KR20050015298A - Apparatus for watching and removing molten ore in sintering ignition furnace - Google Patents

Abstract

PURPOSE: To provide an apparatus for real-time monitoring formation of fused ore adhered to the ceiling and the furnace body of a sintering ignition furnace and removing the fused ore when a large amount of fused ore is stuck to the furnace wall so as to improve product quality and prevent collapse of refractories inside the ignition furnace. CONSTITUTION: An apparatus for monitoring and removing fused ore in sintering ignition furnace(6) comprises a radiation control part comprising a frame(208) at one side of which an air supply pipe(207) is installed, and which is fixed to the furnace wall of the ignition furnace, and a fixed pipe(108) which is installed with being spaced from the air supply pipe in a certain distance, and one end part of which is connected to a monitor through a controller; a fused ore monitoring part comprising an illumination means comprising an infrared light source(102), a light reflection plate for guiding direction of light of the infrared light source, and a lighting(202) installed under the light reflection plate, an observation means for observing the flow state of raw coal in the ignition furnace that is irradiated by the illumination means, and a contamination preventing means comprising a partition plate(107) and a nozzle(106) installed on the partition plate to prevent contamination of the illumination means and the observation means; and a fused ore control part for removing the fused ore through a brush as a rotary shaft and a connection shaft are being rotated according to operation of a driving motor(402) when the fused ore is produced and adhered to the furnace body of the ignition furnace.

Description

Apparatus for watching and removing molten ore in sintering ignition furnace

The present invention relates to an apparatus for monitoring and removing fused light inside a sintering ignition furnace. In particular, in the sintering operation process, the fusion light is scattered into the ignition furnace while being ignited by the charging of the raw materials. The present invention relates to an apparatus for monitoring and removing fused light inside a sintering ignition furnace.

Figure 1 is a schematic diagram showing the sintering manufacturing process, Figure 2 is a conventional sintering ignition formation of the fusion ore in the furnace wall, the sintered ore is generally used in the main charging material of the blast furnace is iron ore, limestone, serpentine and other raw materials and It is manufactured through the process of sintering a blended raw material mixed with coke, which is a fuel source, and semi-glossy in a sintering machine. Specifically, the sintered ore charges the blended raw material from the raw material storage tank 1 into the sintering machine trolley 7, ignites the sintered layer by the burner 11 in the ignition furnace 6 located at the upper side, It is manufactured through a sintering process in which air is sucked by a blower (not shown) to agglomerate particles in the sintered layer.

In order to sinter the charged raw material as shown in FIG. 1, the ignition furnace 6 has to be ignited 10 at the surface of the charged raw material and burned from the upper layer to the lower layer. Thus, the ignition of the raw material surface 10 is ignition. .

In this case, as the heat source used in the ignition furnace 6, COG generated during the coke manufacturing process is used, and the temperature of the ignition furnace 6 is controlled at 1,150 to 1,200 ° C., and the ignition furnace is uniformly ignited throughout the surface layer part 10. The temperature control in the furnace should be good.

In the ignition furnace (6) during the ignition process, the air is burned in the burner 11 at a pressure of 570 ~ 580mm H ₂ O, the gas 880 ~ 890mm H ₂ O, at this time, the blending raw material of the upper part of the sintering machine bogie 7 Fusion light is attached to the ceiling of both the exit side of the ignition furnace and both side walls of the ignition furnace, and when the fused light scattered by the air discharge of the burner 11 is attached to the inner wall of the ignition furnace 6 as shown in FIG. There was a problem that occurred.

The present invention has been made in order to solve the above problems of the prior art, in real time to monitor the formation of fusion ore, the raw coal scattered in accordance with the ignition of the charging raw material attached to the ceiling of the ignition furnace and the side furnace wall, The purpose of the present invention is to provide a sintering ignition furnace monitoring and removal device inside the sintering ignition furnace that can improve the product quality and prevent the internal refractory collapse accident by removing the large amount of fused light on the furnace wall.

In the sintering ignition furnace monitoring and removal apparatus according to the present invention for realizing the above problem is fused sintered in the ignition furnace in accordance with the ignition of the charging material during the sintering process is attached to both the inner wall of the ignition furnace An apparatus for monitoring and removing the gas, comprising: a frame having an air supply pipe on one side and fixed to a furnace wall of the ignition furnace, and a fixed pipe installed at a predetermined distance from the air supply pipe, and having one end connected to the monitor through a controller. A radiation controller configured to; Observation of the flow of raw coal in the ignition furnace irradiated by the illumination means through an illumination means including an infrared light source, a light reflection plate for guiding the light direction of the infrared light source, and an illumination lamp installed under the light reflection plate, and a lens and a surveillance camera. A fusion light monitoring unit including an observation means, a separator and a nozzle installed on the separator and configured to prevent contamination of the lighting means and the observation means; A fusion light control unit configured to remove the fusion light through a wire brush while rotating and connecting shafts rotate according to an operation of a driving motor when the fusion light is generated and attached; Characterized in that configured to include.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is an overall configuration diagram of an apparatus for monitoring and removing fused light in the sintering ignition furnace according to an embodiment of the present invention, and FIG. 4 is fusion in the apparatus for monitoring and removing fused light in the sintering ignition furnace shown in FIG. 3. 5 is a configuration diagram of a light removal device, and FIG. 5 is a view illustrating a configuration of a fusion light monitoring device in a fusion light monitoring and removal device inside the sintering ignition furnace shown in FIG. 3 and a state of use thereof. Light monitoring and removal device is largely a radiation control unit; A fusion light monitoring unit including an illumination unit, observation means for observing a flow of raw coal in the ignition furnace irradiated by the illumination means, and pollution prevention means for preventing contamination of the illumination means and the observation means; And a fusion light control unit for removing fusion light generated on the furnace wall of the ignition furnace.

3 and 5, the table-shaped frame 208 is fixedly installed on both left and right sides of the sintering ignition furnace 6, and air 109 is introduced into one side of the frame. An air supply pipe 207 is formed, and a fixed pipe 108 is installed through the frame 208 at a predetermined interval from the air supply pipe.

The lower portion of the fixed tube 108 is installed with a radiation sample 205 in the lower portion of the surveillance camera to be described later, the lower portion of the radiation sample is installed with a radiation sensor 206, the upper portion of the fixed tube 108 is the controller 201 Is connected to the monitor 110.

As shown in FIGS. 3 and 5, the fusion light monitoring unit is fixed to the separator 107 having a central opening across the frame 208, and has a nozzle 106 at the center of the separator 107. When the air is injected through the nozzle, the vortex phenomenon is generated in the infrared light source 102, and the lens 104, the surveillance camera 105, and the infrared light source 102 described later due to the dust in the ignition furnace 6 are generated. In order to prevent contamination of the light reflection plate 103 and the lamp 202, a clean image signal is transmitted, and the light reflection plate 103 is installed on the nozzle to provide the light reflection plate 103 and the separator 107. The infrared light source 102 is irradiated through the lamps 202 installed at the lower left and right sides of the.

The infrared light source 102 is an infrared band (900 ~ 1100mm) with a large amount of light reflection, the light reflector 103, the light direction of the infrared light source 102 in both sides of the ignition furnace 6 through which the raw coal flows Guide function to flow.

The lamp 202 is an infrared light source having a large amount of reflection from the raw coal, and the rear side of the radiation sample 205 is installed with a surveillance camera 105 sensitive to infrared radiation in the infrared band, which is difficult to observe in the visible band. By imaging the flow state to allow the remote operator to observe, the front of the radiation sensor 206 is provided with a lens 104 sensitive in the infrared band photosensitive efficiency.

As shown in FIGS. 3 and 4, the fusion light removing unit is installed in the vertical direction at both left and right sides of the sintering ignition furnace 6, and the rotating shaft 404 of the driving motor 402 includes a bearing 405 and one pair. Is connected to the speed reducer 403 through the sprocket 408 of the motor, and the driving motor 402 is a motor without a brake, so that the drive motor 402 is rotated through the circulation air in the ignition furnace 6 even when the power is not supplied. free operation), the cyclo reducer 403 is assembled to the rotating shaft 404 through a coupling (not shown).

In addition, one end of the connecting shaft 500 is connected to the rotating shaft 404 through the cyclo reducer 403, and the central portion of the connecting shaft 500 is fixed to the through-assembly 406 above the ignition furnace 6 The wire brush 401 is attached to the outer circumferential surface of the other end of the connecting shaft 500, and a heat sink 407 is installed at the contact portion between the upper portion of the wire brush 401 and the ignition furnace 6.

Hereinafter, the operation of the present invention having the configuration as described above.

As shown in FIG. 5, when the infrared light source 102 is irradiated to the furnace wall inside the ignition furnace 6 directly or together with the illumination lamp 202 without being illuminated by the light reflector 103 onto the lens 104. Only the infrared rays reflected from the object are incident on the surveillance camera 105 through the lens 104 and converted into a video signal, which is remoted through the monitor 110 via the fixed tube 108 and the controller 201. The operator of can be observed in real time.

In the process as described above, the compressed air filtered through the air supply pipe 207 to increase the pressure inside, by injecting air through the nozzle 106, the lens 104 in the ignition furnace 6, the monitoring camera ( 105, the infrared light source 102, the light reflection plate 103, and the illumination lamp 202 are prevented from being transmitted, thereby transmitting a clean image signal.

  On the other hand, when the fusion light is generated and attached to the inner wall of the ignition furnace 6, the video signal is converted into a digital signal of the controller 201 and processed to be rotated in accordance with the operation of the drive motor 402 is rotated. As the connecting shaft 500 rotates, the wire brush 401 removes the fusion light generated in the furnace wall of the ignition furnace 6.

According to the apparatus for monitoring and removing fused light in the sinter ignition furnace of the present invention as described above, the generation and formation of fused light generated by ignition of raw coal in the sinter ignition furnace, which is difficult for workers to access, is monitored in real time. By removing large amount of fused light, it can improve product quality and prevent internal refractory collapse by ignition.

1 is a schematic diagram illustrating a sintering manufacturing process.

2 is a fusion light formation diagram in a furnace wall of a conventional sintering ignition furnace.

Figure 3 is an overall configuration of the apparatus for monitoring and removing fused light in the sintering ignition furnace according to an embodiment of the present invention.

Fig. 4 is a block diagram of a fusion light removing device in the apparatus for monitoring and removing fused light in the sintering ignition furnace shown in Fig. 3;

FIG. 5 is a view illustrating a configuration of a fused light monitoring device in a fused light monitoring and removing device inside the sintering ignition furnace shown in FIG.

<Explanation of symbols for main parts of drawing>

6: ignition furnace 7: sintering machine bogie

102: infrared light source 103: light reflector

105: surveillance camera 106: nozzle

110: monitor 201: controller

401: wire brush 404: rotation axis

500: connecting shaft

Claims (2)

In the apparatus for monitoring and removing the fusion of the fused furnace in the ignition furnace as the ignition of the charged raw material in the sintering process attached to both the inner furnace wall, A radiation control unit including an air supply pipe on one side and a frame fixed to the furnace wall of the ignition furnace, and installed at a predetermined distance from the air supply pipe, and having one end connected to a monitor through a controller; Observation of the flow of raw coal in the ignition furnace irradiated by the illumination means through an illumination means including an infrared light source, a light reflection plate for guiding the light direction of the infrared light source, and an illumination lamp installed under the light reflection plate, and a lens and a surveillance camera. A fusion light monitoring unit including an observation means, a separator and a nozzle installed on the separator and configured to prevent contamination of the lighting means and the observation means; A fusion light control unit configured to remove the fusion light through a wire brush while rotating and connecting shafts rotate according to an operation of a driving motor when the fusion light is generated and attached; Melting light monitoring and removal apparatus inside the sintering ignition furnace, characterized in that configured to include. The method of claim 1, A radiation sample is installed at the other end of the fixed tube, a radiation sensor is installed at a lower portion of the radiation sample, and a heat sink is installed at a contact portion between the upper portion of the wire brush and the ignition furnace. Monitoring and removal devices.