This disclosure relates to methods for calibrating a gas burner regulating system, and methods for gas burner regulation.
A method for gas burner regulation, in which a gas-combustion-air mixture is fed to a gas burner for combustion, is known from DE 198 24 521 A1 . The gas-combustion-air mixture is provided as a result of intermixing a gas flow and an air flow or combustion air flow, wherein the quantity of the gas-combustion-air mixture which is fed to the gas burner, and therefore a so-called burner load, is adjusted by means of a blower, specifically by means of a rotational speed of the blower. According to this prior art, the blower is associated with the air flow. By means of a gas valve which is associated with the gas flow, the gas flow is adjusted in dependence upon the combustion air flow in such a way that a prespecified, defined composition of the gas-combustion-air mixture is maintained, specifically in the sense of a 1:1-gas/air compound regulation or even for forming a 1:N-gas/air compound regulation. For this, according to this prior art, a sensor is connected between the gas flow and the combustion air flow, the measurement signal of which is fed to a regulating device which, in dependence upon the measurement signal of the sensor, operates the gas valve in such a way that the defined composition of the gas-combustion-air mixture is maintained.
In order to ensure a good combustion quality in the gas burner, even in the case of fluctuating gas qualities, the composition of the gas-combustion-air mixture which is to be fed to the gas burner for combustion has to be adapted to the gas quality.
Therefore, in the case of a gas with a high calorific value the quantity of gas in comparison to the quantity of air in the gas-combustion-air mixture can be reduced. On the other hand, if it is a gas with a low calorific value then the quantity of gas in the gas-combustion-air mixture has to be increased. Adapting the composition of the gas-combustion-air mixture especially to the gas quality is carried out via a calibration of the gas burner regulating system.
A method for regulating a gas burner, in which the calibration of the composition of the gas-combustion-air mixture is carried out by means of a carbon monoxide sensor which is associated with an exhaust gas flow discharged from the burner, is known from EP 1 331 444 A2. The carbon monoxide sensor detects the carbon monoxide concentration in the exhaust gas. According to this prior art, for calibration of the gas-combustion-air mixture, specifically of the composition of the gas-combustion-air mixture, it is conducted so that starting from any, relatively lean composition the gas-combustion-air mixture is enriched, specifically until the carbon monoxide concentration, which is detected by the carbon monoxide sensor, in the exhaust gas reaches or exceeds a prespecified limit value. Upon reaching or exceeding this limit value, the gas-combustion-air mixture, according to this prior art, is not further enriched, rather this composition of the gas-combustion-air mixture is associated with a so-called combustion air ratio λ of 1.08. Starting from the gas-combustion-air mixture which is calibrated to the combustion air ratio of λ=1.08, the composition of this can subsequently be enleaned for providing a larger combustion air ratio.
This calibration method which is known from EP 1 131 444 A2 has the disadvantage that this is dependent upon the burner load. In this respect, a separate calibration has to be undertaken for each burner load when applying the method which is known from this prior art. This is disadvantageous.
There is a need for a method for the calibration of a burner regulating system which is independent of a so-called burner load.
This disclosure relates to methods for calibrating a gas burner regulating system, and also methods for gas burner regulation. In one example, and for the calibration of a gas burner regulating system, starting from a relatively lean gas-combustion-air mixture which is fed to the gas burner for combustion, the gas-combustion-air mixture is enriched, specifically until the measurement signal which is provided by a sensor first increases and then reduces to approximately zero, wherein the gas-combustion-air mixture, in which the measurement signal which is provided by the sensor amounts to approximately zero, is defined as a gas-combustion-air mixture with a stoichiometric combustion air ratio of λ=1, wherein starting from this gas-combustion-air mixture, this can be enleaned to a desired combustion air ratio of λ>1.
Example developments may be gathered from the dependent claims and from the subsequent description. Exemplary embodiments of the disclosure , without being limited thereto, are explained in more detail with reference to the drawing. In the drawing:
This disclosure relates to methods for calibrating a gas burner regulating system, and also to methods for gas burner regulation.
The amount of gas-combustion-air mixture 12 which is to be fed to the gas burner 10 for combustion is adjusted by means of a blower 19, specifically by means of a rotational speed of the blower 19, wherein the blower 19, according to
In order to make available to the gas burner 10 a gas-combustion-air mixture 12 with a defined composition in the sense of a 1:N-gas/air compound regulation independently of the quantity of combustion air 13 which is drawn in by means of the blower 13, in the exemplary embodiment of
In the depicted exemplary embodiment of
Reference may also be made at this point to the fact that the 1:N-gas/air compound regulation can also be provided in a pneumatic way.
In order to ensure a good combustion quality in the gas burner 10, especially in the case of fluctuating gas qualities, calibration of the gas burner regulating system is necessary, wherein in the exemplary embodiment of
For such a sensor 28, which is designed as a carbon monoxide sensor,
For calibration of the gas burner regulating system, and starting from a relatively lean gas-combustion-air mixture 12 with any composition, which is currently fed to the gas burner 10 for combustion, the gas-combustion-air mixture 12 is enriched, reducing the combustion air ratio λ or the air coefficient, specifically until the measurement signal which is provided by the sensor 28 first increases and then reduces to approximately zero. The gas-combustion-air mixture 12, in which the measurement signal which is provided by the sensor 28, that is to say the carbon monoxide concentration XCO which is measured by the sensor, amounts to approximately zero, is defined as a gas-combustion-air mixture 12 with a stoichiometric combustion air ratio of λ=1. Starting from this gas-combustion-air mixture 12 with the stoichiometric combustion air ratio of λ=1, the gas-combustion-air mixture 12 is subsequently enleaned to a desired combustion air ratio of λ>1, for example to a gas-combustion-air mixture with a combustion air ratio of λ>1.3.
During the above calibration, a gas flow rate adjusting device, which may be associated with the gas flow 14, is adjusted for the enriching and subsequent enleaning of the gas-combustion-air mixture 12 in order to thereby adjust the gas quantity of the gas-combustion-air mixture. The gas nozzle 17 can be this gas flow rate adjusting device. Alternatively, a separate gas flow rate adjusting device 30 which is integrated into the gas line 16, or a gas flow rate adjusting device which is integrated into the gas valve 24, can be used for the calibration.
The gas flow rate adjusting device which is used for the calibration—in the exemplary embodiment of FIG. 1—must be positioned downstream of the measuring point 27 at which the sensor 20 acts on the gas line 16. If a gas flow rate adjusting device which is integrated into the gas valve 24 were to be consequently used for the calibration, then the measuring point 27 of
Starting from that opening position of the gas flow rate adjusting device 30 in which the gas-combustion-air mixture 12 is defined with the stoichiometric combustion air ratio of λ=1 by way of the calibration , the gas flow rate adjusting device 30 is closed further by a defined degree for providing a combustion air ratio of λ>1, wherein this defined degree is dependent upon characteristics of the gas flow rate adjusting device 30 and is determined in dependence upon characteristics of the gas flow rate adjusting device 30.
For the calibration, use is made of a non-calibrated sensor, specifically a non-calibrated carbon monoxide sensor 28 in the depicted exemplary embodiment, which with oxygen present in the exhaust gas 29 detects the concentration of carbon monoxide in the exhaust gas 29.
The calibration of the gas burner regulating system may be carried out automatically after there being an event which triggers the calibration.
An event which triggers the calibration can be a signal which occurs at regular time intervals in order to carry out calibration of the gas burner regulating system at defined time intervals.
A further event can be a manually triggered signal in order to carry out, when triggered, calibration of the gas burner regulating system by means of a monitor.
Furthermore, calibration can be triggered in dependence upon the measurement signal which is provided by the sensor 28, specifically when the carbon monoxide concentration XCO, which is measured by the sensor 28, exceeds a limit value.
The signal of the sensor 28 may be used exclusively for calibration and not for the 1:N-gas/air compound regulation. The sensor 20 may serve for the 1:N-gas/air compound regulation, wherein the air flow 13 which is provided by means of the blower 19 serves with respect to control engineering as an input reference variable for the gas flow 14 in order to provide the defined 1:N-gas/air compound regulation.
When calibrating by using the sensor 28, the composition of the gas-air mixture 12 can be adjusted in order to compensate for different gas qualities. For this, a gas flow rate adjusting device 30 may be adjusted in dependence upon the measurement signal of the sensor 28, the opening position of which device remains unaltered during the subsequent 1:N-gas/air compound regulation. During the subsequent 1:N-gas/air compound regulation, the gas valve 24 may be operated for matching the gas flow 14 to the air flow 13.
The calibration of a gas burner regulating system may be independent of the so-called burner load.
Number | Date | Country | Kind |
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10 2010 044 762.5 | Sep 2010 | DE | national |