled by heat exchangers in contact with the periphery `of the hearth'to give added protection against the escape of the metal.
Cooling the outside of the bottom of the hearth .-as is done around thesides has littleneifect on the temperature of the bricks in the center of vthe'bottornef the hearth. This is truebecause .of the poor heat conductivity of the fire-clay `ubricks andthe relatively largerrdistance `from the center to the outside of the bottom of the hearth. Efforts to cool the bottom of the hearth with conventional heat exchangers embedded therein have not been too successful. Difficulty is encountered in finding materials capable of withstanding the temperatures in the bottom of the hearth. For example, in a blast furnace these temperatures may be in the neighborhood of 1500 C. Maintenance of such a system is also a serious drawback to its use since the furnace would have to be shut down and the bottom of the hearth torn up to make repairs on pipes which were leaking or otherwise defective.
When the hearth of the furnace is lined with carbon, the difficulties encountered in cooling the bottom of the hearth do not diner greatly from those arising in the cooling of an unlined hearth. There is the added problem of preventing the ow of molten metal between the carbon lining and the iire-claybricks since this'resultsv in l'd-am- Aageto the carbon lining. The temperaturesrand `provide ameans of cooling the bottom'ofiacarbon lined hearth which will Aprovide .improved `protection againstthe escape of metal.
`The 'object of the invention is `accomplished by placing a block orlayer ofgraphtebetween there-clay bricks forming the bottom ci" the -l1earth and the vcarbon lining 4and providing a cooling medium in heat absorbing relationship with the periphery of the graphite. Becauseof the good thermal conductivity of `thegraphitey heat is conducted away from the center ofthe hearth rapidly'enough to lower the temperature at the carbon-graphite interface below the melt- 4ing point of the metal. The heat conducted `away from the center of the graphite is dissipated by the cooling medium.
The drawing illustrates theprinciples of the invention.
'In the drawing a sectional-view of a blast furnace which has a carbon lined hearth-andfis equippedwith the cooling means ofthe invention `is shown.
rIhe hearth I of thefurnace 2 consists. of sides :and a vbottom -6 of Jlire-clay brick. :A carbon lining li,suitably of large` carbon sectionstoricarbon bricks, extends Aacross the lbottom of lathe hearth l, and carbon bricks 5 line the sides of the hearth. A layer of graphite l between the carbon lining #i and fire-clay bricks s conducts the heat transferred from the molten metal 8 to the carbon lining 4 away from the center of the hearth to the cooling coils 9 where it is dissipated by the cooling medium in the coils.
The advantages of the invention will be apparent from the comparisons given below. The temperatures and other data on which the comparisons are based are approximate since they are calculated from experimental results obtained with a model of a blast furnace hearth. The hearth for which the comparative values are calculated contains molten iron at a temperature of from about 1500" C. to about 1600 C. and has an outside diameter of twenty-six feet and an inside diameter of twenty feet. Tempera- 3 tures in the hearth are those occurring along the center line of the hearth.
In the first instance a lining of carbon 50 inches thick on the bottom of the hearth separates the fire-clay brick and the pool of molten iron. The temperature at the carbcn-reclay brick interface when the periphery of the carbon is cooled to 600 C. reaches about l300 C. This temperature is above the melting point of iron which is between 1100 C. to 1150 C. When the thickness of the carbon lining is increased to 76 inches and the temperature of the periphery of the carbon again is cooled to 600 C., the telnperature of the carbon-fireclay brick interface is about 1165 C. or slightly above the melting point of iron.
But when a layer of graphite 23 inches thick is inserted between the fty inch thick carbon lining and the lire-clay brick according to the invention, the temperature at the carbongraphite interface is about 900 C. and at the graphite-reclay brick interface about 800 C. if the periphery of the graphite is maintained by cooling at 600 C. Thus it can be seen that a temperature safely below the melting point of iron is obtained at the interface of the fty inch thick carbon lining and graphite layer installed according to the invention. Under similar conditions the temperature at the interface of the seventy-six inch carbon lining and the lire-clay brick in the absence of the cooling means of the invention is above the melting point of iron.
It will be understood that the thickness of the layers of carbon and graphite may be varied over a wide range to meet the requirements of a particular furnace. Preferably, the graphite should be so shaped that a considerable portion of it provides a continuous path for the heat from the center of the hearth tothe periphery. Joints or other discontinuities in the graphite will lessen its heat conductivity.
The dissipation of the heat conducted to the periphery of the graphite can be accomplished by several conventional procedures. Metal pipes in contact with the periphery of the graphite and through which water or steam is circulated are satisfactory. The periphery of the graphite can also be cooled, for example, by passing a stream of a cooling fluid in direct contact with it. The
heat may also be dissipated, at least in part, by
directing a stream of a cooling medium, for ex1 ample, air, under and along the layer of graphite. This latter arrangement is particularly efcient with a blast furnace having a hearth built at an elevation above the ground so that there is a free space directly below the graphite.
What is claimed is:
1. In a metallurgical furnace which has a carbon lining on the bottom of the hearth of said furnace, a cooling means for the bottom of the hearth of said furnace Which comprises graphite placed between the carbon lining and bricks of the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said graphite being in contact with said carbon lining, and a cooling medium disposed in heat absorbing relationship with said graphite adjacent the periphery of said hearth.
2. In a metallurgical furnace which has a carbon lining on the bottom of the hearth of said furnace, a cooling means for the bottom of the hearth of said furnace which comprises graphite placed between the carbon lining and bricks of the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said graphite being in contact With said carbon lining, and cooling coils in contact with said graphite adjacent the periphery of said hearth.
3. In a metallurgical furnace which has a carbon lining on the bottom of the hearth of said furnace, a cooling means for the bottom of the hearth of said furnace which comprises a layer of graphite placed between the carbon lining and bricks of the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said layer of graphite being in contact with said carbon lining, and cooling coils in contact with said graphite layer .adjacent the periphery of said hearth.
4. In a metallurgical furnace Which has a carbon lining on the bottom of the hearth of said furnace, a cooling means for the bottom of the hearth of said furnace which comprises a block of graphite placed between the carbon lining and bricks cf the bottom of said hearth and extending from the center of said hearth to the periphery of said hearth, said block of graphite being in contact with said carbon lining, and cooling cooils in contact with said graphite block adjacent the periphery of said hearth.
HERBERT G. MACPHERSON. RUSSELL D. WESTBROOK.
References Cited in the le of this patent UNITED STATES PATENTS Number Name Date 1,775,396 Jackman et al Sept. 9, 1930 1,937,940 Boynton Dec. 5, 1933 1 1,940,115 Broadweu Dec. 19, 1933 2,423,898 McLain July 15, 1947 2,532,322 Mcnanin Dec. 5, o
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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2789881A (en) * 1953-07-16 1957-04-23 Combustion Eng Method of operating a chemical recovery smelter furnace
US3045996A (en) * 1959-11-19 1962-07-24 Koppers Co Inc Ultra high pressure blast furnace
US3578302A (en) * 1966-06-27 1971-05-11 Anatoly Alexeevich Cherney Gas cupola furnace with a special superheat hearth
US3599951A (en) * 1968-11-27 1971-08-17 Inland Steel Co Blast furnace hearth
DE2162893A1 (en) * 1970-12-18 1972-07-13 Koninklijke Hoogovens En Staal Floor for a shaft furnace and method for cooling the same
US3705713A (en) * 1969-11-12 1972-12-12 Demag Ag Bottom cooling device for shaft furnaces

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1775396A (en) * 1928-05-31 1930-09-09 Vesuvius Crucible Co Refractory brick
US1937940A (en) * 1930-05-03 1933-12-05 Brassert & Co Bottom for boiler furnaces
US1940115A (en) * 1930-10-08 1933-12-19 Republic Carbon Company Bottom for slag tap furnaces
US2423898A (en) * 1944-02-18 1947-07-15 Carnegie Illinois Steel Corp Refractory bottom for metallurgical furnaces
US2532322A (en) * 1946-06-01 1950-12-05 Tennessee Valley Authority Phosphorus combustion furnace

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1775396A (en) * 1928-05-31 1930-09-09 Vesuvius Crucible Co Refractory brick
US1937940A (en) * 1930-05-03 1933-12-05 Brassert & Co Bottom for boiler furnaces
US1940115A (en) * 1930-10-08 1933-12-19 Republic Carbon Company Bottom for slag tap furnaces
US2423898A (en) * 1944-02-18 1947-07-15 Carnegie Illinois Steel Corp Refractory bottom for metallurgical furnaces
US2532322A (en) * 1946-06-01 1950-12-05 Tennessee Valley Authority Phosphorus combustion furnace

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2789881A (en) * 1953-07-16 1957-04-23 Combustion Eng Method of operating a chemical recovery smelter furnace
US3045996A (en) * 1959-11-19 1962-07-24 Koppers Co Inc Ultra high pressure blast furnace
US3578302A (en) * 1966-06-27 1971-05-11 Anatoly Alexeevich Cherney Gas cupola furnace with a special superheat hearth
US3599951A (en) * 1968-11-27 1971-08-17 Inland Steel Co Blast furnace hearth
US3705713A (en) * 1969-11-12 1972-12-12 Demag Ag Bottom cooling device for shaft furnaces
DE2162893A1 (en) * 1970-12-18 1972-07-13 Koninklijke Hoogovens En Staal Floor for a shaft furnace and method for cooling the same
US3752638A (en) * 1970-12-18 1973-08-14 Koninklijke Hoogovens En Staal Bottom of a shaft furnace, a shaft furnace provided with such a bottom and a method for cooling such a bottom

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