EP3156729B1 - Method for recalibration of a burner device for liquid fuel - Google Patents

Description

Technical area

The invention relates to a method for recalibrating a burner device for liquid fuels. Furthermore, the invention relates to a method for controlling a starting process of a burner apparatus for liquid fuels. Furthermore, the invention relates to a control device for controlling a burner device for liquid fuels, wherein the control device has a calibration function for calibrating the burner device. The invention further relates to a burner apparatus for liquid fuels, wherein the burner apparatus comprises a nozzle, an electrode, a fan for supplying combustion air in the region of the nozzle, a fuel pump for supplying liquid fuel to the nozzle and a control device for controlling the fan and the fuel pump having.

State of the art

In the DE 7910213 U1 An oil burner is described with a flame tube connected to a blower for the combustion air and an atomizer located in the flame tube and connected to an oil feed line and a compressed air line. A seated on the same drive shaft as the fan oil pump, which is designed as a gear pump sucks the oil to be fired through an oil filter and pumps it to the atomizer.

In the EP 0 614 051 A1 An automatic burner control system is described with a programmer which controls and monitors a start-up procedure and a continuous operation, with blower and fuel pump being controlled for each operating point according to the data stored in a setpoint data memory.

The EP 0 209 771 A1 relates to a method for fine adjustment of a fuel flow rate in burner-operated combustion plants for fossil fuels by Measurement of the residual oxygen content of the exhaust gases, wherein the CO contained in the exhaust gas is used as a parameter for the evaluation of the optimal conversion of material.
When setting up or installing a burner device for the first time and also when changing a burner device, for example after nozzle replacement, pump replacement or conversion of the burner device, it is necessary to calibrate the burner device. This is a process that usually has to be carried out manually by a fitter and is usually quite expensive.
Even in the case of already calibrated burner devices, due to changed plant conditions during operation, monitoring of the proper operation of the burner devices may detect an apparent malfunction of the burner devices.

DESCRIPTION OF THE INVENTION: Problem, Solution, Advantages

Object of the present invention is to provide a method for recalibration of a burner device as reliable, simple and automatically feasible.
According to the invention, a method for recalibrating a burner device for liquid fuels is proposed for this purpose. The calibration method is intended for a burner apparatus for liquid fuels, in particular fuel oil, gasoline, diesel and liquid biofuels. The burner device comprises a fan for conveying combustion air, a fuel pump, for. As an oil pump, for the promotion of liquid fuel, eg. As oil, a nozzle and at least one electrode. With the nozzle and the at least one electrode, the burner device protrudes into a combustion chamber of a boiler. In the area of the nozzle opening, a flame is formed during operation. The burner device is controlled by means of a control device. Furthermore, the control device has a calibration function with which the method according to the invention can be carried out.

The inventive method is designed as a method for recalibration of the burner device. This is to be understood as meaning that the burner device has been calibrated at least once, by means of a start calibration. The start calibration can also be understood as a precursor to the recalibration process.

For several power stages, the burner device in each case has a predetermined monitoring setpoint and / or a predetermined monitoring setpoint range. These parameters can be stored, for example, in a memory of the control device. The proper operation of the burner device can be checked regularly using these setpoints or setpoint ranges. It can thus be detected at any time if the burner device does not work properly in a given power level or does not operate in the intended parameter range. This can occur, for example, during a repositioning of the system and a change in the grounding, during oxidation of the electrodes or during burnout of soot.

1. a.) Ansteuern der Brennervorrichtung mit einer ersten Leistungsstufe, wobei der ersten Leistungsstufe ein erster Überwachungssollwert und/oder ein erster Überwachungssollwertebereich zugeordnet ist, wodurch ein ordnungsgemäßer Betrieb der Brennervorrichtung für die erste Leistungsstufe definiert wird; und
2. b.) Ermitteln eines ersten Überwachungswertes bezüglich des tatsächlichen Be- triebs der Brennervorrichtung in dieser ersten Leistungsstufe; und
3. c.) Zuordnen des ersten Überwachungswertes als neuer erster Überwachungs- sollwert zur ersten Leistungsstufe und/oder Zuordnen eines neuen ersten Überwachungssollwertebereichs basierend auf dem ersten Überwachungssollwert zur ersten Leistungsstufe; und
4. d.) Ansteuern der Brennervorrichtung mit einer zweiten Leistungsstufe, wobei der zweiten Leistungsstufe ein zweiter Überwachungssollwert und/oder ein zweiter Überwachungssollwertebereich zugeordnet ist, wodurch ein ordnungsgemäßer Betrieb der Brennervorrichtung für die zweite Leistungsstufe definiert wird; und
5. e.) Ermitteln eines zweiten Überwachungswertes bezüglich des tatsächlichen Be- triebs der Brennervorrichtungen in der zweiten Leistungsstufe; und
6. f.) Zuordnen des zweiten Überwachungswertes als neuer zweiter Überwachungssollwert zur zweiten Leistungsstufe und/oder Zuordnen eines neuen zweiten Überwachungssollwertebereichs basierend auf dem zweiten Überwachungssollwert zur zweiten Leistungsstufe.

According to the invention, the method for recalibrating the burner device provides at least the following steps:

1. a.) driving the burner apparatus with a first power stage, wherein the first power stage is assigned a first monitoring setpoint and / or a first monitoring setpoint range, whereby a proper operation of the burner apparatus for the first power level is defined; and
2. b.) determining a first monitoring value relating to the actual operation of the burner device in this first power stage; and
3. c.) assigning the first monitoring value as a new first monitoring setpoint to the first power stage and / or assigning a new first monitoring setpoint range based on the first monitoring setpoint to the first power stage; and
4. d.) driving the burner device with a second power level, wherein the second power level, a second monitoring setpoint and / or a second monitoring setpoint range is assigned, whereby a proper Operation of the burner device for the second power level is defined; and
5. e.) determining a second monitoring value relating to the actual operation of the burner devices in the second power stage; and
6. f.) assigning the second monitoring value as a new second monitoring setpoint to the second power stage and / or assigning a new second monitoring setpoint range based on the second monitoring setpoint to the second power stage.

Each measuring value of a measured variable which is suitable for monitoring the flame of the burner device could serve as monitoring value or monitoring setpoint. The monitoring value or monitoring setpoint is thus understood to mean a measured value for flame monitoring. This can be a proper operation of the burner device to be monitored. According to the invention, a flame resistance value or a value corresponding to a flame resistance value, in particular a current intensity or a flame signal current, is provided as the monitoring value. For example, in each power stage, the flame resistance or a value corresponding thereto, for example a current intensity or a flame signal current, could be measured directly. Without flame, the electrical resistance between electrode and ground goes to infinity or the flame signal current to zero, because air is a very poor electrical conductor. Due to the ionizing effect of a flame, the electrical resistance (flame resistance) usually assumes a value in the mega-ohm range. Depending on the flame, the flame resistance could be between 20 kohms and 40 megohms.

The monitoring setpoints and / or the monitoring setpoint ranges are determined for the individual power stages before step a.) By means of a start calibration and assigned to the respective power levels. The method for recalibrating the burner device thus has a start calibration function, which is run through at least once during installation or installation of the burner device. In this case, individual power levels of the burner device are controlled, a blower speed or fuel pump speed for each individual controlled power level is set or calibrated and a monitoring setpoint and / or monitoring setpoint range measured and assigned to the respective power level.

By assigning a monitoring value as a new monitoring setpoint or by assigning a new monitoring setpoint range, in the context of the present invention, an updating of the monitoring setpoint values or the monitoring setpoint ranges is to be understood. For this purpose, the prescribed monitoring setpoints or monitoring setpoint ranges for the individual power stages can be overwritten, for example.

Determining a monitoring value with regard to the actual operation of the burner device in a power stage means that a monitoring value is measured in a power stage (for example the first power stage or the second power stage) or a value corresponding to the monitoring value is measured and the monitoring value itself is calculated therefrom , The monitoring value serves to monitor the flame of the burner device.

The method according to the invention for recalibrating the burner device therefore provides that at least two power stages (a first power stage and a second power stage) are controlled and the monitoring setpoint values or monitoring setpoint ranges originally specified for these power stages are updated. According to the invention, it is provided that the method is carried out in the sequence of method steps a.) To f.).

• g.) Ansteuern der Brennervorrichtung mit einer dritten Leistungsstufe, wobei der dritten Leistungsstufe ein dritter Überwachungssollwert und/oder ein dritter Überwachungssollwertebereich zugeordnet ist, wodurch ein ordnungsgemäßer Betrieb der Brennervorrichtung für die dritte Leistungsstufe definiert wird; und
• h.) Ermitteln eines dritten Überwachungswertes bezüglich des tatsächlichen Be- triebs der Brennervorrichtung in der dritten Leistungsstufe; und
• i.) Zuordnen des dritten Überwachungswertes als neuer dritter Überwachungs- sollwert zur dritten Leistungsstufe und/oder zur Zuordnen eines neuen dritten Überwachungssollwertebereichs basierend auf dem dritten Überwachungssollwert zur dritten Leistungsstufe.

It is preferably provided that at least one further power stage, ie a third power stage, is activated and the monitoring setpoint or monitoring setpoint range originally assigned to the third power stage is updated. For this purpose, at least the following further steps are provided in the order given:

• g.) driving the burner apparatus with a third power stage, wherein the third power stage is associated with a third monitoring setpoint and / or a third monitoring setpoint area, whereby a proper operation of the burner apparatus for the third power level is defined; and
• h.) determining a third monitoring value relating to the actual operation of the burner device in the third power stage; and
• i.) assigning the third monitoring value as a new third monitoring setpoint to the third power stage and / or for assigning a new third monitoring setpoint range based on the third monitoring setpoint to the third power stage.

Particularly preferably, even more, for example, a fourth and a fifth power level can be controlled.

Preferably, the burner device or the control device of the burner device not only for the individual power levels predetermined monitoring setpoints or monitoring setpoint ranges, but the burner device are also set monitoring setpoints or monitoring setpoint ranges between the individual power levels, for example by means of a monitoring setpoint characteristic. Such a monitoring setpoint characteristic curve could, for example, be created by interpolation of the monitoring setpoint values for individual power stages and be stored or stored in a memory of the control device of the burner device.

Advantageously, in the method for recalibration, it is provided that after at least two, preferably at least three, output stages have been activated and the corresponding monitoring setpoints or monitoring setpoint ranges have been updated, the monitoring setpoint characteristic is newly created or updated by renewed interpolation ,

Furthermore, it is preferably provided that before step a.) Is checked in a predetermined power level, whether the burner device runs in an intended for the given power level operation. For checking during operation, for example, a monitoring value can be determined at regular intervals in a predetermined power stage (the instantaneous power stage of the burner apparatus) and compared with the monitoring setpoint or monitoring setpoint range assigned for this power stage. If the actually determined monitoring value is outside the specified power level of the monitoring set point range provided for this power stage, it is preferably provided that the method for recalibration is started with step a).

Preferably, the burner device can be restarted several times before and / or after the recalibration. After at least one restart, or more preferably after several, and most preferably after all, restarts, the actual monitor value is updated to a new predetermined power level, e.g. B. an ignition position or starting power level, determined and compared with the assigned for this new predetermined power level monitoring setpoint or monitoring setpoint range.

Furthermore, it is preferably provided that the recalibration with step a) is started only up to a predetermined maximum operating hour limit of the burner device. The maximum operating hour limit may preferably be 72 hours of operation, more preferably 48 hours of operation, and most preferably 24 hours of operation. Preferably, the recalibration is started up to the predetermined maximum operating hours limit if the actually determined monitoring value in the predetermined power level is outside the monitoring setpoint range provided for this power level. Particularly preferably, the burner device is restarted after the predefined maximum operating hours limit has expired if the actually determined monitoring value in the predetermined power level is outside the monitoring setpoint range provided for this power stage. Particularly preferably, a maximum of ten, and most preferably a maximum of five, restarting is provided in succession, if the actual monitoring value in the new predetermined power level is repeatedly outside the monitoring setpoint range provided for this newly specified power level and the maximum operating hour limit is exceeded. If the actually determined monitoring value in the given power level continues to be outside the monitoring setpoint range provided for this power level even after several new starts, the burner device can be switched off and locked. Through this lockout can further operation of the burner device outside of the intended monitoring setpoint range. A manual or automatic start calibration can then be performed.

It is also preferable for the monitoring setpoint range of a higher power level to specify a smaller or larger tolerance span than for the monitoring setpoint range of a lower power level. For example, for the first power level, a smaller or larger tolerance range could be set for the monitoring setpoint range than for the second and / or third power levels. The margin of tolerance of a surveillance setpoint range could be more preferably continuously set to increase or decrease as power increases.

Basically, the recalibration could be started at any power level, such as the lowest or highest power level. However, it is preferably provided that the first power level corresponds to a maximum power level of the burner device and / or that the second or third power level corresponds to a minimum power level of the burner device. The recalibration therefore preferably begins with the maximum power level or at high load and is then continued with a smaller power level. If three or more power levels are approached or controlled in the calibration procedure, the last power level could be the minimum or minimum power level and represent the light load.

Preferably, in step b.) And / or in steps e.) And / or in step h.), The respective monitoring value for flame monitoring is measured directly or indirectly. Particularly preferably, a measured value in the electrode region and / or flame region of the burner device which corresponds to the monitoring value is measured for this purpose. By this is meant that a measured value is determined whose measured variable is identical to the measured variable of the control device of the burner device predetermined monitoring setpoint.

Furthermore, it is preferably provided that in step b.) And / or in step e.) And / or in step h.) In each case values are measured over a predetermined measuring period and from this a respective monitoring value is calculated. Therefor several values of the same measurand are measured within the given measuring period. The predetermined measurement period can be, for example, between 30 seconds and 5 minutes. The monitoring value determined or calculated from the plurality of measured measured values may, for example, correspond to an average value or an average value of these values, or represent a value calculated otherwise, which represents the state profile of the measured values in the measuring period. Particularly preferably, it is provided that the measurements are carried out in the predetermined measuring period at regular intervals, particularly preferably at the same time. For example, the measurements could be measured in milliseconds or seconds intervals. For this purpose, a corresponding clock is preferably provided.

• i1) Ansteuern der Brennervorrichtung mit einer ersten Leistungsstufe, wobei der ersten Leistungsstufe eine erste Gebläsedrehzahl und eine erste Brennstoffpumpendrehzahl zugeordnet ist; und
• i2) Messen eines ersten Messwerts mindestens einer Messgröße im Abgasbereich der Brennervorrichtung. Beispielsweise könnte ein C02-Wert und/oder ein CO- Wert und/oder ein 02-Wert und/oder eine Russzahl und/oder ein Abgaswert und/oder eine Temperatur und/oder ein Stickoxid-Wert gemessen werden; und
• i3) Überprüfen, ob der erste Messwert in einem vorgegebenen ersten Soll-Wertebereich für die erste Leistungsstufe liegt; und
• i4) Verändern der ersten Gebläsedrehzahl durch manuelle Eingabe oder automati- sche Einstellung einer neuen ersten Gebläsedrehzahl oder eines mit einer neu- en ersten Gebläsedrehzahl korrespondierenden Wertes, falls der erste Mess- wert außerhalb des vorgegebenen ersten Soll-Wertebereichs für die erste Leistungsstufe liegt; oder
  Verändern der ersten Brennstoffpumpendrehzahl durch manuelle Eingabe oder automatische Einstellung einer neuen ersten Brennstoffpumpendrehzahl oder eines mit einer neuen ersten Brennstoffpumpendrehzahl korrespondierenden Wertes, falls der erste Messwert außerhalb des vorgegebenen ersten Sollwertebereichs liegt. Je nachdem, ob die erste Gebläsedrehzahl oder die erste Brennstoffpumpendrehzahl verändert wird, kann entweder die gewünschte neue erste Gebläsedrehzahl bzw. gewünschte neue erste Brennstoffpumpendrehzahl oder aber auch ein mit der jeweiligen Drehzahl korrespondierender Wert vorgegeben werden; und
• iS) Zuordnen der neuen ersten Gebläsedrehzahl oder der neuen ersten Brennstoffpumpendrehzahl zur ersten Leistungsstufe, je nachdem, welche Drehzahl im Schritt d) verändert wurde.

The calibration method preferably has a start calibration function with at least the following steps:

• i1) driving the burner apparatus with a first power stage, wherein the first power stage is associated with a first fan speed and a first fuel pump speed; and
• i2) measuring a first measured value of at least one measured variable in the exhaust gas region of the burner device. For example, a CO 2 value and / or a CO value and / or an O 2 value and / or a carbon number and / or an exhaust gas value and / or a temperature and / or a nitrogen oxide value could be measured; and
• i3) checking whether the first measured value is within a predetermined first nominal value range for the first power stage; and
• i4) changing the first fan speed by manual entry or automatic adjustment of a new first fan speed or a value corresponding to a new first fan speed if the first measured value is outside the predetermined first target value range for the first power stage; or
  Changing the first fuel pump speed by manually entering or automatically adjusting a new first fuel pump speed or one corresponding to a new first fuel pump speed Value if the first measured value is outside the specified first setpoint range. Depending on whether the first blower speed or the first fuel pump speed is changed, either the desired new first blower speed or desired new first fuel pump speed or else a value corresponding to the respective speed can be specified; and
• iS) assigning the new first blower speed or the new first fuel pump speed to the first power level, depending on which speed was changed in step d).

Preferably, at least one further calibration pass is also provided in a second power stage. For this purpose, the steps iI) to iS) are repeated for the second power stage.

Advantageously, it is further provided that each power level not only value pairs, namely a fan speed and a fuel pump speed are assigned, but in addition at least one further value, namely a monitoring setpoint. For each power level, a monitoring value of the combustion device is advantageously determined and assigned to the respective power level as a monitoring setpoint. Alternatively, the respective power level can be assigned a monitoring setpoint range based on the respectively determined monitoring setpoint.

Thus, it is preferably provided that the monitoring value is measured in the start calibration (steps il to iS) in each individual power stage and this is then stored as a new setpoint or a monitoring setpoint range based thereon in the control device for the respective power level. The monitoring setpoint or monitoring setpoint range is used in normal operation as a comparison value, whereby it can be continuously determined whether the burner device is operated properly or an adjustment or recalibration (steps a) to f)) is necessary.

Determining the monitoring value means that either a value suitable for the monitoring of the burner device is measured directly or a is calculated based on at least one measured value suitable value. For example, multiple values may be measured over a predetermined measurement period and based thereon a monitoring setpoint, such as an average or average of the measured values, may be calculated.

Advantageously, an ignition position is further defined as a starting power stage for the normal or proper operation of the burner device. For the ignition position, a position on an operating characteristic is determined and stored as starting power stage.

Furthermore, it is advantageously provided that the steps i2) to i4) are repeated for each power stage until the respective measured value lies in the respective predetermined desired value range for the corresponding power stage. A new fan speed or fuel pump speed is only assigned to the respective power stage in step iS) if, by repeating steps i2) to i4), the respective rotational speed has been changed and set such that the corresponding measured value lies within the prescribed nominal value range. In particular, for this purpose, a predetermined waiting time is maintained, within which the measured value is continuously measured and it is checked whether the measured value remains permanently in the predetermined desired value range. A suitable waiting time can be, for example, between 30 seconds and 5 minutes.

The blower speed assigned to the respective power level is preferably not changeable. Thus, it is advantageously provided that in step i4) only the fuel pump speed for the respective power level is changed, wherein in step iS) only the respective new fuel pump speed of the respective power level is assigned and the respective power level associated fan speed is not changed. The fan speed is thus changed only when changing from one power level to another. However, the fan speed assigned to a power stage remains constant and is preferably not changed during the calibration procedure. With burner devices and control methods provided in the prior art, the fuel pump speed can not be varied without simultaneously changing the fan speed. In contrast, it is now advantageously provided that the fuel pump speed in each power level can be adjusted or changed independently of the fan speed and in particular without changing the fan speed.

The fact that only the fuel pump speed and not the fan speed is changed or the fan speed is kept constant in the calibration in the respective power stage, the burner apparatus can be calibrated in a particularly advantageous and simple manner.

According to the invention, a control device for controlling a burner device for liquid fuels is furthermore provided, wherein the control device has a calibration function for calibrating the burner device according to a previously described calibration method. Particularly preferably, the control device has at least two calibration functions, namely a start calibration and a recalibration.

Furthermore, a burner device for liquid fuels is provided according to the invention, wherein the burner device has a control device for controlling the blower and the fuel pump. The control devices of the burner device according to the invention is designed for calibrating the burner device by means of a previously described calibration method. Particularly preferably, the control device has two calibration functions, namely a start calibration and a recalibration.

Brief description of the drawings

Fig. 1:

Ein Ablaufdiagramm eines Verfahrens zur Nachkalibrierung einer Brennervor- richtung,

Fig. 2:

ein Kennliniendiagramm für einen Überwachungssollwert bzw. Überwachungssollwertebereich eines Flammwiderstandwertes in Abhängigkeit von der Leistung der Brennervorrichtung, und

Fig.3:

eine Schnittdarstellung durch eine Brennervorrichtung.

The invention will now be described by way of example with reference to the accompanying drawings by way of particularly preferred embodiments. They show schematically:

Fig. 1:

A flow diagram of a method for recalibrating a burner device,

Fig. 2:

a characteristic diagram for a monitoring setpoint or monitoring setpoint range of a flame resistance value as a function of the power of the burner device, and

Figure 3:

a sectional view through a burner device.

Preferred embodiments of the invention

In Fig. 1 For example, an exemplary flow of a calibration procedure for recalibrating a burner apparatus 200 (shown in FIG Fig. 1 not shown). In this case, a burner device 200 which has already been calibrated at least once is assumed. For example, when the burner device 200 is first installed or set up by means of a start calibration function, the burner device 200 may have been calibrated. In this case, a plurality of power stages 210, 211, 212 are connected by means of a control device 100 (not in FIG Fig. 1 shown), the fan speed or fuel pump speed (eg, speed of an oil pump of the burner apparatus 200) is adjusted, and a monitoring setpoint range for a flame resistance value 215 is measured for the respective power stage 210, 211, 212 and the respective power stage 210, 211, 212 assigned or stored to the respective power stage 210, 211, 212 in a memory of the control device 100. Alternatively, the monitor set point range for a current or flame signal current could be measured and assigned to the power levels.

If, during operation of the burner apparatus 200, it is determined that an actual flame resistance value 215 or the flame signal current is outside a monitoring setpoint range 217 provided for the respective power stage 210, 211, 212, the recalibration can be started in step S1. After completion of all calibration attempts, the burner apparatus may be restarted several times and after each restart the actual flame resistance value 215 or flame signal current may be measured and compared with the monitoring setpoint range 217 provided for the current power level. If the actually measured flame resistance value 215 or the flame signal current is outside the range for the corresponding one even after the burner device 200 has been restarted several times Power level provided monitoring setpoint range 217, the burner device 200 can be turned off and locked.

In step S1, the power stage, initially the first power stage 210, is selected and in step S2 the burner apparatus 200 is driven with this first power stage 210. In step S3, the flame resistance value 215 or the flame signal current is measured. In step S4, the measured flame resistance value 215 or the flame signal current is assigned as the new monitoring setpoint value 216 to the first power level 210. In this case, the monitoring target value 216 originally assigned to the first power stage 210 (for example, by the start calibration) is updated or overwritten in the memory of the control apparatus 100. Alternatively or additionally, a monitoring setpoint range 217 for the first power level 210 can be determined for the monitoring setpoint value and assigned to the first power level 210.

In step S5, it is queried whether the predetermined number of power levels has already been run through. If this is not the case, the recalibration is continued in step S1. In this case, the next power stage, for example the second power stage 211, is selected in step S1. The next steps S2 to S4 are then repeated with the second power stage 211. The recalibration process may be continued with other power levels, such as the third power level 212.

In Fig. 2 is a characteristic diagram for the course of a monitoring setpoint value 216 or a monitoring setpoint range 217 of a flame resistance value 215 as a function of the power 214 of the burner device 200 (in FIG Fig. 2 not shown).

During the calibration process, a plurality of power stages 210, 211, 212 of the burner apparatus 200 are controlled, the flame resistance values 215 are measured and stored as new monitoring setpoints 216, and a monitoring setpoint range 217 is defined for each monitoring setpoint 216 and also assigned to the respective power stage 210, 211, 212. For determining a monitoring setpoint range 216 for a power stage 210, 211, 212 is a tolerance margin 218 around the respective monitoring setpoint 216 around.

As in Fig. 2 For example, the tolerance margin 218 for larger powers 214 is smaller than for smaller powers 214. For example, the margin of tolerance 218 for the first power level 210, the maximum power level, is the smallest. If the flame signal current is used instead of the flame resistance value 215, the tolerance span behaves inversely.

After the calibration procedure has been run through, for example, for three power stages 210, 211, 212 and for each power stage a monitoring setpoint value 216 and a monitoring setpoint range 217 have been determined and the respective power stage 210, 211, 212 has been assigned, a continuous characteristic curve is determined for both by the interpolation of the monitoring setpoint values 216 and the monitoring setpoint ranges 217 Monitoring setpoint course as well as for the course of the monitoring setpoint range 217 as a function of the power 214 of the burner device 200 set.

In Fig. 3 FIG. 3 is a sectional view through a burner apparatus 200 with a controller 100. The burner apparatus 200 has a nozzle 10 and an electrode 11, which extend into the interior of a combustion chamber 17, wherein the combustion chamber 17 is arranged in a boiler 20.

The burner apparatus 200 further includes a blower 12 and a fuel pump 13. The fan 12 is arranged on a first shaft 14 or is driven by a first shaft 14. The fuel pump 13 is arranged on a second shaft 15 or is driven by a second shaft 15. Thus, the blower 12 and the fuel pump 13 are separated and arranged with different shafts 14, 15. The rotational speeds, namely the fan speed and the fuel pump speed, can thus be controlled and adjusted separately from the control device 100.

Via a measuring device 19, the flame resistance value in the mega-ohm range is measured. For this purpose, the current which is ionized by the flame through the Air flows in the flame area, are measured and used to calculate the flame resistance value.

Claims (9)

1. A method for recalibrating a burner device (200) for liquid fuels, wherein the method comprises at least the following steps:

   a) controlling the burner device (200) with a first power stage (210), wherein a first monitoring set point and / or a first monitoring set point range is assigned to the first power stage (210), by which a proper operation of the burner device (200) is defined for the first power stage (210); and

   b) determining a first monitoring value relating to the actual operation of the burner device (200) in the first power stage (210); and

   c) assigning the first monitoring value as a new first monitoring set point to the first power stage (210) and / or assigning a new first monitoring set point range based on the first monitoring set point to the first power stage (210); and

   d) controlling the burner device (200) with a second power stage (211), wherein a second monitoring set point and / or a second monitoring set point range is assigned to the second power stage (211), by which a proper operation of the burner device (200) is defined for the second power stage (211); and

   e) determining a second monitoring value relating to the actual operation of the burner device (200) in the second power stage (211); and

   f) assigning the second monitoring value as a new second monitoring set point to the second power stage (211) and / or assigning a new second monitoring set point range based on the second monitoring set point to the second power stage (211),

   characterized in that
   the monitoring values are equivalent to a flame signal current and / or a flame resistance value and / or correspond to a flame resistance value, wherein the monitoring set point values and / or the monitoring set point ranges for the individual power stages (210, 211) are determined before step a) by means of a start calibration and are assigned to the respective power stages (210, 211).
2. The method according to claim 1,
   characterized in that the method further comprises the following steps:

   g) controlling the burner device (200) with a third power stage (212), wherein a third monitoring set point and / or a third monitoring set point range is assigned to the third power stage (212), by which a proper operation of the burner device (200) is defined for the third power stage (212); and

   h) determining a third monitoring value relating to the actual operation of the burner device (200) in the third power stage (212); and

   i) assigning the third monitoring value as a new third monitoring set point to the third power stage (212) and / or assigning a new third monitoring set point range based on the third monitoring set point to the third power stage (212).
3. The method according to claim 1 or 2,
   characterized in that a characteristic curve for the monitoring set points is created by interpolation of the new monitoring set points and / or characteristic curves for the monitoring set point range are created by interpolation of the new monitoring set point ranges.
4. The method according to one of the preceding claims,
   characterized in that
   for the monitoring set point range of a higher power stage (210, 211, 212) a smaller or larger tolerance margin is set than for the monitoring set point range of a lower power stage (210, 211, 212).
5. The method according to one of the preceding claims,
   characterized in that
   the first power stage (210) corresponds to a maximum power stage of the burner device (200) and / or that the second power stage (211) corresponds to a minimum power stage of the burner device (200).
6. The method according to one of the preceding claims,
   characterized in that
   in step b) and / or in step e) and / or in step h) the respective monitoring value is measured directly or indirectly.
7. The method according to one of the preceding claims,
   characterized in that
   in step b) and / or in step e) and / or in step h) values are each measured over a predetermined measuring period and from this a respective monitoring value is calculated.
8. A control device (100) for controlling a burner device (200) for liquid fuels, wherein the control device (100) has a calibration function for calibrating the burner device (200),
   characterized in that the control device (100) is configured for calibrating the burner device (200) by means of the calibration function according to a method of the preceding claims.
9. A burner device (200) for liquid fuels, wherein the burner device (200) has a control device (100) for controlling the fan (12) and the fuel pump (13),
   characterized in that
   the control device (100) is a control device (100) according to claim 8.

Images