KR101053418B1 - Melting Ladle - Google Patents

Abstract

The present invention discloses a degassing apparatus of molten iron ladle that can reduce the consumption of the spur agent and minimize environmental pollution. The molten iron ladle according to the present invention, the molten iron flow apparatus for flowing the molten iron accommodated in the molten iron ladle; A storage unit for storing a desorbent; A chute unit connected to the storage unit to form a discharge channel of the desorbent, the chute unit being stretchable; And a driving unit configured to extend the chute unit to discharge the desorbent while the discharge end of the chute unit is close to the molten iron surface.

Molten iron ladle, degasser, degreasing agent injector

Description

Discharge device of molten iron ladle {APPARATUS FOR ELEMINATING IMPURITY SUBSTANCE FROM MELTING PIG IRON OF LADLE}

The present invention relates to a degasser of molten iron ladle.

In general, in the molten iron processing process, degreasing and desulfurization are performed by supplying a degreasing agent to the molten iron of the molten iron.

In the molten iron preliminary treatment process, after the molten iron is positioned at the home position, the impeller is lowered to form a vortex on the molten iron of the molten iron. In addition, the desorbent injector supplies the desorbent stored in the hopper inside the molten iron ladle.

At this time, the desorbing agent is evenly mixed with the molten iron by the vortex of the molten iron so that the desulfurization and dephosphorization in the molten iron can be performed smoothly.

In addition, a dust collector is connected to the molten iron ladle to discharge the gas generated when melting the molten iron to the outside.

 However, since the conventional degassing apparatus is fixed on the upper part of the molten iron ladle, the lower end of the degassing apparatus is positioned away from the surface of the molten iron in order to prevent the degassing agent input device from being deformed.

Therefore, when the dust collecting capacity of the dust collecting device is increased, some of the desorbing agent injected into the molten iron ladle is collected by the dust collecting device, so that the dephosphorization efficiency and the desulfurization efficiency of the molten iron may decrease. Furthermore, as the desorbent is collected by the dust collector, the desorbent is wasted and the manufacturing cost is increased.

In addition, when the dust collecting capability of the dust collecting device is lowered, some of the desorbents injected into the molten iron ladle is blown into the atmosphere and the gas is not easily discharged, thereby causing air pollution and environmental pollution. In addition, in order to solve these problems, it was necessary to adjust the dust collecting capability of the dust collector well.

An object of the present invention for solving the above problems is to provide a dehydration device that can improve the dephosphorization efficiency and desulfurization efficiency while increasing the capability of the dust collector.

Another object of the present invention is to provide a degassing apparatus of the molten iron ladle that can reduce the waste of the degreasing agent to reduce the manufacturing cost and minimize the air pollution.

In order to achieve the above object, the deflowing device according to the present invention, a molten iron flow apparatus for flowing the molten iron accommodated in the molten iron ladle; A storage unit for storing a desorbent; A chute unit connected to the storage unit to form a discharge channel of the desorbent, the chute unit being stretchable; And a driving unit configured to extend the chute unit so that the desorbent is discharged while the discharge end of the chute unit is close to the molten iron surface. The chute unit has an air supply unit for injecting air when the desorbent is supplied into the chute unit. Coupled to the air supply unit, an air flow path tube connected to the pump, an air flow path tube connected to the pump, a valve for opening and closing the air flow path tube, and an air discharging end of the air flow path tube and disposed inside the chute part. An air nozzle unit, wherein the air nozzle unit includes a distribution header disposed at the discharge end, and a plurality of air nozzles coupled to the decomposition header.

The chute unit, the stationary chute in communication with the storage; And a mobile chute communicating with the stationary chute and reciprocally coupled to the stationary chute.

The stationary chute and the mobile chute may be combined in a double tube form.

The fixed chute is disposed outside the molten iron ladle, the movable chute is located outside the molten iron ladle when it is reduced and can be inserted into the molten iron ladle when it is extended.

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According to the present invention, there is an effect that can improve the dephosphorization efficiency and desulfurization efficiency while increasing the capacity of the dust collector.

According to the present invention, it is possible to reduce the waste of the desorbent to reduce the manufacturing cost and minimize the air pollution.

It will be described with respect to specific embodiments of the molten iron ladle according to the present invention for achieving the above object.

1 is a block diagram showing the molten iron ladle and the dewatering device according to the present invention, Figure 2 is a block diagram showing the dewatering device.

1 and 2, the deflowing apparatus 100 is disposed above the molten iron ladle 10.

The inner wall surface of the molten iron ladle 10 is made of a refractory 13 to prevent the molten iron from being melted by the molten iron. Ladle cover 11 is installed to cover the upper side of the molten iron ladle 10.

The dust collecting apparatus 20 is connected to the upper side of the molten iron ladle 10 to collect the polluted gas discharged from the molten iron ladle 10. The dust collector 20 is connected to the ladle cover 11 by the gas discharge pipe (21).

The dewatering device 100 is a device for removing sulfur and phosphorus contained in the molten iron. The dewatering device 100 includes a molten iron flow device 110 and a desorbent input device 130.

The molten iron flow apparatus 110 may include an elevating unit 111 capable of elevating up and down, and an impeller 117 coupled to a lower side of the elevating unit 111. At this time, the impeller 117 is rotated by the motor 118.

The elevating unit 111 includes an elevating frame 112 capable of elevating up and down, and guide rails 113 supporting both sides of the elevating frame 112. Rollers 115 may be disposed on both sides of the elevating frame 112 to be in contact with the guide rail 113. In addition, the lifting frame 112 may be lifted up and down by various devices such as a motor device (not shown) or a hoist.

The desorbent injector 130 may include a storage 140, a chute 150, and a driver 160.

In the storage unit 140, a desorbent is stored. The desulfurizing agent is made by mixing a desulfurizing substance and a dephosphorizing substance to remove sulfur and phosphorus contained in the molten iron. The desorbent consists of a powder of approximately 5 mm or less. Such a demulsifier may consist of approximately 92% quick lime and 8% fluorite powder.

The storage unit 140 includes an upper hopper 141 in which the desorbent is stored, and a quantitative hopper 145 in which the desorbent discharged from the upper hopper 141 is stored. The upper hopper 141 and the fixed hopper 145 are connected by a pipe 142, and the opening and closing device 143 is installed in the pipe 142 to open and close the pipe.

The chute unit 150 is connected to the lower portion of the metering hopper 145. The metering valve 146 may be disposed on the discharge side of the metering hopper 145 to open and close the discharge port. The metering valve 146 quantitatively supplies the desorbent to the molten iron ladle 10.

The chute unit 150 includes a fixed chute 151 in communication with the storage unit 140, and a mobile chute 153 in communication with the fixed chute 151. The mobile chute 153 is reciprocally coupled to the fixed chute 151. The stationary chute 151 and the mobile chute 153 may be combined in a double tube form.

The moving chute 153 may be inserted outside the fixing chute 151 or inside the fixing chute 151.

In addition, the fixing chute 151 is disposed outside the molten iron ladle 10, the mobile chute 153 is located outside the molten iron ladle 10 when the length of the chute 150 is reduced. On the other hand, when the length of the chute 150 is extended, it may be inserted into the molten iron ladle 10.

At this time, the discharging end 153a of the mobile chute 153 is tapered to be substantially parallel to the surface of the molten iron. Since the discharge end 153a of the mobile chute 153 is formed to be tapered, it can be made closer to the surface of the molten iron.

The driving unit 160 extends the chute unit 150 to discharge the desorbent while the discharge end 153a of the chute unit 150 is close to the molten iron surface.

The drive unit 160 may include a drive motor 161, a cylinder 162 connected to the drive motor 161, and a rod 163 reciprocally coupled to the cylinder 162. In this case, the load 163 is advanced or retracted by the driving motor 161 supplying and supplying air to the cylinder 162. In addition, the driving unit 160 may enable the rod 163 to be reciprocated by hydraulic pressure.

In this case, the rod 163 of the driving unit 160 may be coupled to the upper end of the mobile chute 153 by the connector 165.

The desorbent injector 130 may further include an air supply unit 170 to supply air to the chute unit 150. In this case, the air supply unit 170 may be connected to the chute unit 150 to inject air into the chute unit 150 when the desorbent is discharged into the chute unit 150.

The air supply unit 170 includes a pump 171 for flowing air, an air flow path tube 173 connected to the pump 171, a valve for opening and closing the air flow path tube 173, and the air flow path tube ( It may include an air nozzle unit 176 disposed at the discharge end of the 173. At this time, the air nozzle unit 176 is disposed inside the chute unit 150.

3 is a block diagram showing an air nozzle unit constituting the degassing apparatus.

Referring to FIG. 3, the air nozzle unit 176 may include a distribution header 177 disposed at the discharge end of the air flow path tube 173, and a plurality of air nozzles 178 coupled to the distribution header 177. It may include. At this time, the distribution header 177 has a structure that can pass through the desorbent flowing along the chute (150).

The operation of the degassing device of the molten iron ladle according to the present invention configured as described above will be described.

A scrap is put inside the molten iron ladle 10 and heated. As the inside of the molten iron ladle 10 is heated by a burner (not shown), the scrap is melted to form molten iron. If sufficient molten iron is formed in the molten iron ladle 10, the molten iron ladle 10 is mounted on a bogie (not shown) by a crane (not shown).

4 is a diagram illustrating a state in which the molten iron ladle is moved to the lower portion of the deflowing device.

Referring to FIG. 4, the molten iron ladle 10 is moved to a processing position by a bogie. Here, the treatment position is the lower portion of the molten iron flow apparatus 110.

In this case, since the lifting frame 112 is in an elevated state, the impeller 117 is disposed above the molten iron ladle 10. In addition, the mobile chute 153 is fixed to the upper side of the fixed chute 151, the mobile chute 153 is located outside the molten iron ladle 10.

5 is a configuration diagram showing a state in which the mobile chute and the impeller is lowered into the molten iron ladle.

5, the lifting frame 112 of the molten iron flow apparatus 110 is lowered. At this time, the lifting frame 112 may be lowered only to the extent that the impeller 117 is locked to the molten iron. In addition, by operating the dust collector 20, the pollutant gas generated in the molten iron ladle 10 may be collected.

In addition, air is injected into the cylinder 162 by operating the driving motor 161. The rod 163 is moved downward by the air pressure to extend the moving chute 153 downward. The moving chute 153 is inserted into the molten iron ladle 10. At this time, the discharge end 153a of the mobile chute 153 is located close to the surface of the molten iron.

Subsequently, when the impeller 117 is rotated, a vortex is formed inside the molten iron ladle 10.

 In addition, the metering valve 146 of the metering hopper 145 is opened to quantitatively discharge the desorbent of the metering hopper 145 to the chute unit 150. The pump 171 of the air supply unit 170 is operated to supply air to the chute unit 150. The air supplied to the chute unit 150 injects the desorbent supplied to the chute unit 150 to the molten iron side.

In this way, since the desorbing agent is injected onto the surface of the molten iron in a state where the discharge end 153a of the mobile chute 153 is as close as possible to the surface of the molten iron, a relatively large amount of the desorbing agent may be mixed in the molten iron. Even if the capacity of the dust collecting device 20 is increased, the amount of desorbent collected in the dust collecting device 20 may be reduced.

Therefore, the desulfurizing effect and the dephosphorization effect of the molten iron can be improved by allowing the molten iron ladle 10 to be mixed with a relatively large amount of desorbing agent. Furthermore, since a relatively small amount of desorbent is used, the manufacturing cost of the molten iron can be lowered.

In addition, since the sprayed desorbent is relatively mixed in the molten iron, less dust may be generated as the amount of the desorbent to be mixed increases. Therefore, air pollution and environmental pollution can be reduced.

When the dehydration of the molten iron accommodated in the molten iron ladle 10 is completed, the drive motor 161 extracts air from the cylinder 162. At this time, as the rod 163 is retracted, the mobile chute 153 is moved out of the molten iron ladle 10.

In addition, as the elevating frame 112 is moved upward along the guide rail 113, the impeller 117 is also moved to the outside of the molten iron ladle 10.

The present invention can improve the dephosphorization efficiency and the desulfurization efficiency while increasing the capability of the dust collector, and thus, there is a marked applicability in industry.

1 is a block diagram showing the molten iron ladle and the dewatering device according to the present invention.

FIG. 2 is a configuration diagram illustrating the deflowing apparatus of FIG. 1.

FIG. 3 is a configuration diagram illustrating an air nozzle unit constituting the degassing apparatus of FIG. 1.

4 is a configuration diagram illustrating a state in which the molten iron ladle of FIG. 1 is moved to a processing position that is a lower part of the deflowing device.

FIG. 5 is a diagram illustrating a state in which the mobile chute and the impeller of FIG. 1 are lowered into the molten iron ladles.

Explanation of symbols on the main parts of the drawings

10: molten iron ladle 20: dust collector

100: deflow apparatus 110: molten iron flow apparatus

111: lifting unit 117: impeller

130: deodorant input device 140: storage unit

150: chute part 151: upper chute

153: moving chute 160: drive unit

162: cylinder 163: rod

170: air supply part 176: air nozzle part

Claims (5)

A molten iron flow device for flowing the molten iron accommodated in the molten iron ladle; A storage unit for storing a desorbent; A chute unit connected to the storage unit to form a discharge channel of the desorbent, the chute unit being stretchable; And And a driving unit configured to extend the chute unit to discharge the desorbent while the discharge end of the chute unit is close to the molten iron surface. The chute unit is coupled to an air supply unit for injecting air when the desorbent is supplied into the chute unit, The air supply unit includes a pump for flowing air, an air flow path tube connected to the pump, a valve for opening and closing the air flow path tube, and an air nozzle unit disposed at the discharge end of the air flow path tube and disposed inside the chute part. Including, The air nozzle unit of the molten iron ladle, characterized in that it comprises a distribution header disposed in the discharge end and a plurality of air nozzles coupled to the decomposition header. The method of claim 1, The chute part: A stationary chute communicating with the reservoir; And And a chute for communicating with the fixed chute and including a mobile chute coupled reciprocally to the fixed chute. The method of claim 2, The fixing chute and the chute chute deflow apparatus, characterized in that coupled to the double pipe form. The method of claim 2, The fixed chute is disposed outside the molten iron ladle, The moving chute is located outside the molten iron ladle when it is reduced and when the elongation of the molten iron ladle, characterized in that inserted into the molten iron ladle. delete

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