AT505442A1 - METHOD FOR FUEL GAS AIR ADJUSTMENT FOR A FUEL-DRIVEN BURNER - Google Patents

Description

Ο 5. 07. 07

Vaillant Austria GmbH AT 4239

The invention relates to a method for fuel gas-air adjustment for a fuel gas burner.

From the prior art it is known that the fuel gas to air ratio of a fuel gas burner can be adjusted by measuring the lonisationsspannung or the ionisationsstrom on a monitoring electrode. EP 770 824 B1 describes a method in which, starting from a superstoichiometric burner operation, the excess air is reduced until there is a slight substoichiometric combustion. In this case, the ionization voltage between an ionization electrode and the burner is measured. At stoichiometric combustion (λ = 1.0) the ionisation voltage is maximal. Consequently, the ionization voltage, starting from superstoichiometric combustion, initially increases in the reduction of the excess air in order to reach a maximum under stoichiometric combustion. If the ionization voltage drops on further reduction of the air fraction, this is an indicator that the combustion is substoichiometric. The method known from EP 770 824 B1 now provides that, starting from the amount of air present at maximum ionization voltage, the proportion of air is increased by a defined amount, so that the setpoint air ratio is reached. This can be done, for example, by increasing the speed of a combustion air blower by 25%, based on the stoichiometric combustion.

Embodiments of this control method are also known from DE 40 27 090 C2, DE 196 18 573 C1 and US 5,971,745 A.

A disadvantage of such a method is that always a stoichiometric or slightly substoichiometric combustion must be started. This results in substantial amounts of carbon monoxide and nitrogen oxide emissions.

From DE 102 00 128 B4 and EP 833 106 B1 methods for adjusting the fuel gas-air mixture are known in which a fuel gas-air mixture is emaciated so long until the flame goes out. Starting from this point, the burner is then operated with a defined richer mixture. Even with such methods is disadvantageous that arise by the extinguishment of the flame and the subsequent restart increased pollutant emissions. Furthermore, the method can not be integrated into normal operation.

The invention has for its object to provide a method for controlling the fuel gas-air mixture in combustion gas-powered burners by ionisationsstrommessung, which avoids polluting combustion conditions.

The object is achieved in that during the operation of the burner, the fuel gas-air mixture is emaciated and in this case the ionization signal is continuously measured. From the ionization signal a gradient is formed during the change. If the gradient exceeds a certain gradient or if the gradient rises disproportionately in comparison to the previous course, then the emaciation is terminated and the fuel gas-air mixture is enriched in a defined manner.

The measurement signal is highly dependent on deposits on the electrode as well as the position of the electrode. Therefore, it is not appropriate to use exceeding or falling below a certain absolute value as a relevant event. The sharp increase in the gradient, on the other hand, is a sure sign that the flame will soon lift off as the proportion of air increases further.

Advantageous embodiments will become apparent according to the features of the dependent claims. Thus, the gradient can be determined by dividing the difference signal of the ionization electrode with the differential speed of the fan motor. Alternatively, a division of the difference signal of the ionization electrode with the difference adjustment position of the actuator of a gas valve or a differential time unit can take place.

The signal of the ionization electrode can be detected by connecting a constant voltage source to the burner flame and a resistor in series, and measuring the voltage drop across the resistor.

The invention will now be explained in detail with reference to FIGS. Show here

Figure 1 shows a structure for carrying out the method according to the invention and

FIG. 2 shows the course of the ionisation signal in the method according to the invention.

1 shows a burner 1 with fan 8 with fan motor 9 in an air inlet 12. In the air inlet 12 opens a gas line 13, in which a gas valve 10 with actuator 11 is located. The blower motor 9 and the actuator 11 are connected to a controller 7. The burner 1 is a flame 2, in which an ionization electrode 3 protrudes.

The ionization electrode 3 is connected to a voltage source 4. This is connected to its second electrode with a resistor 5, which in turn is connected to the burner 1. Parallel to the resistor 5, a voltmeter 6 is connected, which is connected to the controller 7.

During operation of the burner, the fan 8 sucks in combustion air via the air inlet 12. The speed n of the fan 8 can be adjusted continuously. Via the gas valve 10, the amount of fuel gas supplied, which flows in via the gas line 13, can be changed continuously; In this case, the number of steps ns of the actuator 11 is detected. In the fan 8, fuel gas and air are mixed with each other and ignited at the outlet of the burner 1, so that a flame 2 is formed. Since the ions of the flame 2 are electrically conductive, a current can flow between the ionization electrode 3 and the burner 1. It follows that an electric voltage UFiamme is present. The ion flux through the flame 2 ensures that the electrical circuit (burner 1, ionization electrode 3, voltage source 4, resistor 5) is closed. FIG. 2 shows the profile of the voltage U measured at the resistor 5 via the air ratio λ and the fan speed n. U0 is the voltage of the voltage source 4. The following applies: U = Uo-U flame

It can be seen that the voltage U measured at the resistor 5 is minimal at stoichiometric combustion (λ = 1.0). As the excess air increases, the voltage U increases continuously. With an air ratio of about 1.6, the voltage U increases significantly more than before. At an air excess of about λ = 1.7, the flame rises. It is no longer possible to measure an ionization signal; an unillustrated safety valve locks the fuel gas supply.

In the control method according to the invention, the burner 1 first runs with a previously unknown excess of air. At constantly open gas valve 10, the speed n of the blower 8 is increased. As a result, the air ratio λ increases. The voltage drop U across the resistor 5 is measured continuously over the time t and passed on to the controller 7. In the control 7, the gradient Δυ / Δη is calculated, where n is the speed of the fan 8. If the gradient Δυ / Δη increases excessively above a certain point, this is an indication that the flame will soon lift off and thus break off. The air ratio λ is then about 1.6. Starting from this point, the speed n of the fan is now specifically reduced in such a way that an air ratio λ * 1.25) is established. As an alternative to determining the gradient by means of the quotient of the difference signal to the differential speed AU / Δη, a gradient of differential voltage Δυ to the differential setting position of the actuator Ans can also be formed if a reduction in the fuel gas quantity is undertaken instead of an increase in the fan speed. As a further variant, a gradient from time can also be formed with constant emaciation {Alf).

The operating state in which a lift-off is imminent can be determined by comparing the current gradient with at least one previous gradient and in the case that the current gradient converts the comparison value (s). exceeds a certain percentage, the expected state is present. For example, the lowest measured gradient can be used as comparison value. Alternatively, an absolute value can be specified.

In order to eliminate the influence of signal noise (fluctuation of the measuring signal by a trend line), the time difference or speed difference must not be selected too small.

Instead of the voltage drop U across the resistor 5, the voltage of the flame UFiamme can also be measured directly. In this case, however, the ionization voltage at stoichiometric combustion is maximum and the ionization voltage signal drops as the air ratio is increased.

Instead of a constant voltage U0, a constant current source with a constant current I0 can also be connected to the series connection of the resistor 5 to the flame 2. Depending on the flame resistance, a certain voltage sets.

Claims (5)

Verfahren 5. 07. 07 Vaillant Austria GmbH AT 4239 PATENT CLAIMS 1. Method for fuel gas-air adjustment for a burner operated by gas (1), which is monitored by means of an ionization electrode (3), wherein the signal of the ionization electrode (3) directly or indirectly is measured, characterized in that during the operation of the burner (1) the fuel gas-air mixture emaciated while the signal of the ionization (3) is measured continuously, in this case the gradient of the signal of the ionization (3) is formed, when exceeded a certain gradient or the disproportionate increase in the gradient, the emaciation of the fuel gas-air mixture is terminated and the fuel gas-air mixture is enriched defined. 2. A method for fuel gas-air adjustment for a fuel gas burner according to claim 1, characterized in that the air via a blower (8) with blower motor (9) is promoted and the gradient of the signal of the ionisation (3) from the division of Difference signal of the ionization electrode (3) with the differential speed of the fan motor (9) is determined. r 3. A method for fuel gas-air adjustment for a fuel gas burner according to claim 1, characterized in that the fuel gas via a gas valve (10) with actuator (11) is passed and the gradient of the signal of the ionisation (3) from the division of Difference signal of the ionization electrode (3) with the difference position of the actuator (11) is determined. 4. A method for fuel gas-air adjustment for a fuel gas burner according to claim 1, characterized in that the gradient of the signal of the ionization electrode (3) from the division of the difference signal of the ionization electrode (3) is determined by the difference time. 5. A method for fuel gas-air adjustment for a fuel gas burner according to one of claims 1 to 4, characterized in that a constant voltage source (4) or constant current source with the flame (2) of the burner (1) and a resistor (5) serially is connected and as a signal of the ionization electrode (3), the voltage drop across the resistor (5) is measured.