DE19539568C1 - Gas burner regulation system - Google Patents

Abstract

The regulation system uses an ionisation electrode (4) providing an ionisation signal dependent in the temp. or lambda value of the combustion, supplied to a regulation circuit (9) for comparison with a reference value, for adjustment of the air/fuel ratio for the burner (1). A calibration cycle is initiated at regular intervals or after a defined operating time, with the lambda value reduced and the corresponding ionisation signal measured. The max. values of the ionisation signal are stored for correction of the required value for the regulation.

Description

The invention relates to a method for controlling a Gas burner, in particular gas fan burner, with a Measuring electrode, especially the ionization electrode one of the combustion temperature or the Lambda actual value derived electrical quantity to a Control circuit sets which this size with a compares the selected electrical setpoint and that Gas-air ratio (lambda) to a corresponding Set Lambda setpoint. Furthermore, the Invention a corresponding control circuit.

Such a regulation is in DE 39 37 290 A1 described. The ionization electrode is located there a DC circuit. The evaluation of the Ionization current is problematic in practice, though a proportional relationship between the Ionization current and the lambda value can be determined should.

DE 44 33 425 A1 is a Control device for a gas fan burner described. Through an alternating voltage superimposition, the  Evaluate ionization current safely. The respective Air excess (lambda value) of the respective The state of combustion is determined by the ionization electrode detected and in the control circuit with a set Setpoint compared. The composition of the gas Combustion air mixture is made accordingly adjusted so that the end result is always with a desired lambda setpoint is worked. Desired is an over-stoichiometric ratio of air to gas, the lambda setpoint is preferably between 1.15 and 1.3 lies. It is achieved in that at different gas qualities, for example natural gas and LPG, as well as changing Environmental conditions one in terms of emissions and of the firing efficiency Combustion follows.

During operation, the thermal coupling between the Change the ionization electrode and the gas burner, for example by bending, wear and tear Contamination of the ionization electrode or soot of the burner. It has been found that this leads to the fact that despite the lambda value remaining the same Ionization current and thus the derived Measured variable changes. So it changes Proportionality factor between the lambda value and the derived electrical quantity. This one changed measuring voltage at the comparator of the control circuit is present, to which the - unchanged - setpoint acts, the control circuit is the gas-air mixture, ie the lambda value, making it a Deviation of the actual lambda value from the desired lambda value comes what is undesirable.  

A radiation burner is described in DE 41 21 924 C2 ben, in which the respective radiation from a sensor a control device of an exhaust fan optically is detected. The controller also runs a potash program. With one of the described Calibration programs will lower the fan speed driven, the at different speed values respective sensor signals are measured and stored. Using an algorithm, these data pairs become determines the maximum of the curve on which the data pairs lie. Then the setpoint is Sensor signal determined as a deviation from the maximum. At the This type of calibration can lead to Drifting come in areas where undetected are un desired pollutant emissions occur.

The object of the invention is a method and Propose circuit of the type mentioned at the beginning, with the influence of a change in proportionality between the lambda value and the derived one electrical measured variable on the control in the way out It is compared that the desired gas-air ratio (Lambda setpoint) is maintained.

According to the invention, the above object is in a method of type mentioned by the features of claim 1 and with regard to the circuit by the features of the Claim 4 solved.  

After a certain period of operation, either by an hour meter or by counting the Switch-on operations of the burner can be detected the control switched off and on for a short time Run through the calibration cycle. In this the gas Air mixture forcibly enriched, i.e. the lambda value reduced from <1. The detected electrical Measured variable runs through a maximum at Lambda = 1. This Value is held. Does it differ from the set electrical base setpoint, then it will readjusted. Such a deviation arises if the ionization electrode is bent, is worn or sooty, which in itself becomes a undesirable adjustment of the gas-air ratio would lead. The invention is such Avoid adjustment, so that even then desired lambda setpoint is regulated when the between the combustion temperature and the electrical Measurand has changed the existing proportionality factor.

After the calibration cycle, "Control" switched. If the deviation is outside of a "Window" is an interference signal is triggered and / or the burner is forcibly switched off.

Further configurations result from the Subclaims and the following description of a Embodiment. The drawing shows:  

Fig. 1 is a block diagram of a control circuit in a gas fan burner and

Fig. 2 is a characteristic diagram.

A gas burner ( 1 ) has a speed-adjustable fan ( 2 ) which conveys combustion air. It is equipped with a gas supply ( 3 ). An ionization electrode ( 4 ) is arranged as the measuring electrode in the flame area of the gas burner ( 1 ). This measuring electrode ( 4 ) is common in gas burners. However, it is usually only used for flame monitoring. The measuring electrode ( 4 ) detects the ionization current which occurs in the respective combustion state. According to Richardson's equation, this depends on the electrode temperature and thus also on the respective lambda value of the respective gas-air mixture.

An AC voltage, in this case simply the AC mains voltage, is applied to the measuring electrode ( 4 ) via a capacitive coupling element ( 5 ). The coupling element ( 5 ) is connected to earth via a resistor ( 6 ), so that the ionization path (flame area) is electrically connected in parallel to the resistor ( 6 ).

A low-pass filter ( 8 ) is connected to the measuring electrode ( 4 ) via a voltage-impedance converter ( 7 ) and is connected on the output side to a control circuit ( 9 ).

The control circuit ( 9 ) according to FIG. 1 has a comparator ( 10 ) to which a setpoint generator ( 11 ) is placed. An electrical setpoint corresponding to the desired lambda value, for example 1.15 to 1.3, can be set on the setpoint generator ( 11 ). The output direct voltage of the low-pass filter ( 8 ) is applied to the comparator ( 10 ) and is proportional to the respective lambda value. On the output side there is a voltage / current converter ( 12 ) on the comparator ( 10 ), which is connected via a changeover switch ( 13 ) to a power driver ( 14 ) which controls the speed of the fan ( 2 ).

In the control circuit ( 9 ) an automatic start ( 15 ) is integrated, which controls the changeover switch ( 13 ). A setpoint generator ( 16 ) for a starting speed is located on the changeover switch ( 13 ). A memory ( 17 ) for the current speed value is also provided.

A Schmitt trigger ( 18 ) is also connected to the output of the low pass ( 8 ) and is used for flame monitoring.

The control circuit described so far works as follows:
When the gas burner ( 1 ) starts, the automatic start ( 15 ) switches to the setpoint device ( 16 ). The fan ( 2 ) thus runs via the power driver ( 14 ) at a starting speed which results in a mixture which can be ignited safely.

After ignition and successful flame formation, the automatic start ( 15 ) switches the changeover switch ( 13 ) to the voltage / current converter ( 12 ). The ionization current detected by the ionization electrode ( 4 ) leads to the alternating voltage being superimposed on a direct voltage. This is proportional to the ionization in the flame area. It is proportional to the respective excess air (lambda). In practice, it is between 0 V and 200 V. For further processing, the voltage is reduced and at the output of the low-pass filter ( 8 ) a DC voltage between 0 V and 10 V occurs in the example.

The voltage embodying the excess air of the respective gas-air mixture is compared in the comparator ( 10 ) with a desired value. The difference between the two values is converted into a current that changes the state of charge of the storage capacitor ( 17 ), which corresponds to the instantaneous speed value, and thus controls the speed of the fan ( 2 ) accordingly until the respective excess air (actual lambda value ) is equal to the Lambda setpoint.

He then follows a change in Combustion conditions, for example changing the Gas type, change in gas pressure, change in Ambient temperatures or the like, and gives way to the Lambda actual value from the Lambda setpoint, then these Faults corrected in the manner described.

When the flame goes out, the gas supply ( 3 ) is blocked via the Schmitt trigger ( 18 ).

In the exemplary embodiment, the speed of the fan ( 2 ) is regulated to adjust the excess air. Instead or in addition, the gas supply ( 3 ) can also be regulated.

The control circuit ( 9 ) can also be constructed as a digital circuit with a microprocessor.

An activation circuit ( 21 ) is also provided. This counts the starting processes triggered by the automatic start ( 15 ) or records the operating hours of the gas burner ( 1 ), which can also be derived from the automatic start ( 15 ). A ramp generator ( 22 ) is connected to the activation circuit ( 21 ) and is connected to a third switching position of the changeover switch ( 13 ).

At the output of the low pass ( 8 ) there is a detection circuit ( 23 ) which is also connected to the activation circuit ( 21 ) and which is followed by a storage circuit ( 24 ). The memory circuit ( 24 ) is connected to the setpoint generator ( 11 ).

The additional circuit functions in a calibration cycle as follows:
After a certain number of starting processes or operating hours, for example 100 starting processes or 10 operating hours, the activation circuit ( 21 ) brings the changeover switch ( 13 ) into its third switching position and activates the ramp generator ( 22 ). The control described above is switched off.

The ramp generator ( 22 ) now controls the blower ( 2 ) or the gas supply ( 3 ) in such a way that the gas-air mixture is "enriched", ie the gas content increases. The lambda value is continuously reduced from a value <1, for example 1.3, to a value below 1. This results in a curve of the measuring voltage at the output of the low-pass filter ( 8 ) derived from the ionization electrode ( 4 ), as is shown by way of example in one of the curves I, II, III in FIG. 2. Which of the curves occurs depends on the state of the ionization electrode ( 4 ) or the gas burner ( 1 ); So it depends on how the ionization electrode ( 4 ) lies in the connection area of the burner flames. For example, if the ionization electrode ( 4 ) is bent, worn or sooty, a different voltage profile is produced than in the "good" condition.

All curves I, II, III run through a maximum at lambda = 1. The maxima of the curves I, II designated III in Fig. 2 A, B, C.

The detection circuit ( 23 ) detects the respective voltage maximum A, B, C, for example by evaluating the slope of the curve I, II or III. The respective maximum voltage is stored in the memory circuit ( 24 ). The memory circuit ( 24 ) sets the basic value (100%) of the setpoint generator ( 11 ) to this value.

If one assumes, for example, that I is the characteristic of a "good" condition of the ionization electrode ( 4 ) and assumes that the lambda setpoint should be 1.2, then the setpoint generator ( 11 ) has been set in this way that it was set to 90% of its basic value (100%) (cf. a in FIG. 2, whereby FIG. 2 is not to scale).

As long as nothing changes in the state of the ionization electrode ( 4 ) or the gas burner ( 1 ), nothing is changed in the calibration cycles on the basic value (100%) of the setpoint generator ( 11 ).

If the characteristic curve (II) with the maximum value (B) results in a calibration cycle, which is the result of a change in state of the ionization electrode ( 4 ), then this voltage value (B) is stored in the memory circuit ( 24 ) as the basic value for the setpoint generator ( 11 ) saved. The setpoint generator ( 11 ) remains set to 90% of a basic value, which b shows in Fig. 2. From Fig. 2 it can be seen that at the voltage (b) (90% of the maximum voltage B) via the comparator ( 10 ), when the control is switched on again after the calibration cycle by means of the switch ( 13 ), a control to the lambda Setpoint of 1.2.

It is thus achieved that, depending on the respective state of the ionization electrode ( 4 ), the control circuit ( 9 ) is always readjusted in such a way that the control circuit ( 9 ) regulates the actual lambda value to the desired lambda setpoint during control operation. Operational changes in the state of the ionization electrode ( 4 ) or the gas burner ( 1 ) are thus balanced.

There are limits to the adjustment of the setpoint generator ( 11 ) described. These are indicated in Fig. 2 by the window (F). As long as the maxima of the voltage profiles, such as A, B, are within the window (F) in the calibration cycles, the described adjustment of the setpoint generator ( 11 ) takes place. If there is a voltage maximum, such as C, which lies outside the window (F), then the detection circuit ( 23 ) detects this and triggers an interference signal and / or a forced shutdown of the gas burner ( 1 ).

The calibration cycles are very short compared to the times in which the gas burner ( 1 ) operates in normal control mode, so that the combustion occurring during the calibration cycles with a lambda value that deviates from the lambda setpoint can be accepted. The combustion improves in each of the regular operations following a calibration process.

Claims (4)

1. A method for controlling a gas burner, in particular a gas fan burner, with a measuring electrode, in particular an ionization electrode, which applies an electrical variable derived from the combustion temperature or the lambda value to a control circuit which compares this variable with a selected electrical setpoint and sets the gas-air ratio (lambda value) to a corresponding lambda setpoint, characterized in that after an operating time in which the gas burner operates in the control mode, a calibration cycle is forcibly carried out which is short compared to the operating time and in which the Lambda value is reduced from a value <1 to a value below 1 and in which the resulting electrical quantity is measured and its maximum value (A, B, C) is stored, and that the electrical setpoint is followed up with this maximum value is set so that the control circuit regulates to the lambda target value, and that when the maximum value (A, B, C) lies outside a predetermined window (F), ie outside the limits existing for the adjustment, an interference signal is generated. 2. The method according to claim 1, characterized, that a calibration cycle after a certain one Number of hours of operation or gas starts burner is initiated. 3. The method according to any one of the preceding claims,  characterized, that in the calibration cycle the lambda value <1 at least is as large as the adjustable lambda setpoint. 4. Circuit for regulating a gas burner, in particular gas-blown burner with a measuring electrode, in particular ionization electrode, which places a combustion variable temperature (lambda value) corresponding electrical measurement variable to the control circuit, in the control circuit a comparator comparing the respective electrical measurement variable with a setpoint generator compares and regulates the gas-air ratio to a lambda setpoint, characterized in that after an operating time detected by an activation circuit ( 21 ), in which the gas burner operates in the control mode, a changeover switch ( 13 ) breaks the control under and on Ramp generator ( 22 ) reduces the gas-air ratio starting from a lambda value <1 to a value below 1, the electrical variable (U) passing through a curve (I, II, III), and that a detection and Memory circuit ( 23 , 24 ) records the value of the measured variable in the maximum (A, B, C) of the curve (I, II, III) and stores the setpoint tgeber ( 11 ) adjusted to this value as the basic value and that the detection circuit ( 23 ) triggers an interference signal if the respective maximum (A, B, C) lies outside a predetermined window.