JPS61243219A - Combustion control method for radiant tube burner - Google Patents

Abstract

PURPOSE:To prevent combustion gas from being mixed into processing gas in a heat treatment furnace even in case of occurrence of crack or the like in a radiant tube and to cause the gas to be drawn into the radiant tube to make a flow rate of the ambient gas minimum by a method wherein a pressure of discharged gas is adjusted in such a way as a pressure in the radiant tube becomes always a constant low negative value. CONSTITUTION:A combustion discharged gas flow rate Vwg and a representative value T1 of a discharging gas temperature in a radiant tube are calculated, and a total pressure loss DELTAPt of the radiant tube 12 and the discharged gas ducts 13 and 15 is calculated. A target pressure Po in the tube 12 is set and then a target discharged gas pressure Pg at a discharged gas pressure sensing point of the collecting discharged gas duct 15 is calculated in response to the target pressure Po and the pressure loss DELTAPt. A degree of opening of a pressure adjusting damper 25 is adjusted such that an actual discharged gas pressure P becomes a target discharged gas pressure Pg in response to the target discharged gas pressure Pg and the actual discharged gas pressure Pg. A pressure in the tube 12 is always controlled to a low negative pressure Po in respect to the ambient gas pressure in the heat treatment furnace 10.

Description

[Detailed description of the invention]

[Industrial Application Field 1] The present invention relates to a combustion control method for a radiant tube burner, and particularly relates to a quenching furnace for thick steel plates, a continuous annealing furnace for cold rolled steel plates,
Combustion control method for a radiant tube burner in a heat treatment furnace used to heat treat heat treated materials in atmospheric gas, suitable for use in non-oxidation heat treatment of thick steel plates and cold rolled steel plates in a continuous heat treatment furnace for silicon steel, etc. Regarding improvements. [Prior Art] When heat-treated materials such as metal steel strips are subjected to non-oxidation heat treatment,
A heat treatment furnace filled with various atmospheric gases (for example, H2+N2) determined by heat treatment conditions is used. As a heating source for the heat treatment furnace, a radiant tube is used which is disposed so as to penetrate inside the furnace. A burner causes high-temperature combustion gas to flow inside the radiant tube, and the heat of the combustion gas is transferred into the heat treatment furnace through the radiant tube. As the material of the radiant tube, tubes made of various heat-resistant steels and ceramics are used. However, cracks often occur due to oxidation and deformation caused by high temperatures. By the way, combustion control methods for conventional radiant tube burners include the pull method, bushing method, and bushing method.
This is done using a pull method, etc. The combustion control method using the pull method uses a suction fan or an ejector to control the pressure inside the radiant tube from -50 to -
This is done by creating a negative pressure of about 200 nHzO and sucking combustion air through the air intake port of the burner section attached to the radiant tube inlet to combust the fuel. In addition, in the combustion control method using the Bush method, combustion air is forced into the radiant tube by a fan, and the pressure P in the radiant tube is increased by +10 to 501.
This is done by applying a positive pressure of 1H20. In addition, in the combustion control method using the bush-pull method, combustion air is introduced into the radiant tube by a forced fan, and combustion gas is exhausted by an exhaust fan, ejector, etc., so that the pressure inside the radiant tube is increased from -50 to f). -18
This is done by controlling the pressure to about 0mi+H20 Wl (D negative pressure).

[Problems to be Solved by the Invention] However, in the case of the pull method, the negative pressure P in the radiant tube is proportional to the square of the combustion amount, so if a crack occurs in the radiant tube, the combustion amount will decrease. There is a problem in that the negative pressure increases as the temperature increases, and the negative pressure causes a large amount of atmospheric gas in the heat treatment furnace to flow into the radiant tube, consuming a large amount of atmospheric gas. In addition, in the case of the Bush method, the pressure P inside the radiant tube is proportional to the square of the amount of combustion, so if a crack occurs in the radiant tube, the pressure increases as the amount of combustion increases. There is a problem in that a large amount of combustion gas flows into the heat treatment furnace due to the pressure and mixes with the atmospheric gas, contaminating the atmospheric gas, making non-oxidation heat treatment impossible and making the furnace inoperable. In addition, in the case of the bush-pull method, the pressure inside the radiant tube is set to be negative at any time, taking into account the range of operational fluctuations, and if a crack occurs in the radiant tube, the heat treatment furnace Since the atmospheric gas pressure inside the radiant tube is approximately +10 nHzO, similar to the pull method, the atmospheric gas is sucked into the radiant tube due to the pressure difference between the heat treatment furnace and the radiant tube, resulting in a large amount of atmospheric gas being consumed. have Purpose of the Invention The present invention has been made to solve the above-mentioned conventional problems, and even if cracks or pinholes occur in the radiant tube, the combustion inside the radiant tube can be prevented by the atmospheric gas in the heat treatment furnace. It is an object of the present invention to provide a combustion control method for a radiant tube burner that can minimize the flow rate of atmospheric gas in a heat treatment furnace that is sucked into the radiant tube and consumed without introducing gas.

[Means to solve the problem]

The present invention relates to a combustion control method for a radiant tube burner in a heat treatment furnace used when heat-treating materials in an atmospheric gas.As shown in FIG. The above objective is achieved by determining the pressure loss in the exhaust gas duct and adjusting the exhaust gas pressure based on the pressure loss so that the pressure in the radiant tube is always a constant slight negative pressure with respect to the furnace internal pressure. This is what I did. Further, in an embodiment of the present invention, the pressure loss is reduced by a fuel flow rate,
By calculating based on the combustion air flow rate, furnace temperature, and exhaust gas temperature in the exhaust gas duct, pressure loss can be easily and accurately determined. Further, in an embodiment of the present invention, the constant minute negative pressure is -
By setting the value to 5 to -10 nH20, it is possible to efficiently prevent combustion gas from being mixed into the furnace atmosphere gas and reduce the amount of atmospheric gas flowing into the radiant tube.

[Effect]

In the combustion control of a radiant tube burner, the present invention calculates the pressure loss in the exhaust gas duct from immediately after the burner in the radiant tube to the exhaust gas pressure measurement position, and based on the pressure loss, the pressure in the radiant tube is determined relative to the furnace pressure. The exhaust gas pressure is adjusted so that a constant slight negative pressure is maintained at all times. Therefore, even if a crack occurs in the radiant tube, combustion gas will not be mixed into the furnace atmosphere gas, and the amount of atmospheric gas flowing into the radiant tube can be minimized. In the present invention, it is necessary to accurately grasp the pressure inside the radiant tube in order to ensure that the pressure inside the radiant tube is always a constant minute negative pressure with respect to the furnace internal pressure. Note that the exhaust gas pressure within the radiant tube increases as it goes downstream of the exhaust gas duct, as an example of which is shown in FIG. Therefore, by calculating this pressure drop, the exhaust gas pressure within the radiant tube can be estimated. Next, a method of calculating the exhaust gas pressure of the radiant tube will be described. First, the pressure drop ΔP from immediately after the burner in the radiant tube to the collective exhaust gas duct as the exhaust gas pressure measuring part
Calculate t. The pressure drop Δpt can be calculated using the following relationship. In addition, in the following formula, the subscript of each symbol is 1, which indicates the gas inside the radiant tube, 2, which indicates the exhaust gas in the exhaust gas duct on the outlet side of the radiant tube, and 3, which indicates the exhaust gas in the radiant tube. The duct one is shown. ΔPt-φ1・Vw82nd T1+φ2φ■wg2XT2
+φ3・Vwg2・T3・・・・・・(1) Here, φ
1 to φ3 are the pressure loss coefficients of each part determined by the dimensions such as the inner diameter and length of the radiant tube and the duct of the radiant tube. ■1 to T3 are the exhaust gas concentration (K>, G
o is the theoretical wet exhaust gas amount (N♂/Nm"), Ao is the theoretical air amount of fuel (N w' / N"), Vr is the fuel flow rate (N1/h), l is the air ratio, and Vwg is the Shows the fuel exhaust gas flow rate (Nr/h). Note that the air ratio - can be calculated from the relationship of the following equation. m - Va / (AoVr >..." - (2) Here, Va is the combustion air flow rate (Nm'/h). Also, the fuel exhaust gas flow rate Vwg is calculated using the relationship of the following formula. Vwg= (Go+ (1-1)Ao)Vr" (3) Since the combustion exhaust gas duct is normally kept warm, the temperature of the exhaust gas duct on the radiant tube exit side T2
Since and the temperature T3 of the collective exhaust gas duct are approximate, the above equation (1) can be simplified as follows. ΔP-φ1■wg2・T1 (Σφ)Vwg'XT2・
・・・・・・・・・・・・(4) Here, Σφ is the sum of the pressure loss coefficients from the outlet of the radiant tube to the collective exhaust gas duct, which is the exhaust gas pressure detection position, and Determined by the size and shape of Furthermore, since it is impossible to directly measure the combustion gas temperature T1 (representative value) in the radiant tube, it is usually calculated using the relationship shown in the following equation. T 1" T g+α (5) Here, Tg is the heat treatment furnace temperature at steady state, and α is approximately determined by the type of radiant tube, and is usually 50 to 100. C. Based on the pressure loss ΔPt of the radiant tube obtained from the above equation (1) and the target pressure Po inside the radiant tube, the target value Pg of the exhaust gas pressure is calculated from the relationship of the following equation. Pg=Po+ΔP t = ...= (6) Note that the target pressure Po in the radiant tube is usually -5 to -1
Although it is set to 0 nHzO, it is necessary to determine it with a margin depending on the accuracy of the entire control system. As described above, the target value Pg of the exhaust gas pressure in the collective exhaust gas duct as the exhaust gas pressure measurement unit is determined, and the exhaust gas pressure is adjusted based on the target value Pg and the measured pressure value. To adjust the exhaust gas pressure, adjust the opening of the pressure adjustment damper,
This can be done by adjusting the rotation speed of the exhaust fan or by using a combination of these.

【Example】

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a heat treatment furnace using a radiant tube, in which a combustion control device for a radiant tube burner according to the present invention is adopted, will be described in detail below with reference to the drawings. As shown in FIG. 3, this embodiment includes a plurality of radiant tubes 12 arranged in a heat treatment furnace 10, a burner 14 that burns fuel within the radiant tube 12, and a fuel flow rate to the burner 14. A fuel flow rate adjustment valve 16 that adjusts, a fuel flow meter 17 that measures the fuel flow rate to the burner 14, and an air flow rate adjustment valve 1 that adjusts the air flow rate to the burner 14.
8, an air flow meter 19 that measures the flow rate of combustion air sucked into the burner 14 via the fan 21, and a combustion control that controls the regulating valves 16 and 18 to adjust the temperature inside the heat treatment furnace 10. Based on the device 20, a thermometer 22 that measures the temperature within the collective exhaust gas duct 15, and a pressure gauge 24 that also measures the exhaust gas pressure within the collective exhaust gas duct 15, and the output signals of these thermometers 22 and pressure gauges 24, An exhaust gas pressure control device 26 that adjusts the pressure of exhaust gas using a pressure adjustment damper 25, and a combustion control bag that measures the temperature inside the heat treatment furnace 10 with a thermometer 27 and adjusts the inside of the heat treatment furnace 10 to a specified temperature. @20 and exhaust gas pressure control device 26
The exhaust fan 30 is connected to the rear of the pressure regulating damper 25 and discharges exhaust gas to a chimney 32 or the like. Next, the operation of this embodiment will be explained. First, based on the fuel flow rate Vf from the fuel flow meter 17, the combustion air flow rate Vα from the air flow meter 19, and the theoretical air IAo and theoretical wet exhaust gas amount Go determined by the fuel, (3) From the relationship of the formula, the fuel exhaust gas flow rate Vw
Calculate ge. Next, the furnace temperature Tg measured by the thermometer 27 inside the heat treatment furnace 10 is
The representative value T1 of the exhaust gas temperature in the radiant tube is calculated from the relationship of equation (5) above based on the constant α that is approximately determined by the type of the radiant tube. Based on the exhaust gas temperature T2 from the total 22 and the pressure loss coefficients φ1 and Σφ of the radiant tube 12 and the exhaust gas duct 13.15, the total pressure loss of the radiant tube 12 and each exhaust gas duct 13.15 is calculated from the equation (4) above. Calculate ΔPt. Next, a target pressure PO in the radiant tube 12 is set, and based on the target pressure Po and the pressure loss ΔPt, the target pressure at the exhaust gas pressure detection point of the collective exhaust gas duct 15 is determined from the relationship of equation (6) above. Calculate exhaust gas pressure Pg. Next, based on the giant exhaust gas pressure Pg and the actual exhaust gas pressure P from the exhaust gas pressure gauge 24, the opening degree of the pressure adjustment damper 25 is adjusted so that the actual exhaust gas pressure P becomes the target exhaust gas pressure Pg. Therefore, by calculating the target exhaust gas pressure Pg at the exhaust gas pressure gauge 24 position of the collective exhaust gas duct where exhaust gas pressure can be measured, and adjusting the exhaust gas pressure by comparing the target exhaust gas pressure Pg and the actual exhaust gas pressure P. , it becomes possible to accurately adjust the pressure in the radiant tube 12, where it is difficult to directly measure the exhaust gas pressure. As a result, even if the operating conditions of the heat treatment furnace 10 change, the pressure inside the radiant tube 12 can always be controlled to a minute negative pressure PO with respect to the atmospheric gas pressure inside the heat treatment furnace 10. Therefore, even if a crack occurs in the radiant tube 12, the combustion gas in the radiant tube 12 will not flow into the atmospheric gas in the heat treatment furnace 10 and contaminate the atmospheric gas, thereby preventing the operation from being stopped. , heat treatment furnace 10
The amount of atmospheric gas flowing into the radiant tube 12 from within can also be minimized. In the above embodiment, the exhaust gas pressure is adjusted by adjusting the opening degree of the pressure regulating damper 13, but the present invention is not limited to this, and for example, the exhaust gas pressure is adjusted by adjusting the rotation speed of the exhaust fan 30. Alternatively, the adjustment may be performed in combination with the opening degree adjustment of the pressure adjustment damper 25 and the rotation speed adjustment of the exhaust fan 30.

【Effect of the invention】

As explained above, according to the present invention, even if a crack occurs in the radiant tube in a heat treatment furnace using atmospheric gas, the pressure inside the radiant tube is always kept at a minute negative pressure with respect to the pressure inside the heat treatment furnace. Since the heat treatment furnace is controlled, combustion gas and combustion air will not flow into the heat treatment furnace and the operation will become impossible, and the amount of atmospheric gas used can be suppressed to the minimum amount, which is an excellent effect.

[Brief explanation of drawings]

FIG. 1 is a flowchart showing the gist of the combustion control device for a radiant tube burner according to the present invention, and FIG. 2 is a diagram showing the pressure drop in the radiant tube and exhaust gas duct for explaining the present invention in detail. FIG. 3 is a front view, including a partial block diagram, showing the overall configuration of an embodiment of a heat treatment furnace to which the present invention is adopted. DESCRIPTION OF SYMBOLS 10... Heat treatment furnace, 12... Radiant tube, 14... Burner, 20... Combustion control device, 21... Forced fan, 25... Pressure adjustment damper, 26... Exhaust gas pressure control Device, 28... Furnace temperature indication adjustment device, 30... Exhaust fan.

Claims (3)

[Claims] (1) In a combustion control method for a radiant tube burner in a heat treatment furnace used when heat treating materials in an atmospheric gas, the pressure loss in the exhaust gas duct from immediately after the burner in the radiant tube to the exhaust gas pressure measurement position is determined, and the A combustion control method for a radiant tube burner, which is characterized by adjusting exhaust gas pressure based on pressure loss so that the pressure in the radiant tube is always a constant slight negative pressure with respect to the furnace pressure. (2) The combustion control method for a radiant tube burner according to claim 1, wherein the pressure loss is calculated based on the fuel flow rate, the combustion air flow rate, the furnace temperature, and the exhaust gas temperature in the exhaust gas duct. (3) The constant minute negative pressure is -5 to -10 mmH_
A combustion control method for a radiant tube burner according to claim 1 or 2, in which the temperature is set to 2O.