SU739979A1 - Device for detecting upper dead center of internal combustion engine - Google Patents

Description

the signal at the output of the peak detector6 () and the maximum amplitude of the signal at the output of the signal sensor. The accuracy of determining the TDC of the piston is relatively low due to the fact that the threshold triggering value of the comparator is different from zero. The aim of the invention: it is to increase the accuracy of the device. This goal is achieved by the fact that the device additionally contains a dynamic memory element, an assembly element and a controlled pulse generator, the dynamic memory element being connected between the peak detector and voltage cell, one of the inputs of the assembly element is connected to the output y (element 1). pulse generator, the control input of which is connected to a kg output key and to another input of the assembly element whose output is connected to the control input of the dynamic storage element and through the first pulse shaper — with the control input of the Peak detector; Fig. 2 is a diagram of the signals at the outputs of the elements of the device. The device contains an inductive sensor 1 installed against the flywheel of the engine, the output of which is connected to the device 2. The output of amplifier 2 is connected in series with the peak detector 3 of the dynamic memory element U and the voltage divider 5 connected to one of the inputs of the comparator 6 and directly to its other input and to one of the inputs of the comparator 7 "The output of the comparator b is connected to one of The trigger trigger, 8, and the output of the KOMnaipatopa 7, to the input of the terminal 9 pulses. The output of the latter is connected to the input of the key TO, the control input of which is directly / accurate to the output of the trigger 8. The output of the key 10 is coy long with the control input of the Controlled pulse generator 11 and with one of the inputs of the assembly element 12, another EDMS | The output of the generator is x, and the output of element 12 is directly connected to the control input of the dynamic storage element and through the driver of 13 pulses to the control input of the Peak detector 3. Index 1 denotes the input of the comparator 7, which has zero potential, and index 15 - device output. The value of the natural frequency f. following impulses of oscillator 11 is set lower than the lower value fff of the working frequency range of sensor I. An impulse arriving at the control input of oscillator 11 affects the timing chain so that it disrupts oscillator oscillations. For example, if the latter is implemented on the basis of a multivibrator with RC-time, the driving chain is a pulse at the control, input capacitance of this chain. As a result, no pulses: the generator output 11 is generated, with the pulse frequency at the control input higher than the natural frequency of the generator pulses. Dynamic memory element 4 has two modes of operation: in the absence of a signal on its controlling path, element A operates in the sampling mode (repetition) of the input signal, and in the presence of a signal on the control input, it is in the memory mode. The device works as follows. Let the engine be in an idle state. In this case, signals at the output of sensor 1, at the output of amplifier 2, and, therefore, at the inputs of peak detector 3 and comparators 6 and 7 are absent. The generator 11 generates pulses with a certain repetition rate equal to f. The pulse, which appears at the output of the generator 11, passes through the assembly element t and enters directly; but on the control, the input of the dynamic storage element k is set to Ba; j is the last in the signal sampling mode (From the output of the peak detector 3. On the falling edge of the 1j generator pulse, the driver 13, which resets the peak detector 3 from the initial zero state and triggers the trigger 8 to the zero state in which the key 10 is closed. Simultaneously, on the trailing edge of the impulse gene

Claims (1)

gS SSsiSi-ratora 11 element Ji switches to the storage mode of the signal level set at the peak detector output; 3 by the time it is reset. The signal level recorded at the output of the element k decreases by k ", once with the help of the voltage divider 5 and goes to one of the inputs of the comparator 6. Since in the described case the signal at the output of the amplifier 2 is absent, the outputs of the peak detector 3, element k and divider 5 at both inputs of the comparator 6 is set to zero potential. At the same time, the comparator 6 is shifted in one of the circuits so that regardless of the noise level of the circuit, there is no signal at its output and, therefore, trigger 8 remains in the initial zero state, corresponding to favoring the closed state of the switch 10. Both inputs of the comparator 7 is also equal to zero potential. Due to the internal noise of the circuit and the drift of the offset of the comparator 7, the latter can operate and cause the turn of the driver 9 to turn in turn. However, since the key 10 is closed, there is no signal at the output 15 of the device. ; Let the engine start and accelerate to a predetermined speed, which corresponds to the frequency 1 output of the sensor 1: fj fy signal. Suppose that the output of sensor 1 is impulse of positive polarity, occurring when passing through the individual sensor 1 TDC mark on the flywheel engine In MOMeHt, the occurrence of a pulse at a wig of amplifier 2, comparators 6 and 7, are triggered. With this, a signal appears at the output of the comparator 6, which sets the trigger 8 into one state, in which the key 10 opens c. At some point in time, the output of the peak detector 3 detects the level of the signal Uyy, corresponding to the amplitude value of the increased pulse. At the moment of passing the TDC, the pulse changes its 1X) polarity, which causes the comparator 6 and 7 to work backward. At this moment, shaper 9 is triggered on the falling edge of the cdparator 7 pulse, which forms a short pulse that passes through the open key 10 to the device output 15 . At the same time, the same impulse from the output of the key 10 enters the non-controlling input of the generator 11, disrupting its next oscillation, and on,. the input of the assembly element 12. The signal from the output of the latter arrives at the control input of the element k, transferring it to the V | r signal mode of the U signal from the output of the peak Detector 3. On the falling edge of the pulse of the imaging unit 9, the imaging unit 13 triggers the trigger 8 to its initial zero state . In this case, the key 10 is blocked. At the same time, the pulse from the output of the imaging unit 13 arrives at the control input of the peak detector 3 and sets it to the initial zero state. At the output of the element, the signal level and j is fixed, and at the input of the comparator 6, connected to the output of divider 5, a threshold signal level is equal. Thus, as a result, at the input of the comparator 6 connected with divider 5, a threshold level proportional to the value amplitudes of the signal of the TDC mark. and at exit 15, at the instant of the reverse triggering of the comparator 7, a short pulse is generated. The leading edge of this pulse corresponds to the moment of polarity of the signal from the TDC grid, since the threshold value of the comparator 7 is set constant and equal to zero. The above-described process of forming a signal at the output 15 of the device repeats when the next pulse of positive polarity appears at the output of amplifier 2 with amplitude and j exceeds the threshold level of comparator 6 established at the output of divider 5. In this case, if the amplitude of this pulse differs from the amplitude previous pulse, i.e. , then the output of the divider 5 automatically sets a new threshold level for the operation of comparator 6, equal to Uyy, f / kj ,. The process of forming a signal at the output 15 of the device described above does not occur when the output of the amplifier 2 of the next positive polarity with an amplitude lower than the threshold level of the comparator 6, which is set at the output (e divider 5), does not change. Since the amplitude of positive pulses caused by passing the TDC mark past sensor 1 is always greater than the amplitude of pulses caused by flywheel defects, the threshold level of the comparator 6 is determined only by If the condition is kc. k, where is the signal / fur ratio at the sensor output G, the appearance of impulses caused by flywheel defects does not trigger the comparator 6, and hence the signal at the device output 15. At the changes in the amplitude of the signal of the TDC mark caused by the development of the engine operating mode, the horn level C {of the comparator 6 is automatically set with the arrival of each next pulse of the bit signal. Thus, the introduction of new elements is the Dine (amycheo) GS Ea1Pomynayustsiy element ,. assembly element W control; Lambo pulse generator - advantageously distinguishes the proposed device from the prototype, as it allows automatically, without the participation of the operator, to generate a response threshold at a given rate of signal / disturbance in the working circuit of the rotation of the crank shaft of the digger, which simplifies the process of marking the ticker signal. to generate an output signal at the time of changing the polarity of the signal of the inductive sensor, which increases the accuracy of the formation of the signal of the TDC mark, the claims. A device for determining the top dead center of an internal combustion engine comprising an inductive sensor, an amplifier, a first and second comparators, a first and second pulse shaper, a peak detector, a voltage divider, a trigger and a key, the sensor being connected through an amplifier to one of the inputs of the first comparator and to the input of the peak detector, the output of the voltage divider is connected to another input of the first comparator, one of the trigger inputs is connected to the output of the first comparator, the other input is connected to the output of the first driver pulses, and the output is with a control key input, which is so that, in order to improve the accuracy, the device additionally / includes / but contains a dynamic storage element, an assembly element and a controlled pulse generator and a dynamic memory element is connected between the output of the KuKoyogo detector and the input of a voltage divider, one of the inputs of the assembly is connected to the output of a controlled pulse generator, the control input of which is connected to the output of the key, and to another input of the assembly that is OUT and connected to the control input of the dynamic storage element and through the first driver of the pulses to the control input of the peak detector, the output of the amplifier is connected in addition to one of the inputs of the second comparator, to the other input of which the potential is zero potential, and the output of the key is connected to the output through the second pulse generator . , Information sources taken into account during the examination 1. US Patent IP 3839906, cl. 73-1t5 published, 197