KR102153913B1 - Flame anomaly detection apparatus in premix condensing boiler and method thereof - Google Patents

Abstract

The present invention relates to a flame abnormality detection device of a premixed condensing boiler and a method thereof, and more specifically, to a flame abnormality detection device of a premixed condensing boiler and a method thereof, wherein during operation according to heating or hot water operation, flame stabilization operation and combustion operation according to proportional control operation after flame stabilization are classified to monitor a flame abnormality in which the flame of a heat exchanger disappears due to an abnormal combustion balance due to external wind pressure, an abnormality in a boiler burner, and at least one abnormality in an air-fuel ratio balance, and operation is terminated and a user is notified of an abnormal flame when the abnormal flame is detected.

Description

TECHNICAL FIELD [0001] Flame anomaly detection apparatus in premix condensing boiler and method thereof

The present invention relates to an apparatus and method for detecting flame abnormalities of a premixed condensing boiler, and more particularly, when operating according to heating or hot water operation, a flame stabilization operation and a combustion operation according to a proportional control operation after flame stabilization are classified. , External wind pressure, boiler burner unit, and air-fuel ratio balance. It relates to an apparatus and method for detecting flame abnormalities in a premixed condensing boiler.

In general, boilers include a bunsen type gas boiler and a condensing (heat recovery type) boiler.

In the Bunzen gas boiler, since the burner is located under the heat exchanger, a proportional valve (or "proportional valve") is installed in a position close to the burner.

In this way, when gas is supplied through the proportional valve and then ignited by the ignition transformer and a flame (flame) is detected from the flame hole, the ignition transformer is immediately'off' and After the flame propagation time (or "flame stabilization time") waiting for the time to transform the flame into the flame, the proportional combustion operation is performed according to the set temperature.

On the other hand, the condensing boiler is designed to facilitate condensation heat exchange by installing a burner on the top or side of the heat exchanger to make the combustion gas flow downward and the temperature to be below the dew point temperature.

Unlike Bunzen-type gas boilers, such a condensing boiler adopts a porous premixing method, and a heat exchanger is installed immediately after the flame surface to suppress the generation of nitrogen compounds (NOx), and is an environmentally friendly boiler due to low carbon monoxide (CO) emissions. can do. Its principle is that it absorbs the sensible heat first and the latent heat discharged to the exhaust gas secondly, and the exhaust gas temperature of a general boiler is 150-260℃, whereas the condensing boiler recovers heat around 50-100℃. High efficiency of more than 95% can be obtained.

Such a premixed condensing boiler has a structure in which the location of the burner is located on the top or side of the heat exchanger, so the location of the proportional valve that controls the amount of gas supplied and the location of the burner are formed apart by a predetermined length, so that the gas reaches the burner. It takes longer to take.

Therefore, in such a premixed condensing boiler, when the burner is first ignited, the air-fuel ratio (ratio of air and fuel) required for ignition may be ignited by the ignition transformer in an inaccurate state due to the distance between the proportional valve and the burner. As a result, the flame is detected, but the flame may be blown or backfired due to an inaccuracy of the air-fuel ratio, and there is a problem that the controller may recognize it as an ignition error or a misfire when the flame detector does not detect the flame at all.

In other words, the conventional premixed condensing boiler has a long distance between the burner and the proportional valve, so if a flame is detected by the flame detector, the operation of the ignition transformer is stopped, so the proportion according to the set temperature is not stabilized. Since combustion control is performed and the amount of gas and air fluctuates, there is a problem in that noise is generated due to flame blowing and backfire.

In order to solve this problem, Korean Patent Laid-Open No. 10-2003-0086086 [Salt Stabilization Device and Method for Initial Ignition in Premixed Condensing Boiler] (hereinafter referred to as "prior art") is the timing of ignition before proportional combustion control. The ignition transformer is continuously driven for a certain period of time (hereinafter referred to as "flame stabilization time") so that there is no change in the amount of gas and air in the gas and the proportional combustion control is performed after a stable flame transition is achieved. A technology that can prevent noise generation, etc. is disclosed.

However, the prior art is a technology that stabilizes the flame before proportional control, and the flame of the heat exchanger disappears frequently due to a temporary abnormality in the combustion balance due to external wind pressure or abnormal boiler burner part during proportional control combustion, and air-fuel ratio balance. The disappearance of the flame may occur repeatedly, and when the disappearance of the flame occurs repeatedly, there is a problem in that noise is generated due to the blowing of the flame and the burner abnormality backfire.

Republic of Korea Patent Publication No. 10-2003-0086086 (published on November 7, 2003)

Therefore, it is an object of the present invention to distinguish between the combustion operation according to the proportional control operation after the flame stabilization operation and the flame stabilization during operation according to the heating or hot water operation, so that any one or more of external wind pressure, abnormality of the boiler burner and air-fuel ratio balance It is to provide a flame abnormality detection apparatus and method of a premixed condensing boiler that monitors a flame abnormality in which the flame of a heat exchanger disappears due to a combustion balance abnormality, terminates operation when flame abnormality is detected, and notifies a flame abnormality to a user.

The flame abnormality detection device of the premixed condensing boiler according to the present invention for achieving the above object includes: a blower, a heat exchange part, a burner part including an ignition transformer, a gas valve part including a gas valve and a proportional valve, In the flame abnormality detection device of a premixed condensing boiler including a flame detector configured in the heat exchange unit to detect a flame of the heat exchange unit, the reference purge time, the reference ignition stability time, the reference flame stability time, and the reference number of misfire errors during combustion , A storage unit for storing the number of reference flame stability misfire errors; An ignition transformer driver supplying an ignition transformer driving power to the ignition transformer; A blower driving unit for supplying a blower driving power to the blower; A gas valve driving unit supplying on/off driving power to the gas valve and supplying proportional control driving power according to proportional control to the proportional valve; A flame detector connected to the flame detector to operate the flame detector and convert the flame detection signal output from the flame detector into flame detection information and output; And controlling the blower through the blower driving unit during the reference purge time at the start of operation of the condensing boiler to perform pre-purge, and then controlling the ignition transformer driving unit to drive the ignition transformer, and then controlling the gas valve driving unit to control the gas valve. Is turned on, and when a flame is detected through the flame detection unit, the ignition transformer is driven for the reference ignition stabilization time and then turned off, and the number of flame stabilization misfire errors is counted within the reference flame stabilization time counted after ignition stabilization. If the number of flame stabilization misfire errors is exceeded, it is judged as a flame abnormality and the gas valve is turned off to stop the operation of the boiler, and when the flame is detected during the reference flame stabilization time and the flame is stabilized, the proportional valve is controlled through the gas valve driving unit. A control unit that starts combustion by proportional control operation, and if the number of misfire errors during combustion due to non-detection of flames during combustion exceeds the reference number of misfire errors during combustion, it is judged as a flame abnormality and turns off the gas valve to stop the boiler operation. It characterized in that it comprises a.

The control unit may include a time calculation unit for counting the purge time, ignition stabilization time and flame stabilization time; When the operation of the condensing boiler is started, the purge time is counted through the time calculation unit, and the counted purge time is compared with the reference purge time stored in the storage unit to prepurge until the count purge time exceeds the reference purge time. A purge control unit that performs a pre-purge operation to perform a pre-purge operation and performs the pre-purge operation when determining the flame abnormality; An ignition transformer control unit for supplying ignition transformer driving power by controlling the ignition transformer driving unit when the gas valve is turned on, and controlling the ignition transformer driving unit for the reference ignition stabilization time to supply ignition transformer driving power when a flame is detected; A flame detector configured to determine whether a flame exists in the heat exchanger by operating a flame detector through the flame detector after driving the ignition transformer; The number of flame stabilization misfire errors in which no flame is detected through the flame detection unit within the reference flame stabilization time is counted, and when the counted flame stabilization time exceeds the reference flame stabilization time, the flame during the proportional control operation is not detected. An error counting unit that counts the number of misfire errors during combustion; At the start of operation, the purge control unit is activated, and if the counted number of flame stabilization misfire errors exceeds the reference flame stabilization misfire error count, it is determined as a flame abnormality and the gas valve is turned off to stop the operation of the boiler, and a misfire error during combustion. When the number of times exceeds the number of misfire errors during the reference combustion, it is characterized in that it comprises a driving control unit that determines the flame abnormality and turns off the gas valve to stop the boiler operation.

The time calculation unit further includes a misfire error non-occurrence time calculation unit for counting a misfire error non-occurrence time, which is a time during which the combustion operation flame does not disappear by the proportional control operation, wherein the control unit includes: It is characterized in that it further comprises a combustion misfire error initialization unit that determines whether the set reference misfire error non-occurrence time is exceeded, and initializes the number of misfire errors during combustion previously accumulated and counted when it exceeds.

The operation control unit may perform post purging by activating a purge control unit after stopping the operation of the boiler when the flame is abnormal.

The flame abnormality detection method of the premixed condensing boiler according to the present invention for achieving the above object is: The control unit performs a reference purge time operation prepurge at the start of the operation of the condensing boiler, and then controls the ignition transformer driver to control the ignition transformer. An ignition process of igniting a flame in the burner by controlling the gas valve driving unit to turn on the gas valve after driving the gas valve; An ignition stabilization process in which the controller drives the ignition transformer for a reference ignition stabilization time and then turns off when a flame is detected through the flame detection unit; Flame stabilization in which the control unit counts the number of flame stabilization misfire errors within the reference flame stabilization time counted after stabilization of ignition, and determines that it is a flame abnormality and turns off the gas valve to stop the operation of the boiler when the number of flame stabilization misfire errors is exceeded. Misfire error handling process; A combustion process in which the control unit controls the proportional valve through the gas valve driving unit to start combustion by proportional control operation when the flame is sensed during the reference flame stabilization time and the flame is stabilized; And if the control unit determines whether the number of misfire errors counted during combustion when the flame is not detected exceeds the reference number of misfire errors during combustion and does not exceed the number of misfire errors during combustion, the process after the ignition process is performed, and the counted number of misfire errors during combustion. And, if the number of misfire errors during combustion exceeds the reference number of misfire errors during combustion, it is determined as a flame abnormality and the gas valve is turned off to stop the boiler operation.

The combustion process includes: a combustion initiation step of starting combustion by a proportional control operation by controlling a proportional valve through the gas valve driving unit when the flame is stabilized by the control unit detecting the flame during the reference flame stabilization time; And counting the time when the misfire error does not occur during combustion, and checks whether the time when the misfire error does not occur while the flame is continuously detected exceeds the preset reference misfire error time does not occur. And a misfire error initialization step of initializing the number of misfire errors during combustion when the reference misfire error occurrence time is exceeded.

The flame stabilization misfire error processing process includes: a flame abnormality determination step of determining whether the number of flame stabilization misfire errors exceeds the reference flame stabilization misfire error count by the control unit counting the number of flame stabilization misfire errors within a reference flame stabilization time counted after ignition stabilization; An operation stopping step of stopping the operation of the boiler by turning off the gas valve by determining that it is a flame abnormality when the number of flame stabilization misfire errors counted by the control unit exceeds a reference flame stabilization misfire error count; And a post purge step in which the control unit performs a post purge.

The flame stabilization misfire error processing process may further include a misfire error notification step of displaying information indicating that a flame stabilization misfire error has occurred on the display unit.

The process of processing misfire errors during combustion may include: a flame abnormality determination step of determining whether the number of misfire errors counted during combustion exceeds a reference number of misfire errors during combustion, by the controller; A re-ignition step of performing a process after the ignition process when the counted number of misfire errors during combustion does not exceed a reference number of misfire errors during combustion; An operation stopping step of stopping the boiler operation by turning off the gas valve by determining that it is a flame abnormality when the counted number of misfire errors during combustion by the control unit exceeds the reference number of misfire errors during combustion; And a post purge step in which the control unit performs a post purge.

The process of processing a misfire error during combustion may further include a misfire error notification step of displaying information indicating that a misfire error has occurred during combustion on the display unit.

The present invention counts the number of misfire errors by dividing flame stabilization combustion and proportional combustion after flame stabilization during operation according to heating or hot water operation, and when the number of misfire errors exceeds the reference number of misfire errors set for each, the boiler It has the effect of stably driving the boiler by stopping the operation of the system and notifying the user.

In addition, since the present invention can stably drive the boiler even during proportional combustion after the flame stabilization time, there is an effect of preventing the generation of noise due to flame blowing and backfire due to burner abnormality.

1 is a view showing the configuration of a premixed condensing boiler system having a flame abnormality detection device according to an embodiment of the present invention.
2 is a view showing a detailed configuration of a flame abnormality detection device of the premixed condensing boiler according to the present invention.
3 and 4 are flowcharts illustrating a method of detecting a flame abnormality of a premixed condensing boiler according to the present invention.

Hereinafter, a configuration and operation of a flame abnormality detecting apparatus of a premixed condensing boiler and a premixed condensing boiler according to the present invention will be described in detail with reference to the accompanying drawings, and a flame abnormality detection method in the apparatus will be described.

1 is a view showing the configuration of a premixed condensing boiler system having a flame abnormality detection device according to an embodiment of the present invention.

Referring to FIG. 1, a premixed condensing boiler system includes a condensing boiler 100 and a flame abnormality detection device 200.

The condensing boiler 100 includes a blower 10, a burner unit 20, a heat exchanger 30, a gas supply pipe 40, a gas valve unit 50, an ignition transformer 60, and a flame detector 70. .

The blower 10 sucks outside air under the control of the flame abnormality detection device 200 and supplies it to the burner unit 20.

The burner unit 20 includes an ignition transformer 60 that generates a flame by receiving an ignition transformer driving power from the flame abnormality detection device 200 and is connected to a gas supply pipe 40 receiving gas, and is connected to the ignition transformer 60 ) By the flame generated through the air supplied through the blower 10, the mixed gas is lit to generate a flame, and the flame is transmitted to the heat exchanger 30.

The heat exchange unit 30 is supplied with water and, as described above, receives a flame from the burner unit 20 and transfers heat from the flame to the water to heat it.

The gas supply pipe 40 supplies gas supplied from an external gas supply means (not shown) to the burner unit 20. Whether the gas is supplied to the burner unit 20 and the amount of gas supplied are controlled by the gas valve unit 50.

The gas valve unit 50 includes at least one gas valve 51 and 52 for turning on or off the supply of gas under the control of the flame abnormality detecting device 200, and the flame abnormality detecting device 200 It includes a proportional valve 53 for controlling the amount of gas supplied to the burner unit 20 under the control of ).

The flame abnormality detection device 200 performs prepurge during a reference purge time when the condensing boiler 100 starts to operate.

After the pre-purge, the flame abnormality detection device 200 turns on the gas valves 51 and 52, drives the ignition transformer 60, and performs an ignition operation to check whether a flame is detected through the flame detector 70. do.

After the ignition operation, the flame abnormality detection device 200 performs an ignition stabilization operation of driving the ignition transformer 60 for a preset ignition stabilization time and then turning off when a flame is detected through the flame detector 70.

After the ignition stabilization operation is performed, the flame abnormality detection device 200 counts the number of flame stabilization misfire errors within a preset flame stabilization time, and determines that the number of flame stabilization misfire errors exceeds the reference flame stability, and determines that the gas valve 51, 52) is turned off to stop the operation of the boiler, and when the flame is detected during the reference flame stabilization time and the flame is stabilized, the proportional valve 53 is controlled to start combustion by proportional control operation, and no flame is detected during the combustion. If the number of misfire errors during combustion by exceeds the reference number of misfire errors during combustion, it is determined as a flame abnormality and gas valves 51 and 52 are turned off to stop the boiler operation.

The detailed configuration and operation of the flame abnormality detection device 200 will be described with reference to FIG. 2.

2 is a view showing a detailed configuration of a flame abnormality detection device of the premixed condensing boiler according to the present invention.

2, the flame abnormality detection device 200 includes a storage unit 210, a display unit 220, an input unit 230, a blower driving unit 240, a gas valve driving unit 250, and an ignition transformer driving unit 260. , A flame detection unit 270 and a control unit 300 may be included, and a blower rotation speed detection unit 280 may be further included according to an embodiment.

The storage unit 210 includes a program area for storing a control program for controlling the operation of the flame abnormality detecting device 200 according to the present invention, a temporary area for temporarily storing data generated during execution of the control program, and for executing the control program. It includes a data area for semi-permanently storing necessary data and data generated during execution of the control program.

The data area may store a reference purge time, a reference ignition stabilization time, a reference flame stabilization time, a reference number of misfire errors during combustion, a reference number of misfire errors in flame stability, a reference misfire error occurrence time, and the like.

The display unit 220 displays various information according to the operation state of the flame abnormality detection device 200 under the control of the control unit 300 as one or more of text, icon, graphic, still image, and video. The display unit 220 according to the present invention may display whether a boiler is operated, an operation mode, an operating temperature, a flame stabilization misfire error, and a misfire error during combustion.

The input unit 230 is a button input device including a plurality of buttons capable of controlling the operation, mode, etc. of the flame abnormality detection device 200, and is integrated with the screen of the display unit 220 to correspond to a touched position It may be configured to include any one or more of a touch pad that outputs the location signal to the controller 300.

The blower driving unit 240 generates a blower driving power for rotating the blower 10 of the contensing boiler 100 under the control of the control unit 300 and supplies it to the blower 10.

The gas valve driving unit 250 generates first and second valve driving power for turning on/off the gas valves 51 and 52 of the gas valve unit 50 under the control of the control unit 300 to generate the gas valve 51 , 52), and outputs the proportional valve driving power to the proportional valve 53 for controlling the amount of gas supplied to the burner unit 20 by controlling the degree of opening and closing of the proportional valve 53.

The ignition transformer driving unit 260 generates an ignition transformer driving power for generating a spark from the ignition transformer 60 under the control of the control unit 30 and outputs it to the ignition transformer 60.

The flame detection unit 270 is controlled by the control unit 300 to output the flame detector driving power for the flame detector 70 to detect the flame to the flame detector 70, and receive a flame detection signal according to the flame detection information. And output to the control unit 300.

The blower rotation speed detection unit 280 detects the rotation speed of the blower 10 and outputs it to the control unit 300.

The control unit 300 includes a time calculation unit 310, a purge control unit 320, an ignition transformer control unit 330, a flame detection unit 340, an error count unit 350, an operation control unit 360, and an input/output processing unit 370. And a misfire error initialization unit 380 during combustion to control the overall operation of the flame abnormality detection apparatus 200 according to the present invention.

Specifically, the time calculation unit 310 includes a reference time calculation unit 311 that counts a time according to a standard time, and prepurge based on a reference time counted by the reference time calculation unit 311 when performing prepurge. Until the flame is stably ignited based on the reference time when the flame is ignited in the burner unit 20 by driving the ignition transformer 60 and the purge time calculation unit 312 that counts the (free) purge time to be executed. An ignition stability time calculation unit 313 that counts the ignition stability time for operating the ignition transformer 60 of the ignition, a flame stability time calculation unit 314 that counts the flame stability time after ignition stabilization, and a misfire error during the ignition stabilization And a misfire error non-occurrence time calculation unit 315 for counting a misfire error non-occurrence time during combustion that does not occur.

When the operation of the condensing boiler 100 starts, the purge control unit 320 counts the purge time through the purge time calculation unit 312 of the time calculation unit 310, and the counted purge time and the storage unit 210 By comparing the stored reference purge time, the blower 10 is controlled through the blower driving unit 240 until the count purge time exceeds the reference purge time to perform a prepurge operation.

The purge control unit 320 may perform post forge when an abnormal flame occurs according to an embodiment of the present invention.

In addition, the purge control unit 320 performs the pre-purge operation when the flame abnormality is determined during combustion according to ignition stabilization and proportional control.

When the gas valves 51 and 52 are turned on, the ignition transformer control unit 330 supplies the ignition trans driving power by controlling the ignition trans driving unit 260, and when a flame is detected through the flame detection unit 340, the reference ignition During a stable time, the ignition transformer driving unit 260 is controlled to continuously supply the ignition transformer driving power.

The flame detection unit 340 determines whether a flame exists in the heat exchanger 30 by operating the flame detector 70 through the flame detection unit 350 after driving the ignition transformer.

The error counting unit 350 includes a misfire error counting unit 351 during combustion and a flame stabilization misfire error counting unit 352.

The flame stabilization misfire error counting unit 352 counts the number of flame stabilization misfire errors in which no flame is detected through the flame detection unit within the reference flame stabilization time.

When the counted flame stabilization time exceeds the reference flame stabilization time, the misfire error counting unit 351 counts the number of misfire errors during combustion in which no flame is detected during the proportional control operation.

The operation control unit 360 controls the on/off of the gas valve unit 50 and the operation stop of the condensing boiler 100 through the gas valve driving unit 250.

In particular, the operation control unit 360 activates the purge control unit 320 at the start of operation, and when the counted number of flame stabilization misfire errors exceeds the reference number of flame stabilization misfire errors, it is determined as a flame abnormality and the gas valve 51, 52) is turned off to stop the operation of the boiler, and if the number of misfire errors during combustion exceeds the reference number of misfire errors during combustion, it is determined as a flame abnormality and the gas valves 51 and 52 are turned off, and the condensing boiler 100 is used. Shut off the supplied power to stop the boiler operation.

In addition, the operation control unit 360 determines whether or not the blower 10 is normally rotating in accordance with the air-fuel ratio during ignition and combustion, based on the fan rotation speed received from the blower rotation speed detection unit 280.

The input/output processing unit 370 processes a signal input from the input unit 230 and processes information to be displayed on the display unit 220. According to the present invention, the input/output processing unit 370 displays whether a flame stabilization misfire error has occurred and whether a misfire error occurs during combustion when a flame abnormality occurs according to the present invention.

In addition, the input/output processing unit 370 may be configured to generate an alarm sound through an audio processing unit (not shown) including a speaker or an alarm (not shown) when an abnormal flame occurs.

The misfire error initializing unit 380 during combustion determines whether the misfire error non-occurrence time counted by the misfire error non-occurrence time calculation unit 315 exceeds a preset reference misfire error non-occurrence time, and if exceeded, the previous combustion is performed. The number of misfire errors during combustion accumulated by the misfire error counting unit 351 is initialized.

3 and 4 are flowcharts illustrating a method of detecting a flame abnormality of a premixed condensing boiler according to the present invention.

3 and 4, the controller 300 starts a pre-purge operation by controlling the blower 10 when a contensing boiler driving signal is input or power is supplied through the input unit 230 and is purged. The time calculation unit 312 starts to count the purge time (S111).

When the prepurge is performed and the purge time starts to be counted, the control unit 300 checks whether the counted purge time exceeds the reference purge time preset in the storage unit 210 and performs prepurge during the purge time (S113).

When the counted purge time exceeds the reference purge time, the control unit 300 terminates the prepurge and controls the gas valve driving unit 250 to turn on the gas valves 51 and 52, and controls the ignition transformer driving unit 260. After driving the ignition transformer 60 to generate a flame (S115), it starts to check whether a flame is detected in the heat exchanger 30 through the flame detection unit 270 (S117).

If the flame is not detected, the controller 300 turns off the ignition transformer 60, turns off the gas valves 51 and 52 (S119, S121), and then performs the operation after the above-described prepurge again to perform re-ignition. do.

When a flame is detected, the control unit 300 starts counting the ignition stabilization time through the ignition stabilization time calculator 313 (S123), and the counted ignition stabilization time is stored in the storage unit 210 in advance. It checks whether the time is exceeded and the ignition transformer 60 is driven during the ignition stabilization time to perform an ignition stabilization operation (S125).

When the counted ignition stabilization time exceeds the reference ignition stabilization time, the control unit 300 turns off the ignition transformer 60 and starts counting the flame stabilization time through the flame stabilization time calculation unit 314 (S127).

When the flame stabilization time starts to be counted, the control unit 300 checks whether the counted flame stabilization time exceeds the reference flame stabilization time previously stored in the storage unit 210 (S129), and the flame is continuously flamed during the reference flame stabilization time. It is checked whether or not is detected (S131).

If the flame is not detected within the reference flame stabilization time, the control unit 300 determines whether the number of misfire errors during combustion is more than one in order to determine whether it has been re-ignited due to a misfire error during previous combustion (S133).

If the number of misfire errors during combustion occurs more than once, the control unit 300 proceeds to S151 to be described later, and if the number of misfire errors during combustion is 0, the number of misfire errors in flame stability is increased by 1 and counted (S135).

When the number of flame stabilization misfire errors is counted, the controller 300 checks whether the counted flame stabilization misfire errors exceed the reference number of flame stabilization misfire errors previously stored in the storage unit 210 (S137), and the counted flame If the number of stabilization misfire errors does not exceed the reference flame stabilization misfire errors, the processes after S121 and S111 are repeated, and if exceeded, the gas valves 51 and 52 are turned off, and post purge is performed (S139). , The operation of the condensing boiler 100 is stopped and a flame stabilization misfire error is displayed on the display unit 220 (S141).

On the other hand, if the flame is continuously detected until the counted flame stabilization time exceeds the reference flame stabilization time, that is, if the flame does not disappear, the controller 300 controls the proportional valve 53 to start the proportional control operation. The combustion operation is performed (S143).

When the combustion operation is started, the control unit 300 starts counting the non-occurrence time of misfire errors during combustion, which is the non-occurrence time of the misfire errors during combustion, at which the flame disappears during combustion (S145), and the time when the misfire error does not occur during combustion that has started counting. It is checked whether it exceeds the standard misfire error non-occurrence time stored in the storage unit 210 (S147).

If the counted time for no misfire errors during combustion does not exceed the reference time for no misfire errors during combustion, the controller 300 determines whether a flame is detected through the flame detector 70 (S149), and when the flame is detected. S143 to S149 described above are repeatedly performed.

If the misfire error non-occurrence time counted during the repetitive execution of S143 to S149 exceeds the reference misfire error non-occurrence time, the controller 300 initializes the number of misfire errors during combustion previously generated (S139).

During the proportional control operation, that is, when no flame is detected during combustion, the control unit 300 accumulates and counts the number of misfire errors during combustion (S151), and determines whether the counted number of misfire errors during combustion exceeds the reference number of misfire errors during combustion. Inspect (S153).

If the counted number of misfire errors during combustion does not exceed the reference number of misfire errors during combustion, the controller 300 repeats the above-described processes after S121 and S111, and the number of misfire errors during combustion determines the reference number of misfire errors during combustion. If it exceeds, the gas valves 51 and 52 are turned off, post purge is performed (S155), the operation of the condensing boiler 100 is stopped, and a misfire error during combustion is displayed on the display 220 (S157). ).

Meanwhile, it is common knowledge in the art that the present invention is not limited to the above-described typical preferred embodiment, but can be implemented in various ways without departing from the gist of the present invention. Anyone who has a will be able to understand it easily. If implementation by such improvement, change, substitution or addition falls within the scope of the following appended claims, the technical idea should also be considered to belong to the present invention.

10: blower 20: burner part
30: heat exchanger 40: gas supply pipe
50: gas valve portion 51, 52: gas valve
53: proportional valve 60: ignition transformer
70: flame detector 100: condensing boiler
200: flame abnormality detection device 210: storage
220: display unit 230: input unit
240: blower driving unit 250: gas valve driving unit
260: ignition transformer driving unit 270: flame detection unit
280: blower rotation speed detection unit
300: control unit 310: time calculation unit
311: reference time calculation unit 312: purge time calculation unit
313: ignition stabilization time calculation unit 314: flame stabilization time calculation unit
315: Time calculation unit for no real fire error
320: purge control unit 330: ignition transformer control unit
340: flame detection unit 350: error counting unit
351: Misfire error counting unit during combustion
352: flame stability misfire error counting unit
360: operation control unit 370: input/output processing unit

Claims (10)

Flame of a premixed condensing boiler including a blower, a heat exchange part, a burner part including an ignition transformer, a gas valve part including a gas valve and a proportional valve, and a flame detector configured in the heat exchange part to detect the flame of the heat exchange part In the abnormality detection device,
A storage unit that stores a reference purge time, a reference ignition stabilization time, a reference flame stabilization time, a reference number of misfire errors during combustion, and a reference flame stability misfire number;
An ignition transformer driver supplying an ignition transformer driving power to the ignition transformer;
A blower driving unit for supplying a blower driving power to the blower;
A gas valve driving unit supplying on/off driving power to the gas valve and supplying proportional control driving power according to proportional control to the proportional valve;
A flame detector connected to the flame detector to operate the flame detector and convert the flame detection signal output from the flame detector into flame detection information and output; And
When the operation of the condensing boiler is started, the blower through the blower driving unit is controlled for the reference purge time to perform prepurge, and then the ignition transformer is controlled to drive the ignition transformer, and the gas valve driving unit is controlled to When the valve is turned on and a flame is detected through the flame detection unit, the ignition transformer is driven and turned off during the reference ignition stabilization time, and the number of flame stabilization misfire errors is counted within the reference flame stabilization time counted after ignition stabilization. If the reference flame stabilization error number is exceeded, it is judged as a flame abnormality and the gas valve is turned off to stop the operation of the boiler, and when the flame is detected during the standard flame stabilization time and the flame is stabilized, the proportional valve is controlled through the gas valve drive Thus, combustion is started by proportional control operation, and if the number of misfire errors during combustion by the flame not detected during combustion exceeds the reference number of misfire errors during combustion, it is judged as a flame abnormality and the gas valve is turned off to stop the boiler operation. Flame abnormality detection device of a premixed condensing boiler, characterized in that it comprises a control unit.
The method of claim 1,
The control unit,
A time calculator for counting the purge time, ignition stabilization time and flame stabilization time;
When the operation of the condensing boiler is started, the purge time is counted through the time calculation unit, and the counted purge time is compared with the reference purge time stored in the storage unit to prepurge until the count purge time exceeds the reference purge time. A purge control unit that performs a pre-purge operation to perform a pre-purge operation and performs the pre-purge operation when determining the flame abnormality;
An ignition transformer control unit for supplying ignition transformer driving power by controlling the ignition transformer driving unit when the gas valve is turned on, and controlling the ignition transformer driving unit for the reference ignition stabilization time to supply ignition transformer driving power when a flame is detected;
A flame detector configured to determine whether a flame exists in the heat exchanger by operating a flame detector through the flame detector after driving the ignition transformer;
The number of flame stabilization misfire errors in which no flame is detected through the flame detection unit within the reference flame stabilization time is counted, and when the counted flame stabilization time exceeds the reference flame stabilization time, the flame during the proportional control operation is not detected. An error counting unit that counts the number of misfire errors during combustion;
At the start of operation, the purge control unit is activated, and if the counted number of flame stabilization misfire errors exceeds the reference flame stabilization misfire errors, it is judged as a flame abnormality and the gas valve is turned off to stop the operation of the boiler, and a misfire error during combustion. And an operation control unit configured to stop the operation of the boiler by determining that it is a flame abnormality when the number of times exceeds the number of misfire errors during the reference combustion, and turning off the gas valve.
The method of claim 2,
The time calculation unit,
The combustion operation by proportional control operation further includes a misfire error non-occurrence time calculation unit that counts the misfire error non-occurrence time, which is a time when the flame does not disappear,
The control unit,
An example characterized by further comprising a misfire error initialization unit that determines whether the misfire error non-occurrence time exceeds a preset reference misfire error non-occurrence time, and when it exceeds, initializes the number of misfire errors during combustion previously accumulated counted. Flame abnormality detection device of mixed condensing boiler.
The method of claim 2,
The operation control unit,
A flame abnormality detection device for a premixed condensing boiler, characterized in that post purging is performed by activating a purge control unit after stopping the operation of the boiler when the flame is abnormal.
An ignition process in which the control unit performs a reference purge time operation prepurge when the condensing boiler starts operation, and then controls the ignition transformer driver to drive the ignition transformer, and then controls the gas valve driver to turn on the gas valve;
An ignition stabilization process in which the controller drives the ignition transformer for a reference ignition stabilization time and then turns off when a flame is detected through the flame detection unit;
Flame stabilization in which the control unit counts the number of flame stabilization misfire errors within the reference flame stabilization time counted after stabilization of ignition, and determines that it is a flame abnormality and turns off the gas valve to stop the operation of the boiler when the number of flame stabilization misfire errors is exceeded. Misfire error handling process;
A combustion process in which the control unit controls the proportional valve through the gas valve driving unit to start combustion by proportional control operation when the flame is sensed during the reference flame stabilization time and the flame is stabilized;
If the control unit determines whether the number of misfire errors counted during combustion when the flame is not detected exceeds the reference number of misfire errors during combustion and does not exceed the number of misfire errors during combustion, the control unit performs the process after the ignition process, and the counted number of misfire errors during combustion And a process of treating a misfire error during combustion in which a gas valve is turned off and the boiler operation is stopped when the number of misfire errors during combustion is exceeded.
The method of claim 5,
The combustion process,
A combustion initiation step of starting combustion by a proportional control operation by controlling a proportional valve through the gas valve driving unit when the flame is sensed by the control unit during the reference flame stabilization time and the flame is stabilized; And
Misfire error non-occurrence time is counted during combustion, and the counted misfire error non-occurrence time is determined by checking whether the counted misfire error non-occurrence time exceeds the preset standard misfire error non-occurrence time when the flame is continuously detected. A flame abnormality detection method of a premixed condensing boiler, comprising: initializing the number of misfire errors during combustion when the misfire error occurrence time is exceeded.
The method of claim 5,
Flame stabilization misfire error treatment process,
A flame abnormality determination step of determining whether the number of flame stabilization misfire errors is exceeded by the control unit counting the number of flame stabilization misfire errors within a reference flame stabilization time counted after ignition stabilization;
An operation stopping step of stopping the operation of the boiler by turning off the gas valve by determining that it is a flame abnormality when the number of flame stabilization misfire errors counted by the control unit exceeds a reference flame stabilization misfire error count; And
The method of detecting a flame abnormality of a premixed condensing boiler, further comprising a post purge step of the control unit performing a post purge.
The method of claim 7,
The flame stabilization misfire error treatment process,
A method for detecting a flame abnormality of a premixed condensing boiler, further comprising: displaying information notifying that a flame stabilization misfire error has occurred on a display unit.
The method of claim 5,
The process of treating misfire errors during combustion is:
A flame abnormality determination step of determining, by the control unit, whether the number of misfire errors counted during combustion exceeds a reference number of misfire errors during combustion, when the flame is not detected during combustion;
A re-ignition step of performing a process after the ignition process when the counted number of misfire errors during combustion does not exceed a reference number of misfire errors during combustion;
An operation stopping step of stopping the boiler operation by turning off the gas valve by determining that it is a flame abnormality when the counted number of misfire errors during combustion by the control unit exceeds the reference number of misfire errors during combustion; And
The method of detecting a flame abnormality of a premixed condensing boiler, further comprising a post purge step of the control unit performing a post purge.
The method of claim 9,
The process of treating misfire errors during combustion,
A method for detecting a flame abnormality of a premixed condensing boiler, further comprising: displaying information notifying that a misfire error has occurred during combustion on a display unit.

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