KR101185208B1 - Burner - Google Patents

Abstract

The present invention relates to a combustion device, and when the activated carbon adsorbed contaminants in the flue-gas of the sintering furnace is regenerated in a regeneration tower, SO ₂ is recovered and sulfuric acid is produced. By supplying the generated hydrogen to the burner, the amount of main fuel used in the burner is reduced, and the combustion efficiency is improved.

Description

Combustion apparatus {BURNER}

The present invention relates to a combustion apparatus, and more particularly, to an apparatus for generating hydrogen from a steel slag generated in an ironworks plant and burning it using the hydrogen.

In general, slag refers to a solvent, a non-metallic substance, a metal oxide, etc. that floats or remains on waste water when melting iron ore or scrap in a furnace, an electric furnace, a cupola, or the like.

The slag floats on the surface of the molten steel during melting of the raw material, thereby preventing the molten steel surface from being oxidized by air and preserving the surface thereof.

An object of the present invention is to provide a combustion apparatus that generates hydrogen in slag and uses the hydrogen as fuel.

The object of the present invention is a sealed slag storage unit for storing the slag generated during the steelmaking process;

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Sulfuric acid injection unit for injecting sulfuric acid to the slag stored in the slag storage unit;

Sulfuric acid supply unit for supplying sulfuric acid to the sulfuric acid injection unit;

A burner unit which receives and burns hydrogen generated from the slag storage unit;

A hydrogen supply unit connecting the burner unit and the slag storage unit to supply hydrogen to the burner unit;

It is solved by providing a combustion device including a fuel supply unit for supplying a main fuel to the burner unit.

The slag storage unit has an inlet and outlet for introducing and discharging the slag into the inside, and a door for opening and closing the inlet and outlet, and opening and closing the inlet and outlet by the operation of the door, characterized in that the door is closed when the inlet and outlet closes.

It characterized in that it further comprises a slag charging device for injecting slag into the slag storage unit through the inlet and outlet.

And a recovery part for recovering SO ₂ in a regeneration tower for regenerating activated carbon treated with flue gas of the sintering furnace, and a sulfuric acid production part for producing sulfuric acid using the SO ₂ recovered from the recovered water.

The sulfuric acid supply unit is a storage tank for storing sulfuric acid produced by the sulfuric acid manufacturing unit, a connecting pipe connecting the storage tank and the sulfuric acid spraying unit, a supply amount control valve mounted to the connecting pipe to control the supply amount of sulfuric acid; And a control device connected to the pressure sensor and the supply amount control valve and controlling the supply amount of sulfuric acid in response to the pressure value of the pressure sensor.

The fuel supply unit may include a fuel supply pipe for supplying the main fuel to the burner unit, and a fuel control valve mounted to the fuel supply pipe and controlling a supply amount of the main fuel.

The hydrogen supply unit may include a hydrogen supply pipe connecting the burner unit and the slag storage unit, and a hydrogen control valve mounted to the hydrogen supply pipe and controlling the supply amount of hydrogen.

The fuel supply unit includes a fuel supply pipe for supplying the main fuel to the burner unit, and a fuel control valve mounted to the fuel supply pipe and controlling a supply amount of the main fuel, wherein the hydrogen supply unit includes the burner unit and the slag storage unit. And a hydrogen supply valve connected to the hydrogen supply pipe, and a hydrogen control valve mounted on the hydrogen supply pipe and controlling the supply amount of hydrogen, wherein the fuel control valve and the hydrogen control valve are connected to the control device.

The control device receives the pressure in the slag storage unit in real time by the pressure sensor to control the amount of sulfuric acid supplied to the sulfuric acid injection unit, and transfers the amount of fuel supplied to the burner unit and the pressure in the slag storage unit. And control the amount of hydrogen supplied to the burner unit.

The present invention has the effect of lowering the pH in the slag by generating hydrogen using the slag to recycle the slag as a water treatment material.

In addition, the present invention is to improve the recycling rate of the waste sulfuric acid recovered in the sintering plant to solve the problem of environmental pollution and at the same time reduce the amount of fuel used in the existing combustion.

1 is a schematic view showing a combustion apparatus of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Hydrogen production method of the present invention is to produce hydrogen by reacting sulfuric acid to the slag (1) which is generated during the steelmaking process in the steel mill and then solidified and discarded.

As the sulfuric acid, it is preferable to use waste sulfuric acid recovered from activated carbon treated with exhaust gas of the sintering furnace.

The sintering furnace generates exhaust gas containing dioxins, SOx, NOx, etc. during the sintering process.

The exhaust gas is passed through an adsorption tower filled with activated carbon to remove contaminants such as dioxins, SOx, and NOx.

Activated carbon adsorbs and removes contaminants such as dioxins, SOx, and NOx. The activated carbon is transported to a regeneration tower after a certain period of time for regeneration and reuse.

The sulfuric acid is produced in the sulfuric acid production unit by using the recovered sulfuric acid to recover the SO ₂ contained in the activated carbon to the recovery unit when the activated carbon regeneration in the regeneration tower.

The sulfuric acid is not manufactured in high purity when the recovery rate of SOx is low because the SOx content of the exhaust gas is low or the desorption efficiency of activated carbon is low.

The present invention significantly reduces the production cost of hydrogen by producing hydrogen by reacting sulfuric acid treated with wastewater with slag 1 to be treated as described above, and produces little cost.

The slag (1) generated during the steelmaking process is present in a metal state of Fe, Mg, etc., in particular contains a large amount of CaO 30 to 45%, for example, as shown in Table 1 below.

ingredient T-FeO FeO M-Fe MnO TiO ₂ MgO CaO Al ₂ O ₃ SiO ₂ Content (wt%) 20 to 26 12 to 20 0.4 to 0.8 2.0 to 3.5 Greater than 0
To 1.0 3 to 5 30 to 45 1.5 to 6.5 10.2 to 16.5

The concentration of sulfuric acid is 50 to 98%, which is a volume percentage (percent concentration), which is a simple description that 50 mL to 98 mL of sulfuric acid is mixed with 100 mL of water and sulfuric acid in a mixed volume (percent concentration). It is a percentage concentration that indicates the amount of sulfuric acid containing.

The metal ions contained in the slag 1 react with sulfuric acid to generate hydrogen through the following reaction formula.

[Reaction Scheme]

Fe + H ₂ SO ₄ → FeSO 4 + H ₂

As described above, the metal ions included in the slag 1 have a high tendency to discard electrons, which is very reactive, and oxidizes well to generate a large amount of hydrogen.

Hydrogen as described above can reduce the consumption of the main fuel and improve the performance of the burner if it is added as auxiliary fuel in the combustion device.

The combustion apparatus of the present invention includes a sealed slag storage unit 10 for storing the slag 1 generated during the steelmaking process.

The slag storage unit 10 has an inlet and outlet 10a capable of introducing and discharging the slag 1 therein and a door 11 for opening and closing the inlet and outlet 10a.

In addition, the inlet and outlet 10a may be divided into an inlet and an outlet, and may be provided with a door 11 for opening and closing each, or may be provided with a door 11 for opening and closing one passage. .

The slag storage unit 10 opens and closes the entrance and exit 10a by the operation of the door 11 and is closed when the door 11 closes the entrance and exit 10a.

The present invention further includes a slag charging device (not shown) for introducing the slag 1 into the slag storage unit 10 through the inlet and outlet 10a, wherein the slag charging device includes the slag storage unit 10. An example is the use of a conveyor belt for transporting the slag 1 into it. In addition, it is noted that anything that can transfer the slag 1 into the slag storage unit 10 can be used.

Sulfuric acid is injected through the sulfuric acid injection unit 20 inside the slag storage unit 10.

The sulfuric acid spraying unit 20 includes a spraying header 21 disposed in the slag storage unit 10 and provided with a plurality of spraying nozzles 22, and the plurality of spraying nozzles 22 of the spraying header 21. It is preferable to evenly spray sulfuric acid on the slag (1) stored in the slag storage unit (10).

The present invention preferably further includes a recovery part for recovering SO ₂ in a regeneration tower for regenerating activated carbon treated with flue gas of the sintering furnace, and a sulfuric acid production part for producing sulfuric acid using the SO ₂ recovered from the recovered water. .

The sulfuric acid is manufactured by using SO ₂ recovered from activated carbon treated with flue gas of the sintering furnace, and the manufacturing cost is low.

The sulfuric acid is not produced in high purity when the recovery rate of SOx is low because the SOx content in the exhaust gas is low or the desorption efficiency of activated carbon is low.

The present invention includes a sulfuric acid supply unit 30 for supplying sulfuric acid to the sulfuric acid injection unit 20, the sulfuric acid supply unit 30 includes a storage tank 31 for storing sulfuric acid produced by the sulfuric acid manufacturing unit;

A connecting pipe (32) connecting the storage tank (31) and the sulfuric acid spraying unit (20);

Sulfuric acid control valve (33) mounted to the connecting pipe (32) to control the supply amount of sulfuric acid;

A pressure sensor (34) for measuring the pressure in the slag reservoir (10);

It is connected to the pressure sensor 34 and the sulfuric acid control valve 33 and receives a pressure value of the pressure sensor 34 includes a control device 35 for controlling the supply amount of sulfuric acid.

The control device 35 receives the pressure in the slag storage unit 10 in real time by the pressure sensor 34 to control the amount of sulfuric acid supplied to the sulfuric acid injection unit 20 to efficiently produce hydrogen. It is to make it.

In addition, the sulfuric acid supply unit 30 may further include a pump 36 mounted on the connection pipe 32 to supply sulfuric acid in the storage tank 31 to the sulfuric acid injection unit 20.

The sulfuric acid injection unit 20 receives sulfuric acid through the sulfuric acid supply unit 30 to inject sulfuric acid into the slag 1 in the slag storage unit 10.

When the slag 1 is reacted with sulfuric acid supplied by the sulfuric acid injection unit 20, hydrogen is generated as in the reaction scheme.

The hydrogen is supplied to the burner unit 40 by the hydrogen supply unit 50.

The burner unit 40 receives the main fuel from the hydrogen supply unit 50 and the fuel supply unit 60 to combust it.

The fuel supply unit 60 supplies a main fuel such as LNG and COG to the burner unit 40, and a fuel supply pipe 61 to supply the main fuel to the burner unit 40;

It is mounted to the fuel supply pipe 61 and includes a fuel control valve 62 for controlling the supply amount of the main fuel.

The hydrogen supply unit 50 includes a hydrogen supply pipe 51 connecting the burner unit 40 and the slag storage unit 10;

It is mounted to the hydrogen supply pipe 51 and includes a hydrogen control valve 52 for controlling the supply amount of hydrogen.

The fuel control valve 62 and the hydrogen control valve 52 are connected to the control device 35, the control device 35 is the amount of fuel supplied to the burner unit 40, the slag storage unit It is preferable to control the supply amount of hydrogen supplied to the burner part 40 by receiving the pressure in 10.

According to the present invention, hydrogen may be supplied to the burner unit 40 combusted with the main fuel to reduce the consumption amount of the main fuel and increase combustion efficiency.

According to the present invention, hydrogen is generated at almost no manufacturing cost, and the fuel consumption of the main combustion used in the burner unit 40 can be reduced by using the hydrogen to reduce the cost of combustion.

The present invention is not limited to the above-described embodiments, and various changes can be made without departing from the gist of the present invention, which is understood to be included in the configuration of the present invention.

10: slag storage unit 11: the door
20 sulfuric acid injection unit 30 sulfuric acid supply unit
40: burner part 50: hydrogen supply part
60: fuel supply unit 70: recovery unit
80 sulfuric acid manufacturing unit

Claims (11)

delete delete A sealed slag storage unit for storing slag generated during the steelmaking process;
Sulfuric acid injection unit for injecting sulfuric acid to the slag stored in the slag storage unit;
Sulfuric acid supply unit for supplying sulfuric acid to the sulfuric acid injection unit;
A burner unit which receives and burns hydrogen generated from the slag storage unit;
A hydrogen supply unit connecting the burner unit and the slag storage unit to supply hydrogen to the burner unit;
Combustion apparatus comprising a fuel supply for supplying a main fuel to the burner. The method according to claim 3,
The slag storage unit has an inlet and outlet for introducing and discharging the slag into the inside, and a door for opening and closing the inlet and outlet, opening and closing the inlet and outlet by the operation of the door, characterized in that the door is closed when the inlet and outlet is closed Combustion device. The method of claim 4,
Combustion apparatus further comprises a slag charging device for injecting slag into the slag storage through the inlet and outlet. The method according to claim 3,
A recovery unit for recovering SO ₂ in a regeneration tower for regenerating activated carbon treated with exhaust gas of the sintering furnace;
Combustion apparatus further comprises a sulfuric acid production unit for producing sulfuric acid by using the SO ₂ recovered from the collected water. The method of claim 6,
The sulfuric acid supply unit and the storage tank for storing the sulfuric acid produced in the sulfuric acid production unit;
A connecting pipe connecting the storage tank and the sulfuric acid spraying unit;
A supply amount control valve mounted to the connection pipe to control a supply amount of sulfuric acid;
A pressure sensor for measuring the pressure in the slag reservoir;
And a control device connected to the pressure sensor and the supply amount control valve to control the supply amount of sulfuric acid in response to the pressure value of the pressure sensor. The method according to claim 3,
The fuel supply unit,
A fuel supply pipe for supplying the main fuel to the burner;
And a fuel control valve mounted to the fuel supply pipe and controlling a supply amount of the main fuel. The method according to claim 3,
The hydrogen supply unit,
A hydrogen supply pipe connecting the burner part and the slag storage part;
And a hydrogen control valve mounted to the hydrogen supply pipe and controlling the supply amount of hydrogen. The method of claim 7,
A fuel supply pipe for supplying the main fuel to the burner;
A fuel control valve mounted to the fuel supply pipe and controlling a supply amount of the main fuel;
The hydrogen supply unit connects the burner unit with the slag storage unit;
A hydrogen control valve mounted to the hydrogen supply pipe and controlling the supply amount of hydrogen;
The fuel control valve and the hydrogen control valve are connected to the control device. The method of claim 7,
The control device receives the pressure in the slag storage unit in real time by the pressure sensor to control the amount of sulfuric acid supplied to the sulfuric acid injection unit,
And a quantity of fuel supplied to the burner unit and a pressure in the slag storage unit to control the amount of hydrogen supplied to the burner unit.

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