DE4403309A1 - Electronic controlled with dual energisation circuits for motor vehicle - Google Patents

Abstract

An electronic controller (9) for a motor vehicle is energised via either of two input terminals (A,B) where terminal (A) is made live by operating the ignition switch (Sz) and the voltage regulator (3) together with the microprocessor (4) is then energised via the diode (2). Both inputs to the AND gate (5) are thus made and relay (7) is activated via the transistor (6) closing the contact (8) to provide a hold-on circuit via the terminals (D,B) and diode (1). On switching off the ignition relay (7) is de-energised via the gate (5) and transistor (6) but its opening is delayed to maintain power to the controller (9) to enable all necessary close-down routines to be performed in readiness for next start.

Description

The invention relates to a control device with a first, via an electrical commissioning utility power supply input and with a second, fed via a permanent supply connection Supply input according to the generic term of Pa claim 1.

Such a control unit is used for example for the engine control in BMW series vehicles. Known engine control units of this type contain an output via which a main relay is driven, via which a permanent supply connection, for example when the ignition is switched on. B. the positive pole of the battery, with a latching supply connection (terminal 87 ), which is usually used for the common voltage supply of several control units. This connection via the main relay is delayed again when the start-up supply connection (terminal 15 ) is switched off, especially when the ignition is switched off. This switching arrangement ensures a short-term electrical supply of electrical consumers via the self-holding supply connection after the ignition has been switched off. This short-term supply is necessary, for example, to ensure a defined shutdown routine for control units. The known engine control units themselves have, on the one hand, a first supply input connected to a start-up supply connection (terminal 15 ) and, on the other hand, a second supply input connected to a permanent supply connection. The electrical supply of the second supply input via the permanent supply connection, which is usually permanently connected to the battery (terminal 30 ), has the disadvantage that when the ignition is switched off, quiescent current is drawn from the battery via the second supply input, which means that it is switched off for longer periods A deep discharge of the battery is possible for vehicles.

It is an object of the invention, the above Control device to improve such that a quiescent current need is avoided with parked motor vehicles.

This task is characterized by the characteristic of Claim 1 solved.

According to the second supply input is not fixed, but via the self-holding supply connection connected to the permanent supply connection. With this Training according to the invention of the initially described Control unit is a connection of a supply unit was no longer necessary with a permanent supply connection agile.

An advantageous development of the invention is the Ge Subject matter of claim 2.

According to the invention, both the first and the lead second supply input inside the control unit to one electrical voltage regulator to the control unit both with the ignition switched on and also after switching off the ignition during the self-holding phase of the self keep supply connection evenly with voltage supply. Of course, the first and / or the second supply input also with other components  of the control unit. However, one is important sufficiently long supply of the voltage regulator and there with an even supply voltage for the control unit tes also during a shutdown of the motor vehicle power operation, especially when the control unit is turned off the motor vehicle no longer has a permanent supply is standing.

In the drawing is an embodiment of the Erfin shown. It shows

Fig. 1 is a control device according to the prior art and

Fig. 2 shows a control device according to the present invention.

A control device 9 has in Fig. 1 a first via an electrical start-up supply connection A 'fed supply input A, a second via a cross supply connection U⁺ fed supply input B and a third supply input C fed back from a self-holding supply connection D. . An output of the control unit 9 is connected to a self-holding element 7 in the form of a relay, which opens or closes a switch 8 as a function of the switching signal given by the output of the control unit 9 , in order to connect the self-holding supply connection D to the permanent supply connection U ⁺ to connect or disconnect from it.

The control unit contains a voltage regulator 3 , which is connected to a microprocessor 4 via a supply line. The first supply input A and the second supply input B each lead to one input of the voltage regulator 3. An output of the microprocessor 4 leads to a first input of an AND gate 5 , the further input of which is connected to the first supply input A. The output of the AND gate 5 is connected to the base of a switching transistor 6 for outputting the switching signal via the output of the control unit 9 .

The commissioning supply connection A 'is example switchable via the ignition switch S _Z (terminal 15 ) to the supply connection A. The permanent Ver supply connection U⁺ corresponds, for example, to the positive pole of the battery (terminal 30 ) and the latching supply connection D is, for example, the main relay supply connection which is usually referred to as terminal 87 .

When the ignition switch S _Z is closed, the voltage regulator 3 receives a switch-on pulse via the first supply input A. Via the second supply input B, the voltage regulator 3 is fed by the connection to the permanent supply connection U⁺. The voltage regulator 3 supplies the control unit 9 and in particular the microprocessor 4 with a uniform voltage. As long as the ignition switch S _{Z is} closed and the start-up supply connection A is switched on or supplies voltage at the first supply input A and the voltage regulator 3 is also supplied with voltage via the supply input B, the AND gate 5 switches the switching transistor 6 through, to close the switch ter 8 via the relay 7 . As a result, the self-holding supply connection D is connected to the permanent supply connection U⁺.

If the ignition switch S _{Z is} turned off, so that the commissioning supply connection is switched off from the first supply input A, the switching transistor 6 is blocked via the AND gate 5 . The switch 8 is kept closed via the relay 7 for a predetermined time (self-holding phase), after which the self-holding supply connection D is switched off with a delay by the permanent supply connection U⁺. Via the third supply input C z. B. still shutdown routines to prepare the control unit for how the switch-on phase is carried out. After the delayed switching off of the permanent supply connection U⁺ from the self-holding supply connection D, the permanent supply connection B is still present at the second supply input B. As a result, control unit 9 from FIG. 1 consumes quiescent current via voltage regulator 3 .

This disadvantage is prevented in the control device 9 according to FIG. 2:

In Fig. 2 coinciding with Fig. 1's electrical components are provided with the same reference numerals. The control device 9 from FIG. 2 differs from the control device 9 according to FIG. 1 in that only two supply inputs A and B are provided. The first supply input A continues to be fed via the electrical start-up supply connection A '. The second supply input B is no longer permanently connected to the permanent supply connection U⁺, but to the self-holding supply connection D. The supply input of the voltage regulator 3 , which in FIG. 1 is directly supplied with the second supply input via the permanent supply connection U⁺ B is connected, in FIG. 2 either - preferably via a first diode 1 - to the second supply input B or - preferably via a second diode 2 - to the first supply input A.

If the motor vehicle is put into operation or the ignition switch S _{Z is} closed, the supply input A is supplied with voltage via the start-up supply connection A ', as a result of which the voltage regulator 3 receives a switch-on pulse as in FIG. 1. As long as the supply supply input A via the start-up supply connection A 'is connected to voltage, the voltage regulator 3 in FIG. 2 is supplied with voltage via the supply input A. If the voltage from the commissioning supply connection A 'or the supply input A, z. B. switched off by switching off the ignition or opening the Zündschloßschal switch S _Z , the second supply input B takes over the electrical supply of the voltage regulator 3 until the switch-off delay time of the relay 7 has expired.

Ensure such a control device according to the invention is an example especially when it is switched off as sufficient power supply to the Steuerge advises for a new switch on in a defined off to shift current state. At the same time, ver prevents the one after switching off the control unit Connection of a supply input of the control unit with a permanent supply connection to a quiescent current consumption leads.

The exemplary embodiments are true of a motor vehicle limited, but the invention is limited to any battery drive-operated control units applicable.

Claims (2)

1. Control unit with a first supply input fed via an electrical commissioning supply connection, with a second supply input fed via a permanent supply connection and with an output for emitting a switching signal in order to switch off the commissioning Turn off the supply connection from the first supply input towards the permanent supply connection with a delay from a self-holding supply connection, characterized in that the second supply input (B) is connected to the self-holding supply connection (D). 2. Control device according to claim 1, characterized in that the first (A) and the second (B) supply input of the control device ( 9 ) are connected to the supply input of the voltage regulator ( 3 ) of the control device ( 9 ).