EP1154203B1 - Measuring device for a flame - Google Patents

Abstract

The measurement device for a flame, is particularly for use in a regulating device for a burner. It has an ionization electrode in the burner flame area, to which alternating voltage is connected and dependent upon the ionization current a direct voltage constituent is superimposed. The alternating voltage constituent influenced by the flame resistance is separable by first devices (5,6) from the direct voltage constituent, with which it is comparable via second devices (9,10) in order to produce a pulse width modulated signal. The two voltage constituents are separable by a high pass and a deep pass. They are comparable by a comparator (9). The direct voltage constituent is comparable with a reference voltage (U REF) in order to be used as a flame signal. The flame signal is applied to a monoflop (11), in order to form a static on/off signal.

Description

The present invention relates to a measuring device for a flame according to claim 1. The invention also relates to a control device for a burner with the measuring device for a flame according to claim 1.

From DE 196 32 983 A1 discloses a measuring device for a flame and an associated control device, a gas burner is known in which by means of an ionization electrode lambda set value for low emissions is set. By means of a comparator, the analog signal is digitized for further processing. However, the signal generated by the comparator has only a small signal swing and a low signal-to-noise ratio at the on-off threshold if the signal is also to be used for flame monitoring.

The present invention has for its object to provide a measuring device for a flame of the type mentioned, which allows a more accurate and improved signal evaluation.

The stated object is achieved according to the invention by the features specified in the independent claims.

It is thus the essence of the invention that the alternating component influenced by the flame signal can be separated from the direct voltage component via first means and the separate alternating component can be compared to the separated direct voltage component via second means in order to generate a pulse-width-modulated signal.

By comparing the alternating component with the DC component, fluctuations in the amplitude in the supply voltage are compensated for, since both components have the amplitude in change the same ratio. Changes in the flame, z. B. due to changes in the air ratio, on the other hand influence the two shares unequal.

Further advantages are the adjustable signal range in a wide range, the high sensitivity and the large signal-to-noise ratio whether the flame is on or off and that the analog signal is very accurate and reproducible.

Further advantageous embodiments of the invention will become apparent from the dependent claims.

Thus, the signal transmission via an optocoupler is possible, with both information, flame on and off and PWM signal can be transmitted via only one optocoupler. Through the installation of contact protection resistors, the ionization electrode can be made touch-proof.

Some preferred embodiments of the device according to the invention or of the method according to the invention will be explained in more detail with reference to the following drawings.

Fig. 1

Blockschaltbild des erfindungsgemässen Aufbaus;

Fig. 2

tatsächlicher Aufbau der in Figur 1 als Ersatzschaltung 1 dargestellten Flamme mit Ionisationselektrode.

Showing:

Fig. 1

Block diagram of the inventive structure;

Fig. 2

Actual construction of the flame shown in Figure 1 as an equivalent circuit 1 with ionization.

Fig. 1 shows schematically the principle of operation of the inventive circuit. 1, in an equivalent circuit, the flame 14 with ionization electrode 15 shown in FIG. 2 is represented by a diode 1a and a resistor 1b. About L and N, an AC voltage of, for example, 230V is applied. If a flame is present, because of the flame diode la flows through the blocking capacitor 3 in the positive half-wave, a larger current than in the negative half-wave. As a result, a positive DC voltage U _{B is formed} on the blocking capacitor 3 between L and a resistor 2 mounted for the purpose of contact protection. By a decoupling resistor 4 therefore flows a direct current from N to the blocking capacitor 3. The amount of direct current depends on U _B and thus directly from the flame resistance 1b. The flame resistance 1b also influences the alternating current through the decoupling resistor 4, but to varying degrees compared to the direct current. Through the resistor 4 thus flows a direct current and an alternating current as described above. The resistor 4 is now followed by a high pass 5 and a low pass 6. Through the high-pass 5, the alternating current is filtered out and blocked the DC component. Due to the low-pass filter, the DC component dependent on the flame resistance 1b is filtered out and the alternating current is essentially blocked. In an amplifier 7, the alternating current flowing from the high-pass filter 5 is amplified and a reference voltage U _{Ref is} added. In an amplifier 8, the direct current flowing from the high-pass filter 6 is amplified with possibly small alternating current components and a reference voltage U _{Ref is} added. The reference voltage U _Ref can be chosen arbitrarily, eg U _Ref = 0, but it is preferably chosen so that the amplifiers and comparators only need one supply. Exiting the amplifier 7 AC voltage U is at a comparator 9 _- and the emerging from the amplifier 8 DC voltage U ₌ compared and a pulse width modulated (PWM) signal. If the amplitude of the mains voltage changes, the AC voltage and the DC voltage change in the same ratio, the PWM signal does not change. The signal swing of the PWM signal can be adjusted by means of the amplifiers 7 and 8 in a wide range between τ = 0 and τ = 50% duty cycle.
The DC voltage component U = is compared in a comparator 10 with the reference voltage U _Ref . If a flame is present, the DC component is greater than the reference voltage (U ₌ > U _Ref ) and the comparator output of the comparator 10 switches to 0. If no flame is present, the DC component is approximately equal to the reference voltage (U ₌ ≈ U _Ref ). Because of the DC voltage component superimposed, low AC voltage component, which the low-pass filter 6 does not filter out, the DC component briefly falls short of the reference voltage and at the comparator output of the comparator 10 pulses appear. These pulses are applied to a retriggerable monoflop 11. The monoflop is triggered so that the pulse train output from the comparator 10 comes faster than the pulse duration of the monoflop. If a flame is present, the monoflop will not be triggered and the output will always show a 0. The retriggerable monoflop 11 thus forms a "missing pulse detector" which indicates the dynamic on - turns off / off signal into a static on / off signal.

Both signals, the PWM signal and the flame signal can now be further processed separately or linked by means of an OR gate 12. As an output of the OR gate 12, if there is a flame, a PWM signal is shown whose duty cycle is a measure of the flame resistance 1b. If no flame is present, the output of the OR gate is permanently at 1. The PWM signal can be transmitted via an optocoupler, not shown, in order to achieve a protective separation between the mains side and the protective low voltage side.

FIG. 2 shows the actual structure of the diode 1a shown in FIG. 1 as an equivalent circuit 1 and of the resistor 1b, as is also known, for example, from DE 196 32 983 A1. By a burner 13, a flame 14 can be generated. In the flame area 14 protrudes an ionization electrode 15 which detects the ionization current. This depends on the flame resistance and thus the electrode temperature. The electrode temperature in turn depends on the lambda value and thus the excess air of the mixture to be burned. By means of the lambda value, the ratio of air to gas can be adjusted. Typically, the lambda value is chosen between 1.15 and 1.3 to achieve a higher than stoichiometric air to gas ratio

Of course, the invention is not limited to the embodiments shown and described.

Claims (10)

1. Measuring device for a flame, in particular for use in a control device for a burner (13), having an ionization electrode (15) to which an AC voltage is applied and arranged in the flame region (14) of the burner, so that a DC voltage component is superimposed as a function of the ionization current,
   characterized in that
   the AC voltage component affected by the flame resistance can be separated from the DC voltage component via first means (5, 6), and the separated AC voltage can be compared with the separated DC voltage component via second means (9, 10) in order to generate a pulse-width modulated signal.
2. Measuring device according to Claim 1, characterized in that the AC voltage and the DC voltage component can be separated from each other by means of a highpass filter (5) and a lowpass filter (6).
3. Measuring device according to Claim 1 or 2, characterized in that the AC voltage and the DC voltage component can be compared by means of a comparator (9).
4. Measuring device according to Claim 1, 2 or 3, characterized in that the DC voltage component can be compared with a reference voltage (U_ref) by means of a comparator (10) in order to be used as a flame signal.
5. Measuring device according to Claim 4, characterized in that the flame signal is applied to a triggered monoflop (11) in order to form a static input/output signal.
6. Measuring device according to one of the preceding claims, characterized in that the flame signal triggered via a monoflop (11) is combined with the pulse-width modulated signal in an OR gate (12).
7. Measuring device according to Claim 6, characterized in that the signal output from the OR gate (12) can be transmitted via an optocoupler.
8. Measuring device according to one of the preceding claims, characterized in that at least one resistor (2) is connected in series with the ionization electrode (15) as shock hazard protection.
9. Control device for a burner (13), having the measuring device according to one of Claims 1 to 8.
10. Use of the measuring device according to one of Claims 1 - 8 in a combustion automation unit.

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