WO2001006179A1

WO2001006179A1 - Device for controlling oil burners

Info

Publication number: WO2001006179A1
Application number: PCT/DE2000/002193
Authority: WO
Inventors: Marco Techt; Rudolf Haug
Original assignee: Karl Dungs Gmbh & Co.
Priority date: 1999-07-17
Filing date: 2000-07-05
Publication date: 2001-01-25
Also published as: CN1361854A; DE19933591A1; KR20020015716A; EP1196722A1

Abstract

The invention concerns a device for controlling the flame of oil burners, in particular yellow-flame or blue-flame burners, comprising a flame detector detecting the luminous intensity in the combustion space, and a control connection controlling the fuel supply based on the detected luminous intensity, with a luminance threshold (Bmax (I)) for the starting phase (I) of the burner, above which an error signal is transmitted, and a darkness threshold (Bmin (III, IV) higher than the luminance threshold (Bmax (I)) for the stabilising and operating phase (III, IV) of the burner, below which an error signal is transmitted. The darkness threshold (Bmin (III)) during the stabilising phase (III) is higher than the darkness threshold (Bmin (IV)) during the subsequent operating phase (IV). Thus the same flame detector can be used for yellow-flame and blue-flame burners.

Description

Monitoring device for oil burners

The invention relates to a device for flame monitoring of oil burners, in particular of yellow or blue burning oil burners, comprising a flame sensor detecting the illuminance in the combustion chamber and a monitoring circuit controlling the fuel supply as a function of the detected illuminance with a light threshold for the startup phase of the oil burner, above which an error message takes place, and with a higher than the light threshold dark threshold for the stabilization and operating phase of the oil burner, below which an error message occurs. The European standard EN 230 allows the use of flame sensors (flame sensors) for monitoring oil burners, which have an illuminance of at least 1 lx (lux) in the visible range. Furthermore, the standard requires a "negative switching difference", ie the bright message before fuel-free (extraneous light) must be given at lower illuminance levels than a dark message when the flame goes out during operation (flame failure).

These requirements for the flame signal are illustrated in FIG. 2 on the basis of the starting process of a conventional automatic burner control. The values that the flame signal must not assume are hatched. Otherwise an error message is issued and the fuel supply is stopped.

During the start-up phase I of the oil burner, the illuminance detected by a flame sensor in the combustion chamber must not exceed the light threshold B _max (I), otherwise the fuel supply is stopped. The safety phase II following the start-up phase is the maximum time from when the fuel valves are opened, during which fuel can flow into the combustion chamber without the formation of a flame. During the stabilization phase III and the operating phase IV, the detected illuminance must not fall below the dark threshold B _m j_ _n (III, IV) (> B _max (D) occurring in the event of a flame failure, otherwise the fuel supply is stopped. In order to increase the security of the monitoring, The negative switching difference ΔB = B _max (I) - B _m - _j _ _n (III, IV) must take on as large a value as possible, and the bright signal during operation must be given with the highest possible illuminance.

Yellow-burning oil burners (yellow burners) have a high lighting intensity in the visible range. Blue-burning oil burners (blue burners) have a low radiation in the visible range, but start as a yellow burner, so that they achieve a high illuminance at least during the start-up phase. The different courses of the illuminance for yellow burners (a) and blue burners (B) are shown in FIG. 2.

Until now it was common to take into account the different lighting intensities of the burner types by using flame sensors with different sensitivity. For blue burners, this means that the flame signal is set to significantly lower illuminance levels during operation so that external radiation, e.g. with the burner hood removed, a flame is simulated and a flame failure can only be delayed or not responded to at all.

Another problem can be short-circuits on the conductor tracks of the burner control, short-circuits in the supply lines to the flame monitor or other short-circuits that can occur during operation with a flame. With such a short circuit, it is not possible to register a flame failure.

In contrast, it is the object of the invention to develop a flame monitoring device of the type mentioned in such a way that the same flame sensor can be used for monitoring yellow and blue-burning oil burners, and to further improve the safety requirements imposed on flame monitoring devices.

In a first aspect of the invention, this object is achieved in that the dark threshold during the stabilization phase is higher than the dark threshold during the subsequent operating phase. For the use of the flame sensor in blue burners, the higher dark threshold was introduced during the stabilization phase or after the safety phase, so that increased illuminance is required during the stabilization phase. Since a blue burner starts up as a yellow burner and is only driven into the blue area during operation, an increased lighting signal is also available during the stabilization phase. The requirement of increased illuminance during the stabilization phase or after the safety time also reduces the risk of short circuits with contact resistance.

In preferred embodiments of the invention, in the case of blue-burning oil burners, the dark threshold during the stabilization phase is chosen to be higher than the illuminance during its operating phase. Low illuminance is required during operation to ensure safe operation for blue burners.

The above-mentioned object is also achieved in a second aspect of the invention in that the monitoring circuit has, at least for the operating phase, a maximum light threshold above the dark threshold, above which the fuel supply is interrupted. This maximum light threshold is preferably also provided for the stabilization phase and for a safety phase provided between the start-up phase and the stabilization phase.

The conventional monitoring process was supplemented by an additional maximum light threshold for short-circuit detection (low-impedance short-circuits). The short-circuit detection can rule out the case of an undetected flame simulation (eg due to a fuel valve, a defective flame monitor lead, etc.). The monitoring circuit according to the invention can be implemented, for example, by means of hardware with different switching thresholds or by means of analog value detection with definition of different switching thresholds via software.

The invention also relates to corresponding monitoring methods and automatic firing systems which work or are equipped with such a flame monitoring device.

Further advantages of the invention result from the description and the drawing. Likewise, the features mentioned above and those listed further can be used according to the invention individually or in combination in any combination. The embodiment shown and described is not to be understood as an exhaustive list, but rather has an exemplary character for the description of the invention.

The invention is illustrated in the drawing and is explained in more detail using an exemplary embodiment. It shows:

Fig. 1 is a monitoring diagram of an inventive

Flame monitoring device with schematically indicated temporal courses of the illuminance of yellow (a) and for blue (b) burning oil burners; and

Fig. 2 is a monitoring diagram of a conventional monitoring with schematically indicated temporal profiles of the illuminance of yellow (a) and for blue (b) burning oil burners.

In order to rule out the problems of the monitoring diagram according to FIG. 2 described above, the evaluation of the flame signal is changed in the monitoring diagram according to FIG. 1. The monitoring diagram shown in FIG. 2 was achieved by an additional maximum light threshold B _max for short-circuit detection (low-impedance short circuits) during the safety, stabilization and operating phases II, III, IV and by a higher dark threshold B _m -j_ during stabilization phase III. _n (III) added for increased illuminance.

The short-circuit detection can rule out the case of a flame simulation.

During stabilization phase III, an illuminance becomes higher than B _m; y_ _n (III) required. Since a blue burner starts to ignite as a yellow burner and is only driven into the blue area during operation, an increased lighting signal is also present during stabilization phase III. In the operating phase IV, the dark threshold B _mj _ _n (IV) is then lowered in order to also permit lower illuminance and thus to ensure safe operation for blue burners. The requirement of an increased illuminance B _m -j_ _n (III) after the safety time II reduces the risk of short circuits with contact resistance.

The monitoring diagram shown in FIG. 1 thus offers the following advantages:

Short circuits during the operating times with flame formation, i.e. during the stabilization phase III and the operating phase IV, are reliably recognized.

Increased safety by requesting an excessive flame signal during the stabilization phase.

A single flame sensor type LDR (light depending resistor) can be used for yellow and blue burners, which increases efficiency. The LDR can instead the commonly used IRD (infrared flicker detector), which is much more expensive than the LDR.

There is no need to adjust the flame sensors to the respective burner, as required by the IRD.

A device for flame monitoring of oil burners, in particular of yellow or blue burning oil burners, comprises a flame sensor detecting the illuminance in the combustion chamber and a monitoring circuit controlling the fuel supply depending on the detected illuminance with a light threshold B _max (I) for the start-up phase I of the oil burner, above of an error message, is, and is effected with a higher than the light threshold B _max (I) lying dark threshold B _m i _n (III, IV) for the stabilization and the operating phase III, IV of the Olbrenners below which an error message In this case, the dark threshold B _m j_ _n (III) during the stabilization phase III is higher than the dark threshold B _m -j_ _n (IV) during the subsequent operating phase IV. The same flame sensor can be used to monitor yellow and blue-burning oil burners.

Claims

claims

Device for flame monitoring of oil burners, in particular of yellow or blue burning oil burners, comprising: a flame sensor detecting the illuminance in the combustion chamber and a monitoring circuit controlling the fuel supply as a function of the detected illuminance with a light threshold (B _max (I)) for the start-up phase (I) of the oil burner, above which an error message is given, and with a dark threshold (B _m j_ _n (III, IV)) higher than the light threshold (B _max (I)) for the stabilization and operating phase (III, IV) of the oil burner below which an error message occurs, characterized in that the dark threshold (B _mj _ _n (III)) during the stabilization phase (III) is higher than the dark threshold (B _m -j_ _n (IV)) during the subsequent operating phase (IV) ,

Flame monitoring device according to claim 1, characterized in that in the case of blue-burning oil burners, the dark threshold (B _m - _j _ _n (III)) during the stabilization phase (II) is chosen to be higher than the illuminance during its operating phase (IV).

Flame monitoring device according to the preamble of claim 1, particularly according to claim 1 or 2, characterized in that the monitoring circuit at least for the operating phase (IV) one on top of the dark level (B _m i _n (IV) lying maximum light threshold (B _max) up points above which the fuel supply is interrupted.

4. Flame monitoring device according to claim 3, characterized in that the maximum light threshold

(B _max )) is also provided for the stabilization phase (III).

5. Flame monitoring device according to claim 4, characterized in that the maximum light threshold

(B _max ) is also provided for a safety phase (II) provided between the start-up phase (I) and the stabilization phase (III).

6. burner control with a flame monitoring device according to one or more of the preceding claims.

7. A method for flame monitoring of oil burners with a flame monitoring device according to one or more of claims 1 to 5.