PL81427B1 - - Google Patents

Description

Patent holder: Robert Bosch GmbH, Stuttgart (Federal Republic of Germany) Electronic control system for an injector for an internal combustion engine The invention relates to an electronic control system for an injector for an internal combustion engine comprising at least one electromagnetic injection valve which is opened by a rectangular electric pulse synchronously with crankshaft speed and remains open for a period determined by the control system depending on at least one engine operating size, in particular depending on the pressure in the intake pipe. With the use of such an injector, the amount of fuel injected into the engine cylinder during each intake stroke can be very accurately adapted to the operating conditions of the engine, in particular to the engine speed and load, which also gives the advantage that a very low exhaust emission by the engine can be determined. This adjustment takes place when the engine is warm, when it has been running for a long time, and is consequently in the upper temperature range limited by the cooling system. However, when the engine is cold during start-up, correct idling can only be ensured if the amount of fuel adapted to the cylinder at each intake stroke is significantly increased to make the engine a richer mixture compared to the engine's needs after reaching the appropriate operating temperature Electronically controlled fuel injectors are known which have a temperature sensor located in the cylinder head of an air-cooled engine to significantly enrich the fuel-air mixture during engine warm-up, i.e. from start-up. engine in cold condition until operating temperature is reached. The electronic control system used in such an injector comprises a monostable transducer, triggered at each revolution of the crankshaft, having an input and output transistor, and a capacitive or inductive feedback circuit, the storage of electric energy with voltages and currents, varying depending on the engine operating parameters (air temperature, pressure in the intake pipe and the number of revolutions) determine the duration of the pulses opening the injection valves. In the known control system, the operating temperature is measured by by means of a resistor arranged in the cooling circuit or in the cylinder head, which has a positive or negative temperature coefficient and is connected to the collector circuit of the output transistor of the control latch. In another known circuit, a multiplier circuit is engaged downstream of the control latch which extends the incoming from the flip-flop, basic impulse by a variable factor depending on d temperature, which lengthens the time of opening the injection valves. 8142781427 15 30 In many types of engines it appears that after a cold start a relatively rich idling mixture is needed to keep the engine running and to prevent the engine from stalling, and to furthermore provide a good response to sudden throttle opening. short engine operation time, about 5-30 seconds, usually after 20 seconds, enrichment of the mixture is no longer necessary. Many times the amount of fuel can be reduced by half. However, if the engine is still running on a rich mixture, it causes the spark plugs to evaporate after a short time and the resulting ignition deterioration. Moreover, an unacceptably large amount of unburned fuel is discharged in the exhaust gas. These disadvantages can be reduced by switching the control system in the period of 5 to 30 seconds. The aim of the invention is to create an electronic control system which ensures a sufficiently fast depletion of the mixture. This task has been solved according to the invention in that a timer set at 5 to 30 seconds is used. for example, for 20 seconds, which during this time acts on the duration of the pulse to extend it and is activated by starting the engine. Such a timer, switched after starting the engine from a rich to a lean mixture, can be made in various ways, for example as an electric electric, electronic, thermoelectric, mechanical, hydraulic or pneumatic. It is essential, however, that switching is effected by closing or opening a switch, for example a contact or a transistor, or also by a step change in resistance. It is particularly advantageous if the timer is so designed as to cause the pulse duration to vary from a large initial value to that required at a continuous operating temperature. Such a continuous depletion of the mixture takes place in a simple manner with a control system in which the pulse to open the injection valves consists of a base pulse adapted to at least one operating size and an extension pulse which is generated in the multiplier circuit and is greater than the base pulse by a factor varying from 0 to 5. In this case, the timer acts to increase this factor. In a preferred embodiment of the device according to the invention, the timer element comprises a first transistor and a second transistor with the same type of conductivity. the first transistor has a resistor in both the emitter and collector circuits and is held blocked by a base resistor 60 connected in parallel to the emitter-base junction and to the emitter resistor, its base, for example via a diode, it is connected to the starter switch intended for starting It is connected to one of the time determining electrodes of the capacitor, the second electrode of which is connected to the collector of the second transistor. In known control systems of the type described, the multiplier circuit comprises a charged capacitor connected in series with an emitter resistor and with an emitter transition. the collector of the emitter follower transistor, and a charge transistor connected through the collector to the second electrode of the charged capacitor. If the timer is constructed in the manner described above, the continuous reduction of the elongation factor of the multiplier circuit is achieved by the fact that, according to another embodiment of the apparatus of the invention, the collector of the second transistor is connected to the base of the charge transistor, for example via diodes. and possibly through a resistor connected in series thereto, a resistor connected in parallel to the emitter-base junction of the charge transistor and to the emitter resistor, which, in connection with the gate transistor I, maintains a certain base potential of the charge transistor during the base pulse. The subject of the invention is described, for example, on the basis of the drawing, in which Fig. 1 shows a diagram of an injector control system of an internal combustion engine, Fig. 2 - a timing diagram of the operation of a time element belonging to the system of Fig. 1, Fig. time operating in a similar way, and Fig. 4 - variation of the time segment shown in Fig. 1 The fuel injector of FIG. 1 is intended to feed a four-cylinder internal combustion engine 11, the spark plugs 12 of which are connected to a high-drive ignition system, not shown. In the immediate vicinity of the intake valves, not shown, belonging to the individual engine cylinders and connected to these cylinders. Electromagnetically actuated injection valves 14. Each injection valve is connected to a fuel distributor 16 by a fuel line 15 through the nozzles of the suction pipes 13. In the distributor and in the fuel lines 15, the fuel is held by an electromechanically actuated pump 7 under an approximately constant pressure of about three atmospheres, regulated by a pressure regulator 1 & each of the injection valves 14 contains a magnetizing coil not shown, one of which one end is connected to ground and the other end is connected via a connection line 19 to one of the four resistors 20. In the embodiment shown, all four injection valves are opened in sequence synchronized with the rotation of the crankshaft. This is related to the electrical opening impulse Ig, which determines the opening period of the injection valve and makes the power stage 22 of the control system described in detail conductive during the injection. The electronic control system has as main parts a single-switch 25, a reverser phases 26 followed by a multiplication circuit 27 and an OR gate 28, for which a power stage 81427 6 22 and a timer 39 according to the invention are switched on. The trigger 25 comprises an input transistor 31 and an output transistor 33 connected to its collector. The collector of the output transistor is connected to the common positive conductor 33 via the primary winding of the transformer 36 with an adjustable core 37. This core is connected by a linkage 38 by means of a linkage 38. The diaphragm of the pressure box 33, which is located on the suction pipe 13 behind the throttle 41 shown in the suction direction, is not shown in the figure. The input transistor 31 of the trigger 25 in the idle state of the trigger is held in a conduction state by the connecting resistor 31 its base with a common positive conductor 33. The secondary winding 45 of the transformer 36 is connected to its base via a diode 44, the second free end of the secondary winding is connected to the point of connection of the two voltage dividers 46 and 47. In order to make the flip-flop 25 unstable synchronously with the rotation of the shaft In the crank motor 11, for the duration of the basic impulse In, a cam 51 is coupled to the camshaft 50 of the engine, which cooperates with the movable contact 53 of the switch, connected to the minus line 52 of the power source, not shown, the fixed contact 54 of the said switch it is connected to resistor 55 and to capacitor 53. On the other hand, this capacitor is connected via resistor 57 to minus conductor 52 and via diode 58 to the base of input transistor 31. When moving contact 53 is in the shown opening position capacitor 56 is charged via resistors 55 and 57 to the supply voltage existing between the minus conductor 52 and the plus conductor 33. As soon as the moving contact 53 is pressed by the cam 51 to the fixed contact 54 and connects the overcharged electrode capacitor 56 with a negative potential, the base of transistor 31 becomes a strongly negative potential, so that the transistor is blocked and the state of The output transistor 32 passes through the primary winding 35, the collector current of the output transistor 33 induces a voltage in the secondary winding, and keeps the transistor 31 blocked, the duration of this blocking depends on the pressure in the suction pipe 13 of the motor If the pressure is at. The closed or nearly closed throttle 41 is significantly less than the atmospheric pressure, the pressure can 39 raises the core 37 in the direction of the arrow and increases the air gap in the transistor 33, as a result of which the inductance of the primary winding 35 is significantly lowered. The input transistor 31, due to the low induced voltage, quickly returns to the normal conduction state, thereby blocking the output transistor 32. As a result, the fundamental pulse In existing on the collector of the output transistor has a small duration of about 1.2 m / sec. however, the pedal 40 is depressed and thus the throttle 41 is open, even at high revs there is a pressure downstream of the throttle which is only slightly less than the atmospheric pressure. Since the core 37 is only slightly raised in this case, the primary winding 35 has a high inductance, which causes a slow build-up of the collector current in the primary winding 35 and a long duration of the basic pulse In, up to 4.2 msec. the fundamental pulse In is collected from the output transistor 32 by the phase inverter 26 and fed to the multiplier circuit 27, which produces I5 immediately after the fundamental pulse, an extension pulse Iv, with an adjustable duration greater than that of the fundamental pulse. This value is varied according to the operating conditions of the engine, for example the temperature of the cooling water. The multiplication circuit includes a charged capacitor 60, a charge transistor 61, a discharge transistor 62 and a switching transistor 63, the emitter of which is connected directly to the conductor. On the other hand, the base of transistor 63 is connected via a resistor 64 to the minus conductor and to one electrode of the charged capacitor 60 as well as to the collector of the discharge transistor 62. The base of transistor 62 is connected to the connection point 30 of the two resistors 65, 66, constituting a voltage divider and the emitter of the transistor 62 is connected through a resistor 67 to a common pluggable conductor 33. The charge transistor 61 is its collector connected to the second electrode of the charged capacitor 60. This transistor operates in an emitter follower circuit, because its emitter is through an emitter resistor. 69 is connected to positive conductor 33 and its base is connected directly on average with the collector of transistor 70 40 of the phase inverter 26. Transistor 70 has a load resistor 73 and its base is connected through a resistor 71 to the minus conductor 52 and through a resistor 72 to the collector of the output transistor 33. 45 To the collector of transistor 70 through the first resistor. The base of the transistor 75 of the OR gate 28 is connected, the base of this transistor is further connected by a resistor 77 to the negative conductor and by a second coupling resistor 50 78 to the collector of the transistor 63 of the multiplication circuit 27. The collector of transistor 75 is connected to the negative conductor. a common positive wire 33 through a resistor 79, while a resistor 80 connected between the emitter 55 of this transistor and the negative wire serves as a leakage resistor, to which the base is connected by a power transistor 81 of the NPN type, which together with the power transistor 82 of the pnp type forms a step At power 23. 60 The system described so far is basically known. Its operation can therefore be briefly described as follows. When the running motor causes the moving contact 53 to be brought to the short-circuit position 65 by means of the cam 51 once, with each rotation of the crankshaft, to the short-circuit position 65, the idle-conductive input transistor 31 is blocked and a fundamental pulse In is generated in the manner described above. the duration of which depends on the rotation of the engine and the position of the throttle. During the fundamental impulse, the I-gate transistor 70, which conducts in the idle state, is blocked, with the result that the transistor 75 of the OR gate 28 is made conductive. through the first coupling resistor 76 and conducts transistors 81 and 82. In the idle state, the collector potential of transistor 61 as well as the collector potential of transistor 70 are almost equal to the potential of the negative conductor 52. The voltage Uc of the charged capacitor 60 is thus practically equal to zero. However, as soon as the fundamental pulse In begins, the potential basis The y of transistor 61, due to the base current of transistor 75 flowing through resistor 73, lies almost in the middle between the potential of the positive conductor 33 and the value of the potential of the negative conductor, so that transistor 61 gives a constant charge current to the charged capacitor 60. During the fundamental pulse In the voltage Uc on the capacitor 60 increases linearly as shown in FIG. 2 for the time span from the start of the fundamental pulse to the end of this pulse t2. As soon as transistor 70 begins to conduct again at the end of the fundamental pulse, its collector and consequently the collector of transistor 61 receives a strongly negative potential, whereby the charge collected on capacitor 60 gives a strongly negative potential at the base of transistor 63 and blocks it until the charge flows away through transistor 62. Transistor 62 ensures that the discharge current has a constant value. In the conditions shown in FIG. 2, discharge continues from time t2 to time tg, after which transistor 63 is again conductive. Since transistor 63 is held conductive by the coupling resistor 78 and the collector resistor 68 during the blocking of transistor 63, an extension pulse Iv is added to the basic pulse In, which together with the basic pulse In creates a summation pulse Ig, which determines the amount of time. opening of the injection valve1 and therefore the amount of fuel injected. Tv With a warm engine, the factor f = - has a value Tn adjustable from 0 to 5, and after many 50 practical experiments this value is approximately one. The duration of the extension pulse Iv was denoted by Tv, and the duration of the basic pulse In of the metastotor was denoted by Tn. Since it is desirable to supply it with more fuel immediately after starting the engine than is needed when the engine has been running for a long time, a timer 30 is provided according to the invention, which electronically for a period of about 60 seconds. It significantly increases the extension factor f of the multiplication circuit 27, explained above, whereby in the embodiment example shown, this factor continuously decreases at the end of the mentioned period of time to the value that is to be at continuous operation of the engine, and this value is The electronic timer comprises a first transistor 85 and a second transistor 86 which, like the first transistor is NPN and its emitter, is connected to the common minus 52 of the circuit. The base of the second transistor 86 is connected to the emitter of the first transistor 85 and to a resistor 87, the second lead of which is connected to the negative wire. So that both quiescent transistors are blocked between the base of the first transistor 85 and the negative wire 52 is connected. resistor 88. The base of this transistor is further connected to the collector of the second transistor 86 by means of a capacitor 89 with a capacity of about 3 µF, the collector of the second transistor 86 being connected to the positive conductor via a resistor 90, and further connected to the collector in series. the connection of the resistor 91 and the diode 92, the anode of which is connected to the base of the landing transistor 61 or to the collector of the transistor 70. The base of the first transistor 85, the collector of which through a resistor 93 is connected to the positive wire 33, is connected via a resistor 94 to the switch circuit 96, the second terminal of which is connected to the positive conductor 33. The circuit is that the resistor 94 at point P is connected to the end of the magnetizing winding 97 of a starting contactor, not shown, which receives a current when the starter switch 96 is pressed and also starts a starter, not shown. In addition, a resistor 98 is connected between the connection point of resistor 94 and diode 95. on the other side to the negative conductor 52. When the motor is started and the start switch 96 is closed for this purpose, the first transistor receives the base current through this switch, through resistor 94 and diode 95, and is made conductive. At the same time, transistor 86 also begins to conduct. Consequently, capacitor 89, which is charged to full operating voltage prior to starting the start-up, discharges, because when the second transistor 86 is conducted, its collector has a potential close to the potential of the minus conductor. 52. Since the resistor 91 is then also at a potential close to that of the minus wire, a much greater charge current is obtained through transistor 61 as soon as transistor 70 goes into lockout during the fundamental pulse In. As a result, during the start-up, a series of extension pulses Iv of equal length are generated, which cause a corresponding extension of the injection time and therefore facilitate the engine start-up. In the practical embodiment, the above-specified extension factor f is approximately 5 for the duration of the pulse baseline 2.5 msec. hence the summation pulse has a Tg duration of 15 msec. for each injection. In the selected timer 30 arrangement, care was taken that after opening the start switch 96 for about 20 seconds. the elongation factor-81427 10 was greater than the value needed for continuous operation, amounting to about fo = l, and from the large initial value f = 5, this factor continuously decreases to the value proper for continuous operation. Namely, as soon as the start switch 96 is released, the two transistors 85 and 83 of the timer 30 attempt to return to a blocked state, in which the discharged capacitor W is in a 'steady state of full charge' even when the start switch is open. To charge this capacitor, a charge current Ic is needed, which is basically the sum of the emitter-base voltages of transistors 85, 83 and resistances 88. This charge current is approximately constant and is intended to the path of transistor 86 increased linearly and reached after 20 sec. the value at which diode 92 is reverse biased. With the base potential of transistor 61 increasing in the positive direction, the charging current for capacitor 60 supplied by this transistor is, however, smaller. As a result, the voltage Uc across the capacitor during the fundamental impulse following the release of the starter switch, for example, for a fundamental impulse starting at tl9, increases more slowly than for the previous fundamental impulse. With equal lengths of the fundamental pulses, this has the effect that the charge time decreases accordingly, thereby reducing the elongation factor f. In Fig. 2, for the substituted pulse starting at time t31, a state is shown in which the elongation factor w set by a time member of 30 over a period of 20 sec. it is reduced to the value fo = l, which is appropriate for the further operation of the engine. It should be noted, however, that in Fig. 2 the time scale for the pulse train is very tight. In fact, at the idle speed of 600 revolutions per minute or 10 revolutions per second during these 20 sec. there are 200 injections, the duration of one injection with a progressive decrease in the elongation factor f is shorter. The timer 30 shown in Fig. 1 is a preferred embodiment, the advantages of which are that a time period of 20 sec. is maintained irrespective of the motor speed and the length of the fundamental pulse In. Fig. 3 shows a greatly simplified circuit of the time element, which essentially consists only of a transistor Tr with an emitter connected to the minus conductor 52, a collector resistor R1, with capacitor C connected to the base and collector of the transistor, and from two base resistors R2, R3 of the base, the first of which is the base connection to the minus conductor 52, and the second is the base connection of the transistor to the point P of the winding 97 connection with the starting switch 98. In this circuit, the voltage overload of the transistor base Tr, which may occur after the start-up at the moment of opening the switch 96, is on, between the point P and the minus conductor 52 the diode D is switched on. The time period shown in Fig. 4, does not differ much from the time stage from Fig. 1. The only difference from it is that there is no collector resistor 90 of the second transistor 86. Due to this, the capacitance of the capacitor 89, connected between the base of the first transistor 85 and the collector of the second transistor 86 can be reduced tenfold compared to the arrangement of FIG. 1, to a value of about 0.3 µF. The given time by the time loop of FIG. 4 has a time period of 20 seconds. however, in contrast to the circuit of FIG. 1, it is dependent on both the rotation and the length of the fundamental pulse, since only the equalizing current is used to discharge the capacitor 89 in this case and the reversing transistor 26 is blocked during the fundamental pulse. The advantage of the described timer is that by automatically increasing the amount of fuel compared to the amount supplied to the engine during its continuous operation, in the hot state a more reliable rotation of the engine is ensured without any action by the driver. 25 55 Z a s t r z e | Patent 1. Electronic control of an injector for an internal combustion engine comprising at least one electromagnetic injection valve which is opened by a rectangular electric impulse synchronously with the rotation of the crankshaft and remains open for a period determined by the control system depending on at least one engine working size, in particular depending on the pressure in the suction pipe, that is to say that it includes a timer (30) adjustable for 5 to 30 seconds, for example about 25 seconds, which during this time it acts on the duration of the extension pulse, this timer being engaged when the engine is started. 2. System according to claim A multiplication circuit (27) comprising a charge capacitor (60), a charge transistor (61), a discharge transistor (62), and a switching transistor (63), the charge transistor (61) as claimed in claim 1, wherein the charge transistor (61) conducts the electric current during the duration of the fundamental pulse (In) and thus charges the capacitor (60) and the constant discharge current flowing through the transistor (62) until the discharge of the charged capacitor (60) to form an extension pulse (Iv) following immediately after the primary pulse (In), it controls the switching transistor (63). 3. System according to claim The method of claim 1, wherein the timer (39) is connected to the base of the landing transistor (61). 4. System according to claim The timer as claimed in claim 1, characterized in that the timer comprises one transistor (Tr), which in the idle state of the circuit is blocked, 60 the base of the transistor being connected, for example by a diode, to a starting switch (96) for activating the starter. and furthermore with one of the electrodes of the time determining capacitor (6), the other electrode of which is connected to the collector. The timer of claim 1, wherein the timer has a first transistor (85) and a second transistor (86) of the same type of conductivity, the first transistor in both the collector circuit and the emitter circuit having resistors (87, 93) and maintained. in the blocked state by the biasing base resistor (88) parallel to the emitter-base junction and to the emitter resistor (87), the base of this transistor (85), for example via a diode, connected to the starter switch (96) for actuating the starter, and furthermore one of the electrodes of the time setting capacitor (89), the second electrode of which is connected to the collector of the second transistor (86). 6. System according to claim 5. A method as claimed in claim 5, characterized in that the collector of the second timer transistor (86) is connected to the base of the charging transistor (61), for example via a decoupling diode (92) and possibly via a resistor (91) connected in series with the diode. a resistor (73) .AlM is connected in parallel to the emitter-base junction of the charge transistor (61) and to the emitter resistor (69). 'v * 3 RSW Zakl. Graph. Warsaw, Srebrna 16, residing in 7-76 O - 105 + 20 copies Price PLN 10 PL