KR20190109062A - Hot blast stove system - Google Patents

Abstract

A hot blast furnace system comprises: a hot blast furnace for supplying hot blast to a furnace; a mixed gas pipe connected to the hot blast furnace and having a mixed gas mixed with blast furnace gas (BFG) and coke oven gas (COG); a hydrogen concentration analysis unit connected to the mix gas pipe and analyzing a hydrogen concentration of the mix gas; and a combustion control part connected to the hydrogen concentration analysis unit to stop a combustion of the hot blast furnace when the hydrogen concentration of the mix gas exceeds a set concentration. Therefore, the present invention is capable of preventing an explosion accident at the start of combustion.

Description

Hot stove system {HOT BLAST STOVE SYSTEM}

The present disclosure relates to a hot stove system.

In general, a hot stove system burns a mixed gas of blast furnace gas (BFG) and coke oven gas (COG) in a hot stove, and supplies the hot air using the heat to a blast furnace. to be.

The conventional hot stove system has a problem that an explosion accident occurs at the beginning of combustion as the ratio of coke gas to the mix gas through the mix gas pipe connected to the hot stove increases.

One embodiment is to provide a hot stove system that prevents an explosion accident at the start of combustion.

One side is a hot blast furnace for supplying hot blast to the blast furnace, and is connected to the hot blast furnace, the mixed gas pipe through which the mixed gas blast furnace gas (BFG) and coke gas (COG) is mixed, connected to the mix gas pipe, A hot stove comprising a hydrogen concentration analyzing unit for analyzing the hydrogen concentration of the mix gas, and a combustion control unit connected to the hydrogen concentration analyzing unit and stopping the combustion of the hot stove when the hydrogen concentration of the mix gas exceeds a set concentration. Provide a system.

The hydrogen concentration analyzing unit is connected to a water removing unit for removing moisture of the mix gas supplied from the mix gas pipe, the water removing unit, a cooling unit for cooling the mix gas, and the cooling unit. A hydrogen analyzer may be configured to analyze the hydrogen concentration of the mix gas.

The blast furnace is connected between the blast furnace gas and the mix gas pipe, the blast furnace gas pipe through which the blast furnace gas passes, and the coke gas pipe connected with the mix gas pipe, the coke gas may further include.

The coke gas pipe may include a water seal valve adjacent to the mix gas pipe.

It may further include a combustion air pipe connected to the hot stove, through which combustion air passes.

It may further include a purge unit connected to the mix gas pipe and purging the mix gas pipe.

It may further include a combustion air valve and a combustion air control valve connected to the combustion air pipe, a mix gas valve connected to the mix gas pipe, a mix gas control valve, and a mix gas shutoff valve, and a purge valve connected to the purge part. .

The combustion control unit may control the combustion air valve, the combustion air control valve, the mix gas valve, the mix gas control valve, the mix gas shutoff valve, and the purge valve.

According to one embodiment, a hot stove system is provided that prevents an explosion accident at the beginning of combustion.

1 is a view showing a hot stove system according to an embodiment.
2 is a view showing a hydrogen concentration analysis unit shown in FIG.
3 is a view illustrating a hot stove, pipes, valves, a hydrogen concentration analyzing unit, and a combustion control unit of the hot stove system according to one embodiment.
4 is a flowchart illustrating a combustion control method of the combustion control unit illustrated in FIG. 3.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and like reference numerals designate like elements throughout the specification.

In addition, throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding the other components unless otherwise stated.

Hereinafter, a hot stove system according to an embodiment will be described with reference to FIGS. 1 to 4.

1 is a view showing a hot stove system according to an embodiment.

Referring to FIG. 1, the hot stove system 1000 according to an embodiment is connected to the blast furnace 10. The hot stove system 1000 burns a mixed gas in which blast furnace gas (BFG) supplied from the blast furnace 10 and coke gas (COG) supplied from the coke gas supply unit 401 are mixed to hot air (Hot) in the blast furnace 10. Blast).

The hot stove system 1000 includes a hot stove 100, a mixed gas pipe 200, a blast furnace gas pipe 300, a coke gas pipe 400, a coke gas supply part 401, a combustion air pipe 500, and combustion air. The supply part 501, the blowing pipe 600, the blowing supply part 601, the hot air piping 700, the hydrogen concentration analysis unit 800, and the combustion control part 900 is included.

The hot stove 100 may include a combustion chamber for combusting a mixed gas in which blast furnace gas (BFG) and coke gas (COG) are mixed with combustion air and a heat storage chamber for storing the heat. The hot stove 100 burns the mix gas using combustion air, heats the cold blast to the hot blast, and supplies the hot blast to the blast furnace 10 using the heat. It can have a variety of structures.

The hot stove 100 is connected to the mix gas pipe 200, the combustion air pipe 500, the blower pipe 600, and the hot air pipe 700. The hot stove 100 burns the mixed gas supplied through the mix gas pipe 200 using the combustion air supplied through the combustion air pipe 500, and blows the air supplied through the blower pipe 600 using the heat. (Cold Blast) is heated by hot air (Hot Blast), hot air (Hot Blast) is supplied to the blast furnace 10 through the hot air pipe (700).

The hot stove 100 may include a plurality of hot stoves 100 connected to one blast furnace 10. For example, four hot stoves 100 may be connected to one blast furnace 10, but not limited to three hot stoves 100 or five or more hot stoves 100 in one blast furnace ( 10).

The mix gas pipe 200 is connected to the hot stove 100. The mixed gas pipe 200 passes through a mixed gas in which blast furnace gas BFG and coke gas COG are mixed. The mixed gas pipe 200 is connected to the blast furnace gas pipe 300 and the coke gas pipe 400 to supply a mixed gas in which the blast furnace gas (BFG) and the coke gas (COG) are mixed to the hot stove 100. The mix gas pipe 200 may include a chamber in which blast furnace gas BFG and coke gas COG are mixed.

The blast furnace gas pipe 300 connects between the mix gas pipe 200 and the blast furnace 10. Blast furnace gas (BFG) flows through the blast furnace gas piping (300).

Part of the blast furnace gas (BFG) generated in the blast furnace 10 is supplied as a mixed gas to the hot stove 100 through the blast furnace gas pipe 300 and the rest is stored in the gas holder (Gas Holder) to be used for other purposes Can be.

The coke gas pipe 400 is connected to the mix gas pipe 200. The coke gas supply unit 401 is connected to the coke gas pipe 400. Coke gas COG supplied from the coke gas supply part 401 flows through the coke gas piping 400.

The coke gas supply unit 401 is connected to the coke gas pipe 400. The coke gas supply unit 401 supplies the coke gas COG to the coke gas pipe 400.

Coke gas (COG) is 4 times higher than the blast furnace gas (BFG) is supplied from the coke gas supply unit 401 to the mix gas pipe 200 through the coke gas pipe 400, the blast furnace gas so that the set calories Mixed with (BFG). The mixed mix gas is supplied to the hot stove 100 through the mix gas pipe 200.

The combustion air pipe 500 is connected to the hot stove 100. Combustion air passes through the combustion air pipe 500. The combustion air pipe 500 is connected to the combustion air supply unit 501.

The combustion air supply unit 501 is connected to the combustion air pipe 500. The combustion air supply unit 501 supplies combustion air to the combustion air pipe 500.

Atmospheric air sucked from the combustion air supply unit 501 is supplied as combustion air to the combustion air pipe 500 and used for combustion of the mixed gas in the combustion chamber of the hot stove 100. As a result, high-heated gas passes through the heat storage chamber of the hot stove 100 and preheats the heat storage smoke and exhaust gas may be discharged to the chimney.

The blower pipe 600 is connected to the hot stove 100. Blowing air (Cold Blast) is passed through the blowing pipe (600). The blowing pipe 600 is connected to the blowing supply unit 601.

The blowing air supply unit 601 is connected to the blowing pipe 600. The blowing air supply unit 601 supplies a blowing air to the blowing pipe 600. In one example, the blowing (Cold Blast) may be 160 ℃, but is not limited thereto.

The hot air pipe 700 connects between the hot air furnace 100 and the blast furnace 10. The hot wind pipe (Hot Blast) discharged from the hot stove 100 passes through the hot air pipe (700), and the hot wind (Hot Blast) is supplied to the blast furnace (10). Elo, hot blast (Hot Blast) may be 1100 ℃, but is not limited thereto.

When the set time elapses after the start of the combustion process of the hot stove 100, the combustion process is terminated. The hot blast of about 1300 ° C. is blown while the cold blast supplied from the blower supply unit 601 to the hot blast furnace 100 through the blow duct 600 passes through the heat storage chamber of the hot blast furnace 100. Then, it is supplied to the air vent of the blast furnace 10 through the hot air pipe 700. The hot blast (Hot Blast) melts the iron ore of the blast furnace (10) to make the molten water, and the blast furnace gas (BFG) is generated by the reduction action with the iron ore.

The hydrogen concentration analysis unit 800 is connected to the mix gas pipe 200. The hydrogen concentration analysis unit 800 analyzes the hydrogen concentration of the mix gas through the mix gas pipe 200. The hydrogen concentration analyzing unit 800 removes the moisture of the mix gas through the mix gas pipe 200 and cools the mix gas, and then analyzes the hydrogen concentration of the mix gas.

2 is a view showing a hydrogen concentration analysis unit shown in FIG.

2, the hydrogen concentration analysis unit 800 is connected to the mix gas pipe 200 to analyze the hydrogen concentration of the mix gas through the mix gas pipe 200, and analyzes the hydrogen concentration of the analyzed mix gas in the combustion control unit. Forward to 900.

The hydrogen concentration analyzing unit 800 includes a water removing unit 810, a collected water removing unit 820, a cooling unit 830, a sampling unit 840, and a hydrogen analysis unit 850.

The water removing unit 810 is connected to the mix gas pipe 200. The water removing unit 810 removes water from the mix gas supplied from the mix gas pipe 200.

The collected water remover 820 is connected to the water remover 810. The collected water removing unit 820 stores and removes moisture of the mixed gas discharged from the water removing unit 810.

The mixed gas introduced from the mixed gas pipe 200 to the water removing unit 810 is very large than the area of the pipe connected to the water removing unit 810 because the area of the water removing unit 810 is slow, and thus the mixed gas becomes slow. The moisture contained in it will sink to the bottom. The mixed gas cooling tube 811 through which the cooling gas flows is installed inside the water removing unit 810. The mix gas passing through the water removing unit 810 is rapidly cooled by the mix gas cooling tube 811, and the water contained in the mix gas is made of water and removed by the collected water removing unit 820.

The mixed gas cooling tube 811 located in the water removing unit 810 may be a pipe wound at least 18 times in the water removing unit 810, and cooling gas may pass through the pipe.

The temperature of the mixed gas passing through the water removing unit 810 may be 60 ° C. or less.

The cooling unit 830 is connected to the water removing unit 810. The cooling unit 830 cools the mixed gas from which the water supplied from the water removing unit 810 is removed.

The mixed gas from which the water passing through the water removing unit 810 is removed is cooled by the cooling water of the cooling unit 830 while passing through the cooling unit 830 to be lowered to a temperature of 35 ° C. or lower, and then flows into the sampling unit 840. Can be.

The sampling unit 840 is connected to the cooling unit 830. The sampling unit 840 removes the moisture supplied from the cooling unit 830 and treats the cooled mixed gas as a sampling gas and supplies the mixed gas to the hydrogen analyzer 850. The sampling unit 840 may have a variety of known structures as long as it can process the mixed gas into the sampling gas and supply the mixed gas to the hydrogen analyzer 850.

The hydrogen analyzer 850 is connected to the cooling unit 830 through the sampling unit 840. The hydrogen analyzer 850 analyzes the hydrogen concentration of the mixed gas, which is the sampling gas passed from the cooling unit 830 to the sampling unit 840. The hydrogen analyzer 850 may have a variety of known structures as long as the hydrogen analyzer 850 can analyze the hydrogen concentration contained in the mix gas.

The hydrogen concentration analysis unit 800 dehumidifies and cools the mix gas from the mix gas pipe 200 through a water removal unit 810 and a cooling unit 830 to a gas that can be analyzed, and then supplies it to the sampling unit 840. In addition, the mixed gas passed through the sampling unit 840 may be configured to measure the hydrogen concentration in the hydrogen analyzer 850.

Mixing gas flowing into the hydrogen concentration analysis unit 800 from the mix gas pipe 200 at the initial stage of combustion of the hot stove 100 is humidified at a high temperature of 100 ° C. or higher and directly supplied to the hydrogen analyzer 850 to cause a hydrogen analysis failure. Can be. However, while the mixed gas supplied from the mix gas pipe 200 to the hydrogen analyzer 850 passes through the water removing unit 810 and the cooling unit 830, the temperature is lowered to 35 ° C. or less, and the moisture is sampled 840. ) To a level that can be processed.

That is, the hot and humid mix gas supplied from the mix gas pipe 200 is dried at a low temperature while passing through the water removing unit 810 and the cooling unit 830, thereby facilitating the hydrogen concentration of the mix gas in the hydrogen analyzer 850. Is analyzed.

The hydrogen concentration of the mixed gas analyzed by the hydrogen analyzer 850 is transmitted to the combustion controller 900.

Again, referring to FIG. 1, the combustion control unit 900 is connected to components constituting the hydrogen concentration analysis unit 800 and the hot stove system 1000. The combustion controller 900 may control valves connected to the hot stove 100 and the pipes included in the hot stove system 1000.

The combustion control unit 900 may stop the combustion of the hot stove 100 when the hydrogen concentration of the mix gas passing through the mix gas pipe 200 analyzed by the hydrogen concentration analysis unit 800 exceeds a set concentration. For example, the combustion controller 900 may stop combustion of the hot stove 100 when the hydrogen concentration of the mixed gas is 4% or more. The combustion control unit 900 may stop the combustion of the hot stove 100 by controlling the valves connected to the pipes.

3 is a view illustrating a hot stove, pipes, valves, a hydrogen concentration analyzing unit, and a combustion control unit of the hot stove system according to one embodiment.

Referring to FIG. 3, the hot stove system 1000 includes a hot stove 100, a mixed gas pipe 200, a blast furnace gas pipe 300, a coke gas pipe 400, a combustion air pipe 500, and a hydrogen concentration analysis. Unit 800, combustion control unit 900, water seal valve (WV), purge unit (PP), combustion air valve (BAV), combustion air control valve (ACV), mix gas valve (BGV), mix gas control valve ( GCV), mix gas shutoff valve (GIV), purge valve (GPV).

There are a plurality of water sealing valves WV, and the plurality of water sealing valves WV are optionally included in the blast furnace gas pipe 300 and the coke gas pipe 400. There are a plurality of water seal valves WV included in the coke gas pipe 400, and one of the water seal valves WV is adjacent to the mix gas pipe 200.

The purge part PP is connected to the mix gas pipe 200 and other pipes, and purges the mix gas pipe 200 and the other pipes. The purge part PP may purge using nitrogen gas N ₂ and steam.

The combustion air valve BAV and the combustion air regulating valve ACV are connected to the combustion air piping 500. The combustion air valve BAV may be positioned between the combustion air control valve ACV and the hot stove 100, but the position of each valve is not limited thereto.

The mix gas valve BGV, the mix gas control valve GCV, and the mix gas shutoff valve GIV are connected to the mix gas line 200. The mix gas valve (BGV) is located between the mix gas shutoff valve (GIV) and the hot stove 100, and the mix gas shutoff valve (GIV) is located between the mix gas valve (BGV) and the mix gas control valve (GCV). However, the position of each valve is not limited thereto.

The purge valve GPV is connected to the purge part PP. The purge valve GPV may adjust the purge of the mix gas pipe 200 by the purge part PP.

Combustion control unit 900 is a combustion air valve (BAV), combustion air control valve (ACV), mix gas valve (BGV), mix gas control valve (GCV), mix gas shutoff valve (GIV), purge valve (GPV) respectively You can control the open and close of.

For example, if a periodic repair work occurs once a month in the blast furnace because the blast furnace related equipment is stopped for at least 6 hours to 24 hours, the blowing process is stopped by blocking the hot air of hot air supplied from the hot blast furnace 100. As such, since the combustion of the hot stove 100 is no longer necessary, the combustion air pipe 500 and the mix gas pipe 200 are also blocked to stop the combustion process.

The combustion stop closes the combustion air valve (BAV) connected to the combustion air pipe (500), closes the water seal valves (WVs) of the coke gas pipe (400), and shuts off the mix gas valve connected to the mix gas pipe (200). (BGV) and mix gas shutoff valves (GIV) may be closed.

Periodic repair work of the blast furnace usually proceeds from about 6 hours to 24 hours, in special cases 48 hours to 72 hours, nitrogen gas or steam supplied to the pipes for purging the pipes of the hot stove system 1000, etc. The internal pressure of the mix gas piping 200 is raised by this. By this pressure, the one-sealing valve WV1 of the coke gas pipe 400 adjacent to the mixed gas pipe 200 may be released, or the water-sealed water of the one-sealed valve WV1 may be released as the management member after the water is released.

The columnar facilities that treat wastewater from the blast furnace before the blast furnace repair is completed should be refrigerated and dried, and must be supplied with coke gas (COG) in advance to be used for drying and preheating for maintenance work. To this end, coke gas (COG) is supplied to the columnar facilities through the coke gas pipe 400.

When the coke gas COG is supplied to the columnar facilities, when the water sealing valve WV1 of the coke gas pipe 400 adjacent to the mix gas pipe 200 is in the unsealed state, the coke gas COG is mixed gas. In the pipe 200, if the coke gas COG introduced into the mix gas pipe 200 is not removed before the combustion command signal is generated, an explosion accident may occur according to the concentration of the coke gas COG.

Looking at the mixed gas explosion, blast furnace gas (BFG) sikineunde complete combustion of the combustion air required 1Nm ³ 0.64Nm ³ and sikineunde complete combustion of coke oven gas (COG) 1Nm ³ is the combustion air need 4.24Nm ^3.

Since the coke gas (COG) is blocked at the start of the initial combustion process and combustion of the hot stove 100 is performed only by the blast furnace gas (BFG), the required combustion air is initially set to 0.64 times that of the blast furnace gas (BFG). At this time, if the coke gas (COG) is filled in the mixed gas pipe 200, the amount of combustion air is very insufficient and incomplete combustion is made. In addition, the combustion rate of the hydrogen component, which accounts for 55% to 56% of the COG component, is 20 times faster than the carbon monoxide component, which is a combustible gas contained in the blast furnace gas (BFG), which is very insufficient compared to the amount of COG. When combustion of the hot stove 100 starts with combustion air, there is a high risk of explosion.

In the initial combustion process, if the hydrogen concentration of the mixed gas through the mix gas pipe 200 is 4% or more, it is determined that coke gas (COG) is introduced, and the combustion process of the hot stove 100 should be stopped to prevent explosion. .

The reason why the hydrogen concentration of the mix gas should be measured is that the hydrogen content in the blast furnace gas (BFG) is 3% and the hydrogen content in the coke gas (COG) is about 55%, so if the hydrogen concentration of the mix gas is 4% or more, In the initial combustion process, it may be determined that coke gas (COG) is introduced into the mix gas pipe 200.

As described above, in the hot stove system 1000, the hydrogen concentration of the mix gas passing through the mix gas pipe 200 analyzed by the hydrogen concentration analysis unit 800 by the combustion control unit 900 exceeds a set concentration. By stopping the combustion of the hot stove 100, an explosion accident of the hot stove 100 is prevented at the beginning of combustion.

Hereinafter, an example of the combustion control method of the combustion control unit 900 will be described with reference to FIG. 4.

4 is a flowchart illustrating a combustion control method of the combustion control unit illustrated in FIG. 3.

The combustion control unit 900 determines the initial combustion state when the combustion command is generated, and starts the combustion process if it is not the initial combustion.

The combustion control unit 900 generates an initial combustion process start signal when the initial combustion state is performed. The combustion control unit 900 opens the combustion air valve (BAV), opens the combustion air control valve (ACV) and also opens the combustion air to inject combustion air, and if the combustion air flow rate is lower than the set value until 50 seconds have elapsed, the combustion of the corresponding hot blast furnace. If the combustion air flow rate is higher than the Low setting value, open the Mix Gas Control Valve (GCV) when the mix gas shutoff valve (GIV) open signal is input. If it is, the combustion gas control valve (GCV) automatic control is performed while the combustion air control valve (ACV) automatic control is performed to start combustion control.

When the combustion air valve BAV is opened, the combustion control unit 900 purges the pipes by the purge valve GPV operation, opens the mix gas valve BGV, and inputs an open signal to the end gate AND.

When the initial combustion process start signal is generated, the combustion control unit 900 performs a sequence operation separately from the above to command the analysis of the hydrogen concentration analysis unit, and after a predetermined time, the hydrogen concentration of the mixed gas is substantially 4%. If the value is less than the β value, the mix gas valve (BGV) open signal and the end gate are satisfied to generate the mix gas shutoff valve (GIV) open signal to perform combustion of a normal hot stove. On the contrary, the combustion control unit 900 generates a hot blast combustion stop processing signal when the hydrogen concentration of the mix gas is larger than β value of 4% substantially to prevent the explosion before the combustion starts.

As described above, the hot stove system 1000 for preventing the explosion of the hot stove 100 at the beginning of combustion is provided.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Hot stove 100, mix gas pipe 200, hydrogen concentration analysis unit 800, combustion control unit 900

Claims (8)

Hot air furnace for supplying hot air to the blast furnace;
A mix gas pipe connected to the hot stove and having a mixed gas mixed with blast furnace gas (BFG) and coke gas (COG);
A hydrogen concentration analyzing unit connected to the mix gas pipe and analyzing the hydrogen concentration of the mix gas; And
A combustion control unit connected to the hydrogen concentration analysis unit to stop combustion of the hot stove when the hydrogen concentration of the mix gas exceeds a set concentration;
Hot stove system comprising a. In claim 1,
The hydrogen concentration analysis unit,
A water removal unit for removing water of the mix gas supplied from the mix gas pipe;
A cooling unit connected to the water removing unit and cooling the mix gas; And
A hydrogen analyzer connected to the cooling unit and analyzing the hydrogen concentration of the mix gas
Hot stove system comprising a. In claim 1,
A blast furnace gas pipe connecting between the blast furnace and the mix gas pipe and communicating with the blast furnace gas; And
Coke gas pipe connected to the mix gas pipe, the coke gas flows
Hot stove system comprising more. In claim 3,
The coke gas pipe is a hot stove system including a water seal valve adjacent to the mix gas pipe. In claim 3,
And a combustion air pipe connected to the hot stove and through which combustion air passes. In claim 5,
And a purge unit connected to the mix gas pipe and purging the mix gas pipe. In claim 6,
A combustion air valve and a combustion air regulating valve connected to the combustion air pipe;
A mix gas valve, a mix gas control valve, and a mix gas shutoff valve connected to the mix gas pipe; And
A purge valve connected to the purge part
Hot stove system comprising more. In claim 7,
And the combustion control unit controls the combustion air valve, the combustion air control valve, the mix gas valve, the mix gas control valve, the mix gas shutoff valve, and the purge valve.

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