EP0200996B1 - Method for controlling the charging installation of a shaft furnace and charging installation using this method - Google Patents

Method for controlling the charging installation of a shaft furnace and charging installation using this method Download PDF

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Publication number
EP0200996B1
EP0200996B1 EP86105642A EP86105642A EP0200996B1 EP 0200996 B1 EP0200996 B1 EP 0200996B1 EP 86105642 A EP86105642 A EP 86105642A EP 86105642 A EP86105642 A EP 86105642A EP 0200996 B1 EP0200996 B1 EP 0200996B1
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EP
European Patent Office
Prior art keywords
hopper
chamber
dosing valve
discharge
carcase
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
Application number
EP86105642A
Other languages
German (de)
French (fr)
Other versions
EP0200996A1 (en
Inventor
Marc Solvi
Gilbert Bernard
Emile Lonardi
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.)
Paul Wurth SA
Original Assignee
Paul Wurth SA
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
Priority claimed from LU85879A external-priority patent/LU85879A1/en
Priority claimed from LU86340A external-priority patent/LU86340A1/en
Application filed by Paul Wurth SA filed Critical Paul Wurth SA
Priority to AT86105642T priority Critical patent/ATE38857T1/en
Publication of EP0200996A1 publication Critical patent/EP0200996A1/en
Application granted granted Critical
Publication of EP0200996B1 publication Critical patent/EP0200996B1/en
Expired legal-status Critical Current

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Classifications

    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21BMANUFACTURE OF IRON OR STEEL
    • C21B7/00Blast furnaces
    • C21B7/18Bell-and-hopper arrangements
    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21BMANUFACTURE OF IRON OR STEEL
    • C21B7/00Blast furnaces
    • C21B7/18Bell-and-hopper arrangements
    • C21B7/20Bell-and-hopper arrangements with appliances for distributing the burden
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27BFURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
    • F27B1/00Shaft or like vertical or substantially vertical furnaces
    • F27B1/10Details, accessories, or equipment peculiar to furnaces of these types
    • F27B1/20Arrangements of devices for charging
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D3/00Charging; Discharging; Manipulation of charge
    • F27D3/10Charging directly from hoppers or shoots
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F27FURNACES; KILNS; OVENS; RETORTS
    • F27DDETAILS OR ACCESSORIES OF FURNACES, KILNS, OVENS, OR RETORTS, IN SO FAR AS THEY ARE OF KINDS OCCURRING IN MORE THAN ONE KIND OF FURNACE
    • F27D3/00Charging; Discharging; Manipulation of charge
    • F27D2003/0001Positioning the charge
    • F27D2003/0006Particulate materials
    • F27D2003/0007Circular distribution

Definitions

  • the present invention relates to a method for controlling the operation of a loading installation of a shaft furnace comprising a rotary or oscillating distribution chute, a hopper with a central flow opening above the chute controlled by a metering member with symmetrical action around the central axis of the furnace and surmounted by at least one airlock provided with upper and lower sealing valves, as well as a metering valve for regulating the flow towards the hopper.
  • the invention also relates to an installation for implementing this method.
  • the object of the present invention is to provide a loading method and installation which allow a vertical and symmetrical fall of the loading material.
  • the method proposed by the invention is characterized in that the material being contained in the airlock and the metering valve of the hopper being closed, the metering valve of the airlock is first opened to cause the flow of a quantity of material sufficient for the formation of a barrage of material above the flow tubing of the hopper, in that the metering flap of the latter is only opened after the formation of this barrier, in that we weigh separately and throughout the loading time both the hopper and the airlock which is in communication with the hopper, in that we generate signals representing respectively the quantity of material contained in the hopper, the quantity of material contained in the airlock and the sum of the quantities of material contained in the hopper and the airlock and in that the position of the metering valve of the hopper is adjusted so that the hopper flow rate is not greater than the flow rate d e the flow from the airlock to the hopper.
  • the invention also provides an installation for loading a shaft furnace comprising a rotary or oscillating distribution chute, a hopper with a central flow opening above the chute controlled by a metering valve with symmetrical action around the central axis of the oven and surmounted by two storage airlocks juxtaposed on either side of the vertical axis of the oven and carried by means of load cells, these airlocks being each provided with flow pipes directed towards the hopper , a pair of sealing valves and a pair of metering valves respectively associated with the flow pipes for placing the airlocks alternately in communication with the interior of the oven, characterized in that said hopper is contained in a sealed carcass in which penetrate the flow pipes, in that said hopper is suspended from the carcass by means of load cells and in that means are provided outside the carcass for weak re turn the hopper around the axis of the oven and to activate its metering valve through the central suspension of the hopper.
  • the hopper metering valve is preferably constituted by an element movable vertically and defining with the wall of the hopper an annular flow opening whose section is variable by vertical displacement of said element.
  • the hopper suspension consists of a vertical cylinder axially crossing the upper part of the carcass at a sealing bellows and carried by the load cells resting on the carcass, a hollow rod arranged coaxially in said cylinder, the lower part of this rod being connected by means of one or more crosspieces to the hopper, while its upper part undergoes, outside the carcass, the action of a drive means for rotating it around of the vertical axis of the oven and by a rod coaxially passing through said hollow rod, the lower part of this rod being connected to the metering valve, while its upper part undergoes the action of a jack outside the carcass to cause the vertical displacement of the rod and the metering flap.
  • the outer cylinder of the hopper suspension is preferably connected to the carcass by flexible horizontal stabilization elements which do not impede the freedom of vertical movement of the hopper suspension.
  • FIG. 1 shows the upper part of a blast furnace 10 in the head of which is mounted a rotary distribution chute 12 with adjustable angle of discharge. Above the oven 10 is a frame 14 which supports the installation for feeding the material
  • This installation includes, among other things, a hopper 16 whose flow opening is located above the chute 12 on the central axis O and which is controlled by a metering valve 18 composed of two registers with symmetrical action around of axis 0.
  • the frame 14 also supports one or more airlocks, only one of which is represented by the reference 20.
  • This airlock communicates with the hopper 16 through a valve cage 22 which includes a sealing valve not shown and a metering valve 24 controlling the flow of the airlock 20, similar to the valve 18.
  • the hopper 16 rests on a number of load cells 26 which make it possible to continuously supply signals representative of the weight of the hopper and of its content.
  • the airlock 20 rests on several load cells 28 making it possible to supply signals representative of the content of the airlock 20.
  • compensators 30 and 32 have been provided for both 'other of the hopper 16 to separate it from the airlock and the oven.
  • loading phase we mean the deposition of a uniform layer of weight P o on the loading surface in the oven 10.
  • all the quantity of loading material with weight P o is in the airlock 20, the metering valve 24 of which is still closed.
  • the hopper 16 which is empty is also closed by its metering valve 18.
  • valve 24 simply as a check valve and open it fully to allow the flow of material in the hopper up to when the flow stops naturally, which is shown in FIG. 1.
  • the metering is then carried out by the valve 18 and the material descends, without falling, from the airlock through the cage 22 into the hopper 16 as and as it flows from it.
  • valve 24 must be used as a metering valve to regulate the flow of the airlock 20 so as to maintain the dam in the hopper 16.
  • the curves P t and P respectively represent the weight of the content of the hopper and the weight of the content of the airlock. It shows the evolution of the weight of these contents as a function of time T.
  • the flow of the airlock 20 stops automatically when the loading material accumulates at its angle of rest in the hopper 16 through the communication between the airlock and the hopper as shown in Figure 1. This situation is detected by the evolution of the weight of the hopper 16 and the airlock 20 which no longer changes as soon as the flow stops, which is illustrated in FIG. 2 from time t, where the curves P t and P s take directions horizontal.
  • the load flows from the hopper 16 towards the interior of the oven.
  • the flow rate of the material flowing from the hopper 16 is adjusted by the valve 18 so that it is not greater than the flow rate of the flow from the airlock to the hopper 16, so that the weight of the contents of the hopper 16 remains constant as long as the loading material is still in the airlock 20.
  • This is represented by the horizontal evolution of the curve P t beyond the point t 2 .
  • the continuous descent of the curve P illustrates the progressive flow from the airlock 20 towards the hopper 16.
  • the total weight P s + P t decreases, of course, also from the moment t 2 , which is illustrated by the fact that the curve in broken lines descends parallel to the curve P s .
  • FIG. 3 shows an embodiment of an installation for implementing the method described above, and which is becoming more and more advantageous for large capacity ovens.
  • a well-known problem in loading installations with a distribution chute is that of the segregation of the particles, that is to say their separation inside an enclosure according to their particle size.
  • This phenomenon discussed in more detail in patent LU-85,810 intensifies with the increase in the diameter of the enclosure.
  • This problem is also likely to arise, more or less pronounced, in the hopper in which the dam is caused during the implementation of the method described above, in particular because of the fact that the dam is formed by growth the along the conical wall of the hopper into the upper tubing of one of the airlocks.
  • FIG. 3 we can see the upper part of a tank oven 40 in the head of which there is a distribution chute 42 actuated by a drive mechanism located in a housing 44 on the head of the oven 40.
  • a carcass watertight 46 of substantially conical shape, carried by a frame 48 supported by the head of the oven 40 is connected by its lower part by means of a compensator 50 to the housing 44 and communicates through this compensator 50 with the interior of the oven 40.
  • the carcass 46 carries, by means of several load cells 52 two airlocks 54 and 56 whose oblique flow pipes 58 and 60 penetrate inside the carcass 46.
  • the flow of these pipes 58 and 60 is controlled by metering members 62 and 64.
  • the seal between each of the airlocks 54 and 56 and the interior of the carcass 46 and the oven 40 is produced by two sealing valves 66 and 68 cooperating with seats mounted in the carcass.
  • a conical hopper 70 inside the carcass 46 is controlled by a metering valve 72 whose the aim is to cause the formation of a dam of the material in the hopper 70 as described above with reference to FIG. 1.
  • the installation includes means for rotating this hopper 70 around the vertical axis 0 of the oven 40.
  • This rotation in fact allows better filling of the hopper 70 and a filling which takes place over 360 ° rather than an embankment which climbs from the metering valve 72 to the airlocks of the airlocks 54 and 56 and which promotes the phenomenon of segregation.
  • the problem caused by the rotation of the hopper 70 is the need to be able to control the flow of the material by weighing the hopper 70, weighing which with a stationary hopper presented no problem.
  • the hopper 70 is suspended by one or more cross members 74 from a hollow rod 76 disposed on the central axis 0 and held inside an external coaxial cylinder 78 which crosses, in a sealed manner, the upper part of the carcass 46 at the level of a bellows 80.
  • This cylinder 78 rests on the outside on several load cells 82 which supply signals representing the weight of the hopper 70, of its content and of all its suspension and accessories 'training.
  • the rod 76 is connected, outside the carcass 46, to means not shown to rotate it with the hopper 70 around the central axis 0 as symbolized by the arrows A and B.
  • the metering valve 72 which regulates the flow out of the hopper 70 is designed in the form of a disc or bell which, by vertical displacement, defines an annular opening of variable section with the wall of the hopper 70.
  • the metering valve 72 is carried by the end of a rod 84 passing coaxially through the rod 76 and undergoing outside the carcass 46 the action of a jack 86 to move the metering valve 72 between the closed position illustrated in solid lines and a position open illustrated in dotted lines.
  • the cylinder 78 is connected by blades 88 to the carcass 46, these blades being flexible enough not to hinder the freedom of vertical movement of the cylinder 78, that is to say that is, to exert a harmful influence on the results of the weighing.
  • the weighing of the hopper 70 and that of the airlock in the flow phase allow the control and command of the loading, in particular the operation of the metering valve 72 by providing signals representing the content of the hopper 70 and that of one of the airlocks 54 or 56, that is to say during the weighing, the airlock in the flow phase and the hopper are considered as a single container.
  • the weighing of the hopper 70 for monitoring the level of its content.
  • the volume and the level curve of the content of the hopper may vary, it is preferable to monitor the filling level of the hopper by level detectors such as for example ultrasonic, isotope, optical probes, etc.

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Manufacturing & Machinery (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Blast Furnaces (AREA)
  • Furnace Charging Or Discharging (AREA)
  • Filling Or Emptying Of Bunkers, Hoppers, And Tanks (AREA)
  • Manufacture Of Iron (AREA)
  • Vertical, Hearth, Or Arc Furnaces (AREA)
  • Weight Measurement For Supplying Or Discharging Of Specified Amounts Of Material (AREA)
  • Feeding, Discharge, Calcimining, Fusing, And Gas-Generation Devices (AREA)

Description

La présente invention concerne un procédé de contrôle de l'opération d'une installation de chargement d'un four à cuve comprenant une goulotte de distribution rotative ou oscillante, une trémie avec une ouverture d'écoulement centrale au-dessus de la goulotte contrôlée par un organe de dosage à action symétrique autour de l'axe central du four et surmontée d'au moins un sas pourvu de clapets d'étanchéité supérieurs et inférieurs, ainsi qu'un clapet de dosage pour régler l'écoulement vers la trémie. L'invention concerne également une installation pour la mise en oeuvre de ce procédé.The present invention relates to a method for controlling the operation of a loading installation of a shaft furnace comprising a rotary or oscillating distribution chute, a hopper with a central flow opening above the chute controlled by a metering member with symmetrical action around the central axis of the furnace and surmounted by at least one airlock provided with upper and lower sealing valves, as well as a metering valve for regulating the flow towards the hopper. The invention also relates to an installation for implementing this method.

Les installations classiques de chargement à goulotte rotative ou oscillante comportent deux sas juxtaposés opérant en alternance. Il est bien connu que ces installations présentent l'inconvénient d'une chute asymétrique sur la goulotte, due à la position excentrique des sas par rapport à l'axe central. Pour y remédier, on a déjà prévu plusieurs systèmes de rectification de la trajectoire de chute.Conventional loading installations with rotating or oscillating chute have two juxtaposed airlocks operating alternately. It is well known that these installations have the drawback of an asymmetrical fall on the chute, due to the eccentric position of the airlocks relative to the central axis. To remedy this, several systems for rectifying the fall trajectory have already been provided.

Le but de la présente invention est de prévoir un procédé et une installation de chargement qui permettent une chute verticale et symétrique de la matière de chargement.The object of the present invention is to provide a loading method and installation which allow a vertical and symmetrical fall of the loading material.

Pour atteindre cet objectif, le procédé proposé par l'invention est caractérisé en ce que la matière étant contenue dans le sas et le clapet de dosage de la trémie étant fermé l'on ouvre d'abord le clapet de dosage du sas pour provoquer l'écoulement d'une quantité de matière suffisante pour la formation d'un barrage de matière au-dessus de la tubulure d'écoulement de la trémie, en ce que l'on n'ouvre le clapet de dosage de celle-ci qu'après la formation de ce barrage, en ce que l'on pèse séparément et pendant toute la durée de chargement aussi bien la trémie que le sas qui est en communication avec la trémie, en ce que l'on génère des signaux représentant respectivement la quantité de matière contenue dans la trémie, la quantité de matière contenue dans le sas et la somme des quantités de matière contenues dans la trémie et le sas et en ce que l'on règle la position du clapet de dosage de la trémie de telle manière que le débit d'écoulement de la trémie ne soit pas supérieur au débit de l'écoulement du sas vers la trémie.To achieve this objective, the method proposed by the invention is characterized in that the material being contained in the airlock and the metering valve of the hopper being closed, the metering valve of the airlock is first opened to cause the flow of a quantity of material sufficient for the formation of a barrage of material above the flow tubing of the hopper, in that the metering flap of the latter is only opened after the formation of this barrier, in that we weigh separately and throughout the loading time both the hopper and the airlock which is in communication with the hopper, in that we generate signals representing respectively the quantity of material contained in the hopper, the quantity of material contained in the airlock and the sum of the quantities of material contained in the hopper and the airlock and in that the position of the metering valve of the hopper is adjusted so that the hopper flow rate is not greater than the flow rate d e the flow from the airlock to the hopper.

L'invention propose également une installation de chargement d'un four à cuve comprenant une goulotte de distribution rotative ou oscillante, une trémie avec une ouverture d'écoulement centrale au-dessus de la goulotte contrôlée par un clapet de dosage à action symétrique autour de l'axe central du four et surmontée de deux sas de stockage juxtaposés de part et d'autre de l'axe vertical du four et portés par l'intermédiaire de pesons, ces sas étant pourvus chacun de tubulures d'écoulement dirigées vers la trémie, une paire de clapets d'étanchéité et une paire de clapets de dosage associés respectivement aux tubulures d'écoulement pour mettre les sas alternativement en communication avec l'intérieur du four, caractérisée en ce que ladite trémie est contenue dans une carcasse étanche dans laquelle pénètrent les tubulures d'écoulement, en ce que ladite trémie est suspendue à la carcasse par l'intermédiaire de pesons et en ce que des moyens sont prévus à l'extérieur de la carcasse pour faire tourner la trémie autour de l'axe du four et pour actionner son clapet de dosage à travers la suspension centrale de la trémie.The invention also provides an installation for loading a shaft furnace comprising a rotary or oscillating distribution chute, a hopper with a central flow opening above the chute controlled by a metering valve with symmetrical action around the central axis of the oven and surmounted by two storage airlocks juxtaposed on either side of the vertical axis of the oven and carried by means of load cells, these airlocks being each provided with flow pipes directed towards the hopper , a pair of sealing valves and a pair of metering valves respectively associated with the flow pipes for placing the airlocks alternately in communication with the interior of the oven, characterized in that said hopper is contained in a sealed carcass in which penetrate the flow pipes, in that said hopper is suspended from the carcass by means of load cells and in that means are provided outside the carcass for weak re turn the hopper around the axis of the oven and to activate its metering valve through the central suspension of the hopper.

Le clapet de dosage de la trémie est, de préférence, constitué par un élément déplaçable verticalement et définissant avec la paroi de la trémie une ouverture d'écoulement annulaire dont la section est variable par déplacement vertical dudit élément.The hopper metering valve is preferably constituted by an element movable vertically and defining with the wall of the hopper an annular flow opening whose section is variable by vertical displacement of said element.

La suspension de la trémie est constituée par un cylindre vertical traversant axialement la partie supérieure de la carcasse au niveau d'un soufflet d'étanchéité et porté par les pesons reposant sur la carcasse, une tige creuse disposée coaxialement dans ledit cylindre, la partie inférieure de cette tige étant reliée par l'intermédiaire d'une ou de plusieurs traverses à la trémie, alors que sa partie supérieure subit, à l'extérieur de la carcasse, l'action d'un moyen d'entraînement pour la faire tourner autour de l'axe vertical du four et par une tige traversant coaxialement ladite tige creuse, la parti inférieure de cette tige étant reliée au clapet de dosage, alors que sa partie supérieure subit à l'extérieur de la carcasse l'action d'un vérin pour occasionner le déplacement vertical de la tige et du clapet de dosage.The hopper suspension consists of a vertical cylinder axially crossing the upper part of the carcass at a sealing bellows and carried by the load cells resting on the carcass, a hollow rod arranged coaxially in said cylinder, the lower part of this rod being connected by means of one or more crosspieces to the hopper, while its upper part undergoes, outside the carcass, the action of a drive means for rotating it around of the vertical axis of the oven and by a rod coaxially passing through said hollow rod, the lower part of this rod being connected to the metering valve, while its upper part undergoes the action of a jack outside the carcass to cause the vertical displacement of the rod and the metering flap.

Le cylindre extérieur de la suspension de la trémie est, de préférence, relié à la carcasse par des éléments flexibles de stabilisation horizontale qui n'entravent pas la liberté de mouvement vertical de la suspension de la trémie.The outer cylinder of the hopper suspension is preferably connected to the carcass by flexible horizontal stabilization elements which do not impede the freedom of vertical movement of the hopper suspension.

D'autres particularités et caractéristiques ressortiront de la description détaillée d'un mode d'exécution préféré présenté ci-dessous, à titre d'illustration, en référence aux figures annexées dans lesquelles:

  • la figure 1 montre schématiquement une vue latérale d'une installation de chargement avec une trémie de formation d'un barrage de matières de chargement;
  • la figure 2 représente un graphique qui montre l'évolution du poids d'un sas de la trémie lors du chargement et
  • la figure 3 montre schématiquement une vue d'ensemble, partiellement en coupe verticale axiale d'une installation selon la présente invention.
Other particularities and characteristics will emerge from the detailed description of a preferred embodiment presented below, by way of illustration, with reference to the appended figures in which:
  • Figure 1 schematically shows a side view of a loading installation with a hopper for forming a barrage of loading materials;
  • FIG. 2 represents a graph which shows the evolution of the weight of an airlock of the hopper during loading and
  • FIG. 3 schematically shows an overall view, partially in axial vertical section of an installation according to the present invention.

La figure 1 montre la partie supérieure d'un haut fourneau 10 dans la tête duquel est montée une goulotte de distribution rotative 12 à angle de déversement ajustable. Au-dessus du four 10 se trouve une charpente 14 qui supporte l'installation d'alimentation de la matière deFigure 1 shows the upper part of a blast furnace 10 in the head of which is mounted a rotary distribution chute 12 with adjustable angle of discharge. Above the oven 10 is a frame 14 which supports the installation for feeding the material

chargement. Cette installation comporte, entre autres, une trémie 16 dont l'ouverture d'écoulement se trouve au-dessus de la goulotte 12 sur l'axe central O et qui est contrôlée par un clapet de dosage 18 composé de deux registres à action symétrique autour de l'axe 0. La charpente 14 supporte également un ou plusieurs sas dont un seul est représenté par la référence 20. Ce sas communique avec la trémie 16 à travers une cage à clapets 22 qui comporte un clapet d'étanchéité non montré et un clapet de dosage 24 contrôlant l'écoulement du sas 20, analogue au clapet 18.loading. This installation includes, among other things, a hopper 16 whose flow opening is located above the chute 12 on the central axis O and which is controlled by a metering valve 18 composed of two registers with symmetrical action around of axis 0. The frame 14 also supports one or more airlocks, only one of which is represented by the reference 20. This airlock communicates with the hopper 16 through a valve cage 22 which includes a sealing valve not shown and a metering valve 24 controlling the flow of the airlock 20, similar to the valve 18.

Conformément à la présente invention, la trémie 16 repose sur un certain nombre de pesons 26 qui permettent de fournir, en permanence, des signaux représentatifs du poids de la trémie et de son contenu. De la même manière, le sas 20 repose sur plusieurs pesons 28 permettant de fournir des signaux représentatifs du contenu du sas 20. Pour permettre de peser séparément la trémie 16 et le sas 20, on a prévu des compensateurs 30 et 32 de part et d'autre de la trémie 16 pour désolidariser celle-ci du sas et du four.In accordance with the present invention, the hopper 16 rests on a number of load cells 26 which make it possible to continuously supply signals representative of the weight of the hopper and of its content. In the same way, the airlock 20 rests on several load cells 28 making it possible to supply signals representative of the content of the airlock 20. To allow the hopper 16 and the airlock 20 to be weighed separately, compensators 30 and 32 have been provided for both 'other of the hopper 16 to separate it from the airlock and the oven.

On va maintenant décrire une phase de chargement en référence aux figures 1 et 2. Par phase de chargement, il faut entendre le dépôt d'une couche uniforme d'un poids Po sur la surface de chargement dans le four 10. Au début de la phase de chargement, toute la quantité du matériau de chargement de poids Po se trouve dans le sas 20 dont le clapet de dosage 24 est encore fermé. La trémie 16 qui est vide est également fermée par son clapet de dosage 18.We will now describe a loading phase with reference to FIGS. 1 and 2. By loading phase, we mean the deposition of a uniform layer of weight P o on the loading surface in the oven 10. At the start of during the loading phase, all the quantity of loading material with weight P o is in the airlock 20, the metering valve 24 of which is still closed. The hopper 16 which is empty is also closed by its metering valve 18.

Le procédé le plus simple et le plus avantageux dans le mode de réalisation de la figure 1 consiste à se servir du clapet 24 simplement comme clapet de retenue et de l'ouvrir à fond pour permettre l'écoulement de la matière dans la trémie jusqu'à l'arrêt naturel de l'écoulement, ce qui est représenté à la figure 1. Le dosage est alors effectué par le clapet 18 et la matière descend, sans tomber, du sas à travers la cage 22 dans la trémie 16 au fur et à mesure qu'elle s'écoule de celle-ci.The simplest and most advantageous method in the embodiment of Figure 1 is to use the valve 24 simply as a check valve and open it fully to allow the flow of material in the hopper up to when the flow stops naturally, which is shown in FIG. 1. The metering is then carried out by the valve 18 and the material descends, without falling, from the airlock through the cage 22 into the hopper 16 as and as it flows from it.

Il est bien entendu également possible de provoquer la formation d'un barrage de hauteur réduite, qui ne s'étende pas jusque dans le sas 20. Dans ce cas, le clapet 24 doit être utilisé comme clapet de dosage pour régler l'écoulement du sas 20 de façon à assurer le maintien du barrage dans la trémie 16.It is of course also possible to cause the formation of a barrier of reduced height, which does not extend into the airlock 20. In this case, the valve 24 must be used as a metering valve to regulate the flow of the airlock 20 so as to maintain the dam in the hopper 16.

Sur la figure 2, les courbes Pt et P représentent respectivement le poids du contenu de la trémie et le poids du contenu du sas. Il montre l'évolution du poids de ces contenus en fonction du temps T.In FIG. 2, the curves P t and P respectively represent the weight of the content of the hopper and the weight of the content of the airlock. It shows the evolution of the weight of these contents as a function of time T.

Au moment T - 0, on voit donc que le poids P est égal à Po, tandis que le poids Pt est égal à 0. Dès l'ouverture du clapet de dosage 24 du sas, le contenu du sas 20 diminue de façon linéaire, ce qui est représenté par la chute de la courbe PS. En même temps, le poids du contenu de la trémie 16 augmente (son clapet 18 étant toujours fermé), ce qui est représenté par la montée de la courbe Pt.At time T - 0, we therefore see that the weight P is equal to P o , while the weight P t is equal to 0. As soon as the metering valve 24 of the airlock is opened, the content of the airlock 20 decreases so linear, which is represented by the fall in the curve P S. At the same time, the weight of the content of the hopper 16 increases (its valve 18 being always closed), which is represented by the rise of the curve Pt.

L'écoulement du sas 20 s'arrête automatiquement lorsque la matière de chargement s'accumule suivant son angle de repos dans la trémie 16 à travers la communication entre le sas et la trémie comme représenté sur la figure 1. Cette situation est détectée par l'évolution du poids de la trémie 16 et du sas 20 qui ne change plus dès que l'écoulement s'arrête, ce qui est illustré sur la figure 2 à partir du temps t, où les courbes Pt et Ps prennent des directions horizontales.The flow of the airlock 20 stops automatically when the loading material accumulates at its angle of rest in the hopper 16 through the communication between the airlock and the hopper as shown in Figure 1. This situation is detected by the evolution of the weight of the hopper 16 and the airlock 20 which no longer changes as soon as the flow stops, which is illustrated in FIG. 2 from time t, where the curves P t and P s take directions horizontal.

Grâce à la mesure séparée des poids de la trémie 16 et du sas 20, on arrive par conséquent à détecter le moment t, où l'on a formé le barrage souhaité au-dessus de l'ouverture d'écoulement dans la trémie 16. On peut dès lors ouvrir le clapet 18 pour commencer le vrai processus de chargement. Cette ouverture est effectuée au moment t2. Il est à noter que jusqu'à ce moment t2, la somme des poids Pt et Ps est toujours égale à Po, ce qui est illustré sur la figure 2 par la courbe en traits interrompus.Thanks to the separate measurement of the weights of the hopper 16 and the airlock 20, it is therefore possible to detect the moment t, when the desired barrier has been formed above the flow opening in the hopper 16. We can then open the valve 18 to start the real loading process. This opening is carried out at time t 2 . It should be noted that until this moment t 2 , the sum of the weights P t and P s is always equal to P o , which is illustrated in FIG. 2 by the curve in broken lines.

Dès l'ouverture du clapet 18, la charge s'écoule de la trémie 16 vers l'intérieur du four. Le débit de la matière s'écoulant de la trémie 16 est réglé par le clapet 18 de manière qu'il ne soit pas supérieur au débit de l'écoulement du sas vers la trémie 16, de sorte que le poids du contenu de la trémie 16 reste constant tant que la matière de chargement se trouve encore dans le sas 20. Ceci est représenté par l'évolution horizontale de la courbe Pt au-delà du point t2. Par contre, la descente continue de la courbe P illustre l'écoulement progressif à partir du sas 20 vers la trémie 16. Le poids total Ps + Pt diminue, bien entendu, également à partir du moment t2 , ce qui est illustré par le fait que la courbe en traits interrompus descend parallèlement à la courbe Ps.As soon as the valve 18 is opened, the load flows from the hopper 16 towards the interior of the oven. The flow rate of the material flowing from the hopper 16 is adjusted by the valve 18 so that it is not greater than the flow rate of the flow from the airlock to the hopper 16, so that the weight of the contents of the hopper 16 remains constant as long as the loading material is still in the airlock 20. This is represented by the horizontal evolution of the curve P t beyond the point t 2 . On the other hand, the continuous descent of the curve P illustrates the progressive flow from the airlock 20 towards the hopper 16. The total weight P s + P t decreases, of course, also from the moment t 2 , which is illustrated by the fact that the curve in broken lines descends parallel to the curve P s .

Lorsque le sas 20 est vide au moment t3, son clapet d'étanchéité inférieur ainsi que son clapet de dosage 24 sont fermés pour permettre un nouveau remplissage. Pendant ce temps, l'écoulement de la trémie 16 se poursuit, ce qui est représenté par la descente regulière de la courbe Pt à partir du moment t3 jusqu'au moment t4 où elle est vide, à son tour.When the airlock 20 is empty at time t 3 , its lower sealing valve and its metering valve 24 are closed to allow refilling. During this time, the flow of the hopper 16 continues, which is represented by the regular descent of the curve P t from the time t 3 until the time t 4 when it is empty, in turn.

Pour que le chargement se fasse dans des conditions optimales, il est important que le barrage de matière au-dessus de la tubulure d'écoulement de la trémie 16 demeure pendant toute la phase de chargement, c'est-à-dire que le clapet de dosage 18 soit réglé de telle manière que le débit de l'écoulement de la trémie 16 ne soit pas supérieur à celui du sas 20. Ce contrôle peut être effectué facilement par l'observation de la courbe Pt. Celle-ci doit en effet demeurer horizontale entre les points t2 et t3, c'est-à-dire que la matière qui s'écoule de la trémie 16 doit être remplacée par la matière s'écoulant du sas vers la trémie 16. Toute correction de la position des clapets 18 doit être effectuée automatiquement à partir d'un signal représentatif d'une déviation de la courbe Pt de son évolution horizontale.For the loading to take place in optimal conditions, it is important that the material barrier above the flow pipe of the hopper 16 remains throughout the loading phase, that is to say that the valve metering 18 is adjusted so that the flow rate of the hopper 16 is not greater than that of the airlock 20. This control can be easily performed by observing the curve P t . This must indeed remain horizontal between points t 2 and t 3 , that is to say that the material flowing from the hopper 16 must be replaced by the material flowing from the airlock to the hopper 16 Any correction of the position of the valves 18 must be carried out automatically from a signal representative of a deviation of the curve P t from its horizontal evolution.

Au lieu d'effectuer ce contrôle par la mesure du poids de la trémie 16, il est également possible de prévoir dans la paroi de la trémie 16 des détecteurs de niveau qui vérifient, en permanence, le niveau du barrage au-dessus de la tubulure d'écoulement et fournissent un signal lorsque Ie niveau tombe trop bas, c'est-à-dire que le clapet 18 est trop ouvert ou que le clapet 24 ne l'est pas assez.Instead of carrying out this control by measuring the weight of the hopper 16, it is also possible to provide level sensors in the wall of the hopper 16 which constantly check the level of the dam above the pipe. flow and provide a signal when the level falls too low, that is to say that the valve 18 is too open or that the valve 24 is not enough.

La figure 3 montre un mode de réalisation d'une installation pour la mise en oeuvre du procédé décrit ci-dessus, et qui devient de plus en plus avantageux pour des fours de grande capacité. En effet, un problème bien connu dans les installations de chargement à goulotte de distribution est celui de la ségrégation des particules, c'est-à-dire leur séparation à l'intérieur d'une enceinte selon leur granulométrie. Ce phénomène, discuté plus en détail dans le brevet LU-85 810 s'intensifie avec l'augmentation du diamètre de l'enceinte. Ce problème risque également de se poser, de façon plus ou moins prononcée, dans la trémie dans laquelle on provoque le barrage lors de la mise en oeuvre du procédé décrit ci-dessus, notamment à cause du fait que le barrage se forme par croissance le long de la paroi conique de la trémie jusque dans la tubulure supérieure de l'un des sas.FIG. 3 shows an embodiment of an installation for implementing the method described above, and which is becoming more and more advantageous for large capacity ovens. In fact, a well-known problem in loading installations with a distribution chute is that of the segregation of the particles, that is to say their separation inside an enclosure according to their particle size. This phenomenon, discussed in more detail in patent LU-85,810 intensifies with the increase in the diameter of the enclosure. This problem is also likely to arise, more or less pronounced, in the hopper in which the dam is caused during the implementation of the method described above, in particular because of the fact that the dam is formed by growth the along the conical wall of the hopper into the upper tubing of one of the airlocks.

Sur cette figure 3, on voit la partie supérieure d'un four à cuve 40 dans la tête duquel se trouve une goulotte de distribution 42 actionnée par un mécanisme d'entraînement se trouvant dans un boîtier 44 sur la tête du four 40. Une carcasse étanche 46 de forme sensiblement conique, portée par une charpente 48 supportée par la tête du four 40 est reliée par sa partie inférieure au moyen d'un compensateur 50 au boîtier 44 et communique à travers ce compensateur 50 avec l'intérieur du four 40.In this FIG. 3, we can see the upper part of a tank oven 40 in the head of which there is a distribution chute 42 actuated by a drive mechanism located in a housing 44 on the head of the oven 40. A carcass watertight 46 of substantially conical shape, carried by a frame 48 supported by the head of the oven 40 is connected by its lower part by means of a compensator 50 to the housing 44 and communicates through this compensator 50 with the interior of the oven 40.

La carcasse 46 porte, par l'intermédiaire de plusieurs pesons 52 deux sas 54 et 56 dont les tubulures obliques d'écoulement 58 et 60 pénètrent à l'intérieur de la carcasse 46. L'écoulement de ces tubulures 58 et 60 est contrôlée par des organes de dosage 62 et 64. L'étanchéité entre chacun des sas 54 et 56 et l'intérieur de la carcasse 46 et le four 40 est réalisée par deux clapets d'étanchéité 66 et 68 coopérant avec des sièges montés dans la carcasse.The carcass 46 carries, by means of several load cells 52 two airlocks 54 and 56 whose oblique flow pipes 58 and 60 penetrate inside the carcass 46. The flow of these pipes 58 and 60 is controlled by metering members 62 and 64. The seal between each of the airlocks 54 and 56 and the interior of the carcass 46 and the oven 40 is produced by two sealing valves 66 and 68 cooperating with seats mounted in the carcass.

Alors que dans les installations de chargement classiques avec une goulotte rotative, la matière de chargement s'écoule directement des tubulures 58 et 60 le long de la paroi inclinée de la carcasse 46 sur la goulotte 42, on a prévu dans l'installation proposée par la présente invention en vue de la mise en oeuvre du procédé décrit ci-dessus, une trémie conique 70 à l'intérieur de la carcasse 46. L'ouverture d'écoulement inférieure de cette trémie 70 est contrôlée par un clapet de dosage 72 dont le but est de provoquer la formation d'un barrage de la matière dans la trémie 70 comme décrit ci-dessus en référence à la figure 1.Whereas in conventional loading installations with a rotating chute, the loading material flows directly from the pipes 58 and 60 along the inclined wall of the carcass 46 onto the chute 42, provision has been made in the installation proposed by the present invention for the implementation of the method described above, a conical hopper 70 inside the carcass 46. The lower flow opening of this hopper 70 is controlled by a metering valve 72 whose the aim is to cause the formation of a dam of the material in the hopper 70 as described above with reference to FIG. 1.

Pour réduire le phénomène de ségrégation dans cette trémie 70, l'installation comporte des moyens pour faire tourner cette trémie 70 autour de l'axe vertical 0 du four 40. Cette rotation permet, en effet, un meilleur remplissage de la trémie 70 et un remplissage qui s'effectue sur 360° plutôt qu'un talus qui grimpe depuis le clapet de dosage 72 jusqu'aux tubulures des sas 54 et 56 et qui favorise le phénomène de ségrégation. Toutefois, le problème causé par la rotation de la trémie 70 est la nécessité de pouvoir contrôler l'écoulement de la matière par une pesée de la trémie 70, pesée qui avec une trémie immobile ne présentait aucun problème.To reduce the phenomenon of segregation in this hopper 70, the installation includes means for rotating this hopper 70 around the vertical axis 0 of the oven 40. This rotation in fact allows better filling of the hopper 70 and a filling which takes place over 360 ° rather than an embankment which climbs from the metering valve 72 to the airlocks of the airlocks 54 and 56 and which promotes the phenomenon of segregation. However, the problem caused by the rotation of the hopper 70 is the need to be able to control the flow of the material by weighing the hopper 70, weighing which with a stationary hopper presented no problem.

Pour pouvoir résoudre ce problème, la trémie 70 est suspendue par une ou plusieurs traverses 74 à une tige creuse 76 disposée sur l'axe central 0 et maintenue à l'intérieur d'un cylindre coaxial extérieur 78 qui traverse, de façon étanche, la partie supérieure de la carcasse 46 au niveau d'un soufflet 80. Ce cylindre 78 repose à l'extérieur sur plusieurs pesons 82 qui fournissent des signaux représentant le poids de la trémie 70, de son contenu et de tous ses accessoires de suspension et d'entraînement. La tige 76 est reliée, à l'extérieur de la carcasse 46, à des moyens non représentés pour la faire tourner avec la trémie 70 autour de l'axe central 0 comme symbolisé par les flèches A et B. Le clapet de dosage 72 qui règle l'écoulement hors de la trémie 70 est conçu sous forme de disque ou de cloche qui, par déplacement vertical, définit une ouverture annulaire à section variable avec la paroi de la trémie 70. A cet effet, le clapet de dosage 72 est porté par l'extrémité d'une tige 84 traversant coaxialement la tige 76 et subissant à l'extérieur de la carcasse 46 l'action d'un vérin 86 pour déplacer le clapet de dosage 72 entre la position fermée illustrée en traits pleins et une position ouverte illustrée en traits pointillés.To be able to solve this problem, the hopper 70 is suspended by one or more cross members 74 from a hollow rod 76 disposed on the central axis 0 and held inside an external coaxial cylinder 78 which crosses, in a sealed manner, the upper part of the carcass 46 at the level of a bellows 80. This cylinder 78 rests on the outside on several load cells 82 which supply signals representing the weight of the hopper 70, of its content and of all its suspension and accessories 'training. The rod 76 is connected, outside the carcass 46, to means not shown to rotate it with the hopper 70 around the central axis 0 as symbolized by the arrows A and B. The metering valve 72 which regulates the flow out of the hopper 70 is designed in the form of a disc or bell which, by vertical displacement, defines an annular opening of variable section with the wall of the hopper 70. For this purpose, the metering valve 72 is carried by the end of a rod 84 passing coaxially through the rod 76 and undergoing outside the carcass 46 the action of a jack 86 to move the metering valve 72 between the closed position illustrated in solid lines and a position open illustrated in dotted lines.

Pour assurer une certaine stabilité horizontale de la suspension de la trémie 70, le cylindre 78 est relié par des lames 88 à la carcasse 46, ces lames étant suffisamment flexibles pour ne pas gêner la liberté de mouvement vertical du cylindre 78, c'est-à-dire d'exercer une influence néfaste sur les résultats de la pesée.To ensure a certain horizontal stability of the suspension of the hopper 70, the cylinder 78 is connected by blades 88 to the carcass 46, these blades being flexible enough not to hinder the freedom of vertical movement of the cylinder 78, that is to say that is, to exert a harmful influence on the results of the weighing.

Il est donc possible de peser le contenu de la trémie 70 pendant que celle-ci tourne autour de l'axe vertical. La pesée de la trémie 70 et celle du sas en phase d'écoulement permettent le contrôle et la commande du chargement notamment la manoeuvre du clapet de dosage 72 en fournissant des signaux représentant le contenu de la trémie 70 et celui d'un des sas 54 ou 56, c'est-à-dire pendant la pesée, on considère le sas en phase d'écoulement et la trémie comme un seul récipient.It is therefore possible to weigh the content of the hopper 70 while the latter rotates around the vertical axis. The weighing of the hopper 70 and that of the airlock in the flow phase allow the control and command of the loading, in particular the operation of the metering valve 72 by providing signals representing the content of the hopper 70 and that of one of the airlocks 54 or 56, that is to say during the weighing, the airlock in the flow phase and the hopper are considered as a single container.

Bien entendu, il est également possible de se servir de la pesée de la trémie 70 pour la surveillance du niveau de son contenu. Etant donné toutefois qu'à poids égal, le volume et la courbe de niveau du contenu de la trémie peuvent varier, il est préférable de surveiller le niveau de remplissage de la trémie par des détecteurs de niveau comme par exemple des sondes à ultra-sons, à isotopes, optiques, etc.Of course, it is also possible to use the weighing of the hopper 70 for monitoring the level of its content. However, given that for equal weight, the volume and the level curve of the content of the hopper may vary, it is preferable to monitor the filling level of the hopper by level detectors such as for example ultrasonic, isotope, optical probes, etc.

L'installation décrite ci-dessus permet de procéder de deux manières différentes pour vider le contenu d'un sas dans le four. Il est possible de procéder selon le schéma de la figure 2, c'est-à-dire de n'ouvrir le clapet de dosage 72 qu'après l'arrêt d'écoulement à travers la tubulure 60, c'est-à-dire après la formation d'un barrage depuis le fond de la trémie 70 jusque dans l'un des sas 54 ou 56.The installation described above allows you to proceed in two different ways to empty the contents of an airlock in the oven. It is possible to proceed according to the diagram in FIG. 2, that is to say to open the metering valve 72 only after the flow has stopped through the pipe 60, that is to say say after the formation of a dam from the bottom of the hopper 70 to one of the airlocks 54 or 56.

Il est toutefois également possible et généralement préférable à cause de la rotation de la trémie 70 dans le mode de réalisation de la figure 3, d'ouvrir le clapet de dosage 72 avant l'arrêt de l'écoulement à travers la tubulure 60 et de régler, par le contrôle du niveau du contenu de la trémie 70, les clapets de dosage 62 ou 64 du sas en phase d'écoulement, de manière à maintenir un niveau de chargement constant dans la trémie 70.It is however also possible and generally preferable because of the rotation of the hopper 70 in the embodiment of FIG. 3, to open the metering flap 72 before the flow through the tubing 60 stops and to adjust, by controlling the level of the content of the hopper 70, the metering valves 62 or 64 of the airlock in the flow phase, so as to maintain a constant loading level in the hopper 70.

Claims (9)

1. Process for charging a shaft furnace with a charging installation, comprising a rotary or oscillating spout, a hopper with a central discharge pipe above the spout, the discharge aperture of the said pipe being controlled by a dosing device operating symmetrically around the central axis, surmounted by at least one chamber provided with an upper and a lower sealing valve, and also a dosing valve serving to regulate the rate of discharge to the hopper, characterized by the fact that the material being contained in the chamber and the dosing valve of the hopper being closed, the dosing valve of the chamber is first of all opened in order to bring about the discharge of a sufficient quantity of material for the formation of barrage of material above the discharge pipe of the hopper, that the dosing valve is not opened until after the formation of the said barrage, that both the hopper and the chamber in communication with the hopper are weighed separately and throughout the duration of the charging, that signals are produced which represent, respectively the quantity of material contained in the hopper, the quantity of material contained in the chamber and the sum of the quantities of material contained in the hopper and in the chamber, and in that the position of the dosing valve of the hopper is adjusted to ensure that the rate of discharge from the hopper does not exceed the rate of flow of material from the chamber to the hopper.
2. Process in accordance with claim 1 characterized in that the rates of discharge of material are adjusted to ensure that the weight of the quantity of material in the hopper remains constant as long as material is in the chamber. 3. Process in accordance with anyone of claims 1 or 2, characterized by the fact that the dosing valve of the hopper is not opened until after the flow of material out of a chamber has ceased naturally as a result of the formation of a barrage ascending as far as the said chamber.
4. Process in accordance with anyone of claims 1 or 2, characterized by the fact that the dosing valve of the hopper is opened before the natural cessation of the flow of material out of a chamber and that the position of the dosing device of this latter is adjusted to ensure that the barrage in the hopper will be maintained.
5. Charging installation for a shaft furnace (40) comprising a rotary or oscillating distribution spout (42), a hopper (60) with a central discharge aperture situated above the spout (42), and controlled by a dosing valve (72) acting symmetrically about the central axis 0 of the furnace (40) and surmounted by two storage chambers (54, 56) juxtaposed on each side of the vertical axis 0 of the furnace (40) and supported via balances (52), the said chambers (54, 56) being provided with discharge pipes (58, 60) directed towards the hopper (70), a pair of sealing valves (66, 68) and a pair of dosing valves (62, 64) associated respectively with the discharge pipes (58, 60) and serving to enable the chamber (54, 56) to communicate in alternation with the interior of the furnace (40), characterized by the fact that the said hopper (70) is contained in a tight carcase (46) into which the discharge pipes (58) and (60) extend, that the said hopper (70) is suspended from the carcase (46) via pressure cells (82) and that means are provided outside the carcase (46) to cause the hopper (70) to rotate about the axis 0 of the furnace (40) and to actuate its dosing valve (72) via the central suspension system of the hopper (70).
6. Installation in accordance with claim 5, characterized by the fact that the dosing valve (72) of the hopper (70) consists of a vertically movable element which in conjunction with the wall of the hopper (70) defines an annular discharge aperture of which the cross section can be varied by moving the dosing valve (72) vertically.
7. Installation in accordance with anyone of claims 5 or 6, characterized by the fact that the suspension system of the hopper (70) consists of a vertical cylinder (78) passing axially through a bellows-type sealing device in the upper part of the carcase (46) and supported by pressure cells (82) resting on the carcase (46), a hollow bar (76) positioned coaxially in the said cylinder (78), the lower part of this bar being connected to the hopper (70) via one or more cross bars (74) while its upper part is subjected outside the carcase (46) to the action of a driving means to cause it to rotate about the vertical axis O of the furnace (40) and by a bar (84) passing axially through the said hollow bar (76), the lower part of this bar (84) being connected to the dosing valve (72) while its upper part is subjected outside the carcase (46) to the action of a jack (86) in order to move the bar (84) and the dosing valve (72) in the vertical direction.
8. Installation in accordance with claim 7, characterized by the fact that the cylinder (78) of the suspension system of the hopper (70) is connected to the carcase (16) via flexible elements (88) for horizontal stabilization.
9. Installation in accordance with any one of claims 5 to 8, characterized by the fact that level- detectors are associated with the hopper (70).
EP86105642A 1985-05-07 1986-04-23 Method for controlling the charging installation of a shaft furnace and charging installation using this method Expired EP0200996B1 (en)

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Application Number Priority Date Filing Date Title
AT86105642T ATE38857T1 (en) 1985-05-07 1986-04-23 METHOD OF CONTROLLING THE FEED DEVICE OF A PITCH FURNACE AND FEED DEVICE THEREOF.

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
LU85879A LU85879A1 (en) 1985-05-07 1985-05-07 METHOD FOR CONTROLLING THE OPERATION OF A LOADING INSTALLATION OF A TANK OVEN
LU85879 1985-05-07
LU86340 1986-03-04
LU86340A LU86340A1 (en) 1986-03-04 1986-03-04 Charging installation for blast furnace - with symmetrically fed rotating chute

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EP0200996A1 EP0200996A1 (en) 1986-11-12
EP0200996B1 true EP0200996B1 (en) 1988-11-23

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AT332432B (en) * 1972-03-06 1976-09-27 Wurth Anciens Ets Paul DOSING SYSTEM FOR SHAFT FURNACES, IN PARTICULAR HOURS AND METHODS FOR MEASURING THE MOLLER WEIGHT
LU66430A1 (en) * 1972-11-08 1973-02-05
FR2224370B1 (en) * 1973-04-06 1979-05-25 Hermanns Wilhelm
FR2224373A1 (en) * 1973-04-09 1974-10-31 Delattre Levivier Admitting measured charges into e.g. blast furnaces - using appts. unaffected by high press. and temp
US4395179A (en) * 1976-03-10 1983-07-26 Davy Inc. Apparatus and method for charging material into a receptacle
JPS5638409A (en) * 1979-09-04 1981-04-13 Kawasaki Steel Corp Charging of raw material into blast furnace
DE3007743C2 (en) * 1980-02-29 1982-11-11 Estel Hoesch Werke Ag, 4600 Dortmund Process for the uniform filling of blast furnaces
AU559624B2 (en) * 1981-06-25 1987-03-19 Petrocarb, Inc. Apparatus for effecting pneumatic conveyance of particulate solids

Also Published As

Publication number Publication date
UA7024A1 (en) 1995-03-31
JPS61264111A (en) 1986-11-22
CS258479B2 (en) 1988-08-16
CA1269832A (en) 1990-06-05
BR8602182A (en) 1987-01-13
KR860009132A (en) 1986-12-20
CN1008939B (en) 1990-07-25
ES8706934A1 (en) 1987-07-01
KR930009969B1 (en) 1993-10-13
CN86103167A (en) 1986-11-05
JP2587919B2 (en) 1997-03-05
US4767258A (en) 1988-08-30
EP0200996A1 (en) 1986-11-12
DE3661275D1 (en) 1988-12-29
SU1586523A3 (en) 1990-08-15
ES554642A0 (en) 1987-07-01

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