This application is a National Phase Application related to PCT/EP2011/002620 filed on May 27, 2011, which application claims priority to DE 10 2010 022 564.9 filed on Jun. 2, 2010, which applications are incorporated herein by reference in their entirety.
The disclosure relates to a pre-chamber sparkplug.
A pre-chamber sparkplug comprises, among other things, a central electrode and at least one ground electrode, which is arranged at a distance from the central electrode with the formation of a spark gap. The central and the ground electrode are arranged inside the pre-chamber cap. The compressed gas-air mixture flows into the pre-chamber via one or more transfer bores in the pre-chamber. After ignition, this mixture then spreads the flame front from the pre-chamber through these transfer bores into the main combustion chamber.
For example, a first embodiment DE 101 44 976 A1 shows a pre-chamber sparkplug with an annular ground electrode, which is fastened via fasteners at the pre-chamber cap. In the longitudinal direction of the pre-chamber the ground electrode shows an internal and an external circumferential area. The internal circumferential area faces the central electrode. The external circumferential area is arranged on the side of the ground electrode, which faces away from the central electrode. In a second embodiment several ground electrodes are arranged radially facing the central electrode. In both embodiments the central and the ground electrode are not accessible from the outside. Accordingly, both the volume burned off and the life span of the pre-chamber sparkplug is predetermined here. The volume burned off results from the minimal distance of the ground electrode from the central electrode in the new condition of the pre-chamber sparkplug as well as from the maximum distance and the shape of the ground electrode. Furthermore, the annular ground electrode cannot be adjusted, even if the pre-chamber were accessible. The life span of such a pre-chamber sparkplug typically amounts to approximately 2000 operating hours, so that here potentials are given for optimization.
Accordingly, there exists a need to further increase the life span of a pre-chamber sparkplug.
In the pre-chamber sparkplug according to an exemplary arrangement of the disclosure, the internal circumferential area of the ground electrode has a concave progression, while the external circumferential area has a convex progression. Additionally, the internal circumferential area is subjected to tension and the external circumferential area to pressure. These stress forces are generated such that during the production process the ground electrode is inserted into the fastener and is compressed with the holder on the internal circumferential area as well as the external circumferential area, thus plastically deformed in a targeted fashion. Alternatively, tensile and pressure forces can be generated by welding the ground electrode to the fastener via a fillet weld.
During operation of the pre-chamber sparkplug, the thickness of the ground electrode reduces due to the burn-off. When a critical thickness of the ground electrode is fallen short of, the tensile and pressure forces cause the ground electrodes to return to the original state prior to the plastic deformation. Accordingly, by the tensile and pressure forces, a first compensation effect is yielded, which comprises that at an increased distance of the ground electrode from the central electrode the ground electrode automatically resets and thus the distance from the central electrode is shortened again. The first compensation effect ends when the circumferential areas of the central electrode and the ground electrode facing each other extend parallel in reference to each other. In experiments at the test station it was determined that the first compensation effect occurs after approximately 4000 operating hours.
The improved consistency in the formation of sparks is beneficial, caused by the distance between the electrodes being held constant. This in turn leads to a more constant combustion during the operating life of the pre-chamber sparkplug.
One embodiment of the disclosure provides that the transfer bore and/or the transfer bores is/are arranged such that the compressed gas-air mixture (central jet) flows through the spark gap between the central electrode and the ground electrode. A relatively strong heating of the ground electrode at the internal circumferential area with simultaneously good thermal dissipation to the external circumferential area is achieved via the fasteners in connection with the dimensioning of the ground electrode and the fastener. The temperature difference between the external and the internal circumferential area in turn causes the shape of the ground electrode to change. Now, the internal circumferential area shows a convex progression, while the external circumferential area shows a concave progression. By an appropriate arranging of the transfer bores in connection with the suitable sizing of the ground electrode and the fastener, a second compensation effect is achieved. This comprises that after an extended operating time of the pre-chamber sparkplug, the distance of the central electrode from the ground electrode is not enlarged, in spite of burn-off.
In the disclosure, the simple production method and a considerably extended life span are advantageous. The two compensation effects in turn offer the advantage of a more constant ignition time over the entire life span of the pre-chamber sparkplug.
The figures illustrate the preferred exemplary embodiments. In the figures:
According to
As shown in
In order to extend the life span of the pre-chamber sparkplug 1, the disclosure provides for the transfer bores 9 in the pre-chamber cap 5 being arranged and aligned such that the compressed mixture 17 (central jet) flows through the spark gap 7 between the central electrode 2 and the ground electrode 3. Due to the fact that the compressed mixture shows a temperature of approximately 200° C., the internal circumferential area 10 of the ground electrode 3 is heated. Via the fasteners 8, heat conduction develops from the ground electrode 3 to the housing 6. In
The temperature difference between the internal and the external circumferential area in turn now causes the internal circumferential area 10 of the ground electrode 3 to assume a convex progression, and the external circumferential area 12 a concave progression. This status is shown in
The burn-off continues in the area of the external edges 18 of the ground electrode 3 and leads to a rounding of the edges 18 of the ground electrode 3. During the further operation the burn-off continues in a direction towards the central axis of the ground electrode. Consequently, the internal circumferential area 10 once more forms parallel in reference to the central electrode 2. The starting point is reached once more. This burn-off behavior continues until a critical diameter is reached in the area of the central axis of the ground electrode 3, and the ground electrode 3 collapses and the minimum electrode distance is fallen short of or the ground electrode 3 falls out of the fastening.
Number | Date | Country | Kind |
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10 2010 022 564 | Jun 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2011/002620 | 5/27/2011 | WO | 00 | 11/30/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/151035 | 12/8/2011 | WO | A |
Number | Name | Date | Kind |
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1596240 | Dikeman | Aug 1926 | A |
2047575 | Burtnett | Jul 1936 | A |
20090107438 | Baldwin et al. | Apr 2009 | A1 |
20110148274 | Ernst et al. | Jun 2011 | A1 |
20120299459 | Sakakura et al. | Nov 2012 | A1 |
Number | Date | Country |
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101 44 976 | Apr 2003 | DE |
768447 | Aug 1934 | FR |
Entry |
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PCT International Search Report dated Sep. 12, 2011 for PCT/EP2011/002620. |
Number | Date | Country | |
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20130099653 A1 | Apr 2013 | US |