SU506313A4 - Fuel injection system in an internal combustion engine - Google Patents

Description

nozzles 2, located on the intake manifold 3 near the intake valves 4, and an electronic control circuit 5, to the input of which a vacuum sensor 6 in the intake manifold 3, a temperature sensor 7, an engine crankshaft rotation sensor 8 connected to the engine shaft, and other sensors 9. The vacuum sensor 6 is installed on the body 10 of the throttle valves 11.

The output of the electronic control circuit is connected to the windings of the nozzles 2 (not shown in the drawing).

The fuel from tank 12 is supplied by pump 13 through line 14 to nozzles 2, which can be brought both simultaneously and in various combinations in groups or sequentially.

The electronic control circuit is used to supply control pulses to the two groups of nozzles from the sensor 8, preferably made in the form of a single lug cam driven from the crankshaft. Cam alternately closes and opens a pair of koptaktov. The pulses 15 and 16 are fed to the trigger input of the trigger 17, which prevents the latter from being triggered during vibrations. The outputs 18 and 19 of the starting device are connected to block 20, and also with the first inputs of logic elements “And 21 and 22. Sensor converters 6 and 7 are also connected to the input of block 20 (the remaining sensors are not shown in the drawing). The output 23 of the unit 20 is connected to the second inputs of the logic elements “AND 21 and 22. The output of the element 21 is connected to the amplifier 24, and the output of the element 22 is connected to the amplifier 25. The amplifiers 24 and 25 are connected to the corresponding groups of windings of the injectors.

When a pulse is applied from one output of a starter to another output, there is no pulse, i.e. a control pulse is fed to one "I. For example, a pulse is fed from output 18 to element 21. At the same time, this pulse is fed to block 20, which in response produces a control pulse depending on the operation of the engine. This control pulse is applied to both elements of the "I. Since the device 17 only provides a pulse to the element 21, the latter delivers a pulse to the amplifier 24, opening the nozzles, while the element 22 does not generate a signal. Upon completion of the supply of the control pulse from block 20 to the input of element 21, the output pulse of the latter decreases to zero, thereby ensuring the closure of the nozzles of the corresponding group. During the period of the open state of the injectors, the fuel is injected under pressure 9 into the corresponding inlets of the engine cylinders.

FIG. Figure 3 shows the preferred electrical circuit of the unit 20. The latter contains two sources of charge current, which are alternately connected to two storage capacitors 26 and 27.

The first charge current source is formed by an output transistor 28, the base of which is connected to a common point of a voltage divider consisting of resistances 29 and 30, and an emitter is connected to resistance 31. Resistances 30 and 31 are connected to the positive pole of the battery B +, and resistance 29 - to

negative pole of the battery, i.e. to "mass.

The second charge current source is formed by an output transistor 32, the base of which is connected via diode 33 to a common divider point, consisting of resistors 34 and 35, and the emitter is connected to resistor 36. Resistors 35 and 36 are connected to the positive pole of battery B +. The collector of transistor 28 is connected in parallel with the collectors of transistors 37 and 38. Similarly, the collector of transistor 32 is connected in parallel with the collectors of transistors 39 and 40. The bases of transistors 37 and 40 are connected, respectively, through resistances 41 and 42 to output 18 of device 17, and bases of transistors 38 and 39, respectively through the resistances 43 and 44 to the output 19 of the device 17. The emitters of the trapsistors 37 and 39 are connected to the capacitor 26, and the emitters of the transistors 38 and

40 with a capacitor 27. Transistors 37-40 and resistances 41-44 form a switch for alternately connecting capacitors 26 and 27 to two sources of charge current. The switch provides the connection of the capacitor 27 to the second source of charging current when the control pulse is supplied from output 18 and the output 19 does not have a pulse, while the capacitor 26 is connected to the first source of charging current. In this case, the current from the first source of charging current is supplied to the capacitor 26 through the transistor 37, and from the second source of charging current to the capacitor 27 through the transistor 40. When a pulse is applied from the output 19

the capacitor 26 is connected via transistor 40 to the second source, and the capacitor 27 via transistor 38 is connected to the first source. Block 20 contains a circuit having four

transistors 45-48, voltage dividers, consisting respectively of 49, 50 and 51, 52 resistances and diodes 53-58, voltage level setting 59, delay unit 59 and additional diodes 60 and 61. Change

the signal at outputs 18 and 19 causes in block 59 the generation of a return pulse. Block 59 can be performed, for example, in the form of a standby multivibrator or as another device generating a pulse for a predetermined period of time after a pulse arrives from outputs 18 and 19. The presence of pulses from output 18 and from the output of block 59 causes a voltage increase at point 62 and through diode 54, transistor 48 becomes conductive. Accordingly, the transistor 47, the emitter of which is connected to the capacitor 26, becomes conductive. From the latter, the current will flow through the transistors 47 and 48 to ground. The voltage reduction at the capacitor 26 occurs to a predetermined value. During this period of time, the current from the first source through the transistor 37 to the capacitor 26 creates an excess of voltage across it to a predetermined value. When the pulse from block 59 ends, the voltage at point 62 decreases. As a result of turning on the diode 54 and the diode block mounted on it, the voltage at the base of the transistor 48 becomes insufficient for the latter to become conductive. The transistor 47 goes to a non-conducting state, and the discharge of the capacitor 26 is stopped, thereby ensuring its charge from the first source of charging current.

The same thing happens in the circuit when a pulse is output from output 19, since it is made of two identical halves, the work of one of which was described above. By selecting the values of the resistances and the capacitance of the capacitors, it is possible to achieve that the discharge of the capacitors 26 and 27 takes place in a very short time compared with the pulse duration of the outputs 18 and 19.

The control unit 63 receives a signal from the vacuum sensor 6 via input 64. At the same time, capacitors 26 and 27 are connected to unit 63 via diodes 65 and 66, respectively. Block 63 contains transistors 67-69. The emitters of transistors 67 and 68 are interconnected, and that of these transistors is conductive, to the base of which a higher voltage pulse is applied. When the magnitude of the pulse voltage at the base of the transistor exceeds the magnitude of the pulse voltage at input 64, transistor 67 becomes conductive and transistor 68 becomes nonconductive. When the latter goes into the non-conducting state, the transistor 69 also becomes non-conducting. When the transistor 68 is opened, transistor 69 also opens, resulting in a control pulse appearing at output 23 taken from a common point of the voltage divider formed by resistances 70 and 71. When transistor 69 is closed, the control impulse at output 23 is absent, so as resistance 7 is connected to “mass. The control pulse from the output 23 is supplied to the logic elements 21 and 22 to provide a signal for opening the nozzles 2.

The fuel injection system (see Fig. 3) has a regulator for changing the current of the second charge source depending on the engine temperature.

To do this, in the base circuit of the transistor 32, a voltage regulator formed by a voltage divider consisting of a constant resistance 72 and a variable resistance 73 of the temperature sensor 7 (variable resistance is shown as a hermistor, but may be 1) is set.

any other type). The common point of this voltage divider is connected to the base of the transistor 32 through a diode 74 in parallel with a voltage divider consisting of resistors 34 and 35.

The transistor 32 is applied pp-type and its emitter is connected to the positive pole B +. Resistance 73 is connected to "mass" and has a higher value of active resistance at low temperatures. Consequently, when the temperature decreases, the resistance 73 provides the voltage on the base of the transistor 32. Since the emitter voltage of the transistor 32 does not

much more voltage at its base, the current in its emitter-collector circuit changes in inverse proportion to the voltage at the base of transistor 32. Thus, when the temperature of the variable resistor 73 decreases and the voltage at the base of transistor 32 increases, the current in the emitter source - the collector circuit of the transistor, i.e. the current of the second charge current source, is reduced. Conversely, as the temperature of the resistance 73 increases and the voltage decreases at point 75, the current of the second source increases. A voltage divider consisting of resistances 34 and 35 sets the minimum voltage to

the base of the transistor 32.

The graphs (see Fig. 4) show the voltages as a function of time in the various elements of the electronic control circuit. The upper curve 76 shows the voltage on the capacitor 26. The voltage at the start point 77 is the lowest (close to the "mass" voltage). This voltage is maintained for a predetermined period of time by means of a delay block 59. When capacitor 26 or 27 is connected to the first source of charging current, the voltage on the capacitor first rises (this period is indicated on curve 76 between points 78 and 79),

and then for the rest of the time (between points 79 and 80) remains constant. At this time, the impulse comes from exit 18 and is indicated by curve 81. After the arrival of the impulse from exit 18, exactly the same impulse comes from exit 19 (it is indicated by curve 82). The arrival of a pulse from output 19 indicates that the voltage on the capacitor 27 varies as described for capacitor 26. Simultaneously with the onset of

Claims (3)

when the pulse arrives, the voltage across the capacitor 26 increases from the value at point 80 to the value at point 83 (capacitor 26 is connected at this time to the second source of charging current). When a warm engine is running, the voltage on the capacitor changes, as shown in the graph of curve 76. At the same time, the increase in voltage on the capacitor must exceed the voltage from the transducer sensor 6 at some time period (curve 84 ) remains the same from point 77 to point 80. However, from point 80 it can increase along the lines 85, 86, 87, 88 and 89. These voltages correspond to different values of engine temperatures and, therefore, resistance 73. Line 89 corresponds to the voltage at the minimum allowable temperature of the engine, and line 85 - the operating temperature of the engine. This voltage is determined by a voltage divider, consisting of resistances 34 and 35. Lines 86, 87 and 88 are voltages at intermediate temperatures. The voltage supplied from the temperature sensor converter is indicated by lipia 90. The voltage curves 91 show the pulses supplied from the output 23 of the block 20. In this case, the pulse 92 corresponds to the pulse that is applied when the voltage on the capacitor increases along line 85. At lower temperatures motor pulses 93-96 are supplied respectively to lines 86-89. Voltage impulses 91 are supplied to logical terminals 21 and 22 and then produced by one of the amplifiers 24 or 25 of the same duration. Thus, the proposed fuel injection system improves the control accuracy of the supply during the start-up and warm-up period of the engine by adjusting the current, incoming from the second source of charge current to the capacitor, depending on the engine temperature. Claim 1. The fuel injection system of the internal combustion engine according to patent 458139, characterized in that, in order to improve the accuracy of controlling the supply during the engine start-up and warm-up period, the second current source is equipped with a regulator of current variation depending on the engine temperature. 2. The system of claim 1, in accordance with the fact that the second current source is equipped with an output transistor, in the base circuit of which a current control regulator is installed. 3. System no. 2, characterized in that the base of the output transistor of the second current source through dividing diodes is connected to common points of two voltage dividers, one of which is made of constant resistance, and the other, forming a regulator of current variation , - of constant and variable, varying with the temperature of the engine, resistances. #nineteen П 25 58 i l i I