DE2035493C3 - Ignition device for internal combustion engines - Google Patents

Description

The invention relates to an ignition device according to the preamble of claim 1. One such ignition device is known (DE-PS 12 353).

In the known ignition device, however, control current is applied over a longer period of time than is necessary it passed over the control path of the semiconductor switch. Furthermore, the use of the control current flow has there no defined dependence on the trigger signal 5 of the signal transmitter and finally, the switching threshold, which when the ignition process is triggered by the Trip signal to be overcome is an imprecise location in terms of voltage.

The invention is based on the object, unites; Ignition device of the type mentioned above to train that the aforementioned inadequacies are avoided.

This task is carried out by the in claim 1 marked features solved

Advantageous embodiments of the invention, in particular with regard to the implementation in terms of circuitry, are characterized in the subclaims

The invention is explained below with reference to an exemplary embodiment shown in the drawing

In the illustrated case a thyristor It is provided, which is between its anode A and its cathode K is located in a current branch 12 switching path AK and between its control electrode 5, and its cathode K comprises a control path SK for reversing the switching path AK in the current passing state at the control path SK to apply a control voltage Uc , which takes place as a function of a trigger signal Ua The trigger signal Ua is taken from a trigger winding 13, which belongs to a signal generator 14 based on an inductive principle. which includes a magnet 15 'and an air gap 15 ". To generate the trigger signal Ua , a guide cam made of magnetically conductive material can be moved through the air gap 15" with the aid of a shaft 16' that can be set in rotation.

The circuit arrangement used to control the thyristor 11 contains a rated resistor 17 which, with the trigger winding 13, forms a voltage divider connected to a DC supply voltage Ug. From a between the triggering winding 13 and the design resistance 17 lying Abgnffspunkt 18 connect leads to the input 19 of a likewise at the DC supply voltage Ug lying multivibrator 20. The multivibrator 20 provides in response to the trigger signal Ua at its output 21 a rectangular pulse 22 available, which is differentiated by means of a differentiating element 23. The voltage peak 26 obtained during the differentiation from one of the two edges 24, 25 of the rectangular pulse 22, in the preferred example from the leading edge 24, is used to switch a switching path E3-C3 belonging to a controllable electronic switch 7 * 3 into the current-carrying state. This switching path E3-C3 is in a connection which leads from the positive pole of the DC supply voltage Ug to the control electrode S and from there via the control path SK to a ground line 27 at the negative pole of the DC supply voltage Ug.

The flip-flop 20 works like a Schmitt trigger and contains a first transistor T1 and a second transistor T2. These two transistors T1, T2 are with their emitters El, E2 via a common emitter resistor 28 at one pole of the DC supply voltage Ug, preferably at its negative pole, and with their collectors Cl, C2 each via a collector resistor 29 or 30 at the other Pole of the supply voltage Ug, preferably connected to its positive pole. The collector Cl of the first transistor Ti is also connected to the base B 2 of the second transistor 7 * 2 and the input 19 of the flip-flop 20 through the base B 1 of the first transistor Tl, while the output 21 of the flip-flop 20 through the collector C2 the second transistor T2 shown in the preferred case, the belonging to the flip-flop 20 transistors Tl, T2 are formed by npn transistors and induced as trigger signals Ua in the triggering winding 13 voltage half-waves used, by the DC supply voltage U at the base-emitter path B counteract iE 1 of the first transistor Tl generated bias. In order to achieve this with certainty, the release winding 13 is connected to a series circuit at the tap 18 with a diode 31, which is loaded in the forward direction by the DC supply voltage Ug, and one of the DC supply voltage is shunted to the base-emitter path B iE I belonging to the first transistor T1 reverse-biased diode 32 is provided.

A storage capacitor 33 is used as the differentiating element 23, which is connected at its one terminal 33 'to the collector resistor 30 belonging to the second transistor T2 and at its other terminal 33 "via a control resistor 34 to that pole of the DC supply voltage Ug which is also connected to this collector resistor 30 is, so in the preferred example with the positive pole of the DC supply voltage Ug. For reasons of dimensioning, it is useful to divide the collector resistor 30 belonging to the second transistor T2 into two partial resistors 30 ', 30 ", and the storage capacitor 33 on the common Connect the connection point 30 '"of these two partial resistors 30', 30".

A pnp transistor T3 is used as a controllable electronic switch, with its base B 3 at the connection point 35 between the storage capacitor 33 and the control resistor 34, with its emitter E3 at the positive pole of the DC supply voltage Ug and with its collector C3 via a Resistor 36 is connected to the control electrode S of the thyristor 11. It is advisable to place a resistor 38 connected in parallel with a capacitor 37 in the shunt of the control path SK belonging to the thyristor 11. The resistor 38 ensures a defined potential at the control electrode 5, while the capacitor 37 is used to short-circuit interference voltages. For the last-mentioned reason, a capacitor 44 is also connected in parallel to the base-emitter path Bi-Ei , a capacitor 45 to the base-emitter path B2-E2, and a capacitor 46 connected in parallel to the base-emitter path B3-E3. The base-emitter path B3-E3 also has a diode 47 in its shunt, which is stressed by the DC supply voltage Ug in the reverse direction and which serves to protect this base-emitter path B3-E3 and also to rapidly discharge the storage capacitor 33 after the Emitter-collector path E2-C2 has returned to the non-conductive state

Furthermore, it is useful if the DC supply voltage Ug is tapped at a Zener diode 48, which forms a parallel circuit with a capacitor 49 and a series circuit with a resistor 50, this series circuit being between two lines emanating from the two poles + P and -Peiner direct current source Q 51, 52 and the Zener diode 48 is claimed by the direct current source Q in the reverse direction.

The line 51 contains an operating switch 53, when closed, in addition to the control circuit for the thyristor 11 also an ignition system belonging to an internal combustion engine, not shown, in operation is acceptable.

The above-mentioned ignition system has the series circuit consisting of an ignition capacitor 54 and the primary winding 55 of an ignition transformer 56, which is in the shunt of the switching path AK of the thyristor 11 Ground line 27 connected. Furthermore, in the shunt of the switching path AK of the thyristor 11, the output 59, 60 of a known DC voltage converter 61, which first chops the DC supply voltage Ug applied to its input 62, 63, then steps up the chopped DC voltage and then steps up the stepped up voltage by means of a charging rectifier 64 rectifies and makes it available as high-voltage direct current at the output 59, 60. This high-voltage direct current is finally used to charge the ignition capacitor 54.

The system described has the following mode of operation:

After closing the operating switch 53, the system is live. If, for example, the control cam 16, which is set in rotation by the crankshaft of the internal combustion engine and moved through the air gap 15 ″, induces a trigger signal Ua in the trigger winding 13, which at the first transistor TX negatively biases the base BX with respect to the emitter E 1, the Emitter-collector path El-Cl controlled from the current-conducting state to the current-blocking state. As a result, the second transistor T2 receives positive bias at its base B 2 relative to the emitter E 2 , so that the emitter-collector path E2-C2 of the second transistor T2 goes into the current-carrying state Since the trigger signal Ua is a voltage half-wave and the flip-flop 20 works like a Schmitt trigger, the aforementioned reversal of the emitter-collector paths Fl-Cl, E2-C2 is effected when this voltage half-wave rises on the peak value one through the resistance values of the release winding 13 and the rated value iderstandes 17 exceeds the specified threshold. As soon as this voltage half-wave has exceeded the peak value and again

ι ο falls below this threshold, the emitter-collector path Ei-Ci of the first transistor TX returns to the current-conducting state and, depending on this, the emitter-collector path E2-C2 of the second transistor T2 again into the current-blocking state, because then the base-emitter path B2-E2 of the second transistor T2 is bridged by the emitter-collector path El-Cl of the first transistor TX. Depending on the flip-flop process just described, the rectangular pulse 22, which falls towards the negative potential, arises at the output 21 of the flip-flop circuit 20. The leading edge 24 of this rectangular pulse 22 corresponds to the emitter-collector path E2-C2 of the second transistor T2 becoming conductive. This results in a charge reversal of the storage capacitor 33 and, depending on this, a current flow in the control resistor 34 to the connection point 35. As a result, the base 53 of the transistor T3 is biased negatively with respect to the emitter £ "3 and the emitter-collector path E3-C3 is switched to the current-conducting state the resistor 36 brought positive potential to the control electrode S of the thyristor 11 and there the switching path AK converted into the current-conducting state.The ignition capacitor 54 previously charged from the direct current source 50 via the DC voltage converter 61 is now discharged via this switching path AK and the primary winding 55 of the ignition transformer 56 , whereby a high-voltage surge occurs in the secondary winding 57 of this ignition transformer 56 and, depending on this, an electrical flashover (ignition spark) at the spark plug 58 for the ignition of the fuel-air mixture compressed in the cylinder of the internal combustion engine

The differentiating element 23 is dimensioned so that the voltage peak 26 controls the emitter-collector path E3-C3 belonging to the transistor T3 into the conductive state only as long as it is absolutely necessary for the "switching on of the thyristor 11"

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1 sheet of drawings

Claims (10)

Patent claims: 1. Ignition device for internal combustion engines with a semiconductor switch having a switching path and a control path, with an ignition transformer whose primary winding is directly connected to the switching path of the semiconductor switch and, by reversing this switching path, induces a high-voltage surge in the secondary winding belonging to the ignition transformer as a result of stored ignition energy Control transistor, the emitter-collector path of which is connected to the control path of the semiconductor switch in such a way that the switching path of the semiconductor switch goes into the current-conducting state when the emitter-collector path is conductive and into the blocking state when the emitter-collector path is non-conductive, and with one after Type of an alternating current generator working signal transmitter which has a release winding and there provides release signals for the control processes, characterized in that the release winding (13) has a dimensioning gswiderstand (17) forms a voltage divider (13, 17) lying on a DC supply voltage (LJg) that also connects to the input (19) of a tapping point (18) located between the release winding (13) and the rated resistor (17) also leads to the DC supply voltage (Ug) lying flip-flop (20), which, depending on the trigger signal (LJa) at its output (21), provides a square pulse (22) that also serves as a trigger signal (Ua) in the trigger winding ( 13) occurring voltage half-wave is used, which counteracts the bias voltage caused by the voltage divider (13, 17) at the input (19) of the flip-flop circuit (20) and that finally between the output (21) of the flip-flop circuit (20) and the base (B 3) of the control transistor (T3 ) which is in control connection with the semiconductor switch (11), a differentiating element (23) is provided. 2. Ignition device according to claim 1, characterized in that the flip-flop (20) has a Ί5 first transistor ^ Tl) and a second transistor (T2) , that also these two transistors (Ti, T2) with their emitters (Ei, E2) via a common emitter resistor (28) at one pole of the source for the DC supply voltage (Ug) and with their collectors fCl, C2) each via a collector resistor (29 or 30) at the other pole of the source for the DC supply voltage (Ug) that also the collector (Ci) of the / first transistor (Ti) is connected to the base (B2) 'of the second transistor (T2) and that finally the first transistor (Tl) with its base (B 1) the input (19 ) the flip-flop (20) and the second transistor (T2) with its collector (C2) forms the output (21) of the flip-flop (20) and that the flip-flop (20) works like a Schmitt trigger. 3. Ignition device according to claim 2, characterized in that the transistors (Tl ₁ T2 ) belonging to the trigger circuit (20) are npn ^ transistors, the emitter (E 1, E2) of which via the emitter resistor (28) to the negative pole of the source for the DC supply voltage (Ug) and its collectors ( ¹ Cl, C2) are connected to the positive pole of the source for the DC supply voltage (Ug) via the collector resistors (29,30). 4. Ignition device according to claim 2, characterized in that the read-out winding (13) with one of the DC supply voltage (Ug) in the forward direction claimed diode (31) forms a series circuit at the tap point (18) and the first transistor (Ti) is shunted its base-emitter path (Bi-Ei) has a diode (32) stressed by the DC supply voltage (Ug) in the reverse direction 5. Ignition device according to claim 2, characterized in that a storage capacitor (33) is used as the differentiating element (23), which at its one terminal (33 ') with the collector resistor (30) belonging to the second transistor (T2) and at its the other connection (33 ") is connected via a control resistor (34) to that pole of the source for the DC supply voltage (Ug) at which this collector resistor (30) is also connected. 6. Ignition device according to claim 5, characterized in that the control resistor (34) is connected in parallel to a diode (47) stressed in the reverse direction by the DC supply voltage (Ug) 7. Ignition device according to claim 5, characterized in that the to the second transistor C7 * 2) belonging collector resistor (30) consists of two partial resistors (30 ', 30 ") and the Storage capacitor (33) at the common connection point (30 '") of these two partial resistances (30 ', 30 ") is connected 8. Ignition device according to claim 1 and 5, characterized in that the voltage peak (26) obtained during the differentiation from the leading edge (24) of the rectangular pulse (22) for reversing the emitter-collector path (E3 ) belonging to the control transistor (T3) -C3) is used in the current-carrying state. 9. Ignition device according to claim 2 and 5, characterized in that a pnp transistor is used as the control transistor (T3) which has its base (B 3) on the connection point (35) present between the storage capacitor (33) and control resistor (34) , with its emitter (E3) on the positive pole of the source for the DC supply voltage (Ug) and with its collector CC3), preferably via a resistor (36), on the control electrode (S) of the semiconductor switch (11). 10. Ignition device according to claim 1, characterized in that the DC supply voltage (Ug) is tapped off at a Zener diode (48) which forms a parallel circuit with a capacitor (49) and a series circuit with a resistor (50), this series circuit being between two from the two poles (+ P, —P) of a direct current source (Q) outgoing line runs (51,52) and the Zener diode (48) is stressed by the direct current source (Q) in the reverse direction.