KR101495425B1 - Slag movement route alterable slagrunner - Google Patents

Abstract

A main slag bath for the slag to move is formed by branching from the bathtub on which the slag and the charcoal line are moved from the blast furnace and a slag bath for branching in both directions from the main slag bath and a slag bath for forming a slag bath A drive shaft formed at a position where the boiler slag tank and the water slag boiler diverge, a drive means for rotating the drive shaft, and a boiler for simultaneously opening the boiler slag boiler and the boiler slag boiler in unison with the drive shaft, And a damper provided on the damper so as to block any one of the cooling line, a cooling line provided in the damper, a heat exchanger for cooling the cooling water having passed through the cooling line, And a connection pipe connected at one end to the heat exchanger and connected at the other end to the heat exchanger; A slag bath that can change the slag moving path including the sensing sensor to detect.

Description

SLAG MOVEMENT ROUTE ALTERABLE SLAGRUNNER "

The present invention relates to a slag flow diagram in which a slag discharged from an exit port of a blast furnace moves, and more particularly, to a slag flow diagram capable of selectively changing a slag flow path in a slag flow diagram having a bidirectional flow path will be.

Generally, slag is a by-product which is essential for iron making process, such as high base molten slag, blast furnace slag, electric furnace slag, stainless steel slag, and waste molten slag.

Among them, blast furnace slag occurs in the process of obtaining iron ore from raw iron ore. Blast furnace slag is remained after iron ore, coke, limestone, etc. are put into blast furnace and burned coke to heat and reduce iron ore to obtain pig iron.

FIG. 1 is a schematic side cross-sectional view showing a flow process of slag and molten iron discharged from a discharge port of a general blast furnace, and FIG. 2 is a perspective view showing that a slag process is generally performed.

The molten metal 5 is discharged from the outlet 4 of the blast furnace 3 and the discharged molten metal 5 is moved along the molten metal 10 as shown in Fig. At this time, the skimmer 8 provided at the upper part of the hot water tank 10 serves to separate the molten metal 5 into the slag 6 and the molten iron 7. That is, the slag 6 having a low specific gravity due to the difference in specific gravity is positioned on the upper side of the hot water 10, and the hot water 7 having a specific gravity is located at the lower side of the hot water 10, The molten iron 7 located at the lower portion of the molten iron bath 30 travels along the molten iron bath 30 to carry out a next process such as smelting and is transferred to a post-process by a ladle car which is a moving means.

The slag 6 located in the upper part of the hot water tank 10 is moved along the granular slag bath 22 or the water slag bath 23 according to the use and is then transferred to the post-processing by the ladle car.

On the other hand, as shown in FIG. 2, in the main slag bath 21 in the recovery operation of the slag 6 through the slag bath 20, the main slag bath 22 and the water slag bath 23 When the slag (20) having a bi-directional structure is branched, the slag (23) must be closed so that the slag (6) is transferred only to the slag (22) When the slag 6 to be treated is conveyed, it is necessary to close the bulk material slag road 22 so that the slag 6 can flow only through the wood slag casting 23.

However, since there is no suitable means for controlling the flow of the slag 6 in the lump slag 22 or in the lumber slag 23, the sand boll 11 is stacked to close the lump slag 22 The sand blast furnace 23 is closed by stacking the sand blast furnace 11 so that only the slag melt blast furnace 23 can flow the slag 6 into the slag melt blast furnace 22, 6).

For example, in order to move the slag 6 to be treated with water to the water-based slag bath 23, the operator climbs the upper cover 9 of the bulk material slag bath 22 with an appropriate amount of sand in the sand, It is necessary to perform a cutting operation in which the sand bank 11 is stacked with the slag 22 to prevent the slag 6 to be wasted from moving to the blanket slag bath 22.

In order to perform such a cutting operation, it is necessary to close the exit in advance, and after a certain period of time, the worker must collect the sand bank 11 or remove the accumulated sand bank 11, There is a problem that the worker is exposed to the radiant heat generated in the tundish 20 and the hot molten slag 6.

In order to solve such a problem, Patent Document 1 provides a molten slag distributing device capable of easily distributing and supplying the molten slag taken out from the blast furnace to a predetermined slag bath to be produced.

As a result, the molten slag can be freely distributed within a short period of time and can be conveniently distributed to the slag bath for molten slag or water, and the molten iron mixed into the slag can be effectively recycled.

However, in Patent Document 1, there is a limit in the amount of slag that can be transferred to the water slag bath in an abnormal operation situation in which the amount of discharged molten slag temporarily increases or at the same time, the slag is withdrawn, so that the capacity of the slag water bath The slag is overflowed. In addition, when a problem occurs during the movement of the molten slag to be treated with water to the water slag bath, the molten slag to be subjected to the wastewater treatment should be moved in an emergency so as to open the molten slag bath, There is a problem in that the molten slag can not be moved by simultaneously opening the coal slag and the water slag bath.

Patent Publication No. 2002-0049897

The present invention provides a slag bath diagram capable of selectively changing a slag moving path in a slag bath having a bidirectional moving path.

A slag bath diagram capable of changing the slag moving path according to an embodiment of the present invention is formed in such a manner that a main slag bath is formed in which slag and charcoal which are leaving the blast furnace are branched at a high- A driving shaft formed at a position where a boiler slag bath and a water wood slag bath are diverged, a driving shaft formed at a position where a boiler slag bath and a water slag bath are branched, driving means for rotating the driving shaft, An opening / closing unit including a damper provided to simultaneously open the coal slag bath and the water slag bath, or to selectively block any one of them, a cooling line provided inside the damper, And a heat exchanger having one end connected to the cooling line and the other end connected to the cooling line, A cooling unit including a connection pipe connected to the heat exchanger, and a sensing sensor for sensing the position of the damper.

The damper has a shape corresponding to a cross-sectional shape of the carbonaceous material slag bath and the water glass slag bath.

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The damper and the drive shaft are made of a cast material.

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According to the embodiment of the present invention, it is possible to prevent the phenomenon that the slag is overflowed by changing the movement path of the slag fluidly in an abnormal operating situation such as an increase in the amount of slag due to simultaneous outgoing, There is an effect of improving the operation rate.

In addition, it is possible to omit the cutting work for accumulating sand, thereby preventing the worker from being exposed to radiant heat due to the hot molten slag.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic side cross-sectional view showing a flow process of slag and molten iron discharged from a discharge port of a conventional blast furnace; FIG.
FIG. 2 is a perspective view showing that a curd operation is generally performed on a slag bath. FIG.
3 is a perspective view showing a slag bath diagram capable of changing a slag moving path according to an embodiment of the present invention.
4 is a plan view showing an operating state of the opening and closing unit 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.

FIG. 3 is a perspective view showing a slag bath diagram capable of changing a slag moving path according to an embodiment of the present invention, and FIG. 4 is a plan view showing an operating state of the opening and closing unit according to an embodiment of the present invention.

As shown in the drawing, a slag flow path 20 capable of changing a slag moving path according to an embodiment of the present invention includes a slag 6 and a molten metal 7 And the main slag bath 21 is branched so that the main slag bath 21 is branched in both directions and the main slag bath 23 and the water slag bath 23 are branched in both directions, A slag bath 20 in which the slag 20 is formed; An opening / closing unit (100) including a damper (110) provided to selectively block the coal slag bath (22) or the water slag bath (23); And a cooling unit 150 for cooling the damper 110.

The opening and closing unit 100 includes a driving shaft 120 integrally formed with the damper 110 and provided at a position where the bulk material slag bath 22 and the water slag bath 23 are branched. And the driving means 130 for rotating the driving shaft 120 so that the damper 110 selectively blocks the coal slag bath 22 and the water slag bath 23.

The damper 110 has a shape corresponding to the cross-sectional shape of the coal slag bath 22 and the water slag bath 23. The damper 110 is fixed to a side surface of the drive shaft 120 and moves along the direction when the drive shaft 120 rotates clockwise or counterclockwise.

The damper 110 and the driving shaft 120 are formed integrally with each other and each have a hollow portion. The damper 110 and the driving shaft 120 are in contact with each other.

The damper 110 and the drive shaft 120 are made of a cast material so as to prevent thermal deformation or damage due to direct contact with the hot molten slag 6.

Preferably, the driving unit 130 may be any type of driving unit as long as it can drive the driving shaft 120 clockwise and counterclockwise. For example, in the present embodiment, the driving means 130 uses a motor.

And a sensing sensor 140 for sensing the position of the damper 110.

The sensing sensor 140 senses that the damper 110 is positioned at a position where only one of the coal slag bath 22 and the water slag bath 23 is opened or both are opened.

The type of the sensing sensor 140 may be an operation sensing sensor and may be configured to sense the operation of the damper 110 when the damper 110 is positioned at a predetermined position to stop the damper 110. A cover for protecting the detection sensor 140 may be installed on the outer periphery of the detection sensor 140 so that the detection sensor 140 can be protected from the hot molten slag 6.

The cooling unit 150 includes a cooling line 151 provided inside the damper 110 to move cooling water for cooling the damper 110; A heat exchanger (153) provided separately from the damper (110) and cooling the cooling water passing through the cooling line (151); And a connection pipe 152 having one end connected to the cooling line 151 and the other end connected to the heat exchanger 153 to move the cooling water.

The cooling line inlet 151a is provided on an upper surface of the cooling line 151 where the damper 110 and the drive shaft 120 are in contact with each other and the damper 110 is connected to the drive shaft 120 And a cooling line outlet 151b is provided at a lower portion thereof.

One end of the supply connection pipe 152a is connected to the cooling line inlet 151a inside the drive shaft 120 and the other end is connected to the heat exchanger 153. [

One end of the discharge connection pipe 152b is connected to the cooling line outlet 151b inside the driving shaft 120 and the other end is connected to the heat exchanger 153. [

The heat exchanger (153) is provided behind the position where the bulk material slag bath (22) and the water material slag bath (23) diverge. And has a circulation structure for supplying cooling water to the supply connection pipe 152a and cooling the cooling water having passed through the cooling connection pipe 152b to supply the cooling water to the supply connection pipe 152a. In addition, it is preferable that the cooling water is supplied from the outside and the cooling water repeatedly circulated by the heat exchanger 153 is replaced after a predetermined period.

The operating state of the slag moving path changing device according to an embodiment of the present invention will now be described.

The slag 6 and the molten iron 7 are discharged from the blast furnace 3 through the outlet 4 at predetermined time intervals and the molten iron 5 and the molten iron 7 are discharged from the blast furnace 3, So that it moves along the dancet 10. The molten iron 7 having a large specific gravity is moved by the skimmer 8 provided in the upper part of the molten metal 10 to the molten metal bath 30 while flowing along the lower part of the molten metal 10, The molten slag 6 is moved to the slagging bath 20 while flowing along the upper part of the hot-water tank 10.

The slag 6 separated from the molten iron 7 through the skimmer 8 moves through the main slag bath 21.

On the other hand, the main slag blanket 21 is branched into a blanket slag 22 and a wastewater slag 23 so that the slag 6 to be burnt in accordance with the processing method of the slag 6 And the slag 6 to be subjected to the water treatment is moved to the water slag bath 23.

The cooling water is supplied to the cooling line 151 through the cooling line inlet 151a provided in the damper 110 along the supply connection pipe 152a by the heat exchanger 153. [ The supplied cooling water moves along the cooling line 151 to cool the damper 110. Thereafter, the cooling water is moved along the discharge connection pipe 152b connected to the cooling line outlet 151b and cooled in the heat exchanger 153. [ This operation is repeatedly performed while the slag 6 is moving through the slag casting 20.

The detection sensor 140 senses the operation of the damper 110 in real time so that when the damper 110 is positioned at the position for selectively blocking the coal slag bath 22 or the water slag bath 23, The operation is set to stop.

As shown in FIG. 4, in order to move the slag 6 to the gargoyle slag grout 22, the damper 110 must be fixed at the position A to block the gargoyle slag grout 23.

The driving means 130 is operated in a clockwise direction so that the slag 6 to be moved along the main slag duct 21 is moved to the slag winch slag 22 as the slag 6 moves.

The driving shaft 120 connected to the driving means 130 is driven in a clockwise direction and the damper 110 extending from the driving shaft 120 is driven toward the water slag bath 23.

At this time, the operation of the damper 110 is detected by the detection sensor 140, and when the damper 110 reaches the position A, the drive shaft 120 stops to be driven.

That is, the damper 110 integrally connected to the drive shaft 120 is fixed at the position A during the clockwise driving. As a result, the water slag bath 23 is cut off by the damper 110, and the slag 6 to be crushed is moved along the crushed coal slag 22.

Thereafter, the slag 6 to be subjected to the garbage disposal is transferred to a weaving plant by a ladle car, adjusted to a predetermined particle size or lower by a pulverizer, and utilized or buried as a road bed material.

Conversely, in order to move the slag 6 to the water slag bath 23, the damper 110 must be fixed at the position B and the coal slag bath 22 must be shut off.

The driving means 130 is operated in the counterclockwise direction so that the slag 6 to be subjected to the wastewater treatment moves along the main slag bath 21 so that the slag 6 is moved to the wastewater slag bath 23.

The driving shaft 120 connected to the driving means 130 is driven in a counterclockwise direction and the damper 110 extended from the driving shaft 120 is driven to the side of the coal slag bath 22.

At this time, the operation of the damper 110 is detected by the detection sensor 140, and when the damper 110 reaches the position B, the driving of the driving shaft 120 is stopped.

That is, the damper 110 integrally connected to the drive shaft 120 is fixed at a position where the detection sensor 142 is sensed during driving in the counterclockwise direction. As a result, the bulk material slag bath 22 is shut off by the damper 110, and the slag 6 to be treated is moved along the water slag bath 23.

Thereafter, the slag 6 to be wastewater treated is transferred to a water treatment plant by a ladle car and rapidly cooled by cooling water to form an amorphous fine particle, which is used as a raw material for cement.

Further, when the abnormal operation condition, that is, the amount of the slag 6 temporarily increases, there is a limit in the amount of the slag 6 that can be treated in the bricklaying slag 23, The damper slag bath 22 and the water slag bath 23 should be both opened by fixing the damper to the position C in order to prevent the phenomenon that the damper slag 22 is heated.

First, the driving means 130 is operated to drive the driving shaft 120 connected to the driving means 130. The drive shaft 120 connected to the drive means 130 is driven and the damper 110 extended from the drive shaft 120 is positioned between the fly ash slag road 22 and the flyash slag road 23 The operation of the damper 110 is detected by the detection sensor 140 when the damper 110 is positioned at a position where both the coal slag bath 22 and the water slag bath 23 are opened. And the driving of the driving shaft 120 is stopped. The damper 110 integrally connected to the driving shaft 120 is fixed at a position where the third sensing sensor 143 is sensed during driving. Thus, the slag 6 flows in both directions of the bulk material slag bath 22 and the water slag bath 23. [

After that, the slag 6 to be subjected to the lumber processing is transferred to the lumber processing plant by a ladle car, adjusted to a predetermined particle size or less by a crusher, and utilized or buried as a road wheel lumber or the like, It is transferred to a water treatment plant and rapidly cooled by cooling water to form an amorphous fine particle, which is used as a raw material for cement.

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.

3: Blast Furnace 4: Outgoing Pipe
5: Melt 6: Slag
7: Charter 8: Skimmer
9: cover 10:
11: Sand bed 20: Slag bath
21: Main slag bath 22: Slag water
23: Suji slag hot water 30: Hot water hot water
100: opening / closing unit 110: damper
120: drive shaft 130: drive means
140: Detection sensor 150: Cooling unit
151: Cooling line 151a: Cooling line inlet
151b: Cooling line outlet 152: Connection piping
152a: supply connection pipe 152b: discharge connection pipe
153: heat exchanger

Claims (5)

A main slag bath for the slag to move is formed by branching from the bathtub on which the slag and the charcoal line are moved from the blast furnace and a slag bath for branching in both directions from the main slag bath and a slag bath for forming a slag bath Tang tao;
A drive shaft formed at a position where the bulk material slag tank and the water slag bath are branched, a drive means for rotating the drive shaft, and a control means for simultaneously opening the bulk material slag bath and the water slag bath together with the drive shaft, An opening / closing unit including a damper provided so as to block any one of the damper;
A cooling unit including a cooling line provided in the damper, a heat exchanger for cooling the cooling water passing through the cooling line, and a connection pipe having one end connected to the cooling line and the other end connected to the heat exchanger;
And a slag moving path capable of changing a slag moving path including a sensor for detecting the position of the damper.
The method according to claim 1,
Wherein the damper has a shape corresponding to a sectional shape of the carbonaceous material slag bath and the water glass slag bath.
The method according to claim 1,
Wherein the damper and the drive shaft are made of a cast material and the slag moving path can be changed.








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