DE102007027498A1 - Switching arrangement for on-board electrical system, has switching device for interconnecting energy storages and formed as discrete active -semiconductor components e.g. MOSFET, and discrete passive -semiconductor component e.g. diode - Google Patents

Abstract

The arrangement (1) has a switching device (6) for variably interconnecting two energy storages (4, 5), The switching device (6) is formed as discrete active -semiconductor components e.g. MOSFET, and a discrete passive -semiconductor component (6.1) e.g. diode. The energy storage (4) is provided for a starter motor (2) and for supplying energy to an associated electrical consumer equipment (7). The other storage (5) is provided for attenuation of voltage drops supplying electrical energy to another consumer equipment (9) e.g. light and.

Description

The The invention relates to a circuit arrangement of a vehicle electrical system Motor vehicle, comprising an electric starter motor, a Generator, a first energy storage and a second energy storage and at least one switching device for variable interconnection the energy store.

to Improvement of the starting behavior of internal combustion engines in motor vehicles it is known to be a conventional one Energy storage, z. B. a Bordnetzakkumulator, one or more more Energy storage, such. As capacitors, for short-term delivery high currents, the while the boot process needed be to turn on. Various circuit arrangements which the coupling and decoupling between onboard power supply accumulators and one or more Control capacitors are already known.

For example, it is from the DE 10 2004 016 292 A1 known to provide two electrical energy storage, which are separated by a switching device with microprocessor control and suitable power semiconductor circuits during the startup of an internal combustion engine, so that the motor vehicle electrical system is operated independently of the energy requirements of the startup process.

The Necessity of such circuits arises from the Facts that during the Andrehvorgangs an internal combustion engine by a momentary Voltage drop in the electrical system of a motor vehicle all contained herein electrical consumers, except for starter components, temporarily be switched off. This has, for example, a flicker of light devices or restarts of electronic assemblies (also called "power-on-reset") or one Power loss of drives result. A disadvantage of the previous known switching device is that this is very expensive and a Variety of components - microprocessor control and power semiconductor circuits.

Of the The invention is therefore based on the object, a circuit arrangement to specify for operating a vehicle electrical system of a motor vehicle which the previously known switching device is simplified.

The The object is achieved by the Circuit arrangement solved, which contains the features mentioned in claim 1. Advantageous embodiments The invention are the subject of the dependent claims.

The inventive circuit arrangement an electrical system of a motor vehicle includes an electrical Starter motor, a generator and a first energy storage and a second energy storage and at least one switching device for variable connection of the energy storage. Here is the switching device preferably formed as a discrete semiconductor device. By use a single component, in particular with blocking and passage direction as Switching element is a direct decoupling and coupling of the two Energy storage in different operating cases allows. Through the training the switching device as a single discrete semiconductor device are also higher switching speeds, lower error rates and no mechanical wear is achieved, so that the achievable number of switching cycles is increased. In a possible embodiment is the switching device as a discrete active semiconductor device, in particular a MOS field-effect transistor, or as a discrete passive semiconductor device, in particular a diode formed.

Furthermore are to ensure a primary and secondary power supply of electrical consumers also during an engine start the first energy storage engine start and the Supply of associated electrical loads and the second energy storage for damping of voltage dips and provided for the supply of other electrical consumers. In this case, the first energy store is in particular a group of associated with first electrical consumers, for example while of an engine start are unbuffered. The second energy storage is associated with a group of second electrical consumers, during a Engine starts are buffered by the second energy storage and thus opposite voltage dips sufficiently stable and continuously supplied.

embodiments The invention will be described below with reference to various drawings explained in more detail.

there demonstrate:

1 Circuit arrangement for on-board network support with a passive electronic switching device and

2 Circuit arrangement for on-board network support with an active electronic switching device.

each other corresponding parts are in all figures with the same reference numerals Mistake.

1 shows a circuit arrangement 1 for a vehicle electrical system of a motor vehicle. The circuit arrangement 1 includes an electric starter motor 2 , a generator 3 and a first energy storage 4 and a second energy storage 5 , The two energy storage 4 and 5 are via a switching device 6 variably interconnectable for different operating cases. In this case, the first energy storage is used 4 in particular the start of an internal combustion engine, not shown. In addition, the first energy storage 4 the supply of a first group of electrical consumers 7 serve. To secure the first group of electrical consumers 6 is a security element 8th intended. The second energy storage 5 serves to supply a second group of electrical consumers 9 that has an associated further securing element 10 are hedged.

The first energy storage 4 is in particular a storage battery or a battery and serves the primary supply of the electrical system. This can be a supply battery, which is also designed as a starting memory. The second energy storage 5 is in particular a storage battery or a double-layer capacitor with high power density (= high performance at low weight) and serves to support the electrical system in the event that it comes in certain operating cases or conditions to Spannungssein brines in the electrical system. In other words: the second energy storage 5 serves the secondary supply of at least part of the electrical system to limit or compensate for voltage dips in the electrical system. A voltage dip, for example, is understood to mean a voltage dip occurring during motor start, which typically lasts for a time range of less than 500 ms. It may also be redundant designed functions such. B. emergency operation of an electric parking brake or a gear parking position in so-called "shift-by-wire" systems, come to a voltage dip in the electrical system.

To such a voltage drop in terms of operability of electrical loads 7 and 9 limit or compensate for the on-board electrical system is intended that those consumers 7 for which such a voltage dip runs without malfunction, such. B. for heated rear windows, seat heaters, as the first group the first energy storage 4 assigned. The second group of electrical consumers 9 , such as B. lighting, electronic components, drives, are the second energy storage 5 assigned.

To support the electrical system and in particular the part of the electrical system with the second group of electrical consumers 9 is the switching device 6 is designed as a discrete semiconductor device, which in the event of a voltage dip, z. B. at an engine start, or at least when falling below the voltage U5 of the second energy storage 5 by the voltage U4 of the first energy store 4 (ie U4 <U5), the two energy stores 4 and 5 separated from each other and thus decoupled. By decoupling the second energy storage 5 from the first energy storage 4 and the part of the electrical system with a voltage dip is the second group of electrical consumers 9 (Also called buffered electrical loads) from the second energy storage 4 provided. The first group of electrical consumers 7 is not supplied in this case for a short time. These consumers 7 are also referred to as unbuffered consumers. In other words: the switching device 6 automatically disconnects the two energy stores during engine startup if the voltage falls below a specified voltage value 4 and 5 from each other and connecting them again when a predetermined voltage value is exceeded.

Depending on the specification, the switching device 6 as a discrete passive semiconductor device 6.1 , z. B. a diode (see 1 ), or as a discrete active semiconductor device 6.21 , z. B. a MOS field effect transistor (see 2 ), educated. The advantage of a single discrete component, such as the use of a passive switching diode or an active switching diode between the source and drain of a switched MOS field effect transistor, compared to conventional complex power semiconductor circuits in combination with microprocessors or electromechanical switches, such. As relays, in direct switching and thus in higher switching speeds and low error rates. In this case, the device-typical properties of the passive diode and the active MOS field effect transistor are exploited to the effect that a current flow is given in only one direction and thus the switching device 6 has a forward and a reverse direction.

The operation of the vehicle electrical system in a possible operating case will be described in more detail below. In the event of a voltage dip by an engine start at the first Energiespei cher 4 (= Electrical system battery), by pressing the starter motor 2 can arise as a discrete passive or active semiconductor device 6.1 . 6.2 trained switching device 6 in a blocking state. This results from the fact that the regular voltage U4 of the first energy store 4 smaller than the voltage U5 of the second, also referred to as a backup battery energy storage 5 and the forward voltage Us of the switching device 6 is. As a result, a decoupling between the ge buffed consumers 9 and the unbuffered consumers 7 effected in the electrical system of the motor vehicle.

During normal driving, the switching device is 6 polarized in the forward direction and the first and second energy storage 4 . 5 be through the generator 3 charged, which in turn is driven by the internal combustion engine of the motor vehicle.

How out 2 can be seen, the decoupling between the two energy storage 4 and 5 and thus to the different consumers 7 respectively. 9 also by the active discrete semiconductor device 6.2 , For example, by an inversely operated MOS field effect transistor, carried out, similar to the semiconductor diode in the event of a voltage drop across the electrical system battery - the first energy storage 4 - A decoupling of the second energy storage 5 from this first energy store 4 causes. An advantage over the discrete passive semiconductor device 6.1 - the diode after 1 - Here are the lower electrical losses.

Claims (3)

Circuit arrangement ( 1 ) for an electrical system of a motor vehicle, comprising an electric starter motor ( 2 ) and a generator ( 3 ) and a first energy store ( 4 ) and a second energy store ( 5 ) and at least one switching device ( 6 ) for the variable connection of the energy storage ( 4 . 5 ), characterized in that the switching device ( 6 ) as a discrete semiconductor device ( 6.1 . 6.2 ) is trained. Circuit arrangement according to Claim 1, characterized in that the switching device ( 6 ) as a discrete active semiconductor device ( 6.2 ), in particular a MOS field effect transistor, or as a discrete passive semiconductor device ( 6.1 ), in particular a diode is formed. Circuit arrangement according to claim 1 or 2, characterized in that the first energy store ( 4 ) for starting the engine and for supplying associated electrical consumers ( 7 ) and the second energy store ( 5 ) for damping voltage drops and for supplying associated electrical consumers ( 9 ) are provided.