JP2619044B2 - Temperature control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to a temperature control device for controlling the temperature in a heating furnace with a combustion burner mounted on an upper part and a combustion burner mounted on a lower part. About.

(Prior Art) For example, in a metal material annealing process, a metal material fed into a heating furnace is heated by a combustion burner attached to an upper portion and a lower portion so that the furnace temperature becomes uniform. .

FIG. 4 shows a conventional example of a temperature control system in such an annealing step. Burners 2a and 2b are installed at the upper and lower parts of the heating furnace 1, respectively. The burners 2a and 2b are supplied with air via air control valves 3a and 3b, respectively, and are supplied with fuel via fuel control valves 4a and 4b.

Each air control valve 3a, 3b is connected to the air controller 5
a, 5b are connected and controlled so that the air flow rate becomes a set value. The fuel control valves 4a and 4b are connected to the fuel controllers 6a and 6b, respectively, and are controlled so that the fuel flow becomes a set value.

In addition, temperature detectors 7a and 7b are installed in the upper and lower portions of the heating furnace 1, respectively, and the temperature controllers 8a and 8b
It is connected to the. Then, the temperature controller 8a for adjusting the temperature of the upper part obtains the set values of the air controller 5a and the fuel controller 6a so that the measured temperature value becomes equal to the set value, and outputs the set value as an operation signal. Both controllers 5a, 6a are based on this operation signal, the air flow rate, and the air control valve 3a, so that the fuel flow rate becomes a set value.
And the temperature in the heating furnace 1 is controlled by adjusting the fuel control valve 4a.

On the other hand, the operation signal output from the temperature controller 8a is supplied to the ratio calculator 9, and is guided to one end of the changeover switch 10 after being multiplied by a predetermined coefficient (about 1.1 to 1.3). The temperature controller 8b at the lower part of the heating furnace 1
The operation signal output from is connected to the other end of the changeover switch 10, one of them is selected and the air controller 5b,
An operation signal is supplied to the fuel controller 6b. During normal operation, this switch 10
Is connected to the ratio calculator 9 side.

Now, when the metal material 13 is fed into the heating furnace 1, it is heated by the upper and lower burners 2a and 2b. And
The temperature of the upper part of the heating furnace 1 is detected by the temperature detector 7a,
The temperature controller 8a outputs an operation signal so that the deviation between the set value and the detected value becomes zero.

The air controller 5a and the fuel controller 6a adjust the air flow and the fuel flow supplied to the burner 2a based on the operation signal.

Further, the ratio calculator 9 multiplies the operation signal output from the temperature controller 8a by a predetermined coefficient, and outputs the air controller 5b and the fuel controller 6b by this output signal.
Adjusts the flow rate of air supplied to the burner 2b and the flow rate of fuel. As a result, the combustion amount of the lower burner 2b is slightly larger than that of the upper burner 2a, and the temperature in the heating furnace 1, which is usually higher in the upper portion, is kept constant.

(Problems to be Solved by the Invention) However, in such a temperature control method, the combustion amount of the lower burner 2b is controlled so as to always be a constant ratio with respect to the combustion amount of the upper burner 2a. If the internal temperature changes suddenly, such as when a new metal material 13 is fed into the heating furnace 1, the lower temperature control cannot follow the upper temperature control, and as a result, as shown in FIG. However, the lower temperature in the heating furnace 1 deviates from the set value SV as indicated by PV in the figure.

For this reason, a temperature difference occurs in the metal material 13 to be heated,
There was a problem that the quality of the material was reduced.

The present invention has been made to solve such a conventional problem, and an object thereof is to stably control the upper and lower temperatures even when the temperature in a heating furnace changes suddenly. It is to provide a temperature control device which can be used.

[Means for Solving the Problems] To achieve the above object, the present invention provides an upper combustion burner for heating an upper part of a heating furnace, a lower combustion burner for heating a lower part of the heating furnace, Upper combustion control means for adjusting a fuel flow rate and an air flow rate supplied to the upper combustion burner; lower combustion control means for adjusting a fuel flow rate and an air flow rate supplied to the lower combustion burner; and an upper temperature of the heating furnace. , An upper temperature control means for outputting an operation signal to the upper combustion control means so that the measured temperature becomes equal to a set temperature, and an operation signal obtained by multiplying the operation signal by a predetermined coefficient and multiplying the operation signal by a coefficient. And a ratio calculating means for supplying the lower combustion control means to the lower combustion control means, the lower temperature of the heating furnace is measured, and an operation signal is output so that the measured temperature becomes equal to a set value. A lower temperature control means for,
An operation signal determining unit that determines whether an operation signal output from the upper temperature adjusting unit is greater than a predetermined value; and an output from the ratio calculating unit when the operation signal determining unit determines that the operation signal is greater than a predetermined value. And an adding means for adding the operating signal output from the lower temperature adjusting means to the operated signal.

(Operation) In the temperature control device according to the present invention, the operation signal determination unit determines whether the operation signal output from the upper temperature adjustment unit is larger than a predetermined value. Then, when it is determined that the ratio is larger, the operation signal output from the lower temperature control unit is added to the operation signal output from the ratio calculation unit to correct the operation signal.

The amount of combustion of the lower combustion burner is adjusted by the corrected operation signal. Therefore, even when the temperature in the furnace changes suddenly, the inside of the heating furnace can be maintained at a uniform temperature.

(Embodiment) FIG. 1 is a configuration diagram showing one embodiment of the present invention.

In FIG. 1, a heating furnace 1 is for applying a heat treatment to a metal material 13 fed into the inside thereof, and burners 2a and 2b are installed at an upper part and a lower part in the furnace, respectively. Each burner 2
Air and fuel are supplied to the pipes a and 2b through pipes. The air supply pipes are provided with air control valves 3a and 3b, and the fuel supply pipes are provided with fuel control valves 4a and 4b, respectively.

Air flow meters 11a and 11b are attached to the inlets of the air control valves 3a and 3b, and the detected values are used as feedback signals to control the air control valves 3a and 3b.
Supplied in 5b.

Fuel flow meters 12a and 12b are attached to the inlets of the fuel control valves 4a and 4b, and the detected value is used as a feedback signal to control the fuel control valves 4a and 4b.
Supplied to 6b.

Further, temperature detectors 7a and 7b are provided at the upper and lower portions of the heating furnace 1, respectively, and are connected to temperature controllers 8a and 8b for controlling the temperature in the furnace.

The temperature controllers 8a and 8b determine the upper temperature in the heating furnace 1,
The set values of the air flow rate and the fuel flow rate supplied to the burners 2a and 2b are determined so that the lower temperature becomes equal to the set value, and the set values are output as operation signals.

The operation signal output from the temperature controller 8a for adjusting the upper temperature is an air controller 5a, a fuel controller 6a, a ratio calculator 9 for multiplying the operation signal by a predetermined coefficient, and the operation signal is larger than a predetermined value. It is supplied to an operation signal determiner 14 for determining whether or not the operation is performed.

The operation signal multiplied by the coefficient by the ratio calculator 9 is
The signal is supplied to one end of the changeover switch 10 via an adder 15, and the other end of the changeover switch 10 is supplied with an operation signal output from the temperature controller 8b. In the case of normal operation, the changeover switch 10 is connected to the adder side.

When the operation signal output from the temperature controller 8a is equal to or greater than a predetermined value, the operation signal determiner 14 closes the contact 16 so that the operation signal output from the temperature controller 8b is sent to the adder 15. They are being supplied.

 Next, the operation will be described.

Now, the metal material 13 is fed into the heating furnace 1 and the burner
When heating by 2a and 2b is started, the temperature in the upper part of the furnace is detected by the temperature detector 7a, and this detection signal is supplied to the temperature controller 8a.

The temperature controller 8a obtains the set values of the air flow and the fuel flow supplied to the burner 2a so that the detected temperature becomes equal to the set values, and supplies these as operation signals to the air controller 5a and the fuel controller 6a.

The air controller 5a operates the air control valve 3a so that the air flow detected by the air flow meter 11a becomes equal to the given air flow set value. Similarly, in the fuel controller 6a, the fuel flow rate detected by the fuel flow meter 12a is
The fuel control valve 4a is operated so as to be equal to the given fuel flow rate set value.

Since the lower temperature in the heating furnace 1 is usually lower than the upper temperature, the ratio calculator 9 uses the upper burner 2a.
So that the burner 2b in the lower part has a larger amount of combustion than
The operation signal output from the temperature controller 8a is multiplied by a predetermined coefficient (about 1.1 to 1.3), and is output to the adder 15 as an operation signal.

When the heating furnace 1 is operating stably, the operation signal output from the temperature controller 8a has a small value, and the operation signal determiner 14 operates so that the contact 16 is opened. For this reason, the operation signal output from the ratio calculator 9 is directly supplied to the air controller 5b and the fuel controller 6b via the adder 15 and the changeover switch 10, and the combustion of the burner 2b is controlled.

On the other hand, when the furnace temperature fluctuates rapidly, such as when a new metal material 13 is fed into the heating furnace 1, the operation signal output from the temperature controller 8a becomes a large value, and the operation signal determination unit 14 Then, this is detected, and the contact 16 is operated so as to be “closed”.

As a result, the operation signal output from the temperature controller 8b is supplied to the adder 15 through the contact 16 and added to the operation signal output from the ratio calculator 9, and then supplied to the air controller 5b and the fuel controller 6b. The combustion of the burner 2b is controlled.

The characteristic diagram of the upper furnace temperature and the lower furnace temperature at this time is shown in FIG. 3, and even when the temperature in the heating furnace 1 changes suddenly, both the upper furnace temperature and the lower furnace temperature are stably controlled. .

As described above, in the present embodiment, when the temperature in the heating furnace 1 changes suddenly, the operation signal output from the ratio calculator 9 is corrected by the operation signal output from the temperature controller 8b. The lower furnace temperature is controlled.

Therefore, even if the furnace temperature changes suddenly, the upper furnace temperature,
And the lower furnace temperature can be controlled stably.
Can be maintained at a uniform temperature.

FIG. 2 is a block diagram showing another embodiment of the present invention. In this embodiment, a deviation calculator 17 for obtaining a deviation between the measured value of the upper furnace temperature and the set value is provided, and it is determined in the operation signal determiner 14 whether the obtained deviation is larger than a predetermined value. Contact 16 is being operated.

Therefore, as in the embodiment shown in FIG. 1, stable control is possible even when the furnace temperature changes suddenly.

[Effects of the Invention] As described above, in the present invention, when the temperature in the heating furnace changes suddenly, the operation signal output from the ratio calculation means is corrected by the operation signal output from the lower temperature adjustment means. The lower furnace temperature is adjusted by the corrected operation signal.

Therefore, when the furnace temperature changes suddenly, the control of the lower furnace temperature is not disturbed, and the control can be stably performed. As a result, the metal material can be heated at a certain temperature, and the quality of the material is significantly improved.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing one embodiment of the present invention, FIG. 2 is a configuration diagram showing another embodiment of the present invention, and FIG. 3 is a characteristic diagram showing a temperature in a heating furnace. FIG. 4 is a configuration diagram showing a conventional example, and FIG. 5 is a characteristic diagram showing a temperature in a conventional heating furnace. 1 Heating furnace, 2a, 2b Burner 5a, 5b Air controller 6a, 6b Fuel controller 7a, 7b Temperature detector 8a, 8b Temperature controller 9 Ratio calculator 14, … Operation signal judgment device 15… Adder, 16… Contact 17… Deviation calculator

Claims (1)

(57) [Claims] 1. An upper combustion burner for heating an upper part of a heating furnace, a lower combustion burner for heating a lower part of the heating furnace, and an upper combustion control means for adjusting a fuel flow rate and an air flow rate supplied to the upper combustion burner. Lower combustion control means for adjusting a fuel flow rate and an air flow rate supplied to the lower combustion burner; measuring an upper temperature of the heating furnace, and controlling the upper combustion control so that the measured temperature becomes equal to a set temperature. A temperature control unit that outputs an operation signal to the unit; and a ratio calculation unit that multiplies the operation signal by a predetermined coefficient and supplies the operation signal multiplied by the coefficient to the lower combustion control unit. A lower temperature control unit that measures a lower temperature of the heating furnace and outputs an operation signal so that the measured temperature becomes equal to a set value; and an output from the upper temperature control unit. When the work signal is determined and determining the operation signal determination means for determining whether greater than a predetermined value, the larger in the operation signal determination unit,
A temperature control device comprising: an adding unit that adds an operating signal output from the lower temperature adjusting unit to an operating signal output from the ratio calculating unit.