WO2023187172A1 - Electrical connection between a vehicle and a charging station - Google Patents

Abstract

The invention relates to an electrical connection (10) between a vehicle (18) and a charging station (22), having a vehicle-side terminal (14) and a charging station-side terminal (16). The electrical connection (10) comprises additional functionalities (24) integrated into the vehicle-side terminal (14) and/or into the charging station-side terminal (16). The invention furthermore relates to a method for determining an exact geolocation of an electrical connection (10), in particular of a charging cable (12); the invention furthermore relates to the use of the electrical connection (10) and of the method to couple an electrical connection (10) to a user account (50) and to determine an exact geolocation of the electrical connection (10) and of a charging station (22).

Description

Description

title

Electrical connection between a vehicle and a charging station

Technical area

The invention relates to an electrical connection between a vehicle and a charging station, to a method for determining an exact geoposition of an electrical connection and to the use of the electrical connection and the method for coupling an electrical connection to a user account and for determining an exact geoposition a charging station.

State of the art

DE 10 2015 210325 Al is concerned with a method for determining a property of a charging station. The method discloses the determination of vehicle data, which is created by a charging process at the charging station, further the determination of a property of the charging station based on the vehicle data and the provision of data which indicates the determined properties of the charging station.

DE 10 2016 221 471 Al is concerned with a method for providing correction data for position determination. For this purpose, first position data is determined and/or provided for a vehicle, depending on a GNSS reception signal, the corresponding receiver being arranged in the vehicle and the first position data being determined when the vehicle is in the charging position at a charging station.

An e-mobility provider (E-Mobility Provider: EMP) usually offers its customers to recharge the batteries of electric vehicles at public charging stations. The e-mobility provider (EMP) usually has one for this App developed for mobile phones, which he makes available to customers (users). The data from charging stations that the e-mobility provider (EMP) displays in its app is usually received from aggregation platforms. The e-mobility provider (EMP) can license this data. In some cases, the e-mobility provider (EMP) receives the relevant charging station data directly from the charging station operator. The charging station data includes its geoposition, usually in the form of longitude and latitude. The charging station itself usually does not have a GPS receiver.

The geoposition data of charging stations is inaccurate because the data is usually recorded by the installer when the charging station is installed and entered into a system. However, no precise measuring instrument is used for this, but usually a cell phone, which does not always provide exact data. As a rule, several charging stations are combined into one position if, for example, they are set up next to a parking lot. It is not always clear to the user in the app which charging station is on the outer edges, so authorization is not always easy in some cases because it is unclear which charging station is currently being activated/authorized. Furthermore, it has proven to be disadvantageous that the geoposition data of charging stations includes longitude and latitude, but not the geodetic height above ground. For example, if charging stations are set up on the roof of a parking garage, this fact is not always displayed, which can make finding such charging stations very complicated compared to charging stations located at ground level.

If you use an app from an e-mobility provider (EMP), it is possible to query the corresponding geoposition of the mobile phone used every time the driver, usually the user of the app, starts a charging process in the app. From the location of the mobile phone, conclusions can be drawn about the geoposition of the charging station. This procedure can be carried out over several charging processes at a charging station and an average value can then be formed. However, the disadvantage is that the position of the mobile phone is recorded, which may not be accurate. This is the case, for example, if the driver of the vehicle has already noticeably moved away from the charging station in question after plugging in the charging cable, or in the event that the charging process is started, for example, via an app is started in another location, for example for a family member who cannot use the app at the moment. Furthermore, the position is only recorded at one time, especially not at the beginning of the measurement. Mobile phones usually require a settling time to record their geoposition, so the data provided for determining location can be inaccurate.

On the other hand, one possibility would be to use vehicle data. However, there is the problem that the e-mobility provider (EMP) usually does not have access to the vehicle data. In this regard, individual models from individual vehicle manufacturers may have an open data interface that the e-mobility provider (EMP) could use. In principle, however, the vehicle manufacturers do not disclose the data to the outside world, so that the e-mobility provider (EMP) has no access to such geoposition data provided via a vehicle.

Presentation of the invention

According to the invention, an electrical connection is proposed between a vehicle and a charging station, with a vehicle-side connection and a charging station-side connection, the electrical connection having additional functionalities integrated into the vehicle-side connection and/or into the charging station-side connection.

Advantageously, the integrated additional functionalities allow both a coupling of the electrical connection, which is preferably designed as a charging cable, with a user account of an e-mobility provider (EMP) and the determination of a more precise geoposition, compared to the prior art solutions outlined above.

Advantageously, the electrical connection proposed according to the invention is designed with regard to the additional functionalities integrated into it in such a way that they at least enable the detection of an exact geoposition of the electrical connection, which can be coupled to a user account. In an advantageous development of the electrical connection proposed according to the invention, the electrical connection is provided with visible or invisible identification markers on the vehicle-side and/or on the charging station-side connection. The identification markers, such as a serial number of the electrical connection, are used to couple the electrical connection in the form of, for example, a charging cable with the user account. After the end of a charging process, the e-mobility provider (EMP) can merge two data sets from different origins. From the electrical connection in the form of the charging cable, the e-mobility provider (EMP) receives the time and geoposition of a charging process that has been carried out, and from the charging point operator (CPO: Charge Point Operator), the e-mobility provider (EMP) receives the billing data including the charging station used. A combination of the two data sets obtained enables the e-mobility provider (EMP) to determine the geoposition of the charging station used.

Advantageously, in the electrical connection proposed according to the invention, the visible or invisible identification markers are designed, for example, as QR codes and/or as data matrix codes, which can be printed, for example, on the electrical connection in the form of a charging cable, or as serial numbers executed, which can, for example, be stamped into the electrical connection designed as a charging cable.

In the electrical connection proposed according to the invention, the integrated additional functionalities include, in addition to recording the exact geoposition of the electrical connection, recording information regarding the time or times of charging processes.

The electrical connection proposed according to the invention is designed as a charging cable, which includes the vehicle-side connection in the form of a plug and a charging station-side connection, also designed as a plug.

In an advantageous development of the electrical connection according to the invention, the integrated additional functionalities include a GNSS module, which can be integrated into the vehicle-side connection and/or into the charging station-side connection of the electrical connection in the form of a charging cable. Advantageously, the electrical connection is designed with regard to its additional functionalities such that the additional functionalities include a communication module for establishing communication between an electrical connection in the form of a charging cable in the vehicle-side and/or charging station-side connection and a network. For this purpose, according to the invention, a SIM card or an eSIM functionality is included in the connection on the vehicle side and/or in the charging station side.

In a further development of the electrical connection proposed according to the invention, the additional functionalities include an integrated Bluetooth and/or WiFi module, which is accommodated in the vehicle-side connection and/or in the charging station-side connection of the electrical connection.

The electrical connection proposed according to the invention is further characterized in that the electrical connection can be coupled to a mobile phone and/or a WiFi router.

The invention further relates to a method for determining the exact geoposition of an electrical connection and for coupling the electrical connection with a user account, the electrical connection being designed in particular as a charging cable and at least the following method steps being carried out according to the method: a) coupling a user account with the electrical connection by entering a serial number of the electrical connection into a mobile phone or by scanning a QR code or a data matrix code into a mobile phone, b) determining an exact geoposition of the electrical connection by detecting an active charging process of a vehicle at a charging station.

The method proposed according to the invention can, on the one hand, detect the exact geoposition of the electrical connection, and on the other hand, an active charging process can be indirectly assigned to a charging station via the above-mentioned data record merging at the e-mobility provider (EMP) or to a vehicle. The coupling of one A user account with the electrical connection is only required once.

The electrical connection is then registered in the user account; The connection to the user account is not required before every loading process. The vehicle assignment is possible in the event that the electrical connection in the form of the charging cable is able to identify a connected vehicle, for example using ISO15118.

In a further development of the method proposed according to the invention, the following method steps are carried out according to b):

Acquisition and storage of signals from GPS and/or GLONASS and/or Galileo and/or Beidou and/or QZSS,

Recording of longitude and latitude and geodetic height above sea level,

Carrying out geopositioning several times per loading process and recording the time of determination,

Transmission of the geopositions of the electrical connection, which are determined several times per charging process, as well as their determination time or times to the e-mobility provider (EMP).

The method proposed according to the invention can therefore advantageously be coupled to several satellite-based positioning systems, which significantly improves the reliability of use.

In an advantageous development of the method proposed according to the invention, a check of captured data is carried out within the electrical connection in such a way that captured geoposition data are compared with one another and the captured geoposition and its capture time or capture times are only transmitted when the captured geoposition data no longer change during the comparison change significantly. Such an approach greatly increases the accuracy of the geopositions passed on and increases the reliability of the data held by the e-mobility provider (EMP). In an advantageous development of the method proposed according to the invention, geoposition data of the electrical connection received by the e-mobility provider (EMP) is correlated with charging processes by users for temporal consistency and the charging station used during the charging process is determined from this.

In a further development of the method proposed according to the invention, the geoposition of the charging station is updated or corrected or confirmed in the data sets of the e-mobility provider (EMP). Such further processing of the received data takes place in the central system of the e-mobility provider (EMP), without the electrical connection in the form of a charging cable being further used here.

In a further development of the method proposed according to the invention, in order to register the electrical connection in the user account with the e-mobility provider (EMP), the electrical connection is coupled via a Bluetooth connection to a mobile phone via a Bluetooth module integrated into the electrical connection.

In the method proposed according to the invention, the exact geoposition can also be transmitted to the e-mobility provider (EMP) either via a network through communication modules SIM, eSIM integrated in the electrical connection or via a free-to-air WIFI or via a password-protected WIFI, whereby the password is the electrical connection was made known during its setup, or via a Bluetooth connection to a mobile phone from which the received data is further processed and/or forwarded.

In the method proposed according to the invention, the recorded geopositions can also be transmitted to the e-mobility provider (EMP) at regular intervals with their respective recording times, or the geopositions and associated time stamps are recorded regularly and then collectively transmitted to the e-mobility provider (EMP) at one time.

The invention further relates to the use of the electrical connection and the method for coupling the electrical connection to a user account and for determining an exact geoposition of a charging station and/or an electrical connection in the form of a charging cable.

Advantages of the invention

The solution proposed according to the invention can advantageously achieve that a stationary component used during the charging process is used, on the one hand, to couple the electrical connection to a user account of an e-mobility provider (EMP) and, on the other hand, is used by the e-mobility provider (EMP ) an update of geopositions and active charging processes that are booked via the respective authorized user account can be carried out. The solution proposed according to the invention can therefore significantly improve the data structure or the data material at the e-mobility provider (EMP) in terms of its informative value. Furthermore, active charging processes that take place are reliably recorded and unambiguously assigned to a user account maintained by the e-mobility provider (EMP). As part of the merging of data sets that the e-mobility provider (EMP) receives from the CPO, ie the charging station operator, with the data that the e-mobility provider (EMP) receives from the electrical connection in the form of the charging cable, plausibility checks can also be carried out become. The start time and end time of charging processes, which on the one hand are reported by the charging station via the CPO and to the e-mobility provider (EMP) and on the other hand are recorded by the electrical connection, should match. This agreement does not need to be exact to the second, but must also not have any major deviations. On the one hand, this makes the data status easier for the e-mobility provider (EMP) and, on the other hand, the solution proposed according to the invention significantly increases the user-friendliness in terms of finding charging stations, since their geoposition and, above all, the height above ground (such as in or on a multi-story parking garage) through application The solution proposed according to the invention can be stored much more precisely. Through the solution proposed according to the invention, geoposition data from charging stations can be improved with regard to the specification of their longitude and latitude to the extent that a geodetic height above ground is added. For example, charging stations on the roof of a parking garage can be identified just as easily as charging stations provided at ground level.

The solution proposed according to the invention allows exact geoposition data to be used regardless of vehicle models from different vehicle manufacturers. The solution proposed according to the invention allows several data sources to be brought together, namely, on the one hand, the exact geoposition, which results from the use of the electrical connection proposed according to the invention, including its additional functionalities, and also from the information about the times of active charging processes and from the use of stored geopositions of charging stations in the database of the e-mobility provider (EMP).

On the part of the e-mobility provider (EMP), received geoposition data from the electrical connection in the form of a charging cable can be checked for timing with charging processes by users and thus the charging stations used can be identified.

In the final assessment procedures used, the exact geoposition of the charging station is updated or corrected in the data sets of the e-mobility provider (EMP) or, if necessary, confirmed, so that as a result the charging station or frequented charging stations of the respective e-mobility provider (EMP) are shown on maps or in Navigation systems with improved, i.e. H. much more precise coordinates can be displayed.

Furthermore, the solution proposed according to the invention is characterized in that data is recorded and transmitted through the electrical connection in the form of the charging cable and the relatively complex further processing of the recorded data takes place at the e-mobility provider (EMP). This carries out “post-processing” (subsequent data cleansing) with the received geoposition data. This can get in the way of simple data cleansing by averaging or by discarding certain quantiles if the data points are widely spread. The filtering of inaccurate data during a transient phase is not carried out in the electrical connection in the form of a charging cable, but by the e-mobility provider (EMP).

The application of the method proposed according to the invention enables the e-mobility provider (EMP) to add new, previously unknown charging stations if corresponding geoposition data is received and there is not yet a charging station in the database for the location of this new geoposition. The e-mobility provider (EMP) can therefore display at least one charging station on the map or in the data for a navigation system, even if no details exist yet. This makes it possible for the e-mobility provider (EMP) to anticipate a time-delayed transmission by the aggregation platforms used.

In the case of longer offline times, it is possible that, by using the solution proposed according to the invention, the electrical connection saves the geopositions including acquisition times over several charging processes and only transmits them to the e-mobility provider (EMP) when an online connection is available again. This person can then carry out the necessary steps afterwards.

Furthermore, the solution proposed according to the invention can be used based on the information about the geodetic height, i.e. H. the height above ground, can be determined, for example, on a floor within a parking garage through suitable data processing, so that the charging stations can also be precisely located in a vertical respect and this information can be made available to the user.

Brief description of the drawings

The invention is described in more detail below with reference to the drawings.

Show it: 1 shows a schematic representation of an electrical connection in the simplest case, designed as a charging cable with a connection on the vehicle side and a connection on the charging station side,

2 shows the electrical connection as shown in FIG. 1, designed as a charging cable in the plugged-in state on the vehicle or at the charging station,

3 shows an embodiment variant of the electrical connection designed as a charging cable with additional functionalities integrated into the vehicle-side and charging station-side connections in the form of GNSS modules or communication modules for SIM and eSIM as well as a network to the e-mobility provider (EMP),

Figure 4 shows an alternative embodiment variant of the electrical connection proposed according to the invention with Bluetooth or WiFi modules integrated into the vehicle-side or charging station-side connection and

Figure 5 shows an embodiment variant of the electrical connection with charging station-side and vehicle-side connections as well as the representation of a WiFi router or a mobile phone for transmitting the data to the e-mobility provider (EMP).

Embodiments of the invention

In the following description of the embodiments of the invention, the same or similar elements are referred to with the same reference numerals, with a repeated description of these elements being omitted in individual cases. The figures represent the subject matter of the invention only schematically.

Figure 1 shows schematically an electrical connection 10 proposed according to the invention, which is designed as a charging cable 12. This includes a vehicle-side connection 14 and a charging station-side connection 16. The mentioned connections 14, 16 can be designed as plugs, although different types of plugs can certainly come into question, such as a type 2 plug, a CHAdeMO plug and the like.

Figure 2 shows that the electrical connection 10 proposed according to the invention, designed as a charging cable 12 with its vehicle-side connection 14 or its charging station-side connection 16, is plugged into both the vehicle 18 and the charging station 22. This results in a connected plugged-in state 20 according to FIG. 2, i.e. H. the formation of a galvanic connection between the vehicle 18 and the charging station 22 that charges its traction battery. The charging station 22 is operated, for example, via a nationwide e-mobility provider 48 (EMP), which offers its service via an app or the like. A user account 50, cf. representation according to Figures 3 and 5, for the driver of the vehicle 18 is usually maintained by the e-mobility provider 48 (EMP), so that both the user and the charging process can be identified and assigned to a user account 50 of the e-mobility provider 48 (EMP). Mobility provider 48 (EMP) can be assigned.

Figure 3 shows that the electrical connection 10 is designed as a charging cable 12 and integrated additional functionalities 24 are accommodated in the vehicle-side connection 14 and in the charging station-side connection 16. According to the illustration in Figure 3, the integrated additional functionalities 24 are in both elements, i.e. H. both in the vehicle-side connection 14 and in the charging station-side connection 16. Alternatively, it is possible to integrate the additional functionalities 24 only in the vehicle-side connection 14 or only in the charging station-side connection 16.

The integrated additional functionalities 24 include, for example, a GNSS module 26, which is housed in the vehicle-side connection 14, and a GNSS module 28, which is located in the charging station-side connection 16. Additionally or alternatively, communication modules 30, 32 for SIM/eSIM communication can be accommodated in the two connections, ie the vehicle-side connection 14 and/or the charging station-side connection 16. The communication modules 30, 32 for SIM or eSIM communication can also only be accommodated in the vehicle-side connection 14 or only in the charging station-side connection 16. About the ones in that GNSS modules 26, 28 and/or communication modules SIM, eSIM 30, 32 housed on the vehicle-side connection 14 and/or charging station-side connection 16 can be used to transmit captured geoposition data during active charging processes, which can be transmitted wirelessly to an e-mobility provider 48 (EMP ) can be transferred. The e-mobility provider 48 (EMP) maintains a user account 50 through which the user who wants to authorize a charging process can be identified.

Figure 4 shows that the electrical connection 10 in the form of the charging cable 12 in the vehicle-side connection 14 and/or in the charging station-side connection 16 can also have visible or invisible identification markers 36, 38. The visible or invisible identification markers 36, 38 can be, for example, QR codes or data matrix codes or serial numbers or the like stamped into the electrical connection 10 in the form of the charging cable 12. These enable identification of the electrical connection 10 when the recorded geoposition data is transmitted to the e-mobility provider 48 (EMP), where the corresponding user accounts 50 are maintained.

5 finally shows a possible embodiment of the electrical connection 10 in the form of the charging cable 12 with a vehicle-side connection 14 and a charging station-side connection 16, in which the integrated additional functionalities 24 are designed in the form of integrated Bluetooth/WIFI modules 40, 42. Via the Bluetooth/WIFI modules 40, 42 integrated in the vehicle-side connection 14 or charging station-side connection 16, the electrical connection 10 can communicate either with a mobile phone 44 or with a WiFi router 46, so that recorded geoposition data can be transmitted to the E-mobility provider 48 (EMP) and a coupling of the electrical connection 10 to the user account 50 maintained there can be carried out.

The user, who is usually the driver of the vehicle 18, can display the serial number stamped or printed in the electrical connection 10 in the form of the charging cable 12 in his user account 50, for example in an app of the e-mobility provider 48 (EMP ) on his mobile phone 44 or scan a QR code or a data matrix code via the mobile phone 44 and thus assign the electrical connection 10 in the form of the charging cable 12 to his user account 50. When e- Mobility providers 48 (EMP), following the solution proposed according to the invention, bring together several data sources, namely the geoposition, which is recorded by the electrical connection 10 in the form of the charging cable 12, as well as information about the time of the active charging processes and the geopositions of the charging stations 22 in the database of the E-mobility provider 48 (EMP) as well as the data about charging processes that the e-mobility provider 48 (EMP) receives from charging point operators (CPO). As soon as the electrical connection 10 in the form of the charging cable 12 detects an active charging process, see illustration according to Figure 2, namely that the vehicle 18 and the charging station 22 are galvanically connected via the electrical connection 10 in the form of the charging cable 12, the geopositioning is activated through the electrical connection 10 with the additional functionality 24 integrated therein as described above with reference to Figures 1 to 5. Signals from Global Position System (GPS) and/or GLONASS and/or Galileo and/or Beidou and/or QZSS are recorded and stored. Not only longitude and latitude are recorded, but also the geodetic height above sea level (which corresponds to a basic functionality of the satellite-based navigation systems mentioned above). The geoposition can be determined several times during an active loading process, just as measurement times can be recorded several times in terms of date and time. After a sufficiently precise geoposition and the measurement times have been determined, these recorded data can be transmitted to the e-mobility provider 48 (EMP) via the additional functionalities 24 of the electrical connection 10 integrated into the vehicle-side connection 14 or the charging station-side connection 16.

In the present context, “sufficiently precise” means that a data check is carried out in the electrical connection 10 in such a way that recorded geoposition data is compared with one another. As soon as the captured geoposition data no longer changes significantly, that is, after a settling time has elapsed, an exact geoposition is transmitted along with the capture times or the capture time, that is, via the network 34, for example by means of the mobile phone 44 or via a WiFi router 46 to the E -Mobility provider 48 (EMP) transferred. On the part of the e-mobility provider 48 (EMP), received geoposition data from the electrical connection 10 is combined with charging processes from Users are checked for temporal coincidence, so that the charging stations 22 used can be unambiguously identified. Subsequently, in the central system, ie at the e-mobility provider 48 (EMP), an update, correction or confirmation of geopositions of the charging station 22 used in the data base of the e-mobility provider 48 (EMP) takes place by using suitable evaluation methods. This means that the respective geopositions of the charging stations 22 of the e-mobility provider 48 (EMP) can be displayed on an app, a map or as data on a navigation system with improved geoposition coordinates.

The solution proposed according to the invention, ie in the form of the electrical connection 10 proposed according to the invention, preferably designed as a charging cable 12, allows its coupling to a user account 50 of an e-mobility provider 48 (EMP) on the one hand and, on the other hand, that electrical connection 10 for determining the geoposition of the Insert the electrical connection 10 or the charging station 22. To register the electrical connection 10 in the form of the charging cable 12 in the user account 50, the charging cable 12 is coupled via Bluetooth to the mobile phone 44 via the integrated additional functionality 24, here an integrated Bluetooth/WIFI module 40, 42, be it on the vehicle Connection 14, be it housed in the charging station-side connection 16 of the electrical connection 10. In this way, for example, the serial number can be transmitted via the mobile phone 44 for storage in the user account 50. The transmission of the exact geoposition to the e-mobility provider 48 (EMP) of both the electrical connection 10 in the form of the charging cable 12 and the charging station 22 takes place either via the network 34 through the communication modules SIM, eSIM 30, 32 installed in the electrical connection 10 Furthermore, the geoposition can be transmitted via free-to-air WIFI without password access or alternatively via a protected WIFI, whereby the password was made known to the electrical connection 10 during setup. The data can also be transmitted via the already mentioned Bluetooth connection in the form of integrated Bluetooth/WIFI modules 40, 42 to the mobile phone 44 or the existing app of the e-mobility provider 48 (EMP), with the data being sent to the e-mobility provider 48 (EMP) transmitted data can be further processed or forwarded there in the central system. As an alternative to only transmitting the geoposition and the corresponding detection time from the electrical connection 10 to the e-mobility provider 48 (EMP) when the position is considered “sufficiently precise”, the geoposition can be transmitted at regular intervals together with the respective Recording times are sent to the e-mobility provider 48 (EMP). This is also done via the network 34. There is also the possibility of regularly recording the geoposition with the associated time stamp or timestamps and then transmitting it to the e-mobility provider 48 (EMP) as a collective transmission at a later point in time. This carries out post-processing, usually downstream data cleaning, with the geoposition data received. Simple data cleaning is possible, for example, by averaging or discarding certain quantiles if the data turns out to be broadly scattered. Filtering of received inaccurate data, for example during the settling time, is not carried out in the electrical connection 10 in the form of the charging cable 12 itself, but in the central system at the e-mobility provider 48 (EMP). The filtering and further processing (“post-processing”) of data can be fed to the app on the mobile phone 44 if the data connection runs via the app, such as in the case of a Bluetooth connection. The electrical connection 10 cannot be connected to a user account 50 at the e-mobility provider 48 (EMP); However, the transmitted geoposition can be transmitted to the e-mobility provider 48 (EMP) with every detected charging process. This means that no assignment to a specific user can be made on this site. In this case, however, it is known that there must be a charging station 22 at the transmitted geoposition, otherwise the electrical connection 10 would not have recognized an active charging process and would not have carried out a geoposition determination. With the data in its database about the charging stations 22, the e-mobility provider 48 (EMP) can still check which charging station 22 has presumably been used and thus either compare or update and thus improve its position data.

Another possible embodiment of the solution proposed according to the invention is that the e-mobility provider 48 (EMP) includes a new charging station 22, previously unknown to it, in its database when geoposition data is received and in the current database of the e-mobility provider 48 (EMP) at this location no charging station yet 22 is registered. The e-mobility provider 48 (EMP) can then display at least one charging station 22 on the map or its data material, even if no more detailed information is available, which puts the e-mobility provider 48 (EMP) in the position of a time-delayed transmission Preempt aggregation platforms.

If longer offline times occur when transmitting geoposition data, there is the possibility of storing the corresponding geopositions including their acquisition times over several charging processes in the electrical connection 10, designed as a charging cable 12, and when an online connection to the network is available again 34 to be transferred to the e-mobility provider 48 (EMP). This then carries out the further data processing steps in the central system afterwards.

In a further development of the method proposed according to the invention, a three-dimensional position of a charging station 22 can be recorded from the geoposition data transmitted through the electrical connection 10 in the form of the charging cable 12 - more precisely from the height above ground - so that conclusions can be drawn about the floor, for example in a multi-story parking garage , in which the charging station 22 is located, can be closed. The floor, whether above ground or below ground, can then be displayed in the app of the e-mobility provider 48 (EMP) as additional information to make it easier for the user to navigate there and find it.

The invention is not limited to the exemplary embodiments described here and the aspects highlighted therein. Rather, within the range specified by the claims, a large number of modifications are possible, which are within the scope of professional action.

Claims

Expectations

1. Electrical connection (10) between a vehicle (18) and a charging station (22) with a vehicle-side connection (14) and a charging station-side connection (16), characterized in that the electrical connection (10) is inserted into the vehicle-side connection (14 ) and/or additional functionalities (24) integrated into the connection (16) on the charging station side.

2. Electrical connection (10) according to claim 1, characterized in that the additional functionalities (24) integrated into this include at least the detection of an exact geoposition of the electrical connection (10), which is coupled to a user account (50).

3. Electrical connection (10) according to claims 1 to 2, characterized in that the electrical connection (10) is provided with visible or invisible identification markers (36, 38) on the vehicle-side and / or charging station-side connection (14, 16). .

4. Electrical connection (10) according to claim 3, characterized in that the visible or invisible identification markers (36, 38) are QR codes and/or data matrix codes and/or serial numbers and/or RFID chips/- Have markers that can be read using a mobile phone (44).

5. Electrical connection (10) according to claims 1 to 4, characterized in that the integrated additional functionalities (24) include, in addition to recording the exact geoposition of the electrical connection (10), recording information regarding the time(s) of charging processes, further include at least one recording of geopositions of charging stations (22) of an e-mobility provider (48) (EMP). Electrical connection (10) according to claims 1 to 5, characterized in that the electrical connection (10) is a charging cable (12) which comprises a vehicle-side connection (14) and a charging station-side connection (16). Electrical connection (10) according to claims 1 to 6, characterized in that the integrated additional functionalities (24) include a GNSS module (26, 28) in the vehicle-side connection (14) and/or in the charging station-side connection (16). Electrical connection (10) according to claims 1 to 7, characterized in that the integrated additional functionalities (24) include a communication module (30, 32) for establishing communication between a SIM card or an eSIM functionality in the vehicle-side and/or charging station-side connection (14, 16) and a network (34). Electrical connection (10) according to claims 1 to 8, characterized in that the integrated additional functionalities (24) include an integrated Bluetooth or WiFi module (40, 42) in the vehicle-side and/or charging station-side connection (14, 16). Electrical connection (10) according to claim 9, characterized in that the electrical connection (10) is coupled to a mobile phone (44) and/or a WIFI router (46). Method for determining an exact geoposition of an electrical connection (10), in particular a charging cable (12), according to one of claims 1 to 10, with at least the following method steps: a) coupling a user account (50) to the electrical connection (10) by input a serial number of the electrical connection (10) into a mobile phone (44) or by scanning a QR code or a data matrix code into a mobile phone (44) or in a web browser, b) Determination of a geoposition of the electrical connection (10) during detection of an active charging process of a vehicle (18) at a charging station (22). Method according to claim 11, characterized in that the following steps are carried out according to b):

Acquisition and storage of signals from GPS and/or GLONASS and/or Galileo and/or Beidou and/or QZSS, acquisition of longitude and latitude and geodetic altitude above sea level,

Carrying out the geoposition determination several times per charging process and recording the time of determination, transmitting geopositions of the electrical connection (10) determined several times per charging process as well as their determination time or times to the e-mobility provider (48) (EMP). Method according to claims 11 to 12, characterized in that a check of captured data is carried out within the electrical connection (10) in such a way that captured geopositional data are compared with one another and a transmission of the captured geopositional data and its capture time only takes place when the captured geopositional data no longer change significantly during the comparison. Method according to claims 11 to 13, characterized in that geoposition data received by the e-mobility provider (48) (EMP) of the electrical connection (10) with charging processes from users are checked for timing and the charging station (22) used is determined therefrom becomes. Method according to claims 11 to 14, characterized in that the geoposition of the charging station (22) is updated or corrected or confirmed in the data sets of the e-mobility provider (48) (EMP). Method according to claims 11 to 15, characterized in that in order to register the electrical connection (10) in the user account (50), the electrical connection (10) is coupled via Bluetooth connection to a mobile phone (44) via the electrical connection (10 ) integrated Bluetooth/Wl FL modules (40, 42). Method according to claims 11 to 16, characterized in that the geoposition is transmitted to the e-mobility provider (48) (EMP) optionally via a network (34) by communication modules SIM, eSIM (30, 32) or via a free-to-air WIFI or via a password-protected WIFI, whereby the password of the electrical connection (10) was made known when it was set up, or via a Bluetooth connection to a mobile phone (44), from which the received data is further processed and/or or be forwarded. Method according to claims 11 to 17, characterized in that recorded geopositions are transmitted to the e-mobility provider (48) (EMP) at regular intervals with their respective recording times or the geopositions and associated time stamps are recorded regularly and then collected at a later point in time be transferred to the e-mobility provider (48) (EMP). Use of the electrical connection (10) according to one of claims 1 to 10 and the method according to one of claims 11 to 18 for coupling the electrical connection (10) with a user account (50) and for determining an exact geoposition of a charging station (22).