EP1590870A1 - Power supply circuit for a motor vehicle electric system - Google Patents

Abstract

The invention relates to a power supply circuit for a motor vehicle electric system comprising a starter generator (1), a power electronics system (LE), at least one battery (B), at least one dynamic energy accumulator (3) and a DC/DC converter (2). The power supply circuit comprises a first connection branch which is connected to the DC/DC converter (2) and to a dynamic energy accumulator (3) contact, in addition to a second connection branch which is connected to a battery (B) contact. The two connection branches can be separated from the starter generator (1) by means of controllable switches (S1,S2). A control device (5) controls the switches (Sl, S2) in the first and second connection branch and also controls the DC/DC converter (2), according to the charge state of the battery (B), and the energy accumulator (3) in addition to an operational state of the motor vehicle such that the recovered energy is stored in the energy accumulator (3), drive support is provided by power from the energy accumulator (3) when charged or prior to that from the battery (B), and power from the energy accumulator (3) is used for a rapid start, whereby the battery is charged according to the charging state thereof and the electric system is fed by the battery (B) after recovery.

Description

DaimlerChrysler AG

Power supply circuit for a motor vehicle electrical system

The invention relates to a power supply circuit for a motor vehicle electrical system according to the preamble of claim 1.

In energy supply circuits for motor vehicle electrical systems for vehicles with starter / generator systems for stop / start and recuperation, the loads on the electrical system corresponding to start, stop and recuperation are covered by a capacitor in which excess energy is stored or energy is withdrawn. By designing the capacitor, the battery can be relieved and its service life can be increased. In particular, the reproducible behavior of a capacitor in relation to a battery enables the consumption potential to be optimized by recuperation. By using a capacitor with a higher voltage level than allowed in a 12V electrical system, e.g. 20V, an increase in storage energy during recuperation and a reduction in the start time of the engine in stop / start operation is achieved.

From DE 199 17 294 AI an on-board network for motor vehicles is known which comprises at least one battery, a generator and electrical consumers. The battery and the generator are connected in parallel to each other. A dynamic energy store is connected in parallel between the battery and the generator, and a controllable switch is arranged between the battery and the dynamic energy store, which switch can be actuated as a function of the state of charge of the battery and / or the operating temperature. If one is exceeded Operating temperature threshold or when the battery is just below full charge, the controllable switch is opened to prevent the battery from being destroyed.

Furthermore, DE 198 46 319 Cl discloses a power supply circuit for a motor vehicle electrical system with two voltage supply branches at different voltage levels. The first voltage supply branch is fed from the second voltage supply branch via an electrical direct voltage converter and the two voltage supply branch is fed from a generator. At least one voltage supply branch is buffered by an associated energy store. A multiple converter with three voltage levels is formed, one input / output of which is connected to the second voltage supply branch, the other input / output of which is connected to the first voltage supply branch and the third input / output of which is connected to the energy store assigned to the first voltage supply branch. If necessary, the multiple converter enables variable distribution of the power flows between different inputs / outputs.

In addition, from DE 196 28 877 AI an on-board network for vehicles is known, in which a battery and a high-performance energy store, such as a supercapacitor, alternately and others. be charged by braking energy. The stored energy is among other things used to accelerate the vehicle. Furthermore, the battery can be recharged with excess energy from the high-performance energy store.

Finally, from DE 100 63 751 AI a vehicle electrical system is known which has a starter generator.

An ISAD (= Integrated Starter Alternator Damper) system, ie an on-board electrical system for integrated starter / generator, as it is is marketed for example by Continental, is shown in Fig. 3. The ISAD system comprises a two-voltage electrical system for 12V and 42V and is structured as follows. An ISAD machine 30 is connected via a frequency converter 31 to a 42V electrical system which is used, for example, for an electronic A / C compressor, electronic steering, electronic valve control, electronic catalytic converter heating, etc. Furthermore, the frequency converter 31 is connected via a DC / DC converter 32 to a 12 V electrical system which is used for light, radio, ECU, etc. The frequency converter 31 as well as the DC / DC converter 32 are monitored by a control unit 33. Furthermore, there is both a 12V battery 34 which is connected to the 12V electrical system and a 42V starter battery 35 with the 42V electrical system. The two batteries 34, 35 are each connected to a battery status monitoring system 36. An ultra-cap is used, for example, as an energy store with low internal resistance. The energy storage is integrated into the vehicle electrical system via a bidirectional DC / DC converter.

However, the problem with such a conventional system or such a power supply circuit for a motor vehicle electrical system is that the DC / DC converter must be designed for the maximum power of the energy store. This results in more effort and higher costs, especially since a large battery is also required.

It is therefore an object of the present invention to develop a power supply circuit for a motor vehicle electrical system in such a way that it is no longer necessary to design the DC / DC converter for the maximum power of the energy store and the battery can be reduced without the electrical system reliability and / or reduce starting security.

According to the invention, this task is performed by an energy supply circuit for a motor vehicle electrical system with the features of claim 1 solved. Advantageous developments of the invention are specified in the subclaims.

The losses are low due to the direct coupling of the energy storage device to the starter / generator. In addition, voltage-controlled charging of a discharged energy store is possible via the starter / generator, which means that a higher degree of efficiency can be achieved than with the DC / DC converter. In addition, a DC / DC converter is now sufficient for the integration of the energy store into the vehicle electrical system, which is designed for the average power of the energy store.

The energy supply circuit according to the invention for a motor vehicle electrical system is now explained in more detail below on the basis of a preferred exemplary embodiment with reference to the drawing.

Show:

1 is a block diagram of an energy supply circuit according to the invention for a motor vehicle electrical system,

2 shows a tabular representation of various operating states and associated charging states of an energy store and the correspondingly used energy sources for the vehicle electrical system, and

Fig. 3 shows the structure of a conventional ISAD system for a 12V / 42V electrical system.

1 shows an energy supply circuit according to the invention for a motor vehicle electrical system using the example of a motor vehicle with a 12V electrical system. Of course, the power supply circuit according to the invention can also be used in on-board electrical systems with a different voltage level or multi-voltage on-board electrical systems. With multi-voltage Vehicle electrical systems can then be modified according to the invention in one or more of the respective voltage branches.

In Fig. 1, M denotes a motor and 1 a starter generator, which can either be a belt-driven starter generator or an integrated starter generator which is connected to the motor M. The starter-generator 1 is connected to the power supply circuit EV according to the invention via power electronics LE.

This power supply circuit has two different voltage supply branches. The first voltage supply branch has a switch S1, via which the starter generator 1 with the downstream power electronics LE can be connected directly to a battery B, in the exemplary embodiment described a 12V battery with 70Ah, and the vehicle electrical system, here a 12V vehicle electrical system. The second voltage supply branch has a switch S2, via which the starter generator 1 with downstream power electronics LE connects directly to an energy store 3, for example an Ultracap for 14V / 550F and via a DC / DC converter 2 to the vehicle electrical system, here the 12V electrical system can be connected. Furthermore, the energy supply circuit E has a monitoring device 4, which monitors the state of charge of the battery B and of the energy store 3. The monitoring result of the monitoring device 4 is fed to a control device 5 which, in response to this monitoring result, ie the charging states of the battery B and the energy store 3 and an operating state of the engine detected by a device not shown, ie one of those shown in FIG. 2 below States 0 to 4, ie first start, acceleration (boost), constant speed, braking (recuperation) or stop / start, a switchover of switches S1 and S2 and the DC / DC converter in such a way that always the lowest possible energy consumption and the highest possible energy storage is achieved.

The exact functioning of the control device, i.e. the activation of the switches S1 and S2 depending on the determined state of charge of the battery B and the energy store 3 and the operating state of the vehicle can be seen better in connection with FIG. 2. Controllable semiconductor switches are preferably used as switches S1 and S2.

In FIG. 2, various operating states of the vehicle with starter / generator 1 and different charging states of the energy store 3 are plotted against one another in tabular form, and the corresponding energy supply states of the energy store 3 and the battery B are indicated. A distinction is also made between a state of charge SOC of the battery B <70% and a state of charge SOC of the battery B> 70%.

A distinction must be made between five different states, namely state 0 = first start, state 1 = acceleration (boost), state 2 = constant speed (v = constant), state 3 = recuperation (braking process) and state 4 = stop / start. For these, it is explained in more detail below how the energy is withdrawn or supplied from / to energy store 3 and / or battery B. The following explanation also indicates the state in which the control device 5 controls the switches S1 and S2.

State 0 = first start:

In the case of a first start, which is designated as state 0 in FIG. 2, takes place as long as the energy store 3 is empty, ie Uc = 0V, or at the voltage level of the DC / DC converter 2, ie for example Uc = 9V is located, no discharge of the energy store 3 and the battery B supplies the energy both for the starting process and for the electrical system. This is independent of the state of charge SOC of battery B. In this case, switch S1 is closed and switch S2 is open.

- If the energy store 3 has a state of charge corresponding to a desired operating point, for example Uc = 12V, or is completely filled, for example Uc = 15V, then the energy required for the start is taken from the energy store 3 and the vehicle electrical system, regardless of the state of charge SOC of the battery B. powered by battery B. In this case, switch S1 is open and switch S2 is closed.

State 1 = acceleration:

- In the event of acceleration of the vehicle when the energy store 3 is empty, i.e. Uc = 0V, or if the energy store 3 is at the voltage level of the DC / DC converter 2, e.g. Uc = 9V, if the state of charge SOC of battery B is <70%, only the electrical system from battery B is supplied with energy, switches S1 and S2 are open, while if state of charge SOC of battery B is better, battery B also provides the energy for the acceleration, switch S1 is closed and switch S2 is open.

If, on the other hand, the energy store 3 is at the desired working point, ie Uc = 12V, or the energy store 3 is full, ie Uc = 15V, the on-board electrical system is supplied with energy from the energy store 3 when the battery S <S% is charged and the battery B is charged. In this state, switch S1 is closed and switch S2 is open. At a The state of charge SOC of the battery B <70%, on the other hand, provides the energy store 3 with the energy for acceleration and the battery B with the energy for the electrical system. Switch S1 is open and switch S2 is closed.

State 2 = constant speed:

- In the case of a constant speed of the vehicle, when the energy store 3 is empty, i.e. Uc = 0V and a state of charge SOC of battery B <70% supplies the vehicle electrical system with energy from battery B and charges battery B. For this purpose, switch S1 is closed and switch S2 is open. If, on the other hand, the state of charge SOC of the battery B is <70%, the energy store 3 is charged by means of recuperation via the generator 1 and the on-board electrical system is supplied with energy by the battery B. Switch S1 is open and switch S2 is closed.

- At a voltage level of the energy store 3 corresponding to that of the DC / DC converter 2, i.e. For example 9V, the battery B is supplied with energy and the battery B is charged when the state of charge SOC of the battery B is <70%. The switch S1 is closed and the switch S2 is open. If, on the other hand, the state of charge SOC of battery B is> 70%, only the on-board electrical system is supplied with energy by battery B. The switches S1 and S2 are open.

- At a voltage level of the energy store 3 corresponding to the desired operating point, ie, for example 12V, the battery system B is supplied with energy by the energy store 3 and the battery B is charged with a state of charge SOC of the battery B <70%. The switch S1 is closed and the switch S2 is open. If, on the other hand, the state of charge SOC of battery B is> 70%, battery B supplies the vehicle electrical system with energy. The switches S1 and S2 are open.

If the energy store 3 is full, for example Uc = 15V, the on-board electrical system is supplied with energy from the energy store 3 and the battery B is charged when the state of charge SOC of the battery B is _< 70%. In this state, switch S1 is closed and switch S2 is open. If, on the other hand, the state of charge SOC of the battery B is> 70%, the electrical system is supplied with energy from the energy store 3. The switches S1 and S2 are open.

State 3 = recuperation (braking):

- In the event of a braking operation when the energy store 3 is empty, the energy store 3 is charged by recuperation via the generator 1 and the electrical system is supplied with energy by the battery B, regardless of the state of charge SOC of the battery B. Switch S1 is open and switch S2 is closed.

- If the energy store 3 is at the voltage level of the DC / DC converter 2, ie for example Uc = 9V, regardless of the state of charge SOC of the battery B, the energy store 3 is charged by recuperation via the generator 1 and the vehicle electrical system by the battery B with E. - supplied with energy. Alternatively, it is possible to charge the battery B by means of recuperation via the generator 1 when the state of charge SOC of the battery B is <70%. In the first case, switch S1 is open and switch S2 is closed, while in the alternative it is exactly the opposite. - If the energy store 3 is in the desired operating point, for example Uc = 12V, with a state of charge SOC of the battery B <70% the energy store 3 is charged by means of recuperation via the generator 1 and the battery B supplies the vehicle electrical system. Then switch S1 is open and switch S2 is closed. Alternatively, only the battery B can be charged via the generator 1 by means of recuperation. The switch S1 is closed and the switch S2 is open. If the state of charge SOC of the battery B is> 70%, the energy store 3 is charged by means of recuperation via the generator 1 and supplies the vehicle electrical system. For this purpose, switch S1 is open and switch S2 is closed.

- When the energy storage is finally full, i.e. For example, Uc = 15V, when the state of charge SOC of the battery B <70%, the vehicle electrical system is supplied with energy from the energy store 3 and the battery B is charged via the generator 1 by means of recuperation. The switch S1 is closed and the switch S2 is open. If, on the other hand, the state of charge SOC of battery B is> 70%, the vehicle electrical system is supplied with energy from battery B. To do this, switches S1 and S2 are open.

State 4 = stop / start:

- If the energy storage device 4 is empty or has a voltage level corresponding to the DC / DC converter 2, for example Uc = 9V, when the vehicle stops or starts, then the energy required for the start and the battery B will be independent of the state of charge SOC of the battery B. Energy for supplying the vehicle electrical system is supplied by battery B. The switch S1 is closed and the switch S2 is open. If the energy store is in the desired working point, ie for example Uc = 12V, then the energy required for the start is taken from the energy store 3 regardless of the state of charge of the battery B and the battery B supplies the vehicle electrical system with energy. In this state, switch S1 is closed and switch S2 is open.

- When the energy store 3 is finally full, i.e. For example, Uc = 15V, then the energy for the start and for supplying the vehicle electrical system is taken from the energy store 3. For this purpose, switch S2 is closed and switch S1 is open.

The voltage of the energy store 3 depends on its capacity and the power electronics (for example 30V), the integrated starter / generator 1 and the DC / DC converter 2. At voltages of more than 15V, a further recuperation mode is possible for all states. Namely, a combined recuperation can take place, ie if the generator voltage U _Gen > 15V, then the recuperation takes place in the energy store 3, otherwise it takes place in the battery B.

Thus, with the electrical system architecture according to the invention, the energy supply takes place only in the case of the first start from the battery B, while it takes place at later starts or stops via the energy store 3, which is, for example, an ultracap.

The recuperation takes place primarily via the energy store 3. As a result, the battery B can be charged to 95-100% and a constant recuperation energy that is independent of the battery state can be stored. The on-board electrical system is supplied via DC / DC converter 2 during recuperation. After recuperation, the on-board electrical system is supplied via battery B if drive support is not possible or necessary.

If there is excess recuperation energy, energy can be fed back into battery B, then the charge state threshold is set to 85% instead of 70%.

In the on-board electrical system architecture according to the invention, drive support by the integrated starter / generator with the energy from the energy store 3 can take place.

Until the energy store 3 is charged after an initial start, the drive is supported from the battery B.

During the recuperation in the energy store 3, the on-board electrical system is fed via the DC / DC converter 2 and / or the battery B. In this way, it is now possible to adjust the DC / DC converter 2 only to the average power of the energy store 3 interpreted.

A starting process, i.e. for example, a quick start with U >> 12V is basically done via the energy storage 3 without DC / DC coupling.

The battery size can be reduced by the on-board electrical system according to the invention. This has weight, packaging and cost advantages.

In addition, the life of the battery B is increased because its load is reduced. Finally, the battery B can be charged as required with the DC / DC converter 2, which further increases the on-board electrical system reliability and starting security.

Finally, starting security is further improved even with a partially charged battery B.

In summary, the present invention discloses an energy supply circuit for a motor vehicle electrical system with a starter generator, power electronics, at least one battery, at least one dynamic energy store and a DC / DC converter. The energy supply circuit has a first connection branch provided with the DC / DC converter and connected to a connection of the dynamic energy store and a second connection branch connected to a connection of the battery. Both connection branches can be separated from the starter generator via controllable switches. A control device controls the switches in the first and second connection branches and the DC / DC converter in response to a state of charge of the battery and the energy store and an operating state of the motor vehicle in such a way that existing recuperation energy is stored in the energy store, a drive support by energy from the energy store takes place as soon as it is charged, and until then, from the battery, energy from the energy storage is used for a quick start, the battery is charged according to its state of charge and, after recuperation, the vehicle electrical system is fed by the battery.

Claims

DaimlerChrysler AG patent claims

Power supply circuit for a motor vehicle electrical system with: a starter generator (1), power electronics (LE), at least one battery (B), at least one dynamic energy store (3) and a DC / DC converter (2), the starter Generator (1) can be connected to the vehicle electrical system via a first connection branch in which the DC / DC converter (2) is arranged, characterized in that the starter generator (1) can be connected to the vehicle electrical system via a second connection branch is, both the first and the second connection branch on their side connected to the starter generator (1) each have a switch (S1, S2), by means of which the connection branch can be opened, the battery (B) between the vehicle electrical system the second connection branch and ground is connected, the energy store (3) is connected between the switch (S2) in the first connection branch and the DC / DC converter (2) between ground and the first connection branch, and a Control device (5) is formed, the switches (Sl, S2) in the first and second connection branches and the DC / DC converter (2) in response to a state of charge controls the battery (B) and the energy store (3) and an operating state of the motor vehicle in such a way that

- Existing recuperation energy is stored in the energy store (3) and optionally if the energy store

(3) is fully charged, existing recuperation energy is used to charge the battery (B),

- Drive support by energy from the energy store (3) takes place as soon as the energy store (3) is charged after an initial start and drive support from the battery (B) occurs up to this point in time,

- Energy from the energy store (3) is used for a quick start,

- The battery is charged according to its state of charge and

- After recuperation, the vehicle electrical system is powered by the battery (B).

2. Power supply circuit for a motor vehicle electrical system according to claim 1, d a d u r c h g e k e n e z e i c h n e t that a monitoring device (4) is also formed, which monitors the state of charge of the battery (B) and the energy store (3) and transmits the monitoring result to the control device (5).

3. Power supply circuit for a motor vehicle electrical system according to claim 1 or 2, d a d u r c h g e k e n n e e c h n e t that the switches (Sl, S2) are designed as controllable semiconductor switches.

4. Power supply circuit for a motor vehicle according to one of claims 1 to 3, characterized in that that the dynamic energy store (4) is designed as a capacitor.

5. Power supply circuit for a motor vehicle according to claim 4, that the capacitor is designed as a supercap or ultracap.