DE10061672A1 - Spark ignition circuit for motor vehicle internal combustion engine involves limiting power to spark electrode dependent on cylinder conditions - Google Patents

Abstract

The spark ignition circuit for a motor vehicle internal combustion engine has reduction in the thickness of the electrode (5) of a spark plug (7). There can be an insulating layer (11) on the piston crown to increase plasma sparking. A limiting switching circuit (9-11) delimits the high frequency field passing through the electrode discharge process with corresponding discharge energy.

Description

The present invention relates to a device for Energy coupling into a with a certain medium filled space according to the preamble of claim 1. Ins In particular, the present invention relates to a device device for coupling energy into an air Fuel mixture filled combustion chamber of a combustion motors to the air-fuel mixture by means of a plas to ignite the discharge process.

For the ignition of air-fuel mixtures in combustion Power engines are almost used in gasoline engines, for example only ignition systems with conventional spark plugs used. In such ignition systems, the generated by the Spark plug provided ignition energy, which in the combustion chamber of the corresponding internal combustion engine is released, a spark discharge between closely adjacent electrodes of spark plugs, the disadvantage of which is relatively high heat Losses occur on the spark plug electrodes. The transfer ignition energy to the air-fuel mixture follows through direct contact of the ignition spark with the air Fuel mixture, causing formation of flames only in the immediate vicinity of the spark plug electrode Zen takes place. In addition, contact with the re  relatively cold spark plug electrodes a partial out extinguish the flame core. Such as Quench losses Designated losses can be do not avoid conventional ignition systems.

In DE 196 36 712 A1 a possibility for ver Improvement of the ignition behavior proposed, one A plurality of ignition electrodes simultaneously in the corresponding Arrange appropriate combustion chamber and with the ignition voltage are acted upon. This way, at the same time multiple flame cores formed, making an ignition zone larger expansion can be generated, which a si ignition of problematic air-fuel Allow mixtures. A connected with this ignition system However, the problem is the high level of design complexity Provision of suitable spark plugs as well as the required Installation space on the internal combustion engine itself.

Ignition methods for the ignition of air Proposed fuel mixtures for internal combustion engines gene, with the help of plasma discharges thermal Energy in the combustion chamber of the respective internal combustion engine is introduced or coupled in to the air Ignite fuel mixture. With such plasma guns is protruding into the combustion chamber Electrode the air in the combustion chamber Fuel mixture ignited by the fact that the air Sufficient fuel mixture through a radio frequency field brought the energy to a reactive temperature is by the air-fuel mixture through the of the High frequency field coupled into the combustion chamber brought into the electrically conductive plasma state becomes.

Such a generic type and based on plasma discharge or For example, plasma ignition based device known from EP 0 211 133 B1. One is as a spark plug  serving electrode, which in the combustion chamber of a cremation protruding motor, directly with one over a Lei Switched clocked high-frequency generator connected. The radio frequency generated by the radio frequency generator power / high frequency energy is in one of the electrode abge in the combustion chamber of the respective internal combustion engine radiated radio frequency field for plasma ignition of the be air-fuel mixture emitted.

In addition, DE 197 47 701 A1 of the application rin suggested that the radiated from the electrode To regulate the high-frequency field to a high voltage that is on the electrode in the air-fuel mixture at the same time a plurality of high-resistance plasma filaments are shorter Train duration. In contrast to conventional processes for ignition by means of plasmas, in which essentially longer burning, stationary plasmas are caused by this procedure a number of times and in generates intensely forming plasma threads, which are too short lead to early, intense discharges of the plasma and many cores of flame appear in the air-fuel mixture call, resulting in a particularly good ignition behavior of the Air-fuel mixture can be reached. This can especially the geometry of the electrode be chosen that the field strength increases from that of the Electrode emitted high-frequency field which are used to form the short-term plasma threads in the air-fuel mixture.

As can be seen from the above description, Plas Ma discharge or plasma ignition conventionally to the protruding into the combustion chamber of the internal combustion engine Electrode applied a relatively high voltage to equal to execute a plurality of short-term plasma threads in good time form and thus a large volume spread of flam core, through which the air-fuel Mixture is also ignited on a large volume. This Vorge  However, it has a relatively high energy consumption the ignition device or the igniter and a relative excessive wear of the electrodes (electrode erosion) Episode.

The present invention is therefore based on the object de, a device for coupling energy into a a space filled with a particular medium, especially in a burner filled with an air-fuel mixture space of an internal combustion engine to provide, with which the Problems previously described eliminated or mitigated can be and in particular a lower energy consumption needed to ignite the air-fuel mixture becomes.

This object is achieved by a device solved with the features of claim 1. The Unteran sayings define preferred and advantageous Embodiments of the present invention.

The device according to the invention comprises an electrode, around a high-frequency field, which one of the electrodes dissipated radio frequency energy corresponds to a room radiate into which the electrode protrudes, so that through the radiofrequency field radiated into the room Discharge process is caused. It is suitable the present invention preferably for energy coupling in the combustion chamber of an internal combustion engine, for example of a gasoline engine with direct injection to one in the Air-fuel mixture located in the combustion chamber Ignite plasma discharge. Of course it is However, the present invention is also based on whose fields of application are applicable, the following being the However, the invention based on the aforementioned preferred Use case is described.  

In addition, the device Be according to the invention limiting means for limiting the discharge energy or the one required to carry out the discharge process and the energy supplied to the electrode or that of the elec trode current supplied or to limit the through the high-frequency field emitted by the electrode gentle discharge process. This is the case the invention based on the knowledge that large volu Ignition of the air-fuel mixture using high Frequent streamer or sliding discharges one of the elec trode supplied high-frequency energy is sufficient, which le only for a pre-discharge, but not for one Punch leads. The high frequency supplied to the electrode quente current is therefore preferably limited such that low-resistance breakdowns can be avoided.

According to a first embodiment of the present According to the invention, a control is provided for this purpose, which directly leads to the high frequency supplied to the electrode limited energy. The control can in particular be specially equipped in the form of a regulation, which the current value of the electrode Evaluates energy, compares it with a limit value and the Amplification of the energy supplied to the electrodes in this way sets that the specified limit is not is exceeded. This way it becomes a large volume Ignition by current-limited discharges by means of reduction the amplification of the high frequency supplied to the electrode energy achieved.

According to a second embodiment of the present Invention is provided in the combustion chamber or cylinder of the internal combustion engine opposite the electrode such an insulating layer, for example made of ceramic, attach that the discharge process between the Elek trode and the insulating layer expires, so that a direct Rollover in the combustion chamber avoided and also energized  limited sliding discharges can be realized. It can this insulating layer in particular on the surface of a in the combustion chamber movably mounted piston which for Compression of the air-fuel mixture is used hen.

With the help of the present invention, the energy ver need the ignition device to be significantly reduced where with the generation of high-volume and high-frequency Streamer or sliding discharges is guaranteed to a direct ignition of the air / fuel mixture währleisten. By generating high-frequency discharge electrode zones is also avoided. About that is also good electromagnetic compatibility ensured.

The present invention is explained in more detail below preferred embodiments with reference to the attached drawing explained.

Fig. 1 shows an ignition device for igniting an egg in nem combustion chamber of an internal combustion engine located air-fuel mixture according to a first Ausführungsbei game of the present invention,

Fig. 2 shows an ignition device for igniting an air-fuel mixture located in the combustion chamber of an internal combustion engine according to a second embodiment of the present invention, and

Fig. 3 shows a variant of the second embodiment shown in Fig. 2 when used for a gasoline engine with direct injection.

In Fig. 1, the combustion chamber 7 and a cylinder is illustrated Ver brennungsmotors, wherein within the combustion chamber 7, a piston 8 is mounted vertically displaceably to compress a contained in the combustion chamber 7 air-fuel mixture to facilitate the ignition. In the upper region of the combustion chamber 7 , a spark plug 4 is arranged, which has an electrode 5 protruding into the combustion chamber 7 . The electrode 5 of the spark plug 4 is supplied to radio frequency energy so that the supplied high-frequency power corresponding high-frequency field is radiated into the combustion chamber 7 from the electrode 5 to make the air-fuel mixture ignited by means of so-called streamer or sliding discharges to.

For this purpose, a high-frequency generator 1 is provided, which generates a high-frequency output signal with a frequency of preferably several kHz. The output signal generated by the high-frequency generator 1 is amplified by a high-frequency amplifier 2 and fed to the electrode 5 of the spark plug 4 via a transformer 3 . The primary winding of the transformer 3 is connected to the Hochfre frequency amplifier 2 . The secondary winding of the transformer 3 is the one hand candle with the electrode 5 of the ignition 4 on the other hand, connected to a the combustion chamber housing 7 contacting ground electrode terminal 6 of the spark plug 4 and and placed at ground potential.

At the output of the high-frequency amplifier 2 , a current converter 10 is provided, which determines the instantaneous value of the output current generated by the high-frequency amplifier 2 and feeds it to an electronic circuit 9 . The electronic circuit 9 is such staltet out that it compares the actual value supplied thereto from the output current is the high frequency amplifier 2 with a pre-given threshold value and setting depending on the result Ver equal the gain of the Hochfrequenzverstär kers. 2 The limit value is in particular selected such that an output current corresponding to the limit value of the high-frequency amplifier 2 in the combustion chamber 7 is sufficient for a pre-discharge, but not for a breakdown. As soon as the electronic circuit 9 knows that the output current of the high-frequency amplifier 2 exceeds the permitted limit, the gain of the high-frequency amplifier is reduced by appropriate control.

Alternatively, the electronic circuit 9 can also be designed in the form of a controller, which continuously readjusts in dependence on the instantaneous values of the output current is out of the high frequency amplifier 2, the gain of the RF amplifier. 2

The measure described above reduces the energy required for the desired discharge processes, and despite the current-limited discharge processes a large-volume ignition of the air-fuel mixture which is sensitive to the combustion chamber 7 is possible.

Through the use of the transmitter 3 a contactless se and therefore also contamination-proof galvanically decoupled energy coupling from the high-frequency generator 1 into the combustion chamber 7 is possible.

The embodiment shown in Fig. 2, in which the components already shown in Fig. 1 correspond to the components with the same reference numerals, differs from the exemplary embodiment shown in Fig. 1 in that the current-limited discharges not with the help of Electronic circuit be realized, but with the help of an arranged in the combustion chamber 7 of the engine insulating layer or insulating coating, which is to be arranged in particular in the combustion chamber 7 such that the high-frequency field emitted by the radiated from the electrode 5 of the spark plug 4 discharge processes between the electrode 5 and the respective insulating layer occur.

In the embodiment shown in FIG. 2, for example, an insulating layer 11 made of a ceramic material is arranged on the surface of the piston 8 located in the combustion chamber 7 of the internal combustion engine.

In FIG. 2, the discharge region of the insulating layer 11 is also shown in an enlarged view and in plan view. As can be seen from this enlarged view, sliding discharge figures are generated on the insulating layer 11 by the high-frequency field caused by the electrode 5 , which allow a large-volume ignition of the air-fuel mixture located in the combustion chamber 7 of the internal combustion engine, and also by the use of the insulating layer 11 prevents the occurrence of a low-resistance breakdown. In this way, current-limited discharges are realized, with only pre-discharges, but no breakdowns.

In Fig. 3 the application of the previously explained with reference to Fig. 2 he principle in a gasoline engine with direct injection (application of a jet-guided method) Darge represents. As can be seen from FIG. 3, in contrast to FIG. 2, the spark plug 4 is arranged obliquely inclined to the longitudinal axis of the combustion chamber 7 . The surface of the piston 8 or the piston head is slightly curved towards the electrode 5 with a relatively small radius. An insulating layer 11 of the type described above is applied to the surface of the piston 8 at least on the surface section facing the spark plug 4 or its electrode 5 . Furthermore, a nozzle 12 for injecting the air-fuel mixture is seen in the combustion chamber 7 laterally in such a way that the injection jet is directed into the clearance between the electrode 5 and the surface of the piston 8 coated with the insulating layer 11 . Otherwise, with respect to the variant shown in FIG. 3, reference is made to the statements relating to FIG. 2.

Claims (14)

1. Device for coupling energy into a room filled with a specific medium, with an electrode ( 5 ) for emitting a high-frequency energy supplied to one of the electrodes ( 5 ) corresponds to the high-frequency field in the room ( 7 ) to pass through in the room ( 7 ) the discharge process caused by the electrode ( 5 ) emitted high-frequency discharge, characterized in that limiting means ( 9-11 ) are provided for limiting the discharge energy corresponding to the discharge process caused by the high-frequency field emitted by the electrode ( 5 ). 2. Device according to claim 1, characterized in that the limiting means ( 9 , 10 ) are designed in such a way that they bring about the discharge energy by limiting the high-frequency energy supplied to the electrode ( 5 ). 3. Device according to claim 2, characterized in that
that a high-frequency generator ( 1 ) is provided for generating the high-frequency energy, the high-frequency generator generated by the high-frequency generator ( 1 ) being supplied to the electrode ( 5 ) via an amplifier ( 2 ), and
that the limiting means ( 9 ) are designed such that they influence the amplification of the amplifier ( 2 ) in order to limit the discharge energy. 4. The device according to claim 3, characterized in that
that the limiting means comprise measuring means ( 10 ) for measuring the high-frequency energy currently supplied to the electrode ( 5 ) by the amplifier ( 2 ), and
that the limiting means comprise control means ( 9 ) in order to compare the high-frequency energy measured by the measuring means ( 10 ) and the electrode ( 5 ) instantly supplied with a predetermined limit value and to reduce the gain of the amplifier ( 2 ) accordingly if the limit value is exceeded , 5. The device according to claim 4, characterized in that the control means ( 9 ) of the limitation means are designed in the form of a controller. 6. The device according to claim 4 or 5, characterized in that the measuring means ( 10 ) are designed such that they monitor the current output current of the amplifier ( 2 ) for measuring the high-frequency energy supplied to the electrode ( 5 ) at the moment. 7. Device according to one of the preceding claims, characterized in that
that the discharge process caused by the radio frequency field emitted by the electrode ( 5 ) occurs in the space ( 7 ) between the electrode ( 5 ) and a surface ( 8 ) arranged in the space ( 7 ), and
that the limiting means comprise an insulating layer ( 11 ) arranged between the surface ( 8 ) and the electrode ( 5 ) in the space ( 7 ). 8. The device according to claim 7, characterized in that the insulating layer ( 11 ) on the surface ( 8 ) is attached. 9. The device according to claim 7 or 8, characterized in that the insulating layer ( 11 ) is made of a ceramic material. 10. Device according to one of the preceding claims, characterized in that
that the space ( 7 ) is a combustion chamber of an internal combustion engine, and
that the medium is an air-fuel mixture to be ignited by the discharge process caused by the high-frequency field emitted by the electrode ( 5 ). 11. The device according to claim 10 and one of claims 7-9, characterized in that the surface is a surface facing the electrode ( 5 ) of a piston ( 8 ) slidably mounted in the combustion chamber ( 7 ). 12. The device according to claim 11, characterized in that the electrode ( 5 ) facing surface of the piston ( 8 ) to the electrode ( 5 ) is bent out gene. 13. Device according to one of the preceding claims, characterized in that the electric de (5) the high-frequency power is supplied via a transformer (3), so that the electrode (5) by a high-frequency energy generating high-frequency generator (1) is galvanically decoupled. 14. Device according to one of the preceding claims, characterized in that the limiting means ( 9-11 ) are designed such that they limit the discharge energy in such a way that due to the high-frequency field emitted by the electrode ( 5 ) in the room ( 7 ) only a pre-discharge, but no breakdown occurs.