EP0342641B1 - Sparking plug - Google Patents

Abstract

A sparking plug with combined surface and air gaps, there being provided a central electrode (3), an insulator (2) surrounding the central electrode and an earthing electrode (4) which, together with a sparking plug body (1), surrounds the insulator (3). The insulator (2) forms in the end section a discharge chamber (5), through which the central electrode (3) extends axially as far as the end section of the sparking plug body (1). The earthing electrode (4) embraces the insulator (2) around its end with a projection extending into the discharge chamber (5). <IMAGE>

Description

The invention relates to a spark plug with combined sliding and air spark gaps according to the preamble of claim 1.

Such a spark plug is known from DE-C-3 544 176. In this known spark plug, the center electrode extends slightly into the discharge chamber which the insulator forms by extending in the candle-axial direction beyond the center electrode, the insulator, at least in the end region of the center electrode, maintaining a gap to the latter and also the ground electrode , at least in the end region of the insulator, maintains a gap to it.

With such an arrangement, there are extensive spark channels extending over the entire length of the discharge chamber and if the voltage at the spark plug capacity rises quickly enough, a large amount of ignition energy is converted into the gas regardless of the compression pressure of the mixture to be ignited, thereby achieving a practical, long service life.

The known spark plug according to DE-C-3 544 176 is, however, still disadvantageous insofar as there is a high voltage requirement of, for example, 30 kV when starting an internal combustion engine in which such a spark plug is used. Since, in the known spark plug, the sliding spark always runs over the ceramic insulator, which is associated with a corresponding wear of the insulator, the service life of the known spark plug is still not optimal.

The object underlying the invention is therefore to design the spark plug according to the preamble of claim 1 so that it has a relatively low voltage requirement with high energy conversion in the ignitable fuel-air mixture.

Lean mixtures should preferably also be able to be ignited with the spark plug according to the invention, and the pollutant emissions in the exhaust gases of an internal combustion engine should be kept as low as possible due to the candle geometry.

This object is achieved according to the invention by the training specified in the characterizing part of claim 1.

In the spark plug according to the invention, the center electrode is thus preferred so that it ends in the end section of the plug body, so that an air spark gap is formed in the front region of the spark plug, and at the same time the discharge chamber forms a prechamber which allows sliding spark discharges. In the training according to the invention thus taking advantage of a prechamber candle. The spark plug according to the invention also has a long service life.

Specifically, this means that the form of discharge is determined by the load state of the machine, the dynamic pressure conditions of the compression and the mixture vortex determining the form of discharge. In practice, this means that depending on the pressure conditions, either air spark or sliding spark discharges or partial air spark and partial sliding spark discharges occur during operation of the machine. It should be noted that an air spark discharge is formed at a low compression pressure and that at a high compression pressure the spark discharge prevails on the sliding spark gap provided.

In particular, these forms of discharge have the effect that, in the case of an air spark discharge, on the one hand the mixture in the main combustion chamber, i.e. is ignited in the machine cylinder and, on the other hand, the ignitable mixture is ignited in the prechamber. The chemical energy from the antechamber is also transferred to the main combustion chamber by expansion forces. This additional chemical energy causes additional ignition and thus ensures that the mixture burns safely. When the spark plug works as a sliding spark plug, the ignitable mixture is ignited in the prechamber. Since the sliding spark rushes through the entire pre-chamber, any old gas cores have almost no negative effects, so that the ignitable mixture in the pre-chamber is ignited and the ignited pre-chamber mixture is pressed into the main combustion chamber with the resulting overpressure.

The combination of the air spark and sliding spark gaps achieves a long service life overall, since the burn-up areas on the center electrode or ground electrode and the sliding spark gap are very large. With increasing pressure The base of the sparks then moves deeper and deeper into the discharge chamber along the entire free electrode length. The ceramic sliding spark gaps, ie the sliding spark gaps on the ceramic insulator, are protected by the ring-shaped ground electrode, which surrounds the insulator from the outside in around the end of the insulator.

Particularly preferred developments and refinements of the spark plug according to the invention are the subject of claims 2 to 6.

• Fig. 1 eine Axialschnittansicht des Ausführungsbeipiels der erfindungsgemäßen Zündkerze,
• Fig. 2 in einem Diagramm den Zündspannungsbedarf in Abhängigkeit vom Kompressionsdruck bei dem Ausführungsbeispiel der erfindungsgemäßen Zündkerze und
• Fig. 3 in einer Schnittansicht des zündfunkenseitigen Endes des Ausführungsbeispiels der erfindungsgemäßen Zündkerze die Ausbildung der Zündfunken.

A particularly preferred exemplary embodiment of the invention is described in more detail below with reference to the accompanying drawing. Show it

• 1 is an axial sectional view of the exemplary embodiment of the spark plug according to the invention,
• Fig. 2 in a diagram the ignition voltage requirement depending on the compression pressure in the embodiment of the spark plug according to the invention and
• Fig. 3 in a sectional view of the spark end of the embodiment of the spark plug according to the invention, the formation of the ignition spark.

The embodiment of the spark plug according to the invention shown in FIG. 1 essentially comprises a metallic spark plug body 1 with a screw thread, a ceramic insulator 2, a center electrode 3 and an annular ground electrode 4. The insulator 2 is surrounded by the spark plug body 1 together with the ring-shaped ground electrode 4 .

In the front, ie in the area of the insulator 2 on the ignition spark side, a prechamber or discharge chamber 5 is provided in the form of a recess, which is preferably of a V-shaped axial section with a cross section widening towards the end of the insulator. The ground electrode 4 surrounds the insulator 2 at the end of the insulator in a ring from the outside inwards. The ground electrode is located in the discharge chamber extending end of their approach encompassing the insulator to be rounded in order to avoid electrical field distortions, so that the spark does not lift off prematurely from the sliding spark gap in the case of sliding discharges and on the other hand the spark forms as far forward as possible in the direction of the main combustion chamber in the case of air spark discharges, as is more particularly the case will be described later with reference to FIG. 3.

In conventional technology, the center electrode 3 is introduced in the insulator 2 in a pressure-tight manner, for example by melting glass, etc. Known materials such as silver, nickel alloys, platinum composite materials or conductive or semiconducting ceramics can be used as the electrode material of the center electrode 3. Two-substance electrodes can also be provided.

The ground electrode 4 is designed so that it acts simultaneously as a seal between the spark plug body 1 and the insulator 2.

As shown in FIG. 1, the center electrode 3 extends axially through the prechamber or discharge chamber 5 to the end section of the spark plug body 1, on which the ground electrode 4 is provided.

The spark plug shown in Fig. 1 has a calorific value which goes in the direction of very cold candles. This spark plug can be used in connection with an ignition with a very steep voltage rise of, for example, 3 kV per ns in all internal combustion engines, since it is very cold and a shunt does not matter. It is therefore a universal unit spark plug, in which a shunt of less than one kOhm is possible and permissible.

2 shows the characteristic of the ignition voltage requirement in one embodiment of the ignition spark according to the invention. 2 thus shows the dependence of the ignition voltage on the compression pressure.

As shown in FIG. 2, the voltage requirement of the spark plug does not increase proportionally with the compression pressure, but rather the ignition voltage requirement is influenced by the sliding spark discharge when the compression pressure is increased. Since sliding sparks are almost independent of pressure, the ignition voltage requirement does not continue to increase linearly, but rather the ignition voltage requirement remains almost constant. This means that a relatively low voltage requirement of, for example, less than 25 kV is achieved in spite of large spark discharge distances.

Fig. 3 shows in detail the formation of the sparks at the front end portion of the embodiment of the spark plug according to the invention. The spark formation is shown in accordance with the prevailing compression and compression pressures of the machine.

At low pressures, the ignition spark forms in the front area on the air spark gap 6. With increasing pressure, the spark is formed as an air and sliding spark 7, with the discharge being converted into a pure sliding spark discharge 8 at high pressure. The entire area of the center electrode 3, which protrudes into the prechamber 5, is used as the erosion surface. Dadurh is expected to have a very long spark plug life.

If the spark plug is operated with an ignition system with a very steep voltage increase of, for example, 3 kV per ns and a potential energy of ≧ 30 mJ, then multiple spark channels are formed in all load states, since a plasma channel alone cannot carry the large currents.

The design of the blow distance of the air spark formation (electrode spacing) and the design of the sliding spark gap in the isolator must be carried out in accordance with the engine compression. Realistic values for gasoline engines should be at an air spark gap of 2.0 to 2.5 mm and a sliding spark gap of about 5 mm.

This results in the special characteristic of the response voltage shown in FIG. 2 with a regulating effect of the voltage requirement at high pressures, with air and partly sliding spark discharges being possible depending on the pressure, and the spark depending on the pressure starting at different points on the central electrode jacket surface and at optimal burn-up conditions leads. The air and sliding spark gaps are designed so that the spark discharge takes place either on the air spark gap or on the sliding spark gap in accordance with the engine pressure conditions with sliding transition zones. The prechamber or discharge chamber serves as a sliding spark gap and the air spark gap is formed between the center electrode and the ring-shaped ground electrode.

Measurements of the response voltage or the voltage requirement have shown, in particular, that a lower response voltage was found compared to series spark plugs with the same electrode spacing. The arrangement of the electrodes, ie the electrical field distribution, is crucial for the electrodes. Despite an electrode spacing of 2.0 mm, the response voltage during machine operation was max.
25 kV, with a certain control effect being shown at high compression pressures. If the response voltage on the air spark gap is too high, the spark begins to slide, whereby the sliding spark discharges are almost independent of pressure. The ignition voltage requirement of the spark plug can thus be designed to the desired values by means of design measures even at high pressure. It should be noted that the spark discharge is formed at low pressure on the air spark gap and, with increasing pressure, the spark changes into a sliding spark discharge, in the manner shown in FIG. 2 with a smooth transition from spark at low pressure to medium pressure and at high pressure. The shape of the discharge is thus determined by the pressure conditions in the machine, so that a very large area of the central electrode is effective as the burn-up surface and a long service life is therefore to be expected.

The spark plug described is suitable for igniting lean mixtures, leads to a lower pollutant content in the exhaust gas, has a long service life and, with a large electrode spacing of, for example, 2 mm, shows only a relatively low voltage requirement of, for example, 25 kV, and at the same time a lot of energy is converted in the fuel / air mixture .

Claims (6)

1. Sparking plug with combined surface and air sparking gaps, in the case of which a central electrode (3), an insulator (2) surrounding the central electrode, and an earth electrode (4) surrounding the insulator together with a sparking plug body are provided, and the insulator, in its end section, is distanced from the central electrode and forms a discharge chamber (5) into which the central electrode extends, and the earth electrode surrounds the insulator around the end thereof with a projection which extends into the discharge chamber, characterised in that the central electrode (3) extends axially completely through the discharge chamber (5) to the end section of the sparking plug body (1).
2. Sparking plug according to Claim 1, characterised in that the discharge chamber (5) is V-shaped in axial section with a cross-section widening towards the end of the insulator.
3. Sparking plug according to Claim 1, characterised in that the discharge chamber (5) is formed in the end of the insulator and the electrically insulating ceramic material of the insulator (2) forms a surface sparking gap.
4. Sparking plug according to Claim 1 or 2, characterised in that the earth electrode (4) is rounded off at the end of its projection which extends into the discharge chamber (5).
5. Sparking plug according to any one of the preceding claims, characterised in that the central electrode (3) consists of a conductive or semi-conductive ceramic material.
6. Sparking plug according to any one of the preceding claims, characterised in that the central electrode (3) is connected to a pilot electrode in a low-resistance manner.

Images