KR101121103B1 - Heat riser material automatic input device - Google Patents

Abstract

The present invention eliminates the obstacles of the complicated input operation in the short molten steel processing process and the conveyance of the overhead crane molten steel ladle in a short molten steel processing process in the automatic input of the heat insulating material to the molten steel surface at the same time to unify the dualized work process, By evenly insulating the heat rising material, it shortens the processing time of molten steel, prevents excessive dust leakage and contamination generated when the heat insulating material is added, and smoothes the work flow of related work derived from the post-processing process of molten steel. There is an advantage to improve the quality and improve the productivity of the operation.

Molten steel, ladle, heat insulation, insulation, heating material, automation device, screw, dust collection, dust.

Description

Heat riser material automatic input device}

1 is a perspective view showing a conventional heating material input method.

2 is a cross-sectional view showing a standby state of the automatic heating material input device according to the present invention.

3 is a cross-sectional view showing a heating material input and dust collecting state of the automatic heating material input device according to the present invention.

<Description of the symbols for the main parts of the drawings>

50: motor 60: heating material

70: hopper 100: screw feed section

120: hollow tube 130: screw Peter

140: outlet 200: input pipe transfer unit

210: winding-up part 212: wire rope

300: support portion 400: dust collector

402: dust collection valve 450: dust collection hood

452: first vent hole 500: multi-stage input pipe

510: first input pipe 512: second vent hole

520: second input tube 530: third input tube                 

600: ladle 602: molten steel

The present invention relates to an apparatus that improves dust generation and process time delay generated when a heating material is added to keep warm of molten steel.

In general, the molten steel refining process and the secondary steel refining process in the secondary refining process are performed in such a way that the molten steel is appropriate to be cast into the molten steel ladle as required by the type of steel. Will be implemented.

1 is a perspective view showing a conventional heating material input method.

When the temperature of molten steel drops due to equipment failure and production delay during molten steel processing, the heating material is injected into the upper part of the ladle in which molten steel is contained so as not to cause trouble in the subsequent process.

The heating material is a compound that is added to the molten steel and reacted with oxygen to be slag to be removed in the form floating on the molten steel, a large amount of dust is generated by the combination with oxygen during this reaction. In addition, if aluminum (Al) is not completely removed from the molten steel, it has a property of emitting strong light to the molten steel surface.

Such work is usually performed by a worker directly throwing the heating material into the molten steel in the ladle, and the molten steel inside the ladle may scatter, causing a safety accident. There is a problem that it is difficult to evenly input the temperature rising material in the molten steel surface, and also due to the nature of the temperature rising material when a large amount of dust is generated in the molten steel, there is a problem due to the pollution of the working environment.

In addition, even when the heating material is injected into the molten steel by the overhead crane, a large amount of dust is generated and strong light cannot be prevented, so it is difficult to secure the field of view of the ceiling crane driver.

As a result, the temperature of the molten steel is lowered, which may adversely affect the quality of the molten steel as well as causing delays in post-process work, causing environmental pollution, and adversely affecting the health of workers.

The present invention has been made to solve the above-mentioned problems, an object of the present invention is to provide an automatic heating device for heating the heating material to process a large amount of dust generated during the heating material input operation.

In addition, another object of the present invention is to provide a heating material automatic dosing device that can shorten the processing time delay of the molten steel according to the heating material input.

In addition, another object of the present invention is to provide a heating material automatic dosing device capable of evenly introducing the heating material on the surface of the molten steel.

In addition, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

Automatic heating device for heating the heating material according to the present invention for achieving the above object, in the automatic heating device for heating the heating material to automatically input the heating material in the ladle, the hopper is stored, and one end of the hopper and A screw conveying unit including a hollow tube coupled to communicate with each other, a screw peter coupled to the inside of the hollow tube and rotated by a motor so that the heating material is transferred along the hollow tube, and coupled to communicate with the other end of the hollow tube; The discharge port for transporting the heating material downward, and the cover-shaped dust collector is coupled to the lower portion of the upper surface is in communication with the lower end of the discharge port, the lower portion is open to a size enough to cover the upper opening of the ladle, the heating material is transported downward The air inside the dust collection hood communicates with the hood and the first vent hole formed through a portion of the dust collection hood. It includes what consists of a dust collector provided to flow out.

In addition, the upper surface of the dust collection hood includes two or more tubular members are inserted into the insert so that the sliding movement can be expanded downward or contracted upwardly includes a multi-stage injection tube is coupled.

In addition, the multi-stage inlet pipe includes a second vent hole through which a part of the side surface of the position corresponding to the first vent hole extends when extending downward.                     

In addition, a wire rope having one end connected to the lowermost tube member of the multistage input pipe through the upper surface of the dust collecting hood, and mounted on the upper surface of the dust collecting hood, and wound on the other end of the wire rope by driving of a motor. It includes an input pipe transfer unit including a winding.

In addition, the multi-stage injection pipe is a tube-shaped first injection tube fixedly coupled to the upper end of the dust collection hood, the second injection tube is inserted into the insertion insert so as to slide along the outer circumferential surface or the inner circumferential surface of the first input pipe, And a third input pipe which is inserted into the insertion tube to be slidably moved along the outer circumferential surface or the inner circumferential surface of the second input pipe.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the automatic heating material input device according to the present invention.

2 is a cross-sectional view showing a standby state of the automatic heating material input device according to the present invention, Figure 3 is a cross-sectional view showing a heating material input and dust collecting state of the automatic heating material input device according to the present invention.

Automatic heating device according to the present invention is a device for automatically inserting the temperature rising material 60 for maintaining the temperature in the molten steel (602) to be loaded into the ladle 600, the hopper for storing the temperature rising material 60 ( 70) and one end of the horizontal hollow tube 120 is coupled to communicate with the lower end of the hopper 70 and the coaxially coupled to the inside of the hollow tube 120 and rotated by a motor 50 is the heating material ( Screw transfer unit 100 including a screw peter 130 to be transported along the hollow tube 120 and the other end of the hollow tube 120 is coupled to communicate with the heating material 60 in the direction of gravity Tubular drop port 140 to be transferred to, the upper surface portion is coupled to communicate with the lower end of the drop port 140, the lower portion is open to the extent that covers the upper opening of the ladle 600 is the temperature rise Cover dust collecting hood 450 to which the ash 60 is conveyed downward, and after the dust collection In communication with the first ventilation holes 452 formed part of the unit 450 is through is configured to include a dust collecting part (400) such as a pump that is adapted to leak the air inside the dust collecting hood 450 to the outside.

Two or more tubular members are inserted into the upper end surface of the dust collecting hood 450 to prevent external scattering of the molten metal when the temperature rising member 60 is introduced and suck in generated dust so as to be slidable and extend downward. Or the multi-stage inlet tube 500 which is contracted upwardly is combined to allow the heating material 60 to be concentrated or dispersed into the center of the molten steel 602 surface. In addition, the multi-stage input pipe 500 includes a second vent hole 512 formed through a portion of the side surface corresponding to the first vent hole 452 when extended downward into the multi-stage input pipe 500. Double treatment of floating dust.

The multi-stage inlet pipe 500 is a wire rope 212 connected through the top surface of the dust collecting hood 450, and the end of the wire rope 212 is the lowest tube member of the multi-stage inlet pipe 500 It is combined with the expansion and contraction by the injection pipe conveying unit 200 including a winding portion 210 which is provided to move up or down by driving the motor 50.

In this case, in order to further solidify the coupling between the feed pipe transfer unit 200 and the dust collecting hood 450 by using a fastening means such as a bolt nut, a support unit 300 may be further provided.

In addition, the multi-stage injection pipe 500 is slidably moved along the outer circumferential surface or the inner circumferential surface of the first injection pipe 510 and the tubular shape fixedly coupled to the upper end of the dust collecting hood 450. The second inlet tube 520 is coupled to the insertion type, and the third inlet tube 530 is coupled to the insertion type so as to slide along the outer circumferential surface or the inner circumferential surface of the second input tube 520 is configured.

Referring to the operation of the automatic heating material input device according to the present invention configured as described above are as follows.

As shown in Figure 2, when the multi-stage injection pipe 500 in the dust collection hood at the opening position of the molten steel ladle 600 is in the upper standby state, the dust collecting valve 402 of the dust collecting unit 400 is closed The state becomes the heat retention state. In addition, as shown in FIG. 3, when a valve installed in the dust collecting part 400 is opened to inject the temperature raising material 60 into the temperature drop of the molten steel 602 of the ladle 600, the motor 50 for driving the wires. Is driven so that the second input pipe 520 and the third input pipe 530 are lowered, the vent of the first input pipe 510 is opened, and the motor 50 installed on the upper part of the support is driven. As a result of the rotation of the screw peter 130, the temperature raising material 60 is transferred to the molten steel 602 to input the temperature rising material 60.

At this time, a large amount of dust is collected when the heating material 60 is injected, the dust is primarily sucked into the dust collecting part 400 through the second vent hole 512 of the first input pipe 510, and dropped on the molten surface. By-products are raised by the reaction of the temperature riser 60 is collected and guided to the first vent hole 452 in the dust collection hood 450 again.                     

As mentioned above, although this invention was demonstrated in detail through the preferable Example, the scope of the present invention is not limited to a specific Example, Comprising: It should be interpreted by the attached Claim. In addition, those skilled in the art should understand that many modifications and variations are possible without departing from the scope of the present invention.

The present invention eliminates the obstacles of the complicated input operation in the short molten steel processing process and the conveyance of the overhead crane molten steel ladle in a short molten steel processing process in the automatic input of the heat insulating material to the molten steel surface at the same time to unify the dualized work process, By evenly inserting the heat insulating material, it shortens the processing time of molten steel, prevents excessive dust leakage and contamination generated when the heat insulating material is added, and smoothes the work flow of the related work derived from the post-processing process of molten steel. There is an advantage to improve the quality and improve the productivity of the operation.

Claims (5)

In the heating material automatic dosing device that automatically inputs the heating material in the ladle, A hopper for storing the heating material; A screw feeder including a hollow tube having one end coupled to communicate with a lower end of the hopper, and a screw peter coupled to the inside of the hollow tube and rotated by a motor so that the heating material is transferred along the hollow tube; A discharge port coupled to communicate with the other end of the hollow tube to transfer the heating material downward; A cover-shaped dust collecting hood coupled to communicate with a lower end of the upper surface and communicating with the lower end of the discharge port, the lower part being opened to a size that covers the upper opening of the ladle, and the heating material being transported downward; A dust collecting part communicating with a first vent hole through which a part of the dust collecting hood is formed to flow out the air inside the dust collecting hood to the outside; and A multi-stage inlet pipe coupled to the upper surface of the dust collecting hood and including a second vent hole through which a part of a side surface of the position corresponding to the first vent hole penetrates is formed; Heating material automatic input device containing. The method according to claim 1, The multi-stage inlet tube is inserted into the two or more tube members in such a way that the sliding movement is extended automatically downward input device is heated upwardly or contracted upwardly. The method according to claim 2, The multi-stage injection pipe is a heating material automatic injection device that the second vent hole is opened when extended downward. The method according to claim 2 , A wire rope having one end connected to the lowermost tube member of the multi-stage inlet pipe through the top surface of the dust collecting hood, and a winding part mounted on an upper surface of the dust collecting hood and winding the other end of the wire rope by driving of a motor. Automatic heating device temperature increase material including an input pipe conveying portion. The method according to any one of claims 1 to 4, The multi-stage injection tube and the first injection tube of the tubular shape fixedly coupled to the upper end of the dust collection hood; A second input pipe inserted into the insert tube to slide along the outer circumferential surface or the inner circumferential surface of the first input pipe; Automatic heating apparatus for heating the heating material comprising a third inlet pipe coupled to the insertion coupled to slide along the outer circumferential surface or the inner circumferential surface of the second inlet pipe.

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