KR101245317B1 - Device for controlling temperature of combustion chamber for coke oven - Google Patents

Abstract

Temperature detection unit for continuously detecting the temperature of the individual combustion chamber of the coke oven to minimize the temperature variation by adjusting the amount of fuel gas and air supplied to the individual combustion chamber according to the change in the temperature of each individual combustion chamber generated according to the drying time And a controller for checking the temperature deviation of the individual combustion chamber by comparing the detected value of the temperature detector with a predetermined set value, and an opening amount of a gas supply box for supplying fuel gas for combustion to the individual combustion chamber according to a signal of the controller. Coke oven comprising a gas control unit for controlling the supply amount of fuel gas by varying the variable, the air control unit for adjusting the supply amount of air by varying the opening amount of the air supply box for supplying air to the individual combustion chamber according to the signal of the controller It provides a low temperature deviation control device.

Description

Low temperature deviation control device of coke oven {DEVICE FOR CONTROLLING TEMPERATURE OF COMBUSTION CHAMBER FOR COKE OVEN}

The present invention relates to a coke oven for producing coke. More specifically, the present invention relates to a low temperature deviation control apparatus of a coke oven, which is capable of minimizing a temperature deviation of a coke oven combustion chamber.

In general, red coke is produced by drying in a coke oven. The coke oven is composed of a plurality of carbonization chambers into which the coal briquettes are charged, and individual combustion chambers disposed between the carbonization chambers and burning inside the coke oven. The coal is charged into the carbonization chamber (chamber) of the coke oven, and by burning the mixed gas and the air for combustion in the combustion chamber, the generated heat is transferred to the carbonization chamber and the coke is carbonized.

The mixed gas supplied to the combustion chamber is a mixed gas in which blast furnace gas (BFG) and coke oven gas (COG) are mixed, and is supplied to each combustion chamber through a gas inlet box connected to a distribution pipe. . In addition, the combustion air is supplied into the combustion chamber through an air inlet box installed in each combustion chamber by a draft pressure using natural ventilation force.

The change in temperature of the combustion chamber produces a difference in conduction heat conducted to the carbonization chamber, which affects the quality of the coke produced in the carbonization chamber and the operation rate of the coke oven. For example, when the low temperature of the combustion chamber is high, it causes coke overdrying, and when the low temperature is low, it causes coke dryness. Therefore, the combustion management to determine the furnace temperature of the combustion chamber is very important in the operation of the coke oven.

Conventionally, the total fuel gas flow rate is calculated according to the operating rate of the coke oven to control the total amount of heat supplied to the gas so as to adjust the average temperature of the entire combustion chamber of the coke oven to the target low temperature. In the related art, the same amount of air and mixed gas are supplied to each individual combustion chamber until the drying time, that is, the coal is charged into the carbonization chamber and extruded.

However, in the conventional structure, the total gas supply calories are hunted due to the low temperature variation generated according to the dry distillation time, and a problem in that the mixed gas is unnecessarily supplied according to the dry distillation time of the individual carbonization chamber is caused. Energy is wasted due to excess calorie supply, and the smoke is shrunk and expanded in the coke oven due to the low temperature, thereby shortening the service life.

Thus, by adjusting the amount of fuel gas and air supplied to the individual combustion chamber in accordance with the change in the temperature of each individual combustion chamber generated according to the drying time, it provides a low temperature deviation control apparatus of the coke oven to minimize the low temperature variation.

In addition, there is provided a low temperature deviation control device for a coke oven, which is capable of minimizing temperature variations between individual combustion chambers.

To this end, the apparatus includes a temperature detector for continuously detecting the temperature of an individual combustion chamber of a coke oven, a controller for comparing the detected value of the temperature detector with a predetermined set value, and checking a temperature deviation of the individual combustion chamber, and a signal of the controller. According to the signal from the controller of the gas control unit for controlling the supply amount of the fuel gas by varying the opening rate of the gas supply box for supplying the fuel gas for combustion to the individual combustion chamber according to the It may include an air control unit for controlling the supply amount of air by varying the opening degree.

The gas control unit is installed in the connection pipe connecting the gas supply box and the gas distribution pipe is connected to a damper for controlling the opening and closing amount, the hydraulic regulator is connected to the lever installed on the rotary shaft of the damper to rotate the damper according to the signal of the controller It may include.

The air control unit is installed on the front of the air supply box and the wire connected to the door for controlling the opening and closing amount, the hydraulic regulator for opening the door by pulling the wire connected to the wire in accordance with the signal of the controller, the door and It may be installed between the inner surface of the air supply box may include an elastic spring for closing the door.

The hydraulic controller may include a driving bar pivoted by hydraulic pressure, and the wire and the lever may be connected to the driving bar.

The air control unit may further include a pulley installed on the side of the air supply box to switch the traveling direction of the wire toward the hydraulic regulator.

According to the present apparatus as described above, the quality variation of the coke can be improved by minimizing the temperature variation between the individual combustion chambers and the temperature variation according to the drying time in the individual combustion chambers.

In addition, it is possible to reduce the energy consumption by optimizing the supply of fuel gas.

In addition, it is possible to extend the life of the furnace by reducing the lead and breakage due to the temperature deviation.

1 is a schematic view showing a low temperature deviation control apparatus of a coke oven according to the present embodiment.
2 is a schematic view showing the configuration of a low temperature deviation control apparatus of a coke oven according to the present embodiment.
3 is a view for explaining the operating state of the low temperature deviation control apparatus of the coke oven according to the present embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. As can be easily understood by those skilled in the art, the embodiments described below may be modified in various forms without departing from the concept and scope of the present invention. Where possible the same or similar parts are represented with the same reference numerals in the drawings.

All terms including technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the present invention belongs. Predefined terms are further interpreted as having a meaning consistent with the relevant technical literature and the present disclosure, and are not to be construed as ideal or very formal meanings unless defined otherwise.

1 is a schematic view showing a low temperature deviation control apparatus of a coke oven according to the present embodiment.

As shown, the coke oven according to the present embodiment is composed of carbonization chambers 110 for charging coal mixture and combustion chambers 100 for providing heat to the carbonization chambers 110. The carbonization chamber 110 and the combustion chamber 100 are alternately arranged.

Each combustion chamber 100 has a gas supply box 10 connected to the gas distribution pipe 130 for supplying fuel gas for fuel, and an air supply box 20 for supplying oxygen for combustion of fuel gas. Each is provided. Accordingly, heat generated while the air and fuel gas introduced into the combustion chamber 100 through the air supply box 20 and the gas supply box 10 are burned is transferred to the carbonization chamber 110 to the carbonization chamber 110. The charged coal briquettes are carbonized to produce coke.

Here, the device is configured to minimize the temperature variation according to the dry time in the dry process in each individual combustion chamber (100). In addition, the apparatus is designed to minimize temperature variations between the individual combustion chambers 100.

To this end, the apparatus includes a temperature detector which continuously detects the temperature of the individual combustion chamber 100 of the coke oven, and a controller which compares the detected value of the temperature detection unit with a preset set value to check the temperature deviation of the individual combustion chamber 100. 40, a gas control unit for controlling the supply amount of the fuel gas by varying the opening degree of the gas supply box 10 for supplying the fuel gas for combustion to the individual combustion chamber 100 in accordance with the signal of the controller 40, It includes an air control unit for controlling the supply amount of air by varying the opening degree of the air supply box 20 for supplying air to the individual combustion chamber 100 in accordance with the signal of the controller 40.

The temperature detector may include a temperature sensor 30 installed in the combustion chamber 100 of the coke oven to detect the temperature of the combustion chamber 100.

The temperature sensor 30 may be installed on the edge of the combustion chamber 100 or on the edge forming the combustion chamber 100. If the temperature of the combustion chamber 100 can be accurately detected, the temperature sensor 30 may be particularly limited in its measurement position or number of installations. It doesn't work.

The temperature sensor 30 is provided in each of the individual combustion chambers 100 of the coke oven, is connected to the controller 40, the controller 40 is able to detect the temperature of each individual combustion chamber 100 in real time. .

The controller 40 stores the average low temperature value according to the drying time in a separate combustion chamber of the coke oven as a set value. It takes about 16 to 24 hours to charge and extinguish the coal mixture in the carbonization chamber. During this drying time, the combustion chamber is affected by operations such as charging and extruding coal mixture in the adjacent carbonization chamber. The set value is an average value of the furnace temperature that changes during the drying time as described above, and may be a temperature calculated based on data obtained through repetitive drying operation of the coke oven, or may be an optimum drying temperature identified for the charged coal briquettes.

The controller 40 compares the actual temperature value obtained from the temperature sensor 30 installed in the individual combustion chamber 100 with the set value stored therein to adjust the amount of fuel gas and air supplied to the individual combustion chamber 100. It is structured to do.

That is, the controller 40 automatically controls the opening degree of the gas supply box 10 and the air supply box 20. The controller 40 collects and calculates information detected from each temperature sensor 30 to diagnose current combustion conditions for the individual combustion chamber 100. The gas control unit and the air control unit are controlled to supply gas and air flow rates required for the respective combustion chambers 100 calculated according to the above conditions.

In the present embodiment, the controller 40 adjusts the opening ratio of the gas supply box 10 and the air supply box 20 for supplying fuel gas and air to the respective combustion chamber 100 within a range of 40 to 60%. It may be a structure for controlling the gas control unit and the air control unit. When the opening ratio of the gas supply box and the air supply box is out of the above range, the supply of fuel gas and air is too small or excessive, so that the temperature of the individual combustion chamber is out of the manageable range.

In addition, when the controller 40 determines that the temperature of the individual combustion chamber 100 is excessively out of a set value and is bad, the controller 40 supplies a gas supply box 10 and air to supply fuel gas and air to the individual combustion chamber 100. The opening ratio of the box 20 may be configured to adjust within a range of 20 to 100%. It is understood that the opening degree is 100% in the fully open state, and 0% in the fully closed state.

Here, if the temperature of the individual combustion chamber 100 is excessively out of the set value and is determined to be a bad range, and the range within that range is a normal range, the bad range may be variously set. For example, the dry distillation temperature of the individual carbonization chamber 110 is approximately 1180 ~ 1300 ℃, 1212 ~ 1260 ℃ including the average temperature of most of the individual combustion chamber 100 of this temperature range is set to the normal range, If it is out of the above can be determined as a defective range that requires the management of the on. The said temperature range is shown as an example, and a bad range is not specifically limited.

Thus, the apparatus controls the temperature of the individual combustion chamber 100 to a set value by adjusting the opening ratio of the gas supply box 10 and the air supply box 20 at 40 to 60% according to the control signal of the controller 40. It will reduce the temperature deviation according to the drying time. In addition, according to the control signal of the controller 40, the present invention is determined that the opening rate of the gas supply box 10 and the air supply box 20 when the temperature of the individual combustion chamber 100 is determined to be excessively exceeded the set value. By further expanding the control to 20 to 100% to reduce the temperature deviation of the individual combustion chamber (100). If the opening rate is lowered to 20% or less, the supply of fuel gas and air is so small that there is a risk of combustion failure.

FIG. 2 illustrates a configuration of a gas control unit and an air control unit for adjusting a supply amount of combustion gas and air supplied to the combustion chamber 100 according to a control signal of the controller 40.

As shown, the gas control unit is installed in the connection pipe 12 connecting the gas supply box 10 and the gas distribution pipe 130, the damper 14 to control the opening and closing amount of the damper 14 It is connected to the lever 18 is installed on the rotating shaft includes a hydraulic regulator 16 for rotating the damper 14 in accordance with the signal of the controller 40. Accordingly, the hydraulic regulator 16 adjusts the opening ratio of the damper 14 to the connection pipe 12 by moving the lever 18 connected to the damper 14.

In addition, the device is configured to operate in conjunction with the air control unit in accordance with the operation of the hydraulic regulator 16 for adjusting the supply amount of the gas.

That is, the air control unit is installed in the opening 21 of the front of the air supply box 20, the wire 24 connected to the door 22 to control the opening and closing amount, the door 22 and the air supply box (20) is provided between the inner surface and includes an elastic spring 26 for closing the door 22, the wire 24 has a structure connected to the hydraulic regulator (16). The door 22 is slidably installed along the guide rail 28 installed at the upper and lower ends of the air supply box 20. The door 22 is moved along the guide rail 28 to adjust the opening degree of the tip opening 21.

As such, when the hydraulic regulator 16 is driven, the amount of gas supplied to the individual combustion chambers 100 is controlled and at the same time, the amount of air is adjusted.

The hydraulic regulator 16 includes a drive bar 17 which is rotated by hydraulic pressure, and the wire 24 and the lever 18 are connected to the drive bar 17. In addition, as shown in FIG. 2, the pulley 25 is installed on the side of the air supply box 20 to guide the wire 24. The wire 24 extending in the moving direction of the door 22 is spread over the pulley 25 and its direction is turned toward the hydraulic regulator 16. Accordingly, when the driving bar 17 of the hydraulic regulator 16 is rotated, the door 22 is opened while the wire 24 installed on the driving bar 17 is pulled.

With the above structure, the apparatus reduces the temperature deviation by controlling the amount of fuel gas and air supplied to the individual combustion chambers 100.

That is, the actual temperature of the individual combustion chamber 100 is changed according to the drying time. The actual temperature of the individual combustion chamber 100 is detected by the temperature sensor 30, and the signal detected by the temperature sensor 30 is applied to the controller 40. The controller 40 compares the actual temperature value of the individual combustion chamber 100 with a preset internal value and checks whether the current temperature is higher or lower than the predetermined value.

When the current temperature of the individual combustion chamber 100 is higher than the set value, the opening ratios of the gas supply box 10 and the air supply box 20 which supply fuel gas and air to the individual combustion chamber 100 are lowered. And reduce the supply of air. Accordingly, it is possible to reduce the temperature deviation generated according to the drying time in the individual combustion chamber (100). On the contrary, when the temperature of the individual combustion chamber 100 is lower than the set value, the controller 40 increases the opening rate of the gas supply box 10 and the air supply box 20 to increase the supply amount of fuel gas and air. As a result, the temperature of the individual combustion chamber 100 is increased to reduce the temperature deviation.

3 illustrates a structure in which the opening ratios of the gas supply box 10 and the air supply box 20 are varied by driving the hydraulic regulator 16.

When the hydraulic regulator 16 is driven according to the drive signal of the controller 40, the driving bar 17 installed in the hydraulic regulator 16 is moved. Accordingly, the lever 18 installed at the tip of the drive bar 17 is rotated in one direction. As the lever 18 is rotated, the damper 14 installed in the lever 18 may be rotated in the connecting pipe 12 to increase the opening degree of the connecting pipe 12. Therefore, the amount of gas supplied to the gas supply box 10 through the connection pipe 12 is increased.

On the other hand, the wire 24 of the air supply box 20 is also connected to the drive bar 17 of the hydraulic regulator 16, so that the wire 24 is pulled or pushed out according to the rotation of the drive bar 17. do.

When the wire 24 is pulled, the door 22 connected to the wire 24 is pulled. Accordingly, the door 22 is moved along the guide rail 28 so that the opening 21 in the front of the air supply box 20 is more opened. Therefore, by increasing the opening rate of the air supply box 20 it is possible to increase the supply amount of air.

In addition, when the hydraulic regulator 16 is driven and the drive bar 17 is rotated in the opposite direction to the above, the damper 14 is rotated in the opposite direction to reduce the opening rate of the connecting pipe 12. The door 22 is released by the force pulled by the wire 24, thereby being pulled in the opposite direction by the elastic force of the elastic spring 26 installed in the door 22 to reduce the opening degree of the opening 21 do.

While the illustrative embodiments of the present invention have been shown and described, various modifications and alternative embodiments may be made by those skilled in the art. Such variations and other embodiments will be considered and included in the appended claims, all without departing from the true spirit and scope of the invention.

10 gas supply box 12 connector
14 damper 16 hydraulic controller
17: drive bar 18: lever
20: air supply box 21: opening
22: door 24: wire
26: elastic spring 30: temperature sensor
40: controller

Claims (6)

A temperature detector for continuously detecting individual combustion chamber temperatures of the coke oven,
A controller for comparing the detected value of the temperature detector with a preset setting value and checking the temperature deviation of the individual combustion chamber;
A gas control unit controlling a supply amount of fuel gas by varying an opening degree of a gas supply box for supplying fuel gas for combustion to the individual combustion chambers according to a signal of the controller;
It includes an air control unit for controlling the supply amount of air by varying the opening rate of the air supply box for supplying air to the individual combustion chamber in accordance with the signal of the controller,
The air control unit is installed on the front of the air supply box and the wire connected to the door for controlling the opening and closing amount, the hydraulic regulator for opening the door by pulling the wire connected to the wire in accordance with the signal of the controller, the door and Low temperature deviation control device of the coke oven is installed between the inner surface of the air supply box including an elastic spring for closing the door. The method of claim 1,
The controller is a low temperature deviation control apparatus for a coke oven having a structure for controlling the gas control unit and the air control unit to adjust the opening ratio of the gas supply box and the air supply box within the range of 40 to 60%. The method of claim 2,
The controller of the coke oven of the structure to control the gas control unit and the air control unit to adjust the opening ratio of the gas supply box and the air supply box within the range of 20 ~ 100% when the temperature of the individual combustion chamber is out of the normal range. Low temperature deviation controller. The method according to claim 2 or 3,
The gas control unit is installed in the connection pipe connecting the gas supply box and the gas distribution pipe is connected to a damper for controlling the opening and closing amount, the hydraulic regulator for rotating the damper according to the signal of the controller is connected to the lever installed on the rotary shaft of the damper Low temperature deviation controller of the coke oven comprising a. delete The method of claim 4, wherein
The hydraulic controller includes a drive bar rotated by the hydraulic pressure, the wire deviation control device of the coke oven having a structure in which the wire and the lever is connected to the drive bar.

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