DE2044075B2 - Electronic fuel injection timer - has synchronised bistable stage triggered by rotation of crankshaft and supplying two alternatingly-energised sawtooth wave generators - Google Patents

Abstract

The electronic system adjusts the injection timing in a combustion engine. It comprises a bi-stable stage triggered synchronously with crankshaft rotation and has two outputs feeding into two alternatingly energised sawtooth wave generators. The two generator outputs connect into the inputs of a differential amplifier whose output is fed to a monostable stage via a differentiating circuit. The stage may be triggered by a switch operated by a cam on the crankshaft. The circuit may comprise an input amplifier stage.

Description

The invention relates to an electronic circuit arrangement for shifting the injection time of internal combustion engines with high-voltage ignition by freely selectable crankshaft angles.

Electronic circuit arrangements for shifting the injection timing by crankshaft angle, which depend on the operating parameters of the internal combustion engine are known (DE-AS 15 26 498, DE-OS 61 187). With these known arrangements, however, the point in time of injection can only be adjusted within narrow limits vary. But if, for example, the composition of the exhaust gases from the internal combustion engine is on the test bench The known arrangements are sufficient to be examined as a function of the injection time no longer. In these cases, mechanical injection timing adjustment has hitherto been used. The mechanical process is, however, very cumbersome and particularly in the case of series tests time consuming.

The invention is based on the object of creating a circuit arrangement with which it is possible to supply fuel to the internal combustion engine in any position of the crankshaft, i.e. before and after top dead center. Large angular deviations from top dead center should also be possible.
A particularly simple solution results from

ίο that, according to the invention, two alternately operable sawtooth generators are connected to two outputs of a bistable multivibrator that can be triggered synchronously with the crankshaft revolutions, that the outputs of the sawtooth generators are connected to two inputs of a differential amplifier and that one output of the differential amplifier is connected to a monostable multivibrator via a differentiating element is
Further details and useful developments are described and explained in more detail below with reference to an exemplary embodiment shown in the drawing. It shows

F i g. 1 shows a circuit arrangement in a block diagram, 2 shows a circuit diagram of the circuit arrangement according to FIG. 1 and

3 shows the output pulses of various Stages of the circuit arrangement.

The circuit arrangement according to FIG. 1 contains a switch 11 which sends pulses to a bistable multivibrator 12

ι »gives. A sawtooth generator 13 and 14 is connected to two outputs of the bistable multivibrator 12. the Outputs of the sawtooth generators 13 and 14 are connected to two inputs of a differential amplifier 15. The output of the differential amplifier 15 is about

i ^r > a differentiating element 16 is connected to a monostable multivibrator 17. At the output terminal 18 of the monostable multivibrator 17, pulses delayed by defined crankshaft angles can be picked up.

4 () In the circuit diagram according to FIG. 2 the switch 11 of confirmed by a cam 21 which rotates synchronously with the engine speed of the internal combustion engine. The movable contact of the switch 11 is with a Negative line 20 and the fixed contact of the

■ r> switch 11 via an opposing land 22 with a Plus line 19 connected. From the fixed contact of the switch II, two lead from one capacitor each 23 or 24 and a diode 25 or 26 existing series connections to two inputs of the bistable

w flip-flop 12. The bistable flip-flop 12 consists of known way of two transistors 120, 121. These each have an emitter resistor 123 or 127, one Collector resistor 122 or 126 and a base bleeder resistor 124 or 128. The collector of one

ν-, transistor is coupled to the base of the other transistor via a resistor 125 or 129, respectively. The inputs of the two sawtooth generators 13 and 14 are connected to the base electrodes of the two transistors 120 and 121.

W) The first sawtooth generator 13 includes a Capacitor 132, which is slowly charged via a constant current source 130, 131 and via an electronic Discharge switch 133 can be discharged quickly.

(i ^r i The constant current source consists of a transistor 130 with an emitter resistor 131, which is connected to the negative line 20. A PNP transistor 133 is used as the electronic discharge switch.

det, the emitter of which is connected to the positive line 19

The second sawtooth generator 14 is constructed in the same way like the first sawtooth generator 13, thus contains a constant current source and an electronic one Discharge switch, but in contrast to the first sawtooth generator 13 has several capacitors 142, one of which, depending on the desired delay angle, is connected to the positive line via a selector switch 144 19 can be connected

The voltages on the capacitors of the two sawtooth generators are each fed to an input of the Differential amplifier 15 supplied. The differential amplifier 15 consists of two in a known manner Transistors 156, 157, the emitters of which are connected i> and their collectors are connected to the positive line 19 via a resistor 158 and 159, respectively. To the Decoupling of the two transistors from each other and for temperature compensation can be done in the emitter leads Diodes 154 and 155 may be arranged. The two emitters are connected to a constant current source connected. This consists of a transistor 150 with an emitter resistor 151 and a base voltage divider 152.153. The differentiating element 16 contains, in a known manner, a capacitor 162 to which a 2 ") Amplifier stage from a transistor 160 and a collector resistor 161 is connected upstream. The basis of the Transistor 160 is connected to the collector of transistor 156 in differential amplifier 15.

The negative output pulses of the differential energy J <> des 16 pass through a diode 178 to the input of a monostable multivibrator 17, which consists of the output pulses of the differentiating element 16 forms defined rectangular pulses.

The monostable multivibrator 17 contains a known r> Way two transistors 170, 171 with collector resistors 172, 173. Each of the collectors of one The transistor is .nit coupled to the base of the other transistor, once galvanically via one Resistor 174 and the other time capacitive via a capacitor 175. Between the base of the Transistor 171 and capacitor 175 is used to suppress pulses of undesirable polarity a diode 177 arranged. From the connection point between the capacitor 175 and the diode 177, « a resistor 176 to the positive line 19.

Fi g. 3 shows the time curve of the voltage at different points of the circuit: 3a is the curve of the voltage at the fixed contact of the switch 11, 3b is the output voltage of the bistable flip-flop 12, 3c the voltage on the capacitor 132 in the first sawtooth generator 13, 3d the voltage at a first capacitor 142 in the second sawtooth generator 14, 3e the output voltage of the differential amplifier 15, 3 / "the output voltage of the differential element 16, 3g the output voltage of the monostable multivibrator 17, 3h the voltage at a second capacitor in the second sawtooth generator 14, whose capacitance is smaller than that of the first, and 3 / the output voltage of the monostable multivibrator 17, hi, when the second capacitor is switched on in the second sawtooth generator 14. The mode of operation of the circuit arrangement is explained below with reference to FIGS The initial state conducts the transistor 120 in the bistable multivibrator 12, while the> ■ ·> transistor r 121 is blocked. At time i, the switch 11 emits a negative pulse (see Fig. 3a), which causes the bistable multivibrator 12 to flip over the capacitor 23 and the diode 25. Now the transistor 121 conducts, and the transistor 120 blocks the resistors 126 and 127 now drop voltages, so that the transistors 143 and 130 base current is supplied. The transistor 143 discharges the capacitor 142, as shown in FIG. 3d and 3h is shown at time t \ . At the same time, the constant current source, which consists of the transistor 130 and the emitter resistor 131, begins to charge the capacitor 132 in the first sawtooth generator 13. F i g. 3c shows the linear increase in the voltage on the capacitor 132. In the differential amplifier 15, the transistor 156 now takes over the entire current supplied by the constant current source 150, 151 because its base is kept at positive potential.

At the instant ti , the switch 11 again emits a negative pulse which, via the capacitor 24 and the diode 26, flips the bistable multivibrator 12 back again. The transistors 143 and 130 are thus blocked again. The voltage on the capacitor 132 in the first sawtooth generator 13 does not rise any further (see FIG. 3c). At the same time, the transistor 140 in the second sawtooth generator 14 now conducts and charges the capacitor 142. In the period between h and u , the voltage on the capacitor 132 in the first sawtooth generator 13 is kept at the constant value U ₁ , while the voltage on the capacitor 142 increases linearly, as shown in FIG. 3d. As soon as the voltage on capacitor 142 is more negative than that on capacitor 132, transistor 157 in differential amplifier 15 takes over almost all of the current from constant current source 150, 151. That is the case at the time of it. As a result of the high gain of the two transistors 156 and 157 in the differential amplifier 15, the voltage at the collector of the transistor 156 shifts rapidly in the positive direction at the time U , as shown in FIG. 3e is shown.

The transistor 160 in the differentiating element 16 makes the slope even steeper. The capacitor 162 of the differentiating element 16 emits a negative needle pulse (see FIG. 3F) to the monostable multivibrator 17 via the diode 178. This switches to its unstable state and sends a negative output pulse of a defined length to the output terminal 18. This output pulse is also fed to the transistor 133 in the first sawtooth generator 13. As a result, the capacitor 132 is now discharged again (see FIG. 3c time u).

The sequence of these processes is repeated periodically in the subsequent period. The time-shifted impulse is triggered whenever the voltage on capacitor 142 equals the voltage on capacitor 132 is. The delay time therefore depends on the slope of the sawtooth voltage according to FIG. 3d. By selecting a smaller capacitor using selector switch 144, a steeper slope can be achieved can be achieved as shown in FIG. 3h shows.

F i g. 3i shows an output pulse which is shifted less with respect to the input pulse than the output pulse according to FIG. 3g because a smaller capacitance was used in the second sawtooth generator 14. If the capacitor 132 in the first sawtooth generator 13 were always charged to the same voltage U \, regardless of the speed, then the output pulse according to FIG. 3g or 3i would always be shifted by a constant time relative to the input pulse. However, the output pulse should not be at a constant time, but by a constant fraction

the period can be shifted. This is easily achieved in that the charging voltage U \ is inversely proportional to the speed. Since the capacitor 132 is charged via a constant current source, its charging voltage is proportional to the charging time. The charging time is inversely proportional to the period, since the constant current source 130, 131 is switched off and on by the bistable multivibrator 12.

The requirements placed on the circuit arrangement are thus met. The one at output terminal 18 The output pulse emitted is a fraction of the period duration that can be preselected with the selector switch 144 shifted against the input pulse. The is sufficient for engine tests on the test bench Shown gradual adjustability of the ignition point. It can e.g. B. ten finely graduated capacitors 142 can be used. A stepless shifting of the ignition point is also possible, if the resistor 141 in the constant current source of the second sawtooth generator 14 is adjustable.

You can then roughly set the steps with the selector switch 144 and fine-tune with the resistor 141.
To deliver the control pulses for the described

· ■> The circuit arrangement must have additional contacts as switch 11 in the ignition distributor of the internal combustion engine be attached, as is usual with electronically controlled injection systems. The bistable multivibrator However, 12 halves the frequency of switch 11

κι emitted pulses, so that it is necessary to provide either twice the number of contacts or to use two of the circuit arrangements described. The second option is in general not particularly expensive, since the construction of the circuit according to FIG. 1 largely integrated modules can be used.

The circuit arrangement described can also be used to shift the ignition timing of the Internal combustion engine can be used in tests on the test bench.

For this purpose 3 sheets of drawings

Claims (6)

Patent claims: 1. Electronic circuitry for shifting the injection timing of internal combustion engines with high-voltage ignition by any selectable crankshaft angles, characterized in that that at two outputs of a bistable flip-flop (12) which can be triggered synchronously with the crankshaft revolutions, two alternately operable sawtooth generators (13, 14) are connected that the outputs of the sawtooth generators (13, 14) are connected to two inputs of a differential amplifier and that one output of the differential amplifier (15) via a differentiating element (16) to a monostable multivibrator (17) connected 2. Arrangement according to claim 1, characterized in that for triggering the bistable flip-flop (12) at least one switch (11) is provided, which is mechanically connected to the crankshaft by a switch Cam (21) can be actuated. 3. Arrangement according to claim 1 or 2, characterized in that the differentiating element (16) contains at least one amplifier stage (160, 161) on the input side. 4. Arrangement according to one of claims 1 to 3, characterized in that the first sawtooth generator (13) a constant current source (130, 131), a capacitor (132) and an electronic one Load switch (133), the control electrode of which is connected to the output of the monostable multivibrator (17) is, contains. 5. Arrangement according to one of claims 1 to 4, characterized in that the second sawtooth generator (14) a constant current source (140, 141) and several by a selector switch (144) to the Constant current source excludable capacitors and an electronic discharge switch (143) contains. 6. Arrangement according to claim 5, characterized in that the control electrode of the electronic Discharge switch (143) can be actuated by a transistor (121) in the bistable flip-flop (12) and that the transistor (121) also the constant current source (130, 131) in the first sawtooth generator (13) drives.