KR101634733B1 - Powder supply apparatus - Google Patents

Abstract

The present invention relates to a powder material supply device for spraying a powder material on an object to be treated accommodated in a container, the powder material supply device comprising a plurality of openings for covering the open upper part of the container and formed by a pushing force of the powder material A cover including a dispersing portion formed so as to be rotatable and a rotating portion including a rotating shaft extending in the up and down direction and connected to the dispersing portion so as to suppress or prevent biased feed of the powder material put on the object to be processed have.
That is, a multi-stage structure of dispersing units is disposed on the open top of the molten steel accommodated in the ladle and carried to the continuous casting facility, and the dispersing member is rotated by the insulator supplied to the dispersing unit, And can be evenly sprayed.
Accordingly, it is possible to easily spread the insulating material on the molten steel bath surface, thereby suppressing and preventing the temperature drop of the molten steel due to the spraying time of the molten steel thermal insulating material and preventing the oxidation caused by the reaction with the outside air during transportation of molten steel. And the quality of the molten steel can be improved.
Further, it is possible to suppress and prevent the uneven supply of the insulating material to the bath surface, so that it is possible to cover the bath surface in a smaller amount than in the prior art, thereby reducing the consumption cost of the process.

Description

[0001] Powder supply apparatus [

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a powder feeder, and more particularly, to a powder feeder capable of suppressing or preventing feed of a powder to be fed onto a material to be processed.

Generally, the molten steel produced by the continuous casting process is supplied to the continuous casting facility after the primary refining from the converter is completed, the subsequent refining process is completed, and the refining process is completed.

At this time, lowering of temperature and oxidation of molten steel in the process of transporting molten steel to the continuous casting facility cause problems of solidification of molten steel in continuous casting equipment and lowering of quality of molten steel.

That is, when the temperature of the molten steel is lowered during the transportation of the molten steel due to the increase in the external exposure of the molten steel through the opened upper portion of the ladle in which the molten steel is received, the molten steel is solidified in the equipment such as the nozzle of the continuous casting equipment, Fused to cause maintenance of the equipment. In addition, when the oxidation of molten steel occurs due to the reaction between molten steel and external air during transportation of molten steel, the amount of dissolved oxygen in the molten steel is increased to lower the quality of molten steel.

Conventionally, in order to prevent external exposure of molten steel carried by the ladle and to prevent or prevent temperature drop, a method of attaching a heat insulating cover to the open top of the ladle and inserting the heat insulating material through the heat insulating cover into the molten steel bath surface .

However, due to the characteristics of the molten steel bath surface already cured in the conventional inserting process, the heat insulating material is not evenly sprayed on the molten steel, but is injected into a part of the molten steel bath.

As a result, the molten steel temperature is lowered and oxidized and the quality of the molten steel is lowered on the molten steel surface of the molten steel not covered with the insulating material, and the disposal of the slag after completion of the continuous casting operation is not easy due to the sintering of the slag. In addition, since a large amount of a heat insulating material is required to cover the entire surface of the molten steel with the heat insulating material, there arises a problem that the cost of the process according to the amount of the heat insulating material is increased.

KR 1997-0027534 U KR 2002-0076729 A KR 2014-0084558 A

The present invention provides a powder material feeding device capable of uniformly dispersing a thermal insulating material on a hot melt surface of a molten metal to reduce the input amount of the thermal insulating material.

The present invention provides a powder material feeding device capable of suppressing and preventing temperature decrease and oxidation occurrence of a metal melt.

The present invention provides a powder material feeder capable of reducing the cost of a continuous casting process and increasing the quality of the final casting produced through a continuous casting facility.

A powder material supply device for spraying a powder material on an object to be treated accommodated in a container according to an embodiment of the present invention covers an open upper portion of the container and is provided with a plurality of openings to form a multi- A cover including a dispersing portion formed so as to be rotatable by a force, and a rotating portion extending in the up-and-down direction and including a rotating shaft whose side is connected to the dispersing portion.

The dispersing unit may include a dispersing member having a powder material feed hole formed therein and a plurality of guide members that allow the powder material to collide with the dispersing member to enable rotation of the dispersing member.

Wherein the cover includes a cover body which is supported at an upper end of the container to form a space between the upper end of the container and the inlet and is formed at a central portion thereof in a vertical direction, And the guide member may extend from the central portion to the outer periphery.

And a powder material supply unit connected to an upper portion of the cover to supply the powder material to the dispersion unit, wherein the powder material supply unit includes a powder material supply pipe communicating with the injection port to form a supply path of the powder material, And a powder reservoir for supplying the powder material to the supply pipe.

The dispersing members of each of the plurality of dispersing units are spaced apart from each other in a vertical direction and are formed to have different average diameters, and the multi-stage structure may be formed such that the average diameter decreases toward the container.

The dispersing member may be arranged to be inclined downward from the central portion toward the outer periphery.

The guide member may be formed of a plate protruding from the other surface opposite to the one surface, and one end of the center portion and the other end of the outermost surface may be connected to each other at a side of a curve on a plane.

The guide member may be inclined from the top to the bottom on the other surface.

A plurality of through holes passing through the dispersing member in a vertical direction may be formed at a position of the dispersing member that does not overlap the position where the guide member is formed.

The rotation unit may include a support member having one end connected to the side surface of the rotation shaft and the other end connected to the dispersion member, and an upper end of the rotation shaft and the cover body mutually connected to rotate the rotation shaft while being supported by the cover body And may include a rotation fixing member.

The driving unit may include a first gear provided at an upper end of the rotating shaft, a second gear rotatably disposed along a circumferential surface of the first gear, A driving shaft connected to the second gear and extending in a direction intersecting the extending direction of the rotating shaft, and a power unit connected to the driving shaft.

The object to be treated contained in the vessel is a molten steel accommodated in a ladle carried to a continuous casting facility after refining, and the powder material may be a thermal insulator sprayed on the molten steel bath surface.

According to the powder material supply apparatus according to the embodiment of the present invention, it is possible to suppress and prevent the uneven supply of the powder material to be sprayed on the object to be contained in the container, thereby increasing the easiness of the object to be processed.

That is, the primary and secondary refining are completed, the ladle is accommodated and the ladle is conveyed to the continuous casting facility, and the ladle is placed on the open upper part of the molten steel, and the ladle- It turns on power. Accordingly, the heat insulating material can be sprayed by passing through the dispersing member having a multi-stage structure having diameters different from each other, and can be uniformly supplied on the molten steel bath surface.

As described above, since it is possible to easily spread the insulating material on the molten steel bath surface, it is possible to suppress and prevent the temperature drop of the molten steel according to the spreading time of the molten steel thermal insulation material, Can be solved.

Further, it is possible to suppress and prevent the occurrence of oxidation due to the reaction with the outside air during transportation of the molten steel, thereby solving the problem of deterioration of the quality of the molten steel due to the oxidation reaction.

Since it is not conventionally required to cover the bath surface by applying a large amount of the insulating material to the molten steel bath surface by the biased feed of the insulating material, the molten steel bath surface can be covered with a small amount of insulating material compared to the conventional insulating material input amount, It is possible to solve the problem of the increase in cost due to the increase in cost.

1 is a perspective view showing a state in which a powder material supply apparatus according to an embodiment of the present invention is mounted on a ladle.
FIG. 2 is an exploded perspective view showing the powder feeder of FIG. 1. FIG.
Fig. 3 is an enlarged view showing a state of engagement between the dispersion unit and the rotation unit of Fig. 2;
4 is a view for explaining a dispersion unit according to an embodiment of the present invention.
5 is a view for explaining an installation position of the dispersion unit of FIG.
FIG. 6 is a view for explaining a state of inserting a thermal insulating material using a powder feeder according to an embodiment of the present invention. FIG.
7 is a perspective view for explaining a through hole formed in the dispersing member of the present invention.
8 is a perspective view for explaining a driving unit provided in the rotating part of the present invention.
9 is a flowchart for explaining a method of inserting a thermal insulating material using a powder feeder according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

The powder feeder according to the embodiment of the present invention is an apparatus for uniformly spraying powder onto a material to be processed contained in a container and includes a device capable of uniformly spraying a powder material on an entire surface of a top surface to provide. In this case, the present invention can be used to supply a thermal insulating material sprayed on the molten steel bath surface in order to suppress and prevent the exposure of molten steel to the outside during transportation of the molten steel stored in the ladle to be fed to the continuous casting facility through the refining facility. However, the powder re-supply device is not limited to the application of the present invention, and can be applied to and used for uniformly distributing the powder material in the region.

Hereinafter, a powder feeder according to an embodiment of the present invention will be described with reference to FIGS. 1 to 9. FIG. 1 is a perspective view showing a state in which a powder feeder according to an embodiment of the present invention is mounted on a ladle. FIG. 2 is an exploded perspective view showing the powder feeder of FIG. 1. FIG. FIG. 3 (a) is an enlarged perspective view showing a state of engagement between the dispersing portion and the rotating portion, and FIG. 3 (b) is a cross-sectional view showing another coupling state of the dispersing portion and the rotating portion. 4 is a perspective view and a plan view of a dispersion unit according to an embodiment of the present invention. Fig. 5 (a) is a cross-sectional view showing a position where a dispersion unit is installed in the powder material supply device mounted on the ladle, and Fig. 5 (b) is a plan view for explaining the installation position between the ladle and the dispersion member. 6 (a) and 6 (b) are a perspective view and a cross-sectional view for explaining the rotation of the dispersing portion by the powder feed, and FIG. 6 (c) is a cross-sectional view showing a state in which the insulator on the molten steel in the ladle is sprayed. 7 is a perspective view for explaining a through hole formed in the dispersing members of the present invention. 8 is a perspective view for explaining a drive unit included in the rotating part of the present invention. 9 is a flowchart for explaining a method of inserting a thermal insulating material using a powder feeder according to an embodiment of the present invention.

The powder re-supplying device 1000 is a device for uniformly supplying the insulating material P to the entire area of the molten steel M surface of the molten steel accommodated in the ladle 50 and covers the open top of the ladle 50, A cover 100 including a dispersing part 130 formed to be rotatable by a pushing force of the dispersing part 130 and formed in a multi-stage structure, And a rotating part 200 including a rotating shaft 210 which is rotatable. The powder feeder 1000 may include a powder feeder 300 connected to the cover 100 to feed the insulator P to the dispersing unit 130.

The ladle 50 provides a space for accommodating molten steel M for molten steel M spouted from a converter (not shown) to be transferred to a continuous casting facility (not shown), and is composed of a bottom portion and a side portion Shows the shape of the opened container. At this time, the ladle 50 has a cylindrical structure having an open upper portion and a hollow interior, and shows a circular shape on a plane, but the shape of the ladle 50 is not limited thereto. Therefore, the shape of the cover 100 to be described later can be changed according to the shape of the ladle 50.

The cover 100 covers the upper portion of the ladle 50 and is configured to disperse and supply the insulated material P to the inside of the ladle 50. The cover 100 includes a cover body 110 supported at the upper end of the ladle 50, And a dispersing portion 130 disposed between the cover body 110 and the ladle 50.

The cover body 110 is in contact with the upper end of the ladle 50 to form a space S between the upper end of the ladle 50 and an area . The cover body 110 may have an inlet 120 formed at a central portion thereof so as to be vertically penetrated so that the insulating material P can be supplied to the spacing space S. [ The cover body 110 may form a spacing space S so that the dispersion unit 130 may be spaced apart from the ladle 50. The cover body 110 may be formed as an outer perimeter, The upper portion of the center of the ladle 50 may be inclined upward toward the central portion.

The injection port 120 is formed to penetrate the central portion of the cover body 110 and may be connected to a powder material supply unit 300 for supplying a thermal insulation material P. [ The center of the cover body 110 refers to a predetermined region from the center of the plane of the cover body 110 to the outward side. More specifically, the inlet 120 is formed in a plane of the cover body 110, And may have a size with an average diameter of 10 to 15, assuming that the average diameter of the cover body 110 is 100. The reason why the injection port 120 is formed at the center of the cover body 110 is that the thermal insulation material P must be supplied to the center of the separation space S through the injection port 120, The injection port 120 can be formed at the center portion of the cover body 110 because it can be dispersed and sprayed.

The powder re-supply unit 300 is configured to supply the insulator P to the dispersing unit 130 through the injection port 120. The powder re-supply unit 300 is connected to the injection port 120 at the upper part of the cover body 110, And a powder material reservoir 330 for supplying a thermal insulator P to the powder material supply pipe 310. [

The powder re-supply pipe 310 provides a path through which the insulator P can move from the powder reservoir 330 in which the insulator P is stored on the outside of the cover body 110, Screws can be used to be transported.

The powder reservoir 330 provides a space for storing and storing the thermal insulation material P and may serve to supply the thermal insulation material P by a predetermined amount to the powder material supply pipe 310. That is, the powder re-reservoir 330 is installed in the powder reservoir 330 so that the amount of the heat insulation material P supplied to the powder re- Can be controlled.

When the insulator P is to be supplied to the molten steel M, the powder feeder 300 may be connected to the inlet 120 to supply the insulator P to the molten steel M. When the insulator P is inserted into the molten steel M, Can be separated from the injection port 120 after the completion of the operation. That is, the powder feeder 300 is provided to be connectable to and detachable from the cover body 110, so that the movement of the ladle 50 can be performed more easily. When the powder re-supply part 300 is separated from the injection port 120, the injection port 120 is provided with a separate stopper (not shown) to close the open area of the injection port 120, It is possible to suppress and prevent external exposure of the molten steel (M).

A plurality of dispersing units 130 are disposed in the cover body 110 so as to be spaced apart from each other to disperse and spread the heat insulating material P on the hot melt surface of the molten steel M, A dispersing member 132 disposed in a spacing space S formed between the body 110 and the ladle 50 and formed with a powder material feed hole 134 penetrating in a vertical direction at a central portion thereof; And a guide member 136 formed thereon. Hereinafter, the dispersion unit 130 according to the embodiment of the present invention is divided into a first dispersion unit 130a and a second dispersion unit 130b, and the first dispersion unit 130a and the second dispersion unit 130b The number of the dispersing units 130 is not limited to two and the size of the plane of the ladle 50 and the number of the dispersing members 130 But may be provided in a larger number depending on the variable.

The dispersing member 132 is formed of a plate having a surface facing the upper surface (molten metal surface) of the molten steel M and is disposed in the spacing space S to form a multi- do. That is, the dispersing member 132 includes a first dispersing member 132a provided in the first dispersing unit 130a and a second dispersing member 132b provided in the second dispersing unit 130b. And is rotatable in the spacing space S by a pressing force of a heat insulating material P supplied through the heat insulating material P. At this time, the dispersing member 132 can rotate clockwise and counterclockwise on a plane, and the direction of rotation of the dispersing member 132 can be changed according to the shape of the guide member 136 described later.

The dispersing member 132 is formed to have a planar size that covers a part of the upper surface of the molten steel M or the ladle 50 in a plan view and more specifically the first dispersing member 132a and the second dispersing member 132b Are arranged so as to have different average diameters from each other and are spaced apart from each other in the vertical direction in the spacing space S while covering some of the upper surfaces of the ladle 50 or the molten steel M to overlap each other, , Downward direction), so that a multi-step structure can be formed. When the average diameter of the ladle 50 in the plane is assumed to be 100, the dispersing member (i.e., the first dispersing member) disposed close to the inner upper surface of the cover body 110 among the dispersing members 132 forming the multi- , And an average diameter of 50 to 65. [ That is, the first dispersing member 132a may be provided to cover an area ranging from 50 to 65 from the center on the plane of the upper surface of the ladle 50 or the molten steel M. [ The first dispersing member 132a is provided so as to cover an area in the range of 50 to 65 from the center on the upper surface of the molten steel M so that the second dispersing member 132b has an average diameter of the ladle 50 of 100 May be formed to have a diameter range smaller than the average diameter of 50 to 65 and may be formed to have an average diameter of 20 to 30, which is a range which is 1/2 smaller than the range of the first dispersion member 132a have. The reason that the dispersing members 132 are formed with the average diameter size is that the insulator P supplied by the dispersing member 132 is dispersed and spread by the rotation of the dispersing members 132, 132 can increase the area in which the insulating material P can be sprayed. This will be described below again.

In addition, the dispersing member 132 may be arranged to be inclined downward from the central portion to the outer periphery on the cross section. That is, the dispersing member 132 may be arranged to be inclined downward from the center with respect to the width R _L of the ladle 50 toward the outer wall of the ladle 50. The dispersing member 132 is formed to be inclined downward so that the insulator P supplied to the dispersing member 132 is easily supplied onto the molten steel M along the inclination formed by the dispersing member 132 . The inclination angle formed by the dispersing member 132 in the downward direction is not particularly limited as long as the inclination angle of the dispersing member 132 is 15 to 30 degrees with respect to the extension line at the upper end of the dispersing member 132 Can be made to form an angle. At this time, when the inclination of the dispersing member 132 is made to exceed 30 degrees, the insulator P supplied to the dispersing member 132 is rapidly supplied onto the bath surface by riding the dispersing member 132, If the inclination of the dispersing member 132 is formed to be less than 15 degrees, the insulating member P dropped close to the center of the dispersing member 132 even if the dispersing member 132 rotates It is not easy to send to the outer side of the dispersing member 132 and the insulating member P may be stuck to the dispersing member 132 so that the dispersing member 132 can be made to form an angle within the above range.

The powder supply hole 134 is formed to penetrate the dispersing member 132 to flow down the heat insulating material P supplied to the spacing space S from the central portion of the dispersing member 132, The injection port 120 may be formed at a position corresponding to the injection port 120 of the dispersing member 132. The powder supply hole 134 is provided corresponding to each of the plurality of dispersion members 132. The powder supply hole 134 is formed in the first powder feed hole 134a of the first dispersion member 132a and the second powder feed hole 134a of the second dispersion member 132b, And a powder feed hole 134b. The first powder feed hole 134a may be formed to feed the heat insulating material P supplied to the first dispersing member 132a to the second dispersing member 132b, 134b may be formed to supply the insulator P supplied to the second dispersing member 132b onto the bath surface.

At this time, the average diameter of the second powder feed hole 134b may be smaller than the average diameter of the first powder feed hole 134a, and more specifically, The average diameter may be a half of the average diameter of the first powder feed hole 134a because the second dispersing member 132b, in which the second powder feed hole 134b is formed, May be formed with an average diameter smaller than that of the first dispersion member 132a in which the re-supply holes 134a are formed. In order to supply a large amount of the heat insulating material P from the first powder feed hole 134a to the second dispersing member 132b, the first powder feed hole 134b needs to be larger than the second powder feed hole 134b, 134a may be formed to have a larger size. Herein, the average diameter of the lower end of the powder feed hole 134 may be such that the rotation axis 210 of the rotation unit 200, which will be described later, can be inserted and removed. More specifically, The powder feed hole 134 may be formed such that a separation distance may exist between the members 132.

Although only the correlation between the first powder feed hole 134a and the second powder feed hole 134b is described above, two or more dispersing portions 130 may be provided, and two or more dispersing members 132 may be provided. The powder material supply holes 134 formed at the uppermost portion of the plurality of powder material supply holes 134 are formed to have the largest average diameter and are formed so as to be smaller toward the bottom as in the relationship with the dispersing member 132 May be formed to have an average diameter.

The guide member 136 is provided on the dispersing member 132 to generate a pushing force of the insulating material P to the dispersing member 132 and is provided with a guide member 136, And extend from the center of the plane on the other surface of the dispersing member 132 opposite to the one surface to the outer periphery, and may be disposed on the dispersing member 132 at a plurality of spaced apart from each other. The guide member 136 may be formed of a plate protrudingly mounted on the dispersing member 132, and the other end of the one end and the outer end of the center portion may be connected to the side of the curve. The guide member 136 may be formed of a plate having a predetermined length and the length of the guide member 136 may be changed according to the average diameter of the dispersing member 132. That is, the first guide member 136a provided in the first dispersing member 132a may be formed to have a long length with respect to the second guide member 136b provided in the second dispersing member 132b.

The height h _{g of the} guide member 136 projecting on the dispersing member 132 may be formed to be 2 to 2.5 times larger than the thickness of the dispersing member 132. That is, when the thickness of the dispersing member 132 is h, the height h _g of the guide member 136 may have a value of 2h to 2.5h. As such, the guide member 136, the projecting height of the distribution member 132. The insulation material (P), the guide member 136 is supplied to the distribution member 132 is formed so as to have an increased height (h _g) than the thickness of the ( h _g in the vicinity of the guide member 136 on the dispersing member 132 so as to apply a pushing force in the protruding direction of the curve formed by the guide member 136. [ At this time, when the protrusion height h _g of the guide member 136 protrudes to a height lower than 2h, the heat insulating material P does not sufficiently provide the force for rotating the dispersing member 132 to the guide member 136 When the protrusion height h _g of the guide member 136 protrudes to a height higher than 2.5 h, the heat insulating material P does not pass through the guide member 136 The protruding height h _g of the guide member 136 may be selected within the range so that the problem of stagnation may occur in the region near the guide member 136 on the dispersing member 132 have.

In addition, the guide member 136 may be inclined from the top to the bottom on the other surface of the dispersing member 132. That is, the guide member 136 is formed to be inclined from the upper surface to the lower surface, so that the angle? 1 of the side surface of the guide member 136 with respect to the extension extending upward from the vertex of the lower surface of the guide member 136 It can be arranged to be inclined. The side surface of the guide member 136 is inclined at an angle of? 1 so that the insulating member P of the dispersing member 132 is supplied on the inclined side surface to push the dispersing member 132 easily have. In this case, the inclination angle? 1 of the side surface of the guide member 136 may have a value of 40 to 45 degrees. If the angle? 1 has a value smaller than 40, the guide member 136 may be provided with a heat insulating material P And a value greater than 45 causes a phenomenon that the heat insulating material P passes over the guide member 136 before applying a force to push the heat insulating material P to the guide member 136 And the rotation of the dispersing member 132 may not be easy.

The guide member 136 guides the end point D _{2 -1} of one guide member 136-1 of the plurality of guide members 136 with respect to the center point D1 of the dispersing member on the dispersing member 132, _{Between the} connected line Y _g1 and the line Y _g2 connected to the end point D _{2 -2} of the other guide member 136-2 spaced from the one guide member 136-1, Lt; RTI ID = 0.0 > angle. ≪ / RTI > As described above, the guide members 136 are spaced apart from each other with an angle of? 2, so that the insulating members P apply a pushing force to the plurality of guide members 136 spaced apart from each other, thereby making it easier to rotate the dispersing member 132. On the other hand, the value of the spacing angle? 2 between the plurality of guide members 136 is not limited, but? 2 can be set on the dispersing member 132 with a value of 50 to 60 degrees.

The plurality of dispersing units 130 are vertically spaced apart from each other in the spacing space S and the dispersing members 132 constituting each of the plurality of dispersing units 130 are formed to have different average diameters So that the dispersion part 130 can be formed in a multistage structure. 5, the dispersing unit 130 may have a mean diameter Rc1 of the first dispersing unit 130a and an average diameter Rc1 of the second dispersing unit 130b, And is disposed at a position higher than the extension line L1 of the upper end of the ladle 50 to cover a partial area of the upper portion of the ladle 50. [ 5 (b), the first dispersing member 132a is arranged such that the outermost portion is disposed at a position spaced a1 distance from the extension line A0 extending from the inner wall of the ladle 50 in a planar manner, And the second dispersing member 132b is disposed such that the outermost portion of the second dispersing member 132b is disposed at a position spaced apart by a distance a2 from the extension line A1 extending from the outermost periphery of the first dispersing member 132a. The first dispersing member 132a that rotates by the supply of the insulator P can rotate and spread the insulator P in the area of a1 and the second dispersing member can insulate the insulator P in the area of a2, Can be rotated and sprayed. The heat insulating material rotatably spread from the first powder feed hole 134a and the second powder feed hole 134b is extended from the extension line A2 extending from the outermost portion of the second dispersing member 132b to the The thermal insulating material P can be applied to the area extending from the central point to the extension line A3 and the thermal insulating material P can be applied to the hot melt surface of the molten steel M by the multi- It can supply equally.

7, the through hole 138 penetrating the dispersing member 132 in the up-and-down direction is provided at the position where the guide member 136 is not overlapped with the position where the guide member 136 is formed Or may be formed in plurality.

The through hole 138 is formed through the dispersing member 132 at a position spaced apart from the guide member 136 and the powder material feed hole 134. The through hole 138 is formed in the first through hole 138a formed in the second dispersion member 132b and a second through hole 138b formed in the second dispersion member 132b. Such a through hole 138 can serve to discharge the insulated material P supplied on the dispersing member 132 to the lower portion so that the spraying region of the insulator P of the dispersing member 132 can be seen . That is, the first through hole 138a formed in the first dispersing member 132a can easily supply the heat insulating material P on the second dispersing member 132b together with the first powder supplying hole 134a It is possible to supply the insulating material P to the second dispersing member 132b in a shorter time than the case where the insulating material P is supplied to the second dispersing member 132b only through the first powder feed hole 134a, So that the dispersing member 132b can be rotated faster. As the dispersing member 132 is rotated, the insulating member P can be sprinkled in the increased area with respect to the region where the insulating material P is sprayed, so that the dispersing member 132 can be prevented from being provided in an increased number .

The through hole 138 may have a different average diameter depending on the number of the dispersing members 132 and may be formed in the dispersing member 132. The diameter of the first through hole 138a formed in the first dispersing member 132a The average diameter E2 of the second through hole 138b formed in the second dispersing member 132b is formed to be smaller than the average diameter E1 of the insulating member P through the second through hole 138b, It is possible to suppress or prevent the excessive supply of the liquid to the liquid.

The rotating part 200 is provided for fixing the dispersing part 130 to the cover body 110 and includes a rotating shaft 210 extending in the vertical direction and one end connected to the side surface of the rotating shaft 210, And a rotation fixing member 250 for connecting the upper end of the rotation shaft 210 and the cover body 110 so as to rotate the rotation shaft 210 while being supported by the cover body 110 230).

The rotating shaft 210 is formed by extending a predetermined length in the vertical direction, and the upper region is connected to the cover body 110 with respect to the length in the vertical direction, and the dispersing unit 130 is connected to the lower region from the center.

The rotation fixing member 230 is provided for interconnecting the upper surface of the rotation shaft 210 and the cover body 110 and includes a plurality of rotation supporting members 230 extending from the upper side circumferential surface of the rotation axis 210 to the inner side wall of the injection port 120 One end connected to the injection port 120 is fixedly installed and the other end connected to the rotation axis 210 is rotatably connected.

The support member 250 connects the dispersing member 132 and the rotating shaft 210 so that the dispersing member 132 can be disposed apart from the upper portion of the ladle 50 and the molten steel M, A first support member 250a which is formed in the same shape as the rotation fixing member 230 and connects the first dispersion member 132a and the rotation shaft 210 as shown in Figure 3 (a) And a second support member 250b connecting the rotation shaft 210 and the second shaft 132b. 3 (b), the support member 250c may be formed in the form of a bar extending from the dispersing member 132 to the rotating shaft 210. [ Unlike the rotation fixing member 230, the supporting member 250 is rotatably mounted on the rotating shaft 210 such that the dispersing member 132 is rotated (rotated) Both ends may be fixedly coupled so as not to be provided. On the other hand, when the support member 250c is provided only in the shape of a bar as shown in FIG. 3 (b), the insulator P supplied from the injection port 120 is discharged downward through the powder material supply hole 134 The insulating member P can be discharged to the lower portion of the dispersing member 132 through the powder feed hole 134 more easily by increasing the path. Therefore, the support members 250a, 250b and 250c can be selected and used according to the size of the powder feed hole 134 and the size of the dispersing member 132 to be fixed to the rotation axis 210, And the dispersing member 132 can be fixedly coupled to each other.

8, the rotation unit 200 may further include a drive unit 270 for providing a rotational force to the rotation axis 210. In addition, as shown in FIG. The driving unit 270 includes a first gear 271 provided at the upper end of the rotary shaft 210 and a second gear 273 and a second gear 273 rotatably disposed along the circumferential surface of the first gear 271, And a power unit 277 connected to the driving shaft 275 and connected to the driving shaft 275 and extending in a direction intersecting the extending direction of the rotating shaft 210. [

Since the drive unit 270 is provided in the rotation shaft 210, the rotation of the dispersing member 132 can be more easily performed by rotating the dispersing member 132 than by rotating the dispersing member 132 by the force of the insulator P pushing the guide member 136 . That is, when the drive shaft 275 rotates by the operation of the power section 277, the second gear 273 connected to the drive shaft 275 rotates, and the first gear 271 The rotation shaft 210 can be finally rotated.

At least a part of the drive unit 270 may be disposed in the injection port 120 when the rotation unit 200 is provided with the drive unit 270. In this case, So that the configuration of the drive unit 270 can be arranged. The first gear 271 and the second gear 273 constituting the drive unit 270 are provided with a thermal insulating material P by providing a box surrounding a part of the structure of the drive unit 270 disposed in the injection port 120. [ It is possible to suppress or prevent the occurrence of a problem in the operation of the drive unit 270. [

Hereinafter, with reference to FIG. 9, a description will be given of a method of supplying a thermal insulating material P through a powder material supplying apparatus 1000 according to an embodiment of the present invention.

First, the powder feeder 1000 is placed on the open top of the ladle 50 in the process of receiving molten steel M from the converter and refining the ladle 50 in the ladle 50 and conveying it to the continuous casting facility (S10).

The heat insulating material P stored in the powder reservoir 330 is introduced into the spacing space S from the powder material supply pipe 310 and the injection port 120 at step S20.

The heat insulating material P that has been introduced into the spacing space S through the inlet 120 drops onto the first dispersing unit 130a and flows down along the inclination of the first dispersing member 132a, At this time, the heat insulating material P continuously supplied to the first dispersing member 132a pushes the first dispersing member 132a toward the rotating shaft 132 while pushing the first guide member 136a, The first dispersing member 132a rotates in a state in which it is supported by the first dispersing member 210 so that the insulator P is rotated by the rotation of the ladle 50 (S40) by a rotational force.

A part of the insulated insulating material P is supplied onto the second dispersing member 132b through the first powder feed hole 134a and the insulator P supplied to the second dispersing member 132b is supplied The second dispersing member 132b is rotated in a state of being supported by the rotating shaft 210 while the second dispersing member 132b is pushed while the second dispersing member 132b pushes the second dispersing member 132b, Is sprayed and dispersed by a rotational force to a position close to the sidewall of the ladle (50) than the liquid surface of the immediately lower portion of the outermost portion of the ladle (132b).

The remaining part of the insulating material P to be charged is spread and sprayed on the bath surface immediately below the second powder feed hole 134b through the second powder feed hole 134b so that the molten steel stored in the ladle 50 The heat insulating material P can be uniformly distributed over the entire surface area of the bath surface of the molten metal M.

Although the present invention has been described with reference to the accompanying drawings and the preferred embodiments described above, the present invention is not limited thereto but is limited by the following claims. Accordingly, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the spirit of the following claims.

M: molten steel P: insulation
1000: powder feeder 50: ladle
100: Cover 110: Cover body
120: inlet 130: dispersing part
132: dispersing member 134: powder feed hole
136: guide member 138: through hole
200: rotating part 210: rotating shaft
230: rotation fixing member 250: supporting member
270: drive unit 300: powder feeder
310: Powder feed line 330: Powder reservoir

Claims (12)

1. A powder material supply apparatus for spraying powder on a material to be treated contained in a container,
A cover including a plurality of dispersing parts covering the open upper part of the container and spaced apart from each other in a vertical direction so as to be rotatable by a pushing force of the powder material;
And a rotation part extending in the up-and-down direction and having a side surface connected to the dispersion part,
Wherein the dispersing unit comprises:
A dispersion member having a powder feed hole formed therein;
And a plurality of guide members extending from a central portion of the dispersing member to an outer side of the dispersing member and inclined from a top surface to a bottom surface to allow the powder material to collide to enable rotation of the dispersing member, Device. delete The method according to claim 1,
The cover
And a cover body supported on the upper end of the container to form a spacing space between the upper end of the container and the upper end of the cover body,
Wherein the powder material supply hole is vertically formed at a central portion of the dispersing member, and the guide member extends from the central portion to the outer periphery. The method of claim 3,
And a powder material supply unit connected to an upper portion of the cover to supply the powder material to the dispersion unit,
Wherein the powder material supply unit comprises:
A powder material supply pipe communicating with the injection port to form a supply path of the powder material; and a powder material reservoir for supplying the powder material to the powder material supply pipe. The method according to claim 1,
Wherein the dispersion members of each of the plurality of dispersion parts are each formed to have different average diameters,
Wherein the multi-stage structure is formed such that the average diameter decreases toward the container side. The method according to any one of claims 1, 3, 4, and 5,
Wherein the dispersing member is disposed so as to be inclined downward from a central portion of the dispersing member to an outer periphery thereof. The method of claim 6,
The guide member
Wherein one end of the central part of the dispersing member and the other end of the outermost part of the dispersing member are connected to a side surface of a curved line on a plane in plan view. delete The method of claim 6,
And a plurality of through holes penetrating the dispersing member in a vertical direction are formed at a position of the dispersing member which is not overlapped with a position where the guide member is formed. The method of claim 3,
The rotation unit includes:
A supporting member having one end connected to a side surface of the rotating shaft and the other end connected to the dispersing member; And
And a rotation fixing member for interconnecting an upper end of the rotation shaft and the cover body to allow the rotation shaft to rotate while being supported by the cover body. The method according to claim 1,
The rotation unit is provided with a drive unit for providing a rotational force to the rotation shaft,
The driving unit includes:
A first gear provided at an upper end of the rotary shaft;
A second gear rotatably disposed along a circumferential surface of the first gear;
A driving shaft connected to the second gear and extending in a direction intersecting the extending direction of the rotating shaft; And
And a power unit connected to the drive shaft. The method according to claim 1,
The object to be treated contained in the vessel is a molten steel accommodated in a ladle carried to a continuous casting facility after refining,
Wherein the powder material is a heat insulating material sprayed on the molten steel bath surface.

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