DE3707932C2 - Circuit arrangement for switching off electronic systems - Google Patents

Description

The invention relates to a circuit arrangement for switching of units for internal combustion engines according to the preamble of claim 1.

From DE-OS 25 30 955 is one Circuit arrangement for a spark ignition engine associated fuel injection system known with the Difficulties to be avoided when starting the Internal combustion engine, so when you switch on the known Circuit arrangement, can occur. Difficulties consist essentially in the fact that when it is turned on can happen that a sensor organ unintentionally briefly goes back to a shutdown position and so downstream Units, for example an electric pump for Fuel, turns off. This leads to one in the start phase of course undesirable engine standstill. Furthermore, it should be achieved that the working hours of a Cold start valve independent within certain limits on the duration of the startup process. To fix the Difficulties arise with the circuit arrangement mentioned proposed to provide delay elements. Over a Computer control is in the known circuit arrangement nothing said.

From JP-171744 and Patent Abstracts of Japan, Volume 9, No. 25 (M-355) (1747), February 2, 1985 is a circuit arrangement for switching Aggregates of internal combustion engines known, with an ignition switch, a relay and an arithmetic unit, which their operation receives voltage from a switchable voltage source by the Ignition switch can be turned on, and that with a shutdown circuit connected in response to the ignition switch and on Control signals a main relay is switchable.

From JP 57-1791724 and Patent Abstracts of Japan, Volume 7, No. 42 (P-177) (1187), February 19, 1983, it is also known to computer-controlled electronic systems and the power supply until the permissible shutdown of the relay stops only during a Switch over bridging phase, which means only a small load is represented for the energy source.

It has proven to be beneficial by turning it on of the ignition switch a computer or computer circuit to put into operation, the then diverse tax and Control tasks for downstream units, in some cases depending on sensors. Becomes a such computer-controlled electronic system  the ignition switch to its operating voltage, may the computer does not switch off its own operating voltage as long as the ignition switch is closed. Independent depending on the position of the ignition switch should be peripheral Units, e.g. hot wire air flow meter (HLM) or electric fuel pumps (EKP) from the computer and can be turned off. This is supposed to be by providing the supply voltages for the Loss conduction resulting in aggregates as low as possible being held.

When the ignition switch has been opened, the computer should can even determine the timing if its own Operating voltage is switched off in this way to ensure that only a small load on the Energy source (battery) that supplies the entire system occurs. Under no circumstances and at any time after the calculator once a pulse to switch off the own operating voltage, a restart switch your own operating voltage or the units respectively. Beyond that, without further precautions uncontrolled voltage profiles occur when switching off, which also does not lead to an unintentional re-entry may lead switch.

The invention is based on the object to achieve an extremely safe shutdown, that of Stör influences is not affected and being a the greatest possible freedom in determining the sequence the switching off of individual units is provided.

This object is solved by the features of claim 1.

In addition, the circuit arrangement according to the invention not only usable with internal combustion engines if here their main area of application also lies, but can in principle Lich with all computer-controlled electronic Systems are used, which by an input formation applied to an operating voltage and later should be switched off again.

The switchable voltage source is preferably a Provide self-holding device that according to certain Conditions can be overridden by the shutdown circuit is. This can be achieved in a particularly simple manner be that the computer is safe with operating voltage voltage is supplied until it reaches its own operating voltage can finally switch off.

Another benefit arises when the shutdown circuit Switching elements or a logic circuit, preferably a logic IC, of which when a Control signal to another switching element of the shutdown Circuit of the main relay can be switched on when the Ignition switch is open. The main relay takes over so essential tasks in the shutdown and is as long as the ignition switch is closed, inactive and therefore does not burden the entire arrangement.

To switch off in this context according to a another advantageous embodiment of the invention Circuit arrangement suggested that the shutdown circuit  Switching elements, which in turn are also called logic circuits, can preferably be designed as a logic IC points, of which when a control signal is applied to another switching element of the shutdown circuit of the Span voltage regulator and the main relay can be switched off if the ignition switch is open.

A relatively particularly inexpensive circuit arrangement is achieved when in an advantageous manner the switching elements in the aforementioned Ausfüh tion forms are npn transistors, the main relay connected to the collector of the first transistor is the base of which is the collector of the second transis tors is connected, the base of which is connected to a second diode with the ignition switch and via a third diode with the Fourth transistor collector and latch direction is connected, the collector of the third transis tors via a resistor to a supply voltage placed and the emitters of all four transistors each are grounded.

An even simpler design of the shutdown switch circle (without switch-on function) results from use two npn transistors as switching elements, the Main relay attached to the collector of a transistor is closed, the basis of which is resisted to the Collector of the other transistor is connected.

When switching the main relay, the induct occurs Activity of the relay coil voltage peaks that the respective Could jeopardize transistor that switches the main relay. Here, however, can be done in a simple, advantageous manner specify a protection circuit which consists in that the cathode of a Zener to the collector of the transistor diode is connected, the anode of which is connected to the base of the Transistor is connected. Excessively high voltage peaks  are therefore derived via the Zener diode.

Another advantage of the circuit according to the invention according to a further embodiment the provision of another relay, which in Response to a control signal from the computer circuit switchable and its contact the contact of the main relay is connected in parallel. This relay can further aggre supply gate, regardless of the listed head relay. In this context it should be pointed out be that the term "relay" goes without saying not on relays actuated by means of a coil with mechani switch contacts is limited, but basically suitable electronic switching devices for this can be used.

drawing

The invention is explained in more detail below with reference to preferred exemplary embodiments, from which further advantages and features emerge. Fig. 1 shows a system block diagram of a computer-controlled electronic system and Fig. 2 shows a more detailed representation of the associated shutdown circuit. In Fig. 3, a further advantageous embodiment of a computer-controlled electronic system is shown in the block diagram and accordingly Fig. 4 shows more details of an associated shutdown circuit.

Description of the embodiments

The exemplary embodiments are computers controlled electronic systems by an input information (ignition switch) to your operating voltage become. Such electronic systems can for example as in electronic ignition systems for internal combustion engines  Find use.

In Fig. 1, a block diagram of a circuit arrangement is shown, in which a switching device SG indicated by dashed lines is connected to external components. The individual components of the switching device SG can be combined on a circuit board.

A supply (battery) voltage UB is connected to a terminal 18 and via a (ignition) switch 15 to a terminal 27 . Furthermore, a connection of the actuating coil of a relay (EKP relay) for an electric fuel pump and a contact of switch contacts 10, 20 of this relay are connected to the voltage UB. The switch contact 10 leads to an electric fuel pump EKP and the contact 20 to a hot wire air flow meter HLM. The other connection of the coil of the EKP relay is connected to a terminal 3 of SG.

Further units are connected to the contact 20 , which is not connected to the UB, of which, for example, a Hall sensor HALL and injection valves EV and an idle actuator EWD are shown. The latter is connected via an unmarked terminal from SG.

The switching device SG has a computer circuit μC, for example a microprocessor, to which external peripheral devices such as memory (RAM), input / output devices I / O or the like are connected. The computer μC has an output (port) (a) from which a control signal can be output to an amplifier stage T1, which is connected to a coil connection of a main relay HR, the other coil connection of which is connected to a voltage source VDD via a diode. The main relay has a switch contact, one end of which is connected to terminal 18 and thus UB and the other end of which is connected to switch contact 20 (EKP relay) and, via a diode, to a driver stage MJ44.

From terminal 27 , a connection leads via a diode to a switch-on input ON of a switchable voltage regulator 50 , for example of the type CG 31, to which the supply voltage UB is supplied via terminal 18 at an input TN and from which an output voltage VDD can be output, and as long as there is a signal at input ON. The output voltage VDD is given to a designated input of the computer μC.

The voltage VDD is also fed to a switch-off and self-holding circuit 60 which is connected via a diode D1 for the self-holding of the voltage regulator 50 to its switching input ON. Furthermore, the circuit 60 is connected to the terminal 27 and a gate leading to the amplifier T1 and to the output (a) of the computer μC.

Fig. 2 illustrates further details, including the shutdown circuit 60th This has transistors T1, T2, T3 and T4 described in more detail below as switching elements. All transistors T1 to T4 are npn transistors. T1 is used to switch the main relay HR, which is connected via a diode to the collector of T1, whose emitter is connected to ground. If T1 switches through, the main relay HR picks up. To discharge voltage peaks when switching HR, the collector and base of T1 are bridged by a Zener diode DZ. The base of T1 is connected to the collector of T2 and via a resistor to the output VDD of the voltage regulator 50 . The emitter of T2 is connected to ground and the base of T2 via a diode D2 and a resistor at terminal 27 and a diode D4 and a resistor to the base of transistor T3. Furthermore, the base of T2 is connected to the collector T4 via diodes D2, D3 connected in opposite directions and to the self-holding path R1, D1 of the switchable voltage regulator 50 . The emitter of T4 is connected to ground and the base firstly via a resistor to ground, secondly via resistors R10, R11 and a diode at terminal 18 (UB) and thirdly via a resistor and a diode to the output (a) of the computer μC and connected a resistor to VDD.

The function of the circuit arrangements shown in FIGS . 1 and 2 is as follows:

In normal operation, the ignition switch terminal 15 is closed and the hot wire air flow meter HLM is supplied with operating voltage UB via contacts 20 of the EKP relay. The contacts 10 of this relay supply the fuel pump EKP accordingly. The main relay HR is not controlled by the computer μC in this operating state and therefore does not require any (power loss) power that could otherwise interfere on the circuit board of the switching device SG.

If the ignition switch is opened, the contact of the main relay HR is forcibly connected in parallel to the contacts 20 of the EKP relay. The EKP relay can now be switched off, specifically controlled by the computer μC, without the voltage supply UB for HLM and VDD for μC being interrupted. The output (a) of μC is used to control the main relay HR and to safely switch off its own operating voltage. When the ignition switch terminal 15 is closed: Output (a) "Low": HR switched off, Output (a) "High": HR switched on. In contrast, with the ignition switch open, terminal 15 : (a) "Low": HR switched on, (a) "High": HR switched off (switching off the computer's own operating voltage μC). Safe switching off of your own operating voltage is achieved by using the battery voltage UB. The circuit loads the battery very little when switched off, for example with 200 µA.

In detail, the circuit arrangement works so that when the ignition switch terminal 15 is closed and thereby the voltage regulator 50 is switched on, so that the computer μC is supplied with the operating voltage VDD. T3 is conductive. As a result, the computer μC can use output (a) to determine whether T4 is conductive (consequence: T2 blocked, HR switched on) or whether T4 is blocked (consequence: T2 conductive, HR is switched off).

To turn off the ignition switch terminal 15 is opened. If the computer has previously blocked T4, the voltage regulator 50 remains switched on via the self-holding path D1, R1. T3 also remains conductive. However, T2 no longer receives a base current and T1 becomes conductive, which causes the main relay HR to pick up.

If the computer μC now switches its output (a) to "High", T4 becomes conductive and T3 is kept conductive via UB, R11, R10, regardless of the status of the computer output (a). The voltage regulator 50 is switched off and the main relay HR drops out.

By coupling UB, R10 and R11 to the base of transistor T4 is a safe shutdown of the own operating voltage VDD of the computer μC, as long as UB is greater than or equal to 6 V. However, this is unproblematic, because such low voltages only when Start can occur in which on and not off is tested.

In the further embodiment shown in FIGS . 3 and 4, the main relay is not arranged on the circuit board of the switching device SG, but outside. The structure of the circuit according to the block diagram of FIG. 3 should be easily understandable after the above explanations. However, the shutdown circuit 80 is different from the shutdown 60 and should therefore be discussed in detail.

The shutdown circuit 80 is shown in FIG. 4 and has five connections (compare FIG. 3), namely HR for the main relay HR, terminal 37 , ignition switch terminal 15 , operating voltage VDD from the voltage regulator 50 and μC for connection to the computer μC.

Terminal HR is connected to the collector of a Darlington transistor T220, the emitter of which leads to the base of a transistor T221, which is provided for current limitation in the event of a short circuit of HR to UB. The base and collector of T220 are bridged by a capacitor C220 to prevent vibrations when switching off and a zener diode D220, which has the same function as the diode DZ in FIG. 2. Furthermore, the base of T220 is connected to the collector of another via a resistor R222 Transistor T222 connected, the base of which is connected via a diode D223 and a resistor R237 to the output of the computer μC. Furthermore, the base of T222 is connected to HR via a resistor R221.

The function of the circuit arrangement shown in FIGS. 3 and 4 is as follows:

When the ignition switch terminal 15 is closed, T220 becomes conductive via D221, R221. When the switch terminal 15 is closed, T220 is always conductive, even if T222 is on. If the computer switches μC to "Low", T222 is no longer activated, since HR has picked up. There is a maximum of about 3 V at the collector of T222, which is too little for one line.

If the ignition switch terminal 15 is now switched off (open), then via terminal 37 , which is supplied by the contacts of the main relay HR, and via R223, R222, the transistor T220 is kept conductive. With a "high" signal from the computer μC, T222 is conductive. Terminal 37 can no longer keep T220 conductive and the base of T220 is pulled to ground potential, since terminal 15 is switched off and it is no longer possible to conduct via R221. The main relay HR therefore switches off. T222 is kept conductive via R224, R225.

If the computer switches μC to "Low", T222 remains conductive, since about 220 µA flows at 14 V via HR, which has a resistance of approximately 80 to 120 ohms. Therefore, HR can no longer be switched on, so it remains safely switched off. HR can only be restarted using the ignition switch (terminal 15 ).

Claims (6)

1.Circuit arrangement for switching units for internal combustion engines with an ignition switch and at least one relay, with a computer circuit (μC) which receives its operating voltage (VDD) from a switchable voltage source ( 50 ) which can be switched on by the ignition switch (terminal 15 ) and with a Switch-off circuit ( 60, 80 ) is connected, of which a main relay (HR) can be switched in response to the ignition switch and to control signals of the computer circuit (µC), characterized in that the switchable voltage source ( 50 ) is provided with a self-holding device (R1, D1) is provided, which can be overridden by the switch-off circuit ( 60 ), the switch-off circuit ( 60 ) having switching elements (T1, T2, T3) or a preferably integrated logic circuit, of which when a control signal is applied with a first level (LOW) at the input of the shutdown circuit ( 60 ) via a further switching element (T4) of the shutdown circuit, the main relay (HR) can be switched on, we nn the ignition switch (cl. 15 ) is open. 2. Circuit arrangement according to claim 1, characterized in that the switching elements (T1, T2, T3) (T220) or the preferably integrated logic circuit of the shutdown circuit ( 60 , 80 ) when applying a control signal with a second level (high) the switchable voltage source ( 50 ) and the main relay (HR) can be switched off at the input of the switch-off circuit ( 60 , 80 ) via the further switching element (T4) (T222) of the switch-off circuit when the ignition switch (terminal 15 ) is open. 3. Circuit arrangement according to one of claims 1, 2, characterized in that the switching elements (T1, T2, T3, T4) are npn transistors, the main relay (HR) being connected to the collector of a first transistor (T1), the Base is connected to the collector of a second transistor (T2), the base of which is connected to the ignition switch (terminal 15 ) via a first diode (D2) and to the collector of a fourth transistor (T4) via a second diode (D3) its base receives the control signal and the self-holding device (R1, D1) is connected, the collector of a third transistor (T3) is connected to a supply voltage (UB) via a resistor (R11) and the base of the third transistor (T3) is connected via a resistor and a third diode (D5) is connected to the collector of the fourth transistor (T4) and the emitters of the four transistors (T1, T2, T3, T4) are each connected to ground. 4. Circuit arrangement according to one of claims 1 or 2, characterized in that the switching elements (T220, T222) are npn transistors, the main relay (HR) to the Collector of a fifth transistor (T220) connected whose base is connected to the resistor via a resistor (R222) Collector of a sixth transistor (T222) connected which receives the control signal at its base. 5. Circuit arrangement according to one of claims 3 or 4, characterized in that to the collector of the first or fifth transistor (T1, T220) the cathode of one Zener diode (DZ, D220) is connected, the anode of which connected to the base of the first and fifth transistor is.   6. Circuit arrangement according to one of claims 1 to 3, characterized characterized in that a further relay (EKP) is provided, in response to a control signal from the computer circuit (µC) can be switched on and its contact is the contact of the main relay (HR) is connected in parallel.