DE19502900C2 - Ionization electrode - Google Patents

Description

The invention relates to an ionization electrode, which in the Flame area of a burner protrudes.

Burners, for example gas burners in gas heaters for heating of service and / or heating water, are with a Equipped ionization electrode that monitors the burner flames. An electrical current arises according to the flame temperature from the ionization electrode to an electrical ground. In the DE 44 33 425 A1 is described as such Ionization electrode can be used to control the combustion can. To one you want for optimal combustion Obtaining lambda value depends on the gas quality and Ambient conditions mixed with more or less air.

AT 391 197 B shows the burner plate of a surface burner and a device for monitoring the operation of such Brenners. For this purpose, an ionization electrode is provided, which is above the burner plate is provided in the area of special outlet openings is. The arrangement of special outlet openings is costly and increases the manufacturing price of such a burner significantly.

According to JP 58-99 614, a combustion sensor is proposed which of a helix and a wire running coaxially in it consists. In contrast to the AT 391 197 B, this exists Japanese patent does not measure the measuring distance between the  Ionization electrode and the burner, but only between the outer wire and inner wire. At high burner load, i. H. at high flame heights occur in this known device significantly different measured value than at low load, i.e. smaller Flame height.

Also in DE 39 37 290 A1, DE 36 07 386 C2 and DE 42 30 390 A1 such ionization electrodes are used.

It was used in two-stage and modulating burners found that the signal generated by the ionization electrode, d. H. the ionization current or the control voltage derived from it, also depending on the burner load, d. H. in Depends on the height of the burner flames. With the same Lambda setpoint thus occur at different loads on the Different output signals (ionization currents) at the burner Ionization electrode. This is undesirable because it causes the Regulation is impaired.

The object of the invention is an ionization electrode at the beginning to propose the type mentioned, by at high and low Burner load (flame height) as equal as possible Ionization current is reached.

According to the invention, the above object is for an ionization electrode type mentioned solved in that the ionization electrode deviates from the straight line and several lengths of the Ionization electrode alternately closer and farther from the Burner surface, and that the burner surface closest Sections at the highest temperature locations of the lowest flames lie, and that the longest sections of the burner surface at the location of the highest temperature of the highest flames. There are both higher and lower burner flames, ie set greater or smaller burner output, d. H. Burner load, length sections of the ionization electrode in the hottest flame zones, and between the length ranges there is a heat exchange. This results in a largely load-independent signal (ionization current). The one from the  Flame temperature-dependent ionization current does change with the lambda value depending on the gas type and Ambient conditions, but not depending on the respective set burner output what for the implementation of the control (cf. DE 44 33 525 A1) is advantageous because the burner load the measurement signal is practically not falsified.

Advantageous embodiments of the invention result from the Subclaims and the following description of a Embodiment. Show in the drawing

Fig. 1 is a plan view burner with a flame rod according to the prior art,

Fig. 2 is a side view of the burner with the ionisation electrode in the prior art,

Fig. 3 is a burner having an ionization electrode supervision according to the invention,

Fig. 4 is a side view of the burner with the ionisation electrode according to the invention,

Fig. 5 is an enlarged partial view of the ionization according to the invention,

Fig. 6 shows another embodiment of the ionization electrode and

Fig. 7 is a measurement diagram of the output signal of the ionisation electrode as a function of Lambda for two different burner loads.

A surface burner 1 has a plurality of rows 2 with nozzles 3 . An ionization electrode 6 is arranged above the burner surface 4 by means of a holder 5 . This extends directly to the longitudinal direction of the rows of nozzles 2 and projects over two or more rows of nozzles (cf. FIG. 1, FIG. 3).

According to the prior art, the ionization electrode 6 is straight and extends obliquely from the holder 5 to the burner surface 4 (cf. FIG. 2). With this design, when the burner flames are of different heights, that is to say with different burner loads, the output signal (ionization current) of the ionization electrode 6 depends on this, even if the lambda value is constant. This falsifies the regulation by which the combustion gas / air mixture is to be regulated according to the type of gas and other environmental conditions for optimal combustion.

The ionization electrode 6 according to the invention alternately has longitudinal sections 7, 8 , the longitudinal sections 7 being closer to the burner surface 4 than the respective subsequent longitudinal sections 8 (cf. FIGS. 4, 5, 6). A center line 9 of the length sections 7, 8 extends obliquely from the holder 5 towards the burner surface 4 (cf. FIG. 5).

In the embodiment according to FIGS. 4 and 5, the ionization electrode 6 is designed wave-shaped, the troughs 7 are closer to the burner surface 4 as the wave crests. 8 The distance a between the longitudinal sections 7 , 8 is approximately equal to the distance b between the nozzles 3 .

In FIG. 5, the flame heights for two different burner loads are shown. The low flames (small burner load) are shown in broken lines. The flames are indicated by dots at higher burner loads. At the higher burner load, the hottest points B of the flames lie in the region of the longitudinal sections 8 further away from the burner surface 4 . At the lower load, the hottest points A of the flames then occurring are in the area of the longitudinal sections 7 closer to the burner surface 4 . In both cases there is an intensive heat exchange between the longitudinal sections 7 , 8 . As a result, essentially the same ionization current flows from the ionization electrode 6 against the electrical mass formed by the burner 1 at all burner flame heights. The ionization current and the voltage signal derived from it are therefore practically not dependent on the burner load.

This is confirmed in the measurement diagram (see FIG. 7). The course of the signal of the ionization electrode 6 as a function of lambda at a burner output or burner load of 10 kW is shown squarely there. The corresponding course for an output of 20 kW is shown in a corresponding circle. It can be seen that the two curves are very close together in the region of interest of the lambda value from 1.1 to 1.45. For example, an output signal of 210 V was determined for lambda 1.3 both at a power of 10 kW and at a power of 20 kW.

To achieve the desired result, the ionization electrode 6 can not only be designed in a wave shape, as shown in FIGS. 4 and 5. It is also possible to design the ionization electrode 6 in the manner of a comb (cf. FIG. 6). The ionization electrode 6 can also be helical, the central axis of the helix being approximately on the center line 9 .

It is also possible to design the distance a between the one longitudinal section 7 and the respectively subsequent longitudinal section 8 differently with regard to the distance b of the nozzles 3 . For example, the distance a can be twice as large as the distance b.

Claims (7)

1. ionization electrode which projects into the flame area of a burner, characterized in that the ionization electrode ( 6 ) deviates from the straight line and several longitudinal sections ( 7 , 8 ) of the ionization electrode ( 6 ) are alternately closer and further away from the burner surface ( 4 ), and that the sections ( 7 ) closest to the burner surface ( 4 ) are at the points (A) of the highest temperature of the lowest flames, and that the longitudinal sections ( 8 ) furthest from the burner surface ( 4 ) are at the point (B) of the highest temperature of the highest flames . 2. Ionization electrode according to claim 1, characterized in that the ionization electrode ( 6 ) is wave-shaped, the wave troughs being closer to the burner surface ( 4 ) than the wave crests. 3. Ionization electrode according to claim 1, characterized in that the ionization electrode ( 6 ) is comb-shaped. 4. Ionization electrode according to claim 1, characterized in that the ionization electrode ( 6 ) is designed helically. 5. Ionization electrode according to one of the preceding claims, characterized in that the distances a of the closer longitudinal sections ( 7 ) from the respectively adjacent further longitudinal sections ( 8 ) are each approximately equal to the distance between adjacent burner nozzles ( 3 ). 6. Ionization electrode according to one of the preceding claims, characterized in that a center line ( 9 ) of the longitudinal sections ( 7 , 8 ) to the burner surface ( 4 ) extends obliquely. 7. Ionization electrode according to one of the preceding claims, characterized in that the ionization electrode ( 6 ) extends obliquely to the longitudinal direction of the rows of burner nozzles ( 2 ), wherein it projects over two or more rows of nozzles ( 2 ).