WO2010006992A1 - Evaluation circuit for detecting the cylinder assignment of an internal combustion engine - Google Patents

Abstract

The invention relates to an evaluation circuit for detecting the cylinder assignment of an internal combustion engine using a signal which is capacitively output at the ignition coil (1) with respect to a particular first potential for cylinder assignment, having an input circuit with a differential element (IC1-1, R9, C10) which forms a difference between the first potential or a signal (IN_N) derived therefrom and the signal capacitively output at the ignition coil (1) or a signal (IN_P) derived therefrom in order to form a first evaluation signal (A1).

Description

 description

title

Evaluation circuit for detecting the cylinder assignment of an internal combustion engine

State of the art

The present invention relates to an evaluation circuit for detecting the cylinder assignment of an internal combustion engine according to the preamble of claim 1.

State of the art for signal evaluation of ignition coils, in particular 2x2 ignition coils, are various capacitive tap options on such double-spark coils. Double-coil coils connect both ends of the secondary winding with one spark plug each. After switching off the primary-side charging current, the voltages on both spark plugs rise almost symmetrically to the zero line, one towards positive and the other towards negative voltages. The spark plug, which is in the cylinder that is in the exhaust stroke, due to the lower combustion chamber pressure has a lower breakdown voltage than the other, which is in the compression stroke. If only the former breaks through, the voltage across the spark plug decreases from approx. 8 ... 20 kV to only 900 ... 1000 V, which causes the entire potential of the secondary winding to shift by a few kV.

In the known methods, e.g. in DE 40 28 545 A1, however, it is difficult and sometimes not feasible to achieve a cylinder assignment by means of the derived signal, since the decoupled secondary signal is also influenced by the primary circuit of the ignition coil.

Advantages of the invention

The device according to the invention with the features of claim 1 has the advantage that the potential shift on the winding of the double spark coil can be completely detected and a signal is output, which indicates the compressed cylinder and which is similar in its electrical properties to the previous phase signal generator, thereby the previously provided by the phase signal generator cylinder assignment is made possible in the engine. By means of the arrangement according to the invention for detecting the cylinder assignment of a Internal combustion engine, a signal easily and safely to be detected in the control unit is provided, because the fact that an input circuit is provided with a differential element, which is a difference of the first potential or a signal derived therefrom and the decoupled from the ignition coil signal or a derived therefrom Signal forms to form a first evaluation signal, an increased noise immunity is ensured.

The dependent claims show preferred developments of the invention.

The differential element according to the invention is particularly preferably an ohmic-capacitive feedback differential amplifier which receives at its negative input the signal decoupled capacitively from the ignition coil or the signal derived therefrom and receives at its positive input the first potential or the signal derived therefrom.

In the evaluation circuit according to the invention, a temperature-compensated reference voltage is additionally additionally preferably superimposed on the first potential applied to the positive input of the ohmic-capacitive feedback differential amplifier or the signal derived therefrom. By this measure, a temperature drift of the differential amplifier is compensated or at least mitigated.

Further preferred is the temperature-compensated reference voltage in the inventive

Evaluation circuit superimposed by a reference voltage is applied via a first resistor to the positive input of the ohmic-capacitive feedback differential amplifier and the positive input of the ohmic-capacitive feedback differential amplifier is connected via antiparallel connected diodes and a second resistor to ground.

Alternatively or further preferred, in the evaluation circuit according to the invention, the first potential or the signal derived therefrom and the signal output capacitively coupled to the ignition coil or the signal derived therefrom are decoupled before being fed to the differential element by means of a respective capacitive longitudinal coupling and / or via respective base point resistances into the input voltage range shifted the difference element. Through these measures, the

Signal source with the correct impedance completed and a ground offset between the first potential and the mass of the evaluation circuit (ECU ground) eliminated.

Further preferably, the evaluation circuit according to the invention serves as a signal output capacitively coupled to the ignition coil, a charge induced on a tapping plate (2), which is supplied by a

Divider capacitor (4) is distributed against the first potential such that at the divider capacitor (4) a lower capacitor voltage is produced, and the first potential is preferably a ground potential, in particular motor ground. The engine mass is the mass referred to the spark plugs is connected, so in particular the mass of the cylinder head. By selecting the engine mass as the first potential a clamped surface is avoided.

Alternatively or additionally, the evaluation circuit according to the invention preferably comprises a preferably low-pass-limited peak value stage which receives the first evaluation signal and stores a positive peak value of the first evaluation signal to generate a second evaluation signal and stores a negative peak value of the first evaluation signal to generate a third evaluation signal. By this measure, in the inventive

Evaluation circuit low-cost operational amplifier, which have a low slew rate can be used. Furthermore, such an extension of the input signal ensures better robustness.

Further preferably or additionally, the evaluation circuit according to the invention comprises an output stage which receives the second evaluation signal and stores when a first input threshold is exceeded for a certain time to form a fourth evaluation signal and which receives the third evaluation signal and falling below a second input threshold for a certain Saves time to form a fifth evaluation signal.

Additionally or alternatively, the evaluation circuit according to the invention comprises a window forming unit which forms an evaluation window for the first evaluation signal or a signal derived therefrom by detecting the time range in which the secondary voltage of the ignition coil is above a primary voltage determined by a spark-burning voltage.

Finally, according to the invention, the ignition coil is more preferably or alternatively a double-spark coil.

According to the invention, there are also the advantages that the phase information, ie the unambiguous assignment of the crankshaft position to the camshaft position, is made more cost-effective than with a combination of phaser and transmitter wheel, the integration of only a few passive components in the ignition coil and the evaluation of the signal thus prepared is more cost-effective in the evaluation circuit, as a total integration of the electronics in the ignition coil. This is achieved because the input signal is differentially evaluated, whereby a high immunity to interference is ensured, since preferably the signal source is terminated with the correct impedance, whereby a mass offset between the engine mass and control unit mass is eliminated, as more preferably - A -

the input signal is held (extended), which is given a high degree of robustness, since even more preferably temperature influences are compensated, since even more preferably noise signals are filtered out, whereby an increased noise immunity is given because even more preferably the useful of the interference signal by temporal correlation is disconnected, and still more preferably detected states can be stored for a certain time.

drawing

Hereinafter, an embodiment of the invention will be described in detail with reference to the accompanying drawings. In the drawing show:

Figure 1 secondary voltage waveforms and a rough structure of the invention

Contraption,

2 shows the voltage curve at the tapping plate, and Figure 3 shows a first preferred embodiment of an evaluation circuit according to the invention.

Preferred embodiments of the invention

Hereinafter, with reference to the figures, preferred embodiments of the invention will be described in detail.

In Figure 1, the secondary voltage waveform of two spark plugs 16 and 17 is shown on the left, wherein the first spark plug 16 is located in a non-compressed cylinder and the second spark plug 17 is disposed in a compressed cylinder. The upper curve A corresponds to the secondary voltage at the first spark plug 16 and the lower curve B corresponds to

Secondary voltage at the second spark plug 17. It can be seen that when Zündspannungsaufbau the two spark plugs both voltages (ideally) rise symmetrically to the zero line, to one of the two spark plugs, which is the first spark plug 16 on the non-compressed cylinder breaks, and the voltage there a constant level of about 1 kV, namely the separation voltage, assumes.

This results in a potential jump of the secondary winding 1, which leads to the connected from the tapping plate 2 to ground 5 base capacitor 4 to a compensation process. If the second spark plug 17 subsequently breaks through as well, a reversing process occurs, and it is excited to a damped oscillation, so that the base capacitor 4 in FIG

2, in which a signal lying at zero initially drops sharply, then it changes and immediately assumes the form of a decaying sinusoidal oscillation.

In the figure 1 right, the basic structure of the arranged in or on the ignition coil subcircuit is shown. Opposite the secondary winding of a double spark coil 1, an electrically conductive plate 2 is mounted, on which electrical charges are influenced by the electric field. These are connected via a resistor 3 to the Fußpunktkondensator 4, which in turn is connected at its other end to the engine mass 5 of the engine, so with the potential, which also have the spark plugs at its end. The capacitance of this capacitor is chosen so that the voltage appearing on it may be in the range of a few volts, but not kilovolts (as on the secondary winding).

The resistor 3 forms with the Fußpunktkondensator 4 a low-pass filter which serves to damp the oscillation of the resonant circuit formed from the secondary inductance, secondary capacitance and Auskoppelkapazität.

At the connection node of the resistor 3 to the Fußpunktkondensator 4, a resistor 20 is provided which is connected between a tapping plate side first terminal of the divider capacitor 4 and a first terminal of a leading to an evaluation circuit first line 22, and there is a resistor 21 is provided between a motormasseseitigen second terminal of the divider capacitor 4 and a first terminal of a second line leading to the evaluation circuit 23 is connected, wherein the first line 22 and the second line 23 are twisted together, ie they form a "twisted pair".

FIG. 3 shows a preferred exemplary embodiment of a signal evaluation circuit according to the invention. In this exemplary embodiment, the signal fed into the first line 22 is applied to the terminal IN P and the signal fed into the second line 23 to the terminal IN N. Via these two terminals, the decoupled signals are fed to an input circuit, which is a first evaluation signal Al forms.

The input circuit comprises a resistor RO, which is connected between the two inputs IN P, IN N. Parallel to the resistor RO, a series circuit of two capacitors Cl, C2 is connected, whose connection node is connected to ground GND. At the positive input IN P, a capacitor C3 is further connected to a series circuit consisting of the capacitor C3 and a resistor Rl, whose other end is connected via a resistor R2 to ground GND. At the negative input IN N, a capacitor C4 is connected to a series circuit consisting of the capacitor C3 and of the resistor R4, whose the other end is connected through a resistor R3 to ground GND. The connection node between the resistor Rl and the resistor R2 is connected via a resistor R5 to a negative input of a first operational amplifier ICl-I and the connection node between the resistor R4 and R3 is connected via a resistor R6 to the positive input of the first operational amplifier ICl-I connected.

The signal applied to the first input IN P of the input circuit and the second input IN N of the input circuit, which capacitively coupled from the secondary coil via a divider capacitor 4 and two output resistors 20, 21 in the ignition coil 1 via a first and second line 22, 23 driven is thus, by virtue of the resistance RO, normally balanced and terminated by the capacitors C1, C2 equal to and in the opposite sense to ground GND and capacitively coupled into the circuit via the longitudinal coupling capacitors C3 and C4. In addition, a voltage division via the decoupling resistors 20 and 21 integrated in or on the ignition coil or via the resistors R1 and R4 and the base resistances R2 and R3 brings a possible mass offset between the engine mass and the control unit mass into the input voltage range of the first operational amplifier IC1.

The output of the first operational amplifier ICl-I is fed back via a parallel circuit of a resistor R9 with a capacitor ClO to the negative input of the first operational amplifier ICl-I. The negative input of the operational amplifier ICl-I is further connected via a resistor Rl 0 to ground GND. The positive input of the first operational amplifier ICl-I is connected via a series circuit of a resistor R7 and a resistor R30 to a positive operating voltage VDD5, wherein the resistor R7 is at the positive input of the first operational amplifier ICl-I and the resistor R30 with the positive operating voltage VDD5 connected is. A node between the resistor R7 and the resistor R30 is connected via a reference diode D7 to ground GND, wherein the cathode of the reference diode D7 is applied to the connection point between the resistors R7 and R30 and the anode of the reference diode D7 is connected to ground. The reference diode D7 is preferably a Zener diode or a bandgap diode. The positive input of the first operational amplifier ICl-I is further connected via a series connection of antiparallel

Diodes DlO and Di l connected to ground with a resistor R8.

Via the voltage divider R7 / R8 and the temperature compensation diodes C10 / C11, either the positive supply voltage VDD5 or a reference voltage (via R30 and the reference diode D7) is introduced into the input differential sum. The output of the first operational amplifier ICl-I supplies the first evaluation signal Al. The input circuit follows in the embodiment shown an optional amplifier stage to amplify the first evaluation signal Al. This is formed by means of a second operational amplifier IC 1-2, at the positive input of the first evaluation signal Al via a resistor Rl 1 is applied. The positive input of the second operational amplifier IC 1-2 is further connected via a resistor Rl 2 to ground. The output of the second operational amplifier IC 1-2 is connected via a resistor Rl 4 to the negative input of the second operational amplifier ICl -2 and via a resistor Rl 5 to the output of the first operational amplifier ICl-I, ie the first evaluation signal Al. The negative input of the second operational amplifier IC 1-2 is further connected via a resistor Rl 3 to ground. At the output of the second operational amplifier IC 1-2 is the amplified first evaluation signal Al 'on.

The amplified first output signal Al 'or alternatively the non-amplified first output signal Al is fed to a low-pass limited peak stage which stores a positive peak value of the applied evaluation signal to generate a second evaluation signal INT PK POS and stores a negative peak value of the received evaluation signal to generate a third evaluation signal INT PK NEG. The peak value stage comprises a first branch, which receives the evaluation signal Al or the amplified evaluation signal Al 'via an optional coupling capacitor C14. The first branch consists of a connected to the anode to the coupling capacitor C 14 diode D2, whose cathode is connected to a first terminal of a resistor Rl 7. The second terminal of the resistor Rl 7 is connected via a parallel circuit of a capacitor C6 with a resistor Rl 9 to ground GND. At the second terminal of the resistor Rl 7 is the second evaluation signal INT PK POS. The second branch of the peak value stage is connected via an optional coupling amplifier CI 1 to the first evaluation signal Al or to the amplified first evaluation signal Al '. The second branch of the peak value level consists of a diode D1 connected to the cathode on the coupling capacitor CI1, the anode of which is connected to a first terminal of a resistor R1. The second terminal of the resistor Rl 6 is connected via a parallel circuit of a capacitor C5 with a resistor Rl 8 to the positive supply voltage VDD5. At the second terminal of the resistor Rl 6 is the third evaluation signal

INT PK NEG on.

The second evaluation signal INT PK POS and the third evaluation signal INT PK NEG are fed to an output stage which stores the second evaluation signal INT PK POS when a first input threshold is exceeded for a certain time to form a fourth evaluation signal A4, and the third evaluation signal INT PK NEG falls below a second Store input threshold for a certain time to form a fifth evaluation signal A5. For this purpose, the second evaluation signal INT PK POS is fed to the negative input of a third operational amplifier IC 1-3, to whose positive input the first input threshold is applied. This is produced by connecting the center tap of a voltage divider R24, which here is designed as a potentiometer, but is preferably formed by fixed resistors, to the positive input of the third operational amplifier IC 1-3, the voltage divider having a first connection to ground GND is connected and connected to a second terminal to the cathode of a diode D 12 whose anode is connected to the positive supply voltage VDD5. The output signal of the third operational amplifier IC 1-3 is connected via a series circuit of a diode D8, a resistor R31 and a capacitor C8 to the positive input of the third operational amplifier C 1-3, wherein the cathode of the diode D8 to the output of the third operational amplifier ICl -3, the anode of the diode D8 is connected to a first terminal of the resistor R31 whose second terminal is connected to a first terminal of the capacitor C8, the second terminal of which is connected to the positive input of the third operational amplifier IC 1-3 the fourth evaluation signal A4 is present, is connected. The output of the third operational amplifier IC 1-3 is further connected via a parallel circuit of a capacitor C12 with a resistor R34 to ground GND. The third evaluation signal INT PK NEG is connected via a resistor R33 to the positive input of a fourth operational amplifier IC 1-4, at the negative input of which the second input threshold is applied. This is generated by the center tap of a voltage divider R25, here as

Potentiometer is designed, or preferably but is formed by fixed resistors, is connected to the negative input of the fourth operational amplifier IC 1-4. A first terminal of the voltage divider R25 is connected to the positive supply voltage VDD5 and a second terminal of the voltage divider R25 is connected to the anode of a diode Dl 3, the cathode of which is connected to ground GND. The output of the fourth operational amplifier ICl -4, at which the fifth evaluation signal A5 is applied is fed back via a series connection of a diode D9 with a resistor R32 and a capacitor C9 to the positive input of the fourth operational amplifier IC 1-4, the diode D9 with its cathode is connected to the output of the fourth operational amplifier ICl -4 and its anode connected to a first terminal of the resistor R32, whose second terminal is connected to a first terminal of the

Capacitor C9 is connected, whose second terminal is connected to the positive terminal of the fourth operational amplifier IC 1-4. The output of the fourth operational amplifier IC 1-4 is further connected via a parallel circuit of a capacitor C13 with a resistor R35 to ground GND. The evaluation comparators connected to the second evaluation signal INT PK POS and the third evaluation signal INT PK NEG are able to store the overshoot or undershoot of their temperature-compensated input thresholds by the input signal via a device-time-limited positive feedback. 5

The evaluation circuit further comprises a window forming unit, the evaluation window fenstert the fourth evaluation signal A4 and the fifth evaluation signal A5 and forms two output signals by the time region is detected here, in which the secondary voltage of the ignition coil 1 is above a determined by a spark voltage primary voltage. The evaluation window 0 determining window signal INT GATE is linked via an AND operation with the fourth evaluation signal A4 and the fifth evaluation signal A5, whereby the AND operation with the fourth evaluation signal A4, a positive output signal OUT DT POS and the AND operation with the fifth evaluation signal A5, a negative output signal OUT DT NEG is generated. The positive output signal OUT DT POS is obtained by tapping the signal resulting from the ANDing of the window signal INT GATE and the fourth evaluation signal A4 at the center tap of a voltage divider consisting of a resistor R26 and a resistor R27 connected between the AND Link forming logic gates and ground is connected. The negative output signal OUT DT NEG is obtained at the center tap of a voltage divider R28, R29 connected between the logic gate constituting the AND gate of the window signal INT GATE and the fifth evaluation signal A5, and ground. In the exemplary embodiment shown, a first NOR gate IC2-1 is provided for the AND operation of the window signal INT GATE with the fourth evaluation signal A4, and a second NOR gate IC2-2 is provided for the AND operation of the window signal INT GATE with the fifth evaluation signal A5 , These NOR gates form the AND gate due to inverted logic 5.

In order to generate the window signal INT GATE by the window forming unit, a voltage divider consisting of two resistors is connected between the lower primary winding connection of the ignition coil and ground, at whose connection node a signal is tapped which is conducted at the O input IN COL. The window-forming unit then detects the ignition transistor collector signal coming from terminal 1 by detecting, by means of a Z-diode cascade D5, D4, D3, the time range in which the secondary voltage is still above the primary voltage determined by the spark-burning voltage, ie between the first and second the second breakthrough of the two spark plugs. This is achieved by connecting the Z-diode cascade D3, D4, D5 5 to the cathode of the Zener diode D3 to the ignition transistor collector, ie the signal applied to the input IN COL, and to the anode of the diode D5 grounded Shunt resistor R20. The voltage dropped across the shunt resistor R20, ie, the potential at the connection node between the shunt resistor R20 and the Zener diode D5, charges a timer R21 / C7 and drives a transistor Tl which generates the window signal INT GATE. For this purpose, the voltage drop across the shunt resistor R20 is connected via the resistor R21, which is connected to a first terminal at the node between the resistor R20 and the Zener diode D5 and connected to its second terminal via the capacitor C7 to ground GND the base of the transistor Tl out. The capacitor C7 may consist of a single capacitor or for better coordination also of a parallel circuit of several capacitors C71, C72, C73, C7. To the second terminal of the resistor R21, a grounded resistor R22 is further connected. In order for the transistor to switch off precisely, a voltage source, here in the form of a bandgap diode D6, whose cathode is connected to the second terminal of the resistor R21 and whose anode is connected to the base, is connected between the second terminal of the resistor R21 and the base of the transistor T1 of the transistor Tl is connected. The transistor Tl here is a PNP transistor whose collector-emitter-Stecke is connected via a resistor R23 between the positive supply voltage VDD5 and ground GND, the emitter is connected directly to ground GND and the collector via the resistor R23 with the positive Supply voltage VDD5 is connected. The window signal INT GATE is applied to the collector.

FIG. 3 further shows that the IC IC1 containing the first to fourth operational amplifiers IC1 to IC4 is supplied with the positive supply voltage VDD5 and to ground GND, and that three capacitors CBLK1 between the positive supply voltage VDD5 and ground , CBLK2 and CBLK3 are switched.

By means of this evaluation circuit according to the invention, a suitable source and line termination as well as the suitable signal conditioning of a capacitively decoupled signal at the ignition coil, with which the function of the phase encoder is replaced, are given.

The advantages are that the input signal is differentially evaluated, whereby a high interference immunity is ensured, that the signal source is terminated with the correct impedance, that a mass offset between engine mass and ECU mass is eliminated

Input signal is held (extended), whereby a high degree of robustness is given that temperature influences are compensated, that interference signals are filtered out, whereby an increased interference immunity is given, that the useful from the interference signal is separated by temporal correlation, and that detected states for a particular Time can be saved.

Claims

claims 1. evaluation circuit for detecting the cylinder assignment of an internal combustion engine by means of a cylinder assignment to a specific first potential capacitively coupled to the ignition coil (1) signal, characterized by an input circuit with a differential element (ICl-I, R9, ClO), which is a difference of the first Potential or a signal derived therefrom (INJSf) and the signal output capacitively coupled to the ignition coil or a signal derived therefrom (IN P) to form a first evaluation signal (Al). 2. evaluation circuit according to claim 1, characterized in that - the differential element (ICl-I, R9, ClO) is an ohmic-capacitive feedback differential amplifier (ICl-I, R9, ClO), the capacitive on the ignition coil at its negative input decoupled signal or the signal derived therefrom (IN P) and receives at its positive input the first potential or the signal derived therefrom (IN N). 3. evaluation circuit according to claim 2, characterized in that at the positive input of the ohmic-capacitive feedback differential amplifier (ICl-I, R9, ClO) applied first potential or the signal derived therefrom, a temperature-compensated reference voltage is superimposed. 4. evaluation circuit according to claim 3, characterized in that the temperature-compensated reference voltage is superimposed by a reference voltage (VDD5) via a first resistor (R30) to the positive input of the ohmic-capacitive feedback differential amplifier (ICl-I, R9, ClO) applied is and the positive input of the ohmic-capacitive feedback differential amplifier (ICl-I, R9, ClO) via antiparallel connected diodes (DlO, Dl 1) and a second resistor (R8) is connected to ground. 5. evaluation circuit according to one of the preceding claims, characterized in that the first potential or the signal derived therefrom (IN N) and the signal output capacitively coupled to the ignition coil or the signal derived therefrom (IN P) before feeding to the differential element (ICl- I, R9, ClO) by means of a respective capacitive longitudinal coupling (C3, C4) are decoupled and / or via respective Fußpunktwiderstände (R2, R3) in the Input voltage range of the differential element (ICl-I, R9, ClO) are shifted. 6. evaluation circuit according to one of the preceding claims, characterized in that capacitively coupled to the ignition coil (1) signal is a on a tapping plate (2) influenzierte charge is used, which is distributed by a divider capacitor (4) against the first potential such that a lower capacitor voltage arises at the divider capacitor (4), and that the first potential is a ground potential, in particular motor ground. 7. evaluation circuit according to one of the preceding claims, characterized by: a preferably low-pass limited peak value receiving the first evaluation signal (Al) and a positive peak value of the first evaluation signal (Al) stores to generate a second evaluation signal (INT PK POS), and stores a negative peak of the first evaluation signal (Al) to produce a third evaluation signal (INT PK NEG). 8. evaluation circuit according to claim 7, characterized by: an output stage which receives the second evaluation signal (INT PK POS) and stores when a first input threshold is exceeded for a certain time to form a fourth evaluation signal (A4), and the third evaluation signal (INT PK NEG) receives and stores falls below a second input threshold for a certain time to form a fifth evaluation signal (A5). 9. evaluation circuit according to one of the preceding claims, characterized by: a window forming unit which forms an evaluation window for the first evaluation signal or a signal derived therefrom by detecting the time range in which the Secondary voltage of the ignition coil (1) is above a determined by a spark ignition voltage primary voltage. 10. evaluation circuit according to one of the preceding claims, characterized in that - the ignition coil (1) is a double spark coil.