KR101037439B1 - Apparatus for removing scale and method of removing scale in cooling water system using the same - Google Patents

Abstract

PURPOSE: A scale eliminating apparatus and a method for eliminating scales form a cooling system using the same are provided to reduce cost required for operating the apparatus by eliminating fine particles and compacting the structure of the apparatus. CONSTITUTION: An electromagnet housing(121) is combined with the upper side of an inflow head(116) and receives coolant containing fine particles from a cyclone main body(111). The cyclone main body downwardly swivel coarse scale particles and upwardly swivel fine scale particles. The fine particles are attached on electromagnet(122). A coolant discharging pipe(126) discharges coolant without scales from the electromagnet housing. A electromagnet part includes a coolant discharging pipe valve(127). A reverse washing pipe(131) is in connection with the discharging hole of the cyclone main body. A reverse washing part(130) includes a reverse washing valve(132), and the reverse washing vale is controlled to discharge remained scales in the cyclone main body and fine particles on the electromagnet through the reverse washing pipe.

Description

Apparatus for removing scale and method of removing scale in cooling water system using the same}

The present invention relates to a scale removing device and a removing method for removing the scale contained in the cooling water system in the process of cooling the high temperature steel produced through the steelmaking process using a cooling water system.

In general, high temperature steel subjected to a hot rolling process in the steelmaking process is subjected to a cooling process, thereby making a product having a target microstructure and surface quality. In order to cool high temperature steel materials, a cooling water system is used.

The cooling water system cools the hot steel by spraying the coolant directly on the surface of the hot steel by the spray nozzle. At this time, the scale attached to the surface of the hot steel is separated, and the separated scale is discharged by being included in the cooling water passing through the hot steel. The scale contained in the coolant is recovered and recycled through the removal process, and the descaled coolant is reused for cooling the hot steel.

However, if the scale in the cooling water system is not removed below the set level, damage to the cooling water spraying facility may occur, such as clogging of the spray nozzle, abrasion phenomenon, and shortening the life of the equipment when the cooling water is supplied to the spray nozzle while being circulated. Can be. In order to solve this problem, the scale of the cooling water system can be removed through more removal steps, but according to the conventional method, as the removal step increases, the removal facility increases, and the burden of facility cost and operating cost increases. In addition, due to the increased number of removal facilities, a lot of required sites for the increased removal facilities are required.

An object of the present invention is to solve the above problems, it can reduce the required site, and also reduce the installation cost and operating costs, and the clogging of the spray nozzle, wear phenomenon, and shortening the life of the facility when the coolant is reused It is to provide a descaling apparatus that can be prevented, and a descaling method in a cooling water system using the same.

The scale removing apparatus according to the present invention for achieving the above object is to turn the coarse particles of the scale particles down by turning the inlet head for introducing and rotating the flow-included cooling water and the scaled cooling water from the inlet head A cyclone unit having a cyclone body configured to lift and rotate the fine particles; An electromagnet housing coupled to an upper side of the inflow head and receiving cool water including microparticles that are pivoted upward from the cyclone body, an electromagnet for attaching microparticles that are pivoted upward in the electromagnet housing to a surface, and a scale from the electromagnet housing An electromagnet portion having a cooling water discharge pipe for discharging the removed cooling water, and a cooling water discharge pipe valve for opening and closing a flow path of the cooling water discharge pipe; A backwashing pipe having a backwashing pipe connected to the lower outlet of the cyclone body and a backwashing pipe valve for controlling an opening degree of the backwashing pipe; And a controller configured to control the electromagnet, the coolant discharge pipe valve, and the backwash tube valve every set cycle, to discharge the fine particles attached to the electromagnet and the residual scale in the cyclone body through the backwash tube.

Descaling method in the cooling water system using the descaling apparatus according to the present invention, if the cooling water supplied from the cooling water tank used for cooling the high-temperature steel is discharged including the scale, supplying the scale-containing cooling water to the settling tank to reduce the scale Precipitating; Collecting the scale settled in the settling tank and transferring the scale to a scale storage tank, and supplying cooling water including the scale remaining in the settling tank to the scale removing device; Separating scale particles into coarse particles and fine particles by the scale removing device; Discharging the separated coarse particles into the scale reservoir, collecting the separated fine particles into the electromagnet, transferring the descaled cooling water to the cooling water tank through a cooling tower, and allowing the transferred cooling water to be reused for cooling the high temperature steel. ; And discharging the fine particles collected in the electromagnet into the scale storage tank through a backwashing process every set cycle.

According to the present invention, the descaling device can remove not only coarse particles but also fine particles even with a relatively compact configuration. Therefore, compared with the conventional facility for removing coarse particles using a deposition action and a facility for removing fine particles using sand, the required site can be reduced, and facility cost and operation cost can be reduced.

In addition, according to the present invention, since the scale removing device removes the fine particles using an electromagnet capable of adjusting the magnetic strength, the fine particles can be removed to a desired level. Therefore, problems such as clogging of the spray nozzle, abrasion phenomenon, and shortening of the service life of the spray nozzle when cooling water is supplied to the spray nozzle while circulating can be prevented.

1 is a perspective view of a scale removing apparatus according to an embodiment of the present invention.
FIG. 2 is a cross sectional view of the inflow head shown in FIG. 1; FIG.
3 is a side cross-sectional view for explaining the operation example of the descaling device of FIG.
4 is a side cross-sectional view showing an extract of the electromagnet shown in FIG.
FIG. 5 is a block diagram for explaining a method of removing a scale in a cooling water system using the descaling device of FIG. 1. FIG.

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

1 is a perspective view of a scale removing apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the inlet head shown in FIG. 3 is a side cross-sectional view for explaining the operation example of the descaling device of FIG.

1 to 3, the scale removing apparatus 100 according to an embodiment of the present invention removes the scale included in the cooling water system in the process of cooling the high temperature steel produced through the steelmaking process using the cooling water system. It may be used to include a cyclone part 110, an electromagnetic part 120, a back wash part 130, and the control unit 140.

The cyclone unit 110 includes a cyclone body 111 and an inlet head 116. The inflow head 116 injects the swirled cooling water into the cyclone body 111 by swirl flow. The inflow head 116 pivots the cooling water contained in the scale so that centrifugal force acts on the scale, so that the coarse particles and the fine particles of the scale particles can be separated in the cyclone body 111.

Inlet head 116 may be connected to the top of the cyclone body (111). An inlet 117 is formed in the inflow head 116 to introduce the scaled cooling water, and a spiral channel 118 gradually bent while being spirally curved from the inlet 117 may be formed. The rear end of the helical flow path 118 may be connected to the internal space of the cyclone body 111. Therefore, when the scale-containing cooling water is introduced through the inlet 117, the circulating flow 118 passes through the spiral flow passage 118, and may be supplied into the cyclone body 111 while maintaining the swirl flow.

When the cyclone body 111 receives the scaled cooling water from the inflow head 116, the cyclone body 111 rotates the coarse particles in the scale particles and separates the fine particles by turning the fine particles. The cyclone body 111 has a separation space 112 that separates scale particles into coarse particles and fine particles. Separation space 112 functions to maintain a swirl flow of the scaled cooling water flowing through inlet head 116. At this time, the coarse particles are collected on the inner wall of the cyclone body 111 by centrifugal force, and then discharged through the bottom outlet of the cyclone body 111. The fine particles are collected in the central portion in the cyclone body 111 and are supplied to the electromagnet part 120 while turning upward.

The electromagnet unit 120 includes an electromagnet housing 121, an electromagnet 122, a coolant discharge pipe 126, and a coolant discharge pipe valve 127. The electromagnet housing 121 is coupled to the upper side of the inflow head 116. The electromagnet housing 121 is supplied with cooling water including fine particles that are pivoted upward from the cyclone body 111. The lower end of the electromagnet housing 121 is opened, and is inserted into the cyclone body 111 from the upper side of the inflow head 116 via the inner space of the inflow head 116.

The electromagnet 122 is for removing the fine particles in the cooling water by attaching the fine particles to the surface of the electromagnet housing 121 by the magnetic field. Electromagnet 122 is configured to have a magnetic strength that can sufficiently remove the fine particles of the desired size. The electromagnet 122 is inserted through the upper end of the electromagnet housing 121 and is long and vertically disposed at the center of the electromagnet housing 121. In addition, the electromagnet 122 is spaced apart from the inner wall of the electromagnet housing 121 at a predetermined interval so that a flow path may be formed between the electromagnet housing 121 and the electromagnet housing 121.

The flow path between the electromagnet 122 and the electromagnet housing 121 allows the coolant containing the fine particles to flow while rising. In this process, the fine particles are attached to the surface of the electromagnet 122 and collected, and the fine particles removed coolant is discharged through the coolant discharge pipe 126.

The cooling water discharge pipe 126 is for discharging the cooling water having fine particles removed from the electromagnet housing 121. The coolant discharge pipe 126 is formed to communicate with the electromagnet housing 121 at the upper side of the electromagnet housing 121. The coolant discharge pipe valve 127 is installed in the coolant discharge pipe 126 to open and close the flow path of the coolant discharge pipe 126. The coolant discharge pipe valve 127 is controlled to close the flow path of the coolant discharge pipe 126 during backwashing.

The backwash unit 130 includes a backwash tube 131 and a backwash tube valve 132. The backwash tube 131 is connected to the bottom outlet of the cyclone body 111. The backwashing pipe 131 receives coarse particles through the lower outlet of the cyclone body 111 and discharges them to the outside. In addition, the back washing tube 131 allows the fine particles attached to the electromagnet 122 and the residual scale in the cyclone body 111 to be discharged to the outside during back washing. The backwash tube valve 132 is installed in the backwash tube 131 to adjust the opening degree of the backwash tube 131. The back washing tube valve 132 is controlled to widen the opening degree of the back washing tube 131 at the time of back washing.

The controller 140 controls the electromagnet 122, the coolant discharge pipe valve 127, and the backwash tube valve 132 at set intervals to adjust the fine particles attached to the electromagnet 122 and the residual scale in the cyclone body 111. Discharge through the backwash tube (131). The electromagnet 122 has a function of removing the microparticles when the microparticles are attached to and stacked on the surface by a predetermined amount or more, and thus, it is necessary to periodically discharge the microparticles attached to the surface.

To this end, the control unit 140 cuts off the current supplied to the electromagnet 122 for a predetermined period of time. Accordingly, the fine particles attached to the electromagnet 122 can be separated. At the same time, the controller 140 controls the coolant discharge pipe valve 127 to close the flow path of the coolant discharge pipe 126, and also controls the backwash pipe valve 132 to widen the opening degree of the backwash pipe 131. . Accordingly, the coolant flowing into the inflow head 116 does not flow into the coolant discharge pipe 126 and flows back to the backwash pipe 131. As the cooling water flows into the cyclone body 111 and flows back to the backwash tube 131, the fine particles attached to the electromagnet may be discharged together and attached to the inner wall of the cyclone body 111. Residual scales may also be discharged.

The descaling apparatus 100 of the above-described configuration separates coarse particles in one step by using centrifugal force to remove scale particles in the cooling water, and removes the fine particles separated in this process in two steps using a magnetic field. Can be. That is, the scale control device 100 can remove not only coarse particles but also fine particles even with a relatively compact configuration.

Therefore, compared with the conventional facility for removing coarse particles using a deposition action and a facility for removing fine particles using sand, the required site can be reduced, and facility cost and operation cost can be reduced. In addition, the scale removing device 100 removes the fine particles by using the electromagnet 122, which can adjust the magnetic strength, it is possible to remove the fine particles to a desired level. Therefore, problems such as clogging of the spray nozzle, abrasion phenomenon, and shortening of the service life of the spray nozzle when cooling water is supplied to the spray nozzle while circulating can be prevented.

Meanwhile, the cyclone body 111 may have a structure in which the cylindrical tube 113 and the conical tube 114 are alternately connected to have a separation space 112 having a wide upper portion and a narrow lower portion. If the separation space 112 of the cyclone body 111 gradually narrows from the top to the bottom, the swirl flow of the scaled cooling water can be maintained to the lower side of the cyclone body 111, the separation effect of coarse particles and fine particles Can be high. The cylindrical tube 113 may be composed of a plurality of different diameters. And, the conical tube 114 is configured so that the upper diameter between the cylindrical tube 113 and the diameter of the upper cylindrical tube 113, the lower diameter matches the diameter of the lower cylindrical tube 113, the cylindrical tube (113).
For example, as shown in FIG. 4, the electromagnet 122 may include a core 123, a coil 124, and a cover 125. The core 123 may have a structure in which a plurality of core grooves 123a are formed around the cylinder. The core grooves 123a are formed in the circumferential direction of the core 123 and are spaced apart at regular intervals up and down. The core 123 may be made of iron.

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When the coil 124 receives a current from the controller 140, a magnetic field may be formed around the core 123. The coil 124 may be wound around the core grooves 123a around the core 123, respectively. Here, the coil 124 is preferably wound so that the N pole and the S pole are alternately arranged up and down around the core 123. Accordingly, the area to which the fine particles are attached to the surface of the core 123 may be secured to the maximum. The cover 125 seals the core 123 and the coil 124 so that the coolant does not come into contact with the core 123 and the coil 124 when the electromagnet 122 is immersed in the coolant. The cover 125 may be made of a metal material so that the fine particles are attached to the surface well.

A method of removing the scale in the cooling water system using the descaling device 100 having the above-described configuration will be described below with reference to FIG. 5.

First, when a high temperature steel is manufactured in the steelmaking process unit 210, the cooling water contained in the cooling water tank 220 is supplied to the steelmaking process unit 210 and sprayed into the high temperature steel. The cooling water used for the hot steel is discharged including the scale. Then, the scale-containing cooling water is supplied to the settling tank 230 to precipitate the scale in the settling tank 230. Subsequently, the scale settled in the settling tank 230 is collected and transferred to the scale reservoir 240.

On the other hand, the cooling water in the sedimentation tank 230 may include a scale that does not settle and remains in a suspended state, and supplies the cooling water including the remaining scale to the scale removing apparatus 100. Then, the scale removing apparatus 100 separates the scale particles in the cooling water into coarse particles and fine particles by using a cyclone, and discharges the separated coarse particles into the scale reservoir 240. In addition, the descaling apparatus 100 collects the separated microparticles on the surface of the electromagnet by the magnetic field, and discharges the microparticles to the scale storage tank 240 through a backwashing process every set cycle when the microparticles are accumulated for a predetermined time or more. Then, the descaled cooling water is transferred to the cooling tower 250 while passing through the descaling apparatus 100, and the cooling water cooled by heat exchange while passing through the cooling tower 250 is transferred to the cooling water tank 220. The cooling water transferred to the cooling water tank 220 is sent to the steelmaking process unit 210 and reused for cooling the high temperature steel.

According to the method described above, not only coarse particles in the cooling water but also fine particles can be removed by using a magnetic field, so that when the cooling water is supplied to the spray nozzles while circulating, the spray nozzles are clogged, wear occurs, and the life of the equipment is shortened. Causing such problems can be prevented. In addition, compared to conventionally equipped with a facility for removing coarse particles using a deposition action and a facility for removing fine particles using sand, required sites can be reduced, and facility costs and operating costs can be reduced.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Could be. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

110. Cyclone part 111. Cyclone body
116. Inlet head 120 Electromagnet
121. Electromagnet housing 122. Electromagnet
126. Chilled water outlet valve 127. Chilled water outlet valve
130 .. Backwash 131 .. Backwash
132. Backwash pipe valve 140. Control section

Claims (4)

An inflow head for introducing and rotating flow of the cooling water with scale, and a cyclone unit having a cyclone body configured to receive the cooling water included in the scale from the inflow head and to rotate the coarse particles in the scale particles and to rotate the fine particles up and down to separate the fine particles. In the descaling device,
An electromagnet housing coupled to an upper side of the inflow head and receiving cool water including microparticles that are pivoted upward from the cyclone body, an electromagnet for attaching microparticles that are pivoted upward in the electromagnet housing to a surface, and a scale from the electromagnet housing An electromagnet portion having a cooling water discharge pipe for discharging the removed cooling water, and a cooling water discharge pipe valve for opening and closing a flow path of the cooling water discharge pipe;
A backwashing pipe having a backwashing pipe connected to the lower outlet of the cyclone body and a backwashing pipe valve for controlling an opening degree of the backwashing pipe; And
And a control unit configured to control the electromagnet, the coolant discharge pipe valve, and the backwash tube valve at predetermined intervals to discharge the fine particles attached to the electromagnet and the residual scale in the cyclone body through the backwash tube. . The method of claim 1,
The cyclone body is a scale removal device, characterized in that the cylindrical tube and the conical tube is alternately connected so that the upper portion has a narrow separation space is wide. The method of claim 1,
The electromagnet,
And a coil wound around the core so that the N pole and the S pole are alternately arranged up and down around the core, and a cover for sealing the core and the coil. A descaling method in a cooling water system using the descaling device according to any one of claims 1 to 3,
When the cooling water supplied from the cooling water tank for cooling the high-temperature steel material is discharged including the scale, supplying the scale-containing cooling water to the settling tank to precipitate the scale;
Collecting the scale settled in the settling tank and transferring the scale to a scale storage tank, and supplying cooling water including the scale remaining in the settling tank to the scale removing device;
Separating scale particles into coarse particles and fine particles by the scale removing device;
Discharging the separated coarse particles into the scale reservoir, collecting the separated fine particles into the electromagnet, transferring the descaled cooling water to the cooling water tank through a cooling tower, and allowing the transferred cooling water to be reused for cooling the high temperature steel. ; And
And discharging the fine particles collected in the electromagnet into the scale storage tank through a backwashing process every set cycle.

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