KR0155464B1 - Combustion device - Google Patents

Abstract

(Objective) Provides a combustion device in which reignition occurs even if a burner burns due to disturbances such as wind, and combustion is resumed.

(Configuration) The FF type gas warm air heater (A) is a small combustion amount in which a combustion fan supplying combustion air to a gas burner is rotated below a predetermined number of times, and the microcomputer (60) is connected to the frame rod (6). By detecting misfire of the gas burner, the sparker drive circuit 31, the solenoid valve drive circuit 110, and the proportional valve drive circuit 131 are instructed to perform re-ignition operation.

Description

Combustion device

1 is a configuration of the FF gas hot air heater according to an embodiment of the present invention.

2 is an explanatory view showing the shape of the FF gas-heated air heater from the top (a), front (b), end face (c) and back (d).

3 is a block diagram of the FF gas hot air heater.

4 is a flowchart showing the operation of the FF gas hot air heater.

* Explanation of symbols for main parts of the drawings

A: FF gas hot air heater (combustion device) 2: gas burner

3: sparker (ignition means) 4: combustion fan (blower)

5: combustion controller (combustion control means) 11: solenoid valve (fuel supply control means)

12: solenoid valve (fuel supply control means)

13 gas proportional valve (fuel supply control means)

50: microcomputer (combustion monitoring means)

The present invention relates to a combustion apparatus.

A gas burner supplied with gas through a gas safety valve and a gas proportional valve, a sparker for igniting the gas burner, a blower that sucks outside air for combustion air of the burner, and a blower of the blower The combustion controller responsible for the application of wind, high voltage to the sparker, and operation of the gas safety valve and the gas proportional valve, and the combustion state of the gas burner are monitored. When the misfire is detected, the gas safety valve is closed. Warm air having combustion monitoring means for interrupting the gas supply to the gas burner, and a convection fan that sucks indoor air and absorbs heat of the high temperature combustion exhaust gas and blows up the indoor air heated by warm air to the room. Heating devices are conventionally known.

By the way, the said conventional warm air heating apparatus has the inconvenience as shown below.

If the gas burner burns due to wind or the like during operation, safety is ensured because the combustion monitoring means shuts off the gas supply to the gas burner by closing the gas safety valve. However, after that, since heating operation is stopped, room temperature falls and a user feels uncomfortable.

An object of the present invention is to provide a combustion apparatus in which re-ignition is automatically performed and combustion is restarted even if the burner burns due to disturbances such as wind.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, this invention employ | adopted the following structures.

(1) a burner to which fuel is supplied via fuel supply adjusting means, ignition means for igniting the burner, combustion control means for controlling the operation of the ignition means and the supply capacity of the fuel supply adjusting means; And combustion monitoring means for monitoring the combustion state of the burner and instructing the fuel supply adjusting means to cut off fuel supply to the burner when the misfire is detected, and monitoring the combustion while the burner burns below a predetermined combustion amount. When the means detects misfire of the burner, the combustion control means performs a re-ignition operation.

(2) a burner at which the fuel is supplied via the fuel supply adjusting means, the ignition means for igniting the burner, and the rotational speed at which the amount of air suitable for the combustion amount instructed to supply the combustion air to the burner is obtained. A blower controlled to rotate, combustion control means for controlling the operation of the ignition means, the number of revolutions of the blower and the supply capacity of the fuel supply control means, and monitoring the combustion state of the burner and detecting misfire And combustion monitoring means for instructing the fuel supply adjusting means to cut off fuel supply to the burner, and when the combustion monitoring means detects misfire of the burner when the blower is rotating at a predetermined rotation speed or less, The combustion control means performs a re-ignition operation.

(3) With the configuration of (1) or (2) above, the combustion air of the burner is drawn from the outside, and the combustion exhaust is discharged to the outside.

(4) Reignition is detected when the misfire of the burner is detected before the set time has elapsed from the ignition of the burner, having the configuration of (1), (2) or (3).

(5) The re-ignition operation performed by the fuel control means having the configuration of (1), (2), (3) or (4) is within a predetermined number of times.

The combustion control means in claim 1 supports the fuel supply adjusting means so that fuel is supplied to the burner, and instructs the ignition means to ignite the burner to ignite the burner. Then, the combustion control means instructs the fuel supply adjusting means to burn the burner at a predetermined combustion amount. In addition, the combustion monitoring means monitors the burn state of the burner, and when the misfire is detected, instructs the fuel supply adjusting means to cut off the fuel supply to the burner.

If the burner was burning at the time of burning down at a predetermined combustion amount or less (as determined by the instruction value to the fuel supply adjusting means or the like), the combustion control means performs re-ignition operation. In addition, the re-ignition operation instructs the fuel supply adjusting means to supply fuel to the burner in the same manner as the initial ignition operation, and also instructs the ignition means to ignite the burner.

In claim 2, the combustion control means starts to blow the blower so that combustion air is supplied to the burner, instructs the fuel supply adjusting means to supply fuel to the burner, and instructs the ignition means to ignite the burner. Ignite the burner.

Then, the combustion control means instructs the fuel supply control means to burn the burner at a predetermined combustion amount by controlling the rotation speed of the blower so as to rotate at the rotation speed at which the blowing amount suitable for the indicated combustion amount is obtained.

In addition, the combustion monitoring means monitors the burn state of the burner, and when the misfire is detected, instructs the fuel supply adjusting means to cut off the fuel supply to the burner.

When the fan speed when the misfire is detected is less than or equal to the predetermined value, the combustion control means performs the re-ignition operation. In addition, the re-ignition operation starts energizing the blower so that combustion air is supplied to the burner in the same way as the initial ignition operation, and instructs the fuel supply adjusting means to supply fuel to the burner, thereby instructing the ignition means to ignite the burner. .

In claim 3, the combustion apparatus is a structure which sucks the combustion air of a burner from the outdoors, and discharges combustion exhaust to the outdoors. The re-ignition operation by the combustion control means is prevented when the combustion monitoring means detects misfire of the burner before the set time has elapsed from the ignition of the burner.

6. The re-ignition operation performed by the control means is within a predetermined number of claims.

Hereinafter, the effects of the present invention will be described.

If the burner burns down while the burner is below the predetermined combustion amount, the combustion monitoring means instructs the fuel supply adjusting means to cut off the fuel supply to the burner, but the combustion control means re-ignites so that combustion of the burner can be automatically resumed. There is a number.

In addition, if the burner burns in excess of the predetermined combustion amount, it is difficult to be affected by disturbance such as wind, and in the event of a misfire, there is a high possibility that the combustion apparatus has a cause, so that the combustion control means does not perform re-ignition operation. Doing.

Since the blower is controlled to rotate at the rotational speed at which the blowing amount appropriate to the fuel amount is obtained, in the case of the small combustion amount in which the blower is rotating below the predetermined rotational speed, the burner is liable to be affected by the wind.

When the burner burns, the combustion monitoring means instructs the fuel supply adjusting means or the like to cut off the fuel supply, but the combustion control means performs the re-ignition operation so that combustion of the burner can be automatically resumed.

In the case of a large combustion amount in which the blower is rotating above a predetermined rotation speed, it is difficult to be affected by wind or the like, and in the event of a misfire, there is a high possibility that the combustion apparatus has a cause. Do not do it.

In the case of a combustion apparatus which draws combustion air of the burner from the outdoors and discharges the combustion exhaust to the outdoors, combustion of the burner is susceptible to wind and the like. Therefore, in the combustion apparatus of such a structure, re-ignition in consideration of the influence of wind as mentioned above can greatly improve convenience.

If the misfire is detected before the set time has elapsed from the ignition of the burner, the combustion control means prohibits the re-ignition operation. This is because the combustion monitoring means does not perform the re-ignition operation when the burner is burned within the set time after ignition, because there is a high possibility that the combustion apparatus may be caused by the disturbance of the wind or the like.

It is prescribed that the re-ignition operation performed by the combustion control means is within a predetermined number of times. This is because even if the re-ignition operation is carried out for more than a predetermined number of times, it is likely that there is a cause on the combustion apparatus side under the influence of disturbance such as wind.

A first embodiment (corresponding to claims 1 to 5) of the present invention will be described with reference to FIGS.

The FF gas-heated air heater (A) shown in the drawing includes a gas burner (2) supplied with gas through a solenoid valve (11, 12), a gas proportional valve (13), a sparker (3) for ignition, and an outside air. A combustion controller 5 for controlling the intake combustion fan 4, the sparker 3, the combustion fan 4, the solenoid valves 11 and 12 and the gas proportional valve 13, and the combustion state Combustion monitoring means is provided. 71 is a warm air passage, 72 is a convection fan arranged in the warm air passage 71, 73 is a combustion air passage which speaks the intake / exhaust duct 74, and 75 is a high limit dummyster which detects abnormal temperature rise.

The gas burner 2 has a flame port 211 for discharging the mixer at its distal end, and passages 21, 21,... Which have a mixer inlet 212 for discharging primary air and gas at its base end, and A gas pipe 22 having nozzles 221, 221,... At the mixer inlet 212 of the passage 21 has a solenoid valve 11, 12, and a gas proportional valve 13 sequentially. It is supplied by the gas pipe (g) which is delivered and forced combustion.

The sparker 3, which is an ignition means, is disposed in response to the flame port 211. When the high voltage is applied by the sparker drive circuit 31 during the ignition operation, the gas burner 2 is ignited.

The combustion fan 4 is composed of an impeller 41 pivoted in the combustion air passage 73 upstream from the gas burner 2 and a combustion fan motor 42 (direct current motor) for driving the impeller 41. Then, the sucked outdoor air 43 is supplied to the gas burner (2). The combustion fan 4 rotates at the ignition speed during ignition, and at the temperature of the bath (1300 rpm to 3600 rpm) to obtain combustion air suitable for the required combustion amount described later.

The gas proportionality valve 13 is a valve whose opening degree increases with the amount of energization, and increasing the amount of energization increases the amount of gas supplied to the gas burner 2. In addition, the solenoid valves 11 and 12 become an open valve state when energizing, and supplies gas to the gas burner 2. In the gas proportional valve 13, a proportional valve current of the ignition level flows at the time of ignition, and a proportional valve current of the temperature level corresponding to the temperature of rotation of the combustion fan 4, which will be described later, flows at the time of ignition.

The combustion monitoring means is assembled in the frame rod 61 facing the combustion flame and the combustion controller 5, and whether misfire has been issued to the gas burner 2 based on the presence or absence of a flame current detected by the frame rod 61. It consists of a misfire detection circuit 62 for discriminating the difference and a microcomputer 50 to be described later.

The hot air passage 71 is opened on the rear surface of the heater housing 71 to open the air inlet 712 for sucking the indoor air 711 and to open the lower portion of the front of the heater housing 71 to blow out the warm air 713 into the room. It is a communication path with the jet port 714. A filter f for removing dust in the room is detachably arranged at the suction port 712, and a guide plate 715 for changing the blowing direction of the warm air 713 is assembled at the blowing port 714.

The convection fan 72 is composed of an impeller 721 extracted in the warm air passage 71 near the inlet 712 and a convection fan motor 722 (alternating motor) for driving the impeller 721. Generates an air stream 720 from the furnace to the jet port 714. At the time of temperature control, this convection fan 72 flows the electric current of the level with which the air volume proportionate to the required combustion amount mentioned later is obtained.

The combustion air passage 73 is a passage connected to the outlet port 741 and the exhaust port 742 of the double intake / exhaust duct 74 having the upstream end side and the downstream end side installed outdoors (see FIG. 2). A combustion chamber 731 incorporating the gas burner 2 and a heat exchanger 732 for dissipating heat of the combustion exhaust gas 730 generated by the combustion in the air stream 720 are formed in the passage. In addition, the combustion chamber 731 and the heat exchange part 732 are located in the hot air passage 71.

The combustion controller 5 includes a proportional valve driving circuit 131 for driving the gas proportional valve 13, a solenoid valve driving circuit 110 for opening and closing the solenoid valves 11 and 12, and a convection fan motor 722. A convection fan motor driving circuit 723 for driving the engine, a combustion fan motor driving circuit 40 for feeding back the combustion fan motor 42, a sparker driving circuit 31 for driving the sparker 3, And a microcomputer 50 for controlling the respective driving circuits based on the electrical signals transmitted by the operation switch 51, the room temperature setter 52 and the room temperature sensor 53.

Next, control of the gas proportional valve 13, the convection fan 72, and the combustion fan 4 by the combustion controller 5 will be described with the flowchart of FIG.

When the target room temperature is set with the room temperature setter 52 and the operation switch 51 is operated, the operation of the FF gas hot air heater A is started.

In step S1, the microcomputer 50 instructs the combustion fan motor drive circuit 40 to cause the combustion fan 4 to rotate at the ignition speed.

In step S2, the microcomputer 50 instructs the solenoid valve drive circuit 110 to keep the solenoid valves 11 and 12 open.

In step S3, the microcomputer 50 instructs the proportional valve driving circuit 131 so that the gas proportional valve current becomes the ignition level.

In step S4, the microcomputer 50 instructs the sparker drive circuit 31 to operate the sparker 3 for a predetermined time.

In step S5, the microcomputer 50 determines the combustion state of the gas burner 2 by the output of the misfire detection circuit 60. If no misfire is detected, NO proceeds to staff S6, and if misfire is detected (YES), progresses to staff S9. In addition, immediately after the end of the ignition operation (steps S1 to S4) or the re-ignition operation (steps S14 to S17) (for several hundred ms), the output of the misfire detection circuit 62 is not stabilized, so that the microcomputer 50 determines the misfire. I never do that.

In step S6, the microcomputer 50 determines whether 10 seconds or more have elapsed since the end of the (re) ignition operation (step S4 or step S17 and the gas burner 2 is considered to be ignited at this point), and then If yes (YES), the process proceeds to the step S7, and if not cured (NO), the process returns to the step S5.

In step S7, the microcomputer 50 instructs the combustion fan motor drive circuit 40 so that the combustion fan 4 rotates at a temperature of the rotational speed at which combustion air suitable for the required combustion amount described later is obtained.

Specifically, the microcomputer 50 needs the amount of heat Q to be emitted by the gas burner 2 based on the temperature difference between the target room temperature set by the room temperature setter 52 and the detected room temperature detected by the room temperature sensor 53. ) Is calculated every predetermined time, and the rotation speed of the combustion fan 4 (in the present embodiment, in the range of 1300 to 3600 rpm) is determined every predetermined time on the basis of the calculated required amount of heat Q, and combustion is performed at that rotation speed. The combustion fan 4 is feedback controlled so that the fan 4 rotates.

Number of revolutions of the combustion fan 4 = K, Q (where K is the coefficient)

In step S8, the microcomputer 50 determines the proportional valve current (temperature level) by the detected rotational speed every predetermined time so that the gas burner 2 releases the required heat quantity Q, and the proportional valve current is proportional to the gas. The proportional valve driving circuit 131 is instructed to flow through the valve 13, and the process returns to the step S5.

In step S9, the microcomputer 50 instructs the solenoid valve drive circuit 110 to keep the solenoid valves 11 and 12 open.

In step S10, the microcomputer 50 instructs the proportional valve driving circuit 131 so that the gas proportional valve becomes zero. In addition, the fan motor driving circuit 40 is instructed to stop the combustion fan 4.

In step S11, the microcomputer 50 determines whether the number of misfires is less than 11, and if the number of misfires is less than 11 (YES), the process proceeds to staff S12, and if it is 11 or more times (NO), the process proceeds to staff S18. do.

In step S12, the microcomputer 50 determines whether 90 seconds or more have elapsed from the end of the (re) ignition operation (step S4 or the end of step S17), and if it has elapsed (YES), the process proceeds to step S13. If NO has elapsed, NO proceeds to step S18.

In step S13, the microcomputer 50 determines whether or not the rotation speed of the combustion fan 4 is 2100 rpm or less at the time of fire, and when it is 2100 rpm or less (YES), the process proceeds to the SMS staff S14 and exceeds 2100 rpm (NO ) Proceeds to staff S18. Moreover, what is necessary is just to detect the rotation speed of the combustion fan 4 at the time of a misfire between the staff S5 and the staff S9.

In step S14, the microcomputer 50 instructs the combustion fan motor drive circuit 40 to cause the combustion fan 4 to rotate at the ignition speed.

In step S15, the microcomputer 50 instructs the solenoid valve drive circuit 110 to keep the solenoid valves 11 and 12 open.

In step S16, the microcomputer 50 instructs the proportional valve driving circuit 131 so that the gas proportional valve becomes the ignition level.

In step S17, the microcomputer 50 instructs the sparker drive circuit 31 to operate the sparker 3 for a predetermined time, and returns to the step S5.

Hereinafter, the advantages of the present embodiment will be described.

(A) The combustion air passage 73 having the gas burner 2 incorporated therein is connected to the inlet port 741 and the exhaust port 742 of the hop / exhaust duct 4 having the upstream end side and the downstream end side installed outside. to be. In addition, since the combustion fan 4 into which the combustion air of the gas burner 2 is inserted is controlled to rotate at a rotation speed suitable for the combustion amount of the gas burner 2, the combustion fan 4 rotates at a low rotation speed. In the case of the small combustion amount, the gas burner 2 is easily affected by the wind, and the gas burner 2 may be burned under the influence of the wind.

However, when the gas burner 2 burns, the microcomputer 50 instructs the solenoid valve driving circuit 110 or the proportional valve driving circuit 131 to the solenoid valves 11 and 12 and the gas proportional valve 13. The energization is stopped and the gas supply to the gas burner 2 is interrupted (steps S9 and S10). When the conditions are satisfied, the microcomputer 50 performs the re-ignition operation (steps S14 to S17) to stop the gas burner 2. It is the structure to resume combustion automatically.

For this reason, since heating operation is automatically resumed (when a condition is satisfied), the fall of room temperature does not occur and a schedule is maintained.

In addition, the misfire in the case where the combustion fan 4 is the large combustion amount which rotates more than 2100 rpm is likely to be a cause on the combustion apparatus side (it is better not to re-ignite), and does not perform re-ignition operation. It is reasonable because it is a configuration.

(B) The microcomputer 50 performs the re-ignition operation only after 90 seconds or more have elapsed from the ignition detection (when no misfire is detected; NO in the staff S5). This is more likely to be the cause of the combustion device itself than the effect of wind if it is fired early (before 90 seconds) and avoids re-ignition.

(C) The microcomputer 50 performs the re-ignition operation up to 10 times (returns to the 0th time by re-insertion of the operation switch). This is more likely to be caused by the combustion apparatus side than the influence of the wind, even if the re-ignition operation is performed more than 10 times, and inadvertent re-ignition operation can be prevented.

The present invention includes the following embodiment in addition to the above embodiment.

a. Detection that the burner is burning below a predetermined combustion amount may be performed by detecting the proportional valve current, indicating the combustion speed number, energizing current to the blower, combustion temperature, etc., in addition to detecting the rotation speed of the blower.

b. The burner may be configured to use a thermocouple (thermocouple), both the frame rod and the thermocouple in addition to the frame rod.

c. The combustion apparatus may be a hot water heater, a gas stove, a clothes dryer, or the like.

d. In the above embodiment, the FF gas-heated air-heater is shown, but only the combustion exhaust may be discharged to the outdoors, or the combustion exhaust may be discharged to the interior (claims 4 and 5 not citing Claims 1, 2 and 3). ).

e. The combustion apparatus of Claim 1 may be a structure which injects combustion air of a burner by a blower, and a structure which ensures not to be blown.

Claims (5)

A burner to which fuel is supplied via a fuel supply adjusting means, ignition means for igniting the burner, fuel control means for controlling the operation of the ignition means and the supply capacity of the fuel supply adjusting means, and A combustion monitoring means for monitoring the combustion state of the burner and instructing the fuel supply adjusting means to cut off the fuel supply to the burner when the misfire is detected, and the combustion monitoring means performs the combustion while the burner burns below a predetermined combustion amount. And if the burner detects a misfire, the combustion control means re-ignites. A burner supplied with fuel through a fuel supply adjusting means, an ignition means for igniting the burner, and a rotational speed at which a quantity of air suitable for the indicated combustion amount is supplied to supply combustion air to the burner. A controlled blower, combustion control means for controlling the operation of the ignition means, the rotation speed of the blower and the supply capacity of the fuel supply control means, and monitoring the combustion state of the burner to supply the fuel when misfire is detected A combustion monitoring means for instructing a control means to cut off fuel supply to the burner, and when the combustion monitoring means detects misfire of the burner when the blower is rotating below a predetermined rotation speed, the combustion control means A combustion device characterized by performing a re-ignition operation. The combustion apparatus according to claim 1 or 2, wherein the combustion air of the burner is drawn from the outdoors, and combustion exhaust is discharged to the outdoors. The combustion apparatus according to claim 1, 2 or 3, wherein the re-ignition operation is prohibited when a misfire of the burner is detected before a set time has elapsed from the ignition of the burner. The combustion apparatus according to claim 1, wherein the re-ignition operation performed by the combustion control means is within a predetermined number of times.