DE1102484B - Multiple spark gap arrangement for ignition systems of internal combustion engines - Google Patents

Description

Multiple spark gap arrangement for ignition systems of internal combustion engines For ignition systems of internal combustion engines, in particular for aircraft engines, it is known to cause the ignition of the spark plugs in such a way that from the high voltage source a capacitor is charged, to which a three-electrode spark gap is assigned is that when a certain charging voltage is reached, the three-electrode spark gap is ignited and the charged capacitor via the aforementioned three-electrode spark gap delivers an ignition surge to the spark plug to be ignited (British patent 604339).

It is also known to use a charging capacitor via a pre-spark gap and charge the capacitor, which is in series with a transformer a three-electrode spark gap to discharge, so that the Emtladestrom the capacitor causes the ignition of the spark plug in the secondary circuit of the transformer (British patent 587338).

It is also known to use the spark plug to be ignited as a spark plug Form sliding sparks, such that the electrodes through the sliding path initially are conductively connected to each other, but not when the electrode voltage is high enlarged, an ignitable flashover occurs between the electrodes. Under application a sliding spark gap one has already made an arrangement so that a charging capacitor from the high voltage source over the sliding distance of the spark plug would be charged, but the capacitor would then be charged when a sufficiently high voltage was reached discharged via an additional two-electrode spark gap and this caused the occurrence caused a rollover between the electrodes of the surface spark gap (British Patent 682877).

It is also known to arrange three-electrode spark gaps in an insulating housing filled with a suitable gas (see British patent 679681). In a similar way, a two-electrode spark gap serving to discharge a charging capacitor was arranged in an insulating housing, the insulating wall of which consisted of a cylindrical glass tube which was closed with fused metal covers. The electrodes themselves were disk-shaped and attached to the cover surfaces, and the insulating housing was filled with nitrogen (Swiss patent 256076).

The invention describes a multiple spark gap arrangement which from a three-electrode spark gap and a two-electrode spark gap, which are arranged in series in an insulating housing, and the is characterized in that the three-electrode spark gap designed as a sliding spark gap and the two-electrode spark gap serving as a control spark gap as assemblies are arranged axially to one another and that an electrically conductive spring is provided is what the storage of the two-electrode spark gap and a .good electrical Contact of a power supply member of the same with a power supply member of Three-electrode spark gap guaranteed.

The present assembly of the three-electrode spark gap and the Two-electrode spark gap to a structural unit allows maintenance and To improve monitoring of the ignition device of the internal combustion engine. It can be at the maintenance of the machine consisting of the three-electrode spark gap and the two-electrode spark gap existing unit can be removed and then each of the two spark gaps for can easily be examined. This prevents the monitoring and the exchange more properly working parts facilitated.

The arrangement of the present type also ensures the solid electrical and mechanical connection of the two spark gaps with each other.

An embodiment of the invention is described below and explained and illustrated with reference to the drawings. In the drawings is Fig. 1 is a side view, partially in section, showing one embodiment of the spark gap assembly represents according to the invention; Figure 2 is a schematic view of one form of the electrical circuit in which the device of Figure 1 is used; Figure 3 is a detail of a clamp.

The multiple spark gap shown in the drawing has been used with success in ignition devices for gas turbines and jet engines. However, spark gaps of the present type can also be used, for. B. be used in cylinder machines and oil burners. The embodiment comprises a hollow housing 10 made of insulating material, the interior of which is designed to accommodate a three-electrode spark gap and a two-electrode spark gap; it offers the possibility of easy expansion for the purpose of examination, adjustment, repair and replacement. The housing 10 can be a pressed piece and has an open top end, a partially closed bottom end with opening 11 and an opening 12 in a side wall. The housing 10 is designed in three spaces and consists of a space of small diameter 10a at one end, a somewhat wider central space 10b and a wide outer space 10c at the open end. Correspondingly, the housing body 10 has three wall parts 14, 15, 16 offset from one another - it also has two annular, upwardly directed shoulders 20 and 21.

In order to have an electrical power supply at the lower end of the housing 10 To create, a solder lug with hollow rivet 17 is provided in the bottom of the housing, the or which extends through the opening 11. The outer end of the tubular rivet is crimped over the solder lug 18. A threaded bushing 19 is in the bore 16 of the Housing pressed in or inserted in any other suitable form. The socket 19 has at 22 an internal thread and an internal flange 23 resting on the shoulder 21. A connector 24 is attached to the socket 19.

The two-electrode spark gap 30 is in the lower space 10c consists of two spaced apart, on metal disks 27 and 28 mounted disc electrodes 25 and 26, the discs are on the ends a glass cylinder 29 melted in a known manner, so that they have a hermetic Form a degree. This space is wholly or partially evacuated, and it can a suitable gaseous medium under a certain pressure through a pipe 33 are introduced, which is then closed. The spark gap 30 is constructed in such a way that a breakdown at a given voltage regardless of atmospheric To effect condition of the surrounding space. The sheets 27 and 28 serve as a feed for the electrodes. A coil spring 31 can be under pressure between. the spark gap 30 and the flange of the opening 17 must be inserted to ensure good electrical connection to effect with the three-electrode spark gap 32, but it also serves as an electrical Voltage supply to electrode 26.

The three-electrode spark gap is located in the upper and middle cavity of the housing 10 32 attached, which is electrically connected directly to the spark gap 30. the Spark gap 32 consists of a ring part 53 with an external thread for screwing in into the thread 22 of the socket 19 and with a central, threaded one Opening for receiving the screw spindle 34 of the disk electrode 35. The latter can therefore easily be adjusted in the direction of the spindle axis.

A tube36 made of glass or some other suitable insulating material is cemented onto the lower end face of the ring part 53 or in some other way fastened and protrudes into the housing 10. A cylinder-shaped electrode 37 is at a certain distance from the electrode 35; she wears one Flange 38 attached to the other end of tube 36. In the middle of Electrode 37, an inner electrode is arranged by means of a tubular insulator 39, which consists of an enlarged head part 40 and a pin-shaped part 41. It For example, the lower surface of the disk electrode 35 may be bored to form a recess to create opposite the electrode part 40, or the lower surface of the electrode 35 can, as shown, with a ring 51 made of tungsten or the like material be covered with high resistance to electrical sparks. The top the electrode 37 can also be provided with a ring 52 made of tungsten or other material that will resist wear and tear from electrical sparks. The rings 51 and 52 can be soldered onto the end faces of the electrodes.

The insulator 39 can be made of glass or another suitable insulating material exist. In one embodiment, glass powder is made to a malleable consistency heated and pressed into the recess between the electrodes, 37 and 40, 41. if as the glass cools, it keeps the pieces firmly together. The face of the The head of the inner electrode 40 is preferably in the same plane as the end face 52 of the electrode 37 near the surface 51 of the disk electrode 35, and the outer edge of the head 40 is at a distance from the inner edge of the electrode 37, so that a uniform annular air gap is formed. This annular gap becomes preferably filled by an end piece of the insulator 39 with a smaller wall thickness. The end face 42 of the insulator is also in one plane with the surfaces of electrodes 40 and 37, so that surface 42 forms a bridge between the inner and outer surfaces. Forms outer surfaces of electrodes 40 and 37. If desired, one or both electrodes 37 and 40 a short distance over the end face 42 of the insulator protrude. The surfaces 52 and 51 of the electrodes 37 and 35 therefore form one Spark gap with each other, while the surface 52 of the electrode 37 and the electrode 40 form a spark gap shunt. The electrodes 35 and 40 may need but not also to form a spark gap to one another.

The arrangement consisting of the inner electrode 40, 41 and the insulator 39 may contain an insulating washer 43 which surrounds the pin-shaped part 41, and a metal ring 44 is also located on the lower flange part 138 of the electrode 37 a cylindrical part which surrounds the pin-shaped part 41. The ring 44 serves as an electrical contact and holds the insulating washer 43 in place.

The diameter of the ring 44 is chosen so that the bottom 45 of the ring on the bead of the metal disk 27 rests under the action of the spring 31. The outer edge of the underside of the flange 38 also rests on the washer 46 (Fig. 3), which in turn rests on the shoulder 20 and through an opening 12 leads in the side wall of the housing 10 with a shoulder to the outside. The washer46 can also be attached to flange 38.

The annular gap-bridging end face 42 of the insulator 39 is preferably made semiconducting by being in a known manner with a thin Layer of silver nitrate, graphite or the like. Is coated. All or part of the Insulator 39, which sits between the electrodes 37 and 40, can have high resistance, So -approximately 0.1 to 10 megohms, or a special resistance of this size can bypass the electrodes, provided that the withstand voltage of the Gap 37, 40 is less than the voltage of the power source, but greater than the Flashover voltage of the two-electrode spark gap 30.

A suitable circuit in which the device described can be used is shown schematically in FIG. 2. A large capacity 47 will gradually charged by a rectifier 48 to a voltage sufficient to around the gap between electrodes 25 and 26 of the two-electrode spark gap 30 to flash over, but to ignite between electrodes 35 and 37 as well as between the electrodes 37 and 40 is insufficient; it takes place when the Two-electrode spark gap 30 partially discharges capacitor 47 in the capacitor 49 of relatively small capacitance instead. This discharge proceeds initially through the semiconducting bodies 39, 42. This initial current ionizes the Air between electrodes 37 and 40, which reduces the resistance so much will that the rest of the partial discharge through the space between the latter two Electrodes from capacitor 47 into capacitor 49 runs. The gaseous medium between the electrodes 37 and 35 is ionized by this partial discharge and thereby the resistance is reduced so much that the previously insufficient voltage on the capacitor 47 is now sufficient for flashover at the gap and the rest of the charge on the capacitor 47 can be fed to a spark plug 50 or another consumer. One Ignition gap with floating spark gap is shown at 50, but it can be an ordinary one Ignition gap can be used if the voltage source is sufficient.

Claims (10)

PATENT CLAIMS: 1. Multiple spark gap for ignition systems of internal combustion engines, which consists of a three-electrode spark gap and a two-electrode spark gap, which are arranged in an insulating housing and connected in series, characterized in that the three-electrode spark gap designed as a sliding spark gap (35, 37, 40) and the two-electrode spark gap (25, 26) serving as a control spark gap are arranged as assemblies axially to one another in a housing (10) and that an electrically conductive spring (31) is provided which supports the two-electrode spark gap (25, 26 ) and a good electrical contact between a power supply element (27) and a power supply element (44) of the three-electrode spark gap (35, 37, 40). 2. Spark gap according to claim 1, characterized in that that the housing (10) is designed in three spaces, the housing opening being adjacent Closure space (10d) has a threaded bushing (19) in the then following central space (10 b) the three-electrode spark gap (35, 37, 40) with a disk electrode (35) axially to and at a distance from two essentially cylindrical electrodes, namely the electrode (37) and the inner electrode (40, 41), and in the then following outer space (10c) the two-electrode spark gap (30) with two disc electrodes (25, 26) and the spring (31) are housed. 3. Spark gap according to claim 2, characterized in that the housing (10) with its three spaces (10 a, 10 b, 10 c) and the electrodes are designed to be rotationally symmetrical. 4. spark gap according to claim 1, 2 or 3, characterized in that the Spring (31) between the two-electrode spark gap (25, 26) and one in the free one End face of the outer space (10c) provided terminal (11) is arranged. 5. spark gap according to claim 2, characterized in that the three-electrode spark gap (35, 37, 40) rests on an annular disk (46) serving as a power supply and the cylindrical electrode (37) is conductively connected to the washer (46) and that the washer (46) rests on an inner housing shoulder (20) and with a Approach through an opening (12) in the housing wall (10) leads to the outside. 6. Spark gap according to claim 5, characterized in that an insulating tube (39, 42) is provided between the electrode (37) and the inner electrode (40, 41). 7. Spark gap according to claim 6, characterized in that the disk electrode (35) in one with external thread (22) engaging in the threaded bushing of the housing closure space (10a) End plate (53) is mounted and the end plate (53) by means of an insulating tube (36) is attached to an outwardly directed flange (38) of the electrode (37). B. Spark gap according to Claim 7, characterized in that the disk electrode (35) is arranged adjustable in the end plate (53). 9. Spark gap after Claim 2 or one or more of the following claims, characterized in that that the facing end faces of the disk electrode (35) and the electrode (37) Rings (51, 52) made of spark-resistant material, e.g. B. tungsten. 10. Spark gap according to claim 6, characterized in that the ring part (42) of the insulating tube (39) facing the disk electrode (35) is semiconducting. Considered publications: German Patent Nos. 149 201, 268 563, 397173; Austrian Patent No. 125 757; Swiss patents Nos. 187 506, 256 076, 272 671; French Patent No. 552,966; British Patent Nos. 486 307, 587 338, 604 339, 606 893, 633 886, 636 446, 679 8 6 1, 682 877; U.S. Patent No. 2,449,967.