DE2850115A1 - Ignition system with solid state switch and tachogenerator - has second storage module for second count producing off time of switch - Google Patents

Abstract

The ignition system is for an IC engine which uses an electronic switch in the primary circuit of the ignition coil. The electronic switch is triggered by a signal derived from a tacho generator to provide phase triggering. There is a storage system which determines the point of trigger during the duty cycle in the primary circuit of the ignition coil. This is based on the period during which the primary current exceeds a threshold value. There is a storage system (19) for the counter signal, and also a second storage module (20) which takes over the value of the count at the start of the generator signal. The second count is forward and produces the off time for the switch. The signals from the generator are processed through logic circuits and make correction by either advancing or retarding the ignition points.

Description

Ignition system for internal combustion engines

PRIOR ART The invention is based on an ignition system the genre of the main claim. It is such an ignition system from the DE-OS 2 701 968, Fig. 1 and 2, known, which also according to the principle of the dwell angle enlargement is working. This means that an output signal is a transmitter arrangement or a Ignition angle calculation stage, a minimum basic dwell angle for the electronic Switches in the primary circuit of the ignition coil. Depending on the speed the closing time for this electronic switch is now brought forward, with the closing time for the previous cycle for the following cycle is determined. In the known arrangement, the counts the closing time determining counters only during the open time. This is what the counter reading determines Counter at the ignition point the following open time. This counter reading is through set a different counter. In the case of accelerations, this other counter must be from count the highest value according to the speed to the lowest value in order to at Maximum speeds to ensure the maximum dwell angle. This time will be all the more greater, the higher the threshold value for the primary-side current is set, which in turn to avoid control oscillations of the dwell angle when the residual storage effect begins is desirable. The resulting poor dynamics can result in starkpn Acceleration predecessor unpleasant due to weak or intermittent ignition sparks to make noticable.

Advantages of the invention The ignition system according to the invention with the characterizing Features of the main claim has the advantage that a much better one Dynamics is achieved by the other counter, also known as a control counter, has to cover a smaller area. This is achieved in that the first Counter that determines the start of the closing time, itself a speed-dependent one Pretends closing time. The value of the other counter only has a correcting effect with an initial information on this counter reading.

Another advantage is that the counting system follows this principle the dwell angle enlargement is very similar to systems for dwell angle reduction (DE-OS 2 746 885, Figs. 5 and 6). During the sonception of an integrated Circuit, it is desirable implement both principles alternatively to be able to.

The more similar these principles are, the easier it is to do it.

The measures listed in the subclaims are advantageous Further developments and improvements to the ignition system specified in the main claim are possible. It is particularly advantageous to set the visual threshold value for the primary current to one value determine which corresponds to a value of 60 to 90 g of the necessary primary current.

This reduces or avoids control oscillations of the dwell angle, especially when the residual memory effect occurs.

Drawing An embodiment of the invention is shown in the drawing and explained in more detail in the following description. It shows Fig. 1 shows the circuit configuration of the exemplary embodiment and FIG. 2 shows a signal diagram to explain how it works.

Description of the exemplary embodiment The output of an encoder arrangement 10 is via an OR gate 11 with the control input of an electronic switch 12 connected, the first switching connection of which via the primary winding of an ignition coil 13 to a terminal connected to the positive pole of a supply voltage source 14 is connected, and its second switching connection via a e.g. as a current measuring resistor trained current measuring device 15 is connected to ground.

Between the secondary winding of the ignition coil 13 and ground is a spark plug 16 is switched. If there are several spark plugs, one can in a known manner mechanical or non-mechanical high-voltage distribution can be provided. According to the prior art specified at the beginning, the encoder assembly 10 is a through the internal combustion engine is driven rotating encoder arrangement, which has a mechanical or electronic device for parameter-dependent adjustment of the ignition point assigned. The electronic switch 12 is usually designed as a transistor.

A voltage value corresponding to the measured current is obtained from the Current measuring device 15 is supplied to a threshold stage 17, the output of which has a NOR gate 18 with the blocking input E (enable) and with the counting direction input U / D (Up / Down) of a first counter 19 is connected. The binary number outputs this first counter 19 are connected to number inputs of a second counter 20, whose Number outputs are in turn fed to a digital comparator 21. To the comparison numbers this digital comparator 21 is the binary number, preferably by hard wiring X created. Instead of a digital comparator 21, one could of course also use one Logical gate realizable Dekoierstufe for the numerical value X can be used. The number output of the digital comparator 21 is once to a further input of the OR. -Gate 11 and further connected to an Ein.anx of an AND gate 22. The output of the encoder arrangement 10 is via an inverter 23 with another The input of the AND gate 22 is connected and continues to the counting direction input U / D (Up / Down) of the second counter 20 to the set input S of this second counter 20 and finally connected to an input of an AND gate 25 via an inverter 24, whose Output is connected to the blocking input E of the second counter 20. The overflow exit CO (Carry Out) of the second counter 20 is both connected to a second input of the AND gate 25, as well as via an inverter 26 to a further input of the AND gate 22 connected.

A clock generator 27 generates two counting clock frequencies fl and f2. The first, higher clock frequency fl is via an AND gate 28 to the input of a ûDER gate 29 connect, its output to the clock input C of the second counter 20 is connected. The second clock frequency f2 is with the clock input C of the first Counter 19, as well as via an AND gate 30 with a further input of the OR gate 29 connected. The ratio of the two frequencies fl and f2 corresponds to im essential - see Fig. 2 - the duty cycle of the encoder signals U10. The exit the encoder arrangement 10 is once directly in a further input of the AND gate 28 and furthermore via an inverter 31 to a further input of the AND gate 30 connected.

The mode of operation of the exemplary embodiment will be based on the following PM of the sienial diagram shown in Fig. 2. - Diirch the shorter a case of acceleration is shown as the encoder signal sequence 10. By the The encoder signal U10 applied to the counting direction input U / D- of the counter 20 is the counter set to "counting up" during each encoder signal U10, while in Only downward counting processes can take place during the signal pauses.

In the counter 19, counting up operations are only possible when the primary current through the ignition coil 13-is above the setpoint S. Is below this setpoint the counter 19 is set to "down counters". While at the counter 19 for both Counting directions the clock frequency f2 is applied, is the counter 20 during the counting up process - during of a signal U10 -by blocking the AND gate 30, the higher counting frequency f1 is supplied. In the signal pauses of the signal sequence U10, however, the AND gate 28 is blocked, so that the downward process takes place at the frequency f2.

At the beginning of an encoder signal U10 is the current counter reading Za taken over from the first counter 19 into the second counter 20. This takeover takes place by the encoder signal U10 fed to the set input S of the counter 20.

This is followed by an upward counting process with the frequency fl, the from the end of the signal of a signal U10 by counting down with the frequency f2 is continued.

The electronic switch continues to function through the end of the signal U10 12 locked, whereby an ignition spark is generated at the spark plug 16.. If the Numerical value in the counter 20 as a result of the downward counting process, the numerical value X, so speaks the digital comparator 21, through its output signal via the OR gate 11 the electronic switch 12 is placed in the current-conducting state.

The primary-side current through the ignition coil 13 begins to rise again. At the same time via the AND gate 22 and the NOR gate 18, the blocking of the Counter 19 is canceled, which then goes down from its current counter reading begins to count until a renewed blocking takes place via the AND gate 22. the Blocking can have two causes, each of which is the first of these two possibilities the blocking causes: -Once the beginning of a new encoder signal UlO and further on the overflow signal generated in counter 20 when the lowest count is reached at the overflow outlet CO. Both of them occur in the first three cycles shown Alternatives appear at the same time, while in the fourth cycle initially the Blocking is caused by reaching the lowest count in counter 20, and that Encoder signal Ulû only starts shortly thereafter. The other option, not shown consists in the fact that an encoder signal Ulû begins before the counter 20 reaches its lowest Counter reading has counted. In this case, the counter 19 is activated by the encoder signal UiO locked and the counter 20 takes over the count reached by the counter 19 before he counted on the lowest count. A better way in this case would be to take over the count of the counter 19 from the previous cycle. However, this requires an additional effort through a required buffer, the reached counter reading in counter 19 up to the following cycle keeps saved.

The counting up in the counter 19 is determined by the length of an output signal the threshold value stage 17 specified, which occurs when the threshold value S is exceeded the primary-side electricity is generated. This signal unlocks the counting process via the NOR gate 18. In the first illustrated counting cycle of the counter 19 is the steady state at constant speed is shown. The countdown process corresponds to the counting up process. In the following cycle, this will still be the case the same counting result Za is reached, but the subsequent up counting process is shorter as a result of a signal U10 which is shortened in accordance with the acceleration.

In the third cycle, a lower count Zb is reached, the is again taken over into the counter 20 with the rising edge of a signal U10. The counter 19 does not count up in the third cycle because the primary-side current I does not exceed the threshold value S. In the fourth cycle a new downward counting process takes place in the counter 19 up to the numerical value Zc. the Blocking of the counter 20 as soon as the lowest counter reading is reached up to the beginning of an encoder signal U10 takes place via the AND gate 25.

As once in the counter 20 a speed information by the upcounting is obtained during an encoder signal and, on the other hand, this speed information is supplemented by the numerical value taken over from the counter 19, is a good one System dynamics guaranteed. If the speed changes, the numerical value is required of the counter 19 can not be changed as much as it would be necessary if its counter reading would contain only the speed information.

In addition to the circuit shown, it goes without saying that according to the prior art specified at the beginning, a current limiting device and a device for disconnection of the quiescent current can be provided.

Claims (6)

Claims 0 'ignition system for internal combustion engines with an ignition coil, an electronic switch in their primary circuit and an electronic switch in their secondary circuit at least one ignition path is connected, with a dwell angle control device to control the electronic switch depending on the signals of a rotating Sensor arrangement, with a first storage device in the dwell angle control device, whose stored value can be changed through continuous lowering and raising phases, wherein the one phase by the current flow duration in the primary circuit of the ignition coil is specified from the exceeding of a threshold value by the primary current, with a second memory device into which a memory value of the first memory device can be taken over by a signal from the transmitter arrangement, with a definable one when it is reached Threshold through which changing memory value of the electronic Switches in the primary circuit of the ignition coil are closed and activated by a signal from Encoder arrangement is opened again, characterized in that in the second Storage device (20) also run continuous lowering and raising phases, whose ratio is essentially determined by the pulse duty factor of the encoder signals (mio) is predetermined and that the second change phase in the first memory device (19) during the change phase in the second storage device (20) between the definable threshold (X) and a further threshold expires, with a signal the encoder arrangement (10) ends this change phase with priority. 2. Ignition system according to claim 1, characterized in that; that the threshold (S) for the primary current a value of 60 to 90% of the necessary primary current having. 3. Ignition system according to claim 1 or 2, characterized in that the storage value accepted by the second storage device (20) is the current one Storage value of the first storage device - (19) - is. 4. Ignition system according to claim 1 or 2, characterized in that the memory value taken over from the second memory device (20) is the temporarily stored value Storage value the first memory device (19) of the previous cycle. 5. Ignition system according to one of the preceding claims, characterized in that that the storage devices are designed as digital counters and the lowering and Increase phases run as counting down and counting up. 6. Ignition system according to claim 5, characterized in that the two Frequencies (f, f 2) for the up and down counting process in the second memory device (20) essentially determined by the duty cycle of the encoder signal sequence (Ui0) are.