DE3124211C2 - - Google Patents

Description

The invention is based on a circuit arrangement for triggering electrical switching operations depending on the speed of a Internal combustion engine according to the preamble of patent claim 1.

In a known circuit arrangement of this type according to the DE-OS 26 13 227 are the two, each coupled with a timing element Threshold switch through several temperature-sensitive gates formed, which are preferably combined in a COS-MOS module are. Such gates have a temperature-independent type speaking value, which however is subject to manufacturing tolerances. Do you want to this circuit arrangement a switching at a certain speed trigger the process, the timing elements must be opened by variable resistors the response value of the respective downstream gate stages exactly be true. For a series production of the circuit arrangement is but a manual comparison is very expensive.

An inexpensive solution is also not ent from DE-OS 28 47 290 acceptable, according to which a circuit arrangement for obtaining a disturbance tion-free trigger signals for fuel metering devices and the like. Contains threshold switches with differential amplifiers (Fig. 3). Also there is the threshold switch of a delay time control stage on Input with a variable resistor for setting the delay time connected to a capacitor connection of the timer.  

The invention has for its object to provide a circuit arrangement Trigger speed-dependent switching operations in the way to continue training that that a labor-intensive adjustment of the circuit on a be correct response value is no longer required.

The solution according to the invention with the characteristic features of Pa Tent claims 1 has the advantage that the switching threshold can be predefined from the outside with a comparator, so that a grouping and permanent assembly on the input side of the comparator connected components is possible. For this purpose the Kon capacitor for the first timer and the others on the first Components connected on the input side are used for comparators for example determined by a computer program and as a group arranged a circuit board. Another advantage is that the two comparators are available as an IC module and opposite COS-MOS gate modules have a smaller housing volume. To at an unstable switching state to the set response speed prevent, there is a feedback at the output of the second comparator connected, which advantageously with the on the voltage divider connected input of the first comparator is connected and therefore does not return to the timer connected to the other input works.

The measures listed in the subclaims are advantageous Continuous training and improvements to those stated in the main claim characteristics possible. So the feedback is preferably via a switching element, for example via a transistor. When calc voltage of the aforementioned components is the residual voltage of this  Transistors also taken into account, so that both the response speed as well as the switching hysteresis of the circuit arrangement, for example, in a computer program is entered, which is the values of the group belonging components for the fixed assembly calculated net.

drawing

Two embodiments of the invention are in the drawing shown and in the description below explained in more detail. It shows

Fig. 1, the inventive circuit arrangement with two-switching in the same phase angle comparators,

FIGS. 2a and 2b the course of the voltages at various points of the circuit arrangement of FIG. 1 below the response speed of the response speed and above,

Fig. 3 shows a circuit arrangement with two comparators switching in opposite phases.

Description of the embodiments

The circuit arrangement shown in Fig. 1 for triggering a speed-dependent switching process is used, for example, to shut off the fuel supply to an internal combustion engine when a certain speed is exceeded and the throttle is closed (shoe shutdown). As an input signal of the circuit arrangement, for example, the voltage pulses are used which occur in the ignition system of the internal combustion engine on the primary side of the ignition coil, not shown. These pulses are given to the input terminal 10 of the circuit arrangement. The input terminal 10 is connected via a diode 11 to a pulse shaper stage 12 , which consisted of an RC element 13 , an opposing line 14 in series and another RC element 16 in series. The RC element 16 is connected to the base of a switching transistor 17 , the switching path of which is connected in parallel to a capacitor 18 of a first timing element 19 . The capacitor 18 is connected via a counter 20 of the timer 19 to a supply line 21 . To stabilize the DC voltage on the supply line 21 , the latter is connected to the positive terminal 15 of the circuit on the one hand via a resistor 22 and a diode 23 connected in series as a reverse polarity protection, and on the other hand connected to ground via a Zener diode 24 and a smoothing capacitor 25 connected in parallel . The free end of the capacitor 18 , the emit ter connection of the npn-conducting switching transistor 17 and the RC element 16 of the pulse shaper stage 12 is connected to a second supply line 26 which is connected to ground and via a minus terminal 31 as well as the plus terminal 15 to one DC voltage of the vehicle electrical system is to be closed.

At the connection point ª between the resistor 20 and the capacitor 18 of the first timing element 19 , the minus input of a first comparator 27 is connected. The plus input of the comparator 27 is at the tap 28 of a voltage divider with the resistors 29, 30 , which is connected to the supply lines 21 and 26 . The output of the comparator 27 is connected at switching point b to a capacitor 32 of a second timing element 33 , the resistor 34 of which is connected to the supply line 21 . The capacitor 32 of the second timing element 33 is also connected at switching point b to the negative input of a second comparator 35 , while the free connection of the capacitor 32 is connected to ground via the supply line 26 . The plus input of the second comparator 35 is also connected via the line 36 to the tap 28 of the voltage divider 29, 30 . At the output of the second comparator 35 is the switching point c which is connected via a resistor 37 to the base of a further switching transistor 38 . The switching path of this npn-conducting switching transistor 38 , which triggers a speed-dependent switching operation, is connected on the collector side to the field winding 39 of a solenoid valve and connected to the positive terminal 15 . On the emitter side, it is connected to ground with the supply line 26 . To protect the switching transistor 38 , a Zener diode 40 is connected in parallel with its switching path.

The output at the switching point c of the second comparator 35 is fed back to the positive input of the first comparator 27 connected to the tap 28 of the voltage divider 29, 30 . The feedback be consists of a feedback resistor 41 connected to the tap 28 of the voltage divider 29, 30, which is connected to ground via the switching path of an npn-conducting transistor 42 with the supply line 26 . The base of the transistor 42 is located at the switching point c at the output of the second comparator 35 via a resistor 43 . Another resistor 44 is arranged between the supply line 21 and the output of the second comparator 35 .

The mode of operation of this circuit arrangement will now be explained in more detail with the aid of the voltage curves at the switching points ª, b and c shown in FIGS . 2a and 2b.

In the idle state, no pulses are given from the ignition system to the input terminal 10 . Consequently, the switching transistor 17 is blocked and the capacitor 18 of the first timing element 19 is charged via the resistor 20 . The voltage Ua of the capacitor 18 at the switching point ª is consequently above the switching voltage Us of the first comparator 27 . As a result, there is a 0 signal at the output of the first comparator 27 and the capacitor 32 of the second timing element 33 is consequently discharged. The voltage Ub in the switching point b that has reached the minus input of the second comparator 35 is zero. As a result, the output of the second comparator 35 carries an L signal. The voltage Uc in the switching point c thus controls the switching transistor 38 via the resistor 37 in the current-carrying state, whereby the excitation winding 39 of the solenoid valve is switched on. In addition, the transistor 42 is controlled via the resistor 43 from the output of the second comparator 35 in the current-carrying state, so that the feedback resistor 41 is connected to the resistor 30 of the voltage divider in parallel. As a result, the switching voltage Us for the switching of the comparators is fixed for both comparators 27 and 35 .

If the internal combustion engine is now operated in idle mode, a pulse train results at the input terminal 10 of the circuit arrangement. In Fig. 2a, the time interval of the pulses is denoted by t 1 . Through this In pulse, the switching transistor 17 is briefly switched to the current-carrying state via the Impulsfor stage 12 and thereby the capacitor 18 of the first timer 19 is suddenly discharged with each pulse. It then charges again via resistor 20 . This occurs in the switching point ª the United course of the voltage Ua , which reaches the negative input of the first comparator 27 . As soon as the voltage Ua reaches the voltage Us of the comparator 27 , it is reversed and a 0 signal occurs at its output, through which the capacitor 32 of the second timing element 33 is suddenly discharged. With the unloading of the capacitor 18 of the first timer 19 , the comparator 27 is also reset, so that the capacitor 32 of the second timer 33 can be charged via the resistor 34 . The circuit is designed in such a way that the time constant of the first timer 19 is substantially smaller than the time constant of the second timer 33 . This ensures that the voltage Ub in the switching point b remains with certainty below the switching voltage Us of the second comparator as long as it is cyclically discharged by the first comparator 27 . The output of the second comparator 35 therefore carries an L signal unchanged and consequently the transistors 38 and 42 are still kept in the current-carrying state by the voltage Uc at the switching point c .

If the speed of the internal combustion engine now reaches the response speed predetermined by the dimensioning of the circuit arrangement, the time t 1 between two input pulses is no longer sufficient to charge the capacitor 18 of the first timing element 19 up to the switching voltage Us of the first comparator 27 . The course of the voltage Ua at point ª of the circuit shows Fig. 2b. The comparator 27 is now no longer switched over and the capacitor 32 of the second timing element 33 gradually charges further via the resistor 34 . After a time t 2 , the voltage Ub at point b of the circuit therefore reaches the switching voltage Us of the second comparator 35 . The voltage Uc at point c at the output of this comparator 35 is now switched to 0 V. This blocks transistors 38 and 42 . The solenoid valve, not shown, which is arranged in an idle channel on the gasifier of the internal combustion engine, thereby blocks the fuel supply. Almost simultaneously, the feedback resistor 41 is switched off by the transistor 42 and the switching voltage Us of both comparators 27 and 35 is raised somewhat as a result. This prevents the comparators 27 and 35 from reaching an unstable state when the switch speed is reached. To ensure that a too rapid switch-off of the feedback resistor 41 causes a multiple switchover with the raising of the switching thresholds at the comparators 27 and 35 , a capacitor 45 may be connected to ground at the output of the second comparator 35 , which is shown in FIG. 1 is shown in dashed lines.

The feedback of the output from the second comparator 35 to the positive input of the first comparator 27 can take place in various ways. Thus, the transistor 42 , which connects the feedback resistor 41 to the resistor 30 of the voltage divider 29, 30 in parallel, can be omitted if, instead of the feedback resistor 41, a broken line shown in FIG. 1 with a feedback resistor 46 and a diode 47 in series therewith Collector connection of the switching transistor 38 is connected. When the switching transistor 38 is conductive, the feedback resistor 46 is connected in parallel to the resistor 30 of the voltage divider 29, 30 .

Fig. 3 shows a second embodiment of the inventive circuit arrangement, in which for simplification, the pulse shaper 12 and the first time element 19 of Fig. 1 has been omitted. The other construction elements are provided with the same reference numbers in accordance with FIG. 1. The circuit-technical difference is, however, that the second comparator 35 according to FIG. 3 with its negative input via line 36 at the tap 28 of the voltage divider 29, 30 is ruled out, while the positive input is on the capacitor 32 of the second timing element 33 . As a result, a signal inversion occurs at the output of the second comparator 35 compared to the circuit according to FIG. 1. Consequently, the switching transistor 38 is blocked below the response speed and the excitation winding 39 of the solenoid valve is switched off. Only when the response speed is reached, the switching transistor 38 is switched via the output of the two comparators 35 into the current-carrying state.

To generate a switching hysteresis, the feedback from the output of the second comparator 35 must be placed on the positive input of the first comparator 27 in this circuit design so that the switching threshold of the first comparator is also raised when the response speed is exceeded when the signal is reversed at the output of the second comparator 35 . For this purpose, the transistor 42 for the feedback resistor was 41 now connected via the resistor 43 to the collector of the switching transistor 38 . When the response speed is reached, the transistor 42 is thereby blocked and the feedback resistor 41 is ineffective. As in the embodiment of FIG. 1, the response threshold of the comparators 27 and 35 is raised, so that the circuit arrangement voltage tilts back to its original state only when the speed drops when the response speed falls below a certain amount. Depending on the size of the switching hysteresis, an upper and a lower response speed can be determined by dimensioning the circuit arrangement.

The invention is not limited to the illustrated exemplary embodiments, since, for example, the feedback can take place via a feedback resistor lying in parallel with the upper resistor 29 of the voltage divider. This must be connected in parallel by a corresponding coupling at the output of the second comparator only when it reaches the upper response speed to the resistor 29 . Such an electronic speed relay can also be used to change the ignition timing, to switch off the ignition as a speed limitation and for a speed-dependent electronic transmission control.

Claims (3)

1.Circuit arrangement for triggering electrical switching operations depending on the speed of an internal combustion engine, from the ignition system of which speed pulses discharge the capacitor of a first timer with a smaller time constant via a pulse shaper stage, which is connected to an input of a first threshold switch, the output of which is the capacitor of a second Bridges timer with a larger time constant, which is connected to an input of a second threshold switch, the output of which controls an electronic switching element to trigger the switching process, characterized in that the two threshold switches ( 27, 35 ) are two comparators, each with a first input ( a, b) on the capacitor ( 18, 32 ) of a timing element assigned to them on the output side ( 19, 33 ) are connected and with their second input for the exact setting of the switching threshold at the tap ( 28 ) of a common voltage with the supply connected voltage divider ( 29, 30 ) and that the output signal of the second comparator ( 35 ) is fed back to the second input of the first comparator ( 27 ) connected to the tap ( 28 ) of the voltage divider ( 29, 30 ). 2. Circuit arrangement according to claim 1, characterized in that the tap ( 28 ) via a feedback resistor ( 41 ) and via the switching path of a transistor ( 42 ) to one of the supply lines ( 21, 26 ) and the base of the transistor ( 42 ) is connected to the output of the second comparator ( 35 ). 3. Circuit arrangement according to claim 1 or 2, characterized in that the tap ( 28 ) of the common voltage divider ( 29, 30 ) via a feedback resistor ( 46 ) and a diode ( 47 ) at the collector terminal of the transistor serving to trigger the speed-dependent switching process ( 38 ) is connected.