KR100936358B1 - External air intrusion prevention device in reheating furnace when material is charged - Google Patents

Abstract

The present invention relates to a device for preventing outside air intrusion in reheating furnace when charging a material, and blocking the inflow of cold air from the outside when opening and closing the charging side door of the reheating furnace by blocking the outflow of combustion gas in the upper and lower parts of the furnace. This is to prevent fluctuations in furnace temperature and oxygen concentration during material loading.

To this end, the present invention is installed at the rear end of each material loading passage inside the charging side door to form heat storage and vortex by the lower main flow in the furnace when the charging door is closed, and flows into the furnace bottom when the charging door is opened. A plurality of external air blocking members which block air and preheat external air by the heat storage to induce flow to an exhaust gas pipe line; An electric controller (PLC) which finely raises or lowers the furnace pressure by controlling the low pressure control damper by the door opening signal and the door closing signal generated in the furnace combustion control system when the material is charged; Provided is a device for preventing outside air intrusion in a furnace at the time of charging a material composed of a damper for regulating a furnace pressure which changes the furnace pressure by the electric controller.

Reheating Furnace, Charging Door, Air Block

Description

Air inflow protection apparatus for charging process in a reheating furnace

1 is a configuration of a conventional furnace charging or exit system

Figure 2a and Figure 2b is a plan view and a front view showing the heat flow and temperature distribution for the external air intrusion phenomenon when charging the material in the conventional reheating, respectively

Figure 3 is a side view showing the configuration of the outside air intrusion prevention device when loading the material according to an embodiment of the present invention

Figure 4 is a front view showing the configuration of the outside air intrusion prevention device when charging the material according to an embodiment of the present invention

Figures 5a and 5b is a reference diagram shown to explain the process of blocking the outside air by the outside air blocking member in the device for preventing the outside air intrusion according to an embodiment of the present invention

<Explanation of symbols for the main parts of the drawings>

1: furnace body 21: outdoor air blocking member

22: preheater lower burner 23: preheater upper burner

24: Material 25: exhaust gas piping line

26: furnace upper ramp 27: low pressure damper

28: Recuperator 29: Stack                 

30 combustion gas exhaust port 31 electric controller (PLC)

32: combustion control system (ACC) 51: charging side door

52: material charging passage

The present invention relates to a device for blocking external air invading when the material is loaded into the reheating furnace, and more particularly, when the charging side door is opened to charge the material in the reheating furnace to which the working beam method is applied. The present invention relates to a device for preventing outside air intrusion in a reheating furnace when a material is loaded, which can prevent air from invading the furnace, thereby preventing a drop in the temperature of the reheating furnace and a change in oxygen concentration.

1 is a side view illustrating a state in which a door of a material charging side is opened in a reheating furnace to which a conventional working beam method is applied in a steel mill, and a plurality of passages 52 are provided to charge the material into the reheating furnace. In the reheating furnace, the material charging passage 52 is normally blocked by the charging side door 51. When the charging side door 51 is opened when the material is charged, the plurality of passages 52 are shown in the drawing. It will be opened as shown.

By the way, in the conventional reheating furnace as described above, although the furnace operation is operated at a positive pressure of 1-3 [mmH ₂ O], the furnace lower region of the charging side becomes negative pressure due to buoyancy and the charging side is operated. From the door to the furnace lower region of the charging side, the external room temperature air is introduced into the reheating.

Figure 2a and Figure 2b shows the heat flow and the temperature distribution according to the intrusion of the outside air when opening the door for charging the material in the conventional reheating furnace, Figure 2a is a plan view of the reheating furnace, Figure 2b is a front view of the reheating furnace Respectively.

When invasion of the outside air occurs, heat flow is generated in the furnace, and as shown in the temperature distribution diagram of the planar state of FIG. 2A, a temperature deviation is severely generated in the material charging side of the reheating furnace and the inside of the furnace. As shown in the temperature distribution diagram of the front state of FIG. 2B, temperature deviations are severely generated in the upper and lower portions of the furnace centering on the material of the material of the reheating furnace. The heat flow and temperature deviation caused by the intrusion of outside air are generated in the same way on the material loading side and the material extraction side.

The temperature deviation of the upper and lower parts of the furnace caused by the intrusion of the outside air causes excessive temperature difference on the upper and lower surfaces of the material, which adversely affects the quality, and these causes also cause the oxygen concentration inside to be changed by reheating. The reheating makes the air-fuel ratio control of the entire combustion system inaccurate, leading to incomplete combustion and ultimately causing emissions of environmentally regulated materials.

Therefore, the present invention has been made to solve the above problems, the present invention is to block the inflow of cold air outside the opening and closing of the charging side door of the heating beam reheating furnace, block the outflow of the combustion gas of the upper and lower in the furnace The purpose of the present invention is to provide an external air intrusion prevention device in a reheating furnace when the material is loaded, which can prevent the furnace temperature drop and the oxygen concentration from changing.

In order to achieve the above object, the present invention is a device for preventing the inflow of cold air when opening and closing the charging side door in the reheating furnace to which the working beam method is applied, respectively installed at the rear end of each material loading passage inside the charging side door When the charging door is closed, heat storage and vortex are formed by the lower main flow in the furnace, and when the charging door is opened, external air is preheated by the heat storage to flow to the exhaust gas pipe line while blocking the air flowing into the furnace. Inducing a plurality of external air blocking member; An electric controller (PLC) which finely raises or lowers the furnace pressure by controlling the low pressure control damper by the door opening signal and the door closing signal generated in the furnace combustion control system when the material is charged; Provided is a device for preventing outside air intrusion in a furnace at the time of charging a material composed of a damper for regulating a furnace pressure which changes the furnace pressure by the electric controller.

In the present invention, the plurality of external air blocking member is a porous structure of a ceramic system capable of heat storage from the combustion gas in the furnace, and installed in a plurality of rows in parallel with the charging side door, each of the external air blocking members arranged in each row is It is preferable that the height is formed higher toward the charging side, and the inclination of the height of each external air blocking member is installed to be equal to the inclination of the upper slope to the charging side.

The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

Hereinafter, the present invention will be described in the case of the outer air blocking member made of a porous structure of a ceramic system as an example, and the configuration and operation of the present invention with reference to the accompanying drawings in detail as follows.

Figure 3 is a front view schematically showing the overall configuration of the external air intrusion prevention apparatus when charging the material according to an embodiment of the present invention.

As shown in FIG. 3, the charging side external air intrusion prevention apparatus of the walking beam type reheating furnace according to the present invention includes a plurality of external air blocking members 21 installed at the rear end of each material loading passage inside the charging side door 51. And an electric controller (31; Programmable Logic Controller) which finely raises or lowers the pressure in the furnace by adjusting the low pressure control damper by the door opening signal and the door closing signal generated in the furnace combustion control system 32 when the material is charged. And a low pressure damper 27 for changing the pressure in the furnace by the electric controller 31. For reference, reference numeral 1 of FIG. 3 denotes a furnace body, 25 is an exhaust gas pipe line, 26 is a charging side furnace upper ramp, 28 is a recuperator, and 29 is a stack.

FIG. 4 is an enlarged perspective view illustrating the main part of the charging side in order to explain the installation state of the external air blocking member of FIG. 3.

As shown in FIG. 4, each of the external air blocking members 21 in the present invention is formed of a porous structure of a ceramic system and installed on the bottom surface of the lower part of the furnace in such a way that heat storage from combustion gas in the furnace is possible. Arranged in a plurality of rows side by side in the width direction of the furnace at a position corresponding to the charging passage (52). In particular, the height of each air blocking member 21 arranged in each column is formed to be higher toward the charging side, wherein the inclination of the height of each air blocking member is installed to be equal to the slope of the upper ramp 26 to the charging side. The lower main flow of the combustion gas formed by the preheater lower burner 22 is directed to the combustion gas exhaust port 30.

5A and 5B are reference diagrams for explaining the flow and heat flow of the combustion gas formed inside the furnace by the external air blocking member when the charging side door is opened and closed, and FIG. 5A illustrates the furnace when the charging side door is closed. The internal combustion gas flow and heat flow state are illustrated, and FIG. 5B illustrates the air flow flowing in from the outside and the combustion gas flow and heat flow state inside the furnace when the charging side door is opened.

Referring to the effects of the present invention configured as described above in detail.

First, as shown in FIG. 5A, when the charging side door 51 is closed, the combustion gas combusted in the heating zone and the cracking zone at the rear end of the preheating stage and the combustion burned by the upper and lower burners 23 and 22 of the preheating stage. Gas flows toward the exhaust gas pipe line 25 through the combustion gas exhaust port 30 on the left side of the drawing.

At this time, the flow of the combustion gas is largely divided into the main flow of the upper and lower by the material 24, the outer air blocking member 21 installed in the lower part of the furnace as a porous layer type structure to prevent intrusion of the outside air toward the charging side. Since a plurality of high flow rate is installed, the lower main flow flows to the charging side, and a part of the lower main flow passes through the outside air blocking member 21 which is a porous layer structure, and the rest passes over the outside air blocking member 21, It comes from the space between and causes vortex. While going through the above process, it is directed to the combustion gas exhaust port 30 and the exhaust gas piping line 25 at the upper part through the external air blocking member 21 at the charging side.

The exhaust flue gas of about 900 ^° C. is exhausted through the stack 29 at a low temperature of about 300 ^° C by heat exchange with combustion air while passing through the heat recovery device 28.

Therefore, the external air blocking member 21, which is a structure for preventing outside air intrusion of the porous layer type installed in the lower part of the furnace, is thermally stored at a high temperature of about 900 ^o C to about 1000 ^o C using a ceramic material. Vortex flows the hot combustion gases.

In addition, by increasing the height of the outside air blocking member toward the charging side, the upper and lower structure of the furnace is reduced by the charging side furnace upper ramp 26 in FIG. 5A to reduce the charging side direction, thereby increasing the velocity of the main flow of the furnace combustion gas toward the exhaust side. By increasing, it is possible to eliminate the disturbance of the main flow flow by installing the external air blocking member at the bottom.

Next, as shown in FIG. 5B, when the charging side door 51 is opened to charge the material 24, air at room temperature outside the furnace enters the lower region of the charging material 24 and the material loading passage 52. ) Is locally intruded into the lower furnace area. At this time, the electric controller 31 (PLC) receiving the charging side door opening signal from the in-house combustion control system 32 slightly adjusts the low pressure adjusting damper 27 to slightly increase the low pressure.

This can reduce the infiltration of the outside air to some extent, and the intruded outside air flows through the bottom of the furnace while some of the charging side door 51 is closed while passing through the outside air blocking member 21 which is the first porous layer structure. In this case, the heat is preheated to the second porous layer structure by the heat already stored in the external air blocking member.

After colliding by the first air blocking member, a part is directed to the combustion gas exhaust port 30 and the exhaust gas piping line 25 by the lower main flow, and the rest is directed to the second member by riding the first air blocking member. That is, some are directed to the exhaust side by physical collision, the other part is preheated through the external air blocking member, and directed to the first and second external air blocking members, and the part corresponding to the upper part of the remaining air intrusion layer is the second on the first air blocking member. It is directed to the member.

The outside air, which has passed through the first air blocking member and penetrates into the second air blocking member, is heated by buoyancy by being heated by collision with the second air blocking member or by hot combustion gas remaining between the first and second air blocking members. To the exhaust side by means of the lower main flow, part of which is again preheated to a high temperature while passing through the second air blocking member.

In addition, the outside air, which is part of the top of the outside air intrusion layer, passes through the first air blocking member to the second member and is heated by buoyancy or the first air blocking member by hot combustion gas remaining between the first and second air blocking members. It is preheated by the buoyancy and floated upward by the momentum of the outside air, and is directed upward by the lower main flow to the exhaust side.

This process is equally applied to the remaining air blocking members.

Then, when the loading of the material is completed and the charging side door is closed, the electric controller 31 (PLC) receives the door closing signal of the furnace combustion control system 32 and adjusts the low pressure control damper 27 to control the low pressure during normal operation. To maintain.

In this way, when the charging door is opened, low-temperature outdoor air can reduce the air intrusion distance as much as possible by physical collision with the air blocking member and preheating. It is possible to solve the problem of uniform heating of the material, and even if the charging door is closed, heat can be transferred to the lower part of the material by the accumulated external air blocking member. Since the control of air-fuel ratio can be increased, it is possible to greatly improve the environmental problems and the heat source unit of the heating furnace.

According to the present invention, there is an advantage that can reduce the energy used in the heating furnace by blocking the intrusion of outside air when opening and closing the door of the working beam type reheating furnace, and also because the lower temperature of the lower heating by the reheating can increase the lower surface and the lower surface The temperature variation of the is reduced, thereby improving the quality of the final product.

In addition, according to the present invention, due to the fluctuation of the oxygen concentration in the furnace due to the infiltration of the outside air in the reheating furnace, the re-heating furnace inaccurate control of the air-fuel ratio of the entire combustion system, thereby leading to incomplete combustion, which ultimately caused the emission of environmental regulatory substances. The effect of reducing the conventional problem can be obtained.

Claims (4)

Forming a plurality of passages for charging materials in the reheating furnace to which the working beam method is applied, and having a charging side door for opening and closing the passages respectively, and generating a door opening signal and a door closing signal according to the charging material, In a reheating furnace having a combustion control system for controlling the opening and closing of the charging side door, the apparatus for preventing the inflow of cold air when opening and closing the charging side door, It is respectively installed at the rear end of the material loading passage inside the charging side door, and forms the heat storage and vortex by the lower main flow in the furnace when closing the charging side door, and blocks the air flowing into the furnace bottom when opening the charging side door. A plurality of external air blocking members for preheating the outside air by the heat storage to induce flow to the exhaust gas pipe line; An electric controller (PLC) for finely raising or lowering the pressure in the furnace by adjusting the low pressure control damper by a door opening signal and a door closing signal generated when the material is loaded in the combustion control system; It is composed of a low pressure control damper for changing the pressure in the furnace by the electric controller, The plurality of external air blocking members are arranged in a plurality of rows parallel to the charging side door; Each outside air blocking member arranged in each row is installed in the reheating furnace, the outside air intrusion prevention device, characterized in that the height is installed higher toward the charging side. delete The method of claim 1, The inclination of the height of each of the external air blocking member arranged in each row is installed in the same way as the slope of the upper slope of the furnace when the material reloading furnace outside air intrusion prevention apparatus. According to claim 1 or 3, wherein the external air blocking member, External air intrusion prevention device in the reheating furnace when the material is loaded, characterized in that the porous structure of the ceramic system capable of heat storage from the combustion gas in the furnace.

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