KR102077922B1 - Apparatus for preventing odor of ladle heater - Google Patents

Abstract

The present invention relates to a malodor prevention device of a ladle heating table, which is generated when preheating in a ladle heating table before using a newly constructed ladle to prevent thermal shock and a drop in molten steel temperature when using a newly constructed ladle. It is possible to remove the odor, and each step has an effect of improving the filtering efficiency by adjusting the temperature of the exhaust gas for optimal filtering according to the characteristics of the filter.

Description

Odor prevention device of ladle heater {APPARATUS FOR PREVENTING ODOR OF LADLE HEATER}

The present invention relates to a malodor prevention device of a ladle heating stand, and more particularly, in order to prevent thermal shock and a drop in molten steel temperature when using a newly constructed ladle, heating in a ladle heating stand before use of a newly constructed ladle. It relates to a odor prevention device for ladle heating, which can remove the odor generated when.

In general, steel mills use ladles to take molten steel that has been dissolved in an electric furnace and take over to the next process (eg LF, performance, etc.).

The ladle (ladle) is the outer shell is made of the outer shell, the inside of the ladle in contact with the hot molten steel is a refractory of the form or amorphous (eg MgO-C, Al ₂ O ₃ -MgO-C, casta ball, etc.) It consists of.

Ladles constructed of new refractory (i.e. stretch ladles) are used at the appropriate temperature (approximately 1200-1300) in the ladle heating table (or ladle heater) in order to prevent thermal shock and temperature drop of molten steel during use (i.e. taking water). Preheating).

At this time, odor (or odor) is generated outside the ladle during the drying and heat storage of the ladle refractories, in which phenol resin used as a refractory binder causes odor.

Background art of the present invention is disclosed in Republic of Korea Patent Publication No. 10-2017-0119046 (October 26, 2017 ladle heating device).

According to one aspect of the present invention, the present invention provides a odor generated when preheating in a ladle heating table before using the newly constructed ladle in order to prevent thermal shock and molten steel temperature drop in the use of the newly constructed ladle It is to provide a odor preventing device of the ladle heating table to be able to remove.

According to an aspect of the present invention, there is provided a odor preventing apparatus for a ladle heating table, the casing sealing an entire heating table for heating a ladle; A filter for primarily removing high-temperature white smoke and odor generated during heating of the ladle in the casing and preventing high heat transfer of exhaust gas; A primary fan forcibly sucking exhaust gas through a pipe in a next step of the filter; A catalyst burner for raising the temperature of the exhaust gas discharged through the primary fan to a designated temperature for catalysis; A catalyst for filtering odor elements through a catalytic reaction of exhaust gas whose temperature is increased through the catalyst burner; A heat exchanger that recovers the heat of reaction generated in the catalytic reaction to raise the temperature of the exhaust gas discharged from the primary fan to apply it to the catalyst burner and to lower the temperature to apply the exhaust gas passing through the catalyst to the activated carbon adsorption tower. ; Activated carbon adsorption tower is filtered through the catalyst to remove white smoke and odor and filtered through the activated carbon adsorption by applying the exhaust gas whose temperature is lowered through the heat exchanger; A secondary fan forcibly sucking the exhaust gas filtered by the activated carbon adsorption tower in the next step of the activated carbon adsorption tower and discharging it to the atmosphere; And operating a burner of the heating stage, controlling the primary fan, the catalytic burner, the heat exchanger, the secondary fan, and at least one valve to improve the forced suction, discharge, and filtering efficiency of the exhaust gas. And a control unit for performing adjustment.

In the present invention, the catalyst burner is characterized in that to increase the temperature of the exhaust gas discharged through the primary fan to maintain 350 ~ 400 degrees (℃).

In the present invention, the heat exchanger is applied to lower the temperature of the exhaust gas discharged through the catalyst to at least 130 degrees (℃) below to prevent the occurrence of fire in the activated carbon adsorption tower before the activated carbon adsorption tower. It features.

In the present invention, the control unit controls the catalyst burner Full Control Valve (FCV) in order to maintain a constant temperature of the catalyst burner, raising the thermal power by increasing the opening degree of the catalyst burner FCV to increase the temperature, It is characterized by lowering the temperature by reducing the thermal power through the reduction of the opening degree of the catalytic burner FCV.

In the present invention, the control unit controls the external air damper FCV (Full Control Valve) in order to lower the temperature of the exhaust gas introduced into the activated carbon adsorption tower, and the introduction of outside air through the increase in the opening degree of the external air damper FCV. The amount of the exhaust gas is lowered by increasing the amount, and by reducing the opening amount of the external air damper FCV, it is characterized in that the temperature of the exhaust gas is increased by reducing the amount of intake of the outside air.

In the present invention, the control unit, after the burner ON command is input, turns on the main burner of the ladle heating unit and then seals the casing, drives the secondary fan and the primary fan, and the catalyst burner In order to activate the catalytic reaction to the exhaust gas of the catalyst, temperature control of the catalyst burner for raising the temperature of the exhaust gas to a predetermined temperature is performed, and the shear temperature of the activated carbon adsorption tower is set for adsorption of activated carbon. Temperature control for maintaining the optimum temperature.

In the present invention, in order to perform the temperature control of the catalyst burner, the control unit increases the temperature by increasing the thermal power by increasing the opening degree of the catalyst burner FCV when the temperature of the rear end of the catalyst burner is equal to or less than the designated first temperature, The temperature after the catalyst burner is lowered by lowering the thermal power by reducing the opening degree of the catalyst burner FCV above the designated second temperature.

In the present invention, in order to maintain the preset optimum temperature for the activated carbon adsorption, the controller increases the opening degree of the external air damper FCV at a temperature higher than a third temperature specified by the activated carbon adsorption tower to draw in the outside air. It is characterized in that the temperature of the exhaust gas is lowered by increasing the temperature, and the temperature of the exhaust gas is increased by reducing the opening amount of the external air damper FCV by reducing the opening amount of the external air damper at a temperature lower than the designated fourth temperature. .

According to one aspect of the present invention, the present invention provides a odor generated when preheating in a ladle heating table before using the newly constructed ladle in order to prevent thermal shock and molten steel temperature drop in the use of the newly constructed ladle Has the effect of eliminating

1 is an exemplary view showing a schematic configuration of the odor prevention device of the ladle heating table according to an embodiment of the present invention.
Figure 2 is an exemplary view showing a photograph of the white smoke generated when the ladle in Figure 1, the heating.
Figure 3 is a flow chart for explaining a control method of the odor prevention device of the ladle heater according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the odor preventing device of the ladle according to the present invention.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary depending on the intention or convention of a user or an operator. Therefore, the definitions of these terms should be made based on the contents throughout the specification.

1 is an exemplary view showing a schematic configuration of the odor prevention device of the ladle heating table according to an embodiment of the present invention.

As shown in FIG. 1, the odor preventing device of the ladle heater according to the present embodiment includes a casing 110, a filter 120, a primary fan 130, a heat exchanger 140, a catalyst burner 150, A catalyst 160, an activated carbon adsorption tower 170, and a secondary fan 180 are included.

Although not shown in the drawing, the components 110 to 180 are controlled by a controller (or a control server).

In addition, the controller (or control server) (not shown) is an additional component associated with the components (110 to 180), at least one valve (e.g. gas shutoff valve, oxygen shutoff valve, catalyst burner FCV (Full) Control valves, air damper full control valves (FCV) valves, fans (eg air curtain fans, air fans, etc.) and catalyst burner ignition for burner on / off.

The casing 110 is a casing (or house) that seals the entire heating table (or heating device) for heating the ladle, and includes a trolley and a door capable of retracting the ladle. In addition, refractory materials are constructed inside to cope with high heat exhaust gases such as white smoke and odor generated during ladle heating.

The lower part of the casing 110 (or house) is implemented to allow the outside air to be sucked in, and the upper (or upper side) is a odor inlet (that is, an outlet for inhaling odor or white smoke to the outside) To form.

For reference, FIG. 2 is an exemplary view showing a photograph of white smoke generated when a ladle is heated in FIG. 1. Therefore, although only white smoke is photographed in FIG. 2, in fact, the white smoke contains phenol resin which causes odor.

The filter 120 primarily removes high-temperature white smoke and odor (odor) while considering rising air flow generated when the ladle inside the casing 110 is heated. To prevent heat loss of electrically operated fans, heat exchangers, catalyst burners, etc.

The primary fan 130 forcibly sucks the exhaust gas whose flow is blocked by the filter 120. Accordingly, the exhaust gas filtered by the first filter 120 is forced to discharge continuously along the pipe. At this time, the temperature of the exhaust gas filtered by the filter 120 and discharged through the primary fan 130 drops to about 200 degrees (° C.).

However, the temperature dropped to about 200 degrees (° C.) is too low to perform secondary filtering using a catalyst in the next step.

Therefore, the catalyst burner 150 raises the exhaust gas dropped to about 200 degrees Celsius to 350 to 400 degrees Celsius. This is because the catalytic reaction through the catalyst 160 proceeds actively when the temperature of the exhaust gas is 350 to 400 ° C.

Wherein the catalyst 160 comprises a platinum catalyst. However, it is not intended to limit the platinum catalyst. That is, when the catalytic reaction (or catalytic oxidation half) is performed on the exhaust gas through the catalyst 160 (eg, CmHn + O ₂ ), carbon dioxide (CO ₂ ) and water (H ₂ O) are decomposed into heat of reaction.

At this time, the reaction heat is recovered by 95% or more in the heat exchanger 140 is reused.

However, the method of raising the temperature of the exhaust gas using the catalyst burner 150 has a problem in that energy efficiency is lowered because of high energy consumption.

Therefore, the heat exchanger 140 utilizes the exhaust gas discharged from the catalyst 160 (that is, recovers and reuses the reaction heat generated in the catalytic reaction) to determine the temperature of the exhaust gas discharged from the primary fan 130. By raising the energy efficiency by reducing the consumption of energy used in the catalyst burner 150.

On the other hand, the exhaust gas from which the odor (odor) and the white smoke are removed by the second filtering through the catalyst 160 is subjected to the third filtering in the activated carbon adsorption tower 170.

However, since the temperature of the exhaust gas discharged through the catalyst 160 is 350 to 400 degrees (° C.), a fire may occur in the activated carbon adsorption tower 170.

Therefore, the heat exchanger 140 serves to lower the temperature of the exhaust gas discharged through the catalyst 160 to at least 130 degrees (° C.) before being applied to the activated carbon adsorption tower 170.

That is, the heat exchanger 140 raises the temperature of the exhaust gas passing through the primary fan 130 and applies it to the catalyst burner 150, and lowers the temperature of the exhaust gas passing through the catalyst 160. It performs the function of applying to the activated carbon adsorption tower (170).

In this case, although not shown in the drawing, the control unit (not shown) may control the catalyst burner FCV (Full Control Valve) to increase the temperature in the catalyst burner 150. For example, increasing the opening of the catalyst burner FCV increases the thermal power to increase the temperature, and decreasing the opening reduces the thermal power to lower the temperature.

The activated carbon adsorption tower 170 performs third-order filtering to remove white smoke and odor (odor) from the exhaust gas introduced through the heat exchanger 140.

At this time, when the temperature of the flue gas introduced into the activated carbon adsorption tower 170 is high, there is a possibility that a fire may occur in the activated carbon adsorption tower 170, and therefore, it is necessary to lower the temperature below an appropriate temperature (eg, 130 degrees).

Accordingly, although not shown in the drawing, a controller (not shown) may control an external air damper FCV (Full Control Valve) to lower the temperature introduced into the activated carbon adsorption tower 170. For example, increasing the opening degree of the outside air damper FCV increases the amount of outside air drawn in and the temperature of the exhaust gas decreases, while decreasing the opening amount of the outside air damper FCV decreases the incoming air amount in the outside air, which reduces the temperature of the exhaust gas. To rise.

The secondary fan 180 forcibly sucks the exhaust gas whose flow is blocked by the activated carbon adsorption tower 170. Accordingly, the tertiary filtered exhaust gas from the activated carbon adsorption tower 170 is forcibly discharged to the outside atmosphere.

As described above, the filtering efficiency is improved by adjusting the temperature of the exhaust gas for optimum filtering according to the characteristics of the filter (for example, the catalyst filter and the activated carbon adsorption filter) in each embodiment as described above. No phenol resin was found in the flue-gases emitted through filtration, causing odors.

Hereinafter, a method of controlling a odor prevention device of the ladle heating table by a controller (not shown) will be described.

3 is a flowchart illustrating a control method of the malodor prevention device of the ladle heating table according to an embodiment of the present invention.

As shown in FIG. 3, when a burner on command is input (S101), the controller (not shown) starts a pilot burner (S102) and pilot burner through the pilot burner start. It is checked whether a flame has occurred (S103).

When a flame occurs in the pilot burner, a gas (for example, LNG) opens a shutoff valve (not shown) (S104) to inject gas, and an oxygen shutoff valve (not shown) is opened (S105). ) Inject oxygen. In addition, the inside of the casing 110 is sealed by starting an air curtain fan FAN (not shown).

When flame occurs in the main burner after the flame is generated in the pilot burner (YES in S103) (YES in S107), the controller (not shown) starts a local exhaust process (S108). At this time, if the flame does not occur in the main burner returns to the pilot burner start step (S102).

On the other hand, when the local exhaust process is started (S108), the controller (not shown) starts (ie, drives) the secondary fan of the malodor prevention device of the ladle heating table (S109), and also starts the primary fan (that is, Drive) (S110).

Accordingly, the exhaust gas containing the white smoke and the odor (odor) inside the casing 110 of the odor prevention device of the ladle heating table is forced to intake to filter a total of three stages (that is, the removal of phenol resin causing the odor removal). To perform.

As the local exhaust process is started (S108), at the same time as starting the primary and secondary fans, the control unit (not shown) starts the catalyst burner 150 (S111).

The catalyst burner 150 raises the temperature of the exhaust gas to an optimal temperature (for example, 350 ° C. to 400 ° C.) in order to activate the catalytic reaction with respect to the exhaust gas of the catalyst 160.

In order to start the catalyst burner 150, the control unit (not shown) starts the ignition (for example, generating sparks for ignition) (S112), and starts the air fan (FAN) (for example, injects air to start ignition). Help) (S113).

When the catalyst burner start S111 is normally completed, flame is generated in the catalyst burner. Therefore, the controller (not shown) checks whether a flame occurs in the catalyst burner 150 (S114).

If no flame is generated in the catalyst burner 150 (NO in S114), the catalyst burner start process (S111) is repeatedly aquatic.

Meanwhile, when the catalyst burner start S111 is normally completed and a flame occurs in the catalyst burner 150 (S114), the controller (not shown) performs temperature control of the catalyst burner 150 (S115). S116). That is, the controller (not shown) maintains the temperature of the rear end of the catalyst burner 150 at an optimum temperature (for example, 350 to 400 degrees C) for a predetermined catalyst.

However, the optimum temperature for the catalyst may vary depending on the embodiment.

For example, the controller (not shown) controls the catalyst burner full control valve (FCV) to adjust the temperature of the catalyst burner 150. For example, when the temperature of the rear end of the catalyst burner 150 is 350 ° C. or less, the temperature is increased by increasing the thermal power by increasing the opening degree of the catalyst burner FCV, and the temperature of the rear end of the catalyst burner 150 is 400 ° C. Above), the temperature is lowered by reducing the openness of the catalyst burner FCV and lowering the thermal power.

In addition, the controller (not shown) performs temperature control to maintain the temperature of the front end of the activated carbon adsorption tower 170 at an optimum temperature (eg, 120 to 130 degrees (° C.)) for the preset activated carbon adsorption (S117). , S118). However, the optimum temperature for the activated carbon adsorption (or fire protection) may vary depending on the embodiment.

For example, the controller (not shown) controls an external air damper full control valve (FCV) to adjust the temperature introduced into the activated carbon adsorption tower 170. For example, when the temperature introduced into the activated carbon adsorption tower 170 is 130 degrees (° C.) or more, the temperature of the exhaust gas is lowered by increasing the amount of outside air by increasing the opening degree of the external air damper FCV, and the temperature of the exhaust gas decreases. When the temperature drawn into 170 is 120 degrees C or less, the opening degree of the outdoor air damper FCV is reduced to reduce the amount of outside air drawn in, thereby increasing the temperature of the exhaust gas.

Such filtering (i.e. removal of phenolic resin which causes odor removal) is performed by heating the ladle to a predetermined temperature (e.g. 1,000 degrees Celsius) in the ladle heating table (e.g. 9 hours in total, 1 hour ( Preheating), 8 hours (heating)) is continued, and when the heating is finished, the alarm outputs and ends (S119).

As described above, the present embodiment improves the filtering efficiency by controlling the temperature of the exhaust gas for optimal filtering according to the characteristics of the filter (eg, catalyst filter, activated carbon adsorption filter) at each stage to remove odor generated during ladle heating. It is effective to let.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible for those skilled in the art to which the art pertains. I will understand the point. Therefore, the technical protection scope of the present invention will be defined by the claims below.

110: casing 120: filter
130: primary fan 140: heat exchanger
150: catalyst burner 160: catalyst
170: activated carbon adsorption tower 180: secondary fan

Claims (8)

A casing sealing the entire heating table for heating the ladle;
A filter for primarily removing high-temperature white smoke and odor generated during heating of the ladle in the casing and preventing high heat transfer of exhaust gas;
A primary fan forcibly sucking exhaust gas through a pipe in a next step of the filter;
A catalyst burner for raising the temperature of the exhaust gas discharged through the primary fan to a designated temperature for catalysis;
A catalyst for filtering odor elements through a catalytic reaction of exhaust gas whose temperature is increased through the catalyst burner;
A heat exchanger that recovers the heat of reaction generated in the catalytic reaction to raise the temperature of the exhaust gas discharged from the primary fan to apply it to the catalyst burner and to lower the temperature to apply the exhaust gas passing through the catalyst to the activated carbon adsorption tower. ;
Activated carbon adsorption tower is filtered through the catalyst to remove white smoke and odor and filtered through the activated carbon adsorption by applying the exhaust gas whose temperature is lowered through the heat exchanger;
A secondary fan forcibly sucking the exhaust gas filtered by the activated carbon adsorption tower in the next step of the activated carbon adsorption tower and discharging it to the atmosphere; And
By operating a burner of the heating table, and controlling the primary fan, the catalytic burner, the heat exchanger, the secondary fan, and at least one valve, stepwise temperature control of the exhaust gas to improve the forced suction, discharge and filtering efficiency of the exhaust gas Control unit for performing; including,
The control unit,
If a burner ON command is input, starting a pilot burner;
Checking whether a flame has occurred in a pilot burner through the pilot burner start;
When a flame occurs in the pilot burner, opening a gas shutoff valve to inject gas, opening an oxygen shutoff valve to inject oxygen, and sealing the inside of the casing by starting an air curtain fan (FAN);
Starting a local exhaust process when the flame occurs in the main burner after the flame occurs in the pilot burner;
When the local exhaust process is started, starting the primary and secondary fans and simultaneously starting a catalyst burner;
Raising the temperature of the exhaust gas to a predetermined temperature to activate a catalytic reaction to the exhaust gas of the catalyst through the catalyst burner;
Starting an ignition and also starting an air fan (FAN) to start the catalyst burner;
Checking whether a flame is generated in the catalyst burner when the catalyst burner start is normally completed;
When the catalyst burner start is normally completed and a flame is generated in the catalyst burner, performing temperature control of the catalyst burner to maintain the predetermined temperature; And
And continuously performing temperature control for maintaining a temperature of the front end of the activated carbon adsorption tower at a predetermined optimum temperature for activated carbon adsorption for a predetermined time and outputting an alarm when the heating is terminated. Odor prevention device of ladle heating table.
The method of claim 1, wherein the catalyst burner,
The odor prevention device of the ladle heating table, characterized in that to increase the temperature of the exhaust gas discharged through the primary fan to maintain 350 ~ 400 ° C.
According to claim 1, The heat exchanger,
Odor prevention device of the ladle heating table characterized in that the temperature of the exhaust gas discharged through the catalyst is lowered below at least 130 degrees (° C.) in order to prevent the occurrence of fire in the activated carbon adsorption tower before being applied to the activated carbon adsorption tower. .
The method of claim 1, wherein the control unit,
In order to maintain a constant temperature of the catalyst burner to control the catalyst burner FCV (Full Control Valve),
Increasing the opening degree of the catalyst burner FCV to increase the thermal power to increase the temperature,
The odor preventing device of the ladle heater, characterized in that the temperature is lowered by reducing the thermal power through the opening degree of the catalyst burner FCV.
The method of claim 1, wherein the control unit,
In order to lower the temperature of the exhaust gas introduced into the activated carbon adsorption column, an external damper controls a FCV (full control valve),
Increasing the opening amount of the outside air damper FCV to increase the incoming amount of the outside air to lower the temperature of the exhaust gas,
The odor prevention device of the ladle heater, characterized in that to increase the temperature of the exhaust gas by reducing the amount of intake of the outside air by reducing the opening degree of the outside air damper FCV.
delete The method of claim 1, wherein the control unit,
In order to perform temperature control of the catalyst burner,
When the temperature at the rear of the catalyst burner is equal to or less than the first temperature specified, the temperature is increased by increasing the thermal power by increasing the opening degree of the catalyst burner FCV,
The odor prevention device of the ladle heating table characterized in that the temperature is lowered by lowering the thermal power by reducing the opening degree of the catalyst burner FCV when the temperature of the rear end of the catalyst burner is higher than the designated second temperature.
The method of claim 1, wherein the control unit,
In order to maintain the predetermined optimum temperature for the activated carbon adsorption,
When the temperature introduced into the activated carbon adsorption tower is higher than the third temperature specified, the temperature of the exhaust gas is lowered by increasing the opening amount of the external air damper FCV to increase the amount of external air drawn in,
The odor preventing device of the ladle heating table is raised when the temperature introduced into the activated carbon adsorption tower is lower than the fourth specified temperature, thereby reducing the opening degree of the outdoor air damper FCV to reduce the amount of external air drawn in.

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