EP0790408A2 - Measuring circuit for an ionic current in ignition devices for internal combustion engines - Google Patents

Abstract

The invention relates to a circuit arrangement for ion current measurement in the combustion chamber of an internal combustion engine with an ignition coil consisting of primary and secondary windings, the secondary winding of which is connected both to a spark plug, which also serves as an ion current probe, and also via its low potential side with an inverting amplifier to generate a constant measurement voltage is connected to the ion current measurement. According to the invention, both a first discharge circuit branch with a first semiconductor diode and a second discharge circuit branch connected in parallel with the inverting amplifier with a second semiconductor diode are provided for deriving the ignition current flowing during the burning time of the spark plug to the ground potential of the circuit arrangement.

Description

The invention relates to a circuit arrangement for ion current measurement according to the preamble of patent claim 1.

Such an ion current measuring circuit is known from US 5483818, which has a differential amplifier connected as an inverting amplifier, for this purpose the low potential side of the secondary winding of the ignition coil is connected via a resistor to the inverting input of the differential amplifier, while a bias voltage of approximately 40 V is applied to its non-inverting input is created. To achieve the inverting amplifier property, the output is fed back to the inverting input via a resistor and, at the same time, the output signal is fed to a threshold circuit for evaluating the ion current. Also connected to the low potential side of the secondary winding are two series-connected zener diodes, the connection nodes of which are controlled by a further inverting amplifier in such a way that the leakage currents which occur during an ion current measurement are avoided, in order to generate unadulterated ion current signals. The further inverting amplifier is constructed in a corresponding manner to the amplifier connected directly to the secondary winding, the output of which is connected via a resistor to the inverting input of the further amplifier and the non-inverting input of which is supplied with the same bias voltage.

In order to avoid the leakage currents generated by the Zener diodes used, this known ion current measuring circuit disadvantageously requires a high level of circuitry.

The object of the present invention is therefore to provide a circuit arrangement for ion current measurement of the type mentioned at the outset which avoids this disadvantage.

The solution to this problem is given by the characterizing feature of claim 1. According to this, first and second diverting circuit branches are provided for diverting the ignition current flowing during the burning time of the spark plug, each of which has a semiconductor diode and the second diverting circuit branch is arranged parallel to the inverting amplifier. The main advantage of this solution according to the invention lies in the use of normal semiconductor diodes, so that the problem of high leakage currents does not occur and therefore a complex circuit as proposed in the prior art can be dispensed with.

Another advantage that can be achieved with the present invention is a lowering of the value of the measuring voltage below the voltage value of 40 V specified in the prior art.

In an advantageous development of the invention, an ignition current measuring resistor is connected in series with the further semiconductor diode, which forms the second discharge circuit branch. The voltage drop occurring at this ignition current measuring resistor can advantageously serve as a measurement signal for the amount of the ignition current during the burning time of the spark plug. This ignition current measurement signal can be used to control the ignition sequence in the event of a secondary ignition.

The second diverting circuit branch can preferably be connected to the ground potential of the circuit arrangement via a semiconductor switch which can be controlled by the output of the inverting amplifier, in particular a transistor. This can advantageously increase the current carrying capacity of the differential amplifier.

According to a further advantageous embodiment of the invention, a differential amplifier connected as an inverting amplifier is provided.

Preferably, one input of such a differential amplifier is connected to the low potential side of the secondary winding of the ignition coil, while a reference voltage is supplied to the other input, the value of which corresponds to the measuring voltage and in which the output is connected to the one input via a measuring resistor.

With the simplest circuit means, the ion current is converted into a voltage serving as a measurement signal, which voltage is then fed to an evaluation.

The reference voltage supplied to such a differential amplifier is generated in the simplest way with a constant voltage source.

Furthermore, when using a multi-cylinder internal combustion engine, the measuring sections of the spark plugs serving as ion current probes can be connected in parallel, so that the advantage of a low circuit complexity is retained. If, on the other hand, the measuring sections of the spark plugs serving as ion current probes are to be measured completely independently of one another, there may also be multiple circuits whose output signals are then time-multiplexed in a suitable form.

Finally, in a particularly preferred embodiment of the invention, a parallel circuit comprising a dissipation resistor and at least one zener diode can be connected in series with the secondary winding in order to rapidly dissipate the energy which is still in the ignition coil or the secondary capacitances after the ignition spark has broken off, so that the ion current measurement can then be carried out without great time delay. Advantageously, two antiserially connected zener diodes can preferably be used instead of only a single zener diode in order to achieve a decay behavior compared to the use of only a single zener diode, the duration of which is shorter and also symmetrical.

Figur 1

ein Schaltbild eines elektronischen Zündsystems gemäß der Erfindung und

Figur 2

einen Schaltungsausschnitt des Schaltbildes nach Figur 1 mit einem alternativen zweiten Ableitschaltungszweig A2.

In the following, the invention will be illustrated and explained using an exemplary embodiment in connection with the figure. Show it:

Figure 1

a circuit diagram of an electronic ignition system according to the invention and

Figure 2

a circuit section of the circuit diagram of Figure 1 with an alternative second diverting branch A2.

FIG. 1 shows a transistor ignition system of a 4-cylinder internal combustion engine, each with an ignition output stage assigned to a cylinder, each ignition output stage comprising an ignition coil Tr ₁ ,..., Tr ₄ , a primary winding P ₁ ,..., P ₄ and a secondary winding S ₁ , ... S ₄ , and an ignition transistor 1a, ..., 1d connected to the primary winding P ₁ , ..., P ₄ with associated spark plug Zk ₁ , ..., Zk _{4 is} constructed. The primary windings P ₁ , ..., P ₄ are connected by their one connection to an on-board battery voltage U _B of 12 V, for example, while the other connection is connected to the associated ignition transistor 1a, ..., 1d.

The ignition transistors 1a, ..., 1d are controlled via their control electrodes by a circuit 2a for cylinder selection, which in turn is connected to a control circuit 2, which supplies the corresponding ignition trigger pulses for the individual cylinders of this circuit 2a.

The figure also shows a control unit 4, which takes over the function of an engine management and in turn controls the control circuit 2. For this purpose, engine parameters such as load, speed and temperature are fed to this control unit 4 via an input E. Corresponding actuators are controlled via outputs A.

The secondary windings S ₁ , ..., S ₄ are each connected with their high-voltage side to the associated spark plug Zk ₁ , ..., Zk ₄ , while their low potential side are brought together in a circuit node S via a dissipation resistor R ₃ .

This circuit node S is connected to the input of a differential amplifier 3 connected as a non-inverting amplifier, in that this circuit node S is connected to the inverting input of this differential amplifier 3. In contrast, a constant reference voltage U _ref , preferably 20 V, is applied to the non-inverting input of this differential amplifier 3, this constant reference voltage being generated by a constant voltage source 6. This constant reference voltage U _ref is fed to the secondary windings S ₁ , ..., S ₄ via this differential amplifier 3 by means of a measuring resistor R1 fed back to the inverting input, and thus reaches the spark plugs Zk ₁ , ... working as ion measuring current paths as the _test voltage U _test . , Mark ₄ .

In order to derive the ignition current which arises during the burning time due to the ignition process, the circuit according to the figure has a first and second diverting circuit branches A1 and A2. The first discharge circuit branch A1 connects the circuit node S to the ground potential of the circuit via a semiconductor diode D ₂ , while the second discharge circuit branch A2 consists of a series connection of an ignition current discharge resistor R ₂ , a further semiconductor diode D ₁ and a pnp transistor T, the ignition current measurement resistor R ₂ is connected to the circuit node S and the collector electrode of the transistor T is at the ground potential of the circuit. The base electrode of this transistor T is driven by the output of the differential amplifier 3.

The first diverting circuit branch A1 serves to derive negative voltage peaks occurring in one of the spark plugs Zk ₁ ,... Zk ₄ at the moment of a high voltage breakdown.

The actual ignition current is derived via the second derivation switching branch A ₂ , which can also be constructed without the transistor T, which only serves to increase the current carrying capacity of the differential amplifier 3. If such a transistor T is dispensed with, the cathode of the semiconductor diode D _{1 is} directly connected to the output of the differential amplifier 3 Connected so that the diverting branch A _{2 is connected in} parallel to the ion measuring resistor R ₁ .

The function of the circuit according to FIG. 1 is to be explained below:

The generation of an ignition pulse by the control circuit 2 leads to the activation of the corresponding ignition transistor 1a, ..., 1d. The ignition spark generated in this way on the associated spark plug Zk ₁ ,..., Zk ₄ leads to a certain burning duration, which is accompanied by an ignition current. This ignition current flows through the low-resistance leakage circuit branch A ₂ to a part via the differential amplifier 3 and to another part in accordance with the set operating point of the transistor T to ground potential. This operating point of the transistor T is determined by the output signal U _{ion of} the differential amplifier 3, which, by means of the feedback via the ion measuring resistor R _1, regulates its potential at the inverting input to the U _ref potential, which represents the measuring voltage for the subsequent ion current measurement. Overloading of the differential amplifier 3 by the ignition current is thus avoided by using such a transistor T.

an, wobei U_D1 bzw. U_BE die Diodenflußspannung bzw. die Basis-Emitterspannung darstellt.During the burning time, the output signal U _{ion of} the differential amplifier 3 indicates the level of the ignition current flowing through the ignition current measuring resistor R ₂ and can therefore be used as a measurement signal of the ignition current after evaluation for charging and burning time control of the internal combustion engine. The value of the ignition current measuring resistor R ₂ is chosen so that its voltage drop U _R2 with the value R ₂ · I _{ignition is} in the range of a few volts. Such a value for the resistor R ₂ would be 15 Ω, for example. At the output of the differential amplifier 3 there is a voltage U _ion with a value of ${\text{U}}_{\text{ref}}{\text{- I}}_{\text{ignition}}{\text{· R}}_{\text{2nd}}{\text{-U}}_{\text{D1}}{\text{-U}}_{\text{BE}}$

where U _D1 or U _{BE represents} the diode forward voltage or the base-emitter voltage.

The measuring voltage for the level of the ignition current could also be tapped at the emitter of the transistor T or with high resistance at the anode of the diode D ₁ . The tolerances of the base-emitter voltage of the transistor T or the diode forward voltage of the diode D ₁ would then not be included in the measurement come in. Another possibility for generating a measuring voltage for the ignition current is given in FIG. 2 explained below.

After the ignition radio has been torn off, that is to say at the end of the burning time, the residual energy still remaining in the corresponding secondary winding S ₁ ,... S ₄ or in the secondary capacitances must be rapidly dissipated. For this purpose, the already mentioned dissipation resistor R ₃ , to which two antiserially connected Zener diodes Z ₁ and Z ₂ are connected in parallel.

Such a parallel connection substantially shortens the duration of the decay after the ignition spark has broken off, so that an ion current measurement which is not impaired by the decay behavior can be carried out immediately thereafter.

Such accelerated energy dissipation is particularly important at high engine speeds. The value of the dissipation resistance R ₃ is preferably chosen so that it corresponds to the value (L _sek / C _sek ) ^1/2 , the quantities L _sek and C _{sek representing} the coil inductance or coil and stray capacitances effective on the secondary side. The value of this dissipation resistance R ₂ will usually be in the range between 10 kΩ and 100 kΩ and thus causes the energy to dissipate rapidly.

The two Zener diodes Z ₁ and Z ₂ are necessary to limit the voltage drop occurring across the dissipation resistor R ₃ , which would otherwise result in a considerable reduction in the ignition energy. For example, an ignition current of 100 mA at a resistor of 50 kΩ, for example, would cause a voltage drop of 5000 V. The Zener voltages of the Zener diodes Z ₁ and Z ₂ are therefore chosen so that there is only a slight reduction in the ignition energy, for example in the amount of 50 V.

Instead of using two Zener diodes Z ₁ and Z ₂ , it is also possible to provide only the Zener diode Z ₂ and to dispense with the Zener diode Z ₁ . However, this would make the swing-out behavior asymmetrical and the swing-out period can be extended somewhat. On the other hand, it would be advantageous that the voltage loss in ignition mode would be less than 1 V.

Since in both cases the Zener diodes are in series with the secondary winding of the ignition coils Tr ₁ ,... Tr ₄ and the ion current measuring resistor R ₁ , their leakage currents have no negative effect in the subsequent ion current measurement.

After the ignition current has decayed, the reference voltage U _ref serving as measurement voltage U _{test is applied} by the inverting differential amplifier 3 to the secondary windings S ₁ ,... S ₄ , which then generates an ion current at the corresponding spark plug.

The inverting differential amplifier 3 converts this ion current into a voltage signal U _ion , which is now fed to the evaluation unit 5 as a measurement signal of the ion current, the evaluation result of which is then forwarded to the control unit 4. The measuring voltage U _test supplied to the secondary windings S ₁ , ..., S _{4 of} the ignition coils Tr ₁ , ..., Tr ₄ , which can be between 5 and 30 V, preferably 20 V, is constant during the entire ion current measurement period. Since the ion current is in the µA range, a differential amplifier 3 with a low input current is used, which is available inexpensively today. The low-impedance provision of this measuring voltage U _{test means} that there is no need to recharge stray capacitances, as can occur in other known systems when exposed to alternating current, such as, for example, with knocking combustion. This advantage is particularly noticeable when several ion measuring sections are operated in parallel, as shown in the figure, since effective stray capacities can then be multiplied.

In order to limit the current flowing into the differential amplifier 3, a further resistor (not shown in the figure) can be provided in the feed line to its inverting input.

2 shows a detail of the circuit diagram of Figure 1 with the inverting amplifier connected as a differential amplifier 3 and the associated two Ableitschaltungszweigen A ₁ and _A2.

The difference from FIG. 1 lies in the wiring of the ignition current measuring resistor R ₂ , which is now arranged on the ground side, namely between the collector of the transistor T and the ground potential. The measurement voltage U _Zünd , which is proportional to the ignition current, is therefore ground-related, which is advantageous for the further use of this measurement signal.

The additional use of a resistor R ₄ connected between the output of the differential amplifier 3 and the base of the transistor T limits the measurement error resulting from a base current to small values.

The ion current signal can be used to detect the knocking of the internal combustion engine and to set up a corresponding knock control by controlling the ignition timing.

Another application is to use the ion current signal both to detect misfires and to detect the camshaft position.

The circuit arrangement according to the invention for ion current measurement can be used not only in transistor ignition systems, as shown in the exemplary embodiment, but also in alternating current ignitions or high-voltage capacitor ignitions.

Claims (10)

Circuit arrangement for ion current measurement in the combustion chamber of an internal combustion engine, consisting of: a) an ignition coil (Tr ₁ , ..., Tr ₄ ) with primary and secondary winding (P ₁ , ..., P ₄ , S ₁ , ..., S ₄ ), b) a) connected to the secondary winding (S _1, ..., S ₄ spark plug (Zk _1, ..., Zk ₄₎ that simultaneously serves as an ion current probe, c) an inverting amplifier (3, R ₁ ) connected to the low potential side of the secondary winding (S ₁ , ..., S ₄ ) of the ignition coil (Tr ₁ , ..., Tr ₄ ) for generating a constant measuring voltage (U _M ) for ion current measurement, characterized by the following feature: d) for deriving the ignition current flowing during the ignition of the spark plug to the ground potential of the circuit arrangement d1) a first discharge circuit branch (A ₁ ) with a semiconductor diode (D ₂ ) is provided and d2) a second diverting circuit branch (A ₂ ) connected in parallel to the inverting amplifier (3, R ₁ ) with a further semiconductor diode (D ₁ ) intended. Circuit arrangement according to Claim 2, characterized in that the second discharge circuit branch (A ₂ ) has an ignition current measuring resistor (R ₂ ) connected in series with the further semiconductor diode (D ₁ ). Circuit arrangement according to Claim 1 or 2, characterized in that the second discharge circuit branch in (A ₂ ) is connected to the ground potential via a semiconductor switch (T) which can be controlled by the output of the inverting amplifier (3, R ₁ ), in particular a transistor. Circuit arrangement according to Claim 3, characterized in that the ignition current measuring resistor (R ₂ ) is arranged in the emitter branch of the transistor (T). Circuit arrangement according to Claim 3, characterized in that the ignition current measuring resistor (R2) is arranged in the collector branch of the transistor (T). Circuit arrangement according to one of the preceding claims, characterized in that a differential amplifier 3 is provided as an inverting amplifier. Circuit arrangement according to Claim 6, characterized in that one input of the differential amplifier (3) is connected to the low potential side of the secondary winding (S ₁ , ..., S ₄ ) of the ignition coil (Tr ₁ , ..., Tr ₄ ) and that another input a reference voltage (U _ref ) is supplied, the value of which corresponds to the measuring voltage (U _test ), and the output of the differential amplifier (3) is connected to the one input via an ion current measuring resistor (R ₁ ). Circuit arrangement according to one of the preceding claims, characterized in that a parallel circuit comprising a dissipation resistor (R ₃ ) and at least one Zener diode (Z ₁ , Z ₂ ) is connected in series with the secondary winding (S ₁ ... S ₄ ). Circuit arrangement according to Claim 8, characterized in that two anti-series Zener diodes (Z ₁ , Z ₂ ) are connected in parallel with the dissipation resistor (R ₂ ). Use of the circuit arrangement according to one of Claims 2 to 9 for an ignition current measurement in that the voltage drop occurring at the ignition current measurement resistor (R ₂ ) serves as a measurement signal for the amount of the ignition current.

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