DE2018335C3 - Electromagnetic fuel injection control system for internal combustion engines - Google Patents

Description

tive charging and discharging circuit with a third and logic circuitry receiving the second control pulse for combining both

The invention relates to an electromagnetic control pulse to a signal and to a table Fuel injection control system for 45 ses signal responsive circuit to open and engines with injection valves, which by first discharging a first capacitor and generating and second of a first and second monostable a corresponding output signal and through len flip-flop coming control pulses can be actuated a second charging and discharging circuit, with a are, wherein the flip-flops are based on the speed of the fourth mono internal combustion engine controlled by the first control pulse corresponding impulses to 5 ° stable trigger stage to generate a fourth controllable are, the first control pulse a changing pulse responsive circuit for controlling the has borrowed pulse length and the switching time of the second charging and discharging process of a second condenser flip-flop can be controlled by the first control pulse. tors to generate the first control pulse be-on such injection control system is e.g. B. from the influencing pulse signal, the length of which is in dependent-BE-PS 7 07 060 known that consists of two monostable 55 gigkeit of the fourth control pulse and its ampli flip-flops is, the first monostable multivibrator tude depending on the aforementioned output Has transformer whose transmission signal can be changed.

properties by shifting its iron core in the circuit arrangement according to the invention are changeable. The iron core is dependent on an additional third and fourth monostable ability of the negative pressure in the intake line of the 60 tilting stages provided with two internal and external combustion engines adjusted. On the other hand, the charging circuits will work together in such a way that in The first monostable multivibrator is controlled by the engine speed as a function of the pulse length of the pulses corresponding to the control. With this pulse for the injection valves, another known control system, the pulse is generated that corresponds to the primary output pulse the first flip-flop as well as the 65 development of the transformer in the first monosta output pulse the voltage present in the second flip-flop to the auxiliary flip-flop is influenced in this way the injection valves are used, so that the infeed that also the Andenirtf; s speed with which injection valve is open for a period of time that corresponds to the period for opening the injection valves.

changes, with increasing dwell time for the injection nozzles also increases. However, such an increasing rate of change is one To achieve opümalere metering of the amount of fuel to be injected into the internal combustion engine.

Further advantages of the invention and these further developing features emerge from the following Description of an embodiment based on the drawing. In it shows

1 shows a fuel demand-speed diagram for different suction pipe pressures,

Fig. 2 is a circuit diagram of an electromagnetic fuel injection system according to the invention and

3 shows the time course of voltage forms or wave trains at different points the circuit according to FIG. 2.

The electromagnetic fuel injection control system according to the invention produces a high output torque by fully injecting the fuel into the internal combustion engine at a speed above point b shown in FIG in terms of fuel consumption, exhaust gas quality, idling, etc. as a function of changes in the intake manifold pressure P at a speed of the internal combustion engine below point b .

In the case of the FIG. 2, where a diagram of an electromagnetic fuel injection system with the compensation circuit according to the invention is shown, the sections A, B and C consist of individual circuits for supplying excitation pulses to an electromagnetic fuel injection valve 38. The first section A is a monostable multivibrator , which is composed of a pulse-generating circuit or a pulse generator circuit with a cam disk 1 with two lugs or cams and an interrupter 2 and has transistors 16, 32 and a transformer T , while the second section B is another monostable multivibrator with transistors 24, 31 , 33 and the third section C is an output amplifier with a transistor 37 and an injection valve 38 which has an electromagnetic coil L.

The function of section A begins with the ON-OFF activity of a cam disk 1 actuated by an internal combustion engine. When it is actuated, the switch shown in FIG. Junction shown U 3 ₀ a rectangular pulse waveform generated by the wave U ₀ in F i g. 3 is shown, which shows the voltage forms or wave trains occurring at various points in the circuit according to FIG. Then the wave train U ₀ is differentiated by differential acting elements, consisting of capacitor 4 and resistor 7, and negative trigger or. Control pulses are sent to a connection point 6. Of these pulses, the diode 8 sends negative pulses to the connection point U ₁ . These trigger pulses are shown in FIG. 3 indicated with the wave train U _1. As soon as a negative pulse reaches the junction U ₁ , the transistor 16 blocks, and consequently the transistor 23 becomes conductive. Current therefore flows in the primary winding 20 of the transformer T, with an exponential increase in accordance with the time constant determined by the inductance of the winding 20 and the resistor 22.

until the current reaches its maximum value determined by the resistance values of the winding 20 and the resistor 22. During this rise, an exponentially decreasing voltage is induced in the secondary winding 19, and a negative voltage is maintained at the base of the transistor 16. As soon as the induced voltage decreases, the voltage of the base of transistor 16 becomes positive and this consequently becomes conductive, but transistor 23 becomes non-conductive, thus completing an operation. up to the point in time at which the same base becomes positive, corresponds to the pulse duration or width Γ of the wave train t / 20. The core 21 of the transformer T can assume its position according to the pressure in the intake pipe of the internal combustion engine, so that the output _{pulse duration T 1} of the pulse coming from this monostable multivibrator is related to the mentioned division ratio and the negative pressure of the intake pipe U ₂ connected via a resistor 36 to the base of the transistor 37 i st, the output pulses reach its base. The transistor 37 is therefore conductive when each pulse with a pulse duration T ₁ arrives during this pulse duration, and the injection valve 38 is kept open during this pulse duration.

The voltage of the base of the transistor 24 in section B is positive for the positive pulse duration 7 ″ of the pulse U _2. This voltage lies approximately in the middle between that of the negative conductor 86 and that of the positive conductor 80 T ₁ of the positive pulse U ₂ is conductive, its collector current flowing into the capacitor 26 and loads it on linear. During charging, thus increasing the voltage across capacitor 26 linearly what g with the Wellenzua U., in F i. 3 As soon as the positive pulse duration T _{1 has} expired and the transistor 16 becomes conductive again, the base of the transistor 24 becomes strongly negative with respect to the positive conductor 87, so that this transistor blocks and the transistors 31, 24 and 16. The voltage drop of the capacitor which occurs due to this discharge is shown by the sawtooth wave train C / ₄ in FIG At the end of the discharge, the point) U _{1 is} negative, so that the diode 30 maintains a negative voltage at the base of the transistor 33 and keeps this transistor in the non-conductive state until the capacitor 26 is completely discharged. Then, during the discharge of the capacitor 26, a positive pulse induced at point U ₃ , to which the collector of transistor 33 is connected. Due to the positive pulse of the waveform U. the base of the transistor 37 becomes positive via the resistor 35 and makes this transistor 37 _{conductive for the pulse duration T 2 in} order to excite the coil L of the valve 38. Since the base of the transistor 37 is now connected to the point U ₂ in section A , the valve 38 also remains open during the pulse duration T ₁ , and because the pulse duration T, immediately follows the pulse duration T ₁ , there is a valve of reflection the pulse duration Γ, until the end

the pulse duration T ₂ kept open continuously. Let the total duration be denoted _{by T 0.} It is the sum of the pulse duration T _{1 of} the pulse U _s and the pulse duration T ₂ at point U. in the monostable circuit B, ie T ₀ = T ^ T ₂ , as shown by the wave train U ₆ in FIG. Since the charging voltage of the capacitor 26 is proportional to the pulse duration T _x , the charging time for this voltage is also proportional to the pulse duration T ₁ , so that due to the pulse duration T ₂ at the connection point U ₅ , using the pressure in the intake pipe as a parameter, a compensation effect described below is achieved.

With the in F i g. 2 inventive equalization circuits D and E i «; t the base of a transistor 45 is connected to the negative conductor 86 via a resistor 42 and also to the cathode of a diode 43, the anode of which is connected to the positive conductor 87 via a resistor 44 and also via a Series arrangement of capacitor 14 and resistor 40 is connected to the collector of transistor 16. The emitter of this transistor is connected to the negative conductor 86 and the collector is connected to the positive conductor 87 via the connection point U _{7 and the resistor 46.} The base of the transistor 49 is connected via a resistor 47 to the negative conductor 86 and also via a resistor 48 to the connection point U ₁ ; its emitter is directly connected to the negative conductor 86 and the collector is connected to the positive conductor 87 _{via the connection point t / c and a resistor 50.} The base of a transistor 53 is connected via a resistor 51 to the collector (point U.) of the transistor 33 and via a resistor 52 also to the collector of the transistor 49, its emitter is directly connected to the negative Leitei 86 and the collector is connected to the Point U ₉ and a resistor 54 connected to the positive conductor 87. The base of a transistor 57 is connected to the negative conductor 86 via a resistor 55 and also to the collector (point U ₉ ) of the transistor 53 via a resistor 56; the emitter is directly connected to the negative conductor 86 and the collector is connected _{to the positive conductor 87 via the junction point J7, o} and a resistor 58 and also to the cathode of the diode 66 via a resistor 65. The base of a transistor 61 is connected via the resistor 59 to the collector (point U ₉ ) of the transistor 53 and via a resistor 60 also to the collector (point U _B ) of the transistor 49; the emitter is directly connected to the negative conductor 86 and the collector via the point U _n and a resistor 62 to the positive conductor 87 and via a diode 63 also to the anode of the diode 66. At the connection point U j, between the diode 63 and the diode 66 on the one hand and on the negative conductor 86 on the other hand, a capacitor 64 is provided. The base of a transistor 68 is connected to the anode (point U J of the diode 66; the emitter is connected via a resistor 67 to the negative conductor 86 and the collector is connected directly to the positive conductor 87. Through the above circuit elements and connections, a Formed charge-discharge network (Section D).

"The base of a transistor 74 is connected via a resistor 71 to the negative conductor 86 and also to the cathode of a diode 72, the anode of which is connected to the collector (point U ₂ ) of the transistor 16 and via a series connection of capacitor 70 and resistor 69 a resistor 73 is also connected to the positive conductor 87, the emitter is connected directly to the negative conductor 86 and the collector is connected via the junction point U ₁₃ and a resistor 75 to the positive conductor 87. The base of a transistor 78 is connected to the negative Conductor 86 through a resistor 76

ίο and connected via a resistor 77 to the collector (connection point U ₁₃ ) of the transistor 74; the emitter is directly connected to the negative conductor 86, and the collector is connected via the point U _n and a resistor 79 to the positive

Conductor and also at the cathode of a diode 80. The base of a transistor 83 is connected via the point U ₁₅ and a capacitor 81 to the negative conductor 86 and via a resistor 82 to the anode of the diode 80 and to the emitter of the transistor 68; the emitter is connected to the secondary winding 19 of the transformer T via a resistor 84 and the connection point 85 and the collector is connected to the positive conductor 87. The circuits with transistors 74, 78 and 83

represent a further charge-discharge network forming section .E represent.

Sections D and E above operate in conjunction with the monostable multivibrators A and B in the following manner. The capacitor 41 becomes

Charged via the resistor 40 with the positive pulse of the waveform U., (Fig. 3). The transistor 45 remains blocked for the pulse duration T _{1 of this pulse.} As soon as the voltage at point L ' ₂ drops after the end of the pulse duration T ₁ , it discharges

the capacitor 41 via the resistors 40, 41 and holds the transistor 45 in its non-conductive state, until it is completely discharged. During the discharge, the diode 43 is non-conductive and therefore holds a negative voltage at the base of the transi-

stors 45 upright. The duration of this non-conductive state is roughly determined by the ohmic size or the value of the resistors 40, 44 and the capacitor 41 is determined. For the duration of the blocking state the collector of transistor 45 with positive

ver voltage T ₃ supplied (U ₇ in Fig. 3), that is, the positive pulse with the pulse duration T ₅ corresponds to the duration of the non-conductive state. It should be noted here that the pulse duration T ₃ immediately follows the pulse duration T _1. The change in the

The vector voltage of the transistor 45 is transmitted through the divider resistors 47, 48 to the base of the transistor 49, so that the pulse shape U _{7 appears} inverted in terms of voltage (U ₈ in FIG. 3) at the collector of the transistor 49. As U _a in Fig. 3

The reverse wave train shown is applied via the resistor 52 to the base of the transistor 53, which is also _{fed the waveform t / s} via the resistor 51 from section C. Since transistor 51 is an npn transistor, it is only

non-conductive when both wave trains U _{s down} .
at the same time the voltage of the negative conductor
ben, ie during the pulse duration T ₄ . The TrafiS ¹ , disturb 53 generates a pulse of the waveform U _r afc on its collector. The pulse U ₉ passes through «bold

Resistor 56 to transistor 57. A signaling takes place through transistor 57 so that the reversed pulse occurs at its collector (pulse duration T ₄ 'of waveform IZ ₁₀ in FIG. 3)

Pulse duration T ₄ negative the voltage at transistor 57, so the charge on capacitor 64 is reduced.

The capacitor 64 is charged as follows. Since the base of the transistor 61 receives two pulses, namely U ₉ via the resistor 59 from the transistor 53 and U _B via the resistor 60 from the transistor 49, the npn transistor 61 only blocks when the two pulses have a negative polarity at the same time have, ie during the pulse duration 7 ",. The transistor 61 generates a pulse at its collector (i / ,, in Fig. 3). The pulse U ₁₁ with the pulse duration T ₅ is fed through the diode 63 to the point U _12, which lies on the cathode side of the diode 63. This is conductive when the voltage of the pulse U _{n is} higher than the voltage of the point U ₁₂ , and then charges the capacitor 64. For the pulse duration T ₄ 'of the pulse U ₁₀ discharges the capacitor is connected in series with diode 66 and resistor 65 and also across the collector-emitter of transistor 57. Diode 66 becomes non-conductive when the transistor blocks, the voltage of its collector increases and becomes the same as that of positive conductor 87. Exactly i At the moment in which this equality is reached, the discharge on the capacitor 64 ceases. The increase in voltage at the point U ₁₂ is abrupt, but their decrease gradually, in the form of the wave train U ₁ in Figure 3. Thus, once the intake pipe pressure drops -. Which is not shown - and thus the pulse duration T ₁ of the through monostable circuit A is reduced, the voltage of the capacitor 26 decreases, so that the trailing edge of the pulse duration T, of the positive pulse generated by the second monostable circuit B to that shown in waveform U ₅ (Fig. 3) shown dashed Line is returned. Since the pulse length Τ _Λ 'of the pulse U _R remains unchanged, the charging time T ₅ for the capacitor 64 decreases, while the discharging time T ₄ ' increases. Due to this increase in the discharge time, the voltage at point U ₁₂ approaches the voltage of the negative conductor after the discharge has ended, as shown by dashed lines in waveform U ₁₂ (FIG. 3).

The time constant for the discharge can be changed by changing the resistance of the resistor 65 and the capacitance of the capacitor 64. The voltage at point U ₁₂ is applied to the base of transistor 68, so that a pulse _{similar to the pulse at point U 12} appears on the collector of this transistor and passes through resistor 82 to capacitor 81, the resistance of which is relatively high, to produce a steep exponential charging characteristic with a large time constant. On the other hand, the pulse waveform U ₁₃ , the pulse duration of which is constant, is generated by a multivibrator circuit consisting of the capacitor 70 and the transistor 74.The pulse waveform U ₁₃ follows the positive pulse duration T _{1 of} the pulse U ₂ (Fig. 3) and becomes the base of the transistor 78 supplied to receive an inverted pulse U ₁₄ (FIG. 3) at the collector of transistor 78. It should be noted that the pulse U ₁₄ the pulse U ₁₈ with Ausnähme of the reversed polarity is equal to Since the collector of Transistors78 is connected to the cathode of the diode 80 to the point U _15, no charging current flows into the capacitor 81 currencies

the time period T ₆ 'which the pulse width de pulse U, and end ₁₄ for which the voltage de point U that _n of the negative conductor equals If the pulse U _{14 n} at the point U is positive, de capacitor 81 is exponen through the resistor 82 tially charged and its voltage increases towards the emitter potential of the transistor »üj. The exponentially increasing voltage of the point U ₁₅ due to this charging by the pulse U ₁₅ is ii

F i g. 3 shown. The peak value of the pulse with duration T ₁ is determined by the load voltage of the waveform U ₁₃ , which depends on the intake pipe pressure, and the pulse width T , which is dependent on the speed of the internal combustion engine (rpm). The through-conductivity of the transistor 83 via the emitter and collector wire is changed by this variable pulse of the wave form U ₁₅ . As mentioned above, the pulse duration T _{1 can be} changed by changing the voltage de:

"Connection point 85 in section A is changed. This means that due to the fact that the emitter of transistor 83 is connected to point 85 and as an element with variable conductance connected in parallel with resistor 11

»5 works, the pulse width T _{1 also} varies when the conductance is changed. The change in the pulse duration T ₁ also affects the pulse duration T ₁ . As a result, the energization pulse duration i T ₀ varies with the engine speed (rpm) and the intake manifold pressure. If the intake pipe pressure is low, the charging voltage of the capacitor 81 is also low, as shown by the dashed line in the waveform U ₁ (FIG. 3), while the resistance across the emitter and collector of the transistor 83 is high. This variable resistance is little influenced by changes in the speed of the internal combustion engine, so that the voltage at point 85 is also little influenced by changes in the speed. It is assumed that the speed of the internal combustion engine increases during operation from the range of low speeds in the direction of the range of high speeds and that the speed exceeds the assumed point b of 4000 rpm.

At this speed, the charging time and the charging voltage of the capacitor 81 become zero, so that the internal resistance of the transistor 83 increases to a maximum and the voltage at point 85 drops to a minimum. Even with a further increase in the speed of the internal combustion engine, the voltage of the capacitor 81 remains equal to zero. In other words, the capacitor voltage is zero at a speed above 4000 rpm.
In the event that the intake manifold pressure is high, the capacitor voltage is also high, as indicated by solid lines in wave train U _15. Due to the variable Leif value of transistor 83, the high charge voltage rank of capacitor 81 leads to a high voltage at point 85, this voltage largely depending on the speed of the internal combustion engine. At speeds above 4000 rpm, the charged voltage is the same - as above Zero. This type of influencing of the voltage at point 85 obviously meets the requirements which are shown in FIG. 1 with curves drawn in solid lines. The modified secondary characteristic obtained in this way can be changed

609432/294

by changing the setting of the variable resistor 84 and thus the pulse duration T ₀ . By changing the setting of the resistor 65, the discharge characteristics of the capacitor 64 and thus the gradient of the AtIt curve is changed, which otherwise depends exclusively on the intake manifold vacuum, so that the desired ratio of the change in the time to energize the valve is guaranteed, ie

Δ t _i lt _l < Δ I ₂ It ₂ < Δ t ₃ / t ₃ .

In the above description, the pulse T. (Fig. 3) has been shown for the sake of simplicity

T ₂ and

broad

explained the same way. As far as the pulse duration T _{5 is} concerned, this pulse was explained during the charging of the capacitor 64 with an exponentially increasing voltage wave train. If the capacitor 64 is charged from the point U ₅ (FIG. 2) with the positive pulse of the pulse duration T ₂ , the

10

increases exponentially, the result is not a perfect square waveform. Such an undefined, running square wave train possibly brings a small time gap between the end of the pulse duration 7 "and the beginning of the pulse duration T ₂ at the time of the generation of the pulse duration 7" ₀ (-Γ, + T ₂ ). If the desired course is such that a small time gap is irrelevant, then the capacitor 64 can be charged directly from the connection point U ₅ , whereby the circuit for generating the pulse with the pulse width T _{5 is} omitted.

Since it is possible according to the invention, the ratio of the change in the pulse duration for the speed of the internal combustion engine as a function of changes in the intake manifold pressure in internal combustion engines can largely change, as shown in Fig. 1, the. Injection quantity characteristic of the fuel injection pump can be easily adapted to the fuel requirement.

For this purpose 3 sheets of drawings

> i

Claims (1)

the sum of the pulse lengths of both pulses ent Claim: speaks. The pulse duration of the first pulse is there by changing the transfer properties Electromagnetic fuel injection control of the transmission according to the respective pressure to change system for internal combustion engines with injection valve 5 in the intake line, so that the combustion Do that by first and second from a first engine through different length openers and second monostable flip-flop, the injectors receive a correspondingly dosed quantity Control pulses can be actuated, the tilting receiving fuel. steps of the speed of the internal combustion engine Such an injection control system can be controlled by corresponding pulses, the circuit connection known from DT-AS 12 68 900 a variable pulse length order has been improved insofar that the compliance and the switching time of the second flip-flop of switching time of the injection valves and thus the respective; can be controlled by the first control pulse, geke η η - injected fuel quantity is additionally characterized by a third monostable speed of the internal combustion engine (41, 45) controlled by the first of a certain law and controlled by the control pulse (t / 2) Generating a third will. This happens in the known circuit control pulse (t / 7), by a first capacitive 'arrangement in such a way that in the discharge circuit of the charging and discharging circuit (64, 65, 66) with a time-determining capacitor of the first monostad third and the second Control pulse (t / 7 bilen flip-flop as a controllable discharge resistor one and US) receiving logic circuit (51, 10 transistor, whose conductance during 52, 53) is provided to combine both control in each pulse period depending on the through the pulse to a signal (t / 9) and with a circuit (59, 60, 61) responsive to the speed of the internal combustion engine given impulses, the frequency is changed. A certain dependency gate (64) and generation of a corresponding 25 on the speed can be achieved by suitable change for charging and discharging a first capacitor of this conductance.
Output signal (t / 12) and a second object of the invention is to create a new injection-charging and discharging circuit (80, 81, 82) with a control system of the type mentioned at the outset an optimal adaptation of the monostable flip-flop (70, 74) for generating the respective switch-on time of the injection nozzle to that of a fourth control pulse (1/13) and with a visual pressure corresponding to the fourth control pulse in the intake pipe of the internal combustion engine takes place, but also the Change circuit (76, 77, 78) for controlling the charging speed with which the respective switch-on and discharge process of a second capacitor is changed (81) to generate a first control pulse, depending on the respective size of the Influencing pulse signal (t / 15) whose switching time is also changed.
Length as a function of the fourth control pulse In an injection control system of the type mentioned and its amplitude as a function of the output signal (1/12) mentioned above, this object is achieved according to the invention. by a third monostable multivibrator controlled by the first control pulse for generating 40 a third control pulse, by a first capacitive