DE4009305A1 - Electronic ignition controller serving two plugs per cylinder - Google Patents

Abstract

In a four-cylinder engine the eight sparking plugs (ZK1-ZK8) are energised in pairs from four ignition coils (ZS1-ZA4) switched by power transistors (18-21) under the control of a microprocessor (22). A control circuit (24) connected to an engine revolution counter (23) through a threshold stage (25) operates the transistor switches (18-21) at practically the same frequency in a simple ignition mode, whereby in each cylinder (e.g. 14) the two plugs (ZK1, ZK2) are fired alternately before two successive power strokes.

Description

State of the art

The invention relates to an electronic ignition control device for internal combustion engines, each combustion chamber two Has spark plugs, according to the preamble of claim 1.

While most ignition control devices for internal combustion engines, especially for gasoline engines, any combustion chamber the internal combustion engine is assigned a spark plug and this combustion chamber is therefore ignited in single-ignition mode dual ignition systems are also used in high-performance engines used, in each combustion chamber two spark plugs are assigned, which are ignited together. With these Double ignition systems cause double ignition sparks a larger one at low speeds or low load Ignition safety and a better ignition of the mixture, especially when the engine is warming up there is a very lean mixture. On the other hand, it is not necessary at high speeds or high load, to maintain dual ignition operation since there at rich mixture the ignition by means of a single spark generally sufficient. The shutdown of a spark plug in the high speed range or at high load has the advantage that the noise level will decrease and that at least one spark plug is spared. However when changing spark plugs in the workshop in general Always replace all spark plugs at the same time, regardless whether some of these spark plugs are still in good condition State so that the shutdown of a spark plug brings no advantages in terms of the effective lifespan.  

Advantages of the invention

The ignition control device according to the invention with the characteristic Features of the main claim has the advantage that the wear of the spark plugs in single-ignition operation takes place evenly, so that the ignition of the ignition electrodes half of conventional ignition systems reduced. The spark plugs reach one in this way higher mileage and need to be changed less frequently. Compared to the double ignition mode, one becomes clear Noise reduction achieved, especially at high speeds, in which case on the double ignition can be dispensed with.

By the measures listed in the subclaims are advantageous developments and improvements to ignition control device specified in the main claim possible.

In the simplest case, it is in all operating states Single ignition operation before. The extension thus achieved the mileage compared to conventional single ignition operation with a spark plug or opposite Dual ignition operation with two spark plugs allows longer Maintenance intervals.

However, it is also a switchover between the dual ignition mode and the single ignition operation depending specified parameters possible. For example in critical operating conditions in double ignition mode be driven, e.g. B. at low speeds and / or with a lean mixture during warm-up and / or during the starting process and / or for diagnostic purposes, while the rest is switched to the single ignition mode. There with the spark plugs are evenly loaded, increases the lifespan is also considerable here, in particular then when the dual ignition operation only in very limited  and relatively short operating states is switched on.

It is also possible to have good emergency running properties in the event of failure a spark plug or a corresponding ignition system to achieve a complete failure Switching to the other spark plug takes place. In this The trap increases its wear, but it is Driving comfort otherwise not affected. Also will protection of the sensitive catalyst is achieved, which must be protected against unburned mixture.

In the simplest case, each is in single-ignition mode an alternating firing order for the two spark plugs each Combustion chamber set, but there are other consequences possible, with an essentially identical ignition frequency overall must be present in both spark plugs.

To achieve a static high voltage distribution without rotating high-voltage distributors are more advantageous Two combustion chambers each have two double spark coils assigned, each of these double spark coils with a spark plug from one and a spark plug from the other Combustion chamber is connected, and being each during the ignition in one combustion chamber the other combustion chamber is in the exhaust stroke or in the overlap. These two double spark coils are easily in double ignition mode together and in single ignition mode individually controllable.

This ignition control device is suitable for two, four, Six-cylinder internal combustion engines, the number of Cylinder can be varied even more, but even numbered should be. The number of double spark coils corresponds then the number of combustion chambers.

In four or more cylinder engines there are at least two Groups of two double spark coils are provided, whereby  each group is assigned to two combustion chambers. The switching device switches one after the other in single ignition mode first double spark coil of the first group, the first double spark coil the second group, the second double spark coil of the first group and the second double spark coil of the second Group, taking in the corresponding subsequent cycles the order of the first double spark coils and second double spark coils changes. This will make it easy Alternate actuation of the two spark plugs achieved in every combustion chamber.

However, it is also possible that each spark plug has a single spark coil is assigned to a static high voltage distribution to achieve. This doubles the number the ignition coils and the number of power amplifiers controlling them, however, the danger of ignition triggers in the exhaust stroke prevented. In addition, there are also designs for Internal combustion engines with an odd number of cylinders possible.

The ignition control device is advantageously together with the switching device is designed as a microcomputer, wherein Power stages between the microcomputer and the individual or double spark coils are provided. The simultaneous (in Dual ignition mode) and the successive (in Single ignition operation) Actuation of the two spark plugs in the individual combustion chambers can be computer-controlled in a simple manner depending on one contained in the microcomputer Program. Switching between simple and dual ignition operation in a simple manner by this Microcomputer can be controlled.

To switch between the two operating modes is a Function switch or encoder connected to the microcomputer, depending on the shortfall or shortfall of a Predeterminable threshold value and / or the switching state of the  Function switch the switchover takes place. In doing so the two operating modes advantageously different Ignition and / or lambda maps assigned.

drawing

An embodiment of the invention is in the drawing shown and in the description below explained. The only figure shows a block diagram of the electrical part of the ignition control device and a schematic representation of four combustion chambers of a four Cylinder internal combustion engine.

Description of the embodiment

In the embodiment shown in the single figure, four cylinders Z 1 to Z 4 of a four-cylinder internal combustion engine are shown schematically. Four pistons 10 - 13 movable therein are also shown schematically. Between the cylinders Z 1 to Z 4 and the pistons 10 - 13 there are corresponding combustion chambers 14 - 17 , into which an ignitable mixture is introduced via inlet valves (not shown) and the burned mixture is discharged via outlet valves (not shown).

Two spark plugs ZK are screwed into each cylinder Z 1 to Z 4 , the spark plugs ZK 1 and ZK 2 in the combustion chamber 14 , the spark plugs ZK 3 and ZK 4 in the combustion chamber 15 , the spark plugs ZK 5 and ZK 6 in the combustion chamber 16 and the spark plugs ZK 7 and ZK 8 protrude into the combustion chamber 17 . These spark plugs ZK 1 to ZK 8 are electrically connected to the secondary outputs of four double spark coils ZS 1 to ZS 4 . The double spark coils are referred to below as ignition coils. The output of the ignition coil ZS 1 is connected to the spark plugs ZK 2 and ZK 8 , the output of the ignition coil ZS 2 to the spark plugs ZK 1 and ZK 7 , the output of the ignition coil ZS 3 to the spark plugs ZK 4 and ZK 6 and the output of the Ignition coil ZS 4 with spark plugs ZK 3 and ZK 5 . The switching on and off of the ignition coils 1 to ZS ZS 4 via power amplifiers 18-21 which in turn are controlled by a microcomputer 22nd Such a microcomputer for controlling the ignition functions as a function of ignition and / or lambda maps is common in modern motor vehicles and is described in detail, for example, in the automotive paperback from Robert Bosch GmbH, 19th edition, p. 405 ff. To detect the speed, a speed sensor 23 is connected to a speed input of the microcomputer 22 . Other sensors, such as pressure sensors, temperature sensors, voltage sensors and switch sensors, which are usually required for such a map control, have been omitted to simplify the illustration.

A switching device 24 in the microcomputer 22 controls the individual power output stages 18-21 or the spark plugs ZK 1 to ZK 8 according to a scheme to be explained in more detail below. This switching device 24 is only indicated schematically by a dashed line, the speed sensor 23 acting on the switching device 24 via a threshold value stage 25, also indicated schematically. Of course, such a threshold level 25 and a switching device 24 are usually implemented in a microcomputer by program functions, but in principle a hardware implementation, for. B. possible as an external circuit.

The operation of the ignition control device shown in the single figure consists essentially in that, below a definable load and / or speed value, a switchover to double ignition operation takes place, in which both spark plugs of a cylinder ignite simultaneously. This load value or speed value is determined by the threshold value stage 25 or a corresponding computer function. Above this definable value, there is again a switch back to single-ignition operation, in which only one spark plug of a cylinder fires at a time. Simultaneously with the switchover between the two operating modes, there is also a switchover between different ignition or lambda maps, which are stored in the microcomputer 22 . These maps are customarily adapted to the two operating modes.

Below the predetermined load or speed value, the driving of the output stages 18 is effected - 21 and ignition coils ZS ZS 1 to 4 in dual ignition operation. In the four-cylinder internal combustion engine shown, an ignition sequence 1-3-4-2 is required, that is, the correspondingly designated cylinders must be fired in this order. For this purpose, the ignition coils ZS 1 and ZS 2 are first controlled so that both spark plugs ZK 1 and ZK 2 of the cylinder Z 1 ignite the ignitable mixture in the combustion chamber 14 . The ignition sparks generated simultaneously on the spark plugs ZK 7 and ZK 8 meet there with a burned mixture in the exhaust stroke, so that they have no effect. The next ignition process takes place by simultaneous activation of the ignition coils ZS 3 and ZS 4 , whereby the ignitable mixture in the combustion chamber 16 of the cylinder Z 3 is ignited by both spark plugs ZK 5 and ZK 6 , while the ignition sparks on the spark plugs ZK 3 and ZK 4 from the reasons explained remain ineffective. Then the ignition coils ZS 1 and ZS 2 are actuated again, whereby the ignitable mixture is now ignited in the combustion chamber 17 of the cylinder Z 4 , while the ignition sparks of the spark plugs ZK 1 and ZK 2 remain ineffective. Finally, the ignition coils ZS 3 and ZS 4 are actuated together again, as a result of which ignition sparks are generated at the spark plugs ZK 3 and ZK 4 for igniting the ignitable mixture in the combustion chamber 15 of the cylinder Z 2 . Now the process is repeated in the order described. The driving pattern for the ignition coils ZS ZS 1 to 4 or for the power output stages 18-21 thus repeated with each revolution. The following table shows this ignition pattern:

In the single ignition mode, a switchover to the following takes place Control pattern:

Here, the ignition coil ZS 2 is first activated, whereby the spark plug ZK 1 ignites the mixture in the cylinder Z 1 , then the ignition coil ZS 4 is activated to ignite the ignitable mixture in the cylinder Z 3 , etc. according to the table above. Here the pattern repeats every 4 revolutions of the crankshaft of the internal combustion engine. From this table it can be seen that first one spark plug of the four cylinders is fired during the first four ignition cycles and then the other spark plugs of the four cylinders are ignited in the following four cycles. Ignition here is to be understood to mean the generation of an ignition spark in an ignitable mixture, but not the generation of the other ignition spark on the other spark plug, which is in the exhaust cycle of the other cylinder. The spark plugs ZK 1 to ZK 8 are thereby ignited above the predeterminable load or speed value with the same frequency in each case by an alternating firing sequence, so that a uniform candle burn-off also takes place in the single ignition range.

The invention is of course not based on four-cylinder Internal combustion engines limited, but is also for internal combustion engines applicable with a different number of cylinders. In any case, with a contactless ignition distribution the number of ignition coils corresponds to the number of cylinders. Two double spark coils are two cylinders assigned that behave complementarily, that is, with those at the time of ignition spark generation Cylinder in the work cycle and the other cylinder in the exhaust cycle located. These two ignition coils form a group where the number of groups depends on the number of cylinders. An ignition coil is activated in each case the individual groups and then the other ignition coil of the individual groups one after the other. After that returns the order of the ignition coils.

While using double spark coils only on straight Number of cylinders is possible, can also be odd or even Cylinder numbers are ignited using single spark coils. Each spark plug is assigned a single spark coil, that is, two individual spark coils for each combustion chamber. Ignition trips do not occur here in the exhaust stroke. The spark plugs wear out less.

It is of course also possible instead of known ones Double spark coils also three spark coils, four spark coils or the like. to use what of course only is possible within the framework to ensure that the jointly generated spark only in one cylinder encounter an ignitable mixture.

Switching between single ignition mode and double ignition mode  is not only dependent on a definable one Load and / or speed value possible. This switchover can also take place depending on other parameters, whereby the important point is that in terms of Ignition critical operating conditions a dual ignition operation is present while in uncritical operating states is operated in single ignition mode. For example can switch depending on a diagnostic or Start switch take place, then only in the case of diagnosis (if desired) and / or during the start is switched to double ignition mode. Farther can also be switched by a temperature sensor be controlled by the fact that below a predetermined Temperature, i.e. in the warm-up phase, in double ignition mode and then driven in single ignition mode. Switching depending on other parameters or switches is alternatively or cumulatively possible.

A further embodiment can take place in that, for example a microcomputer a test facility for detection proper ignition on each spark plug having. If a defective spark plug or a corresponding one defective ignition circuit is detected, so there is a constant Switching to the other spark plug in the combustion chamber so that a comfortable emergency operation is guaranteed. Last but not least, this serves to protect a catalytic converter.

An alternative application of the invention also consists in that is continuously operated in single ignition mode, whereby corresponding switching devices for dual ignition operation can be omitted. This serves to extend the Maintenance intervals for the ignition system, as the service life this doubles the spark plugs.

Claims (15)

1. Electronic ignition control device for generating ignition sparks on spark plugs in the combustion chambers of an internal combustion engine, each combustion chamber having two spark plugs which are each individually ignited in at least one operating state of the internal combustion engine (single ignition operation), characterized in that one of the two spark plugs (ZK 1 , ZK 2; CC 3 CC 4; CC 5, ZK 6; CC 7, ZK a combustion chamber (14 8) - 17) is provided in the single ignition operation with substantially equal frequency igniting switching means (24). 2. Ignition control device according to claim 1, characterized in that that in all operating conditions a single ignition operation is present. 3. Ignition control device according to claim 1, characterized in that in each case the two spark plugs (ZK 1 to ZK 8 ) of a combustion chamber ( 14 - 17 ) below a predeterminable load and / or speed value are jointly ignited (dual ignition mode) and above the same individually ( Single ignition operation). 4. Ignition control device according to claim 1, characterized in that in each case the two spark plugs (ZK 1 to ZK 8 ) of a combustion chamber ( 14 - 17 ) under special operating conditions, such as. B. diagnostic, start-up or warm-up operation, together (dual ignition operation) and otherwise individually ignited (single ignition operation). 5. Ignition control device according to one of the preceding Claims, characterized in that in the event of a failure Spark plug in single ignition mode means for complete Switching to the other spark plug are provided. 6. Ignition control device according to claim 1, characterized in that in the single ignition mode an alternating firing sequence for the two spark plugs (ZK 1 , ZK 2 ; ZK 3 , ZK 4 ; ZK 5 , ZK 6 ; ZK 7 , ZK 8 ) of each combustion chamber ( 14 - 17 ) is provided. 7. Ignition control device according to one of the preceding claims, characterized in that two combustion chambers ( 14 , 17 ; 15 , 16 ) are assigned two double spark coils (ZS 1 , ZS 2 ; ZS 3 , ZS 4 ), each of these double spark coils having a spark plug of the one and a spark plug of the other combustion chamber is connected and wherein the other combustion chamber is in the exhaust cycle in each case during the ignition triggering in a combustion chamber. 8. Ignition control device according to claim 7, characterized in that the two double spark coils (ZS 1 , ZS 2 ; ZS 3 , ZS 4 ) are controllable together in double ignition operation and individually in single ignition operation. 9. Ignition control device according to claim 8, characterized in that at least two groups of two double spark coils (ZS 1 , ZS 2 ; ZS 3 , ZS 4 ) are provided, each group being assigned to two combustion chambers ( 14 , 17 ; 15 , 16 ) and that the switching device ( 24 ) in single-ignition operation, the first double spark coil (ZS 1 ) of the first group, the first double spark coil (ZS 3 ) of the second group, the second double spark coil (ZS 2 ) of the first group and the second double spark coil (ZS 4 ) of the second group, the sequence of the first double spark coil and second double spark coil changing in the corresponding subsequent cycles. 10. Ignition control device according to one of claims 1 to 6, characterized in that each spark plug (ZK 1 to ZK 8 ) is assigned a single spark coil. 11. ignition control device according to any one of the preceding claims, characterized in that it is designed together with the switching device (24) as a microcomputer (22), said power output stages (18-21) between the microcomputer (22) and the single or double spark coil (ZS 1 -ZS 4 ) are provided. 12. Ignition control device according to claim 11, characterized in that a function switch or transmitter ( 23 ) is connected to the microcomputer ( 22 ), and that depending on the shortfall or exceeding of a predeterminable threshold value and / or the switching state of the function switch, a switchover between the Single ignition operation and double ignition operation is provided. 13. Ignition control device according to claim 12, characterized in that that the two modes of operation are different Ignition and / or lambda maps are assigned. 14. Ignition control device according to claim 12 or 13, characterized characterized in that the function switch is a diagnostic or start switch. 15. Ignition control device according to one of claims 12 to 14, characterized in that the encoder a load, speed and / or temperature sensor.