DE3321766A1 - IGNITION SYSTEM FOR AN INTERNAL COMBUSTION ENGINE - Google Patents

Description

18733 "

2U.5.1983 Li / Wl

ROBERT BOSCH GMBH, 7OOO Stuttgart 1

State of the art ignition system for an internal combustion engine

The invention is based on an ignition system according to the preamble of the main claim. It was (in the DE patent application P 32 15 728.2) already has one in this Direction of the ignition system proposed, however, in the case of the on the crankshaft of the internal combustion engine related angle of rotation sections over which the duration of the current flow in the primary winding on the one hand and the Interruption of this current flow on the other hand, are essentially constant. This has the consequence that at low speeds of the internal combustion engine more energy is stored in the ignition coil than that is necessary for an effective ignition spark and that thereby harmful heating of the ignition coil can occur. In contrast, at higher speeds of the internal combustion engine the duration of the current flow in the primary winding is too short to maintain the fuel-air mixture in the cylinder to be able to ignite the internal combustion engine with certainty.

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Advantages of the invention

In the ignition system according to the invention by application the characterizing measures of the main claim with a relatively simple and easily integrated structure of the electrical Circuit arrangement avoided the above-mentioned inadequacies.

Advantageous measures for implementing the invention are specified in the subclaims.

drawing

An embodiment of the invention is shown in the drawing and in the following description in more detail explained. FIG. 1 shows the circuit diagram of an ignition system according to the invention and FIG. 2 shows the Curve of the AC voltage signal used for control there in the voltage (U) -time (t) diagram.

Description of the embodiment

The ignition system shown in Figure 1 is intended for an internal combustion engine, not shown, of a motor vehicle, also not shown. This ignition system is fed from a direct current source 1, which can be the battery of the motor vehicle. At the power source 1, a line 2 connected to ground extends from the negative pole and a supply line k containing an operating switch 3 extends from the positive pole. The supply line h is the starting point for a connection, which is initially via the primary winding 5 of an ignition coil 6 and then via an electronic breaker 7 to the ground line

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2 leads. The breaker 7 is through the emitter-collector path of an (npn) transistor 8, the emitter of the ground line 2 facing. The one to the ignition coil β belonging secondary winding 9 is with its one winding end to the between the primary winding 5 and the Interrupter 8 existing connection and with its other winding end via at least one spark plug 10 Ground connected.

In addition, the supply line k is the starting point for a connection which leads first via a polarity reversal protection diode 11 and then via a current limiting resistor 12 to a circuit point 13, the anode of the polarity reversal protection diode 11 facing the supply line h. The circuit point 13 is connected to the ground line 2 via a buffer capacitor 1 k. The buffer capacitor Ii + has a Zener diode 15 in its shunt, the anode of which faces the ground line 2. The cathode of the reverse polarity protection diode 11 is connected via a resistor 16 to the collector of an (npn) transistor 17 and at the same time to the base of the transistor 8 forming the interrupter 7. The transistor 17 is connected to the ground line 2 directly at its emitter and at its base via a resistor 18. In addition, the base of the transistor 17 is connected via a resistor 19 to the output of a first threshold switch 20 which is formed by an operational amplifier 21. The operational amplifier 21 is connected with its non-inverting input via a resistor 22 to the junction of two resistors 23 ₃ 2k, which are a voltage divider between the junction 13 and the ground line 2 and which also provide a potential at their junction that

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corresponds to approximately half the voltage of the power source 1. The inverting input of the operational amplifier 21. is connected via a resistor 25 to the connection terminal 26 of an alternating current generator 27, the other connection terminal 28 of which is connected to the connection point of the resistors 23, 2k .

The one at the operational amplifier 21 between the output and resistor 29 connected to the non-inverting input is used to determine the switching hysteresis Ub-Ug, whereas with the help of the between the inverting input and the Circuit branch 30 lying circuit point 13 shows the position of the switching hysteresis Ub-Ug in the voltage (U) -time (t) diagram (Figure 2) is determined.

The alternating current generator 27 is connected upstream of a second threshold value switch 31 in such a way that the two threshold value switches 20, 31 are shunted to one another on the input side. The second threshold switch 31 is also formed by an operational amplifier, which has the reference number 32. This operational amplifier 32 is connected with its inverting input via a resistor 33 to the connection terminal 26 of the alternator 27 and with its non-inverting input via a resistor 3 ^ · to the connection point between the resistors 23 ₅ 2U. The resistor 35 located at the operational amplifier 32 between the output and the non-inverting input is used to determine the switching hysteresis Uc-Uh, while the resistor 36 located between the inverting input and the ground line 2 determines the position of the hysteresis Uc-Uh in the voltage (U ) Time (t) diagram (Figure 2) is determined.

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Both operational amplifiers 21, 32 are connected to ground as well as to circuit point 13 via a line 37. The output of the operational amplifier 32 is connected to the cathode of a blocking diode 38 and via a resistor 39 to the circuit point 13, the anode of the blocking diode 38 also being connected to the circuit point 13 via a resistor kO. In addition, the anode of the blocking diode 38 is connected via a control capacitor ^ I to the ground line 2 and via a resistor k2 to the base of an (npn) transistor ^ 3 a-n, the emitter of which is connected to the ground line 2 and its collector via a Resistance hk is at the node. The base of the transistor k3 is also connected to the ground line 2 via the parallel connection of a resistor k-5 and a diode h6 , the anode of this diode k6 being connected to the ground line 2. The circuit elements Uo, k 1, 1 + 2, ^ 3 are essential components of a timing element hj.

Sin further (npn transistor kQ is connected at its base to the collector of the transistor hl, at its emitter to the ground line 2 and at its collector via a resistor hg to the circuit point 13. In addition, the collector of the transistor ^ 8 is connected to the anode a diode 50, the cathode of which is connected to the base of the transistor 17.

The control capacitor hl is also in a charging circuit connected to the alternating current generator 27, which runs via the resistor 2H, a diode 51 and a resistor 52.

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In the circuit branch 30, a voltage divider consisting of two resistors 53, 5U is provided lying between these two resistors 53, 5 ^ Tap point 55 with the cathode one on the ground line 2 lying Zener diode 56 is connected. The one on his one terminal connected to the node 13 voltage divider 53, 5 ^ has at its other terminal with the emitter of a (pnp) control transistor 57 connection, which is connected with its collector to the inverting input of the operational amplifier 21. The control transistor 57 is connected as an emitter follower by its base through a resistor 58 to that of the node 13 facing away from the connection of the voltage divider 53, 5U and via a resistor 59 niit the cathode of a Zener diode ÖO connection, the anode of which has a blocking diode 61 is connected to the terminal of the control capacitor U1 facing away from the ground line 2. Included the cathode of the blocking diode 61 is the control capacitor Ui facing.

The ignition system just described has the following mode of operation:

In the voltage (U) -time (t) diagram of Figure 2 is based on the AC voltage signal Ua supplied by the alternator 27 shows that the switch-on threshold Ub of the first threshold switch 20 and the switch-on threshold Uc of the second threshold switch 31 is initially at least almost have the same size and have the same polarity with respect to the zero value 0 of the alternating voltage signal Ua .auch with curve values ₉ , namely positive polarity. The curve section Ue, which precedes the peak value Ud, thus finds itself

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Switching on the threshold value switch 20, 31 and this Curve segment Uf following peak value Ud for switching off the threshold switch 20, .31 use. The off switching threshold Ug of the first threshold switch 20 in With respect to the zero value 0 of the alternating voltage signal Ua at curve values lie the opposite polarity, in the present case have negative polarity compared to those curve values at which the switch-on threshold Ub this threshold switch 20 is located. In addition, the switch-off threshold Uh of the second threshold switch 31 with respect to the zero value 0 of the AC voltage signal Ua lie at curve values that have the same polarity as those curve values for which the switch-on threshold Uc of this threshold value 31 lies.

If the switch-on threshold Ub the first threshold switch 20 and the switch-on threshold Uc of the second threshold switch 31 is reached these threshold switches 20, 31 are switched on, i.e. that make their outputs available almost at ground potential. Depending on this, the emitter-collector path of the transistor 17 is in the blocking state and the emitter-collector path of the transistor 8 forming the interrupter 7 is controlled in the current conducting state. Thus, the Primary winding 5 conducts current and 6 ignition energy in the ignition coil saved for the next ignition process.

If the AC voltage signal Ua falls below the switch-off threshold Uh of the second threshold switch 31, this threshold switch is switched off and its output is raised to positive potential. As a result, a change in the state of charge occurs on the control capacitor kl , namely

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via the reverse polarity protection diode 11, the resistor 12 and the resistor kO. This change in the state of charge has the effect that transistor h-3 initially remains in the blocking state at its emitter-collector path.

The AC voltage signal is then used during normal operation of the internal combustion engine Finally, among other things, the switch-off threshold Ug of the first threshold switch 20 falls below, so that then through the positive potential made available there at the output, the emitter-collector path of the transistor 17 in the current conduction state and the emitter-collector path of the transistor 8, that is to say the interrupter 7j, is brought into the blocking state. The current conducted through the primary winding 5 is interrupted and a high-voltage surge is induced in the secondary winding 9, which causes an electrical flashover (ignition spark) on the spark plug 10.

Finally, in the normal case, the unstable time of the time element hf set at time ti also expires at time t2, which means that the control voltage on transistor k3 is sufficient for the passage of current on the associated emitter-collector path and, depending on this, the emitter The collector path of the transistor kQ becomes non-conductive, whereupon the current conduction state at the emitter-collector path of the transistor 17 and the blocking state at the interrupter 7 can also be ensured via the resistor ^ 9 and the diode 50.

In the event that the internal combustion engine "stalled" i.e. is brought to a standstill by overload, and the AC voltage signal Ua the switch-off threshold Ug des has not yet reached the first threshold value switch 20,

'so takes place over the aforementioned, the circuit elements k-9, 50 containing connection, the reversal of the Transi stor 17 belonging to the emitter-collector path in the current state and depending on the switching off of the interrupter J. It is thus ensured here that with With the ignition system switched on and the internal combustion engine not in operation, a sustained flow of current in the primary winding 5 is not possible.

Because the unstable time of the timing element U7 only extends over the period between ti and t2, the capacitor kj can have a relatively small capacitance value and can easily be integrated when the ignition system is designed as an integrated circuit.

In the present case, the control capacitor now finds 1 * 1 in addition to its function in the timer ^ 7 in addition to Relocation of the switch-on threshold Ub of the first threshold switch 20 use, namely according to curve values with greater distance from the peak value Ud after the internal combustion engine has reached a minimum speed and continues to rise. This is done by connecting the control capacitor to the terminal facing away from the ground line 2 U1 the negative potential rises with increasing speed and the zener diode when the minimum speed is reached 6o breaks through. Now the conductivity at the emitter-collector path decreases with increasing speed of the control transistor 57, whereupon the bias voltage on the inverting input of the operational amplifier 21 is changed in such a way that the switching threshold Ub itself with increasing speed further and further away from the peak value Ud. This results in the at high speeds Internal combustion engine an automatic enlargement of the

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the angle of rotation section related to the crankshaft, over which the power supply of the primary winding 5 extends. It follows that even at high speed of the internal combustion engine an amount of ignition energy can be made available which is sufficient for an effective ignition spark.

With the help of the Zener diode 56, a fixed reference potential is created at the tapping point 55. The diode 61 keeps disruptive influences away from the control transistor 57 which can be exerted via the resistor kO. The diode 38 ensures that the potential at the output of the operational amplifier 32 is decoupled from the potential at the control capacitor kl and thus the control capacitor k 1 can not have a disruptive influence on the switching thresholds Uc, Uh.

The fact that the control capacitor kl influence is exerted on the control transistor 57 with a negative potential, results in a very satisfactory shifting of the switching threshold Ub of the first threshold switch 20, while at the same time having an unfavorable influence on the switching off of the current carried through the primary winding 5 and thus on the ignition timing is avoided.

Claims (1)

2U.5 · 1983 Li / Wl ROBERT BOSCH GMBH, TOOO Stuttgart 1 Expectations M.) Ignition system for an internal combustion engine with a switched on State of a first threshold switch Current-carrying electronic interrupter, with an ignition coil, the primary winding of which is connected to the interrupter forms a series circuit that can be connected to a direct current source, and with a series circuit connected upstream of the threshold value switch AC generator for outputting an AC voltage signal from the one in relation to the curve shape in the stress-time diagram, that of a peak value preceding curve section for switching on the quick value switch and the curve section following this peak value to turn off the threshold switch is used, with the alternator still a second threshold switch is connected upstream and both threshold switches on the input side in shunt lie to each other, furthermore, in the normal case, the reversal of the electronic interrupter to the blocked state takes place by the first threshold switch and if this reversal does not occur, the interrupter by the second threshold switch in connection with a one Control capacitor containing timing element impermeable to current is made and finally with respect to the zero value of the AC voltage signal first of all the switch-on threshold and switch-off threshold of the first threshold value switch for curve values that are opposite Polarity, whereas the switch-on threshold and «18733 the switch-off threshold of the second threshold switch lie at curve vertices which have the same polarity how those curve values had at which the switching threshold of the first threshold value switch lies, thereby characterized in that the control capacitor (Ui) besides its function in the timer (1 * 7) in addition to the Relocation of the switch-on threshold (Ub) of the first threshold switch (20) is used, namely according to curve values with a greater distance from the peak value (Ud) after the internal combustion engine has exceeded a minimum speed. 2. Ignition system according to claim 1, characterized in that the control capacitor ( k 1) is located in a charging circuit ( 2h, 51, 52) connected to the alternating current generator (27). 3. Ignition system according to claim 1 and 2, characterized in that the control capacitor (U1) has a connection at the negative pole of the direct current source (1) and receives positive charging potential at this connection, that the first threshold switch (20) also has an operational amplifier (21) is, which can be connected with its inverting input via the emitter-collector path of a control transistor (57) to the positive pole of the direct current source (1), and that finally the base of the control transistor (57) facing away from the negative pole of the direct current source (1) Connection of the control capacitor (kl) has connection. H. Ignition system according to Claim 3, characterized in that the control transistor (57) is connected as an emitter follower. »1871 5. Ignition system according to claim 3 _9, characterized in that in the connection between the base of the control transistor (57) and the control capacitor (Hl) there is a circuit element (60) which only allows current to pass after the applied voltage has exceeded a certain value .