DE10261770A1 - Method for stabilizing a supply voltage for at least one consumer - Google Patents

Abstract

The invention relates in particular to a method and a voltage supply device (100) for stabilizing a supply voltage for at least one electronic consumer (A, B), in particular in a motor vehicle. With the traditional voltage supply devices, voluminous capacities are generally required in order to prevent an undesired collapse of the supply voltage supplied to the consumers. In order to be able to make these capacities smaller and thus also more space-saving, it is proposed according to the invention to save part of the buffer work performed by the capacities by at least individual electronic consumers (A, B) having an electronic regulator device (120) from which they obtain their obtain the respective supply voltage (U¶A¶, U¶B¶), load it, put it into an energy-saving mode or switch it off if instabilities, in particular in the form of voltage dips, are found in the input voltage for the voltage regulator device.

Description

The invention relates to a method to stabilize a supply voltage for at least one electronic Consumers in a system, which is particularly arranged in a motor vehicle can be. The invention also relates to a software program and a power supply device for performing this Process.

Such methods and voltage supply devices are basically known in the prior art. 4 shows an example used in the automotive field for such a voltage supply device 100 , It serves to provide a stabilized supply voltage U _A , U _B , U _μC for at least one electronic consumer A, B, the consumers preferably in one system 130 are summarized. This system can be, for example, an ABS system or a rain or dirt detector for dirt on the windshield. The voltage supply device has for the provision of the stabilized supply voltages 100 a voltage regulator device 120 on which is connected to a voltage source 110 is connected and receives an input voltage U _{E from} it. The voltage regulator device 120 has the task of buffering this input voltage before it passes it on, possibly converted into levels suitable for the individual consumers. The buffering serves to compensate for or filter out positive or negative voltage peaks or long-term voltage drops in the input voltage U _E before the voltage regulator 120 this as supply voltage to the individual consumers A, B or to a control device 140 for controlling the individual consumers A, B forwards.

The voltage regulator preferably comprises 120 a reset function for resetting the control device 140 when the input voltage U _E supplied to it has dropped to 0 volts for more than a predetermined period of time, for example T = 100 ms. Conversely, this means that the voltage regulator must then be designed to reliably compensate for a drop in the input voltage U _E to 0 volts for at least exactly this period of time. In the prior art, this is done in that the voltage regulator device 120 has sufficiently large input and output capacitors.

Alternatively, this reset function can also be carried out directly in the control device 140 be provided. The control device resets itself when its supply voltage U _μc falls below its reset threshold. The control device too 140 can have sufficient input capacities to additionally buffer its own supply voltage.

However, large capacities basically have that Disadvantage that they are a big one Claim room volume. Increasing miniaturization too These are large-volume electronic components in motor vehicles Capacitors counter.

It is therefore the task of the present Invention, a known method for stabilizing a supply voltage for at least a consumer, especially in a motor vehicle, and a known one Software program and a known power supply device to carry out further develop this method such that the size of the in the capacitance required for the voltage regulator device or the control device can be made without the stability of consumers and consumers Control device fed Supply voltage suffers from it.

• a) Überwachen des Wertes der Eingangsspannung der Spannungsreglereinrichtung und Erkennen eines Einbrechens der Eingangsspannung, wenn diese unter einen vorgebbaren Unterspannungsschwellenwert abfällt und/oder Erkennen einer Überspannung, wenn die Eingangsspannung über einen vorgebbaren Überspannungsschwellenwert steigt; und
• b1) Versetzen des elektronischen Verbrauchers in einen Energiesparmodus oder Abschalten des elektronischen Verbrauchers, wenn das Einbrechen der Eingangsspannung der Spannungsreglereinrichtung erkannt wird; oder
• b2) Abschalten des elektronischen Verbrauchers, wenn die Überspannung erkannt wird.

This object is achieved by the method claimed in claim 1. Accordingly, it is proposed in particular to carry out the following steps:

• a) monitoring the value of the input voltage of the voltage regulator device and detecting a dip in the input voltage if it drops below a predeterminable undervoltage threshold and / or detecting an overvoltage if the input voltage rises above a predefinable overvoltage threshold value; and
• b1) placing the electronic consumer in an energy-saving mode or switching off the electronic consumer when the drop in the input voltage of the voltage regulator device is detected; or
• b2) switching off the electronic consumer when the overvoltage is detected.

In general terms, this method provides for the load hanging on a voltage regulator device to be reduced if instabilities, in particular in the form of voltage dips, are determined at its input voltage. By reducing the load, the voltage regulator 120 enabled the instabilities found at its input voltage 10 to compensate for that this does not affect the supply voltages it issues for consumers and the control device. In other words, the occurrence of instabilities on the supply voltages supplied to the consumers is preventively averted by reducing the load of the voltage regulator when instabilities are found on its input side.

Due to this preventive control, it is possible to increase the buffer capacities in the voltage regulator device 120 or in the control device 140 to be kept low without the stability of the supply voltages for the consumers or the control device having to suffer as a result. The reduced capacities inevitably only require a reduced construction volume and thus enable a further miniaturization of the overall system.

Because of the stability of the supply voltage from in particular also the control device according to the invention also at Use of only small capacities is also advantageous ensured that no unwanted Reset the control device and associated with it no undesirable Data loss due to instabilities on the input voltage UE occurs.

The reduction in the load can Example take place in that individual consumers first in an energy saving mode can be set or switched off completely.

The transfer is advantageously carried out the consumer in energy saving mode or its shutdown only then when the input voltage supplied to the voltage regulating device has fallen below various undervoltage thresholds that for the individual consumers can be specified individually.

Correspondingly, the individual consumers or the control device is also restarted from the energy-saving mode only when the input voltage U _{E of} the voltage regulator exceeds an input voltage threshold value that can be predefined individually for each consumer.

It is beneficial if a first Order according to which the individual consumer or the control device be put into energy saving mode or switched off, in advance is defined. The same applies to one second order according to which the consumers after a shutdown in energy saving mode or according to which the consumer and the Control device from the energy saving mode to a normal mode be transferred.

It is also an advantage if individual at over- or falling below a threshold value for events to be triggered indeed triggered if an individually assignable to the individual threshold values Time has expired. The term "events" here refers in particular to the transfer the consumer or the control device in another operating mode Roger that. The claimed delay has the advantage that the events are not unintentional, for example with only brief interference pulses in the input voltage become. Moreover it is advantageous if in particular the consumer if possible quickly after detecting an instability of the input voltage for the voltage regulator device in the energy saving mode or be switched off, so as possible a lot of load on the capacities remains in the network or in the control device.

The above object of the invention is further supported by a software program and by a voltage supply device each for implementation solved the claimed method. The advantages of these solutions correspond to those mentioned above in relation to the claimed method Benefits. Further advantageous configurations of the solutions are Subject of the subclaims.

The invention is hereinafter in Form of several embodiments and with reference to the figures accompanying the description described in detail, whereby

1 a power supply device according to the invention;

2 a first embodiment for a voltage divider device according to the invention;

3 a second embodiment of a voltage divider device according to the invention; and

4 shows a voltage supply device according to the prior art.

1 shows the power supply device according to the present invention. It is based in substantial parts on the introductory part with reference to 4 described device. To avoid repetition, reference is made to this description at this point. The same components are provided with the same reference symbols. In addition, it should only be noted that in 1 shown voltage supply device 100 at least some of the consumers A, B each have a plurality of supply voltages from the voltage regulator 120 can be supplied, for example, the consumer B can be supplied with a first supply voltage UB1 of 12V and a second supply voltage of UB2 of 5V.

The voltage supply device according to the invention 100 differs from that in 4 shown voltage supply device 100 in particular in that here the voltage regulator device 120 supplied input voltage U _E detected and on instabilities, in particular voltage breaks is monitored. For this purpose, the input voltage U _{E is} first the voltage divider device 150 supplied, which the input voltage on for the downstream control device 140 Processable voltage levels, preferably 5 volts or 3.3 volts, implemented.

2 shows the structure of the voltage divider according to the invention 150 , This initially comprises a voltage divider consisting of the resistors connected in series 151 and 152 for converting the input voltage U _E in for the control device 140 suitable voltage levels. Furthermore, the voltage divider device 150 one to the resistance 152 capacity connected in parallel 153 exhibit. This can ensure that a possible voltage drop in the input voltage that occurs at the node 154 can be registered immediately, only then to the control device 140 is forwarded if this voltage drop lasts longer than a predetermined period of time, for example 400 μs. In this way it is ensured that the method according to the invention is not already triggered in the presence of only short interference pulses on the input voltage U _E. The function of the further in the voltage divider device 150 existing voltage divider 155 . 156 and 157 will be explained below.

That through the voltage divider 151 . 152 and 153 divided input voltage U _E is subsequently from the voltage divider 150 to the control device 140 forwarded. The control device 140 is designed according to the invention, this converted input voltage of the voltage regulator device supplied to it 120 to monitor and detect a drop in this input voltage if it drops below a predefinable undervoltage threshold. The control device is preferably 140 further trained to recognize an overvoltage when the converted input voltage of the voltage regulator supplied to it rises above a predefinable overvoltage threshold value.

The control device 140 However, it is not only designed to detect an undervoltage or overvoltage, but also, if necessary, is also designed to initiate suitable measures that prevent the propagation or transmission of determined instabilities of the input voltage U _E to the supply voltages at the output of the voltage regulator device 120 to avoid or, if an impact of this instability on the supply voltages cannot be avoided, to avoid any possible damage to the individual consumers. Such from the control device 140 Measures to be initiated are shown in Table 1 as examples.

As can be seen from Table 1, the control device is designed to switch off individual consumers, for example consumer A, when an overvoltage is detected, if the input voltage U _E exceeds the predefinable overvoltage threshold value, this overvoltage threshold value being individually predeterminable for the individual consumers. While consumer A exceeds a first over voltage threshold value is already threatening, reaching this threshold value, for example for a consumer B, may still be completely harmless; it can then remain connected to the supply voltage while maintaining its full functionality.

As long as that of the control device 140 supplied converted input voltage U _E neither exceeds the overvoltage threshold nor falls below an undervoltage threshold, there is a normal operating state in which the control device 140 has no reason neither to put one of consumers A, B into an energy-saving mode or to switch it off, nor to put himself into an energy-saving mode; that is, for all consumers as well as for the control device 140 remains fully functional or is restored.

Only when that of the control device 140 supplied converted input voltage falls below a first undervoltage threshold value, the control device guides 140 Take appropriate measures to control the load at the output of the voltage regulator device 120 to reduce. According to Table 1, such a reduction in the load can preferably consist in that individual or all consumers A, B are first put into an energy-saving mode. This is preferably done for those consumers whose function is currently - given the voltage - or not necessary in the near future. The control device remains as long as only a first, but not a second, undervoltage threshold value, which is smaller than the first undervoltage threshold value, is not undershot 140 fully functional.

Only when the second undervoltage threshold value is also fallen below are measures for a further reduction in the load of the voltage regulator device 120 from the control device 140 causes. It is then particularly provided that the control device 140 First, individual, but possibly all consumers A, B are switched off. Switching off is also preferably carried out according to a predeterminable sequence, which specifies on the basis of a previously carried out needs analysis, which the consumer can currently dispense with at these input voltages.

The control device is preferably only when all consumers have already been switched off, quasi as the last possible preventive measure 140 put yourself into an energy-saving mode. If the control device 140 as is usually designed as a microcontroller, it usually also has such an energy-saving mode.

At this point it should be mentioned that all threshold values are preferably for the individual consumers, but also for the control device 140 can be specified individually. Furthermore, it is advantageous if the individual controls by the control device when a threshold value is undershot or exceeded 140 Measures initiated or events to be triggered are only actually triggered when a time period that can be individually assigned to the individual threshold values has expired. In this way, it is ensured that a consumer or even the control device itself is not put into an energy-saving mode or is switched off if the input voltage U _{E has} not actually plummeted for a long time or exceeds the overvoltage threshold value, but only has a short interference pulse.

The control device 140 is not only designed to put the individual consumers or even themselves into an energy-saving mode or to switch them off, but it is also responsible for reactivating the consumers and themselves if the instabilities of the input voltage U _E no longer exist. Specifically, this means that the control device 140 is designed to restart a consumer, which it has previously put into the energy-saving mode, into the normal operating mode when the input voltage U _{E of} the voltage regulator exceeds an input voltage threshold value that can be predetermined for this consumer. This predeterminable input voltage threshold value need not be identical to the first undervoltage threshold value at which the consumer was put into the energy-saving mode; rather, a so-called switching hysteresis can be provided here. The same applies to a start-up of the consumers after they have been switched off beforehand. It should be mentioned that after switching off, the consumers do not necessarily have to be brought back to normal operating mode immediately, that is, to their full functionality, but rather, if necessary, they can also first be put into an energy-saving mode.

However, before any consumer is put into a higher operating state with more energy consumption, the control device is first 140 itself started up in its normal operating mode if it had previously been put into its energy saving mode for reasons of energy saving.

For this start-up of the control device 140 Two basic options are shown below: A first option is that on the control device 140 implemented energy saving mode itself provides a wake-up function, which can be configured, for example, so that the control device 140 automatically interrupts their energy-saving mode themselves at certain time intervals and then briefly returns to their normal operating mode to determine whether the condition for the energy-saving mode still exists. That is, in the present invention, the controller can 140 then check on its own initiative whether the input voltage U _E in particular still falls below the second undervoltage threshold. If this is still the case, the control device returns 140 au automatically returns to energy saving mode. However, if this is no longer the case, the control device returns 140 permanently automatically returns to its normal operating state.

A second possibility for waking up the control device 140 is out of their sleep mode 2 shown. It can be seen there that the voltage divider device shown there 150 a second voltage divider consisting of the resistors connected in series 155 and 156 having. If at the junction between these two resistors 158 if a voltage drops that is greater than a predefinable threshold value, this leads to the control device 140 , which receives this voltage, to trigger an interrupt, which the control device 140 awakened from the energy-saving mode and returned to its normal operating state. The resistor is so that this interrupt is not triggered undesirably by interference pulses on the input voltage U _E 156 a capacitor 157 connected in parallel, which ensures that such interference pulses from the to the control device 140 forwarded interrupt signal are filtered out or that this signal is only delayed to the control device 140 is forwarded.

Is an accurate for the alarm function Switching threshold required, their level can be processed using a comparator. Such a function is used by individual known voltage regulators to disposal posed.

3 shows a further embodiment for the voltage divider device according to the invention 150 , This exemplary embodiment essentially corresponds to that in FIG 2 shown embodiment; Identical components are identified by the same reference symbols. Opposite the in 2 shown embodiment, however, the voltage divider still has a switch 159 on, via a control signal from the control device 140 can be opened and closed. For the operation of the claimed method and the claimed voltage supply device 100 is the switch 159 close. However, if the entire system is to be switched off with all consumers, that is to say in particular if the motor vehicle is switched off when this system is installed in a motor vehicle, it is advantageous to use this switch 159 to be opened by the control device so that in this state there are no currents through the voltage divider device 150 flow and in this way consumes energy unnecessarily. That switch 159 is of course unnecessary if the system is not supplied with electrical energy when the vehicle is parked.

The use of the claimed method and the claimed voltage supply device is particularly advisable only when other measures to save energy have been carried out for the consumers in the motor vehicle and for the control device. Such measures can be, for example, the use of components with particularly low power consumption or the lowering of the reset threshold for the control device 140 his. The buffer capacities in the voltage regulator device should also be fundamentally 120 and the control device 140 be chosen as large as possible from the available volume. The method according to the invention and the voltage supply device according to the invention only need to be used when the available construction volume is not sufficient to have sufficiently large capacities in the voltage regulator device 150 or in the control device 140 provided. In this case in particular, it is advisable to virtually replace the still missing buffer effect, which cannot be achieved by the capacities used, by the method according to the invention. So-called surface mounted device SMD capacitances or wired capacitances are preferably used as input capacitances for buffering.

The method according to the invention for stabilizing a supply voltage for at least one electrical consumer, in particular in a motor vehicle, can be implemented both in the form of an electronic hardware circuit and in the form of a software program. When implemented in the form of a software program, a sequence of commands must then be present, the commands then carrying out the individual method steps. Depending on the type of implementation, this is then in the control device 140 either the hardware circuit or the software program, or a combination of both, is available to carry out the method. If necessary, the software program can be stored on a data carrier together with other software programs for controlling and / or regulating consumers A, B. The data carrier can be a floppy disk, a compact disk (so-called CD), a so-called flash memory or the like. The software stored on the data carrier can then be sold to a customer as a product. In addition, in the case of software implementation, it is possible that the software program, together with other software programs for controlling consumers A, B - without the aid of an electronic storage medium - is transmitted as a product to a customer via an electronic communication network, in particular the Internet, and to the customer Way is sold.

Claims (17)

Method for stabilizing a supply voltage for at least one electronic consumer, in particular in a motor vehicle, the supply voltage being from a voltage regulator direction ( 120 ) is provided, which derives the supply voltage from an input voltage (U _E ) supplied to it, characterized by the following steps: b) monitoring the value of the input voltage (U _E ) of the voltage regulator device ( 120 ) and detection of a drop in the input voltage (U _E ) if it drops below a predefinable undervoltage threshold and / or detection of an overvoltage if the input voltage (UE) rises above a predefinable overvoltage threshold; and b1) putting the electronic consumer (A, B) into an energy-saving mode or switching off the electronic consumer when the input voltage (U _E ) of the voltage regulator device ( 120 ) is recognized; or b2) switching off the electronic consumer (A, B) when the overvoltage is detected. Method according to Claim 1, characterized by: - placing the at least one electronic consumer in an energy-saving mode when the input voltage (U _E ) of the voltage regulator device ( 120 ) falls below a first undervoltage threshold value, which can be individually specified for each individual consumer (A, B). Method according to claim 1 or 2, characterized by: - switching off the at least one electronic consumer when the input voltage (U _E ) of the voltage regulator device ( 120 a second predefinable undervoltage threshold value, which is preferably less than the first undervoltage threshold value, and which can be predefined individually for each individual electronic consumer. Method according to one of claims 2 or 3, characterized in that at least individual consumers in the system are assigned a rank within a first order, according to which the individual consumers (A, B) are placed in the energy-saving mode or switched off after a break-in Input voltage (U _E ) of the voltage regulator device ( 120 ) was recognized. Method according to one of the preceding claims, characterized in that the at least one consumer, after having been put into the energy-saving mode beforehand, is restarted into a normal operating mode when the input voltage of the voltage regulator device ( 120 ) exceeds an input voltage threshold value that can be individually specified for the consumer. Method according to one of claims 1-3, characterized in that the at least one consumer, after it was previously switched off, is started up either in the energy-saving mode or in a normal operating mode when the input voltage (U _E ) of the voltage regulator device ( 120 ) exceeds an input voltage threshold value that can be individually specified for the consumer. Method according to one of the preceding claims, characterized in that at least individual consumers connected to the voltage regulator device ( 120 ) are connected, a rank is assigned within a second sequence, according to which the individual consumers are first brought up from the energy-saving mode or after their switch-off to their normal operating state or after the switch-off into the energy-saving mode after the input voltage (U _E ) one for the individual consumer individually predeterminable input voltage threshold value. Method according to one of the preceding claims, characterized in that the individual consumers from the control device (if a threshold value is exceeded or fallen below) 140 ) measures to be initiated are only actually triggered when a time period that can be individually assigned to the individual threshold values has expired. Software program for a control device ( 140 ) preferably in a motor vehicle, with program code which is suitable for carrying out the method according to one of the preceding claims 1-8 when it is executed on a computer or a microcontroller. The software program of claim 9, wherein the program code on a disk is saved. Electronic circuit, preferably for a control device ( 140 ) in a motor vehicle, characterized in that the electronic circuit is designed to carry out the method according to one of claims 1-8. Power supply device ( 100 ) to provide a stabilized supply voltage for at least one electronic consumer (A, B) in a system ( 130 ), in particular in a motor vehicle, comprising: a voltage regulator device ( 120 ) connected to a voltage source ( 110 ) is connected and receives an input voltage (U _E ) from it to provide a supply voltage (U _A , U _B ) for the electronic consumer; and - a control device ( 140 ) for monitoring the value of the input voltage (U _E ) for the voltage regulator device ( 120 ) and to detect the drop in the input voltage (U _E ) if it drops below a predefinable undervoltage threshold and / or to detect an overvoltage if the input voltage (U _E ) rises above a predefinable overvoltage threshold and to put the electronic consumer into an energy-saving mode or for Switching off the electronic consumer when the drop in the input voltage (U _E ) of the voltage regulator is detected or switching off the electronic consumer when the overvoltage is detected. Power supply device ( 100 ) according to claim 12, characterized in that the control device ( 140 ) is designed to carry out the method steps according to claims 2-8. Power supply device ( 100 ) according to claim 12 or 13, characterized by a voltage regulator device ( 150 ) for detecting the input voltage (U _E ) of the voltage regulator device ( 120 ) and to forward the input voltage (U _E ) to the control device ( 140 ) converted into voltage levels that can be processed by the control device. Power supply device ( 100 ) according to claim 14, characterized in that the voltage divider device ( 150 ) is formed, a collapsed input voltage (U _E ) of the voltage regulator device ( 120 ) only after a predeterminable delay time to the control device ( 140 ) forward. Power supply device according to one of claims 12-15, characterized in that the control device ( 140 ) can be put into an energy-saving mode. Power supply device ( 100 ) according to claim 16, characterized in that the voltage divider device ( 150 ) is designed to send an interrupt command to the control device ( 140 ) so that the system returns from an energy-saving mode into which it had previously been set to the normal operating mode when the input voltage (U _E ) at the voltage regulator device ( 120 ) exceeds a predefinable activation threshold voltage.