WO2024046762A1

WO2024046762A1 - Method for client-assisted battery calibration of a battery

Info

Publication number: WO2024046762A1
Application number: PCT/EP2023/072532
Authority: WO
Inventors: Jochen Siehr; Johannes Sieg; Adnan Nuhic; Johannes Schmalstieg; Heiko Witzenhausen; Hermann Pfisterer; Frieder Stöhr; Toni Mrkonjic; Judith BÄHR; Tobias ERBES
Original assignee: Mercedes-Benz Group AG
Priority date: 2022-09-01
Filing date: 2023-08-16
Publication date: 2024-03-07
Also published as: DE102022003202A1

Abstract

The invention relates to a method for client-assisted battery calibration of the battery of an electric vehicle or of a hybrid vehicle. The invention is characterized in that, as needed, a driver is actively prompted to switch the battery to a state in which its state-of-charge and/or capacity is determined if it was not possible to determine its state-of-charge and/or capacity for a certain predefined use of the vehicle.

Description

Mercedes-Benz Group AG

Method for customer-supported battery calibration of a battery

The invention relates to a method for customer-supported battery calibration of a battery of electric or hybrid vehicles according to the type defined in more detail in the preamble of claim 1.

In principle, methods for customer-supported battery calibration of a battery are known from the prior art. In the automotive industry, these are of interest for batteries based on lithium-ion cells that are installed in electric vehicles (EV), hybrid vehicles (HEV), plug-in hybrid vehicles (PHEV) or other electric vehicles. Such batteries include many individual lithium-ion cells, measurement technology for current, voltage and temperature of the cells as well as a battery management system (BMS), which is used, among other things, to determine the condition. The condition determination is used to monitor cell conditions. Important cell states include, for example, a state of charge, called state-of-charge (SOC), and a capacity, which represents a typical amount of charge between a full state and a teaching state, i.e. H. between 100% and 0% SOC.

In order to determine a range forecast and a charging power release, an exact determination of these conditions is essential. Therefore, inaccurately determined SOC values and capacity values lead to inaccurate range forecasts and possibly incorrect charging power releases. If the charging power is incorrectly determined to be too low, the charging time for the customer or driver is incorrectly determined to be too long. Likewise, if the charging power is incorrectly determined to be too high, it can cause irreversible damage to the battery cells. The terms customer and driver can be used interchangeably here. For lithium iron phosphate-based battery cells (LFP-based battery cells), determining the SOC in the battery management system when the vehicle is at rest is more difficult than, for example, for nickel-manganese-cobalt-oxide-based battery cells (NMC-based battery cells). This is due, among other things, to the flatter shape of the open-circuit voltage characteristic (OCV characteristic) over a large SOC range. As a result, a measured resting voltage cannot be converted into an SOC in all states using this characteristic curve. In addition, the conversion is made more difficult by common effects such as temperature dependence (entropy) and hysteresis of the resting voltage characteristic.

As a result, the capacity of the LFP-based battery cells is difficult to determine. As is well known, to determine the capacity, at least two different SOC states are used as well as the amount of charge that has flowed between these states, stated for example in ampere-hours. This amount of charge can be used to determine whether the battery is full or empty. However, since the SOC cannot be determined over wide SOC ranges via the resting voltage characteristic, the capacity cannot be determined in this way either.

There are therefore different approaches in the prior art. For example, a customer or driver is recommended to fully charge LFP-based batteries regularly once a week. This can possibly solve the problem of SOC determination in peace, but not the problem of capacity determination, since the second SOC value is not determined. Other methods are known, using a filter method, for example a sigma point Kalman filter or a particle filter, to estimate the SOC and other conditions using models. However, this results in a high computing requirement, combined with a high data and validation effort.

The object of the present invention is to create a method which overcomes the disadvantages mentioned above. This should be particularly suitable for lithium-ion cells and enable precise determination of the state of charge (SOC) and capacity. According to the invention, this object is achieved by a method with the features in claim 1 and here in particular in the characterizing part of claim 1. Advantageous refinements and further developments result from the dependent claims.

At the core of the method according to the invention, a driver is actively requested, as required, to bring the battery into a state for state-of-charge determination and/or capacity determination if there is no state-of-charge for a certain predefined use of the vehicle -determination and/or no capacity determination was possible. According to the invention, the customer or the driver is therefore actively involved in the method in order to enable a SOC estimate and a capacity estimate in the battery management system. A predefined usage can be, for example, a time, an energy throughput, a distance traveled or something similar. If no SOC determination and/or capacity determination was possible, the battery was not in a suitable condition. As a result, the driver can actively intervene to improve the service life of the battery cells. The term battery also refers to a plurality of batteries or all batteries that are installed in the vehicle.

The customer-assisted battery calibration procedure of a battery is suitable for electric vehicles, hybrid vehicles, plug-in hybrid vehicles or other electric vehicles. The driver can be informed about what to do via a display, for example in connection with a head unit or an application (app).

The driver can preferably be given an indication of a battery calibration process. Such information can include a recommendation as to how the driver can make a SOC determination or a capacity determination possible through active intervention. In this way, the driver or another occupant of the vehicle can be requested, if necessary, to actively bring the battery into a state suitable for the SOC determination. A notice can contain requests such as “Please (dis)charge your vehicle to x% SOC”. The percentage can be specified individually, for example it can be 20% or 100%. Other values are also conceivable. According to a very advantageous development of the idea, it can be provided that the driver can agree to the battery calibration process by activating a process, or can reject the battery calibration process by deactivating the process. Depending on the driver's decision, a targeted calibration process of the battery can be initiated and carried out. Such a calibration process can, for example, have a controlled charging process and/or a controlled discharging process, as described below. The driver can therefore determine the time at which the respective process is started.

According to an advantageous embodiment, it can be provided that a controlled loading or unloading process can be started by the driver. In such a charging or discharging process, the battery can be specifically brought into advantageous states, which have a positive effect on the service life of the battery. The battery can therefore be operated gently and optimally charged or discharged in terms of performance during operation.

A further advantageous embodiment can provide that the controlled charging or discharging process includes unidirectional or bidirectional charging. Other charging options or consumption options are also conceivable.

According to an advantageous embodiment, it can be provided that the battery is specifically brought into state-of-charge areas that enable and/or improve a state-of-charge determination and/or a capacity determination. For example, the driver can also be suggested to use the battery, which is designed to be both battery-friendly in terms of service life and optimal in terms of operation.

A further advantageous embodiment can provide for an advantageous charging current and/or a reduction or increase in the charging current in advantageous state-of-charge ranges. This can also optimize the lifespan and operation of the battery.

According to an advantageous embodiment, it can be provided that determined values of the state-of-charge determination and/or the capacity determination are sent to the driver are displayed. This can be done via a display in the vehicle and/or using an app on a smartphone.

Overall, it is therefore advantageously possible to motivate the driver or another occupant of the vehicle in a targeted manner and as required to ensure the use necessary for stable and optimal operation of the battery. With the proposed improved SOC determination and capacity determination, an improved range forecast and/or an improved charging power release can be made possible. This can have a positive impact on battery life. The method therefore allows the driver to specifically influence the calibration status of the battery. The method can also be used to determine a residual value of the battery, which is, for example, directly dependent on a remaining capacity, using a targeted process at a given time and, for example, to display it at will.

Further advantages of the method according to the invention result from the remaining dependent subclaims and become clear from the exemplary embodiments, which are described in more detail below with reference to the figures.

Show:

Fig. 1 shows a possible embodiment of the method;

Fig. 2 shows another possible embodiment of the method.

A possible embodiment of the method 1 is shown schematically in the illustration in FIG. For example, step 2 may determine that the battery's SOC is poorly calibrated. This can be displayed to the driver, for example on a display in the vehicle, on a smartphone or other mobile device. In step 3, the driver can be given a message to specifically set a specific SOC. This can be done by a request such as “Please charge the vehicle to 30% SOC”. Any percentage can be specified here. An indication can also be given that the vehicle should be discharged to a certain SOC. For example, a note can read: “Please fully charge the battery and leave the vehicle parked for 2 hours”. Another battery calibration recommendation may display a notice or prompt such as “Please keep vehicle below 30% SOC and above 10°C turn off. Connect charging cable and activate battery calibration. The charging time is extended by 3 hours”. These are just examples, with any time and temperature possible. In step 4, the battery SOC can be recalibrated. This can also be displayed to the driver accordingly.

A further embodiment variant of method 1 is shown schematically in FIG. 2. Here, for example, in step 5 the driver can be shown that the battery capacity is poorly calibrated. This can also be done via a display, as described above. In step 6, a request can be made to the driver to specifically set a specific SOC and allow calibration. In step 7, a charging procedure or discharging procedure can specifically control states in order to calibrate the capacity.

With the method 1 described, the battery calibration can therefore be controlled through active intervention by the customer or the driver.

Of course, the described embodiment variants of method 1 in Figures 1 and 2 can also be combined with one another, so that various possibilities arise. For example, a charge status and capacity can be evaluated in just one step.

Claims

Mercedes-Benz Group AG patent claims

1. Method (1) for customer-supported battery calibration of a battery of an electric vehicle or a hybrid vehicle, characterized in that a driver is actively requested, as required, to bring the battery into a state for state-of-charge determination and/or for capacity determination if no state-of-charge determination and/or capacity determination was possible for a certain predefined use of the vehicle.

2. Method (1) according to claim 1, characterized in that the driver is given an indication of a battery calibration process.

3. Method (1) according to claim 2, characterized in that the driver can agree to the battery calibration process by activating a process or reject the battery calibration process by deactivating the process.

4. Method (1) according to one of claims 1 to 3, characterized in that a controlled loading or unloading process can be started by the driver.

5. Method (1) according to claim 4, characterized in that the controlled charging or discharging process comprises unidirectional or bidirectional charging. Method (1) according to one of claims 1 to 5, characterized in that the battery is specifically brought into state-of-charge areas which enable and/or improve a state-of-charge determination and/or a capacity determination. Method (1) according to one of claims 1 to 6, characterized in that an advantageous charging current and/or a reduction or increase in the charging current takes place in advantageous state-of-charge ranges. Method (1) according to one of claims 1 to 7, characterized in that determined values of the state-of-charge determination and/or the capacity determination are displayed to the driver.