EP4276202A1 - Method for charging raw material into blast furnace - Google Patents

Method for charging raw material into blast furnace Download PDF

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Publication number
EP4276202A1
EP4276202A1 EP22755842.6A EP22755842A EP4276202A1 EP 4276202 A1 EP4276202 A1 EP 4276202A1 EP 22755842 A EP22755842 A EP 22755842A EP 4276202 A1 EP4276202 A1 EP 4276202A1
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EP
European Patent Office
Prior art keywords
raw material
charging
storage part
blast furnace
eccentricity
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.)
Pending
Application number
EP22755842.6A
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German (de)
English (en)
French (fr)
Other versions
EP4276202A4 (en
Inventor
Koki Terui
Masaru Ida
Takeshi Sato
Yasushi Ogasawara
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JFE Steel Corp
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JFE Steel Corp
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Filing date
Publication date
Application filed by JFE Steel Corp filed Critical JFE Steel Corp
Publication of EP4276202A1 publication Critical patent/EP4276202A1/en
Publication of EP4276202A4 publication Critical patent/EP4276202A4/en
Pending legal-status Critical Current

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    • CCHEMISTRY; METALLURGY
    • C21METALLURGY OF IRON
    • C21BMANUFACTURE OF IRON OR STEEL
    • C21B5/00Making pig-iron in the blast furnace
    • C21B5/008Composition or distribution of the charge
    • 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
    • C21B5/00Making pig-iron in the blast furnace
    • C21B5/001Injecting additional fuel or reducing agents
    • C21B5/003Injection of pulverulent coal
    • 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
    • F27BFURNACES, KILNS, OVENS, OR RETORTS IN GENERAL; OPEN SINTERING OR LIKE APPARATUS
    • F27B3/00Hearth-type furnaces, e.g. of reverberatory type; Tank furnaces
    • F27B3/10Details, accessories, or equipment peculiar to hearth-type furnaces
    • F27B3/18Arrangements 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
    • F27D3/0025Charging or loading melting furnaces with material in the solid state
    • 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
    • F27D3/0033Charging; Discharging; Manipulation of charge charging of particulate material
    • 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

Definitions

  • This disclosure relates to a method of charging raw material into a blast furnace.
  • a blast furnace as illustrated in FIG. 1 , usually operates to obtain pig iron by charging sintered ores, pellets, lumps of ore, and other ore material, and coke alternately in layers from the top to form ore layers and coke layers and by flowing a hot-reducing gas upward from ends of tuyeres.
  • ore material and coke are referred to collectively as raw material.
  • reference numeral 1 is a blast furnace
  • reference numeral 2 is a tuyere
  • reference numeral 3 is an ore layer
  • reference numeral 4 is a coke layer
  • reference numeral 5 is a fusion layer.
  • the flow of gas in the blast furnace affects the reduction efficiency of ore material and the amount of heat dissipated out of the blast furnace.
  • the packed particles of the former have a smaller total specific surface area, i.e., the friction between the particles and the gas flowing through the packed layer is reduced and the gas flow rate increases.
  • JP 4591520 B (PTL 1) proposes: "A method of charging raw material into a blast furnace which uses a bell-less charging device equipped with a rotating chute and in which bunkers are arranged in parallel at the top of the furnace, comprising:
  • furnace top bunkers which temporarily store raw material to be charged into the blast furnace, are located at a top part of the blast furnace.
  • a flow regulating gate is then opened to charge the raw material, which is discharged from the furnace top bunker, into the blast furnace through a collecting hopper and rotating chute.
  • the radial tip position of the rotating chute may be changed (hereinafter referred to as tilting) to adjust the drop position of the raw material in the radial direction of the blast furnace.
  • reference numeral 6 are furnace top bunkers
  • reference numeral 7 are flow regulating gates
  • reference numeral 8 is a collecting hopper
  • reference numeral 9 is a rotating chute.
  • the rotating chute when charging raw material into the blast furnace, rotates at a constant speed in the circumferential direction of the blast furnace with the axial center of the blast furnace as its axis of rotation, while tilting at regular intervals.
  • the tilting mode is divided into two main types: forward tilt charging, in which the rotating chute is tilted from near the blast furnace wall to the center part of the blast furnace, and reverse tilt charging in which the rotating chute is tilted from the center part of the blast furnace to near the wall of the blast furnace.
  • reverse tilt charging has the effect of preventing raw material from flowing into the center part of the blast furnace after the raw material is charged and deposited into the blast furnace. Therefore, reverse tilt charging, in comparison with forward tilt charging, more easily stabilizes the raw material deposition shape and is more advantageous for controlling the raw material particle size distribution in the blast furnace.
  • the furnace top bunkers typically store the raw material for each batch. Therefore, when performing reverse tilt charging, the raw material particle size distribution in the furnace top bunker is preferably such that much of the large particle size raw material is discharged at the initial stage of raw material discharge from the furnace top bunker.
  • the technology of PTL 1 intentionally segregates the raw material stored in a furnace top bunker by using a freely tilting movable plate (hereinafter referred to as a segregation control plate) installed in the furnace top bunker.
  • a segregation control plate installed in the furnace top bunker.
  • FIG. 3 is a schematic diagram illustrating the arrangement of each part of the furnace top bunker when viewed from above in the vertical direction.
  • reference numeral 6-1 is a raw material storage part
  • reference numeral 6-2 is a raw material discharge outlet.
  • the direction of eccentricity is defined as a direction from the center of the raw material storage part to the center of the raw material discharge outlet in a horizontal plane.
  • a direction rotated 90° clockwise from the direction of eccentricity is called a first direction
  • a direction rotated 180° is called a direction opposite eccentricity
  • a direction rotated 270° is called a second direction.
  • the raw material discharge outlet of the furnace top bunker is located eccentrically from the center of the raw material storage part to the axial center of the blast furnace in the horizontal plane (projected surface to the vertical direction).
  • the direction of eccentricity is usually the same direction as the direction from the center of the raw material storage part to the axial center of the blast furnace (hereinafter also referred to as the blast furnace axial center direction).
  • the segregation control plate When performing reverse tilt charging with the technology of PTL 1, the segregation control plate is operated so that the drop direction of raw material is near the side opposite the raw material discharge outlet of the furnace top bunker in a horizontal plane, that is, near the wall in the direction opposite eccentricity (hereinafter referred to as the wall opposite eccentricity) as illustrated in FIG. 4 . Therefore, the shape of the stacked layers of raw material in the furnace top bunker is such that a raw material deposition surface inclines vertically downward toward the direction of eccentricity (from the wall opposite eccentricity to the wall in the direction of eccentricity (hereinafter referred to as the wall of eccentricity)).
  • 6-3 is a segregation control plate.
  • the particle size distribution of raw material in the furnace top bunker and the raw material discharge sequence when discharging raw material from the furnace top bunker were calculated with a numerical simulation called the discrete element method, and as illustrated in FIG. 5 , more than half of the large particle size raw material collects near the raw material discharge outlet, i.e., in the area where the raw material is discharged at the initial stage of raw material discharge.
  • the first wall and the second wall which are perpendicular to the direction of eccentricity of the furnace top bunker, i.e., in the area where the raw material is discharged at the mid to end stages of raw material discharge.
  • this causes a certain amount of large particle size raw material to be mixed also near the furnace wall of the blast furnace when performing reverse tilt charging.
  • the gas flow rate near the center part of the blast furnace can be increased during blast furnace operation regardless of the tilting mode to further improve gas permeability and reduction efficiency.
  • the method of charging raw material into a blast furnace is carried out in a blast furnace equipped with one or more furnace top bunkers arranged at the top part of the furnace, and comprises:
  • the furnace top bunkers are located at the top part of the blast furnace and temporarily stores raw material to be charged into the blast furnace.
  • the number of furnace top bunkers located at the top part of the blast furnace is not particularly limited and can be appropriately set according to the number of raw material types and the capacity required for the furnace top bunkers, but the number is usually 2 to 4.
  • the following is a description of the furnace top bunker used in the method of charging raw material into a blast furnace according to one of the disclosed embodiments, as well as the storing process and charging process of the method of charging raw material into a blast furnace according to one of the disclosed embodiments.
  • a furnace top bunker comprising:
  • the above furnace top bunker is used for all of the furnace top bunkers located at the top part of the blast furnace.
  • top part and bottom part shall mean above, below, top part and bottom part in the vertical direction, unless otherwise noted.
  • the raw material charging inlet is located at the top part of the raw material storage part.
  • the position of the raw material charging inlet in the horizontal plane is not particularly limited but is generally positioned from the center position of the raw material storage part to the axial center of the blast furnace (in the same direction as the raw material discharge outlet).
  • the raw material charged from the raw material charging inlet is caused to impinge on the raw material impingement surface of the structure located inside the raw material storage part, then drops into the raw material storage part and is temporarily stored in the raw material storage part.
  • the raw material temporarily stored in the raw material storage part is usually one batch.
  • the raw material storage part has a body part, which can be cylindrical, conical cylindrical, or a combination of these shapes, and a reduced diameter part that decreases in diameter toward the bottom.
  • the maximum diameter (outer diameter) of the furnace top bunkers is usually 4000 mm to 5000 mm, and the height of the furnace top bunkers is 9000 mm to 13000 mm.
  • a flow regulating gate is opened and the raw material is gradually discharged from the raw material discharge outlet at the bottom edge of the reduced diameter part of the raw material storage part by the weight of the raw material, and the raw material is charged into the blast furnace through the collecting hopper and rotating chute.
  • the raw material discharge outlet is eccentric from the center of the raw material storage part in the horizontal plane, and usually the distance, denoted as A, between the centers of the raw material storage part and the raw material discharge outlet in the horizontal direction (amount of eccentricity) is 0.60 to 0.70 times the inner radius, R, of the raw material storage part.
  • the inner radius, B, of the raw material discharge outlet is usually 0.10 to 0.30 times the inner radius R of the raw material storage part.
  • the center position and inner diameter of the raw material storage part are based on the installation height of the top part of the structure, which is described below.
  • the center position and inner diameter of the raw material discharge outlet are based on the height where it connects with the bottom edge of the raw material storage part. The same also applies hereafter.
  • the horizontal cross-section of the raw material storage part is described by way of example as a circular shape.
  • the center of the raw material storage part is the center of gravity of the horizontal cross-section that has the largest area.
  • the direction of eccentricity is the direction from the center of the raw material storage part to the center of the raw material discharge outlet, which connects the center of the raw material discharge outlet and the center of the raw material storage part in the relevant horizontal cross-section (the horizontal cross-section that has the largest area), where R is 1/2 the length of the raw material storage part in the direction of eccentricity in the relevant horizontal cross-section.
  • the shape of the raw material impingement surface of the above structure is extremely important.
  • the shape of the raw material impingement surface incline downward from the top part of the structure (raw material impingement surface) to the edge parts of the raw material impingement surface, at least in each of the direction of eccentricity, the direction opposite eccentricity, and the first direction and the second direction which are perpendicular to the direction of eccentricity and the vertical direction.
  • the drop position of the raw material charged into the furnace top bunker is distributed not only near the wall opposite eccentricity, but also near the first wall and the second wall as illustrated in FIG. 6 .
  • the shape of the raw material impingement surface of the above structure (circumferential shape of the vertical cross-section) incline downward from the top part of the structure to the edge parts of the raw material impingement surface not only in the direction opposite eccentricity but also in each of the first direction and the second direction.
  • the drop position of raw material charged into the furnace top bunker is distributed not only near the wall of eccentricity (i.e., near the raw material discharge outlet) but also near the first wall and the second wall. Therefore, it is important that the shape of the stacked layers of raw material in the furnace top bunker are made to incline vertically downward toward the wall opposite eccentricity, not only from the wall of eccentricity but also from the first wall and the second wall. This enables the large particle size raw material to collect at a position away from the raw material raw discharge outlet. That is, large particle size raw material is discharged at the end stage of discharge from the furnace top bunker.
  • the shape of the raw material impingement surface of the above structure (circumferential shape of the vertical cross section) incline downward from the top part of the structure to the edge part of the raw material impingement surface, even in the direction of eccentricity.
  • the shape of the raw material impingement surface inclining downward from the top part of the structure to the edge parts of the raw material impingement surface in the direction of eccentricity and direction opposite eccentricity means that when the vertical cross-section of the structure at a position which passes through the top part of the structure is viewed from the first direction, the shape inclines downward from the top part of the structure to the edge parts of the raw material impingement surface as illustrated in FIG. 8 .
  • the shape of the raw material impingement surface inclining downward from the top part of the structure to the edge parts of the raw material impingement surface in the first direction and the second direction means that when the vertical cross-section of the structure at a position which passes through the top part of the structure is viewed from the direction of eccentricity, the shape inclines downward from the top part of the structure to the edge parts of the raw material impingement surface in the first direction and the second direction as illustrated in FIG. 8 . It also means that the shape inclines downward from the highest point on the raw material impingement surface to the edge parts in the cross-section of the structure along the first direction and the second direction.
  • the raw material impingement surface is the top surface of the structure (the area of the structure when viewed from above). Therefore, the top part of the structure is the highest point on the raw material impingement surface in the vertical direction. In the case there are multiple highest points on the raw material impingement surface, the point that is at the furthest distance from the raw material discharge outlet in the direction of eccentricity among the highest points is considered to be the top part. Components and other members used to secure the structure are excluded from the raw material impingement surface.
  • the raw material impingement surface may comprise one continuous surface or multiple surfaces.
  • Inclination angles ⁇ and ⁇ ' of line segments connecting the top part of the structure and the edge parts of the raw material impingement surface in the direction of eccentricity and the direction opposite eccentricity are each preferably 25° or more from a horizontal direction, ⁇ and ⁇ ' are each preferably 45° or less. ⁇ and ⁇ ' are each more preferably 40° or more. ⁇ and ⁇ ' are each more preferably 43° or less.
  • inclination angles ⁇ and ⁇ of line segments connecting the top part of the structure and the edge parts of the raw material impingement surface in the first direction and the second direction are each preferably 25° or more from the horizontal direction.
  • ⁇ and ⁇ are each preferably 45° or less.
  • ⁇ and ⁇ are each more preferably 40° or more.
  • ⁇ and ⁇ are each more preferably 43° or less.
  • the shape from the top part of the structure to the edge parts of the raw material impingement surface in a direction from the first direction, through the direction opposite eccentricity to the second direction (a direction between 90° and 270° clockwise from the direction of eccentricity) also preferably inclines downward from the top part of the structure to the edge parts of the raw material impingement surface.
  • Suitable inclination angles from the horizontal direction of the straight lines connecting the top part of the structure and the edge parts of the raw material impingement surface in these directions are also similar to the inclination angles ⁇ , ⁇ ', ⁇ and ⁇ above.
  • the shape (circumferential shape) of the structure from the top part of the structure to the edge parts of the raw material impingement surface in each vertical section of the structure does not have to be a constant slope regardless of the direction but can be a shape whose slope varies in various ways, such as an arc shape or a shape whose slope varies in steps, as illustrated in FIG. 9 .
  • the shape from the top part of the structure to the edge parts of the raw material impingement surface in a direction from the first direction, through the direction of eccentricity to the second direction is not particularly limited.
  • the shape may incline downward from the top part of the structure to the edge parts of the raw material impingement surface.
  • the shape of the structure may be, for example, a cone, an oblique cone, an elliptical cone, a cone joined on top of a conical base (Shape 1), a half-split cone and a half-split elliptical cone joined at their cut surfaces (Shape 2), a dome whose raw material impingement surface is a sphere, a polyhedron such as a square pyramid, hexagonal pyramid, octagonal pyramid, and shapes such as these cut in a vertical direction at arbitrary positions.
  • the interior of the structure may be hollow, and no members may be placed on surfaces other than the raw material impingement surface, such as the bottom and sides.
  • the shapes described above also include those whose shape has been changed by providing a member to the bottom or other surface, as long as the area of the raw material impingement surface does not change.
  • the length, a, of the above structure (the distance between the edge parts of the raw material impingement surface in the horizontal direction when the structure is viewed from the first direction) is preferably 0.4 to 0.8 times the inner radius R of the raw material storage part (see FIG. 8 , the same applies to the width and height of the structure described below).
  • the width, b, of the above structure (the distance between the edge parts of the raw material impingement surface in the horizontal direction when the structure is viewed from the direction of eccentricity) is preferably 0.4 to 0.8 times the inner radius R of the raw material storage part.
  • the height, h, of the above structure (the distance from the bottom edge of the raw material impingement surface to the top part) is preferably 0.47 to 1.0 times the length a of the structure.
  • the shape of the structure may be symmetrical or asymmetrical in the first direction and the second direction.
  • the top part of the structure is preferably positioned at a dimensionless distance (r/R) of 0 to 0.6 from the center of the raw material storage part, as illustrated in FIG. 11 .
  • the dimensionless distance (r/R) is a value obtainable by dividing the distance (r) from the center of the raw material storage part in the horizontal plane (projected surface to the vertical direction) by the inner radius (R) of the raw material storage part.
  • the dimensionless height (h'/H) at the top part of the structure is preferably in the range of 0.75 to 0.85.
  • the dimensionless height (h'/H) is a value obtainable by dividing the distance (height), h', from the bottom edge of the furnace top bunker (the height position of the raw material discharge outlet) to the top part of the structure in the vertical direction by the height, H, of the furnace top bunker.
  • the above structure is preferably arranged so that the shape is symmetrical with respect to a vertical line passing through the center of the raw material storage part when viewed from the direction of eccentricity.
  • the shape does not have to be symmetrical as long as it inclines downward from the top part of the structure to the edge parts in the first direction and the second direction.
  • the materials of the above structures are not particularly limited, and in general steel or other materials can be used.
  • the installation method of the structure is not particularly limited.
  • a beam member can be fixed to the inner wall of the furnace top bunker by metal fittings or welding, and the above structure can be fixed to this beam member by metal fittings or welding.
  • the above structure may have a position adjustment mechanism for changing its position and an installation angle adjustment mechanism for changing its installation angle.
  • the storing process of the method of charging raw material into a blast furnace comprises: charging raw material from the charging inlet of the furnace top bunker to the raw material storage part; and, after causing the raw material to imping on the structure, storing the raw material in the raw material storage part.
  • the preferred raw material particle size distribution in the furnace top bunker varies depending on the tilting mode.
  • whether the raw material impingement position on the structure is in the direction opposite eccentricity or in the direction of eccentricity is determined based on a representative position in the direction opposite eccentricity of the raw material impingement range on the structure.
  • the impingement position (range) of each particle of raw material on the structure (raw material impingement surface) when viewed from above in the vertical direction is plotted with the top part of the structure as the origin, the horizontal axis (x-axis) as the distance from the top part of the structure in the direction opposite eccentricity, and the vertical axis (y-axis) as the distance from the top part of the structure in the first direction (the distances in the direction opposite eccentricity and the first direction are positive values, and the distances in the direction of eccentricity and the second direction are negative values).
  • the position of the center of gravity in the direction opposite eccentricity i.e., the average value in the direction opposite eccentricity (x-coordinate) in the plot of the impingement position of each particle
  • the position of the center of gravity in the first direction i.e., the average value in the first direction (y-coordinate) in the plot of the impingement position of each particle
  • the representative position in the first direction is the representative position in the first direction of the raw material impingement range on the structure (hereinafter referred to simply as the representative position in the first direction).
  • the raw material impingement position on the structure is further in the direction opposite eccentricity than the top part of the structure, and if the impingement representative position in the direction opposite eccentricity is a negative value (less than 0), the raw material impingement position on the structure is further in the direction of eccentricity than the top part of the structure.
  • the representative position of impingement in the direction opposite eccentricity is preferably in the range of a 1 /4 to a 1 /2.
  • a 1 is the distance between the top part of the structure and the edge part of the raw material impingement surface in the direction opposite eccentricity (the distance between the top part of the structure and the edge part of the raw material impingement surface in the direction opposite eccentricity when the structure is viewed from the first direction, see FIG. 8 ).
  • the representative position of impingement in the direction opposite eccentricity is preferably in the range of -a 2 /2 to -a 2 /4.
  • a 2 is the distance between the top part of the structure and the edge part of the raw material impingement surface in the direction of eccentricity (the distance between the top part of the structure and the edge part of the raw material impingement surface in the direction of eccentricity when the structure is viewed from the first direction, see FIG. 8 ).
  • the impingement range of the raw material in the first direction on the structure is not particularly limited, but the representative position in the first direction of the raw material impingement range on the structure (hereinafter also referred to as the representative position of impingement in the first direction) is preferably in the range of -b/10 to b/10. Particularly preferably, the representative position of impingement in the first direction is 0.
  • the raw material impingement ratio on the structure may be 100 %.
  • the raw material impingement position and raw material impingement angle on the structure can be adjusted by, for example, providing a movable control plate 17 in a raw material flow passage from the receiving hopper to the raw material charging inlet of the furnace top bunker as illustrated in FIG. 16 and changing its position and angle.
  • FIG. 16 illustrates a case in which the raw material impingement surface of the movable control plate 17 is fixed at a right angle to the horizontal plane and the movable control plate 17 is moved in the direction opposite eccentricity and the direction of eccentricity of the furnace top bunker 6, but the embodiment is not so limited.
  • the above storing process comprises: discharging, from the raw material discharge outlet, the raw material stored in the raw material storage part of the furnace top bunker; and charging the discharged raw material into the blast furnace through the rotating chute of the blast furnace, either by reverse tilt charging or forward tilt charging.
  • the raw material when performing reverse tilt charging, the raw material is discharged from the furnace top bunker, which has a raw material particle size distribution suitable for reverse tilt charging, and the discharged raw material is charged into the blast furnace.
  • the raw material when performing forward tilt charging, the raw material is discharged from the furnace top bunker, which has a raw material particle size distribution suitable for forward tilt charging, and the discharged raw material is charged into the blast furnace.
  • the gas flow rate near the center part of the blast furnace increases for both forward tilt charging and reverse tilt charging, improving gas permeability and reduction efficiency.
  • the conditions are not particularly limited to those above and may be in accordance with conventional methods.
  • the furnace top bunkers were modeled in accordance with Condition 1 and Condition 2 below, and the raw material particle size distribution in each furnace top bunker when charging raw material into the furnace top bunker and the raw material discharge sequence when discharging raw material from the furnace top bunker (the discharge time for each raw material storage position in the furnace top bunker) were calculated using the discrete element method.
  • the raw material charging conditions were also the same for Conditions 1 and 2.
  • the raw material here refers to ore, and the amount of raw material charged is equivalent to one batch.
  • the particle size was represented by three types of particles: large particles, medium particles, and small particles, and the particle size ratio of large particles, medium particles, and small particles was set to 3.8:2.0:1.0 to match the actual raw material. It was further assumed that the large, medium, and small particles each contained the same mass. At this time, the same bunker of coke was used for Conditions 1 and 2, and the charging conditions were the same.
  • FIG. 12 illustrates representative results of the evaluation when reverse tilt charging was performed.
  • Condition 1 achieved a raw material particle size distribution in the furnace top bunker suitable for reverse tilt charging.
  • large particles collect near the raw material discharge outlet and many large particles can be discharged at the initial stage of discharge from the furnace top bunker. It was also possible to achieve a raw material particle size distribution in the furnace top bunker suitable for forward tilt charging.
  • large particles collect at a position away from the raw material discharge outlet and many large particles can be discharged at the end stage of discharge from the furnace top bunker.
  • Condition 2 (comparative example) could not sufficiently collect large particles near the raw material discharge outlet in the case of reverse tilt charging and could not achieve a raw material particle size distribution in the furnace top bunker suitable for reverse tilt charging.
  • Model experiments were also conducted to confirm the accuracy of the particle size distribution in the furnace top bunker based on the above numerical simulation.
  • reference numeral 10 is a charging belt conveyor
  • reference numeral 11 are furnace top bunker models
  • reference numeral 12 is a collecting hopper model
  • reference numeral 13 are sampling boxes
  • reference numeral 14 is a roller conveyor
  • reference numeral 15 is a belt conveyor for the sampling boxes
  • reference numeral 16 is a segregation control plate model or structure model.
  • the raw material (in this case ore) was then charged from the charging belt conveyor into the furnace top bunker model of the furnace.
  • the charging position of the raw material (the impingement position of raw material impinging on the segregation control plate model and the structure model) was adjusted by changing the position of the charging belt conveyor.
  • the valve of the discharge outlet connected to the bottom edge of the furnace top bunker model was opened and the raw material was discharged from the discharge outlet.
  • the discharged raw material was then collected in multiple sampling boxes. At this time, the sampling boxes were gradually moved in a horizontal direction by a belt conveyor for the sampling boxes, and the discharged material was sorted chronologically at regular intervals from the start of discharge to the end of discharge.
  • the dimensionless particle size of the raw material for each dimensionless discharge time was then calculated by sieving the raw material collected in each sampling box, calculating the average particle size of the raw material collected in each sampling box, and dividing the result by the average particle size of all the raw material before being charged the raw material into the furnace top bunker model. The results are illustrated in FIGS. 14 and 15 .
  • FIGS. 14 and 15 illustrate that the model experiment also produced data that corroborate the above numerical simulation results.
  • Condition 1 in the case of forward tilt charging, many large particles could be discharged at the end stage of discharge from the furnace top bunker. In the case of reverse tilt charging, many large particles could be discharged at the initial stage of discharge from the furnace top bunker.
  • Condition 2 comparative example
  • Condition 1 comparative example

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  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • Mechanical Engineering (AREA)
  • General Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Materials Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Blast Furnaces (AREA)
  • Manufacture Of Iron (AREA)
EP22755842.6A 2021-02-19 2022-01-24 PROCESS FOR CHARGING RAW MATERIAL INTO A BLAST FURNACE Pending EP4276202A4 (en)

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PCT/JP2022/002471 WO2022176518A1 (ja) 2021-02-19 2022-01-24 高炉の原料装入方法

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JPS62218507A (ja) * 1986-03-17 1987-09-25 Sumitomo Metal Ind Ltd ベルレス高炉の原料装入方法
JP4460661B2 (ja) 1998-12-15 2010-05-12 Jfeスチール株式会社 高炉の炉頂バンカの使用方法
JP4591520B2 (ja) 2008-02-15 2010-12-01 Jfeスチール株式会社 炉頂バンカ及びベルレス型装入装置を用いた高炉の原料装入方法
JP5810509B2 (ja) * 2009-11-24 2015-11-11 Jfeスチール株式会社 高炉炉頂バンカーの原料偏析装置
JP2012072471A (ja) * 2010-09-29 2012-04-12 Jfe Steel Corp 炉頂バンカー及びこれに使用した高炉への原料装入方法
JP2016053201A (ja) * 2014-09-04 2016-04-14 Jfeスチール株式会社 高炉原料の装入方法
JP6304174B2 (ja) * 2015-08-19 2018-04-04 Jfeスチール株式会社 高炉への原料装入方法

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KR20230109743A (ko) 2023-07-20
JP7343052B2 (ja) 2023-09-12

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