The present invention relates to a spark plug, which is designed especially for use in a stationary internal combustion engine.
BACKGROUND INFORMATION
Spark plugs in diversified embodiments are discussed in the related art. In stationary internal combustion engines or rather, in internal combustion engines that run at essentially constant speed, spark plugs have to have as long a service life as possible, since a standstill of such internal combustion engines during a change of spark plugs leads to high costs. For this reason, up to now, center electrodes have been used in such internal combustion engines, which have a crown-like shape, using four crosspieces that lie in the axial direction. A ground electrode is situated, in this instance, at the radial outer end of the crosspieces, beyond the length of the crosspieces. In response to such a geometry, however, a very large, locally erosive stress occurs in the ground electrode. Because of that, the ground electrode has to be made of a noble metal, which makes the overall spark plug very costly.
By contrast, the spark plug according to the exemplary embodiments and/or exemplary methods of the present invention, having the features described herein, has the advantage that it may be produced in a simple and cost-effective manner. In particular, no noble metal has to be used for the ground electrode, in this context. This is achieved, according to the exemplary embodiments and/or exemplary methods of the present invention, by the center electrode including an inner area, an outer ring and at least two crosspieces. The crosspieces, in this instance, connect the inner area to the outer ring, so that the center electrode has a plurality of free areas between the inner area and the outer ring. The center electrode is able to be produced particularly simply, for example, by a stamping process or a laser cutting process, in this instance. This significantly reduces the production costs for the entire spark plug, especially since no noble metal is required as the material for the ground electrode. The center electrode may have a symmetrical design, in this context.
The further embodiments described herein show further developments of the present invention.
The inner area of the center electrode may be configured as an inner ring. This requires only a low material requirement for the center electrode. The inner area of the center electrode is alternatively configured as an inner disk. The material requirement for the center electrode is thereby increased only insubstantially, since the inner area has a relatively small outer diameter. The center electrode having an inner disk is, however, fastened more simply, for instance, using laser welding.
Furthermore, the inner area may be configured as an inner ring, and the width of the inner ting is equal to the width of the outer ring. From this, there comes about a particular geometry of the center electrode. Moreover, a width of the crosspiece may be 1.5 times, and further may be twice the width of the inner ring. Thereby, in particular, good heat dissipation may be achieved from the outer ring to the inner area of the ground electrode. The width of the crosspiece may also be 1.5 times, and may be twice the width of the outer ring.
In order to be able to produce the center electrode in a particularly simple and cost-effective manner, the center electrode has a flat, disk-shaped form.
In order to have only slight wear on the center electrode during operation of the spark plug, the outer ring of the center electrode may be made of noble metal. It should be noted at this point that, from a standpoint of production engineering, the entire center electrode may be made of noble metal. It is true that more noble metal is thereby used for the center electrode, but production is significantly more cost-effective.
The center electrode may include exactly three or exactly four or exactly five or exactly six crosspieces. When four crosspieces are used especially, particularly good heat dissipation is able to be achieved from the outer ring in the direction of the inner area, so that the temperature stress of the outer ring is able to be reduced. Using exactly four crosspieces yields an optimum between good heat conduction and a cross sectional area covered by the crosspieces.
In order to achieve a particularly long service life for the spark plug, the thickness of the center electrode may equal to the width of the outer ring. A square cross section of the outer ring is particularly obtained thereby, which is particularly resistant to wear. Furthermore, a square cross section demonstrates a very good ratio between the surface (for heat absorption) and the cross sectional area (for heat dissipation).
Moreover, the ground electrode is configured to be annular, and has a thickness equivalent to the thickness of the center electrode. The ground electrode is situated radially outside the outer ring, in this context.
In order to reduce the ignition voltage requirement of the spark plug, the center electrode may have a non-circular outer circumference, particularly a toothed outer circumference at the outer ring. If the outer circumference is configured to be toothed, the teeth may be provided in such a way that they taper to a point or that the point is cut off, so that the teeth have a frustoconical shape. Alternatively, the outer circumference of the center electrode may also be milled.
The spark plug according to the exemplary embodiments and/or exemplary methods of the present invention may be used in stationary internal combustion engines or in internal combustion engines that are operated at constant speed. In this connection, the spark plugs may have an anterior chamber, in which the ground electrode and the center electrode are situated. The anterior chamber has one or more channels that produce a connection between the anterior chamber and a combustion chamber of the internal combustion engine. The use of an anterior chamber, in connection with a cart-wheel-like center electrode, having a plurality of crosspieces, makes possible a practically infinite number of spark gaps, so that no special alignment of the channels with respect to the electrodes has to be undertaken.
Exemplary embodiments of the present invention are described in detail below, with reference to
With reference to
As may be seen in
Inner ring 30 has a width B1, in this instance, which is equal to the width B2 of outer ring 35. Furthermore, crosspieces 31, 32, 33, 34 each have a width B3, which is twice as big as width B1 and B2 of the inner ring and outer ring, respectively. This ensures in particular a superb thermal conductive property of center electrode 3, so that damage due to temperature may be avoided on outer ring 35. As may be seen in
Reference numeral 8 designates an electrically conductive element, to which center electrode 3 is fastened, for instance, by laser welding. The longitudinal axis of spark, plug 1 is denoted by X-X.
Because of the flat, wagon wheel-like development of center electrode 3, according to the exemplary embodiments and/or exemplary methods of the present invention, it is possible to provide a spark plug which has a particularly long service life. This service life may be additionally prolonged by using a noble metal as the material for outer ring 35. In particular, according to the exemplary embodiments and/or exemplary methods, of the present invention, the use of noble metal may be omitted in ground electrode 2. This makes the spark plug according to the exemplary embodiments and/or exemplary methods of the present invention very cost-effective. It should also be noted that, in particular, the outer circumference of outer ring 35 may be toothed or milled, in order to reduce the ignition voltage requirement.
With reference to
Number | Date | Country | Kind |
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10 2008 042 625.3 | Oct 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/061626 | 9/8/2009 | WO | 00 | 10/12/2011 |