EP1881573A2 - Ignition device, in particular ignition plug for a combustion engine and method for positioning at least one ground electrode in the ignition device - Google Patents

Abstract

The ignition device (10) has an electrical insulating element, which is arranged centric in a spark plug body (1). A central electrode (2) is arranged centric in the insulating element and protrudes from the foot tip of the insulating element. A measuring electrode pair (4) is arranged in a hight adjusting way at another measuring electrode pair with relative to a tip (21) of the central electrode and each measuring electrode pair forms an equal electrode distance together with the central electrode. An independent claim is also included for a method for positioning of an ground electrode in an ignition device.

Description

The invention is in the field of high voltage ignition. The invention relates to an ignition device for igniting combustible mixtures, in particular a spark plug for generating the spark for a particular gas-fired internal combustion engine according to the preamble of patent claim 1 and a method for positioning at least one ground electrode in the ignition device according to the preamble of claim 12.

Ignition devices are known in which an essentially rotationally symmetrical spark plug body is provided in which an insulating element is centrally arranged. The insulating member includes a center electrode whose tip protrudes from the insulating member. At least one ground electrode is attached to the essentially rotationally symmetrical spark plug body, wherein a noble metal reinforcement at the spark gap, the so-called discharge gap, which forms the electrode gap, increases the service life. At this spark gap, a discharge takes place by applying a high voltage (eg, 30 kV) between the center electrode and the at least one ground electrode. In order to increase the life of the spark plug, noble metal reinforcements become, for example, the center electrode made with platinum and iridium. The precious metals used and the alloys containing at least one precious metal are very expensive together with the noble metal reinforcements, which require a high production cost.

Conventionally, in the case of an ignition device with four earth electrodes, a so-called four-pole spark plug, the ground electrodes are bent toward the center axis of the ignition device in such a way that the four earth electrodes are fastened in the same bending height with respect to the center electrode. After attachment of the ground electrodes, they are punched out. This embodiment is not applicable to igniters having a small micrometer pitch electrode gap, since the conventional igniters do not provide accurate punching of the ground electrodes where the circularity of the stamped ground electrode matches the diameter of the center electrode.

Furthermore, ground electrodes of a four-pole or three-pole spark plug of the order of about 2.7 mm, which is the usual width of the ground electrode, can not be bent so close to the body center axis because of the mutual overlap that there is a small electrode spacing in the micrometer range formed.

According to the DE 195 03 223 A1 is an ignition device, in particular a spark plug, with at least two fixed with respect to the tip of the center electrode in the same bending height ground electrodes known in which take place several types of discharge. Thus, a first discharge is performed, the so-called air spark, at a first wide ignition gap between the end surface of the ground electrode facing the center electrode and the circumferential surface of the center electrode when a high voltage is applied between the center electrode and the at least two ground electrodes. According to the conventional technology, a second discharge takes place at a second wide spark gap, the so-called air sliding spark, between the ground electrode, the insulating member and the center electrode. In order for air slip to be formed, a relatively wide electrode spacing is needed to allow the air sliding spark to slide over the surface of the insulator element. This embodiment of the ignition device is not applicable in particular for gas-fired industrial engines with high compression pressures, as with such igniters a small located in the micrometer range electrode spacing to reduce the voltage requirement increase over time is not displayed and thus a production of arranged close to the center electrode ground electrodes by punching is not feasible.

At present, the life expectancy requirements for internal combustion engine igniters are increasing significantly, in particular for igniters intended for use in gas-fired stationary, large volume and high compression internal combustion engines. Ignition devices for this purpose should have a long duration of at least 1,000 to 2,000 hours. Since such internal combustion engines operate with high compression pressure, special emphasis must be placed on the smallest possible electrode spacing. The currently available ignition devices do not meet the requirement for a long life, resulting in a costly spark plug change.

The invention is based on this prior art based on the object, an ignition device for an internal combustion engine, which has a long service life in a simplified and cost-effective production, and to provide an economically optimized method for positioning at least one ground electrode in the ignition device.

This object is achieved with respect to the ignition device according to the invention with the features of the preamble of claim 1 by its characterizing features and solved in relation to the process to be created with the features of the preamble patent claim 12 by its characterizing features. Further advantageous embodiments and modifications of the invention will become apparent from the dependent claims and the description.

• einen Zündkerzenkörper aus einem elektrisch leitenden Material,
• ein elektrisches Isolierelement, das zentrisch im Zündkerzenkörper angeordnet ist,
• eine Mittelelektrode, die zentrisch im Isolierelement angeordnet ist und von der Fußspitze des Isolierelementes vorsteht und

seitlich zur Mittelelektrode angestellte Masseelektroden, die mit dem Zündkerzenkörper verbunden sind, wobei wenigstens eine der Masseelektroden mit einer zweiten Masseelektrode im Wesentlichen auf der gleichen Biegehöhe angeordnet ist und ein erstes Masseelektrodenpaar bildet, wobei das erste Masseelektrodenpaar zu wenigstens einem weiteren Masseelektrodenpaar in Bezug auf die Spitze der Mittelelektrode höhenversetzt angeordnet ist und jede Masseelektrode zusammen mit der Mittelelektrode einen im Wesentlichen gleichen Elektrodenabstand ausbildet. Die erfindungsgemäße Zündeinrichtung kann beispielsweise in einem gasbetriebenen Industriemotor mit einem hohen Kompressionsdruck Verwendung finden.The solution according to the invention is given by an ignition device for an internal combustion engine comprising:

• a spark plug body of an electrically conductive material,
• an electrical insulating element, which is arranged centrally in the spark plug body,
• a central electrode, which is arranged centrally in the insulating element and protrudes from the toe of the insulating element and

At least one of the ground electrodes is arranged with a second ground electrode substantially at the same bending height and forms a first ground electrode pair, wherein the first ground electrode pair to at least one further ground electrode pair with respect to the tip the center electrode is arranged offset in height and each ground electrode together with the Center electrode forms a substantially equal electrode spacing. The ignition device according to the invention can be used for example in a gas-powered industrial engine with a high compression pressure.

With regard to its design and the positioning of the ground electrodes in the ignition device, the ignition device according to the invention has considerable advantages over the prior art. For example, the inventive arrangement of the ground electrode pairs in a simple manner, depending on the engine operation preferably a Nachjustierbarkeit the electrode distances, which is known in the art as Regaping guaranteed. Thus, the electrode spacings of the ignition device can be readjusted by bending the ground electrodes again and again to small electrode distances lying in the micrometer range. Accordingly, the ignition device can be used several times, which leads to an increase in the life of the ignition device.

A significant advantage of the ignition device according to the invention is that the previously expensive to install noble metal reinforcement of the ground electrodes and / or center electrodes is eliminated and thus a simple production of the ignition device according to the invention is made possible. Despite the saving of precious metals for the ground electrodes and / or center electrodes, a significant increase in the life of the ignition device according to the invention is achieved by the height-offset arrangement of the ground electrode pairs of the ignition device.

Another significant advantage of the ignition device according to the invention is that in the height-offset arrangement of the ground electrode pairs preferably a nearly 360 ° - Abbrandfläche on the lateral surface of the center electrode for Available. In the arrangement according to the invention a mutual contact of the ground electrodes with each other is substantially excluded. With the enlargement of the Abbrandfläche the spark exit surface is simultaneously increased and thus achieved an increased life.

Another advantage of the ignition device according to the invention is that the electrode spacing between each ground electrode and the center electrode is set to be substantially the same. The electrode spacing is preferably in the micrometer range to avoid unwanted misfire. Since the ignition device according to the invention requires a high discharge voltage, the requirement for a stable operation without misfire is fulfilled by means of this small micrometer range.

In an advantageous embodiment of the ignition device according to the invention, the first ground electrode pair is arranged lower in relation to the tip of the center electrode than the second ground electrode pair.

In an advantageous embodiment of the invention, a third ground electrode pair to the first and the second ground electrode pair with respect to the tip of the center electrode arranged offset in height such that the third ground electrode pair is arranged lower than the first ground electrode pair. As a result, an additional increase in the burning surface can be achieved.

In a further advantageous embodiment of the ignition device according to the invention belonging to a pair of ground electrodes on the spark plug body are arranged opposite to each other. This arrangement allows for improved Accessibility for subsequent readjustment of the individual ground electrodes.

In another embodiment of the invention, the center electrode and the ground electrodes are formed substantially of a non-noble metal.

This has the advantage that the price-performance ratio of the ignition device with the inventive arrangement of the ground electrode pairs is cheaper than that of the ignition devices according to the prior art. Nevertheless, the ignition device according to the invention in terms of durability and reliability comparable properties as igniters with a noble metal reinforcement on.

According to a further embodiment of the ignition device according to the invention, the center electrode and the ground electrodes consist essentially of a nickel-based alloy, comprising elements such as Al, Si, Mn, Cr, Y, Hf. The advantage of using nickel-based alloys is the reduced material costs.

According to a further preferred embodiment of the invention, each end face of the ground electrode of the lateral surface of the center electrode opposite and the electrode distance is less than the distance of the ground electrode to the insulating. This has the advantage that a plurality of ground electrode pairs can be arranged offset in height with respect to the tip of the center electrode. The burning surface of the ignition device is thus increased.

In a further embodiment of the invention, the electrode spacing between each ground electrode and the center electrode is substantially equidistant. This leads to a uniform burnup of the ground electrodes and the center electrode. In addition, with each individual ground electrode, a reduced electrode distance between ground electrode and center electrode in the micrometer range is possible, which can lead to a reduction in the voltage requirement increase over the runtime. Furthermore, the spark is formed directly as air sparks. A gliding of the air spark on the toe of the insulating thus does not take place.

In another preferred embodiment of the invention, the electrode spacing is approximately between 200 .mu.m to 600 .mu.m, preferably at 300 .mu.m. The small electrode spacing in the micrometer range is particularly important for ignition devices for use in gas-powered industrial engines with high compression pressures of great importance, since a particularly small electrode spacing leads to a reduction in the discharge voltage requirement.

In a further preferred embodiment of the ignition device according to the invention, the electrode spacing can be readjusted by bending the ground electrodes. The advantage of this refinement makes it possible to readjust to small electrode spacings, preferably 300 .mu.m, during engine operation at regular maintenance intervals. A repeated use of these ignition devices is given.

According to a further advantageous embodiment of the invention, each ground electrode forms an air gap with the center electrode over the electrode gap. The height-offset arrangement of the ground electrode pairs preferably results in at least four air gaps ranging in size between 200 .mu.m and 600 .mu.m, preferably 300 .mu.m. The distance between the air gap between the ground electrode and the center electrode substantially the electrode gap.

• Anbringen eines führenden Endes einer ersten und einer zweiten Masseelektrode auf die Stirnfläche eines Zündkerzenkörpers derart, dass ein erstes Masseelektrodenpaar gebildet wird,
• Anbringen eines führenden Endes einer dritten und einer vierten Masseelektrode auf die Stirnfläche des Zündkerzenkörpers derart, dass ein zweites zu dem ersten Masseelektrodenpaar in Bezug auf die Spitze der Mittelelektrode höhenversetztes Masseelektrodenpaar gebildet wird,
• Biegen der ersten und zweiten Masseelektrode des ersten Masseelektrodenpaars in Richtung der Mittelachse der Zündeinrichtung,
• Ausstanzen der ersten und zweiten Masseelektrode des ersten Masseelektrodenpaars derart, dass zwischen jeder Masseelektrode des ersten Masseelektrodenpaars und der Mittelelektrode ein im Wesentlichen gleicher Elektrodenabstand gebildet wird,
• Biegen der dritten und vierten Masseelektrode des zweiten Masseelektrodenpaars in Richtung der Mittelachse der Zündeinrichtung,
• Ausstanzen der dritten und vierten Masseelektrode des zweiten Masseelektrodenpaars derart, dass zwischen jeder Masseelektrode des zweiten Masseelektrodenpaars und der Mittelelektrode ein im Wesentlichen gleicher Elektrodenabstand gebildet wird.

Another object of the present invention relates to a method for positioning at least one ground electrode in the ignition device comprising the following steps:

• Attaching a leading end of a first and a second ground electrode to the end face of a spark plug body such that a first ground electrode pair is formed,
• Attaching a leading end of a third and a fourth ground electrode to the end face of the spark plug body so as to form a second ground electrode pair offset in height from the first ground electrode pair with respect to the tip of the center electrode,
• Bending the first and second ground electrodes of the first ground electrode pair in the direction of the center axis of the ignition device,
• Punching out the first and second ground electrodes of the first ground electrode pair such that a substantially equal electrode gap is formed between each ground electrode of the first ground electrode pair and the center electrode,
• Bending the third and fourth ground electrodes of the second ground electrode pair in the direction of the center axis of the ignition device,
• Punching out the third and fourth ground electrodes of the second ground electrode pair such that a substantially equal pitch is formed between each ground electrode of the second ground electrode pair and the center electrode.

A significant advantage of the method according to the invention is that predefined electrode distances in the micrometer range can be set cost-effectively and with a minimum of method steps by positioning the ground electrode pairs according to the invention. In addition, the small electrode spacings in conjunction with an increase in burnup area allow for an increase in the life of the igniter without the use of precious metals.

A further advantage of the method according to the invention is that the height-offset attachment of the laterally arranged ground electrodes makes it possible to use a large burnup area, which makes it possible to reduce the rise in the voltage requirement over the runtime.

The object of the invention shows the significant advantage that the electrode spacing can also be readjusted by attaching lateral ground electrodes.

As an alternative to the described method, the sequence of method steps can be changed such that after the ground electrodes of the first and second ground electrode pair are mounted on the end face of the spark plug body, they are bent in the direction of the center axis of the ignition device in a bending step. Subsequently, the ground electrodes of the first and second ground electrode pair are punched out again in a punching process step such that a substantially equal electrode gap is formed between each ground electrode and the center electrode.

As an alternative to this embodiment, the ground electrodes of the ground electrode pairs may be mounted on the end face of the spark plug body without respecting any order.

In a particularly advantageous embodiment of the method according to the invention, a substantially equal electrode spacing is formed between each ground electrode and the center electrode. The electrode spacing is set between 200μm and 600μm, preferably 300μm, to avoid misfire. Since the ignition device according to the invention enables a low discharge voltage, the requirement for stable operation without misfire is met by means of an electrode spacing of between 200 μm and 600 μm.

In an advantageous embodiment of the method according to the invention, a third ground electrode pair to the first and the second ground electrode pair with respect to the tip of the center electrode mounted in such a height offset, that the third ground electrode pair is arranged lower than the first ground electrode pair, which additionally increases the burning surface.

In a further advantageous embodiment of the method according to the invention, the ground electrodes are bent in such a way that the electrode spacing is readjusted.

The advantage of the method according to the invention makes it possible in motor operation, as needed, to readjust to small electrode spacings in the micrometer range, preferably 300 .mu.m, so that low raw emissions are possible until the end of the runtime. Thus, the ignition devices according to the invention can be used several times with the ground electrodes positioned according to the invention.

In another advantageous embodiment of the method according to the invention, the ground electrodes with equidistant Radien punched out with respect to the lateral surface of the center electrode.

An advantage of this embodiment is that a uniform erosion of the ground electrodes and the center electrode takes place.

Fig. 1

Eine schematische Ansicht einer Zündkerzeneinrichtung mit einem ersten und zweiten Masseelektrodenpaar, die gegeneinander höhenversetzt sind

Fig. 2

Eine schematische Darstellung einer Querschnittsansicht eines brennraumseitigen Endes einer Zündeinrichtung

Fig. 3

Eine schematische Darstellung einer Querschnittsansicht eines brennraumseitigen Endes einer Zündeinrichtung

The objects according to the invention will be explained in more detail below on the basis of the exemplary embodiments and FIGS. 1 to 3. Here are from the figures and their description further features and advantages of the invention. Showing:

Fig. 1

A schematic view of a spark plug device with a first and second ground electrode pair, which are offset in height relative to each other

Fig. 2

A schematic representation of a cross-sectional view of a combustion chamber end of an ignition device

Fig. 3

A schematic representation of a cross-sectional view of a combustion chamber end of an ignition device

1 schematically illustrates an exemplary embodiment of the inventive ignition device 10 for an internal combustion engine, which is designed as a spark plug. The ignition device 10 has a cylindrical spark plug body 1 made of metal, in which a ceramic insulating element 3 is arranged centrally. From the insulating member 3, the tip of the center electrode 2 formed of a non-noble metal projects into the combustion chamber (not shown) of the internal combustion engine. The ceramic insulating member 3 includes the center electrode 2 of the igniter 10. The center electrode 2 is disposed axially in the ceramic insulating member 3 and protrudes from the toe of the insulating member 31 before. Centrally center axis 6 of ignition device 10 extends through center electrode 2. A first ground electrode pair 4 is attached to the end surface of cylindrical spark plug body 1 such that the leading end of first and second ground electrodes 41, 42 of first ground electrode pair 4 are welded to the end surface by welding of the cylindrical spark plug body 1 is fixed. 90 ° offset to the first ground electrode pair 4, a second ground electrode pair 5 is fixed on the end face of the spark plug body 1 such that the leading end of the third and fourth ground electrodes 51, 52 of the second ground electrode pair 5 is fixed to the end face of the cylindrical spark plug body 1 by welding , For the ground electrodes 41, 42, 51, 52 made of a non-noble metal, made of a nickel-based alloy, electrode wires having dimensions of the order of 1.7 mm × 2.7 mm are used. After welding, the first and second ground electrodes 41, 42 of the first ground electrode pair 4 are bent toward the central axis 6 of the ignitor 10 such that the ground electrodes 41, 42 of the first ground electrode pair 4 with respect to the tip 21 of the center electrode 2 are the same Bending height are positioned. Thereafter, the first and second ground electrodes 41, 42 of the first ground electrode pair 4 of equidistant radius are punched out by means of a punch having a diameter of 3.4 mm to 3.6 mm, depending on the center electrode diameter and the electrode gap. The ground electrodes 41, 42 of the first ground electrode pair 4 are aligned with each other at the same bending height. In a further method step, the third and the fourth ground electrode 51, 52 of the second ground electrode pair 5 are bent in the direction of the central axis 6 of the ignition device 10 such that the ground electrodes 51, 52 of the second ground electrode pair 5 with respect to the tip 21 of the center electrode 2 are positioned at the same bending height. Thereafter, the third and fourth ground electrodes 51, 52 of the second pair of ground electrodes 5 of equidistant radius are punched out by means of a punch having a diameter of 3.4 mm to 3.6 mm depending on the center electrode diameter and the electrode gap. With respect to the center electrode 2, the ground electrodes 51, 52 of the second ground electrode pair 5 are aligned with each other at the same bending height, with the second ground electrode pair 5 being disposed offset in height from the first ground electrode pair 4 with respect to the tip 21 of the center electrode 2 Ground electrode pair 4 with respect to the tip 21 of the center electrode 2 is arranged deeper than the second ground electrode pair 5. The distance of the ground electrodes 41, 42, 51, 52 to the center electrode 2, the so-called. Electrode gap g1 and thus the air gap, corresponds approximately to the spark gap of the air spark emerging from the center electrode 2 and jumping to the center electrode 2 facing end surface of the ground electrodes 41a, 42a, 51a, 52a. As shown in FIGS. 2 and 3, the electrode gap g1 is thus formed between the end surface of the ground electrodes 41a, 42a, 51a, 52a facing the center electrode 2 and the peripheral surface of the center electrode 2. Each of the four ground electrodes 41, 42, 51, 52 forms the same electrode gap g1 and the same air gap together with the center electrode 2, so that the electrode gap g1 between each ground electrode 41, 42, 51, 52 and the center electrode 2 is equidistant. The electrode gap g1 is 300μm. Depending on the wear, the electrode gap g1 is readjusted by bending the ground electrodes 41, 42, 51, 52 to 300 .mu.m. The electrode gap g1 is smaller than the distance g2 of the ground electrodes 41, 42, 51, 52 to the insulating member 3, so that only one air gap corresponding to the electrode gap g1 is formed.

In a second embodiment, a third (not shown) ground electrode pair to the first and second ground electrode pair 4, 5 with respect to the top 21 of the center electrode 2 arranged offset in height such that the third ground electrode pair deeper with respect to the tip 21 of the center electrode 2 as the first ground electrode pair 4 is arranged. With respect to the tip 21 of the center electrode 2, the second ground electrode pair 5 is disposed higher than the first ground electrode pair 4 and the third ground electrode pair, with the third ground electrode pair being disposed lower than the first ground electrode pair 4. In this case, the ground electrodes of the first, second and third pairs of ground electrode are arranged offset to the end face of the cylindrical spark plug body 1 by approximately 60 °.

On the end face of the cylindrical spark plug body 1, the third ground electrode pair (not shown) is mounted according to the method described in the first embodiment. For the ground electrodes of the third ground electrode pair formed of a non-noble metal made of a nickel-based alloy, electrode wires having dimensions of the order of 1.7 mm × 2.7 mm are used as described in the first embodiment.

The positioning of the ground electrodes of the first, second and third ground electrode pairs is performed by first welding the ground electrodes of the lowest ground electrode pair, the third ground electrode pair, with respect to the tip 21 of the center electrode 2 on the end face of the cylindrical spark plug body 1. Thereafter, the ground electrodes 41, 42 of the middle ground electrode pair, the first ground electrode pair 4, with respect to the tip 21 of the center electrode 2 at the end face of the cylindrical spark plug body 1 welded. Subsequently, the ground electrodes 51, 52 of the uppermost ground electrode pair, the second ground electrode pair 5, are welded to the end face of the cylindrical spark plug body 1 with respect to the tip 21 of the center electrode 2. Subsequently, the ground electrodes of the third ground electrode pair are bent and punched out. In a further method step, the ground electrodes 41, 42 of the first ground electrode pair 4 are bent and punched out. Subsequently, the ground electrodes 51, 52 of the second ground electrode pair 5 are bent and punched out. Each ground electrode forms the same electrode gap g1 together with the center electrode 2.

The invention is not limited only to the examples described, but other ground electrode pairs can be arranged offset in height with respect to the tip of the center electrode.

Furthermore, it is possible to additionally arm the ground electrodes with a noble metal alloy. Furthermore, it is conceivable that the ground electrodes are made of other metallic materials.

An additional possibility is that the ground electrodes of the ground electrode pairs are arranged offset on the end face of the cylindrical spark plug body to another than 90 ° or 60 ° angle.

In addition, electrode wires of other dimensions may be used for the ground electrodes. Furthermore, the punch with which the ground electrodes are punched out may have different diameters.

The invention is generally applicable to igniters.

LIST OF REFERENCE NUMBERS

1 -

spark plug body

2 -

center electrode

21 -

Tip of the center electrode

3

- Insulating element

31 -

Toe of the insulating element

4

- first ground electrode pair

41 -

first ground electrode of the first ground electrode pair

41a -

the center electrode 2 facing end surface of the ground electrode 41st

42 -

second ground electrode of the first ground electrode pair

42a -

the center electrode 2 facing end surface of the ground electrode 42nd

5 -

second ground electrode pair

51 -

third ground electrode from the second ground electrode pair

51a -

the center electrode 2 facing end surface of the ground electrode 51st

52 -

fourth ground electrode of the second ground electrode pair

52a -

the center electrode 2 facing end surface of the ground electrode 52nd

6 -

Center axis of the ignition device

10 -

ignition device

Claims (17)

Ignition device, in particular spark plug for an internal combustion engine, comprising: a spark plug body made of an electrically conductive material, an electrical insulating element, which is arranged centrally in the spark plug body, - A center electrode, which is arranged centrally in the insulating element and protrudes from the toe of the insulating element and - Ground electrodes attached laterally to the center electrode, which are connected to the spark plug body, wherein at least one of the ground electrodes is arranged with a second ground electrode substantially at the same bending height and forms a first ground electrode pair characterized,
in that the first ground electrode pair (4) is arranged offset in height relative to the tip (21) of the center electrode (2) with respect to at least one further ground electrode pair, and each ground electrode together with the center electrode (2) forms a substantially equal electrode gap (g1). Ignition device according to claim 1,
characterized in that the first ground electrode pair (4) is located lower than a second ground electrode pair (5) with respect to the tip (21) of the center electrode (2). Ignition device according to claim 1 and 2,
characterized in that a third ground electrode pair to the first and second ground electrode pairs (4, 5) is offset in height relative to the tip (21) of the center electrode (2) such that the third ground electrode pair is located lower than the first ground electrode pair (4) , Ignition device according to claim 1 to 3,
characterized in that the mass electrodes belonging to a pair are arranged on the spark plug body (1) opposite to each other. Ignition device according to claim 1 to 4,
characterized in that the center electrode (2) and the ground electrodes are formed substantially of a non-noble metal. Ignition device according to claim 5,
characterized in that the center electrode (2) and the ground electrodes are formed substantially of a nickel-based alloy. Ignition device according to claim 1 to 6,
characterized in that each end surface of the ground electrodes faces the peripheral surface of the center electrode (2), and the electrode gap (g1) is smaller is as the distance (g2) of the ground electrode (2) to the insulating element (3). Ignition device according to one of the preceding claims,
characterized in that the electrode gap (g1) between each ground electrode and the center electrode (2) is substantially equidistant. Ignition device according to claim 8,
characterized in that the electrode spacing (g1) is approximately between 200μm to 600μm. Ignition device according to one of the preceding claims,
characterized in that the electrode spacing (g1) is readjustable by bending the ground electrodes. Ignition device according to one of the preceding claims,
characterized in that each ground electrode with the center electrode (2) over the electrode gap (g1) forms an air gap. Method for positioning at least one ground electrode in the ignition device according to one of Claims 1 to 11,
characterized,
that it includes the following steps: Attaching a leading end of a first and a second ground electrode (41, 42) to the end face of a spark plug body (1) such that a first ground electrode pair (4) is formed, - Attaching a leading end of a third and a fourth ground electrode (51, 52) on the end face of the spark plug body (1) such that a second (5) to the first ground electrode pair (4) in With respect to the tip (21) of the center electrode (2) height offset ground electrode pair is formed, Bending the first and second ground electrodes (41, 42) of the first ground electrode pair (4) in the direction of the central axis (6) of the ignition device (10), - Punching the first and second ground electrode (41, 42) of the first ground electrode pair (4) such that between each ground electrode (41, 42) of the first ground electrode pair (4) and the center electrode (2) formed a substantially equal electrode gap (g1) becomes, Bending the third and fourth ground electrodes (51, 52) of the second pair of ground electrodes (5) in the direction of the central axis (6) of the ignition device (10), - Punching the third and fourth ground electrode (51, 52) of the second ground electrode pair (5) such that between each ground electrode (51, 52) of the second ground electrode pair (5) and the center electrode (2) formed a substantially equal electrode gap (g1) becomes. Method according to claim 12,
characterized,
in that a substantially equal electrode gap (g1) is formed between each ground electrode (41, 42, 51, 52) and the center electrode (2). Method according to claims 12 and 13,
characterized,
that a third ground electrode pair to the first and the second ground electrode pair (4, 5) with respect to the tip (21) of the center electrode (2) is mounted vertically offset. Method according to claims 12 to 14,
characterized,
that the ground electrodes are bent in such a way that the electrode spacing (g1) is readjusted. Method according to claims 12 to 15,
characterized,
in that the ground electrodes are punched out with equidistant radii with respect to the lateral surface of the center electrode (2). Internal combustion engine with an ignition device (10) according to one of claims 1 to 11.

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