KR102008372B1 - Raw material process apparatus - Google Patents

Abstract

The raw material processing apparatus according to the embodiment of the present invention includes a plurality of upper openings formed to be spaced apart from each other, extending in one direction, and capable of classifying raw materials according to particle diameters. And a classification section located outside of the upper screen to guide movement of the raw material to the upper screen, and having a plurality of lower openings spaced apart from each other, and positioned below the upper screen and the classification section, And a lower screen capable of sorting the raw material dropped from the screen and the classification unit according to the particle size.
Therefore, according to the embodiment of the present invention, the amount of raw material to be classified in the upper screen can be reduced, and the raw material can be spread widely over the entire area of the upper screen. Therefore, the classification efficiency by the upper screen can be reduced as compared with the conventional one, and thus, the raw material having a small particle size which is not suitable to be used as the raw material of the blast furnace can be reduced compared to the conventional one. For this reason, the problem that the air permeability of the raw material in a blast furnace is reduced can be prevented.

Description

Raw material processing device {RAW MATERIAL PROCESS APPARATUS}

The present invention relates to a raw material processing apparatus, and more particularly to a raw material processing apparatus that can improve the raw material sorting efficiency according to the particle size.

Generally, the charges charged to the blast furnace are fuels such as coke and steel raw materials (sintered or iron ore) .In general, after charging fuels such as coke, charged steel raw materials (sintered or iron ore), and then subsidiary materials and steel raw materials are charged again. Repeat charging in sequence. At this time, the various raw materials are crushed using a crusher, and then sorted to have a predetermined particle size using a screen device, and then charged into the blast furnace.

The screen facility is located below the chute, and includes a screen body having an inner space, an upper and lower screens spaced up and down inside the screen body, and each having an opening, and a vibrating unit for vibrating the screen body. According to such a screen facility, the raw material discharged from the chute to the screen body moves in the extending direction of the upper screen by vibration by the vibrating unit. At this time, the raw material having a smaller particle size than the upper opening provided in the upper screen falls through the upper opening to the lower screen, and the raw material that does not pass through the upper opening moves in the extending direction of the upper screen and is provided outside the screen facility. It is charged into the first hopper. Then, the raw material dropped through the upper opening of the upper screen is secondary classified by the lower screen having a lower opening of a smaller size than the upper opening. That is, among the raw materials dropped through the upper opening to the lower screen, the raw material having a smaller particle diameter than the lower opening falls through the lower opening to the lower side, and the raw materials of the small particles are placed on the lower side of the lower screen. It is loaded into the hopper. Then, the raw material having a larger particle size than the lower opening moves in the extending direction of the lower screen and is charged into the first hopper provided on the outside of the screen equipment. The raw materials classified by the upper screen and the lower screen and charged into the first hopper are used as raw materials for the blast furnace.

As described above, the raw material discharged from the chute is first dropped and moved to the upper screen, and is primarily classified. In other words, the upper screen becomes the initial classification means. Thus, the amount of raw material passing through the upper screen is excessively high, and therefore the height of the raw material loaded in the vertical direction on the upper screen is high. In addition, as a large amount of the raw material is moved to the upper screen by the chute, there is a problem that it does not spread widely over the entire area of the upper screen, but is scattered to one side, which means that the material loading amount is high on either of the upper screens. In this case, the amount of the raw material loaded on the raw material having a larger particle size compared to the upper opening of the upper screen is increased. Therefore, a raw material having a smaller particle size than the upper opening of the upper screen does not pass through the upper opening, and is charged into the first hopper as it is.

Thereby, the loading amount of the small raw material which is not suitable as a raw material of blast furnace among the raw materials classified by the upper screen and charged to the 1st hopper increases. The raw material of elementary granules is a factor deteriorating air permeability in the blast furnace, thereby reducing the molten iron quality or the molten iron production.

Korean Laid-Open Patent 2003-0035664

The present invention provides a raw material processing apparatus capable of efficiently distributing raw materials to the upper and lower screens, and inducing the raw materials to spread over the entire area of each of the upper and lower screens.

According to an embodiment of the present invention, a raw material processing apparatus includes: an upper screen having a plurality of upper openings formed to be spaced apart from each other, extending in one direction, and allowing selection of raw materials according to particle diameters; A classification unit having a plurality of classification lines capable of classifying the raw materials according to the particle diameter and positioned outside the upper screen to guide the movement of the raw materials to the upper screen; And a lower screen having a plurality of lower openings formed to be spaced apart from each other and positioned below the upper screen and the classification unit, and capable of sorting the raw materials dropped from the upper screen and the classification unit according to particle diameters.

It is a shape of the empty space extending in the extending direction of the classification line upper screen, the plurality of classification lines are formed to be spaced apart from each other in a direction crossing the extension direction of the upper screen.

Located above the classifier, and includes a chute for discharging the raw material to the classifier.

The classification unit includes a plurality of classification members each of which is formed extending in the direction of the upper screen and the chute, arranged in a direction crossing the extension direction of the upper screen and spaced apart from each other, the classification line is continuous It is a spaced space between the classification members arranged.

An area of the upper opening is larger than an area of the lower opening, an area of the classification line is larger than an area of the lower opening, and an area of the classification line is equal to or larger than an area of the upper opening.

An area of the upper opening is larger than an area of the lower opening, an area of the classification line is larger than an area of the lower opening, and an area of the classification line is smaller than an area of the upper opening.

The classification member may include a classification body extending in one direction; And a liner formed to surround at least a portion of the surface of the classification body and comprising a wear resistant material.

The liner is formed on the upper surface of the classification body.

The classification body may include a first body member extending in an extending direction of the upper screen; And extending in the extending direction of the first body member, the width of the direction crossing the extending direction of the first body member being smaller than that of the first body member and provided to protrude from an upper portion of the first body member. Two-body member.

In the lower side of the chute, located between the classifier and the lower screen and the chute, the guide portion for guiding the raw material discharged from the chute to the classification unit, and guides the raw material dropped from the classification line in the direction of the lower screen Include.

Among the guides, the upper surface facing the classifier and the lower screen includes an upper inclined surface that is inclined closer to the classifier and a lower inclined surface that is inclined closer to the lower screen from the upper inclined surface toward the lower side. Include.

The upper inclined surface includes a first inclined surface disposed relatively upward and a second inclined surface positioned below the first inclined surface, and the inclined degree of the second inclined surface is lower than that of the first inclined surface.

According to the embodiment of the present invention, the amount of raw material to be classified in the upper screen can be reduced, and the raw material can be spread widely over the entire area of the upper screen. Therefore, the classification efficiency by the upper screen can be reduced as compared with the conventional one, and thus, the raw material having a small particle size which is not suitable to be used as the raw material of the blast furnace can be reduced as compared with the conventional one. For this reason, the problem that the air permeability of the raw material in a blast furnace is reduced can be prevented.

1 is a three-dimensional view illustrating a raw material processing facility according to an embodiment of the present invention
Figure 2 is a three-dimensional view showing the classifier, guide, upper and lower screen according to an embodiment of the present invention
4 is a three-dimensional view showing a classification member according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention and to those skilled in the art. It is provided for complete information.

The present invention relates to a raw material processing apparatus for sorting raw materials by particle diameter before charging raw materials for blast furnace molten iron production. A raw material processing apparatus according to the embodiment is disposed between a storage bin (not shown) in which raw materials are stored and a hopper, and classifies raw materials provided from the storage bins according to particle diameters.

Hereinafter, a raw material processing apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4.

1 is a three-dimensional view for explaining a raw material processing facility according to an embodiment of the present invention. Figure 2 is a three-dimensional view showing the classifier, guide, upper and lower screen according to an embodiment of the present invention. 3 is a cross-sectional side view of a classification apparatus according to an embodiment of the present invention. 4 is a three-dimensional view showing a classification member according to an embodiment of the present invention.

Referring to FIG. 1, a raw material processing apparatus according to an embodiment of the present invention is located at a lower side of a storage bin, and works at the lower side of the chute 100 and the chute 100 for guiding raw materials supplied or moved from the storage bin. It extends in the direction and includes a classification device 200 for classifying the raw material provided from the chute 100 according to the particle diameter.

The chute 100 is connected to the lower portion of the storage bin 10 to guide the raw material discharged from the storage bin 10 to the classification apparatus 200. The chute 100 has an internal space capable of passing or moving raw materials, and has a cylindrical shape in which an upper portion corresponding to the storage bin and a lower portion corresponding to the classification apparatus 200 are opened. Then, the gate 110 is provided to open and close the lower opening of the chute 100, when the lower opening is opened by the gate 110, the raw material in the chute 100 is cut out or discharged to the classification apparatus 200. do. The chute 100 moves downward from the position of the storage bin 10 in the direction in which the classification apparatus 200 is located so as to stably or efficiently guide and move the raw materials provided from the storage bin 20 to the classification apparatus 200. It is preferable that it is inclined shape. In addition, it is effective that the chute 100 is formed such that its width becomes narrower toward the lower side.

1 and 2, the classifier 200 is formed extending in one direction from the bottom of the chute 100, a plurality of openings (hereinafter, the upper opening 212) to be classified according to the particle size of the raw material The upper screen 210 is provided between the chute 100 and the upper screen 210 in the lower side of the chute 100, a plurality of classification lines 232 through which at least a portion of the raw material can be passed depending on the particle size The classification unit 230 having a lower portion of the upper screen 210, and has a smaller opening (hereinafter, the lower opening 222) than the upper opening 212 is provided with a lower screen (220). In addition, the classification apparatus 200 may include a main body 240 installed inside the upper screen 210, the classification unit 230, and the lower screen 220 to surround side surfaces of the chute 100. Located at the lower side, the guide portion 260, which guides the raw material discharged from the chute 100 can be moved to the classifier 230 and the lower screen 220, the body 240 may be vibrated up and down A first hopper provided on one side of the upper and lower screens 210 and 220 so as to face the vibrator (not shown) and the chute 100, and temporarily storing the raw material moved through the upper and lower screens 210 and 220 ( 240, a second hopper 250 positioned below the lower screen 220 to temporarily store raw materials classified by the lower screen.

The upper screen 210 selects a raw material having a size or particle size suitable for use as a raw material of the blast furnace among the raw materials provided from the chute 100, and the raw material remaining on the upper screen 210 is transferred to the first hopper 240. After charging, it is then moved to the blast furnace. To this end, the upper screen 210 is provided to be located between the chute 100 and the first hopper 240, one end facing the chute 100 is connected to the classifier 230, the first hopper 240 The other end facing the) is not closed by the main body 240 but is open.

The upper screen 210 is formed of an upper screen member 211 extending in one direction, each of which penetrates the upper screen member 211 in an up and down direction, and a plurality of upper openings spaced apart from each other on the upper screen member 211. 212. The upper opening 212 is for classifying the raw material to be charged into the blast furnace, and the size of the upper opening 212 depends on the size to be used or suitable for use as the raw material of the blast furnace. That is, since the raw material supplied to the first hopper 240 along the upper screen member 211 without passing through the upper opening 212 is used as the raw material of the blast furnace, according to the target particle diameter to be used in the blast furnace, The size of 212) may vary. The upper opening 212 according to the embodiment may be, for example, a rectangle having a pair of opposing long sides and a pair of short sides, and may have a rounded corner at which the short side and the long side meet. Of course, the shape of the upper opening 212 is not limited to the above-described examples and can be variously changed in various shapes, for example, oval, circular, and polygonal.

In addition, the upper opening 212 as described above is provided in plural, preferably provided evenly distributed over the entire area of the upper screen member 211.

The classification unit 230 is a means for primarily classifying the raw material discharged from the chute 100 before moving to the upper screen 210. In other words, the classification unit 230 primarily classifies the raw material discharged from the chute 100 to reduce the amount of raw material directed to the upper screen 210 as compared with the conventional. The classification unit 230 according to the embodiment is formed in each extending in the extending direction of the upper screen 210, the plurality of classification member 231 disposed to be spaced apart from each other in a direction crossing the extending direction of the upper screen 210. Include.

Hereinafter, the direction in which the classifying member 231, the upper screen 210, and the lower screen 220 extend, the chute 100, the classifying unit 230, and the upper screen 210 are listed in the x-axis direction. This direction is referred to as the y-axis direction.

The classifying member 231 is positioned between the upper screen 210 and the guide 260, and the classifying member 231 according to the embodiment is arranged in an arrangement direction of the upper screen 210 and the guide 260, that is, the x axis. Extending in the direction. The classification members 231 are provided in plural and are spaced apart from each other in the y axis direction. Here, the separation space between two continuous classification members 231 is the classification line 232. That is, the classifier 230 is formed to extend in the x-axis direction, and is a spaced space between the plurality of classification members 231 arranged in the y-axis direction and the classification members 231 arranged in succession, and the raw material moves. A passageway or a classification line 232 that may be passed through. Since the classification line 232 according to the embodiment is a spaced space between two classification members 231 continuously arranged as described above, the classification line 232 is an arrangement direction of the upper screen 210 and the guide part 260. That is, it is formed extending in the x-axis direction, the plurality of classification lines 232 are arranged in the y-axis direction, and are spaced apart from each other. The shape in which the plurality of classification members 231 are arranged or the shape in which the plurality of classification lines 232 are separated by the classification member may be a track shape.

The classification line 232 according to the embodiment extends in the extending direction of the upper screen 210 as described above, the length of the upper screen 210 in the extending direction (x-axis direction), the upper screen ( The shape may be longer than a length in the direction (y axis direction) crossing the extension direction of the 210, for example, a rectangular shape. Thus, the classification member is also formed to extend in the extending direction of the upper screen 210, the length (D1) in the extending direction (x axis direction) of the upper screen 210, and the extending direction of the upper screen 210 The shape is longer than the length D2 in the crossing direction (y axis direction).

In this way, the length of the classification line 232 in the extension direction (x axis direction) of the upper screen 210 is longer than the length in the direction (y axis direction) that intersects the extension direction of the upper screen 210. When formed, the amount of raw material that can be selected by the classification line 232 is increased as compared with the case where the length of the x-axis direction and the y-axis direction is the same.

Of course, the shape of the classification line 232 is formed to extend in the extending direction of the upper screen as in the above-described embodiment, or the length of the upper screen 210 in the extending direction (x-axis direction), the upper screen 210 It is not limited to the shape which is long compared with the length in the direction (y-axis direction) which intersects the extension direction of the, and the classification line 232 is any shape, extension direction, and arrangement direction as long as it can pass a raw material according to particle diameter. It may be changed.

In addition, the classification member 231 also extends in the extending direction of the upper screen 210, or the length of the upper screen 210 in the extending direction (x-axis direction) is equal to the extending direction of the upper screen 210. Any shape, extension direction, and arrangement direction are not limited to the shape that is long compared to the length in the intersecting direction (y axis direction) and can be divided into the classification line 232 through which raw materials can pass depending on the particle diameter. This may be changed.

The classification line 232 according to the embodiment has a length in the extending direction (x axis direction) of the upper screen 210 in the direction (y axis direction) intersecting with the extending direction of the upper screen 210. It is formed longer than that. And the shape of each of the upper opening and the lower opening is a substantially rectangular shape. In addition, the area of the classification line 232 is larger than or equal to the area of the upper opening 212, and the area of the upper opening 212 is larger than the area of the lower opening 222.

At this time, in the embodiment, the extension length of at least the y axis direction of the classification line 232 is greater than or equal to the length of the x axis direction, which is the long side direction of the upper opening 212, so that the area of the classification line 232 is upper. It is larger than or equal to the area of the opening 212. In addition, the length of the upper opening 212 in the x-axis direction is larger than the length of the lower opening 222 in the y-axis direction so that the area of the upper opening 212 is larger than the area of the lower opening 222. do.

The separation interval of the classification line 232 according to the embodiment is greater than or equal to the length of the upper opening 212 in the x-axis direction. However, the present invention is not limited thereto, and the separation distance of the classification line 232 may be smaller than the length of at least one of the x axis direction and the y axis of the upper opening 212. Even in this case, the raw material having a particle size smaller than the width W1 of the classification line 232 and smaller than the width W2 of the upper opening 212 is provided by the classification line 232. Since falling in the direction, it is possible to reduce the amount of raw material to move to the upper screen 210 compared to the prior art.

By providing a classification unit 230 between the chute 100 and the upper screen 210 in this way, the raw material discharged from the chute 100 is first classified through the classification unit 230, and then the upper screen 210 or Move to lower screen 220. That is, all of the raw material discharged from the chute 100 is not directly moved to the upper screen 210, but is primarily classified by the classifying unit 230, and some of the raw material is partially transferred to the upper screen 210, and the other is the lower screen 220. Is moved to). Accordingly, all of the raw materials discharged from the chute 100 may be blocked or prevented from moving to the upper screen 210 as in the prior art without the classification unit 230. That is, the amount of raw material moving to the upper screen 210 is reduced compared to the conventional. For this reason, the amount of raw materials loaded on the upper screen 210 in the vertical direction decreases as compared with the related art. Accordingly, the raw material having a small particle size is stacked or stacked on the raw material having a large particle size, so that the raw material having a small particle size does not pass through the upper opening and remains on the upper screen 210, compared with the conventional art. Therefore, there is an effect that the classification efficiency in the upper screen 210 is improved compared to the conventional.

On the other hand, of the raw materials moved to the classification unit 230, some of the raw materials smaller than the width (W1) of the classification line 232 is loaded on the raw material larger than the width (W1) of the classification line 232, the classification line Raw material smaller than the width W1 of 232 may not fall downward through the classification line 232. However, at least some of the raw materials that are smaller than the width W1 of the classification line fall downward through the classification line 232. Therefore, as described above, the amount of raw material to be moved to or separated from the upper screen 210 is reduced as compared with the related art.

In addition, the plurality of classification members 231 or the plurality of classification lines 232 are arranged in the direction (y axis direction) that intersects with the moving direction of the raw material or the extending direction of the upper screen 210. In this case, the plurality of classification members 231 or the plurality of classification lines 232 are arranged to have an even or uniform interval with respect to the entire width of the direction (y axis direction) intersecting with the extending direction of the upper screen. Therefore, the raw material which is discharged from the chute 100 and does not pass through the plurality of classification lines 232 and moves to the upper screen 210 is guided and moved by the plurality of classification lines 232. Thus, the raw material may move to spread evenly with respect to the y-axis direction of the upper screen 210, so that the raw material is moved to either side when moving to the upper screen 210 or when moving in the direction of the first hopper 240 on the upper screen. Problems can be suppressed or prevented. Then, as the raw material does not lie on either side of the upper screen 210 and spreads widely over the entire area of the upper screen, the raw material having a small particle size is stacked or stacked on the raw material having a large particle size so that the raw material having a small particle size has an upper opening. Not passing through, and remaining on the upper screen 210 can be reduced compared to the prior art. Therefore, there is an effect that the classification efficiency in the upper screen 210 is improved compared to the conventional.

The classification member 231 according to the embodiment includes a classification body 231a extending in one direction and an abrasion resistant liner 231b formed to surround the surface of the classification body 231a as shown in FIG. 4. . The liner 231b may prevent wear and dropping due to the movement of the raw material or the raw material falling from the chute 100.

The classification body 231a according to the embodiment extends in an extension direction of the first body member 231a-1 and the first body member 231a-1 extending in one direction, for example, in the extension direction of the upper screen 210. The width of the direction intersecting the extending direction of the first body member 231a-1 is smaller than that of the first body member 231a-1, and protrudes from an upper portion of the first body member 231a-1. It includes a second body member (231a-2) installed to be. That is, for example, according to the embodiment, it may be a 'ㅗ' shape of the Hangul vowels. The liner 231b may be formed on at least a portion of the classification body 231a, and may be formed on, for example, an upper surface of the first body member 231a-1 and a side surface of the second body member 231a-2. have.

As described above, when the classification member 231 has a 'ㅗ' shape of the Hangul vowel as described above, the raw material moved from the guide part is moved to the separation space between the two second body members 231a-2, and the classification line ( 232) It is easy to place the raw material on the upper side.

However, the shape of the classification body 231a is not limited to the 'ㅗ' shape described above, but may be a variety of shapes extending in one direction, for example, a 'ㅣ' shape of a bar or a Korean vowel.

The lower screen 220 selects raw materials having a size or particle size to be charged into the blast furnace among the raw materials dropped through the plurality of classification lines 232 of the classifying unit 230 and the upper opening 212 of the upper screen 210. The raw material remaining on the upper portion of the lower screen 220 is charged to the first hopper 240 and then moved to the blast furnace. To this end, the lower screen 220 is provided to be located between the chute 100 and the first hopper 240 under the upper screen 210, the other end facing the first hopper 240 is the main body 240 It is not closed but it is open. In the lower portion of the lower screen 220, a second hopper 250 that receives a small particle size that passes through the lower opening 222, that is, a small particle of raw material, is provided.

The lower screen 220 has a lower screen member 221 extending in one direction, each of which is formed so as to penetrate the lower screen member 221 in the vertical direction, a plurality of lower openings formed spaced apart from each other on the lower screen member 221 222. The lower opening 222 is for classifying the raw material to be charged into the blast furnace, and the size of the lower opening 222 depends on the size to be used or suitable for use as the raw material of the blast furnace. That is, since the raw material supplied to the first hopper 240 along the lower screen member 221 without passing through the lower opening 222 is used as a raw material of the blast furnace, the lower opening ( 222 may vary in size. The lower opening according to the embodiment may be, for example, a rectangle having a pair of opposing long sides and a pair of short sides, and may have a rounded corner at which the short side and the long side meet. Of course, the shape of the lower opening 222 is not limited to the above-described example and can be variously changed in various shapes, for example, oval, circular, and polygonal.

In addition, the lower openings 222 as described above are provided in plural numbers, and the lower openings 222 are preferably distributed evenly with respect to the entire area of the lower screen member 221.

The guide part 260 transfers or guides the raw material discharged from the chute 100 to the classifying unit 230 so that the raw material dropped from the classifying unit 230 can be easily or stably moved to the lower screen 220. do. The guide portion 260 is disposed below the chute 100 so as to be positioned between the classifier 230 and the lower screen 220 and the chute 100.

And, the guide portion 260 has a height extending at least from the bottom surface of the lower screen 220 to the height of the classifier 230. Guide portion 260 according to the embodiment is formed so that the height of the upper end is located above the classifier 230. The top end of the guide part 260 may be a flat surface 261 parallel to the ground. In addition, the upper surface of the classifier 230, the upper and lower screen 220 and the guide portion 260 positioned opposite, the inclined surface having a slope closer to the classifier 230 toward the lower side from the flat surface 261 (Hereinafter, the upper inclined surface 262) and an inclined surface (hereinafter, the lower inclined surface 263) having an inclination closer to the lower screen 220 toward the lower side from the upper inclined surface 262.

Here, the upper inclined surface 262 may be divided into two inclined surfaces 231a-1 and 231a-2 having different inclined surfaces, and the inclined surface relatively close to the classifier 230 is inclined relative to the inclined surface thereof. It is preferable to be formed to be low. That is, the upper inclined surface 262 is closer to the classifier 230 from the flat surface 261 toward the lower side, the first inclined surface 262a having the first inclination, the first inclined surface 262a and the classifying unit 230. And a second inclined surface 262b closer to the classifier 230 as the classifier 230 is located from the first inclined surface 262a and having a second inclination lower than that of the first inclined surface. It includes. Thus, the raw material discharged from the chute 100 is dropped to the flat surface 261 of the guide portion 260, and then moved to the classifier 230 along the first inclined surface 262a and the second inclined surface 262b. .

In addition, the raw material passing through the plurality of classification lines 232 of the classification unit 230 falls or moves in the direction of the lower screen 220, wherein at least some of the raw materials are lower inclined surfaces 263 of the guide unit 260. As it falls along it can fall stably.

Hereinafter, a raw material classification process using the raw material processing apparatus according to the embodiment will be described with reference to FIGS. 1 to 4. At this time, the raw material processing apparatus according to the embodiment is located below the iron ore bin (not shown), which is one of the raw materials charged to the blast furnace, and is an apparatus for sorting the raw material provided from the iron ore bin, that is, iron ore according to the particle size.

When the gate of the iron ore bin is opened, the iron ore raw material (hereinafter referred to as raw material) is charged into the chute, and the raw material charged into the chute 100 falls onto the guide portion 260 of the raw material processing apparatus. The raw material dropped onto the guide part 260 moves along the upper inclined surface 262 of the guide part 260 toward the classifying part 230. The raw material moved in the classifier 230 direction is along the plurality of classification lines 232 by the vibration of the classifier 230, the upper screen 210, and the lower screen 220 according to the operation of the vibrator. Direction). At this time, the raw material having a larger particle size compared to the width of the classification line 232 (the length in the y axis direction or the separation distance between the continuously arranged classification members) moves along the plurality of classification members 231 to the upper screen 210. do. The raw material moved to the upper screen 210 is gradually moved in the direction of the first hopper 240 by the vibration of the upper screen 210, wherein the raw material having a smaller particle diameter than the upper opening 212 is the upper opening 212 Falling downward through, and the raw material having a larger particle size than the upper opening 212 is moved along the upper screen 210 and charged to the first hopper 240, which is then charged to the blast furnace.

On the other hand, the raw material having a particle size smaller than the width of the classification line 232 passes through the classification line 232 and falls to the lower screen 220. That is, the raw material discharged from the chute is first classified by the classifying unit, and only the raw material remaining on the classifying unit is moved to the upper screen and classified by the upper screen 210. That is, the amount of raw material moved to the upper screen or classified by the upper screen can be reduced by the classifying unit according to the embodiment of the present invention. As a result, the raw material having a small particle size is stacked or stacked on the raw material having a large particle size, so that the raw material having a small particle size does not pass through the upper opening and remains on the upper screen, as compared with the related art. Therefore, there is an effect that the classification efficiency in the upper screen is improved compared to the conventional.

In addition, the plurality of classification members 231 or the plurality of classification lines 232 may be arranged to have an even or uniform interval with respect to the entire width of the direction (y axis direction) intersecting with the extending direction of the upper screen 210. Thus, the raw material may move to spread evenly with respect to the y-axis direction of the upper screen 210, so that when the raw material moves to the upper screen 210 or in the direction of the first hopper 240 on the upper screen 210 It is possible to suppress or prevent the problem from being pulled to one side, and to spread widely. Therefore, it is possible to reduce the size of the raw material having a small particle size on the raw material having a large particle size so that the raw material having a small particle size does not pass through the upper opening 212 and remains on the upper screen 210 as compared with the related art. Therefore, there is an effect that the classification efficiency in the upper screen 210 is improved compared to the conventional.

The raw materials dropped through the plurality of classification lines 232 of the classifying unit 230 and the upper opening 212 of the upper screen 210 gradually move toward the first hopper 240 by the vibration of the lower screen 220. In this case, the raw material having a smaller particle size than the lower opening falls down through the lower opening, and the raw material having a larger particle size than the lower opening 222 is moved along the lower screen 220 and then the first hopper 240. It is then charged to the blast furnace.

Thus, according to the raw material processing apparatus having a classification unit 230 according to the embodiment of the present invention, the amount of raw material to be classified in the upper screen 210 can be reduced, and the raw material is wider with respect to the entire area of the upper screen 210. It can spread. Therefore, the classification efficiency by the upper screen 210 can be reduced as compared with the prior art, and thus the raw material having a small particle size which is not suitable for use as a raw material of the blast furnace can be charged as compared to the conventional. For this reason, the problem that the air permeability of the raw material in a blast furnace is reduced can be prevented.

100: suit 200: classification
210: upper screen 220: lower screen
230: classification unit 260: guide unit
231: classification member 232: classification line
261: flat surface 262: upper inclined surface
262a: first inclined surface 262b: second inclined surface
263: lower slope

Claims (12)

An upper screen having a plurality of upper openings spaced apart from each other, extending in one direction, and capable of sorting raw materials according to particle diameters;
A classification unit having a plurality of classification lines capable of classifying the raw materials according to the particle diameter and positioned outside the upper screen to guide the movement of the raw materials to the upper screen;
A lower screen having a plurality of lower openings formed to be spaced apart from each other and positioned below the upper screen and the classifying unit and capable of sorting the raw materials dropped from the upper screen and the classifying unit according to particle diameters;
A chute positioned above the classifying unit and discharging raw materials to the classifying unit;
In the lower side of the chute, located between the classifier and the lower screen and the chute, the guide portion for guiding the raw material discharged from the chute to the classification unit, and guides the raw material dropped from the classification line in the direction of the lower screen ;
Including,
The upper surface facing the classifier and the lower screen of the guide portion includes a lower inclined surface inclined so as to be closer to the lower screen toward the lower side. The method according to claim 1,
The classification line is a shape of an empty space extending in the extending direction of the upper screen,
The plurality of classification lines are formed raw material processing apparatus spaced apart from each other in a direction crossing the extending direction of the upper screen. delete The method according to claim 2,
The classification unit,
Each of which extends in a direction in which the top screen and the chute are arranged, and includes a plurality of classification members arranged in a direction crossing the extension direction of the top screen and spaced apart from each other,
The classification line is a space processing space between the classification members arranged in a row. The method according to claim 4,
The area of the upper opening is larger than the area of the lower opening,
The area of the classification line is larger than the area of the lower opening,
The area of the classification line is the same or larger than the area of the upper opening. The method according to claim 4,
The area of the upper opening is larger than the area of the lower opening,
The area of the classification line is larger than the area of the lower opening,
The area of the classification line is smaller than the area of the upper opening. The method according to claim 4,
The classification member,
A classification body extending in one direction; And
A liner formed to surround at least a portion of the surface of the classification body and comprising a wear resistant material;
Raw material processing apparatus comprising a. The method according to claim 7,
And the liner is formed on the upper surface of the classification body. The method according to claim 7,
The classification body may include a first body member extending in an extending direction of the upper screen; And
A second extension extending in the extending direction of the first body member and having a width in a direction crossing the extending direction of the first body member smaller than that of the first body member and protruding from an upper portion of the first body member; Body member;
Raw material processing apparatus comprising a. delete The method according to claim 1,
Of the guide portion, the upper surface facing the classifier and the lower screen,
Located on the upper side of the lower inclined surface, the raw material processing apparatus comprising an upper inclined surface inclined closer to the classification portion toward the lower side. The method according to claim 11,
The upper inclined surface includes a first inclined surface disposed on an upper side and a second inclined surface located below the first inclined surface, and a raw material processing apparatus having a lower inclination of the second inclined surface compared to that of the first inclined surface. .

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