KR20160010926A - Limestone sludgy supply system for flue gas desulfurization equipment - Google Patents

Abstract

The present invention relates to a system for supplying, to flue gas desulfurization equipment, limestone sludge produced when pre-treating quicklime inserted to a blast furnace, in order to produce slag in steel works. According to the present invention, the fuel gas desulfurization equipment comprises: a natural limestone supply system including a limestone day silo, a wet-type ball mill, a mill-slurry tank, a classifier, and a limestone slurry storage tank; a gas absorption part absorbing disulfur gas by limestone supplied from the natural limestone supply system; an exhaust part releasing gas from which disulfur gas is eliminated; a precipitate separation part separating a precipitate produced in the gas absorption part; and a waste treatment part treating solid separated from the precipitate. In addition, the flue gas desulfurization equipment further comprises a lime sludge supply system which supplies limestone sludge to the gas absorption part.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a limestone sludge supply system for a flue gas desulfurization system,

The present invention relates to a limestone sludge supply system for a flue gas desulfurization facility, and more particularly, to a system for supplying limestone sludge to a flue gas desulfurization facility during the pretreatment of burnt lime, which is introduced into a furnace to produce slag in a steel mill.

In iron and steel mills, iron ore, coke, quicklime, etc. are put into a furnace to burn pig iron in raw iron ore, and coke is burned to heat or reduce iron ore. The residue obtained after obtaining pig iron, that is, blast furnace slag, is subjected to cooling treatment using high-pressure water or air. In the method of quenching using high-pressure water, the glassy slag is produced due to rapid cooling rate, The process can produce glassy slag and crystalline slag according to the cooling conditions. Blast furnace slag powder is used mainly as an admixture for cement because it has hardness that hardens by reacting with water.

As shown in FIG. 1, the quicklime introduced into the blast furnace to obtain pig iron is obtained by washing limestone with tap water. At this time, the limestone fine particles having a diameter of 1 mm or less are separated and precipitated from the limestone billet, And is buried in a yard. Therefore, landfill and land contamination problems are caused.

The abandoned limestone sludge contains about 20% moisture, and the CaO content exceeds 50%, which can be said to be a high-quality limestone. It can be recycled and recycled to produce slurry raw materials for flue gas desulfurization and raw materials for asbestos A method of utilizing limestone sludge is disclosed in Korean Patent No. 134862.

Limestone used in large quantities in flue gas desulfurization processes to remove sulfur oxides in exhaust gas discharged from power plants using coal, oil, gas and other energy sources has a CaCO ₃ content of 95% or more The higher limestone is more excellent in crushability and exhibits high reactivity with sulfuric acid.

As shown in FIG. 2, the wet flue gas desulfurization method can be generally classified into a sulfur dioxide gas absorption process, a process of separating the precipitate produced after the reaction, and a waste treatment process of treating the separated solid matter. Among them, the process of absorbing sulfur dioxide is performed by introducing dust and exhaust gas containing SO ₂ from the boiler into an absorber through an electrostatic precipitator (EP) by a booster fan . At this time, the exhaust gas is heated to a temperature of about 120 to 160 ° C by a gas-gas-heater (GGH) installed at the inlet of the absorption part and is introduced into the absorption part. The exhaust gas flowing into the absorber undergoes gas-liquid contact with water or a liquid alkaline slurry. At this time, the SO ₂ component in the exhaust gas chemically reacts with the alkali slurry, which is an absorbent, and a solid precipitate (gypsum) such as CaSO ₃ or CaSO ₄ is formed in the lower part of the absorption part. Then, the gas discharged from the absorption part is discharged to the atmosphere through the heat exchanger. The gypsum by-products precipitated in the lower part of the absorption part are buried or recycled through a series of processes.

In the natural limestone feed system in which the absorbent used in the absorber of the flue gas desulfurization facility is fed, limestone is taken out from a day silo 20 and is pulverized in a wet ball mill 30, The slurry is poured into a slurry tank 40 and transported to a classifier 50 by a mill slurry pump 41. The slurry is divided into approximately 325 meshes, Limestone slurry (generally 45 탆 or less) that has been pulverized to pass through a slurry tank (which means the number of spaces per inch (2,54 cm)) is stored in a limestone slurry storage tank 60, And the limestone slurry of 325 mesh or more is again conveyed to the ball mill 30 and re-pulverized.

However, limestone sludge discharged from a steel mill is a high-grade limestone having excellent crushability, and since it is discarded in the form of a sludge cake in a steel mill, it is in a solidified and adhered form. Therefore, in order to use it as an absorbent in a flue gas desulfurization plant, There is a need to construct the slurry separately from the line supplying the slurry.

It is an object of the present invention to provide a system for supplying limestone sludge, which is a steel by-product to a flue gas desulfurization facility, separately from a natural limestone supply system.

The flue gas desulfurization facility according to the present invention comprises a natural limestone feed system comprising a limestone day silo, a wet ball mill, a mill-slurry tank, a classifier, a limestone slurry storage tank, a limestone feed system, A sediment separating section for separating sediment generated in the gas absorbing section, and a waste disposal section for treating the separated solid matter in the sediment, wherein the flue gas desulfurization facility comprises: And a limestone sludge supply system for supplying limestone sludge to the gas absorption unit.

Preferably, the limestone sludge supply system comprises a transfer device for transferring the limestone sludge discharged from the dump feeder; A pair of sludge hoppers for storing the transferred limestone sludge; A pair of double screw conveyors for conveying limestone sludge discharged from each of the pair of sludge hoppers, respectively, into a corresponding one of a pair of induction mills; A pair of induction mills for crushing or crushing the introduced limestone sludge; And a pair of pressure transfer pumps for transferring the limestone sludge crushed or shredded in a pair of induction mills to a wet ball mill or a limestone day silo, respectively.

The method for driving a limestone sludge supply system for an exhaust gas desulfurization plant according to the present invention comprises the steps of: inputting limestone sludge into a sludge hopper; Transferring the limestone sludge discharged from the sludge hopper into an induction mill; Crushing and pulverizing the limestone sludge in the attrition mill; Transporting the ground, pulverized limestone sludge to a ball mill or a day silo of a natural limestone feed system; And, when the limestone sludge is transferred to the ball mill, further pulverizing and transferring it to the absorption part.

The limestone sludge supply system for a flue gas desulfurization facility according to the present invention can reduce the material cost by replacing limestone sludge, which is a steel industry waste, with natural limestone in a desulfurization process, and the limestone sludge is mostly present in the form of a fine powder, It is possible to reduce the use power, time and crushing cost of the limestone sludge, and solve problems caused by limestone sludge landfill.

1 is a view showing a process of generating limestone sludge in a steel mill.
2 is a view showing an overall configuration of a wet type flue gas desulfurization facility.
3 is a view schematically showing the construction of a limestone sludge supply system for a flue gas desulfurization system according to the present invention.
4a is a top plan view of a limestone sludge supply system for a flue gas desulfurization plant in accordance with the present invention.
4b is a side plan view of a limestone sludge supply system for a flue gas desulfurization plant according to the present invention as seen in "A" of FIG. 4a.
4C is a side plan view of a limestone sludge supply system for a flue gas desulfurization plant according to the invention as seen in "B" of FIG. 4A.
5 is a diagram showing the operation of a limestone sludge supply system for a flue gas desulfurization plant according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a limestone sludge supply system of a flue gas desulfurization system according to the present invention will be described with reference to the drawings.

3 to 5, the flue gas desulfurization facility includes a limestone day silo 20, a wet ball mill 30, a mill slurry tank 40, a classifier, 50, a natural limestone supply system including a limestone slurry storage tank 60, a gas absorption unit for absorbing the sulfuric acid gas by the limestone supplied from the natural limestone supply system, an exhaust unit for discharging the sulfur- A sediment separating section for separating the sediment generated in the gas absorbing section, and a waste disposal section for treating the separated solid in the sediment, and further comprising a limestone sludge supply system for supplying limestone sludge to the gas absorbing section.

The limestone sludge supply system according to the present invention for feeding the limestone sludge, which has been subjected to disposal treatment in a steel mill separately from the natural limestone supply system for supplying natural limestone to the absorption part of the flue gas desulfurization plant, A feeding system, a pair of sludge hoppers 130a and 130b, a pair of double screw conveyors 140a and 140b, a pair of attrition mills 150a and 150b And a pair of sludge feed pumps 160a and 160b.

The limestone sludge discharged from a steel mill and carried on a truck is unloaded to a dump feeder. The dump feeder is a modification of a conventional plate conveyor system. A large-capacity storage hopper is attached, The raw material unloaded to the dump feeder is discharged on the belt conveyor 110, which is a conveying device, by a predetermined amount.

A forward / reverse conveyor 120, which is a distributing device, is disposed below the rear end of the belt conveyor 110. Since the moving direction of the belt is changed according to the operation of the driver, the forward and reverse conveyor 120 is operated by the sludge hoppers 130a and 130b, And the limestone sludge is supplied to a pair of sludge hoppers 130a and 130b.

A pair of sludge hoppers 130a and 130b for storing the limestone sludge transferred from the normal conveyor 120 may not be discharged due to the nature of the limestone sludge and may not be discharged to the inside of the hopper of the sludge, In order to prevent the phenomenon, the material of the lower cone portion of the hopper is selected and the surface treatment method is changed. The lower discharge screw is made into a double screw structure to prevent the limestone sludge from attaching to the screw blade .

Double screw conveyors 140a and 140b are provided at the lower portions of the outlets of the pair of sludge hoppers 130a and 130b so that the sludge sludge discharged from each sludge hopper is supplied to the respective impact mills 150a and 150b ). That is, the limestone sludge discharged from the sludge hopper 130a is conveyed to the induction mill 150a by the double screw conveyor 140a, that is, the limestone sludge discharged from the sludge hopper 130b is conveyed to the double screw conveyor 140b To the induction mill 150b.

The pair of induction mills 150a and 150b crushes the limestone sludge fed from the sludge hoppers 130a and 130b into limestone sludge. The limestone sludge has different shapes depending on the season and the adhesion between the limestone sludge particles is severe Strong stirring is required. A general agitation mill is a vertical grinding machine using beads (1 ~ 5mm), which is an impeller type using rotary blades and beads for grinding and a bead-based grinding However, in the present invention, an impact mill that does not use beads and mainly performs a crushing action is used. However, the present invention is not limited thereto. Seam mill may also be used.

The pair of induction mills 150a and 150b has a high pulverizing and breaking speed and can improve the pulverization efficiency by several times to several tens times as compared with the ball mill. The particle size distribution is fairly narrow and homogeneous pulverization can be expected, The process range from viscosity to high viscosity is wide, and temperature and particle size can be easily controlled.

A pair of sludge pressure feeding pumps 160a and 160b constituting each of the pair of induction mills 150a and 150b is constituted by the pulverized or crushed limestone sludge in each of the induction mills 150a and 150b, (ball mill) 30, or directly into the limestone silo 20 to operate.

The limestone sludge supply system of the flue gas desulfurization equipment according to the present invention as described above

Introducing limestone sludge into a sludge hopper;

Transferring the limestone sludge discharged from the sludge hopper into the induction mill;

Crushing limestone sludge in an induction mill;

Transporting the ground, pulverized limestone sludge to a ball mill or a day silo of a natural limestone feed system; And

When the limestone sludge is transported to the ball mill, the limestone sludge can be introduced into the absorption part according to the step of further grinding and transferring to the absorption part.

When the limestone sludge is transported to the day silo 20, the limestone sludge may be transported to the ball mill 30 in accordance with the driver's command and then pulverized and put into the absorption part.

When the limestone sludge discharged from the sludge hopper is transferred to the induction mill, the additive for improving the desulfurization efficiency may be added to the induction mill to maximize the desulfurization efficiency. The additives are classified into alkali additive and organic acid additive. Representative alkali additives include sodium carbonate (Na ₂ CO ₃ ), magnesium sulfate (MgSO ₄ ) and magnesium oxide (MgO). As the organic acid additive, adipic acid acid, and DiaBasic Acid (DBA).

The limestone sludge supply system described above operates simultaneously with the natural limestone feed system when the feed pumps 160a and 160b transfer limestone sludge into the ball mill 30 directly. In addition, when the feed pumps 160a and 160b transfer limestone sludge into the limestone day silo 20, they can be operated alternately with the natural limestone feed system, and all of these operations are transmitted to the central control room, Remote monitoring of flue gas desulfurization facilities.

As described above, the limestone sludge supply system for the flue gas desulfurization equipment according to the present invention can reduce the material cost by replacing the limestone sludge, which is the steel industry waste, in the desulfurization process in place of natural limestone, and the limestone sludge is mostly present in the form of a fine powder Thereby reducing power consumption, time and crushing cost in the wet ball mill and solving the problems caused by the burial of limestone sludge.

The foregoing description is merely illustrative of the technical idea of the present invention and various changes and modifications may be made without departing from the essential characteristics of the present invention by those skilled in the art. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents thereof should be construed as falling within the scope of the present invention.

Claims (10)

A natural limestone supply system including a limestone day silo, a wet ball mill, a mill-slurry tank, a classifier, a limestone slurry storage tank, a gas absorption unit that absorbs sulfur dioxide by limestone supplied from a natural limestone supply system, 1. A flue gas desulfurization system comprising an exhaust unit for exhausting a removed gas, a precipitate separator for separating precipitates generated in the gas absorption unit, and a waste treatment unit for treating the separated solid in the precipitate,
The flue gas desulfurization facility
Further comprising a limestone sludge supply system for supplying limestone sludge to the gas absorption unit.
The method according to claim 1,
The limestone sludge supply system
A transfer device for transferring the limestone sludge discharged from the dump feeder;
A pair of sludge hoppers for storing the transferred limestone sludge;
A pair of double screw conveyors for conveying limestone sludge discharged from each of the pair of sludge hoppers, respectively, into a corresponding one of a pair of induction mills;
A pair of induction mills for crushing or crushing the introduced limestone sludge;
And a pair of feed pumps for feeding the limestone sludge pulverized or shredded in a pair of induction mills to a wet ball mill or a limestone day silo, respectively.
3. The method of claim 2,
The transfer device
A belt conveyor for conveying the limestone sludge discharged from the dump feeder; And
And a normal conveyor for supplying the limestone sludge conveyed from the belt conveyor to the pair of sludge hoppers, respectively.
3. The method of claim 2,
Wherein the outlet of the sludge hopper has a double screw structure.
3. The method of claim 2,
Wherein the attraction mill is a screw type grinding equipment.
The method according to claim 1,
The limestone sludge supply system
Wherein the limestone sludge supply system operates simultaneously with the natural limestone supply system to supply limestone sludge to the gas absorption unit.
The method according to claim 1,
The limestone sludge supply system
Wherein the limestone sludge supply system operates alternately with the natural limestone supply system to supply limestone sludge to the gas absorption unit.
Introducing limestone sludge into a sludge hopper;
Transferring the limestone sludge discharged from the sludge hopper into an induction mill;
Crushing and pulverizing the limestone sludge in the attrition mill;
Transporting the ground, pulverized limestone sludge to a ball mill or a day silo of a natural limestone feed system; And
Further comprising milling the limestone sludge to the absorber when the limestone sludge is transported to the ball mill.
9. The method of claim 8,
When limestone sludge is transferred to a day silo,
Transporting the limestone sludge to a ball mill and further pulverizing the limestone sludge;
And transporting the further pulverized limestone sludge in the ball mill to the absorber. ≪ RTI ID = 0.0 > 18. < / RTI >
9. The method of claim 8,
Wherein the step of transferring the limestone sludge discharged from the sludge hopper to the induction mill further comprises the step of adding an additive for improving the desulfurization efficiency to the induction mill. Method of operating a supply system.

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