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Publication numberUS2408945 A
Publication typeGrant
Publication dateOct 8, 1946
Filing dateMay 9, 1945
Priority dateMay 9, 1945
Publication numberUS 2408945 A, US 2408945A, US-A-2408945, US2408945 A, US2408945A
InventorsGrilli John P, Mohr Jr Albert
Original AssigneeGrilli John P, Mohr Jr Albert
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Blast-furnace charging system
US 2408945 A
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Description  (OCR text may contain errors)

Oct. 8, 1946. A. MOHR, JR., EI'AL 2,408,945

BLAST FURNACE CHARGING SYSTEM Filed May 9, 1945 2 Sheets-Sheet l COMPRESSOR Oct. 8, 1946. A. Moi-1R, JR., .ETAL I 2,403,945 I BLAST FURNACE CHARGING SYSTEM Filed May 9, 1945 v 2 Sheets-Sheet 2 Patented Oct. 8, 1946 UNITED STATES PATENT OFFICE BLAST-FURNACE CHARGING SYSTEM Albert Mohr, J12, and John P. Grilli, Chicago, Ill.

Application May 9, 1945, Serial No. 592,908

8 Claims.

Heretofore, iron blast-furnaces have incorporated an upper, material-receiving and distributing-hopper, its companion conical bell intermittently closing and opening the bottom of such hopper, automatic means to actuat such bell, a lower larger discharge-hopper at the top of the furnace adapted to receive the material delivered to it from such upper hopper and to dump it into the top of the furnace, a similar bell coactins with such large hopper, and means to open the bell intermittently automatically for the delivery of the material into the furnace, such a furnace ordinarily operating at an internal pressure in its upper portion of about one-half pound to about one and ne-half pounds per square-inch.

Recently, it has been discovered that the functioning of such a blast-furnace can be materially improved by increasing the gas pressure in the top portion of the furnace to from about 10 lbs. to lbs. per square-inch, but, when it was attempted to work such old style blast-furnace at the indicated higher pressure, the conditions of operation were so changed, due in part to the gases and to the large amount of extremely abrasive dust in them, that it was impossible to have the furnace perform satisfactorily.

The outstanding difiiculties encountered were in large measure due to the warping oi the lower, big discharge-hopper and of its comp-anion bell, cutting of the coasting seating-surfaces of such hopper and its bell, and, due to the damage and warping of these seating-surfaces, gas-leakages developed between the bell and hopper making it practically impossible to dump the material efiectively on the small bell of the upper hoppe on to the lower large bell.

In some cases, a gas connection was installed to equalize the gas pressures below and above the big bell, which equalizer line would be closed to shut off the supply of gas and-automatic means were provided to relieve the pressure between the small bell and the large bell, whereupon it was then possible to open th small bell and dump the contents of its hopper into the lower hopper, which dumping action consumes about ten seconds, then the bell is held in its dumping position for about the succeeding ten seconds in order that all material may slide off the upper hopper, and then the bell is closed consuming an additional ten seconds.

In th course of a day the small bell of a blastfurnace is opened and closed approximately 1152 times consuming about 576 minutes of the day, and, during these periods, the seating-junction between the large bell and the large hopper is subjected to a difierential pressure of about 10 lbs. or more per square-inch.

From calculations, any openings, passages or leakages between such large bell and its hopper are scoured with heavy abrasive hot gases traveling at a speed of about 1200 ft. per second and it 2 will be readily appreciated that this dirty gas can cut and injure steel, such as that of the hopper and bell, almost as rapidly as a cutting torch.

Supplementing the above-mentioned dimculties of these earlier systems are those due to the large and irregular sections of the big bell and hopper which cannot be designed and constructed of a uniform metal thickness due to their great size and weight, these large bells being from about 14 ft. to 15- ft. in diameter and varying in thickness from six inches to two inches, the complementary large hoppers ranging in diameter from 13 ft. to 15 ft. and being approximately 10 ft. to 13 ft. high.

As these large and heavy castings are subject in operation to varying unpredictable temperature cycles, their shapes are constantly changing, and also, as a result of these temperature modifications, the bell and associated hopper are not expanding and contracting symmetrically with each other and therefore their seating-surfaces are never tight. 7

In View of all of the above damaging factors and difiiculties, it was impossible to have an operating period of the furnace of longer than five days without shut-downs for repairs and minor changes to equipment, and finally, the furnace top charging-apparatus reached such a stage of damage and injury that it was necessary to take the furnace ofi and make major repairs to the charging-equipment.

The present innovatory, improved and advantageous charging-system constituting the subject matter of this invention, on the other hand, is capable of operating for relatively-long periods of time with none of the serious difficulties which were heretofore experienced.

In order that those skilled in this art may have a full understanding of such invention, both from structural and functional standpoints, a present preferred embodiment of the invention is disclosed in the novel construction and system illustrated in the accompanying drawings, forming a part of this specification, and to which reference should be had in connection with the following detailed description, and, for simplicity, like reference numerals have been employed to designate the same parts of the structure throughout the several views.

In these drawings:

Figure 1 is an elevation of the novel blastfurnace charging-system;

Figure 2 is a side. View of the upper portion only of the structure illustrated in Figure 1;

Figure 3 is a larger-scale, fragmentary, vertical section through the portion of the chargingequipment incorporating the present invention; and

Figure 4 illustrates one of the means for auto- 3 matically operating the valves of the new part of the system.

The upper portion of the blast-furnace has been designated by the reference numeral its cone top by the numeral l2, and the dischargeflues for the hot abrasive gases have been denominated I3, I 3.

The bottom of the huge, lower discharge-hopper I4 is normally closed by the massive conicalbell I5, the contacting bottom edge of the hopper and the marginal portion of the upper surface of the bell constituting the pressure-sealing means between those parts, such bell, as is usual, being automatically, intermittently lowered and raised to open and close it, respectively, by a rod l6 secured to the top of the bell and actuated by a lever 34 and connecting mechanism 25 all of usual and ordinary construction and mode of operation.

The top of such hopper I4 is normally closed by a truncated conical-shell l8, an intermediate hopper 2| and its bell or valve 22, raised and lowered at intervals, as indicated by dotted lines in Figure 3, by a hollow rod 23, accommodating the rod inside of it, such rod 23 being actuated in well known manner up and down by a lever I1 and connecting means l3.

Above hopper 2| is a shell 26 at the top of which is an upper, rotary, receiving and distributing hopper 21, the bottom of which is ordinarily closed by a companion conical-bel1 28, such hopper and shel1 being in pressure-tight relation with one another, and over hopper 21 is another shell 29 receiving material from above through a hopper 3| into which the skip-tub 32 intermittently and automatically delivers its charges or loads of material.

Such bell 28 is moved up and down, to close and open it, and it also rotates intermittently with its hopper, such vertica1 movement being brought about by its hollow supporting rod 33 actuated by its levers 24 and connecting means 35, all of such mechanism being well known in the art.

' As will be readily understood, the space between the bells 22 and 23 constitutes an upper chamber 36 and the space between the large lower bell l5 and the intermediate bell 22 comprises a lower chamber 31,

By means hitherto in common use, shown diagrammatically in Figure l, at least some of the hot, abrasive and grinding gases leaving the furactive Opening the valve, and the other when supplied with current closing the valve.

Valve 44 is of like construction having its pair of companion magnets 52 and 53.

The rotation of hopper 21, the operation of its bell 28, and the actuation of the larger bel1 I! are all brought about by the commonplac method employing the well-known electric equipment including correct timing means represented in general or conventionally by the part characterized 54 in Figure 3.

Inasmuch as the opening and closing of the new intermediate bell 22 is effected by like or comparable means, it is unnecessary to illustrate it since it is in common'use in the art'in association with other bells and those skilled in this industry will encounter no difliculty in providing it.

In addition, the two valves 44 and are operated by electric-currents controlled as to their actions and timing by the same known and conventional relay mechanism 54, although in its broadest aspect the invention includes any manner of actuating the valves as referred to hereinafter.

The cycle of operation of this new and improved furnace charging-system is as follows:

The material to be fed or delivered into the furnace at intervals is carried up to the top of the furnace in the skip-bucket 32 which dumps it into the topmost introductory-hopper 3| from which it falls by gravity into the then bell-closed receiving and distributing hopper 21 which is thereupon rotated a fixed number of degrees, for example and then stops.

By the automatically-operated electric means referred to, the previously-open valve 44 is then closed and valv 46 is opened, this causing an equalization of the pressures in hopper 21 and in chamber 36 allowing the distributor small-bel1 28 to be opened, which takes place, and the contents of hopper 2| dumped into hopper 2| on top of its closed bell 22.

Valve 43 now closes and valve 44 opens thus equalizing the pressures above and below bell 22 nace through the outlet conduits |3, |3 are washed to free them from their scraping and rasping constituents and are cooled and are then compressed to about one pound greate pressure per square-inch than the specified gas pressure in the top portion of the furnace. Such cleaned, cooled, compressed gas is delivered through a pipe 33 and a pressure regulator 38, which maintains the gas at such one pound superpressure, into branched pipes 4| and 42. The former is lead into the top portion of chamber 31, and the latter connecting with the interior of chamber 36, pipe 4| being supplied with a manually-operated normally-open valve 43 which is closed only in case the furnace is shut down or under emergency conditions. Pipe 42 is equipped with an electrically opened and closed valve 44, and also fitted with the discharge pipe 45 to the external atmosphere, and provided with an electrically-operated valve 46.

Valve 46 is opened and closed by its gear 41 meshing with a rack 48 equipped with complementary electro-magnets 49 and 5|, the one when whereupon the latter opens and delivers the contents of-its hopper 2| on to the closed bel1 IS in the lower hopper l4, it being remembered that the gas pressure in hopper i4 is always about one pound greater than that in the top of the furnace into which its contents are discharged.

After having thus dumped the material in hopper 2| into hopper l4, bell or valve 22 closes ready to receive its next load during the subsequent opening of hell 28.

Usually eight skip-loads of material are thus charged and delivered sequentially on the large bell I5 in different angular locations thereon before such large bell is opened to discharge such plurality of accumulated skip-loads into the top of the furnace.

As can be well appreciated from what has been stated above relative to the cycle of operations, the space enclosed by the large bell l5 and its hopper I4 is always at a slightly greater clean and cool gas pressure than that in the furnace. By reason of any poor or defective seating between the large bell and its hopper, the downward gas-leakage will be relatively-cool, nonabrasive, inert gas into the furnace whereby comprevents injury to, or destruction of, the pressure;

sealing surfaces between the bell and hopper of the final dumping structure. The gas used for this purpose being inert prevents combustion from taking place in the spaces between the bells and in the top part of the furnace.

In this connection it may be noted that no two of the three hopper bells are open at the same time.

Those acquainted with this art will readily understand that the present invention, as defined by the appended claims, is not necessarily limited and restricted to the precise and exact details of structure and function described and. illustrated, and that reasonable modifications may be availed of without departure from the heart and essence of the invention and without the loss or sacrifice of any of its material benefits and advantages,

We claim:

1. In a blast-furnace charging-system having an upper receiving-hopper internally at atmospheric-pressure, its cooperating bell, actuatingmeans opening and closing said bell intermittently, alower delivery-hopper and its bell discharging into the top of the furnace, operatingmeans opening and closing said delivery-hopper bell intermittently, a conduit connecting said hoppers together, and means to feed charging material into said receiving-hopper intermittently, the novel improvement of the combination of means including a valve-construction in said conduit dividing said conduit into an upper chamber and a lower chamber, the latter including said delivery-hopper, 'means to open and close said valve-construction intermittently, means to feed substantially-nonabradant inert gas under pressure into said lower chamber and maintain the gas-pressure in said lower chamber at all times greater than the gas-pressure in the top portion of the furnace, means to feed substantially-nonabradant inert gas under said specified pressure into said upper chamber, means controlling said gas fed into said upper chamber to maintain equalized gas-pressures on opposite sides of said valve prior to and during the open condition of the latter, means connecting said upper chamber to the external-atmosphere, and means controlling the passage of gas from said first chamber to the atmosphere to provide atmospheric-pressure in said upper chamber on the underside of said receiving-hopper bell prior to and during the open condition of said bell.

2. The novel combination in a blast-furnace charging-system set forth in claim 1, in which said valve-construction includes an intermediate-hopper and its bell discontinuously receiving the charging material discharged from said receiving-hopper and interruptedly dumping it into said delivery-hopper.

3. In thecharging-system of a blast-furnace operating under a gas-pressure in its top portion of from about lbs. to about lbs. per squareinch, said charging-system having an upper receiving-hopper internally at approximately atmospheric-pressure and its bell, actuatingmeans intermittently open ng and closing said bell, a lower delivery-hopper and its bell discharging into the top portion of the furnace, a conduit connecting said hoppers together, and means to feed charging material intermittently into said receiving hopper, the novel improvement of the combination of an intermediatehopper and its bell in said conduit between said hoppers and dividing said conduit into an upper chamber and a lower chamber, the latter including said delivery hopper, said intermediate-hopper and its bell acquiring its material from said receiving-hopper and discharging it into said delivery-hopper, means to intermittently open and close said intermediate-hopper bell, means to deliver substantially-nonabradant inert gas at about one-pound pressure per square-inch greater than that in the top portion of the furnace into said lower chamber and maintain said specified gas-pressure therein during the operation of the furnace, means to feed substantially-nonabradant inert gas under said specified onepound excess pressure into said first chamber, means to control the feed of said gas into said first chamber to equalize the pressures on the opposite sides of said intermediate-hopper bell prior to its opening and while it remains open, means connecting said upper chamber to the external-atmosphere, and means controlling the passage of gas therethrough to the atmosphere to provide substantially atmospheric gas-pressure in said first chamber prior to the opening of said receiving-hopper bell and while the latter is open.

4. The novel improvement in a blast-furnace charging-system set forth in claim 3, in which said one-pound excess pressure gas is hot abrasive gas from the top portion of the furnace freed from its abrasive media, cooled and compressed.

5. In a blast-furnace charging-system of known type having an upper receiving-hopper and its bell, actuating-means opening and clos- 1 ing said bell intermittently, a lower deliveryhopper and its bell discharging into the top of the furnace, and operating-means opening and closing said delivery-hopper bell intermittently, the novel improvement of means for continuously maintaining the interior of said delivery-hopper with substantially-nonabradant inert gas at a super-atmospheric pressure at least equalling that in the top of the furnace during the operation of the latter.

6. The novel improvement in a blast-furnace charging-system set forth in claim 5, in which said gas under pressure is hot abrasive gas from the top portion of the furnace freed from its abrasive properties, cooled and compressed.

'7. In a blast-furnace charging-system of known type having an upper receiving-hopper and its bell, actuating-means opening and closing said bell intermittently, a lower deliveryhopper and its bell discharging into the top of the furnace, and operating-means opening and closing said delivery-hopper bell intermittently, the novel improvement of means for continuously maintaining the interior of said deliveryhopper with substantially-nonabradant inert gas at a super-atmospheric pressure at all times greater than the gas-pressure in the top portion of the furnace during operation of the latter.

8. In a blast-furnace charging-system of known type having an upper receiving-hopper and its bell, actuating-means opening and closing said bell intermittently, a lower deliveryhopper and its bell discharging into the top of the furnace, and operating-means opening and closing said delivery-hopper bell intermittently, the novel improvement of means to maintain at all times a pressure in said delivery-hopper with substantially-nonabradant inert gas at a pressure about one pound greater per square-inch than the super-atmospheric pressure per squareinch in the top portion of the furnace during the operation of the latter.

ALBERT MOHR, JR. JOHN P. GRILLI.

Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US2516190 *Apr 7, 1945Jul 25, 1950Bethlehem Steel CorpApparatus for charging blast furnaces
US2563681 *Mar 1, 1946Aug 7, 1951American Steel & Wire CoLarge bell assembly
US2585800 *Sep 3, 1947Feb 12, 1952Republic Steel CorpBleeder and equalizer for blast furnaces
US2606672 *Jul 10, 1947Aug 12, 1952Avery Julian MBlast furnace
US2628829 *Oct 25, 1947Feb 17, 1953Basic Refractories IncCalcining apparatus
US2658636 *Jun 14, 1949Nov 10, 1953Little Inc AMethod of controlling pressure between bells of blast furnaces
US2765935 *Mar 24, 1948Oct 9, 1956Republic Steel CorpClean gas seal for bell and hopper
US2875137 *Oct 24, 1955Feb 24, 1959Union Oil CoSolids feeding process and apparatus
US3045996 *Nov 19, 1959Jul 24, 1962Koppers Co IncUltra high pressure blast furnace
US3061314 *Feb 16, 1960Oct 30, 1962Armco Steel CorpBlast furnace bell rod gas seal
US3139472 *May 5, 1961Jun 30, 1964Inland Steel CoCharging apparatus for blast furnace with high top pressure
US3142480 *Jun 8, 1961Jul 28, 1964Azbe CorpCalcining apparatus
US3198623 *Sep 1, 1961Aug 3, 1965Inland Steel CoGas sealing and continuous charging method for blast furnace
US3216819 *Jun 21, 1960Nov 9, 1965Armco Steel CorpBlast furnace bleeder valve operation
US3276757 *Dec 2, 1963Oct 4, 1966Kaiser Steel CorpBlast furnace charging system
US3297432 *Dec 26, 1963Jan 10, 1967Mohr & Sons JohnBlast furnace charging apparatus pressurization
US4183705 *Jan 16, 1978Jan 15, 1980K-B Engineering Co.Reciprocating airlock valve
DE1433323B1 *Nov 10, 1964May 31, 1972Ishikawajima Harima Heavy IndDruckausgleicher fuer die Begichtung von Hochdruckhochoefen
Classifications
U.S. Classification414/170, 414/201
International ClassificationC21B7/00
Cooperative ClassificationC21B7/007
European ClassificationC21B7/00C