KR20190101044A - Method for substituting cooling water for furnace - Google Patents

Abstract

Disclosed is a method for substituting cooling water which has excellent effects of reducing usage of chemicals for cooling water and cooling water usage. A blast furnace cooling water system comprises: a first cooling water system to circulate first cooling water and cool a blast furnace body; a second cooling water system to circulate second cooling water stored in a first pond, and exchange heat with the first cooling water by a heat exchanger to cool the first cooling water; and a third cooling water system to circulate third cooling water stored in a second pond, and cool supplementary equipment. The first and the second ponds are connected by a transport pipe. According to an embodiment of the present invention, the method for substituting cooling water of the blast furnace cooling water system comprises: a step of measuring a water level of the second cooling water stored in the first pond; a step of increasing the water level of the second cooling water in the first pond by supplying first supplementary water if the water level of the second cooling water is lower than a prescribed value, and measuring a contamination factor of the second cooling water stored in the first pond if the water level of the second cooling water is higher than or equal to a prescribed value; and a step of continuing a circulation operation of the second cooling water if the contamination factor of the second cooling water is lower than a prescribed value, and spilling the second cooling water to the second pond by controlling a valve of the transport pipe if the contamination factor of the second cooling water is higher than or equal to a prescribed value.

Description

Blast furnace cooling water replacement method {METHOD FOR SUBSTITUTING COOLING WATER FOR FURNACE}

The present invention relates to a blast furnace cooling water replacement method. More specifically, the present invention relates to a blast furnace cooling water replacement method having excellent effects of reducing the amount of chemicals used for cooling water and the amount of cooling water using water discarded in an existing blast furnace cooling water system.

Cooling water use in blast furnace plant in steelworks can be divided into indirect closed system, indirect open system, and direct open system. Among these, the indirect closed system means coolant for cooling the blast furnace body, the indirect open system means coolant for cooling the indirect closed system and other auxiliary equipment, and the direct open system means coolant for cooling slag. do.

Since the closed crab is a closed system, water quality problems do not occur much, but in the case of an open system, a lot of pollution occurs because it comes into contact with the outside atmosphere. Since the direct open system is used for slag cooling itself, the quality of the cooling water is not a problem, but the indirect open system used as the secondary cooling water and auxiliary equipment cooling water is highly related to the cooling of the blast furnace and the auxiliary equipment. Is relatively important.

Background art of the present invention is disclosed in Republic of Korea Patent Publication No. 10-1558925 (2015.10.12., The name of the invention: furnace cooling water treatment method).

According to an embodiment of the present invention, by using the water discarded in the existing cooling water system, it is to provide a blast furnace cooling water replacement method excellent in the amount of chemicals for cooling water and cooling water consumption.

According to one embodiment of the present invention, it is to provide a blast furnace cooling water replacement method that can minimize the facility load and the cycle of facility replacement of the blast furnace cooling water system.

One aspect of the invention relates to a blast furnace cooling water replacement method. In one embodiment, the blast furnace cooling water replacement method includes: a first cooling water system configured to circulate a first cooling water and to cool the blast furnace body; A second cooling water system configured to circulate a second cooling water stored in a first pond and to heat exchange with the first cooling water through a heat exchanger to cool the first cooling water; And a third cooling water system configured to circulate the third cooling water stored in the second pond to cool the auxiliary equipment, wherein the first pond and the second pond are cooling water replacement methods of the blast furnace cooling water system connected through a transfer pipe. The cooling water replacement method may include: measuring a level of a second cooling water stored in the first pond; When the level of the second cooling water is less than a predetermined value, the first supplement water is added to increase the level of the second cooling water in the first pond, and when the level of the second cooling water is a predetermined value or more, the first pond Measuring a second coolant contamination factor stored in the storage device; And if the measured value of the second coolant contamination factor is less than a predetermined value, continuing the circulation operation of the second coolant, and if the measured value of the contaminated factor of the second coolant is a predetermined value or more, controlling the valve of the transfer pipe to And flowing a second coolant into the second pond.

In one embodiment, the total phosphate concentration of the second cooling water stored in the first pond is measured, and when the total phosphate concentration is less than a predetermined value, an anticorrosive may be introduced into the first pond.

In one embodiment, the contaminant of the second cooling water may be at least one of suspended solids (SS), turbidity, chlorine (Cl), and calcium (Ca) concentration of the second cooling water.

In one embodiment, the auxiliary equipment may include at least one of a gas cleansing facility, a blast furnace static pressure power generation (TRT) facility, a hot stove, a raw material transportation facility, a pulverized coal injection facility (PCI), and a refurbishment facility.

When the blast furnace cooling water replacement method of the present invention is applied, the water used in the existing cooling water system is used to reduce the amount of chemicals for cooling water and the amount of cooling water used, and minimize the load and facility replacement cycle of the blast furnace cooling water facility such as hydrocyclone. Can be.

Figure 1 shows the blast furnace cooling water replacement method.
Figure 2 shows the blast furnace cooling water system according to an embodiment of the present invention.
3 shows a first pond and a second pond of the blast furnace cooling water system according to one embodiment of the invention.
Figure 4 shows the blast furnace cooling water replacement method according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail. In this case, when it is determined that the detailed description of the related known technology or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The terms to be described below are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators, and the definitions should be made based on the contents throughout the specification for describing the present invention.

Blast furnace cooling water replacement method

One aspect of the invention is a first cooling water system for circulating the first cooling water and cooling the blast furnace furnace body; A second cooling water system configured to circulate a second cooling water stored in a first pond and to heat exchange with the first cooling water through a heat exchanger to cool the first cooling water; And a third cooling water system configured to circulate the third cooling water stored in the second pond to cool the auxiliary equipment, wherein the first pond and the second pond are connected to a blast furnace cooling water system through a transfer pipe. will be.

Figure 1 shows the blast furnace cooling water replacement method. Referring to FIG. 1, the cooling water replacement method includes measuring a level of a second cooling water stored in a first pond; When the level of the second cooling water is less than a predetermined value, the first supplement water is added to increase the level of the second cooling water in the first pond, and when the level of the second cooling water is a predetermined value or more, the first pond Measuring a second coolant contamination factor stored in the storage device; And if the measured value of the second coolant contamination factor is less than a predetermined value, continuing the circulation operation of the second coolant, and if the measured value of the contaminated factor of the second coolant is a predetermined value or more, controlling the valve of the transfer pipe to And flowing a second coolant into the second pond.

Figure 2 shows the blast furnace cooling water system according to an embodiment of the present invention. Referring to FIG. 2, the blast furnace cooling water system 1000 includes: a first cooling water system in which first cooling water flows into the blast furnace furnace cooling panel 110 and circulates to cool the furnace body 100; A second cooling water system configured to circulate the second cooling water stored in the first pond 201 and to heat exchange the first cooling water with the heat exchanger 203 to cool the first cooling water; And a third cooling water system configured to circulate the third cooling water stored in the second pond 301 to cool the auxiliary equipment 310. The first pond 201 and the second pond 202 may include a valve 212. Is connected through a transfer pipe 210 is provided.

In a second embodiment, the second cooling water system includes a hydro cyclone 202 for separating solids, particulates, etc. in the second cooling water, and a second cooling water for cooling the first cooling water of the first cooling water system. Since the cooling water quality is continuously deteriorated due to the large amount of atmospheric evaporation, the first pond 201 may be discharged for water quality management, that is, blow down, to be discharged to the outside.

In a specific embodiment, the third cooling water system circulates the third cooling water stored in the second pond 301 to cool the auxiliary equipment 310, and the third cooling water discharged from the auxiliary equipment 310 is transferred to the third pond 302. After being introduced and stored, it may be introduced to the second pond 301 again.

In one embodiment, the first cooling water system may be circulated by introducing the first cooling water through the high water tank 101. The second cooling water system and the third cooling water system may be supplied with a first supplementary water and a second supplementary water, respectively, through a first water tank (not shown) and a second water tank (not shown).

In one embodiment, the auxiliary facility 310 may include at least one of a gas cleaning facility, a blast furnace static pressure power generation (TRT) facility, a hot stove, a raw material transport facility, a pulverized coal injection facility (PCI), and a refurbishment facility.

3 shows a first pond and a second pond of the blast furnace cooling water system according to one embodiment of the invention. Referring to FIG. 3, the first pond 201 and the second pond 301 may include a first measuring unit 401 and a second measuring unit 402. The first measuring unit 401 and the second measuring unit 402 may include a measurement sensor for measuring the contamination factor and the water level, respectively. The measured pollution factor and the level measurement value may be transmitted to and collected from the control unit 501 electrically connected to the first and second measurement units 401 and 402.

In one embodiment, the contaminant of the second cooling water may be at least one of suspended solids (SS), turbidity, chlorine (Cl), and calcium (Ca) concentration of the second cooling water. For example, when the concentration of at least one of chlorine, turbidity, suspended solids (SS) and calcium, which are pollutants measured by the first measuring unit 401, is greater than or equal to a predetermined value, the valve 212 of the transfer pipe 210 is controlled. The secondary cooling water may flow out to the second pond 301.

In one embodiment, it can be measured by setting the type of pollution factor that increases at the fastest rate or increases to the highest value of the second cooling water, one or more pollution factors can be measured. This may vary depending on the quality of the coolant, and setting the contaminant type is common to those skilled in the art.

In one embodiment, when measuring one or more contaminants, the contaminant increases at the fastest rate or increases to the highest value, and is sequentially set and measured. By controlling the valve 212, the secondary cooling water of the first pond 201 may flow out to the second pond 301.

In one embodiment, when the blast furnace cooling water is replaced, the total phosphate concentration (total PO ₄ ) of the second cooling water stored in the first pond 201 is measured, and when the total phosphate concentration is less than a predetermined value, the anticorrosive is added to the first pond ( 201). The said anticorrosive can use a conventional corrosion inhibitor. For example, it may include phosphoric acid (PO ₄ ).

On the other hand, the second cooling water for cooling the first cooling water system has a lot of atmospheric evaporation, and the quality of the cooling water may deteriorate continuously. Therefore, the second coolant should increase the discharge through blow down for water quality control. On the other hand, since the third cooling water system for cooling the auxiliary equipment 310 is used in many places, such as gas cleaning equipment, TRT, PCI equipment, raw material transport equipment, the cooling water consumption is higher than other cooling water systems. Therefore, it is difficult to concentrate for the chemicals of the third cooling water, the situation is required to continuously input the chemicals.

On the other hand, when applying the blast furnace cooling water replacement method of the present invention by using the second cooling water discarded in the existing second cooling water system, by replacing with a third cooling water system, the chemical component in the blowdown discarded in the existing secondary cooling water system, the It can be used as a substitute for the chemical of the third cooling water of the third cooling water system, it can be excellent in reducing the amount of the chemicals used for the cooling water and the amount of cooling water. This minimizes the load and facility replacement cycles of blast furnace cooling water systems, such as hydrocyclones.

Hereinafter, the configuration and operation of the present invention through the preferred embodiment of the present invention will be described in more detail. However, this is presented as a preferred example of the present invention and in no sense can be construed as limiting the present invention.

Example  One

Pollution factor  Set

A first cooling water system circulating the first cooling water and cooling the furnace body 100; A second cooling water system configured to circulate the second cooling water stored in the first pond 201 and to heat exchange the first cooling water with the heat exchanger 203 to cool the first cooling water; And a third cooling water system configured to circulate the third cooling water stored in the second pond 301 to cool the auxiliary facilities 310, wherein the first pond 201 and the second pond 202 are transport pipes 210. Cooling water substitution was carried out in the blast furnace cooling water system 1000 as shown in FIGS.

The general water quality management criteria of the second cooling water system are shown in Table 1 below, and the suspended solids were set as the pollutant to be measured, and the suspended solids concentration reference value of the first pond 201 was set to 15 ppm with reference to Table 1 below. .

On the other hand, Table 2 shows the results of measuring the average water quality of the existing second cooling water and the third cooling water.

Referring to Table 2, it can be seen that the second coolant has a lower overall water quality than the third coolant, and much chemical (anticorrosive) injection is required to satisfy the total phosphate concentration for cooling the auxiliary equipment of the third coolant. have. Referring to Table 2, the total phosphate concentration of the second cooling water in the first pond 201 was set to 6 ~ 10ppm.

The water level of the second coolant stored in the first pond is measured, and when the water level of the second coolant is less than a predetermined value, first supplementary water is added to increase the level of the second coolant in the first pond. When the level of the second cooling water is equal to or greater than a predetermined value, the contamination factor (floating material SS) of the second cooling water stored in the first pond 201 through the first measuring unit 401 provided in the first pond 201. Concentration).

When the measured value of the concentration of the second coolant suspended solids (SS) is less than 15 ppm, the circulation operation of the second coolant is continued, and when the measured value of the contamination factor of the second coolant is 15 ppm or more, the valve of the transfer pipe 210 is used. The second coolant is discharged to the second pond by substituting the second coolant, and the second coolant introduced into the second pond is mixed with the third coolant of the second pond. Cooling facility, blast furnace static pressure power generation (TRT) facility, hot stove, raw material transportation facility, pulverized coal injection facility (PCI) and recharging facility) were cooled.

In addition, by measuring the total phosphate concentration of the second cooling water stored in the first pond 201 at the time of cooling water replacement, when the total phosphate concentration is less than 6ppm flows into the first pond, if the corrosion inhibitor is 10ppm or more, Inflow was stopped.

Example  2

The blast furnace cooling water was substituted as shown in FIG. In the same blast furnace cooling water system as in Example 1, the blast furnace cooling water was replaced. Referring to Tables 1 and 2, the contaminants of the second cooling water were set to suspended substances (reference value: 15 ppm), chlorine (reference value: 150 ppm), and turbidity (reference value: 20 ppm).

The water level of the second coolant stored in the first pond is measured, and when the water level of the second coolant is less than a predetermined value, first supplementary water is added to increase the level of the second coolant in the first pond. When the level of the second cooling water is higher than or equal to a predetermined value, the contamination factors (floating matter, chlorine, and the like) of the second cooling water stored in the first pond 201 through the first measuring unit 401 provided in the first pond 201. Turbidity) was measured.

When the suspended solids concentration is 15 ppm or more, the valve 212 of the transfer pipe 210 is controlled to flow out the second cooling water to the second pond 301, and when less than 15 ppm, the valve of the transfer pipe 210 is controlled. 212 was controlled to stop the outflow of the second cooling water, and the circulation operation of the second cooling water was continued.

Then, when the concentration of chlorine is 150ppm or more, by controlling the valve 212 of the feed pipe 210, the second coolant flowed out to the second pond 301, if less than 150ppm, of the feed pipe 210 The valve 212 was controlled to stop the outflow of the second cooling water and to continue the circulation operation of the second cooling water.

Then, when the concentration of turbidity is 20ppm or more, by controlling the valve 212 of the feed pipe 210, the second coolant flowed out to the second pond 301, if less than 20ppm, of the feed pipe 210 The valve 212 was controlled to stop the outflow of the second cooling water and to continue the circulation operation of the second cooling water.

The second cooling water flowing out to the second pond is mixed with the third cooling water of the second pond, and the auxiliary facilities (gas cleaning equipment, blast furnace static pressure power generation (TRT) equipment, hot blast furnace, raw material transportation equipment, pulverized coal blowing equipment ( PCI) and water equipment) were cooled.

In addition, by measuring the total phosphate concentration of the second cooling water stored in the first pond 201 when the cooling water is replaced, when the total phosphate concentration is less than 6ppm when the anticorrosive is introduced into the first pond and more than 10ppm, anticorrosive inflow Stopped.

In Examples 1 and 2 by replacing the blast furnace cooling water in operation, compared to the operation (Comparative Example) that does not replace the cooling water, the average amount of cooling water was reduced to 1,100 tons per day, and the amount of anticorrosive was also reduced.

Simple modifications or changes of the present invention can be easily carried out by those skilled in the art, and all such modifications or changes can be seen to be included in the scope of the present invention.

100: blast furnace 101: elevated tank
110: blast furnace furnace cooling panel 201: first pond
202: hydrocyclone 203: heat exchanger
210: transfer pipe 212: valve
301: second pond 302: third pond
310: additional equipment 401: first measuring unit
402: second measurement unit 501: control unit
1000: blast furnace cooling water system

Claims (4)

A first cooling water system circulating the first cooling water and cooling the blast furnace furnace body; A second cooling water system configured to circulate a second cooling water stored in a first pond and to heat exchange with the first cooling water through a heat exchanger to cool the first cooling water; And a third cooling water system configured to circulate the third cooling water stored in the second pond to cool the auxiliary equipment, wherein the first pond and the second pond are cooling water replacement methods of the blast furnace cooling water system connected through a transfer pipe.
The cooling water replacement method may include: measuring a level of a second cooling water stored in the first pond;
When the level of the second cooling water is less than a predetermined value, the first supplemental water is added to increase the level of the second cooling water in the first pond, and when the level of the second cooling water is a predetermined value or more, the first Measuring a second coolant contamination factor stored in the pond; And
When the measured value of the second coolant contamination factor is less than a predetermined value, the circulation operation of the second coolant is continued, and when the measured value of the pollutant factor of the first coolant is more than a predetermined value, the valve of the transfer pipe is controlled to control the first Blast furnace cooling water replacement method comprising the step of flowing out the cooling water to the second pond.
The method of claim 1, wherein the total phosphate concentration of the second cooling water stored in the first pond is measured, and when the total phosphate concentration is less than a predetermined value, an anticorrosive agent is introduced into the first pond. .
The method of claim 1, wherein the contamination factor of the second cooling water is at least one of suspended solids (SS), turbidity, chlorine (Cl) and calcium (Ca) concentrations of the second cooling water. .
The blast furnace cooling water according to claim 1, wherein the auxiliary equipment includes at least one of a gas cleaning facility, a blast furnace static pressure power generation (TRT) facility, a hot stove, a raw material transport facility, a pulverized coal injection facility (PCI), and a recharging facility. Substitution method.

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