DE3003892A1 - PRESSURE-DEPENDENT ADJUSTMENT OF OPERATING PARAMETERS OF INTERNAL COMBUSTION ENGINES - Google Patents

Description

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Pd / Jä I6.I.198O *

Robert Bosch GmbH, 7000 Stuttgart 1

Pressure-dependent adjustment of operating parameters of internal combustion engines

State of the art

The invention is based on a pressure-dependent adjustment of operating parameters of an internal combustion engine according to the genre of the main claim. From US-PS 4 009 699 a digital electrical ignition system is known, in which the ignition is adjusted depending on the pressure. To measure the atmospheric pressure is a pressure transducer is proposed which outputs a current proportional to the pressure, which is generated by means of an analog-to-digital converter is converted into a digital signal. Furthermore, it is known in the injection a make pressure-dependent adjustment. The pressure transmitter acts on a potentiometer, its wiper is adjusted depending on the pressure.

These arrangements have the disadvantage that an analog signal is available as a measure of the pressure. at In digital ignition systems, the signal must be converted into digital pulses by means of an analog-digital converter will. In potentiometrically operated pressure transducers, there is the disadvantage that in particular in the Operation in the motor vehicle, the potentiometer tracks of the

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The potentiometer is slightly dirty. Furthermore, the spring pressure of the grinder must be overcome. this leads to the fact that the actual pressure sensor has to apply a certain force to the grinder to move. This is particularly disadvantageous when only small pressure differences, such as the atmospheric pressure, are to be recorded. Dirt on the grinding tracks and the forces required to Adjustment of the potentiometer wiper leads to incorrect displays at the output of the pressure transmitter and to a hysteresis.

Advantages of the invention

The arrangement according to the invention with the characterizing features of the main claim has the advantage that on the one hand there are already pressure-dependent pulses available for digital ignition systems and on the other hand inductive or capacitive encoders can be used, which work largely frictionless. The influence of dirt does not play a role with these donors.

The measures listed in the subclaims are advantageous developments and improvements of the In the main claim specified arrangement for pressure adjustment possible. To generate continuous impulses it is advantageous to charge and discharge the timers using electronic switches. This is the most defined Creation of initial states possible, so that the measurement gains considerably more accuracy than if one would wait for the natural discharge of the inductances or capacitances. Downstream by the timers It is possible for comparators to trigger pulses when the timing elements have a defined, predetermined state of charge. To get an impulse that is directly related to the

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measured pressure is proportional, it is favorable to the Subtract pulses from the two coparators from each other. This can be done in a simple way using a Nand link happen. If, instead of a digital pulse, an analog signal proportional to the pressure is required to to operate the circuit arrangement with analog circuits, an integrating element must be connected after the NAND element, which converts the impulse into a direct voltage. By means of such a direct voltage, for example a multivibrator can be controlled, which emits impulses for an ignition system or an injection. the The easiest way to control the pulse time or the pulse ratio of the multivibrator is by means of the current control of the Multivibrators causes. The electronic switches for the timers are expediently through controlled a clock generator that either oscillates freely or is controlled externally if at certain times Pulses are to be emitted by the pressure measuring device.

drawing

An embodiment of the invention is shown in the drawing and in the following description explained in more detail. 1 shows a block diagram of an air pressure-dependent retardation of an ignition system. FIG. 2 shows a diagram for explaining the function of the pressure measuring device, FIG. 3 shows a diagram for Explanation of the control of an analog ignition system by means of the pressure measuring device and FIG. 4 a concrete one Embodiment of an ignition system with a pressure measuring device according to the invention.

Description of the invention

In the block diagram of FIG. 1, the timing elements

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1 and 2 each have a resistor 3 and 5 and a variable inductance 4 and a capacitor 6, respectively. Of the Resistor 3 is connected in series with the variable inductance 4, while the capacitor 6 with the Resistor 5 is connected in series. The other side of the resistor 3 and the capacitor 6 is on the Supply voltage, while the other side of the resistor 5 is led to ground. The inductance 4 is connected to ground via the collector-emitter path of a transistor 7. The inductance is from the pressure Executed changeable. For this purpose, for example, the iron core of the inductance 4 is designed to be movable and with it connected to the membrane of a barometer box, which moves the core in the coil depending on the pressure. The collector-emitter path of a transistor 8 is connected in parallel to the capacitor 6. The bases of the Transistors 7 and 8 are connected to a clock generator 9. Between resistor 3 and inductance leads a line to a comparator 10, while the input of a comparator 11 between capacitor 6 and Resistor 5 is connected. The outputs of the comparators 10 and 11 lead to the input of a differential pulse generator 12, which in the simplest case is designed as an AND element. The output of the differential pulse generator 12 leads to the base of a transistor 13. Parallel to the collector-emitter path of the transistor 13 is the Series connection with a resistor 14 and a capacitor 15 · The emitter of the transistor 13 and the one Side of the capacitor 15 is connected to ground, while the collector of transistor 13 continues to have a resistor 16 connected to the supply voltage stands. A line is connected between the resistor 14 and the capacitor, on the one hand to a Comparator 17 and on the other hand to a multivibrator

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leads. From an unrepresented Zündirüpuis ^ s'oer reaches a line for pulse shaper 19 _s d ^ -i * ci.::erseits .verbunden with an AND gate 20, and he he s ^ i .zi .. ei.nen differentiator 21 is. The · A ^ s-jang cs differentiator 21 leads via a Scha.L-öi-% which is controlled by the comparator 17 to the synchronization input of the multivibrator 18. The output of the multivibrator 18 is connected to a further input of the AND element 20. The output of the AND element 20 leads to a pulse shaper 23, to whose output the ignition coil, not shown, is connected.

The mode of operation of the pressure adjustment will be explained with the aid of the pulse diagrams according to FIGS. 2 and 3. By the clock generator 9, the impulses according to Pig. 2a emits and can be externally controlled, the transistors 7 and 8 are switched alternately into the conductive and the blocking state. When transistor 7 becomes conductive, the current through inductance 4 increases according to an exponential function. When the transistor 7 is blocked, the full operating voltage is applied between the resistor 3 and the inductance 4. The voltage profile at the input of the comparator therefore corresponds to FIG. 2b. The process on capacitor 6 takes place in a similar manner. If the transistor 8 is blocked, the capacitor 6 is charged to the supply voltage. The voltage drop across resistor 5, which is applied to comparator 11, therefore drops exponentially. If the transistor 8 is conductive, the operating voltage is applied to the input of the comparator 11. The voltage curve across the resistor 5 is shown in FIG. 2d. While the voltage drop across the resistor 5 does not change over time with the transistor 8 blocked, since the time constant of the timing element 2 is always the same,

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the course of the voltage drop across coil A depends on its inductance. The comparators 10 and 11 are now connected in such a way that they ^{change their state at the beginning of the voltage 1} drop and when a threshold 25 is reached they again tilt back into the original state. A practicable embodiment of such a comparator is described with reference to FIG. Comparator 10 switches from the 1 to the 0 state at the beginning of the voltage drop and from the 0 to the 1 state when the voltage drops below a predetermined threshold. At the beginning of the voltage drop, the comparator changes from 0 to 1 state and when it falls below threshold 25 from 1 to 0 state. The pulses formed at the output of the comparator are shown in FIG. 2c, the pulses arising at the output of the comparator 11 are shown in FIG. 2e. In order to achieve the most accurate results possible, the switching threshold 25 of the comparators is set as low as possible, since this makes the pulses long. As a threshold value, 63% of the final value of the voltage can be reached, which roughly corresponds to the time constants of timing elements 1 and 2.

The signal at the output of the comparator 10 is composed of a basic value, that of the basic inductance corresponds to the lowest pressure, and from a portion that is dependent on the pressure change. While it is already possible for some digital circuits to use this pulse in binary form, by r.an, for example, the basic inductance by subtracting a corresponding one of this basic inductance binary value is taken into account, with other circuit arrangements a subtraction of the pulse component is necessary, which corresponds to the basic inductance. The pulse present at the output of the comparator 11 serves for this purpose

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Pig. 2e, which is chosen so that its pulse length just corresponds to the basic inductance. Since this Pulse is also derived from a time constant, there is the advantage that the pulse processing is independent of any fluctuations in the supply voltage, since only the short-term Zeitr the course of the unloading process is decisive. Although the output pulses of the comparator 10 and the! Comparator 11 can be selected as desired, results from the selected output combination according to FIG. 2c and FIG. 2e the advantage that the differential pulse in the differential pulse generator 12 is obtained by a NAND link can be. If the differential pulse generator 12 is designed as a Nand element, this results at the output of the Nand element a pulse according to Fig. 2f. The length of this pulse is the differential pressure in relation to the pressure at which the inductance has its basic inductance, proportional.

These differential pressure pulses can be used to directly control a digital ignition device or a digital injection. Their length is also determined by a suitable choice of the threshold value can be varied to a certain extent, so that they can be directly linked to the pure ignition pulse or injection pulse Adjustment can be connected. Do the impulses need a certain beginning or a certain one At the end, it is possible to synchronize the clock generator 9 externally.

If analog signals proportional to the differential pressure are required, this is achieved by sending them through the transistor 13 is negated and integrated onto the capacitor 15. The falling at the capacitor 15

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Tension is in Pig. 2g and inversely proportional to the differential pressure. With this signal analog ignition systems or injection systems can be controlled.

An example of an ignition system is also described below, which serves to reduce fuel consumption at a certain output and to bring the ignition point closer and closer to the bell limit while the mixture is at the same time becoming lean. Here, a higher air pressure, e.g. B. at sea level compared to the mountains , to a greater filling of the cylinder, which then leads to premature ignition (ringing). To compensate for this, the ignition point must be retarded depending on the absolute air pressure. The pressure measuring device described above is particularly suitable for measuring the air pressure and for retarding. The same problem also occurs with the injection.

In the case of analog ignition systems, the signal coming from the pulse generator and shown in FIG. 3a reaches the Schmitt trigger 19, which switches at the O-passages of the signal. This signal is applied to the AND element 20 and is shown in Fig. 3b. The negative edge of the triggered signal is differentiated by the differentiating element, while the positive edge is suppressed. At the output of the differentiating element 21 there is a signal behind Fig. 3c. The differentiated signal toggles when switch 22 is closed, for example as a transistor switch can be executed, the multivibrator 18, whose pulse ratio is determined by power sources is. A current source of the multivibrator 18 is controlled by the voltage applied to the capacitor 15, so that the charging and discharging of the pulse determining capacitor, which is shown in Fig. 3d, from

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Differential pressure is dependent on «The pulse formed by a buffer that is caused by the rising edge is given and which is shown in Fig. 3e proportional to the pressure difference and synchronized as a function of the ignition pulse sequence. Through these measures it is achieved not only that the differential pressure pulse follows the ignition pulse, but also that the pressure-dependent Pulse is varied as a function of the speed of the internal combustion engine so that it is constant Pressure always sweeps over a constant angle of rotation with one crankshaft revolution. The ignition pulse according to Fig. 3b and the pressure-dependent pulse according to 3e are added in the AND element 20, at the output of which a retarded pulse according to FIG. 3f is applied. This signal is processed by the pulse shaper stage in such a way that it can be used to control the Ignition coil can serve. Such a signal is shown in Fig. 3g.

If the retardation is to be 0, then the pressure-controlled current of the multivibrator should approach infinity walk. This is not possible with real versions because the pulse duty factor has not fallen below a certain level so that some adjustment would remain. The comparator 17 therefore detects the pressure-dependent voltage and switches over when a specified voltage is exceeded. Through this the pulses emitted by the multivibartor are suppressed. This is symbolic by the Switch 22 is shown. Adjusting pulses according to FIG. 3e are then not emitted by the multivibrator, so that an uncorrected ignition signal according to FIG. 3b is applied to the pulse shaper stage 23. With such a Jump function can therefore eliminate the remaining adjustment.

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Pig. 4 now shows a detailed embodiment of the essential parts of an arrangement according to the invention for an air pressure-dependent retardation of the ignition. A resistor is connected to the supply voltage line 30 31 connected, in turn with a variable Inductance 32 is connected. The variable inductor 32 is connected to the collector of a transistor 33 connected, the emitter of which leads to the common ground line 34, which at the same time carries the negative supply voltage. It also goes from the supply voltage line 30 a capacitor 35, which is also connected to the collector of the via a resistor 36 Transistor 33 is connected. The collector-emitter path of a transistor is parallel to the capacitor 35 37 switched. The base of the transistor 37 is on the one hand connected to the supply voltage line via a resistor 38 30 in connection, on the other hand it leads to a further resistor 39 · Between the supply voltage line 30 and the collector of the transistor 33 are also the resistors 40 and 4l as well the resistors 42 and 43 connected in series. A tap between resistor 4l and 42 leads to the negative Input of an operational amplifier 45 connected as a comparator. Between resistors 43 and 44 leads a tap to the positive input of an operational amplifier 46 connected as a comparator. The negative The input of the operational amplifier 46 is connected to the line between the resistor 31 and the inductance 32. The positive input of the operational amplifier 45 is connected to the connecting line Capacitor 35 and resistor 36 in connection. The clock generator 9 on the one hand feeds the base of the transistor On the other hand, it is connected to the resistor 39 via a negation element 47. The exits the operational amplifier 45 and 46 are with

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the inputs of the Nand element 48 in connection. The output of the NAND element leads to the base of a transistor 49 _3, the emitter of which is connected to the common ground line 34. The collector of the transistor 49 leads via a resistor 51 to the voltage supply line 30. A resistor 52 is also connected to the collector of the transistor 49 and is in turn connected via a capacitor 53 to the common ground line.

Between resistor 52 and capacitor 53 is the negative one Input of an operational amplifier 54 connected as a comparator. The positive one The input of the operational amplifier 54 is connected to a resistor 55 and a resistor 56, the resistor 55 to the supply voltage line 30 and the resistor 56 to the ground line 34 is connected. The output of the operational amplifier 54 leads to the base of a transistor 57.

The output 59 is connected to the base of a transistor 58 des in Pig. I connected differentiator 21, which emits pulses according to FIG. 3c. A resistance 60 is connected between the base of transistor 58 and supply voltage line 30. Further A resistor 61 leads to the collector of a transistor 62. The emitter of transistor 58 is connected to the Supply line 30 in connection, while the collector leads to a current source 63. The power source 63 is furthermore connected to the ground line 34 via the collector-emitter path of the transistor 57. To the The collector of transistor 58 is also a capacitor 64 connected, which is on the other hand with the base of the transistor 62 in connection. Between

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A resistor 65 is connected to the supply voltage system 30 and the base of the transistor 62. Furthermore, a controllable current source 66 is connected to the base of the transistor 62 and is in turn connected to the ground line 34. Current source 66 is controlled by the voltage applied between resistor 52 and capacitor 53, which is to be indicated by the connection of the control arrow of the controllable current source to the line between resistor 52 and capacitor 53. A further resistor 67 leads from the collector of the transistor 62 to the ground line 34. There is a resistor to the supply voltage line 30

68 connected, which leads to the base of a transistor 69. A further resistor 70 leads from the base of the transistor 69 to the collector of the transistor 62. A resistor 71 leads from the collector of the transistor 69 to the AND gate 20, not shown in this figure, which is shown in FIG. A pulse according to FIG. 3e is applied to this line. The emitter of the transistor

69 is connected to the supply voltage line 30.

By means of the clock generator 9, the transistor 33 is alternately conductive and non-conductive switched. If transistor 33 is in the non-conductive state, then flow through the voltage dividers ^ 3 and 44 and 41 and 42 as well as through the timers 35 and 36 and 31 and 32, apart from a certain one Residual current, no currents. If transistor 33 is blocked, transistor 37 becomes conductive via negation element 47 held so that capacitor 35 is discharged. At the inputs of the operational amplifiers 46 and 45 is located therefore almost the supply voltage 30 on. By suitable choice of the voltage divider with the resistors 43 and 44 and the resistors 41 and 42 can under

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Taking into account the residual currents, a voltage is achieved at the output of the operational amplifier 46 when the transistor 33 is blocked, while no voltage is present at the output of the operational amplifier 45. If transistor 33 is now switched to the conductive state, transistor 37 blocks. A current flows through the voltage dividers with resistors 43, 44 and 41, 42, which lowers the voltage at the positive input of operational amplifier 46 and at the negative input of operational amplifier 45. Shortly after switching on, the two other inputs of the operational amplifiers 45 and 46 still carry almost operating voltage, which drops exponentially over time due to the charging of the capacitor 35 or the current through the inductance 32. By changing the voltages applied to the voltage dividers, the operational amplifiers 45 and 46 change their state, ie when the transistor 33 opens, operational amplifier KS receives no signal at the output, while operational amplifier 45 emits a signal at the output. If the voltages at the timing elements fall below the threshold 25 given by the voltage divider over time, the operational amplifiers 45 and 46, which are connected as comparators, tilt back to their original state. Exceeding the threshold after turning off the transistor 33 has no further consequences, since the voltage dividers with the resistors 43, 44 and 41, 42 are switched beforehand so that the reference voltage is raised. The output signal present at the operational amplifier -6 is already proportional to the inductance in terms of its duration and thus to the air pressure. Since even at the lowest air pressure, at which the retardation should be 0, there is still a basic inductance, a

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Time can be subtracted accordingly. This signal is present at the output of the operational amplifier 45 and is also generated via an e-puncture, which is generated by the timer with the capacitor 35 and the Resistance 36 is given. The outputs of the two operational amplifiers are therefore linked by the NAND gate 48. At the output of the NAND gate 48 one obtains a pulse, the length of which is directly related to the differential air pressure (based on the pressure at which the adjustment 0 should be) is proportional. The pulses, which are proportional to the differential pressure, are passed through the transistor 49 negated and integrated on the capacitor 53. The longer the pulse emitted by the Nand element 48, the more the capacitor 53 is discharged via the resistor 52. The rest of the time the capacitor is 53 charged through the resistor 53 and 52. So it can be said that the voltage across the capacitor 53 is inversely proportional to the differential air pressure.

Of the actual ignition system, only the multivibrator with the electronic switch is shown, since the other components correspond to those of conventional electronic ignition systems. The multivibrator, which consists of the transistors 58 and 62, the capacitor 64 and the current sources 63 and 66 , tilts due to the negative differentiated pulses according to FIG. 3c, which are at the input 59 of the multivibrator. As a result of the tilting process, the capacitor 64 becomes Pig. 3d charged by the power source 63. The current source 63 supplies a constant current. The multivibrator is fed back through the resistor 61 so that it tilts after reaching a certain state of charge. The capacitor is then discharged by the current source 66 . The current that is output by the current source 66 is determined by the voltage on the capacitor 53. The stream of electricity

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source 66 is proportional to the differential pressure. The pulse ratio of the multivibrator is therefore dependent on the ratio of the currents of the current sources 63 and 66 to one another. The current sources 63 and 66 are shown here only symbolically; any known power source can be used. The pulses are buffered by transistor 69 and are used to retard known ignition systems, the output pulse being added to the original ignition pulse.

If the retardation is to be 0, the from Pressure controlled discharge current go towards infinity. However, this cannot be achieved, so that there is always a certain amount Adjustment remains. The operational amplifier connected as a comparator 5 ^ detects the pressure-dependent Voltage and switches over when a specified voltage is reached. The specified voltage is through the voltage divider from the resistors 55 and 56 determined. By switching at the output of the operational amplifier 54, the transistor 57 is blocked, so that the charging current of the current source 63 becomes 0 and thus also the adjustment, since there is no at the output of the multivibrator Signal is emitted. With this step function, the remaining adjustment can be eliminated.

The entire circuit arrangement is except for the inductance 32 can be easily integrated.

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Claims (10)

^R 6 0 2 1 Pd / Jä I6.I.I98O Robert Bosch GmbH, 7000 Stuttgart 1 Claims ' -., /. Arrangement for pressure-dependent adjustment of operating parameters an internal combustion engine with an inductance that changes as a function of the pressure, which is Resistance forms a timing element whose Zeitkonstar.te is a measure of the pressure, characterized in that Another timing element (2) is provided, the time constant of which is equal to the time constant of the pressure-dependent Timing element (1) is in its basic position, and that the two timers (1, 2) obtained from their time constant dependent pulses are subtracted from each other. 2. Arrangement according to claim 1, characterized in that the timing elements by means of electronic switches (7, 8) can be charged or discharged. 3. Arrangement according to claim 1 or 2, characterized in that the timing elements (1, 2) comparators (10, 11) are connected downstream are that change their state at a given charge state of the timing elements (1, 2). 130 0 33/0086 '60 4. Arrangement according to claim 3, characterized in that that the comparators (10, 11.). a Nand element (.12) connected downstream which causes a subtraction of the pulses emitted by the comparators (10, 11). 5. Arrangement according to claim 4, characterized in that that the pulse emitted by the Nand element (12) is converted into a direct voltage by means of an integrating element will · 6. Arrangement according to claim 5, characterized in that the DC voltage for controlling a multivibrator serves. 7. Arrangement according to claim 6, characterized in that the pulse length of the multivibrator is changed by controlling a current source (66) of a transistor branch of the multivibrator. 8. Arrangement according to one of the preceding claims, characterized ■ _ that a combination of a resistor (5) and a capacitor (6) is used as a further timing element (2). 9. Arrangement according to one of the preceding claims, characterized in that a clock generator (9) before 130033/0086 ORIGINAL BATHROOM is seen, which opens or closes the electronic switch (.7, 8). 10. Arrangement according to claim 9 »characterized in that that the clock generator is externally controlled. 130033/0086