WO2020089044A1 - Method and device for detecting a defect in a battery in a low-voltage electrical system of an electric vehicle - Google Patents

Abstract

The present invention relates to a method for detecting a defect in a battery (B) in a low-voltage electrical system of an electric vehicle. The method comprises the step of applying (S1) an electrical load (L) from the electric vehicle to the low-voltage electrical system. The method also comprises the step of sensing (S2) a resulting voltage dip in the battery (B) of the low-voltage electrical system using a voltage sensor (V). The method also comprises the step of determining (S3) the defect if the sensed voltage dip meets a predefined criterion. The present invention also relates to a device for detecting a defect in a battery (B) in a low-voltage electrical system of an electric vehicle.

Description

 Method and device for detecting a defect in a battery in one

Low-voltage electrical system of an electric vehicle

The present invention relates to a method and a device for detecting a defect in a battery in a low-voltage electrical system of an electric vehicle.

State of the art

In conventional vehicles, for example in vehicles with

Internal combustion engine, is diagnosed by starting the vehicle

Low-voltage electrical system battery (NSP-BN battery), mostly 12V or 24V nominal voltage instead. If the vehicle is started successfully, it can be assumed that the NSP-BN battery is OK. If the NSP-BN battery is defective or worn, the vehicle will no longer start because the NSP-BN battery is no longer able to provide the required power for the starter (starter). The vehicle remains in a safe state (the engine does not start) and can no longer be moved. The driver can clearly see that the vehicle or the NSP-BN battery must be checked in a workshop.

In electric vehicles, this high level of stress is lacking

Starting process, for example through the starter's current consumption. The electric vehicle can also be started with an almost defective or worn NSP-BN battery, since the currents required during the starting process of an electric vehicle are relatively low and shortly after the starting of the electric vehicle, the low-voltage electrical system of the electric vehicle through the DC / DC converter is supported or supplied. This has the disadvantage that a defective NSP-BN battery, for example 12V, is only recognized when it is finally defective. In the worst case, a defective NSP-BN battery is not recognized and, if the DC / DC converter fails at the same time, the NSP-BN breaks in. This can be critical

Lead driving situation. Neither the impending defect (NSP-BN battery weak / deeply discharged) nor the defect that has occurred (NSP-BN battery without any significant capacity and so low-impedance that the DC / DC converter can power the network just enough support) is recognized. A failure of the DC / DC converter that then occurs can lead to a critical driving situation (possibly and possibly endangering road users).

Circuit arrangements for checking an operating state of a battery are known, for example, from DE 10 2014 003309 Al.

Disclosure of the invention

The present invention provides a method and a device for detecting a defect in a battery in a low-voltage electrical system of an electric vehicle according to independent claims 1 and 10, respectively.

The present invention provides a method for detecting a defect in a battery in a low-voltage electrical system of an electric vehicle, with a first step of applying an electrical consumer of the electrical vehicle to the low-voltage electrical system. The method further comprises the second step of detecting a resulting one

Voltage drop in the battery of the low-voltage electrical system with a voltage sensor. The method further comprises the third step of determining the defect when the detected voltage drop occurs

specified criterion met.

Furthermore, the present invention provides a device for detecting a defect in a battery in a low-voltage electrical system of an electric vehicle, with a control device, a switching device, an electrical consumer and a voltage sensor, which is designed such that an electrical consumer is switched by a switching device with a battery Low-voltage electrical system of the electric vehicle is electrically connected and the switching device is actuated via a control device. Furthermore, a resulting voltage drop in the battery of the low-voltage electrical system is detected with a voltage sensor and a defect in the battery is determined if the detected voltage drop meets a predetermined criterion. Furthermore, the present invention provides a computer program product according to independent claim 9.

The present invention relates to a computer program product with a program code stored on a machine-readable carrier

Carrying out a method according to claims 1 to 8, if the

Program running on a control device of the electric vehicle.

The computer program product can be executed with a control device. The control device can be an electrical control unit

Vehicle, comprising a processor and a memory. In addition, the control device can be a microcontroller or a computer.

Advantages of the invention

The method and the device for detecting a defect in a battery according to the present invention enable existing components in electric vehicles to be used for diagnosing the NS P-BN battery. Even before the low-voltage on-board electrical system (NSP-BN) is supported by the DC / DC converter, a previously defined load, for example an electrical consumer of the electric vehicle, can be applied to the NS P-BN battery in order to detect a possible defect in the NSP -BN- to recognize battery. Advantageously, the 12V consumers in an electric vehicle can be used as an electrical load, in which a measurable and correspondingly noticeable drop in voltage occurs,

for example on the rear window heater or seat heater. Additional consumers, which are only switched on or off again specifically for diagnosis, are not required.

Furthermore, existing electrical consumers and / or controllable loads, for example bidirectional DC / DC converters, advantageously offer the possibility of identifying relevant properties of the battery during a start or over a sequence of several starts. These include the state of health (SOH) and the state of charge (SOC) of the battery. This can be used, on the one hand, to predict the future Battery behavior and on the other hand to derive remedial measures, for example battery training, controlled cycling and the creation of defined loading / unloading profiles.

The idea on which the present invention is based thus consists in using existing components and thus additionally saving hardware components, such as an intelligent 12 V battery sensor. Systems known in the prior art require

Determine the current current and voltage an intelligent battery sensor. In the present invention, existing voltage sensors of the electric vehicle, for example the voltage sensors of the vehicle control units or the DC / DC converter, are advantageously used individually or in combination in order to detect a voltage drop beyond a predetermined criterion and thus to determine a defect in the battery .

Advantageously, the method and the device according to the present invention can also be used for batteries with a 24V or 48V nominal voltage.

It is also advantageous that the battery of the electric vehicle can be dimensioned smaller and scarcer, since a defect in the battery is determined before the electric vehicle starts and thus the previously required remaining capacities of the battery, as a reserve for safe operation of the electric vehicle, are no longer are necessary.

The NS P-BN battery is advantageously diagnosed reliably, thus ensuring the necessary redundancy of the 12 V voltage supply. This ensures that in the event of a failure if the previous defect of the 12V battery is not recognized, the function of electrical braking and steering support and possibly other important vehicle functions do not cease to apply.

Increased wear can also be diagnosed and displayed to the vehicle driver. An early replacement of the 12V Batteries take place and the number of technical downtimes and non-starting vehicles are greatly reduced. The increased wear occurs when the battery has reached the end of its useful life and needs to be replaced.

Preferred developments are the subject of the respective subclaims.

According to a preferred embodiment, the first step and the second step are repeated at least one more time and the defect in the battery is determined in the third step if the voltage drop repeatedly fulfills the predetermined criterion.

 This embodiment is advantageous in that the state of the battery and thus the wear and / or the defect can also be determined via a trend.

According to a preferred embodiment, the defect in the battery of the low-voltage electrical system is determined before the electric vehicle is started.

This embodiment is advantageous in that a defect in the battery can be determined before the electric vehicle is started and thus before the start of use. Critical driving situations due to the failure of the battery while driving can be better avoided.

According to a preferred embodiment, the defect in the battery of the low-voltage electrical system is determined after a DC / DC converter of the electric vehicle has been switched off.

This embodiment is advantageous in that the battery of the electric vehicle can be checked even with a long driving cycle time.

DC / DC converters in LV / HV operation are best suited to apply a short, high load to the NSP-BN without large energy loss. According to a preferred embodiment, the defect in the battery of the low-voltage on-board electrical system is determined during a diagnostic phase and the predetermined criterion includes a break-in and a recovery

Battery voltage in the diagnostic phase.

This embodiment is advantageous in that the collapse of the

Voltage represents the condition and thus possible wear of the battery.

According to a preferred embodiment, the electrical consumer of the electric vehicle is applied to the low-voltage electrical system in a pulsed manner.

This embodiment is advantageous in that the battery of the electric vehicle can be tested more gently and has a longer service life.

According to a preferred embodiment, a warning message

output when the detected voltage drop fulfills a specified criterion.

This embodiment is advantageous in that the battery of the electric vehicle is worn out but still provides power that the wear and tear of the battery is signaled to the vehicle driver and he initiates appropriate measures, for example, to have the battery replaced before a defect occurs in the battery.

According to a preferred embodiment, the drive of the electric vehicle is deactivated when the detected voltage drop fulfills a predetermined criterion.

This embodiment is advantageous in that if a defect of the battery is determined, the further use of the electric vehicle

is prevented in order to avoid possible critical driving situations. According to a preferred embodiment, the wear of the battery is determined, the voltage drops in the battery being recorded over the service life of the battery.

The state of health of the battery can thus advantageously be determined over the period of use.

Brief description of the drawings

Show it:

Fig. 1 is a schematic representation for explaining a device 10 for detecting a defect in a battery B in one

 Low-voltage electrical system of an electric vehicle according to an embodiment of the present invention;

Fig. 2 is a schematic representation for explaining a method for detecting a defect of a battery B in one

 Low-voltage electrical system of an electric vehicle according to an embodiment of the present invention;

Fig. 3 is a schematic representation for explaining a first

 Voltage curve 1 during diagnosis with a functioning battery B;

Fig. 4 is a schematic representation for explaining a second

 Voltage curve 2 during the diagnosis of a worn battery B;

Fig. 5 is a schematic representation for explaining a third

 Voltage curve 3 during the diagnosis of a defective battery B;

In the figures, elements that are the same or have the same function are provided with the same reference symbols. Description of the embodiments

1 is a schematic illustration for explaining a device 10 for detecting a defect in a battery B in a low-voltage electrical system of an electric vehicle.

In Fig. 1, reference symbol SC denotes a switching device which is connected to a battery B, typically a 12V low-voltage on-board electrical system battery (NSP-BN battery). The switching device SC is set up in such a way that an electrical consumer L, preferably an existing electrical component of the electric vehicle with the battery B des

To connect low-voltage electrical system of the electric vehicle. All electrical components of the electric vehicle can be used as electrical consumers, by means of which a noticeable

Voltage drop can be generated, for example the

Rear window heater or the seat heater. The switching device SC is connected to a control device ST. The control device ST actuates the switching device SC.

The device 10 is also set up to connect a voltage sensor V in parallel to the electrical load L in order to detect a resulting voltage drop in the battery B of the low-voltage electrical system (NSP-BN). In this case, a voltage drop is to be understood as the no longer possible possibility of providing battery B with current. This depends on the switched electrical load L and on the nominal voltage of the battery B.

The device 10 is also set up to determine the defect of the battery B when the detected voltage range meets a predetermined criterion. The predetermined criterion depends on the battery B used in the low-voltage electrical system of the electric vehicle. The device 10 can be used to determine a defect in batteries B with a nominal voltage of 12V, 24V and 48V. The device 10 of the present invention makes it possible to reliably diagnose a defect of the battery B in the NSP-BN, for example a short circuit, a worn battery B due to the service life, deep discharge or damage due to thermal stress, without using an intelligent battery sensor as a voltage sensor V or an additional electrical consumer L must be installed in the electric vehicle. If a defect in the battery is found, the vehicle can be brought into a safe state, for example the drive torque is denied. Furthermore, the defect can be shown to the vehicle driver, for example in a head-up display or on a multifunctional display of the electric vehicle.

In an alternative embodiment, the DC / DC converter can be switched off in support of the 12V battery B in the case of electric vehicles with a long driving cycle time and which have a high power consumption. This would have the consequence that all of the electrical consumers L that are switched on are supplied by the battery B and cause a voltage drop in the battery B. Diagnosis D can thus also be carried out while the vehicle is stationary by switching off the charging function of the DC / DC converter. This is possible as long as there are no objections to safety, for example the danger to other road users.

In one embodiment, the diagnosis to be carried out with existing electrical consumers L can be carried out in pulse form, similar to a start pulse for conventional starters, in which a high maximum current flows in the order of a few 10 ms, or as quasi-steady state diagnosis with rather medium currents over a somewhat longer period. The length of the pulse depends on the amplitude of the voltage dip that can be achieved with the electrical loads L.

FIG. 2 is a schematic illustration for explaining a method for detecting a defect in a battery B in a low-voltage electrical system of an electric vehicle. The method for detecting a defect in a battery B in a

Low-voltage on-board electrical system of an electric vehicle comprises, before starting the electric vehicle, a defined electrical consumer L of the electric vehicle is applied to the low-voltage on-board electrical system of the electric vehicle in a first step S1. The electric one

Consumer L can be, for example, a bidirectional DC / DC converter, the rear window heater or seat heater of the electric vehicle.

Due to the applied consumer, the voltage on the 12V side of battery B will drop or decrease by a certain value. The value of the voltage dip depends on the system and the load. The voltage drop in battery B of the low-voltage electrical system is caused by a

Voltage sensor V detected in a second step S2. The voltage sensor V is preferably an existing voltage sensor V of the DC / DC converter or a vehicle control unit and can be used individually or in combination to determine the voltage dip.

If the detected voltage drop fulfills a specified criterion, it can be assumed that the battery B is defective. The defect of the battery B is determined in a third step S3. If there is a defect, the vehicle start can be stopped or the electric vehicle can be switched to a safe state (drive without function) and this can be signaled to the driver.

Fig. 3 is a schematic illustration for explaining a first

Voltage curve 1 during diagnosis D with a functioning battery B.

3 shows the first voltage curve 1 during the diagnosis D of a battery B, in particular in the case of a functioning battery B. The axis of abscissa represents the time course of the first voltage course 1 in seconds [s] and the ordinate axis represents the voltage drop during the diagnosis D in volts [V]. The schematic illustration is divided into three voltage ranges 11, 12 and 13. The voltage range 11 is the first voltage range in which the battery B is rated as working. The second voltage range 12 is the voltage range at which the battery B is rated as worn. The third voltage range 13 is the

Voltage range at which the battery B has a defect.

In FIG. 3, before the electric vehicle starts, an electrical consumer L is switched by the switching device SC into the NSP-BN of the electric vehicle. The first voltage curve 1 has one

Voltage drop within the diagnosis phase D. The

Voltage drop does not exceed the first voltage range 11, as a predetermined criterion for a functioning battery B. In addition, the battery recovers within the diagnostic phase. For the battery B according to the first voltage curve 1 in FIG. 3, no defect is thus determined and the battery B is rated as OK. The voltage ranges 11, 12 and 13 must be adjusted according to the nominal voltage of the battery used (12V, 24V, 48V).

During the diagnosis, it is not the absolute voltage drop that is assessed, but the relative voltage value and how this is within the

Diagnostic phase D recovers when the electrical consumer L is disconnected from the NSP-BN of the electric vehicle. The predefined criterion thus indicates the maximum amplitude of the voltage drop and the duration (diagnosis phase) of the voltage drop until the maximum amplitude is reached and the battery B is recovered until the voltage that is still possible is reached.

Fig. 4 is a schematic illustration for explaining a second

Voltage curve 2 during diagnosis D with a worn battery B.

4 shows the second voltage curve 2 during the diagnosis D of a battery B, in particular in the case of a worn battery B. Before the starting process, a defined electrical consumer L is switched by the switching device SC into the NSP-BN of the electric vehicle. The second voltage curve 2 exhibits a voltage dip within the diagnosis phase D. The voltage drop exceeds the first

Voltage range 11, as a predetermined criterion for a functioning Battery B. Due to the electrical consumer L applied, the voltage on the 12V side drops by a certain value (system and

Due to load) and reaches the second voltage range 12, as

predefined criterion for a worn out battery B. After a

Switching off the electrical consumer L, the voltage of the battery B recovers and reaches the first voltage range 11.

This diagnosis can be carried out repeatedly over several measurements. If the second voltage range 12 is repeatedly reached during the diagnosis, it can be assumed that the battery B is worn out. In this scenario, further use of the electric vehicle is not prohibited. The driver is advised, for example, that he should go to a workshop with the electric vehicle, since the worn-out battery B threatens to keep the electric vehicle at a standstill.

In one embodiment, the battery B is rated as worn out if the second voltage range 12 is reached in two successive diagnoses.

In an alternative embodiment, the battery B is rated as worn out if the second voltage range 12 is repeatedly reached in the case of successive diagnoses, determined by a counter. The counter value of the counter can be reset to its starting value by reaching the first voltage range 11, so that the counting for the repeated diagnosis begins again. Only when the defined meter reading is reached is the vehicle driver warned and / or the electric vehicle is put into the safe state (drive without function).

5 is a schematic illustration for explaining a third one

Voltage curve 3 during diagnosis D with a defective battery B.

5 shows the third voltage curve 3 during the diagnosis D of a battery B, in particular in the case of a defective battery B. Before the starting process, a defined electrical consumer L is switched by the switching device SC into the NSP-BN of the electric vehicle. The third course of tension 3 has a voltage drop within the diagnostic phase D. The voltage drop exceeds the first voltage range 11, as a predefined criterion for a functioning battery B, and the second voltage range 12, as a predefined criterion for a worn battery B. Due to the electrical load L applied, the voltage drops

Voltage on the 12V side around a certain value (system and

Due to load) and reaches the third voltage range 13, as

Predefined criterion for a defective battery B. After the electrical consumer L is switched off, the voltage of the battery B recovers and reaches the first voltage range 11. The voltage drop in FIG. 5 represents an extreme drop, which suggests that the battery B can no longer provide the necessary electricity for the electrical consumer L. A defect for the battery B is thus determined. With a worn or defective battery B, the voltage drop is much greater than with an intact battery B. In addition, the recovery of the battery can take place more slowly.

5, the beginning of the third voltage curve 3 lies in the first

Voltage range 11. A defective battery can, however, already have a limited voltage, so that the third voltage curve 3 can already lie in the second voltage range 12 when the electrical consumer L is applied.

Claims

Expectations

1. A method for detecting a defect in a battery (B) in one

 Low-voltage electrical system of an electric vehicle with the steps:

- Creating (Sl) an electrical consumer (L) of the electrical

 Vehicle to the low-voltage electrical system;

 - Detecting (S2) a resulting voltage dip in the battery (B) of the low-voltage electrical system with a voltage sensor (V); and

- Determine (S3) the defect if the detected voltage drop fulfills a predetermined criterion.

2. The method of claim 1, wherein the first step (S1) and the second step (S2) are repeated at least one more time and the defect of the battery (B) is determined in the third step (S3) when the

 Voltage drop repeatedly meets the specified criterion.

3. The method according to claim 1 or 2, wherein the determination of the defect of the battery (B) of the low-voltage electrical system is carried out before the start of the electric vehicle.

4. The method according to claim 1 or 2, wherein the determination of the defect of the battery (B) of the low-voltage electrical system is carried out after switching off a DC / DC converter of the electric vehicle.

5. The method according to any one of the preceding claims 1 to 4, wherein the determination of the defect of the battery (B) of the low-voltage electrical system takes place during a diagnostic phase (D) and the predetermined criterion of a break-in and a recovery of the voltage of the battery (B) in the

 Diagnostic phase (D) includes.

6. The method according to any one of the preceding claims 1 to 5, wherein the application of the electrical consumer (L) of the electric vehicle to the low-voltage electrical system is pulse-shaped.

7. The method according to any one of the preceding claims 1 to 6, wherein a warning message is issued if the detected voltage drop meets the predetermined criterion.

8. The method according to any one of the preceding claims 1 to 7, wherein the drive of the electric vehicle is deactivated when the detected voltage drop meets the predetermined criterion.

9. Computer program product with a program code stored on a machine-readable carrier for carrying out a method according to claims 1 to 8 when the program runs on a control device (ST) of the electric vehicle.

10. Device (10) for detecting a defect in a battery (B) in one

 Low-voltage electrical system of an electric vehicle, with one

 Control device (ST), a switching device (SC), an electrical consumer (L) and a voltage sensor (V), which is designed such that

 - An electrical consumer (L) is electrically connected by a switching device (SC) to a battery (B) of a low-voltage electrical system of the electric vehicle, the switching device (SC) via a

 Control device (ST) is operated;

 - With a resulting voltage drop in the battery (B) of the

 Low-voltage electrical system with a voltage sensor (V) can be detected;

- A defect in the battery (B) can be determined when the detected

 Voltage drop fulfills a specified criterion.