WO2013107560A1 - On-board electrical system having a d.c. converter, control device, and associated operating method - Google Patents

Abstract

The invention relates to an on-board electrical system (1), in particular for a motor vehicle, having at least two sub-systems (10, 20), of which one first sub-system (10) is designed to be operated at a first d.c. voltage and a second sub-system (20) is designed to be operated at a second d.c. voltage. The first and second d.c. voltages have different nominal voltage values, and the first sub-system (10) and the second sub-system (20) are connected to each other by means of a d.c. converter (30), which is designed to be operated at least in a first operating mode, in which said converter converts the first d.c. voltage into the second d.c. voltage and/or converts the second d.c. voltage into the first d.c. voltage, and in a second operating mode, in which said converter forms a direct electrical connection between the first sub-system (10) and the second sub-system (20).

Description

 Description title

 On-board network with DC-DC converter, control device and associated operating method

The present invention relates to a two or more voltage electrical system with a DC-DC converter, a control device for such a

On-board network and an associated operating procedure.

State of the art

Two- or multi-voltage electrical systems for motor vehicles are used, for example, when consumers with different power consumption are to be supplied in a motor vehicle. Typically, two-voltage vehicle systems are used which have a first subnetwork and a second subnetwork. The first subnet is operated with a higher target voltage value than the second subnet. For example, in the first subnet 48 V as a target voltage value, in the second subnet 12 V set as a target voltage value. The electrical system is usually designed as a direct voltage network. The subnetwork with a higher nominal voltage value is also referred to as a high voltage (partial) network, and the subnetwork with a lower nominal voltage value is also referred to as a low voltage subnetwork.

Often only one of the subnetworks, eg with a generator, is directly supplied with voltage and the other subnetwork is connected via a suitable DC-DC converter (DC / DC converter). For example, the DC-DC converter can supply the low-voltage sub-network with electrical energy from the high-voltage sub-network. DC-DC converters can be designed as galvanically isolated converters, but this is functional not mandatory. Corresponding DC-DC converters can be installed as a separate device with a separate housing or in a housing together with a pulse inverter or a battery, so that there is a compact unit for providing two voltage levels.

If an attenuator (for example a battery connected there or a corresponding capacitor) fails in the high-voltage sub-network, the power supply in this sub-network may only be maintained with difficulty due to considerable voltage fluctuations. Load connections and disconnections, for example, lead to voltage fluctuations there, which, depending on the gradients of the load changes, lead to destabilization of the vehicle electrical system. The usually provided generator control can usually not correct load jumps fast enough. The high-voltage sub-network, and thus possibly also the low-voltage sub-network (the latter by degradation of the DC-DC converter) can therefore get into overvoltage when connecting a consumer in undervoltage and when switching off a consumer. This has the consequence, for example, that either the Berührspannungsgrenze of 60 V can not be met or an overvoltage protection circuit is excessively loaded. Depending on the intended control strategy, voltage fluctuations can lead to failures of consumers or the entire high-voltage subnetwork. Electrically excited machines, which are typically connected to the high-voltage subnetwork, can not be switched on easily in a de-energized state.

One can use a DC-DC converter to stabilize the voltage supply of the low-voltage network. The mutual supply of subnets via bidirectional or alternately switchable unidirectional

Converter is known for example from DE 101 19 985 A1. However, there is still a need for improved ways to stabilize such voltages, especially in the case of loss of attenuators, such as batteries or capacitors.

Disclosure of the invention

According to the invention, a vehicle electrical system with a DC-DC converter, a control device for such a vehicle electrical system and an associated operating method with the features of the independent claims are proposed. Advantageous embodiments are the subject of the respective subclaims and the following description.

The proposed measures make it possible, in the case of loss of a battery or a capacitor, more generally an attenuator, especially in the high voltage subnet, to couple the subnet directly via the DC-DC converter, so that an attenuator, for example. The battery or a capacitor in the low voltage subnet as an attenuator for the components in the high voltage subnet, eg a generator and the corresponding consumer, can act.

The DC-DC converter is not, as it corresponds to the normal function of a DC-DC converter, operated unidirectionally or bidirectionally, but controlled by. In this case, the converter establishes a direct connection between the two subnetworks. This operating mode is referred to in this application as "second mode", the regular operation as a downward and / or up-converter as "first mode". If such a DC-DC converter is controlled, currents are transmitted equally between subnets in both directions and both subnetworks are directly electrically connected to each other.

A corresponding DC-DC converter can be configured according to the invention to switch over from the first operating mode to the second operating mode on the basis of a drive signal. However, it can also be provided to design a DC-DC converter in such a way that it can be used by means of continuously monitors the voltage values at its terminals (connections) to both subnetworks. A corresponding DC-DC converter can therefore autonomously either switch from the first operating mode to the second operating mode or cancel a direct electrical coupling between the two subnets, ie switch back from the second operating mode into the first operating mode. Such a DC-DC converter can also be operated without a control device.

An external monitoring of the vehicle electrical system by means of a control device, in contrast, makes it possible to continue to use existing voltage measuring devices, which are evaluated by a corresponding control device. In this case, for example, it may be provided that the actual voltage values in both subnetworks are continuous, i. Over a defined (also sliding) period to monitor and determine based on predefined criteria that switching from the first mode of operation in the second mode of operation is required. This can be done, for example, when fluctuations in the actual voltage values in one or in both subnetworks, in particular in the high voltage subnetwork, exceed a defined limit.

If a DC-DC converter provided according to the invention switches from the first operating mode to the second operating mode, the high-voltage sub-network can thus be operated with the voltage of the low-voltage sub-network. Even if the corresponding voltage value does not correspond to the nominal voltage value of the high-voltage subnetwork, at least one emergency operation can thereby be maintained. Due to the damping effect of the battery in the low-voltage subnetwork, the system no longer passes easily into overvoltage or undervoltage, but allows continuous operation.

In particular, when an electric machine is arranged in the high-voltage subnetwork, the method according to the invention enables its operation. An omission of an attenuator in the high-voltage subnet does not necessarily lead to a total system failure. The operation according to the invention thus provides a fallback level, which maintains a subsystem, namely the high-voltage subnetwork, functionally for an emergency operation of a vehicle in order to prevent the vehicle from being left behind. It thus at least makes it possible to approach the nearest workshop or service center, where a corresponding damage can be remedied. Advantageously, in this case, the components connected to the high-voltage subnetwork are designed such that they allow an emergency operation with a correspondingly lower voltage value, at least for a certain time or with limited functionality. An emergency operation may also include switching off certain components which are not absolutely necessary for the basic functions of the vehicle in order to reduce the power requirement in the electrical system.

If a generator is installed in the high-voltage subnetwork, an advantageous method may also include that if the DC-DC converter is in the second

Switches operating mode, the generator or a rectifier associated therewith is at the same time reduced to the nominal voltage value of the low voltage subnet. As a result, the generator supplies the setpoint voltage value of the low-voltage subnetwork and can thus supply the high-voltage subnetwork and the low-voltage subnetwork with this voltage. The low voltage subnet does not get into overvoltage.

Also intermediate configurations are possible. Thus, an emergency operation can also include a setting of the corresponding voltage value to an intermediate value which lies between that of the high and the low voltage subnetwork.

It should be emphasized that the measures proposed according to the invention are not restricted to use in on-board networks with two subnetworks, but in principle can also be used for the conversion of voltages on several voltage levels. Likewise, the invention is not on the

Use limited in motor vehicles, but in all two- or multi-voltage networks used, for example, in boats, aircraft, rail vehicles and the like. An arithmetic unit according to the invention, for example a control unit of a motor vehicle, is, in particular programmatically, configured to perform a method according to the invention.

The implementation of the method in the form of software is also advantageous, since this causes particularly low costs, in particular if an executing control device is still used for further tasks and therefore exists anyway. Suitable data carriers for providing the computer program are in particular hard disks, flash memories, EEPROMs, CD-ROMs or DVDs. It is also possible to download a program via computer networks (Internet, intranet, etc.).

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination indicated, but also in other combinations or in isolation, without departing from the scope of the present invention.

The invention is illustrated schematically by means of exemplary embodiments in the drawing and will be described in detail below with reference to the drawing.

Brief description of the drawings

1 shows a vehicle electrical system according to the prior art in a schematic representation.

FIG. 2 shows a vehicle electrical system according to an embodiment of the invention in FIG

 schematic representation.

FIG. 3 shows a vehicle electrical system according to a further embodiment of the invention in a schematic representation. Embodiment (s) of the invention

In the following figures, in each case electrical systems or wiring systems are shown, of which two voltage levels are shown. These can, as explained above, also comprise other voltage levels, not shown. The vehicle electrical systems are shown with the essential components for the understanding of the invention, wherein identical or equivalent elements are given identical reference numerals. A repeated explanation is omitted for clarity.

1 shows a vehicle electrical system according to the prior art in a schematic representation. The electrical system is designated 100 in total. It has a first subnetwork 10 and a second subnetwork 20, wherein the first subnetwork 10 in the present case is for operation with a DC voltage having a higher

Set voltage value is set as the second sub-network 20. All components are designed for the corresponding voltage values. By way of example, the setpoint voltage value is 48 V in the first subnetwork 10 and 12 V in the second subnetwork 20. This is illustrated by the different representation of the batteries 1 1, 21 arranged in the first subnetwork 10 and the second subnetwork 20. At least one storage capacitor may be provided instead of or in addition to one of the batteries 1 1, 21. In addition to the battery 1 1 in the first subnetwork 10, a schematically illustrated consumer 12 is provided there, which can be switched on or off. In the first subnet 10, an electrical machine 13 is shown, which is designed as a generator. About the electrical

Machine can be fed by means of a pulse changer or rectifier 14, a DC voltage signal in the first sub-network 10.

The electric machine 13 is provided with a corresponding control, which, for example, also acts on the pulse inverter 14 and allows control of the voltage level of the voltage provided by the electric machine 13. Due to the design of the electric machine 13 and / or the pulse inverter 14, these units are set up to supply the first subsystem 10 with the first voltage. In the second subnet 20, a consumer 22 is also provided in addition to the battery 21, which, as explained above, can be switched on or off. In the second subnet 20, for example, a starter 23 is provided, which can be used to start an internal combustion engine at startup.

The first subnetwork 10 and the second subnetwork 20 are interconnected via a DC-DC converter 300 of conventional design. This DC-DC converter 300 acts in the present case as a buck converter and takes a conversion of the first voltage of the first subnetwork 10 in the second

Voltage of the second sub-network 20, for example, from the provided by the electric machine 13 and the pulse inverter 14 voltage value of 48 V to the voltage required in the second sub-network voltage of 12V before. In the first subnetwork 10, the battery 1 1 acts as an attenuator. This means that by means of the battery 1 1 even when switching on and off of loads such. of the consumer 12, and / or in the case of a lack of dynamics of an electrical machine 13 or the pulse inverter 14, voltage peaks or voltage dips can be intercepted. If the battery 1 1 fails, corresponding fluctuations fully impact on the consumer and it comes to the problems discussed above. The conventionally trained

DC-DC converter 300 can not compensate for these variations.

2 shows a vehicle electrical system according to a particularly preferred embodiment of the invention in a schematic representation. The electrical system is designated overall by 1. The electrical system 1 has the essential components, as they have already been explained above with respect to the electrical system 100. The elements of the two subnetworks 10 and 20 are identical to those previously explained. Deviating from the electrical system 100, however, the DC-DC converter 30 is adapted to switch from a first operating mode in which it is operated as a buck converter to a second operating mode in which it establishes a direct electrical connection between the subnetworks 10 and 20. The DC-DC converter 30 is shown here as an electrically non-separated DC-DC converter 30. Among other components, the DC-DC converter 30 has active switching elements 31, 32, which are driven accordingly can. A voltage side arranged switching element 31 is referred to herein as a so-called "highside" switching element, a mass side arranged switching element 32 as a so-called "lowside" -Schaltelement. To provide the second operating mode, for example, the high-side switching element is fully controlled and the subnets 10, 20 are thus directly or via a

Coupling inductance 33, connected.

A DC-DC converter 30 can autonomously switch between the operating states. However, as explained above, it may also be advantageous to provide a control device 40 which carries out a corresponding monitoring or control. For this purpose, a control device 40 has an evaluation unit 43 and a control unit 44. The evaluation unit 43 is connected, for example, via corresponding signal lines 41 'and 42' to voltage measuring devices 41 and 42 in the subnetworks 10 and 20. If the evaluation device determines that an attenuator in the high-voltage subnetwork, such as the battery 1 1, has failed, it can instruct the actuation device 44 to output a control signal via a control line 44 '. This causes the DC-DC converter 30 establishes a direct connection between the sub-networks 10, 20.

The determination of a corresponding error state can be carried out, for example, by temporal evaluation of voltage signals and the detection of excessive voltage fluctuations and / or the evaluation of error signals. At the same time, the controller 40 may also have generator control, e.g. a regulation of the electric machine 13, adapt such that the corresponding generator or a pulse inverter 14 tunes to the target voltage value of the sub-network 20. The control device 14, or its evaluation unit 43, can continuously evaluate the voltage and detect corresponding voltage fluctuations.

FIG. 3 shows a vehicle electrical system according to a further particularly preferred embodiment of the invention and also designated 1. The

Vehicle electrical system of Figure 3 differs from that of Figure 2 only by the design of the DC-DC converter 30. A corresponding control device 40 may also be provided here, but is not shown for clarity. In the figure 3, the DC-DC converter 30 is formed as a galvanically isolated DC-DC converter 30 having two galvanically isolated units 34, 35. To bridge the galvanic isolation, a switching element or switch 36 is provided, which can be controlled either autonomously or in accordance with a control by a control device 40, to provide the second operating mode.

Claims

claims

1 . Vehicle electrical system (1), in particular for a motor vehicle, with at least two subnetworks (10, 20), of which a first subnetwork (10) is adapted to be operated with a first DC voltage, and a second subnetwork (20) is arranged therefor to be operated with a second DC voltage, wherein the first and the second DC voltage have different target voltage values, and wherein the first subnetwork (10) and the second subnetwork (20) are interconnected via a DC-DC converter (30) adapted to at least in a first operating mode in which it converts the first DC voltage into the second DC voltage and / or the second DC voltage into the first DC voltage, and in a second operating mode in which it establishes a direct electrical connection between the first subnetwork (10) and the first DC bus second subnetwork (20) to be operated.

2. Vehicle electrical system (1) according to claim 1, wherein the DC-DC converter (30) is designed as a galvanically non-separate converter and at least one controllable switching element (31, 32), wherein the converter by permanently driving the at least one switching element (31) in the second operating mode is operable.

3. vehicle electrical system (1) according to claim 1, wherein the DC-DC converter (30) is designed as a galvanically isolated converter and a galvanic isolation bridging switch (36), wherein the converter by permanently closing the switch (36) in the second operating mode is operable

4. Vehicle electrical system (1) according to any one of the preceding claims, wherein the DC-DC converter (30) is arranged for, based on a on his Terminals detected voltage automatically switch from the first mode of operation in the second mode of operation.

Vehicle electrical system (1) according to one of the preceding claims, wherein the DC-DC converter (30) is adapted to switch from the first operating mode to the second operating mode on the basis of a drive signal.

Control unit (40) for an electrical system (1) according to claim 5, which comprises a detection unit (43) which is adapted to detect an actual voltage value of the first and / or the second DC voltage, and a drive device (44) therefor is arranged to provide the driving signal for the DC-DC converter (30) based on the detection comprises.

Method for operating a vehicle electrical system according to one of Claims 1 to 5, in particular comprising a control device (40) according to Claim 6, which comprises detecting an actual voltage value of the first and / or the second DC voltage, wherein the DC-DC converter (30), in the first operating mode is operated when the actual voltage value of the first and / or second DC voltage corresponds to a target voltage value, and the DC-DC converter (30) is operated in the second operating mode, if the actual voltage value of the first and / or second DC voltage at least temporarily does not correspond to the target voltage value.

The method of claim 7, wherein the actual voltage value in the DC-DC converter (30) is detected and the DC-DC converter automatically switches from the first to the second operating mode or from the second to the first operating mode based on the detection.

Method according to claim 7 or 8, in which the actual voltage value is detected in a control device (40), in particular according to claim 6, and the DC-DC converter is automatically detected on the basis of a drive signal of the control device (40) on the basis of the detection is switched first in the second operating mode or from the second to the first operating mode.

Arithmetic unit adapted to perform a method according to any one of claims 7 to 9.

Computer program with program code means stored on a computer-readable data carrier, which cause a computer or a corresponding computing unit to carry out a method according to one of claims 7 to 9 when executed on the computer or a computer unit, in particular according to claim 10.