KR20040059175A - An Apparatus for Controlling Combustion in Hot Stove - Google Patents

Abstract

PURPOSE: An apparatus for controlling combustion in hot stove is provided to control flow rate of mixed gas according to change of heat capacity of combustion gas when controlling combustion of hot stove for supplying high temperature hot blast into blast furnace and prevent steep temperature increase during combustion of the hot stove. CONSTITUTION: The apparatus comprises a coke oven gas heat capacity detection part(204) for detecting heat capacity of coke oven gas; a blast furnace gas capacity detection part(205) for detecting capacity of blast furnace gas; a mixed fuel burning ratio calculation part(202) for calculating a mixed fuel burning ratio that is a ratio of flow rate of the coke oven gas to flow rate of the blast furnace gas according to a preset mixed gas heat capacity by receiving the detected heat capacity of the coke oven gas detected in the coke oven gas heat capacity detection part and detected heat capacity of the blast furnace gas detected in the blast furnace gas capacity detection part; a coke oven gas flow rate control part(203) for controlling flow rate of the coke oven gas according to the mixed fuel burning ratio calculated in the mixed fuel burning ratio calculation part; a dome temperature operation control part(206) for controlling flow rate of mixed gas so that dome temperature of the hot blast is constantly increased to a preset target dome temperature for a preset time and controlling flow rate of atmospheric air to constantly maintain the target dome temperature; and a waste gas temperature operation control part(207) for controlling flow rate of the mixed gas to constantly maintain temperature of the hot stove after constantly increasing temperature of waste gas of the hot stove to a preset target waste gas temperature for a preset time.

Description

An Apparatus for Controlling Combustion in Hot Stove}

The present invention relates to a hot furnace combustion control device for stably supplying hot air in a hot blast furnace facility, such as a blast furnace factory, and more particularly, to control the combustion of a hot furnace for supplying hot air to a blast furnace at a high temperature in a blast furnace molten metal manufacturing process. It relates to a hot stove combustion control device for controlling the flow rate of the mixed gas according to the fluctuation of the combustion gas heat during combustion, and to prevent a sudden rise in temperature during combustion.

In general, in a hot blast furnace facility such as a blast furnace plant, a heat generated by burning a mixed gas of blast furnace gas (BFG) and coke oven gas (COG) in a combustion chamber is stored in a heat storage chamber. Hot air at a constant temperature is continuously supplied to the blast furnace, and the like, and the hot blast furnace facility manages the dome temperature at the end of combustion and the temperature of the hot blast flue gas discharged from the heat storage chamber. Usually, the hot air supplied to the blast furnace should maintain a high temperature of 1250 ℃. In order to maintain such a high temperature, the hot stove dome temperature should be maintained at 1350 ° C. during combustion of the hot stove, and the exhaust gas discharged from the heat storage chamber to 330 ° C. should be maintained.

As such, controlling the dome temperature and the exhaust gas temperature to maintain the proper temperature through the combustion of the hot stove is a very important problem in terms of satisfying the thermal efficiency and the blowing conditions. In other words, if the temperature control is not performed properly and the overheated state, unnecessary heat loss occurs, the efficiency is lowered. If the unheated state does not allow the air to be blown at the desired temperature during blowing, it may cause considerable trouble to the blast furnace operation. do. Therefore, it is preferable that the temperature of the dome is controlled at a desired constant temperature during combustion, and the temperature of the exhaust gas is gradually increased over time to control the desired temperature at the end of combustion.

As shown in FIG. 1, in the conventional combustion operation of the hot stove, when the combustion is started, the installation operator mixes the mixed gas of the blast furnace gas (BFG) and the coke gas (COG) until the initial dome temperature is reached. Set the supply amount of the mixed gas at 101, the mixed gas set flow rate is input to the mixed gas flow rate control unit 105, the mixed gas flow rate control unit 105 is the flow rate of the mixed gas supplied from the mixed gas flow rate detector 127 The flow rate of the mixed gas supplied to the actual combustion chamber 122 by controlling the opening and closing amount of the mixed gas supply valve 126 is controlled to maintain a constant the set gas flow rate. At the same time, the atmospheric air is supplied to the combustion chamber 122 according to the air-fuel ratio set by the air-fuel ratio setting unit 104 where the ratio of the flow rate of the atmospheric air to the mixed gas set flow rate set by the mixed gas flow rate setting unit 101 is set. The supplied atmospheric air is detected by the atmospheric air flow rate detector 124 and is constantly controlled by adjusting the opening / closing amount of the atmospheric air supply valve 125 by the air flow controller 103.

The mixed gas and the air supplied as described above are combusted in the combustion chamber 122 to gradually increase the temperature of the heat stored in the heat storage chamber 123, and the temperature at which the dome temperature detected by the dome temperature detector 140 is set in advance. When the dome temperature control unit 102 reaches, the dome temperature is prevented from rising above the set value by forcibly increasing the flow rate of the atmospheric air supplied to the combustion chamber 122 through the air flow control unit 103. In addition, when the temperature of the exhaust gas detected by the exhaust gas temperature detector 130 reaches a preset temperature, the exhaust gas temperature controller 108 adjusts the flow rate of the mixed gas supplied to the combustion chamber 122 through the mixed gas flow controller 105. It is controlled to keep the exhaust gas temperature constant until the end of combustion by reducing it to prevent the exhaust gas temperature from rising.

However, the conventional combustion control as described above has a problem that unstable heat storage occurs due to a change in combustion conditions according to the changed mixed gas calories when fluctuations of the blast furnace gas (BFG) and coke gas (COG) constituting the mixed gas occurs. have. That is, when the same amount of mixed gas is combusted, if the amount of heat of the mixed gas decreases, it becomes an unheated state. On the contrary, if the amount of heat of the mixed gas increases, it becomes an overheat state. In addition, when the flow rate is excessively set by the operator of the facility, there is a problem in that the life of the hot-winding iron shell and the internal smoke is shortened by the rapid rise of the dome temperature and the rapid rise of the exhaust gas temperature during combustion.

The present invention has been made to solve the above-mentioned problems, the temperature of the dome and exhaust gas temperature of the hot stove is constantly raised for a predetermined time to reach a desired set temperature, the coke constituting the mixed gas supplied to the hot stove combustion chamber It is an object of the present invention to provide a hot stove combustion control device that detects the heat of gas (COG) and blast furnace gas (BFG) and adjusts the supply amount of coke gas (COG) according to the fluctuation thereof to maintain a constant amount of heat of the mixed gas. .

1 is a block diagram of a conventional hot stove combustion control device.

2 is a block diagram of a hot stove combustion control apparatus according to the present invention.

* Description of the symbols for the main parts of the drawings *

101: mixed gas flow rate setting unit 102: dome temperature control unit

103: air flow control unit 104: air-fuel ratio setting unit

105: mixed gas flow control unit 108: exhaust gas temperature control unit

122: combustion chamber 123: heat storage chamber

201: mixed gas heat amount setting unit 202: mixing ratio calculation unit

203: coke gas flow rate control unit 204: coke gas calorie detection unit

205: blast furnace gas heat detection unit 206: dome temperature calculation control unit

207: exhaust gas temperature calculation control unit

In order to achieve the above object, the present invention, in the combustion control apparatus of the hot stove to generate a high temperature heat by burning the mixed gas of the coke gas (COG) and blast furnace gas (BFG), the atmospheric air supplied to the combustion chamber,

Coke gas calorie detection unit for detecting the heat of the coke gas, blast furnace gas calorie detection unit for detecting the heat of the blast furnace gas, coke gas calorie detection detected by the coke gas calorie detection unit and the blast furnace gas calorie detection unit A mixing ratio calculator configured to receive a detection calorific value of the blast furnace gas and calculate a mixing ratio, which is a ratio of the flow rate of the coke gas to the flow rate of the blast furnace gas, according to a preset heat quantity of the mixed gas, and a horn calculated by the mixing ratio calculator A coke gas flow rate control unit for controlling the flow rate of the coke gas according to a small rate, and controlling the flow rate of the mixed gas so that the dome temperature of the hot stove rises to a predetermined target dome temperature for a preset time, and the target dome temperature A dome temperature calculation control unit for controlling a flow rate of the atmospheric air to maintain a constant; It characterized in that the exhaust gas temperature provides a combustion control device to the hot air containing the exhaust gas temperature calculation control unit for controlling the flow rate of the mixed gas for a predetermined amount of time, after a predetermined target constant raised to the exhaust gas temperature to be kept constant.

In addition, the hot stove combustion control device,

Characterized in that it further comprises a mixed gas calorie setting unit for setting the heat of the mixed gas in advance.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration of the hot stove combustion control apparatus according to the present invention. In the drawings referred to in the following description, components having substantially the same configuration and function will use the same reference numerals.

2 is a configuration diagram of a hot stove combustion control apparatus according to the present invention, referring to FIG. 2, the present invention detects a heat amount of the mixed gas calorific value setting unit 201 and a coke gas calorific value. The coke gas calorie detection unit 204, the blast furnace gas calorie detection unit 205 for detecting the calorific value of the blast furnace gas, the coke gas calorie detection unit 204, and the calorie gas detected by the coke gas calorie detection unit 204. A mixing ratio calculation unit 202 for receiving a detection calorific value of the blast furnace gas detected by 205 and calculating a mixing ratio that is a ratio of the flow rate of the coke gas to the flow rate of the blast furnace gas according to a preset calorific value of the mixed gas; Coke gas flow control unit 203 for controlling the flow rate of the coke gas according to the mixing rate calculated by the mixing rate calculation unit 202, and the target dome for a predetermined time for the dome temperature of the hot stove A dome temperature calculation control unit 206 for controlling the flow rate of the mixed gas so as to constantly rise to a temperature, and controlling the flow rate of the atmospheric air to maintain the target dome temperature constant, and the exhaust gas temperature of the hot stove is set in advance. And a flue gas temperature calculation control unit 207 for controlling the flow rate of the mixed gas so as to constantly increase to a predetermined target flue gas temperature for a time and then maintain a constant.

The operation of the hot stove combustion control apparatus according to the present invention configured as described above will be described in more detail with reference to FIG. 2.

First, when combustion of the hot stove starts, the facility operator sets the flow rate of the mixed gas of coke gas and blast furnace gas supplied from the mixed gas flow rate setting unit 101 to the combustion chamber, and the mixed gas set flow rate is the mixed gas flow rate control unit. Input to the 105, the mixed gas flow rate control unit 105 receives the flow rate of the mixed gas supplied from the mixed gas flow rate detector 127 to adjust the opening and closing amount of the mixed gas supply valve 126, the actual combustion chamber 122 The flow rate of the mixed gas supplied to the control unit is controlled to be kept constant at the mixed gas set flow rate. At the same time, the atmospheric air is supplied to the combustion chamber 122 according to the air-fuel ratio set by the air-fuel ratio setting unit 104 where the ratio of the flow rate of the atmospheric air to the mixed gas set flow rate set by the mixed gas flow rate setting unit 101 is set. The supplied atmospheric air is detected by the atmospheric air flow rate detector 124 and is constantly controlled by adjusting the opening / closing amount of the atmospheric air supply valve 125 by the air flow controller 103.

As soon as the mixed gas is supplied to the combustion chamber, the flow rate control of the coke gas and the blast furnace gas is made according to the heat amount of the mixed gas. The mixing rate calculation unit 202 receives the calorific value of the coke gas and the calorific value of the blast furnace gas supplied from the coke gas calorie detection unit 204 and the blast furnace gas calorie detection unit 205, respectively, and is set in the mixed gas calorie setting unit 201. The flow rate ratio of the coke gas to the flow rate of the blast furnace gas is calculated according to the result of the mixed gas calorific value. For example, if the calorific value of the blast furnace gas is not changed but the heat quantity of the coke gas is increased, the flow rate ratio of the coke gas to the flow rate of the blast furnace gas is reduced, on the contrary, if the calorific value of the blast furnace gas is unchanged but the heat quantity of the coke gas is reduced. The flow rate of the coke gas to the flow rate of the blast furnace gas is increased to keep the heat quantity of the mixed gas constant. Similarly, the calorific value of coke gas remains unchanged, but if the calorific value of the blast furnace gas increases, the coke gas flow rate increases with respect to the flow rate of the blast furnace gas. By reducing the flow rate ratio of the coke gas to the flow rate of to keep the heat amount of the mixed gas constant.

The reason for calculating the flow ratio of the coke gas to the flow rate of the blast furnace gas is to control the flow rate of the coke gas only by controlling the flow rate of the coke gas without installing a flow rate detector and a flow control valve for controlling the flow rate in the line where the blast furnace gas is supplied. This is to implement calorie control.

On the other hand, when combustion is started, the dome temperature calculation control unit 206 controls the dome temperature of the hot stove. The dome temperature calculation control unit 206 controls the flow rate of the mixed gas so that the dome temperature of the hot stove rises up to a predetermined target dome temperature for a predetermined time, and maintains the target dome temperature at a constant temperature. To control the flow rate. In more detail, the dome temperature detected by the dome temperature detector 140 is input to the dome temperature calculation control unit 206, and the dome temperature calculation control unit 206 is currently detected and the target dome temperature set in advance. Calculate the difference. Subsequently, the dome temperature calculation control unit 206 calculates a dome temperature increase ratio according to a time for raising the target dome temperature from the current dome temperature for a predetermined time. This is to prevent damage to the hot stove facility that may occur due to the rapid rise of the dome temperature. The dome temperature calculation control unit 206 controls the flow rate of the mixed gas by varying the set flow rate set by the mixed gas flow rate setting unit 101 according to the calculated dome temperature rise ratio.

As described above, the mixed gas supplied through the mixed gas set flow rate control of the dome temperature calculation control unit 206 is combusted in the combustion chamber 122, and gradually increases the temperature of the heat stored in the heat storage chamber 123, thereby increasing the temperature of the dome temperature detector. When the dome temperature detected by 140 reaches a preset temperature, the dome temperature calculation control unit 206 increases the flow rate of the atmospheric air supplied to the combustion chamber 122 through the air flow control unit 103, thereby increasing the dome temperature. Maintain constant at preset target dome temperature.

When the dome temperature reaches the preset target dome temperature through the dome temperature control of the dome temperature calculation control unit 206, the control of the exhaust gas temperature by the exhaust gas temperature calculation control unit 207 is started. The exhaust gas temperature calculation control unit 207 controls the flow rate of the mixed gas so that the exhaust gas temperature of the hot blast furnace is constantly raised to a predetermined target exhaust gas temperature for a preset time and then remains constant. In more detail, the flue gas temperature detected by the flue gas temperature detector 130 is input to the flue gas calculation controller 207, and the flue gas temperature calculation controller 207 is the flue gas temperature currently detected and a target flue gas which is set in advance. Calculate the difference in temperature. Subsequently, the exhaust gas temperature calculation control unit 207 calculates the exhaust gas temperature increase ratio according to the time for raising the target exhaust gas temperature from the current exhaust gas temperature for a predetermined time. This is to prevent damage to the hot stove facility that may occur due to the rapid rise of exhaust gas temperature. The exhaust gas temperature calculation control unit 207 controls the flow rate of the mixed gas by varying the set flow rate set by the mixed gas flow rate setting unit 101 according to the exhaust gas temperature increase ratio calculated as described above to maintain the exhaust gas temperature constant. .

According to the present invention as described above, by controlling the flow rate ratio of the coke gas and blast furnace gas according to the heat quantity fluctuation of the coke gas and blast furnace gas constituting the mixed gas, even if the heat quantity fluctuation of the mixed gas occurs, It has the effect of enabling heat storage. In addition, by preventing the rapid rise of the dome temperature and the exhaust gas temperature, there is an excellent effect of preventing damage to the hot stove facility and extending the life.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be apparent to those of ordinary skill in Esau.

Claims (2)

In the combustion control apparatus of a hot stove that generates a high temperature heat by receiving a mixed gas of coke gas (COG) and blast furnace gas (BFG) and the atmospheric air supplied to the combustion chamber, A coke gas calorie detection unit for detecting a heat quantity of the coke gas; Blast furnace gas calorie detection unit for detecting the heat of the blast furnace gas; The flow rate of coke gas with respect to the flow rate of the blast furnace gas according to the calorific value of the mixed gas is input in accordance with the heat quantity of the coke gas detected by the coke gas calorie detection unit and the calorific value of blast furnace gas detected by the blast furnace gas calorie detection unit A mixing rate calculation unit for calculating a mixing ratio that is the ratio of the mixing ratio; A coke gas flow rate controller configured to control the flow rate of the coke gas according to the mix rate calculated by the mixing rate calculator; Dome temperature calculation for controlling the flow rate of the mixed gas so that the dome temperature of the hot stove is constantly raised to a predetermined target dome temperature for a predetermined time, and the flow rate of the atmospheric air to maintain the target dome temperature constant Control unit; And And a flue gas temperature calculation control unit configured to control the flow rate of the mixed gas so that the flue gas temperature of the hot stove is constantly raised to a predetermined target exhaust gas temperature for a predetermined time and then maintained constant. According to claim 1, The hot stove combustion control device, And a mixed gas calorific value setting unit for presetting a heat quantity of the mixed gas in advance.