WO2023030835A1 - Method for determining an availability of an electrical energy store, electrical energy store, and device - Google Patents

Abstract

The invention relates to a method for determining an availability of an electrical energy store, which comprises at least one electrical energy storage cell and at least one sensor, wherein a demanded power profile is specified for the electrical energy store, more particularly a demanded power is defined by means of the demanded power profile, a prospective voltage of the electrical energy store is compared with a minimum voltage limit value of the electrical energy store and/or a present minimum state of charge (SOCmin) is compared with a state of charge (SOCtab) of the electrical energy store which is required for the demanded power profile, and a result of the comparison is output, more particularly whether the electrical energy store has an availability required for the demanded power profile.

Description

Description

title

Method for determining an availability of an electrical energy store, electrical energy store and device

field of invention

The present invention relates to a method for determining an availability of an electrical energy store, an electrical energy store and a device.

State of the art

DE 10 2014 103 803 A1 discloses a battery state estimator that combines an electrochemical solid state concentration model with an empirical equivalent circuit model.

US 2016/0055736 A1 shows an improved battery early warning system and a battery monitoring system.

DE 10 2010 024241 A1 discloses a method for use with a vehicle battery stack that has a large number of battery cells.

Disclosure of Invention

The core of the invention in the method for determining an availability of an electrical energy storage device, which has at least one electrical energy storage cell and at least one sensor, is that a required performance profile for the electrical energy storage device is specified, in particular with a required performance being determined by means of the required performance profile becomes, wherein an expected voltage of the electrical energy store is compared with a minimum voltage limit value of the electrical energy store and/or a current minimum state of charge is compared with a state of charge of the electrical energy store required for the required performance profile, with a result of the comparison being output, in particular whether the electrical energy store has the availability required for the required performance profile.

The background to the invention is that the availability of the electrical energy store can be determined with improved accuracy.

Advantageously, a reliable statement can be made as to whether the available power of the electrical energy store is sufficient, for example, for an autonomous driving maneuver of an at least partially electrically powered vehicle.

Further advantageous embodiments of the present invention are the subject matter of the dependent claims.

According to an advantageous embodiment, the availability of the electrical energy store for the required performance profile is sufficient if the expected voltage of the electrical energy store is greater than the minimum voltage limit value of the electrical energy store and/or if the current minimum state of charge is greater than the state of charge required for the required performance profile of the electrical energy storage. A clear statement can thus be made about the availability of the electrical energy store.

It is advantageous if a respective hysteresis threshold value is used when comparing the expected voltage of the electrical energy store with the minimum voltage limit value of the electrical energy store and/or when comparing the current minimum state of charge with the state of charge of the electrical energy store required for the required performance profile. By means of the hysteresis threshold flickering when deciding on the availability of the electrical energy storage device can be avoided if the expected voltage fluctuates around the minimum voltage limit value or if the current minimum state of charge fluctuates around the state of charge of the electrical energy store required for the required performance profile. For this purpose, the hysteresis threshold value is added to or subtracted from the respective reference value, so that a value range is defined with which the expected voltage or the current minimum state of charge is compared.

An expected current is advantageously determined as the quotient of the required power and an expected voltage of the electrical energy store.

It is also advantageous if an expected cell voltage is determined using an electrochemical battery model from the expected current and status parameters of an electrical energy storage cell and the expected voltage of the electrical energy store is determined from the expected cell voltages of all electrical energy storage cells. In this case, the accuracy in determining the expected voltage can be improved by means of the electrochemical battery model.

Advantageously, at least individual method steps of the method are repeated repeatedly over time, the expected voltage of the electrical energy storage device determined by means of the electrochemical battery model being used to determine the expected current. Thus, the accuracy in determining the expected current can be improved with each run of the method. In addition, in the case of a dynamically fluctuating required performance profile, the prediction of the availability can be adapted to the performance profile.

According to an advantageous embodiment, an open-circuit voltage and a voltage drop of the electrical energy storage cell are used to determine the anticipated cell voltage, in particular the open-circuit voltage and the voltage drop of the electrical energy storage cell using an ohmic resistor, a charge transfer resistor and a Diffusion resistance of the electrical energy storage cell can be determined. The ohmic resistance, the charge transfer resistance and the diffusion resistance of the electrical energy storage cell can advantageously be taken from a data sheet for the electrical energy storage cell.

According to a further advantageous embodiment, a voltage drop, an ohmic resistance, an open circuit voltage, a temperature of the electrical energy storage cells and a capacitance of the electrical energy storage cells are used as input parameters for determining the probable voltage of the electrical energy storage. The accuracy in determining the availability can thus be further improved.

Furthermore, it is advantageous if the probable cell voltage of an electrical energy storage cell is the sum of a probable no-load voltage of the electrical energy storage cell and a probable diffusion voltage of the electrical energy storage cell.

It is advantageous if the anticipated open-circuit voltage of the electrical energy storage cell and the anticipated diffusion voltage of the electrical energy storage cell are determined using a time integral over the anticipated current, a capacity of the electrical energy storage cell and a state of charge of the electrical energy storage cell. The accuracy in determining the availability can thus be further improved.

According to a further advantageous embodiment, at the beginning of the method, a database or table with pre-calibrated values for an availability of the electrical energy store as a function of a state of charge of the electrical energy store at a respective temperature is created, in particular the database or table being stored in a storage medium of the electrical energy store is, using the required performance profile and a current temperature of the electrical energy store from the database or table, a required state of charge for the electrical energy store to run the required performance profile is determined. This enables a high level of accuracy when determining the availability with little effort at the same time.

Furthermore, it is advantageous if, at the beginning of the method, it is checked whether the electrical energy storage device has a temperature below a maximum temperature and an initial state of charge of the electrical energy storage device can be determined.

The core of the invention in the case of the electrical energy store is that an availability of the electrical energy store can be determined using a method as described above or according to one of the claims relating to the method.

For this purpose, the electrical energy store advantageously has a control unit which is set up to carry out the method at least partially.

The background to the invention is that the availability of the electrical energy store can be determined with improved accuracy.

The core of the invention in the device, in particular the vehicle, is that the device has an electrical energy store as described above or according to one of the claims relating to the electrical energy store.

The background to the invention is that the availability of the electrical energy store for a power requirement of the device can be determined with improved accuracy.

Advantageously, this makes it possible to predict whether the availability of the electrical energy store is sufficient for an autonomous driving maneuver of the vehicle. In this way, a failure of the vehicle during the driving maneuver can be avoided.

The above configurations and developments can be combined with one another as desired, insofar as this makes sense. Other possible configurations, further training and Implementations of the invention also include combinations of features of the invention described above or below with regard to the exemplary embodiments that are not explicitly mentioned. In particular, the person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the present invention.

Brief description of the drawings

In the following section, the invention is explained using exemplary embodiments, from which further inventive features can result, but to which the scope of the invention is not limited. The exemplary embodiments are shown in the drawings.

Show it:

1 shows a schematic flowchart of a first exemplary embodiment of a method according to the invention for determining an availability of an electrical energy store;

2 shows a schematic flow chart of a second exemplary embodiment of the method according to the invention for determining an availability of an electrical energy store;

3 shows a schematic flowchart of a third exemplary embodiment of the method according to the invention for determining an availability of an electrical energy store and

4 shows a schematic flowchart of method steps for predicting a cell voltage Ucell.pred for the third exemplary embodiment of the method according to the invention.

1 shows a schematic flow chart of the first exemplary embodiment of the method according to the invention for determining an availability of an electrical energy storage device that has a plurality of electrical energy storage cells and at least one sensor, in particular a current sensor, a voltage sensor and a temperature sensor. The electrical energy storage cells are preferably arranged in series, with each electrical energy storage cell having its own voltage sensor and the electrical energy storage having a single current sensor and temperature sensor.

Alternatively, several temperature sensors can also be arranged in the electrical energy storage device and/or each electrical energy storage cell or subsets of the electrical energy storage cells can each have a current sensor and/or a temperature sensor.

According to the first exemplary embodiment, at the beginning of the method, a database or table with precalibrated values for a power availability of the electrical energy store as a function of a state of charge of the electrical energy store at a respective temperature is created. The database or table is stored in a storage medium of the electrical energy store.

In a first method step of the method, it is checked whether the electrical energy store has a temperature T below a maximum temperature Tmax and an initial state of charge SOCin of the electrical energy store can be determined.

In a second method step, a required performance profile for the electrical energy store, for example an autonomous driving request from a vehicle, is recorded. Using the required power profile and the current temperature T of the electrical energy store, a required state of charge SOCtab for the electrical energy store for executing the required power profile is determined from the database or table.

In a third method step, the current minimum state of charge SOCmin of the electrical energy store is recorded. The minimum state of charge SOCmin of the electrical energy store preferably corresponds to the minimum state of charge of all electrical energy store cells of the electrical energy store. In a fourth method step, the current minimum state of charge SOCmin is compared with the required state of charge SOCtab in order to decide whether the electrical energy store has sufficient power availability for the required power profile. For this purpose, the minimum state of charge SOCmin of the electrical energy storage device at the beginning of the process must be greater than the sum of the required state of charge SOCtab and a hysteresis threshold value, and the minimum state of charge SOCmin must not fall below a difference between the required state of charge SOCtab and the hysteresis threshold value during the process. The hysteresis threshold is, for example, 0.1% to 5% of the required state of charge SOCtab.

In a fifth method step, the result of the comparison is output, ie whether the electrical energy storage device has a power availability required for the required power profile.

In Fig. 2, the second embodiment of the method according to the invention is shown schematically.

In a first method step, a required performance profile Pprof for the electrical energy store, for example an autonomous driving request from a vehicle, is recorded. A maximum required power Preq is determined using the required power profile Pprof.

In a second method step, a probable current Ipred is determined as the quotient of the maximum required power Preq and a probable voltage Upack.pred of the electrical energy store.

In a third method step, an expected cell voltage Ucell.pred is determined using an electrochemical battery model BM from the expected current Ipred and status parameters of an electrical energy storage cell, in particular a state of charge SOCcell and a temperature Tcell of the electrical energy storage cell. For this purpose, an open-circuit voltage and a voltage drop of the electrical energy storage cell are used, which are determined by means of an ohmic resistance, a charge transfer resistance and a diffusion resistance. These resistances can be read or taken from a data sheet for the electrical energy storage cell, for example.

In a fourth method step, the expected voltage of the electrical energy store Upack.pred is determined from the expected cell voltages Ucell.pred of all electrical energy storage cells, for example as the sum of the expected cell voltages Ucell.pred of all electrical energy storage cells in the case of a pure series connection of the electrical energy storage cells.

In a fifth method step, the probable voltage of the electrical energy store Upack.pred is compared with a minimum voltage limit value of the electrical energy store. The power availability of the electrical energy store is sufficient for the required power profile Pprof if the anticipated voltage of the electrical energy store Upack.pred is greater than the minimum voltage limit of the electrical energy store.

In a sixth method step, the result of the comparison is output, that is to say whether the electrical energy store has the power availability required for the required power profile.

The method is then preferably continued with the second method step and the probable voltage of the electrical energy store Upack.pred from the fourth method step is used to determine the probable current Ipred.

In Fig. 3, the third embodiment of the method according to the invention is shown.

In addition to the second exemplary embodiment of the method, in the third exemplary embodiment the voltage drop Udropinit and the ohmic resistance Rinit at the beginning of the method as well as the current no-load voltage OCVact of the electrical energy storage cells are measured using an electrochemical battery cell model CM determines, which takes into account the current temperature Tcell of the electrical energy storage cells.

The current temperature Tcell of the electrical energy storage cells is determined by means of a temperature sensor ST.

The current capacity C of the electrical energy storage cells is taken from a data sheet Ccell.tab for the electrical energy storage cells. The current capacity C is the capacity of the electrical energy storage cells that they have at the current time of the method due to their aging.

The voltage drop Udropinit and the ohmic resistance Rinit at the start of the process, as well as the current open circuit voltage OCVact, the current temperature Tcell of the electrical energy storage cells and the current capacitance C of the electrical energy storage cells are used as input parameters for determining the expected voltage of the electrical energy storage device Upack.pred.

As in the second exemplary embodiment, the anticipated voltage Upack.pred of the electrical energy storage device is determined from the anticipated cell voltage Ucell.pred and compared with a minimum voltage limit value of the electrical energy storage device. The power availability of the electrical energy store is sufficient for the required power profile Pprof if the anticipated voltage of the electrical energy store Upack.pred is greater than the minimum voltage limit of the electrical energy store.

The result of the comparison is then output, ie whether the electrical energy store has the power availability required for the required power profile.

Method steps for predicting a cell voltage Ucell.pred according to the third exemplary embodiment are shown in detail in FIG. 4 .

A probable current Ipred, as the first quotient of the maximum required power Preq and a probable voltage Upack.pred of the electric Energy storage is integrated over time t, and a second quotient formed from this integral and the current capacity C of an electrical energy storage cell.

A current state of charge SOCact of the electrical energy store is determined and added to the second quotient. This sum corresponds to a required state of charge SOC of the electrical energy storage cell for the required power profile Pprof.

A probable no-load voltage Uocv.pred of the electrical energy storage cell is determined using the required state of charge SOC.

The resistance REOL of the electrical energy storage cell at the end of its service life is determined from a database using the required state of charge SOC and the cell temperature Tcell. The prospective diffusion voltage Udiff.pred of the electrical energy storage cell is determined as the product of the resistance REOL of the electrical energy storage cell at the end of its useful life and the prospective current Ipred.

The sum of the probable no-load voltage Uocv.pred of the electrical energy storage cell and the probable diffusion voltage Udiff.pred then results in the probable cell voltage Ucell.pred.

An electrical energy store is understood to mean a rechargeable energy store, in particular having an electrochemical energy storage cell and/or an energy storage module having at least one electrochemical energy storage cell and/or an energy storage pack having at least one energy storage module. The energy storage cell can be designed as a lithium-based battery cell, in particular a lithium-ion battery cell. Alternatively, the energy storage cell is designed as a lithium polymer battery cell or nickel metal hydride battery cell or lead acid battery cell or lithium air battery cell or lithium sulfur battery cell.

A vehicle is understood here as a land vehicle, for example a passenger car or a truck, or an aircraft or a watercraft, in particular an at least partially electric one powered vehicle. The vehicle is, for example, a battery-electric vehicle that has a purely electric drive, or a hybrid vehicle that has an electric drive and an internal combustion engine.

Claims

Claims Method for determining the availability of an electrical energy storage device, which has at least one electrical energy storage cell and at least one sensor, with a required performance profile (Pprof) being specified for the electrical energy storage device, in particular with a required performance (Preq) being determined by means of the required performance profile (Pprof) is determined, with an expected voltage of the electrical energy store (Upack.pred) being compared to a minimum voltage limit value of the electrical energy store and/or a current minimum state of charge (SOCmin) being compared to a state of charge (SOCtab) required for the required performance profile of the electrical energy store , a result of the comparison being output, in particular whether the electrical energy store has the availability required for the required power profile (Pprof). The method according to claim 1, characterized in that the availability of the electrical energy store for the required power profile (Pprof) is sufficient if the expected voltage of the electrical energy store (Upack.pred) is greater than the minimum voltage limit of the electrical energy store, and / or that the availability of the electrical energy store for the required power profile (Pprof) is sufficient if the current minimum state of charge (SOCmin) is greater than the state of charge (SOCtab) required for the required power profile of the electrical energy store. Method according to Claim 2, characterized in that when comparing the expected voltage of the electrical energy store (Upack.pred) with the minimum voltage limit value of the electrical energy store and / or when comparing the current minimum state of charge (SOCmin) with the state of charge required for the required performance profile (SOCtab) of the electrical energy store, a respective hysteresis threshold value is used. Method according to one of the preceding claims, characterized in that an expected current (Ipred) is determined as the quotient of the required power (Preq) and an expected voltage (Upack.pred) of the electrical energy store. Method according to Claim 4, characterized in that an expected cell voltage (Ucell.pred) is determined using an electrochemical battery model (BM) from the expected current (Ipred) and status parameters of an electrical energy storage cell and from the expected cell voltages (Ucell.pred) of all electrical Energy storage cells, the expected voltage of the electrical energy storage (Upack, pred) is determined. Method according to claim 5, characterized in that

Method steps of the method are repeated repeatedly over time, the expected voltage of the electrical energy store (Upack.pred) determined by means of the electrochemical battery model (BM) being used to determine the expected current (Ipred). Method according to Claim 5 or 6, characterized in that an open-circuit voltage and a voltage drop in the electrical energy storage cell are used to determine the expected cell voltage (Ucell.pred), in particular the open-circuit voltage and the voltage drop in the electrical energy storage cell using an ohmic resistor, a charge transfer resistor and a diffusion resistance of the electrical energy storage cell can be determined. - 15 - Method according to one of claims 5 to 7, characterized in that a voltage drop (Udropinit), an ohmic resistance, an open circuit voltage (OCVact), a temperature (Tcell) and a capacitance (C) of the electrical energy storage cells as input parameters for the Determination of the expected voltage (Upack.pred) of the electrical energy store can be used. Method according to one of the preceding claims, characterized in that the anticipated cell voltage (Ucell.pred) of an electrical energy storage cell is the sum of an anticipated open circuit voltage (Uocv.red) of the electrical energy storage cell and an anticipated diffusion voltage (Udiff.pred) of the electrical energy storage cell, In particular, the anticipated open circuit voltage (Uocv.pred) of the electrical energy storage cell and the anticipated diffusion voltage (Udiff.pred) of the electrical energy storage cell by means of a time integral over the anticipated current (Ipred), a capacity (C) of the electrical energy storage cell and a state of charge (SOCact ) of the electrical energy storage cell can be determined. Method according to one of the preceding claims, characterized in that at the beginning of the method a database or a table with pre-calibrated values for an availability of the electrical energy store depending on a state of charge (SOCtab) of the electrical energy store at a respective temperature (T) is created, In particular, the database or table being stored in a storage medium of the electrical energy store, a required state of charge (SOCtab) for the electrical energy store for execution using the required power profile (Pprof) and a current temperature (T) of the electrical energy store from the database or table of the required performance profile (Pprof) is determined. Method according to one of the preceding claims, - 16 - characterized in that at the beginning of the method it is checked whether the electrical energy store has a temperature (T) below a maximum temperature (Tmax) and an initial state of charge (SOCin) of the electrical energy store can be determined. Electrical energy store having electrical energy storage cells and at least one sensor, characterized in that the availability of the electrical energy store can be determined using a method according to one of the preceding claims. Device, in particular a vehicle, having an electrical energy store according to Claim 12.