EP0913897A1 - Spark plug for plasma beam ignition device - Google Patents

Abstract

The ignition plug has an insulating layer (10) on a section in the combustion chamber (7), separating an electrically conducting inner electrode (1) from an earth housing electrode (4). A HF high voltage field is applied to the plug to form plasma in the combustion chamber and ignite the air-fuel mixture. The inner electrode has at least one electrically conducting section (9) on its combustion chamber end. An independent claim is also included for use of the ignition plug in lean-burn, layer-charge and diesel engines.

Description

The present invention relates to a spark plug for a plasma jet ignition device according to the preamble of claim 1.

For the ignition of fuel-air mixtures in internal combustion engines Otto engines almost exclusively ignition systems with conventional coil ignitions and Related spark plugs. In such systems, that generated by the ignition coil provided ignition energy, which is released in the combustion chamber of the engine, a Spark discharge between closely adjacent electrodes of the spark plugs, when used as Disadvantage relatively high heat losses occur at the spark plug electrodes. The The ignition energy is transferred to the fuel-air mixture by direct contact of the spark with the fuel-air mixture, causing a formation of Flame cores only take place in the immediate vicinity of the spark gap of the spark plugs. In addition, contact with the relatively cold spark plug electrodes can cause a partial Extinguish the flame core. Such as quench losses Losses cannot be avoided with conventional ignition systems. From A particular disadvantage of the conventional coil ignition systems is that the exposed electrically conductive electrode sections of the spark plugs a high Wear due to erosion as a result of the arcing between them, which causes only short downtimes and short maintenance intervals are to be observed.

Is the ignition energy remaining despite conventional quench losses Ignition systems under normal operating conditions of the engine for a safe ignition of the Air-fuel mixture, so in certain operating areas or Operating modes of the engine mixture compositions occur with such Ignition procedures can no longer be ignited safely. In particular, increasing Requirements for internal combustion engines due to environmental protection, such as reduced Pollutant emissions and better use of the fuel, above all, can be achieve that the engine is operated in the so-called lean area, that is in the area of a Reduction of the proportion of fuel in the air-fuel mixture. Likewise, the engine in stratified operation, i.e. with an inhomogeneous mixture distribution. Such mixtures are generally more difficult to ignite than richer mixtures, since the Velocity of the flame front spreading in the mixture after ignition a lean mixture is less than a rich mixture. It comes with conventional ignition systems for incomplete combustion of the fuel-air mixture or even complete lack of ignition and thus loss of one Work cycle. Thus, the limit of the mixture becoming leaner increases with increasing Leanness determined by a rough engine run due to misfires. To ensure a safe lean mixture even for environmental reasons To achieve ignition of the mixture, the conventional ignition systems must be improved or be replaced.

One way of improving ignition behavior is to use a plurality of Arrange ignition electrodes in the combustion chamber at the same time and with the ignition voltage act upon. Such ignition systems form several flame cores at the same time and reach an ignition zone of greater extension, which is a safe ignition also allow problematic mixture systems. This is particularly disadvantageous high design effort to provide suitable spark plugs as well as the required Installation space on the engine itself.

Ignition methods for the ignition of fuel-air mixtures are also included Internal combustion engines are known in which with the help of plasma discharges thermal energy is introduced into the combustion chamber and the mixture is thereby ignited. In the case of such plasma ignitions, one protrudes into a combustion chamber Electrode ignited the mixture located in the combustion chamber in that the mixture through a high-frequency field of sufficient energy to a reactive temperature is brought in by the gas introduced into the combustion chamber by the electrode High-frequency field enters the electrically conductive plasma state. This is done at known devices such a plasma in the combustion chamber of a narrow Internal combustion engine generated and by varying the energy supplied or Frequency of the high-frequency field applied to the electrode the required Ignition temperature for the mixture in a determinable by the electrode geometry Room volume provided. All known plasma jet ignition devices are included common that the formation of the plasma is spatially limited near the electrode takes place and therefore the spread of the flame front is not fundamentally different than in conventional spark plugs and therefore not fast for all engine operating states enough is done.

DE 40 28 869 A1 describes a spark plug for such a plasma jet ignition system proposed to achieve a sufficiently high energy density of the plasma the plasma discharge only in one in the electrode body of the spark plug ignition chamber arranged in the back is generated, thereby acting on larger ones Area of the mixture and thus an increase in ignition reliability only indirectly Ejection of ionized particles from the ignition chamber into the combustion chamber is possible. The design of the electrode shape can be varied, whereby the shape of the Ignition chamber should be optimized with regard to the ignition behavior. Can also be on the electrodes are provided with a heat-resistant electrical insulating layer which but is only used to protect against sparking. Disadvantage of this The proposed solution is above all that the fuel-air mixture to be ignited can only be ignited by the plasma in a small partial volume and moreover due to the thermal load and pressure load due to expanding gases the electrodes of the ignition chamber are subject to high wear.

It is therefore an object of the following invention to provide a spark plug for a plasma jet ignition device propose an internal combustion engine with which to wear the spark plug while improving the ignition suitability for the fuel-air mixture can be reduced.

The solution of the task according to the invention results from the characterizing Features of claim 1 in cooperation with the features of the preamble. The Subclaims each describe preferred developments of the invention Spark plug.

The spark plug according to the invention as claimed in claim 1 is used in particular a method for operating a plasma jet ignition device in Internal combustion engines, as in a parallel application by the same applicant is described, which is also fully the subject of this application becomes.

This plasma jet ignition device has at least one area inside a Combustion chamber of an internal combustion engine arranged spark plug with at least an electrode. This electrode is electrical with a high frequency generator connected, being in a fuel-air mixture in the combustion chamber by one of a high-frequency field provided to the high-frequency generator is generated. Here, the high-frequency field is regulated to a high voltage so that the Electrode in the fuel-air mixture simultaneously a plurality of high-resistance Form plasma threads of short duration. In contrast to the known methods for Ignition by means of plasmas, essentially through longer-burning, stationary plasmas are generated by the high frequency and high voltage Plasma discharges are a number of short-term and intense plasma threads formed, which lead to short-term, intense discharges of the plasma and many Flame cores in the fuel-air mixture cause, which makes a special good ignition behavior of the fuel-air mixture can be achieved. It will High-frequency field operated such that the fuel-air mixture in the Combustion chamber-formed plasma is not thermally in equilibrium. It is due the high frequency achieved that short-term, local high-resistance plasma discharges in Form the form of plasma threads, the intense flame cores for igniting the fuel-air mixture cause. These plasma threads only work for a short time, but they do due to their number in the area adjacent to the electrode at high Potential differences are particularly intense. Here, the plasma threads from the Spread the electrode in tufts in a divergent manner into the fuel-air mixture. This calls a large-volume spread of flame nuclei through which the fuel-air mixture is also ignited in large volume. This also means that at least an electrode more distant volumes of the fuel-air mixture in the combustion chamber ignited safely, which on the one hand results in incomplete combustion of the fuel-air mixture avoided and at the same time the reliability of ignition even with inhomogeneous mixtures is increased.

A generic spark plug according to claim 1, preferably for use with a Such plasma jet ignition device is characterized in that the inner electrode its combustion chamber end an electrically conductive, the field lines of Has high-frequency field bundling section, which is opposite to the combustion chamber an insulator layer is covered. The design of the electrode end by a the electrically conductive section that bundles the field lines of the high-frequency field calls the high-resistance plasma discharges, which reliably ignite fuel-air mixtures even further away from the electrode end within the combustion chamber favored. Here, however, this is subject to the field lines of the high-frequency field Section and in particular its fuel-air mixture tapered end normally a high load due to the high impedance Plasma discharges and combustion. There are no arc discharges as with conventional spark plugs, but an unprotected such section wears out through electro-erosion also through the plasma discharges and the corrosion of the combustion quite fast. This section is therefore opposite the combustion chamber by a Insulator layer covered, the direct exposure to the plasma or Combustion of the fuel-air mixture on the electrically conductive parts of the Field lines of the high-frequency field bundling section prevented. This will make the The load on these areas is significantly reduced and the life of the spark plug is reduced overall significantly increased.

In a preferred development, it has the field lines of the high-frequency field bundling section of the inner electrode the shape of at least one to the Bennraum tapered tip area. In this top area are formed by the connected field line density from high local field strengths, which the electrical discharge enable and initiate the formation of flame nuclei. In addition, such leads advantageous taper not to disturb the field lines or the high-frequency field due to arcing, for example, due to interference radiation negatively on electronic Devices in the vicinity of the internal combustion engine could act.

In another embodiment, the one that bundles the field lines of the high-frequency field Section of the inner electrode several, tapering to the combustion chamber, diverging have tip regions arranged to each other. This is due to the Radio frequency field is not just a single starting point for the emergence of a provided high-resistance plasma, but according to the number of such peaks can form a larger volume area with high-resistance plasma, which leads to a large-volume and thus improved ignition and combustion of the fuel-air mixture contributes.

It is particularly advantageous if at least the insulator layer in the area of the Field lines of the high-frequency field bundling section of the inner electrode from one material resistant to erosion and electrical erosion. This will make the Covering the section very resistant to stresses arising from operation the internal combustion engine and the formation of the plasma and the combustion in the combustion chamber. Typical insulator materials can be used as the insulator material Find use that is used in spark plug construction or in electrical insulation construction become.

It is particularly advantageous if the covering insulator layer consists of a thin layer exists, which is easily enforceable by the field lines. This will create the Plasmas not hindered by the field lines of the radio frequency field, so that by the Covering this section does not affect the ignition properties of the Spark plug is caused. In a further development, the isolator and the covering can Insulator layer made of an aluminum oxide, in another embodiment made of quartz glass (fused silica) exist.

By choosing the appropriate materials for the cover and other described The spark plug can be designed as a lifetime Internal combustion engine functional spark plug to be designed, whereby especially cost-intensive change and maintenance processes during the service life the internal combustion engine can be avoided.

It is particularly advantageous if the spark plug according to claim 1 in lean-burn engines, Stratified charge engines or diesel engines are used, as this causes the mixture to ignite these ignition-problematic engines can be significantly improved.

Further advantageous refinements of the spark plug according to the invention are provided by the others Subclaims.

A particularly advantageous embodiment of the spark plug according to the invention is shown in FIG Drawing.

Figur 1

einen Schnitt durch den Brennraum einer Verbrennungskraftmaschine mit darin angeordneter erfindungsgemäßer Zündkerze

It shows:

Figure 1

a section through the combustion chamber of an internal combustion engine with a spark plug according to the invention arranged therein

In the single Figure 1 is a schematic representation of an inventive Spark plug shown in a partial view in section.

The spark plug is only shown with its section facing the combustion chamber 7 since it otherwise the known spark plugs can correspond essentially and only that Design of the combustion chamber side section is important in the context of this invention. The spark plug consists of one arranged here along the screw axis Inner conductor 1, which consists of an electrically conductive material and on the connection side the spark plug with a connection to an ignition cable or the like. in electrical connection stands. The inner conductor 1 is surrounded by an insulator 2 made of a preferably ceramic material in the form of a thick-walled, essentially tubular component, in the Inner bore of the inner conductor 1 is used. On the outside of the insulator 2 is in one Section shows a ground-leading housing electrode 4, which is on its outside carries a thread 11 with which the spark plug in a manner not known in principle illustrated threaded hole z. B. an internal combustion engine and can be set. The ground-leading housing electrode 4 and the inner electrode 1 form a pair of electrodes, as is also known in conventional spark plugs. By the thick-walled insulator 2, the two electrodes 1, 4 are separated from each other, so that maintain the electrical potential difference between the two electrodes 1, 4 remains. On the outside, the insulator 2 also has a profile 5 as protection against Leakage currents, which is also provided on conventional spark plugs.

The design of the spark plug according to the invention can be seen in the section here furthest into the combustion chamber 7 of the internal combustion engine. The inner electrode 1 here forms an arrangement of z. B. three diverging and pointing in different directions of the combustion chamber 7 tips 3 that each from the node at which they are connected to the inner electrode 1 stand, taper towards the combustion chamber 7. As a result, the inner electrode 1 three at the same electrical potential 3 peaks, at which this is in the Can generate fuel-air mixture plasma 6.

The formation of the tips 3 of the internal electrode 1 on the combustion chamber side will continue achieved that at each of the tips 3 there is a strong increase in the field at the Internal electrode 1 in operation applied high-frequency field that the effect of High-frequency field on the fuel-air mixture. This will form on the Spark plug, if this is operated on the plasma jet ignition device on which the Field lines of the high-frequency field bundling section 9 tuft discharges plasmas 6 which are not in thermal equilibrium and which are formed by corona and / or Streamer discharges at the section bundling the field lines of the high-frequency field 9 are caused. These tuft discharges penetrate the plasma 6 in the Fuel-air mixture also in volumes and further away from the inner electrode 1 thus form large-volume flame cores, which also form the fuel-air mixture ignite on a large scale.

Of particular advantage of the embodiment shown in Figure 1 Spark plug according to the invention is that the electrode tips 3 of a thin layer 10 are coated from an insulator material, which the electrode tips 3 of the in Combustion chamber 7 located plasma 6 and the fuel-air mixture separates. Hereby increases the life of the inner electrode 1 and thus the entire spark plug clearly so that the spark plug even during the entire life of the Internal combustion engine can remain functional. The layer thickness of the the electrode tips 3 covering insulator 10 are chosen so that the formation of the Plasma 6 is not due to the high-frequency field that passes through the insulator layer 10 is hindered. If an insulator layer 10 is selected which is also particularly resistant to Electro-erosion and erosion occurs, the inner electrode 1 will also operate after a long period of operation unchanged covered with the insulator 10 and thus protected against wear. Also is through the covering insulator layer 10 on which the field lines of the radio frequency field bundling section 9 prevents arcing in the thermally not in Form equilibrium plasma 6.

The insulator layer 10 covering the electrode tips 3 can, for example, consist of one Alumina or quartz glass exist.

REFERENCE SIGN LIST

1

Inner electrode

2nd

insulator

3rd

Electrode tips

4th

earth-leading housing electrode

5

Leakage current protection

6

tufted discharges

7

Combustion chamber

8th

Section on the combustion chamber side

9

Field line bundling section

10th

covering insulator layer

11

thread

Claims (12)

Spark plug for a plasma jet ignition device, which has at least partially an insulator layer (2) on its section (8) arranged in a combustion chamber (7) of an internal combustion engine, which isolates an electrically conductive inner electrode (1) from a ground-conducting housing electrode (4), whereby a high-frequency field of high voltage can be applied to the spark plug, which forms a plasma (6) in the combustion chamber (9) and ignites a fuel-air mixture located in the combustion chamber (7),
characterized in that the inner electrode (1) has at least one electrically conductive section (9) bundling the field lines of the high-frequency field at its combustion chamber end, which section is covered by an insulator layer (10) opposite the combustion chamber (7). Spark plug according to Claim 1, characterized in that the section (9) of the inner electrode (1) which bundles the field lines of the high-frequency field has the shape of at least one tip region (3) which tapers towards the combustion chamber (7). Spark plug according to one of Claims 1 or 2, characterized in that the section (9) of the inner electrode (1) which bundles the field lines of the high-frequency field has a plurality of diverging tip regions (3) which taper towards the combustion chamber (7). Spark plug according to one of the preceding claims, characterized in that at least the covering insulator layer (10) in the region of the section (9) of the inner electrode (1) which bundles the field lines of the high-frequency field consists of a material which is resistant to erosion and erosion. Spark plug according to Claim 4, characterized in that the covering insulator layer (10), at least in the region of the section (9) bundling the field lines of the high-frequency field, consists of a thin layer which can be easily penetrated by the field lines. Spark plug according to one of Claims 4 or 5, characterized in that the covering insulator layer (10) consists of an aluminum oxide at least in the region of the section (9) which bundles the field lines of the high-frequency field. Spark plug according to one of Claims 4 or 5, characterized in that the covering insulator layer (10) consists of quartz glass (fused silica) at least in the region of the section (9) which bundles the field lines of the high-frequency field. Spark plug according to one of the preceding claims, characterized in that the spark plug is designed as a spark plug which is functional over the entire service life of the internal combustion engine. Spark plug according to one of the preceding claims, characterized in that the spark plug in the plasma jet ignition device forms tuft discharges of a plasma (6) which is not thermally in equilibrium at the section (9) which bundles the field lines of the high-frequency field. Method according to one of the preceding claims, characterized in that the plasma (6) is formed from corona and / or streamer discharges at the section (9) which bundles the field lines of the high-frequency field. Spark plug according to one of the preceding claims, characterized in that the covering insulator layer (10) on the section (9) bundling the field lines of the high-frequency field prevents arc discharges in the thermally unbalanced plasma (6). Use of the spark plug according to claim 1 in lean burn engines, stratified charge engines or diesel engines.

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