DE29608070U1 - Pilot burner with ground electrode - Google Patents

Description

&Ggr;::&Igr;&Ggr; rr.IIDr. Dieter Weber d _¥ .-

'..· ; '..·.„· »'*-Klaus Seiffert

Di _P i.-Ph _y s.

Dr. Winfried Lieke

Di _P i.-Ph _ys .

Patent attorneys

Weber, Seiffert, Lieke ■ Patent Attorneys · PO Box 6145 · 65051 Wiesbaden

Gustav-Freytag-Strasse 25

German Patent Office 65189 Wiesbaden

Zweibrückenstr. 1 2 PO Box 6145 · 65051 Wiesbaden

Telephone 0611/372720 and 3725 80 80297 Munich Telex 4-186247

Fax 0611/372111

^Date: 03 May 1996

Li/dl - st\anm\rausch96.003

Rauschert GmbH & Co KG
Paul-Rauschert-Strasse 6, 96347 Steinwiesen

Ignition burner with ground electrode

Description

The present invention relates to an ignition burner with injector, ionization electrode and ground electrode.

Examples of pilot burners are used in gas-powered heating systems, such as gas boilers or flow heaters. The fuel used in the heating system is ignited by a permanently burning pilot flame on the pilot burner. The pilot flame of the pilot burner is maintained by an injector that is connected to a gas reservoir. The pilot flame on the pilot burner is ignited by discharging an overvoltage between an ignition electrode arranged on the pilot burner and a ground electrode. If the pilot flame goes out, which can happen, for example, due to an air blast, a pressure surge or a temporary interruption in the gas supply

Postgiro: Frankfurt/M 6763-602
Bank: Dresdner Bank AG, Wiesbaden Account 27680700 (bank code 51080060)

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can, it must be re-ignited in the manner described above. If this re-ignition does not take place, the gas supply must be stopped. Otherwise, unburned gas could flow out of the injector unhindered, accumulate in large quantities and possibly lead to an explosion after ignition, which could pose a significant risk to people and equipment in the vicinity. For this reason, the burning of the ignition flame in such ignition burners is permanently monitored. This can be done, as is the case with the ignition burner of the present invention, via an ionization electrode, in which a small but measurable current flow is induced by flame ionization by the ignition flame. Such ionization currents measured via the ionization electrode of ignition burners according to the state of the art are in the order of about 1.5 microamperes, with the switching threshold being about 0.8 microamperes. The measurement of such low currents or differences in currents can be subject to errors in such systems due to the occurrence of leakage currents and can lead to malfunctions, e.g. extinguishing of the ignition flame due to unnecessary interruption of the gas supply or the above-mentioned dangers due to uncontrolled gas leakage. Another problem that can occur with ignition burners based on the state of the art is that the ignition flame is blown out by a pressure surge when the burner is ignited.

Compared to the prior art, the present invention is based on the object of creating an ignition burner with an injector, ionization electrode and ground electrode, in which the ignition flame is stabilized and in which the ionization currents measured via the ionization electrode are higher than in conventional ignition burners in order to ensure the highest possible functional reliability, measurement and switching accuracy, despite any leakage currents that may occur.

The object is achieved in that a section of the ground electrode of the ignition burner of the present invention runs through the area covered by the ignition flame between the injector and the ionization electrode.

It has been found that the shape and arrangement of the ground electrode of the pilot burner have an influence on the current flow induced in the ionization electrode and the stability of the ignition flame. The ground electrode of the pilot burner of the present invention is shaped and arranged in such a way that the ignition flame is divided and directed to the ionization electrode arranged above it. This apparently causes a stabilization of the ignition flame and reduces the risk of the ignition flame being blown out by the pressure surge during ignition or by an air blast. Another and particularly important advantage of the present

The advantage of the invention is that the arrangement of the ground electrode formed according to the invention causes currents of about 3 to 4 microamperes to be induced by the ignition flame in the ionization electrode, which corresponds to two to three times the current strength of known devices. These ionization currents, which are comparatively high compared to known arrangements, mean a considerable increase in the functional reliability of the ignition burner, since leakage currents, e.g. caused by corrosion-related leaks in the insulation of the ionization electrode, can no longer distort the signal generated in the measuring unit as easily as before.

In a preferred embodiment of the invention, the ground electrode of the ignition burner is an optionally bent rod. The ground electrode is preferably bent in a U-shape, with the U-bend preferably being curved and particularly preferably having a constant bending radius. The cross section of the ground electrode of the ignition burner preferably has a cylindrical cross section, but optionally also an ellipsoidal or polygonal cross section. This shape of the ground electrode obviously causes both a stabilization of the ignition flame and an increase in the ionization currents induced in the ionization electrode.

Preferably, the ignition burner has an ignition electrode and is connected to a holding plate, via which the individual components of the ignition burner are attached and positioned.

A further preferred embodiment of the present invention has a ground electrode that is symmetrical with respect to the longitudinal axis of the injector. The symmetry of the ground electrode prevents it from deforming when heated on one side, thereby achieving a largely constant ionization current.

A particularly preferred embodiment of the invention has a ground electrode of the ignition burner made of an aluminum-chromium alloy, preferably of the aluminum-chromium alloy 1.4765. The thermal stability of this material ensures the highest temperature resistance and long service life of the ground electrode.

In a further preferred embodiment of the invention, one end of the ionization electrode of the ignition burner is arranged in the extension of the longitudinal axis of the injector above the ground bracket in such a way that the ignition flame is directed to this end of the ionization electrode, which obviously has an advantageous effect on the level of the induced ionization current.

affects.

Further advantages, features and possible applications of the present invention will become clear from the following description of a preferred embodiment and the associated figures. They show:

Figure 1 is a side view of a pilot burner, and

Figure 2 is a schematic plan view of the same pilot burner arrangement from above.

Figure 1 shows a schematic side view of an ignition burner with injector 1, ionization electrode 2, ground electrode 3, ignition electrode 4 and holding plate 5.

It can be seen in Figure 1 that the gas outlet of the injector 1, the apex of the U-shaped ground electrode 3 and the free end of the L-shaped ionization electrode 2 are arranged along the longitudinal axis of the injector 1. The injector 1 consists of a substantially cylindrical tube with a rounded top, on which side plates are arranged, which extend from a base 7 of the substantially cylindrical tube over the top of the injector to the opposite side at the level of the base 7. These plates serve on the one hand to deflect the gas flowing out of the injector outlet and thereby give the ignition flame a special shape and on the other hand to dissipate the heat generated by the ignition flame on the injector. It can also be seen that the ground electrode 3 is bent essentially in a U-shape, the U-bend being curved with a constant bending radius, the cross-section being essentially circular and the distance between the two legs from the apex of the ground electrode up to the height of the base 7 of the injector being constant and then increasing in the direction of the holding plate. The ends of the ground electrode 3 are attached to the holding plate 5. The ionization electrode 2 and the ignition electrode 4 are each covered by insulating sheaths, corresponding to 2' and 4', which are passed through holes in the holding plate 5 and are intended to insulate the ionization electrode 2 and the ignition electrode 4 and shield them from leakage currents. The fastening of the ionization electrode 2 and the ignition electrode 4 with the corresponding insulation sheaths 2' and 4' to the holding plate 5 is carried out via fastening plates 8 and 8', respectively, which are preferably made of plastic or another insulating material, which are connected to the insulation sheaths 2' and 4', respectively, and riveted or screwed to the holding plate 5 via the devices 6 and 6', respectively.

Figure 2 shows a schematic plan view of the pilot burner arrangement shown in Figure 1.

View from above with injector 1, ground electrode 3 and retaining plate 5, whereby the places at which the ionization electrode 2 and the ignition electrode 4 are arranged in Figure 1 are only indicated in this drawing by the circles 2' and 4'. In Figure 2 it is clear that the ground electrode 3 is arranged offset in the circumferential direction to the attached plates of the injector 1 by an angle of approximately 45°.

Claims (13)

Protection claims 1. Ignition burner with injector (1), ionization electrode (2) and ground electrode (3), characterized in that a section of the ground electrode runs through the area swept by the ignition flame between the injector and the ionization electrode. 2. Ignition burner according to claim 1, characterized in that the ignition burner has an ignition electrode (4). 3. Ignition burner according to one of claims 1 or 2, characterized in that the ignition burner is connected to a holding plate (5). 4. Ignition burner according to one of claims 1 to 3, characterized in that the ground electrode (3) has an optionally bent rod. 5. Ignition burner according to one of claims 1 to 4, characterized in that the ground electrode (3) is bent substantially in a U-shape. 6. Ignition burner according to claim 5, characterized in that the U-bend of the ground electrode (3) is substantially curved. 7. Ignition burner according to one of claims 5 or 6, characterized in that the U-bend of the ground electrode (3) has a constant bending radius, preferably with half the injector diameter. 8. Ignition burner according to one of claims 1 to 7, characterized in that the ground electrode (3) of the ignition burner has a substantially cylindrical, optionally ellipsoidal or polygonal cross-section. 9. Ignition burner according to one of claims 1 to 8, characterized in that the ground electrode (3) of the ignition burner consists at least in sections of an aluminum-chromium alloy, preferably of the aluminum-chromium alloy 1.4765. 10. Ignition burner according to one of claims 1 to 9, characterized in that the ground electrode (3) of the ignition burner with respect to the longitudinal axis of the injector (1) is symmetrical. 11. Ignition burner according to one of claims 1 to 10, characterized in that the apex of the ground electrode (3) of the ignition burner is arranged in the extension of the longitudinal axis of the injector (1). 12. Ignition burner according to one of claims 1 to 11, characterized in that areas of the ground electrode (3) of the ignition burner rest against the injector (1) or are connected thereto. 13. Ignition burner according to one of claims 1 to 12, characterized in that the free end of the ionization electrode (2) of the ignition burner is arranged in the extension of the longitudinal axis of the injector (1) above the ground electrode.