JPS645216B2 - - Google Patents

Description

[Detailed description of the invention] The present invention relates to a combustion control device for a combustor.

Generally, in gas combustion machines used for hot water supply and space heating, such as hot water boilers, when the operation switch is turned on, a safety timer circuit is activated, which activates the igniter for a certain period of time and turns on the burner. Gas supply is started, and combustion operation is started by igniting the burner, and at the same time as the safety timer circuit is activated, a flame detection circuit is activated, and the gas supply to the burner is controlled according to the flame detection result. There is something I did.

By the way, in such a combustion machine, if the combustion flame of the burner fluctuates, the flame detection circuit may erroneously detect it as a misfire, and the combustion operation may be stopped unnecessarily. Therefore, the flame detection circuit is usually provided with a misfire detection time, and the combustion operation is stopped only when the misfire detection continues for a predetermined period of time. However, in this case, even if the burner actually misfires, the gas supply to the burner continues during the misfire detection time of the flame detection circuit, which may cause the following problem. In other words, when a burner actually misfires, if the user immediately confirms the misfire and starts combustion (that is, turns the operation switch off and on again) within the misfire detection time, there is a possibility that the gas pipe near the burner may still be in contact with the burner. The remaining unburned gas is rapidly pushed out by the new gas supply, resulting in explosive ignition and accompanying abnormal noise.

This invention was made in view of the above-mentioned circumstances, and its purpose is to prevent explosive ignition and the generation of abnormal noise associated with it, even if the combustion start operation is performed immediately in the event of a misfire. An object of the present invention is to provide a combustion control device with excellent safety that can prevent the above.

An embodiment of the present invention will be described below with reference to the drawings.

In Figure 1, 1 is an AC power supply, and this power supply 1
The igniter 3 is connected to the igniter 3 via the operation switch 2 and the relay contact 32a in series. Furthermore, a rectifier circuit 4 is connected to the power source 1 through the operation switch 2 and the relay contact 35a in series, and an electromagnetic valve 5, which is a fuel supply device, is connected to the output end of the rectifier circuit 4. Although not shown, the solenoid valve 5 is provided in a gas pipe between a fuel (gas) supply source and a burner, and is configured to supply gas to the burner by being energized and opened. The gas supplied to the burner is then ejected and ignited by the igniter 3. Thus, when the burner ignites, its combustion flame heats a load (eg, a water heat exchanger, etc.).

Furthermore, the primary side of a transformer 6 is connected to the power source 1 via the operation switch 2, and the rectifier circuit 7 is connected to the secondary side of the transformer 6. A safety timer circuit 10 is connected to the output end of the rectifier circuit 7.
The flame detection circuit 33 is connected to the NPN transistor 32 through the collector and emitter of the NPN transistor 31.
A relay 35 is connected between the collector and emitter of the type transistor 34, respectively. The base of the transistor 31 is connected to the output terminal of the safety timer circuit 10, and the base of the transistor 34 is connected to the output terminal of the flame detection circuit 33. Further, a diode 36 is connected between the collectors of the transistors 31 and 34 in the illustrated polarity.

FIG. 2 shows details of the safety timer circuit 10.

That is, the safety timer circuit 10 includes resistors 41,
A first time constant circuit that obtains a voltage that increases with the time constant of a resistor 42 and a capacitor 43, and a resistor 44 (resistance value
_R1 ), a capacitor 45, and a resistor 46 (resistance value _R2 ). The comparator 47 compares the voltage of the two time constant circuits (the voltage obtained at the connection point B) with the comparator 47, and is operated by being energized when the operation switch 2 is turned on.

In this case, as shown in FIG. 3, the voltage of the first time constant circuit increases exponentially. In contrast,
The voltage of the second time constant circuit becomes a voltage of V·{R ₂ /(R ₁ +R ₂ )} at the start of energization, and then increases with a predetermined time constant. That is, the voltage of the second time constant circuit increases with respect to the voltage of the first time constant circuit at a high level at first, a low level in the middle, and then a high level.

Thus, the output of the comparator 47 becomes a logic "0" for the first t ₁ hour, a logic "1" for the next t ₂ hours, and finally a logic "0", and based on the output, the safety time t ₁ and the ignition time t are determined. ₂ are set sequentially.

Note that the safety time t ₁ is set to be longer than the misfire detection time t ₀ of the flame detection circuit 33 (true misfire detection is only made when misfire detection continues for t ₀ time).

Next, the operation of the above configuration will be explained with reference to FIG.

Now, when the operation switch 2 is turned on, the safety timer circuit 10 is activated, and the relays 32 and 35 are energized at the ignition time _t2 , which is _one hour after the safety time t. Then, the igniter 3 is operated by closing the contacts 32a and 35a, and the solenoid valve 5 is opened. That is, gas is supplied to the burner, and the gas ejected from the burner is ignited by the igniter 3.
When the ignition time _t2 of the safety timer circuit 10 has elapsed, the relay 32 is de-energized and the igniter 3 stops operating. At this time, the flame detection circuit 33 is operating, and if the burner ignition is completed within the ignition time t ₂ hours, the output of the flame detection circuit 33 becomes a logic "1" signal and the relay 35 is activated. Excitation continues and gas supply to the burner continues. However, if the ignition of the burner is not completed within time _t2 , the relay 35 is also deenergized as the relay 32 is deenergized, and the solenoid valve 5 is closed. This means that the gas supply to the burner is stopped and
Combustion operation will stop. In this way, safety is ensured when the fuel is not ignited.

On the other hand, when the ignition is completed and the combustion operation continues, if the burner misfires due to blowout or the gas pipe being pressed down, the flame detection circuit 33 detects this. At this time, the flame detection circuit 33
In order to prevent false detection due to fluctuations, etc., the output is set to a logic "0" signal after the misfire detection time _t0 , and the solenoid valve 5 is closed. Therefore, in this case, if the burner actually misfires, unburned gas will remain in the gas pipe near the burner. Therefore, if a combustion start operation (turning off the operating switch 2 and then turning it on again) is performed within this misfire detection time, there is a risk of causing explosive ignition and abnormal noise as described above. However, in this invention, the solenoid valve 5 is not opened and the igniter 3 is not operated until a safety time t ₁ hour (longer than the misfire detection time t ₀ ) has elapsed since the operation switch 2 was turned on. Residual gas can be released within _one hour, and explosive ignition and abnormal noise can be prevented from occurring at the time when the solenoid valve 5 is opened and the igniter 3 is operated, that is, at the time of ignition.

In particular, the safety timer circuit 10 is designed to obtain two times, the safety time t ₁ and the ignition time t ₂ , with a simple configuration of only two time constant circuits and one comparator, reducing the number of parts and reducing the number of parts. In turn, it is possible to reduce costs.

In this way, open types that do not have a combustion blower or
In the case of a BF combustor, the pre-purge time is not ensured, so the adoption of the technology of the present invention is extremely effective in ensuring safety.

In addition, the present invention is not limited to the above-mentioned embodiments, and it goes without saying that various modifications can be made without changing the gist.

As described above, according to the present invention, the safety time t ₁ from when the combustion start operation is performed until the igniter and the fuel supply device are operated is obtained by the safety timer circuit, and the safety time t ₁ is obtained from the flame detection circuit. Since the misfire detection time t is set to ₀ or more, even if combustion is started immediately in the event of a misfire, explosive ignition and the accompanying abnormal noise can be prevented, resulting in excellent safety. A combustion control device can be provided.

[Brief explanation of drawings]

The drawings show one embodiment of the invention.
The figure is a configuration diagram, Figure 2 is a configuration diagram showing the safety timer circuit in detail, Figure 3 is a signal waveform diagram to explain the operation in Figure 2, and Figure 4 is a diagram to explain the main operation. be. 2... operation switch, 3... igniter, 5... fuel supply device (electromagnetic valve), 10... safety timer circuit,
33... Flame detection circuit, t ₀ ... Misfire detection time.

Claims (1)

[Claims] 1. In a combustor that uses an igniter to ignite a burner supplied with fuel by a fuel supply device and heats a load with the combustion flame of this burner, there is an operation switch and a first switch that obtains a voltage that increases at a predetermined time constant. A time constant circuit, a second time constant circuit that obtains a voltage that is initially at a high level, becomes a low level midway through, and then rises to a high level with respect to the voltage of the first time constant circuit, and the voltage of this first time constant circuit. and _the voltage of _the second time constant circuit; Ignition time of safety timer circuit
At t ₂ , means for operating the fuel supply device and the igniter, and upon detecting the combustion flame of the burner, continue the operation of the fuel supply device, detect a misfire of the burner, and this state continues for a misfire detection time t ₀ or more. and a flame detection circuit for stopping the operation of a fuel supply device, the safety time t ₁ of the safety timer circuit being set to a misfire detection time t ₀ or more of the flame detection circuit.