KR101352011B1 - Composite structured hot blast furnace using internal combustion - Google Patents

Abstract

The present invention relates to a multi-segment internal combustion-type hot-blast furnace of a composite structure, and is characterized by comprising; a main body unit formed in a barrel shape; and a division unit installed in an up and down direction inside the main body unit to divide an interior space into a plurality; and a plurality of hot-blast units divided into a plurality by the division unit inside the main body unit to sequentially supply hot blast to a blast furnace. Therefore, by being provided with a plurality of hot-blast units with division into a plurality of an interior space of the main body unit to sequential supply hot blast to a blast furnace, the present invention not only reduces an installation area for the hot-blast furnace, but also shortens a separation distance from the blast furnace to provide an effect of preventing heat losses of the hot-blast.

Description

Composite structured hot blast furnace using internal combustion

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-segment internal combustion hot stove of a composite structure, and more particularly, to a multi-segment internal combustion hot stove of a composite structure in which hot combustion gas is accumulated to supply hot air to the blast furnace.

Generally, steel mills are equipped with hot air ducts for supplying hot air at the time of blast furnace operation. Such a hot blast furnace is a facility for producing high temperature hot blast to reduce iron ore by burning coke inside the blast furnace that produces pig iron. The hot blast furnace burns through a burner supplied with fuel gas and air, and heat generated during the combustion process. It comprises a heat storage chamber for storing.

Combustion gas moving from the combustion chamber to the heat storage chamber is discharged to the outside through the communication, and a hot stove is installed in the heat storage chamber so as to supply heat to the blast furnace to supply hot air of about 1250 ℃.

In addition, the hot air furnace is divided into an internal combustion type and an external combustion type depending on the position of the combustion chamber, and a dome combustion type. Particularly, the internal combustion type hot air furnace has a cylindrical structure and is configured to divide the combustion chamber and the heat storage chamber.

As such a hot stove, a combustion chamber and a heat storage chamber are paired, and two to four hot stoves are provided, respectively. Each hot stove repeats the combustion stage and the blowing stage at regular intervals to supply hot wind to the blast furnace. .

FIG. 8 is a configuration diagram showing a conventional hot stove. As shown in FIG. 8, four hot stoves 11, 12, 13, and 14 are provided in parallel as the hot stove 10, and the blast furnace 20 is shown in FIG. 8. Between them, control valves 11a, 12b, 13a, and 14a for controlling communication with the respective hot stoves 11, 12, 13, and 14 are provided.

However, such a conventional hot stove has a problem that the installation of refractory softening is complicated when the heat storage chamber is installed, and heat loss occurs at the upper dome.

In addition, the distance between the hot blast furnace 10 and the blast furnace 20 has a problem that the heat loss occurs during the blowing of the hot wind is not supplied with hot air of a constant temperature, the working efficiency of the blast furnace is also reduced.

In addition, the conventional hot stove has a problem that the outer wall of the heat storage chamber is exposed to the outside, the heat storage efficiency of the combustion gas is lowered and further inflow of fuel gas is inevitable, so that the combustion cost of the combustion chamber increases.

The present invention has been made in order to solve the above-mentioned conventional problems, it is possible to reduce the installation area of the hot blast furnace and at the same time shorten the distance between the blast furnace to prevent heat loss of the hot blast, hot air at a constant temperature in the blast furnace It can be continuously supplied to improve the working efficiency of the blast furnace, and a plurality of hot air can be supplied to the blast furnace sequentially by alternating the combustion step, the blowing step and the preliminary step, and the heat blast is compactly configured to heat loss in the combustion chamber In addition, it is possible to improve the heat storage efficiency of the heat storage chamber, to reduce the generation of impurities during combustion of the burner, to prevent environmental pollution, to facilitate the introduction of fuel gas and combustion air, and to discharge the hot air. It facilitates the discharge of waste gas in the combustion stage and facilitates the introduction of low temperature hot air in the blowing stage. To reduce the operating cost by blocking the heat loss to the outside of the heat storage chamber to improve the heat efficiency of the hot stove, and to reduce the investment cost by reducing the amount of checker refractory in the heat storage chamber. It is for that purpose.

The present invention for achieving the above object, the main body portion formed in a cylindrical shape; A division unit installed in the main body part in a vertical direction to divide an internal space into a plurality; And a plurality of hot air parts which are divided into a plurality of parts by the dividing part inside the main body part and sequentially supply hot air to the blast furnace.

The hot air portion of the present invention is divided by the dividing portion with reference to a central rod provided up and down in the center of the inner space of the main body portion. The hot air portion of the present invention comprises a first hot air portion, a second hot air portion, and a third hot air portion divided by the dividing portion, and the first hot air portion, the second hot air portion, and the third hot air portion are burned. The hot air is sequentially supplied to the blast furnace by alternating the steps, the blowing step and the preliminary step.

The hot air of the present invention, the burner is installed in the lower burner combustion chamber; A heat storage chamber in which the flue gas combusted in the combustion chamber is thermally stored; And a separating wall curved inwardly from an inner circumferential surface of the main body to separate the combustion chamber and the heat storage chamber and having upper portions communicating with each other. The burner of the said combustion chamber of this invention consists of a ceramic burner.

In the combustion chamber of the present invention, the gas inlet is connected to the lower portion of the burner and the inlet gas into which the by-product gas of the blast furnace flows in and the air inlet through which the combustion air is introduced, and the hot wind outlet connected to the upper part of the burner to supply hot air to the blast furnace. It is provided.

The heat storage chamber of the present invention is provided with a waste gas outlet connected to one side of the lower side to discharge waste gas, and a low temperature hot wind inlet connected to the other side of the lower side to introduce low temperature hot air.

The combustion chamber of the present invention is formed outside the main body portion with respect to the separation wall, and the heat storage chamber is formed inside the main body portion with reference to the separation wall.

As described above, the present invention divides the internal space of one main body into a plurality of parts and includes a plurality of hot air portions and sequentially supplies hot air to the blast furnace, thereby reducing the installation area of the hot air furnace and reducing the distance between the blast furnace and the blast furnace. It provides an effect that can prevent the heat loss of the hot air.

By splitting the hot air evenly on the basis of the center rod in the inner space of the main body, it is possible to continuously supply hot air of a predetermined temperature to the blast furnace to improve the working efficiency of the blast furnace.

Since the hot air is divided equally into three, it is possible to sequentially supply the hot air to the blast furnace by alternating the combustion step, the blowing step and the preliminary step.

Since the hot air portion is composed of a combustion chamber, a heat storage chamber, and a separating wall separating them, the hot air portion can be compactly configured to minimize heat loss of the combustion chamber and improve heat storage efficiency of the heat storage chamber.

It is possible to minimize the heat loss of the combustion chamber and to improve the heat storage efficiency of the heat storage chamber by compactly configuring the hot air chamber.

By constructing the burner of the combustion chamber with a ceramic burner, it is possible to reduce the generation of impurities during combustion of the burner to prevent environmental pollution.

By installing a hot air outlet at the top of the burner in the combustion chamber and a gas inlet and an air inlet at the bottom of the burner, it facilitates the introduction of fuel gas and combustion air and at the same time facilitates the discharge of hot air.

By forming a waste gas outlet in one lower portion of the heat storage chamber and forming a low temperature hot air inlet in the lower portion of the heat storage chamber, the waste gas may be easily discharged in the combustion step, and the low temperature hot air may be easily introduced in the blowing step.

In the hot air part, a combustion chamber is formed on the outside based on the partition wall, and a heat storage chamber is formed on the inside, thereby reducing heat loss to the outside of the heat storage chamber to improve thermal efficiency of the hot air furnace, thereby reducing operating costs, and It provides the effect of reducing the investment volume by reducing the quantity.

1 is a block diagram showing a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.
Figure 2 is a plan sectional view showing a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.
Figure 3 is a cross-sectional view showing a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.
Figure 4 is a block diagram showing a combustion step of a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.
Figure 5 is a cross-sectional view showing a combustion step of a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.
Figure 6 is a block diagram showing a blowing step of a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.
7 is a cross-sectional view showing a blowing step of a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.
8 is a configuration diagram showing a conventional hot stove.

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

1 is a block diagram showing a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention. 3 is a stepped sectional view showing a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention, and FIG. 4 is a combustion of a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention. 5 is a cross-sectional view showing a combustion step of a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention, and FIG. 6 is a multi-section of the composite structure according to an embodiment of the present invention. FIG. 7 is a sectional view showing a blowing step of a multi-segment internal combustion hot stove of a composite structure according to an embodiment of the present invention.

As shown in FIGS. 1 to 3, the multi-segment internal combustion hot air furnace of the composite structure according to the present embodiment includes a main body portion 100, a division portion 200, and a hot air portion 300. It is a multi-segment internal combustion type hot stove that supplies continuously.

The main body 100 is a storage means for storing the heat to form a tubular shape to accumulate the heat generated by combustion and to blow it to the blast furnace, the main body 110, the upper dome (120), the center rod 130 Consists of

The main body 110 is a cylindrical structure formed in a cylindrical shape, the internal space of the main body 110 is formed with a combustion space for generating heat, and a heat storage space for storing and accumulating the heat.

The upper dome 120 is a cover member installed on the upper part of the main body 110 in a dome shape to cover the upper part of the main body 110, and the inner space of the upper dome 120 has a combustion space and a heat storage space. It is formed as a communication space connected to each other.

The central rod 130 is a support member vertically placed on the center of the inner space of the main body 100 and extends from the bottom of the main body 110 to the upper end of the upper dome 120.

The dividing unit 200 is a dividing unit which is installed in the up and down direction inside the main body unit 100 and divides the internal space into a plurality of units. The dividing unit 200 is outwardly based on the central rod 130 placed on the center of the main body unit 100. It is composed of a plurality of divided walls arranged in a radially arranged manner to divide the internal space of the main body portion 100 into a plurality of equal to each other.

In addition, the divided part 200 is formed of a double heat insulation wall, and is disposed radially from the outer wall of the main body 110 to the central rod 130. In particular, an access passage for entering and repairing the hot air portion 300 is formed in the space between the double insulating walls, and the outside air flows into the access passage.

Therefore, not only the worker's entrance and exit through the access passage formed between the double insulation walls during the maintenance work of the hot air blowing unit 300, but also the work of the remaining hot air blowing unit 300 during the maintenance work of some hot air blowing unit 300 Of course it is possible.

The hot air part 300 is divided into a plurality of parts by the dividing part 200 in the inside of the main body part 100, and is formed into a plurality of hot air means so as to sequentially supply hot air to the blast furnace, and the inside of the main body part 100. It is divided evenly by the division part 200 with respect to the center rod 130 installed up and down on the space center part.

As shown in FIG. 2 which is sectional drawing by the cutting line AA of FIG. 1, the hot air | gas part 300 of this embodiment is the 1st hot air part 301 and 2nd hot air divided | segmented evenly each other by the division part 200. FIG. It consists of three hot air parts like the part 302 and the 3rd hot air part 303.

In this case, the dividing unit 200 may include a first dividing unit 210 that divides the first hot air unit 301 and a second hot air unit 302, a second hot air unit 302, and a third hot air unit 303. It is preferable that the second division part 220 for dividing between) and the third dividing portion 230 for dividing between the third hot air portion 303 and the first hot air portion 301.

The first hot air unit 301, the second hot air unit 302, and the third hot air unit 303 alternately perform a combustion step, a blowing step, and a preliminary step to sequentially supply hot air to the blast furnace.

Since the first hot air balloon 301, the second hot air balloon 302, and the third hot air balloon 303 are equally divided and have the same configuration, only the configuration of one first hot air balloon 301 is specifically described. Explain.

As shown in FIG. 3 which is sectional drawing by the cutting line BB of FIG. 1 and FIG. 1, the 1st hot air blast part 301 of this embodiment is a hot air supply means which accumulates fuel gas and supplies hot air to a blast furnace, and is a combustion chamber. It consists of the 310, the heat storage chamber 320, the separation wall 330.

The combustion chamber 310 is a combustion space in which a burner 311 is installed at a lower portion and a fuel gas is burned by the burner 311 to generate a high temperature combustion gas. The main body part 100 is referred to the separation wall 330. It is formed outside of. The combustion chamber 310 is provided with a burner 311, a gas inlet 312, an air inlet 313, and a hot air outlet 314.

The burner 311 is made of a ceramic burner to minimize the impurities during combustion of the fuel gas to prevent environmental pollution. Gas inlet 312 is connected to the lower portion of the burner 311, the by-product gas, such as BFG (Blast Furnace Gas), COG (Coke Oven Gas) generated during the operation of the blast furnace or coke oven flows into the fuel gas Let's go.

The air inlet 313 is connected to the lower portion of the burner 311 to introduce the air for combustion. The hot air discharge port 314 is connected to the upper portion of the burner 311 to discharge hot air generated by the burner 311 to the blast furnace.

The heat storage chamber 320 is a heat storage space in which the exhaust gas combusted in the combustion chamber 310 is accumulated, and is formed inside the main body part 100 with reference to the separation wall 330. In addition, a heat storage checker having pores formed inside the heat storage chamber 320 is installed as fire-softening, and a checker support is provided below the heat storage checker.

In the heat storage chamber 320, a waste gas outlet 321 connected to one lower side of the heat storage chamber 320 and discharging waste gas, and a low temperature hot wind inlet connected to the other side of the bottom of the heat storage chamber 320 to receive low temperature hot air ( 322 is provided.

The separating wall 330 is formed to be curved inwardly from the inner circumferential surface of the main body portion 100 so as to separate the combustion chamber 310 and the heat storage chamber 320 and the upper portion is formed to communicate with each other.

Hereinafter, the operation of the multi-segment internal combustion type hot stove of the composite structure of the present embodiment will be described in detail with reference to FIGS. 4 to 7.

As shown in Fig. 4 and Fig. 5, in the combustion step of the multi-segment internal combustion hot air furnace of the composite structure of the present embodiment, the gas inlet 312 and the air inlet 313 are opened while the hot air outlet 314 is closed. The fuel gas and the combustion air are introduced into the combustion chamber 310 and mixed.

The fuel gas and combustion air introduced into the combustion chamber 310 are burned by the burner 311 to generate a high temperature combustion gas. The high temperature combustion gas generated here moves to the upper portion of the combustion chamber 310 and moves to the heat storage chamber 320 through the inner space of the upper dome 120 of the main body 100 connected to the upper portion of the separation wall 330. Done.

The high temperature combustion gas moved to the heat storage chamber 320 is stored in a heat storage checker installed inside the heat storage chamber 320, and the remaining waste gas after the heat storage is discharged to the outside through the waste gas outlet 321.

As shown in Fig. 6 and 7, in the blowing step of the multi-segment internal combustion hot air furnace of the composite structure of the present embodiment, the low temperature hot air inlet 322 is closed with the gas inlet 312 and the air inlet 313 closed. The low temperature hot air of about 240 ° C. is introduced into the heat storage chamber 320.

The low temperature hot air introduced into the heat storage chamber 320 is heated by heat transfer while passing through the heat storage checker accumulated at high temperature by the high temperature combustion gas in the combustion step, and is converted into high temperature hot air of about 1250 ° C or more.

The high temperature hot air converted as described above moves to the upper portion of the heat storage chamber 320 and moves to the combustion chamber 310 through the inner space of the upper dome 120 of the main body portion 100 communicated with the upper portion of the separation wall 330. It is supplied to the blast furnace through the hot air outlet (314).

As described above, according to the present invention, by dividing the internal space of one main body into a plurality of hot air parts and supplying hot air sequentially to the blast furnace, the installation area of the hot air furnace is reduced, and the blast furnace and the separation distance are shortened. It provides an effect that can prevent the heat loss of the hot air.

In addition, by splitting the hot air evenly on the basis of the central rod in the inner space of the body portion, it is possible to continuously supply hot air of a constant temperature to the blast furnace to improve the work efficiency of the blast furnace. Since the hot air is divided equally into three, it is possible to sequentially supply the hot air to the blast furnace by alternating the combustion step, the blowing step and the preliminary step.

In addition, since the hot air portion is composed of a combustion chamber, a heat storage chamber, and a separating wall separating them, the hot air portion can be compactly configured to minimize heat loss of the combustion chamber and improve heat storage efficiency of the heat storage chamber. By constructing the burner of the combustion chamber with a ceramic burner, it is possible to reduce the generation of impurities during combustion of the burner to prevent environmental pollution.

In addition, by installing a hot air outlet at the top of the burner in the combustion chamber and a gas inlet and an air inlet at the bottom of the burner, it is easy to introduce fuel gas and combustion air and at the same time facilitate the discharge of hot air.

Further, by forming a waste gas outlet in one lower portion of the heat storage chamber and forming a low temperature hot air inlet in the other lower portion, it facilitates the discharge of the waste gas in the combustion step and at the same time provides an effect of facilitating the introduction of the low temperature hot air in the blowing step.

In addition, since the combustion chamber is formed on the outside of the hot winder on the basis of the partition wall and the heat storage chamber is formed on the inside, the heat loss to the outside of the heat storage chamber is blocked, thereby improving the thermal efficiency of the hot air furnace, thereby reducing operating costs, and checking the heat storage chamber. It reduces the amount of refractory and reduces the investment costs.

The present invention described above can be embodied in many other forms without departing from the spirit or main features thereof. Therefore, the above embodiments are merely illustrative in all respects and should not be construed as limiting.

100: main body 200: division
300: hot air 301: first hot air
302: second hot wind 303: third hot wind
310: combustion chamber 320: heat storage chamber
330: partition wall

Claims (8)

A main body portion formed in a tubular shape;
A division unit installed in the main body part in a vertical direction to divide an internal space into a plurality; And
And a plurality of hot air units which are divided into a plurality of parts by the dividing unit inside the main body and sequentially supply hot air to the blast furnace. The method of claim 1,
And the hot air portion is divided by the dividing portion on the basis of a central rod installed up and down in the center of the inner space of the main body portion. 3. The method of claim 2,
The hot air portion is composed of a first hot air portion, a second hot air portion and a third hot air portion divided by the dividing portion,
The first hot air portion, the second hot air portion and the third hot air portion, a multi-segment flame-retardant hot air of the composite structure characterized in that the hot air is sequentially supplied to the blast furnace by alternating the combustion step, the blowing step and the preliminary step. in. The method of claim 1,
The hot air portion,
A combustion chamber in which a burner is installed at the lower part and combusted;
A heat storage chamber in which the flue gas combusted in the combustion chamber is thermally stored; And
A multi-segment flame-retardant hot-air furnace, comprising: a separation wall formed to be inwardly curved from the inner circumferential surface of the main body to separate the combustion chamber and the heat storage chamber, and upper portions thereof communicating with each other. 5. The method of claim 4,
The burner of the combustion chamber is a multi-segment flame-retardant hot stove of the composite structure, characterized in that consisting of a ceramic burner. 5. The method of claim 4,
The combustion chamber is provided with a gas inlet through which the by-product gas of the blast furnace flows into the lower portion of the burner, an air inlet through which the combustion air flows, and a hot air discharge port connected with the upper portion of the burner to supply hot air to the blast furnace. Multi-segment flame-retardant hot air furnace characterized in that the composite structure. 5. The method of claim 4,
The heat storage chamber, a multi-segment flame-retardant hot air furnace characterized in that it is provided with a waste gas outlet connected to one side of the lower side to discharge the waste gas, and a low temperature hot air inlet connected to the other side of the lower side. 5. The method of claim 4,
The combustion chamber is formed on the outer side of the main body portion on the basis of the partition wall, the heat storage chamber is formed on the inner side of the main body portion on the basis of the separation wall, a multi-segment internal combustion type hot stove.

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