WO2022263177A1 - Method for locating a reserved charging post, and at least partly electrically driven vehicle - Google Patents

Abstract

The invention relates to a method for locating a reserved charging post (3') within a charging station (2) for charging a traction battery of an at least partly electrically driven vehicle (1), wherein a controller (4) of the vehicle (1) is given access to geocoordinates of the reserved charging post (3'). The invention is characterized in that upon reaching the charging station (2), which comprises a plurality of charging posts (3), the reserved charging post (3') is optically marked for a person using the vehicle (1). The invention additionally relates to an at least partly electrically driven vehicle which has a controller (4) that is designed to carry out the method together with at least one display device.

Description

Mercedes-Benz Group AG

Method for finding a reserved charging station and at least partially electrically powered vehicle

The invention relates to a method for finding a reserved charging station within a charging station for charging a traction battery of an at least partially electrically powered vehicle according to the type defined in more detail in the preamble of claim 1. The invention also relates to an at least partially electrically powered vehicle with a traction battery according to Art defined in more detail in the preamble of claim 13.

WO 2013/034406 A1 describes a system for reserving a charging station for an electric vehicle. On the one hand, occupancy data from this charging station and, on the other hand, a travel destination entered by a vehicle user in the vehicle are taken into account. A selection of available charging stations corresponding to the planned trip is then determined from the travel data and the occupancy data. An available charging station is then selected and reserved according to the availability data that is transmitted to the vehicle control unit. This ensures a good planning option for both the utilization of the charging stations and their availability. Reliable planning for charging the traction battery is thus possible, so that a journey planning adapted thereto and/or use of the energy reserves in the vehicle can take place.

A person using a vehicle who wants to recharge their vehicle, which is fully or at least partially electrically powered from the traction battery, can be guided by their navigation system to a charging station at which there is a reservation for a corresponding period of time for charging the traction battery. In practice, however, it is now the case that such charging stations have several charging stations, some of which are of different types. For example, there are charging stations with different charging capacities, charging stations for charging with direct current (DC) or alternating current (AC) or possibly also charging stations that can handle both types of charging. It is now in the interest of the operator of the charging station as well as in the interest of the user who wants to recharge the traction battery of his vehicle, after arriving at the charging station, to land at the charging station that is ideal for his vehicle, for example in terms of charging power or charging parameters . In practice, however, this is typically associated with the user having to look for the right charging station himself, for example using a number, a label or the type of plug used within the charging station. This is complex and not very convenient and, in case of doubt, can lead to a charging station being selected due to a number of matching options and features which, although it works for the vehicle in question, is not optimal. This can sometimes increase the loading time considerably.

It is now the object of the present invention to create a method which minimizes this disadvantage for a user of an electric vehicle that is to be recharged.

According to the invention, this object is achieved by a method having the features in claim 1, and here in particular in the characterizing part of claim 1. Advantageous refinements and developments of the method according to the invention result from the dependent subclaims. In addition, a vehicle with the features in claim 10 solves the problem.

The method according to the invention serves to find and to transmit information in connection with a reserved charging station within a charging station. A control unit of the vehicle can, for example, in accordance with the method mentioned at the outset, reserve a charging station on the route that has a free charging station available at a suitable point in time for recharging its traction battery. Corresponding parameters can already be exchanged between the vehicle or its control device and the operator of the charging station when making the reservation in order to Reservation to immediately reserve a charging station within the charging station that matches the parameters. The vehicle can then be driven to the charging station using a navigation device, for example. This can be done manually by a person using and driving the vehicle, or entirely or partially by means of an autonomous driving system.

According to the invention, when the charging station comprising a large number of charging stations is reached, the charging station reserved for the vehicle is marked optically for a person using the vehicle. Such an optical marking, which can take place in various ways that will be explained later, makes it easier for the person using the vehicle to find their way around within the charging station and makes it possible to find the charging station reserved for them or their vehicle easily and efficiently. The optical marking allows the charging station to be controlled quickly and efficiently without having to pay attention to the corresponding features of the individual charging stations, such as symbols relating to the type of charging, the charging capacity, the plugs that can be used and the like. On the one hand, this is for the comfort of the person using the vehicle and, on the other hand, it also serves the operator of the charging station, since the vehicles move quickly within the charging station to the reserved charging stations, thereby facilitating the logistical processes within the charging station, since there is no one looking for a suitable charging station Vehicles are moving slowly within the station and accordingly block the flow of traffic within the charging station or, when searching for a charging station, block charging stations that have already been reserved for the authorized user or at least temporarily impede their access. The optical marking can include any type of information, for example optical highlighting, an arrow, but also information on costs, charging capacity, charging time, etc.

According to a very simple embodiment of the method according to the invention, the optical marking can be done very easily on a display inside the vehicle by showing an overview map of the charging station and marking the reserved charging station therein. Such a display can be created, for example, based on existing map data of a navigation system or can also be transmitted to the vehicle, for example, when the reservation is confirmed and/or the vehicle arrives at the charging station. Such an overview map, which typically shows a bird's-eye view, or Similar to navigation systems, it can also contain a 3D view, serves to facilitate orientation within the charging station, so that the reserved charging station can be easily found by optically marking it on the overview map.

A possibility that can be used in addition or as an alternative to this is to superimpose the optical marking of the reserved charging station on a real view and/or a view captured by a camera. In contrast to the pure representation of an overview map, this enables a more efficient grasp of the situation for many people, since the real image visible to the person does not have to be abstracted in order to compare it with the map, but since the optical marking is directly in the real image is displayed. According to a very advantageous development of this idea, this can be done, for example, by superimposing the optical marking using a head-up display. Such a head-up display can display an optical marking on the windscreen in particular, but also on the side windows, exactly where the person using or driving the vehicle can see the reserved charging station. If this is not immediately visible to the person, such a head-up display can also be used to provide navigation information such as the display of directional arrows, which then appear to be virtually on the road surface.

An alternative to such a head-up display is superimposition in a display of the vehicle, which reproduces a camera image of the surroundings. Instead of a head-up display, a conventional display can also be used in the vehicle. As an alternative or in particular also in addition to the overview map, the image from a camera of the vehicle can then be shown on the display. The reserved charging station can then be marked in this image so that it can also be found easily and efficiently. This can also be supplemented, for example, with the overview map already mentioned. On the one hand, the real image recorded by the vehicle's camera with the charging station marked and next to it the map overview in a bird's eye view can be shown on the display. This makes orientation even easier, especially when the charging station is still relatively far away from the vehicle, for example at the other end of the charging station. Another very efficient alternative or additional option for optically marking the charging station or for displaying possible navigation instructions for reaching the reserved charging station, as already mentioned, is possible if the vehicle has so-called pixel headlights. Headlights of this type, which enable targeted emission of light and which are often used to implement what is known as an adaptive high beam, which is able to remove oil from oncoming vehicles, is often also able to illuminate individual points in a targeted manner and/or Project symbols around the vehicle. Such pixel headlights can now be used to specifically illuminate the reserved charging station and/or a section of the floor in the area of this charging station. For example, the parking space belonging to the respective charging station can be marked. This technology can also be used to display navigation instructions on the road, for example directional arrows or the like. The technique works particularly well when the brightness is reduced, so it may be more difficult to use in strong sunshine, which is why it can preferably be combined with one or the other of the techniques already described and can be used depending on the ambient brightness.

According to an extremely favorable development of the method according to the invention, it can also be provided that the exact geo-coordinates of the reserved charging station of the charging station are only transmitted to its control unit when the vehicle arrives at the charging station or are retrieved by the latter when the charging station is controlled. Above all, this enables the operator of the charging station to assign his charging stations flexibly. At the time of reservation, he only has to specify that he has a charging station available that provides the corresponding parameters in the requested period. He does not have to decide at this point which of the charging stations this must be if he has several charging stations in his charging station that meet the requirements of the vehicle. In particular, he can only specify this immediately before the vehicle arrives in the area of the charging station and communicate this to the charging station upon arrival. Only then does the vehicle know which charging station is intended for it. This charging station can then be found very easily and efficiently using the method according to the invention. Another extraordinarily favorable embodiment of the method according to the invention can now also provide for vehicle identification data and/or data serving for cashless payment to be transmitted to the reserved charging station before the start of charging the traction battery. This makes it easy and efficient to start and complete the charging process. In the embodiment just described, this can be done in particular after the exact geo-coordinates of the charging station have been received within the charging station. A charging station identification is then received by the vehicle or its control unit together with the geo-coordinates and a separate identification is transmitted to the charging station. This can be used to check the reservation made and at the same time data for cashless payment can be implemented. A person using and charging the vehicle then only has to identify themselves and can then, for example, start charging via an NFC connection and also pay for it immediately. The fact that the vehicle identification data can also contain parameters relating to the charge, for example the maximum possible charging power, whether charging takes place via direct current or alternating current and, if necessary, the charge status of the traction battery when it arrives at the charging station, all parameters for the vehicle, which has just reserved this column, can be preset. By identifying the relevant person or vehicle at the reserved charging station and plugging in the charging cable, if one is used, charging can start immediately. When charging without a charging cable, for example with inductive power transmission, this step can also be omitted, so that charging of the traction battery can be started extremely quickly and conveniently after the vehicle arrives at the charging station.

In a further or additional embodiment, a charging power of the charging station is received, a charging time is determined from the charging power that can be drawn from the vehicle and a capacity to be charged. The charging time is displayed superimposed on the charging station. The user can specify the extent to which the battery should be charged, ie the battery should be half or fully charged, for example. Based on the current state of charge, the capacity to be charged is determined in kilowatt hours (kWh). The duration for charging the capacity depending on the charging power of the charging station and the vehicle is determined and superimposed on the charging station displayed so that the user can plan the idle time associated with charging for other activities.

In one embodiment, if another vehicle is occupied, the probable occupancy time for the charging process of the charging station is displayed superimposed. Without leaving the vehicle, the user can plan further steps, for example go to another charging station or take up activities that can be carried out according to the occupancy time.

An at least partially electrically powered vehicle with a traction battery, a control unit and at least one display device is set up according to the invention such that the control unit is designed together with the at least one display device for carrying out the method in one of the variants mentioned.

In a further refinement, POIs determined from a database are displayed superimposed with associated directions and/or distances from the charging station. The coordinates of the POI'S are determined from a database on a backend server and/or from map material. The display enables the vehicle user to easily visit relevant locations during the charging process. The data in the database is preferably stored in a personalized way, so that every user is shown POIs that correspond to their taste and preferences.

In an additional development, based on the current state of charge and a charging process with a predetermined charging time/charging capacity, a current and available range after the charging time is determined and displayed superimposed on the charging station. The user is immediately informed about the success of the charging process and can plan his further journey more precisely.

The display device can in particular include a display, i.e. a screen inside the vehicle, or also several screens of the vehicle, a head-up display and/or pixel headlights, which are able to project specific symbols, points of light or the like into the environment. By means of such The vehicle can then be recharged very easily, efficiently and comfortably for the person using the vehicle.

Further advantageous refinements of the method according to the invention and of the vehicle according to the invention also result from the exemplary embodiment, which is illustrated in more detail below with reference to the figures.

show:

1 shows a scenario for explaining the method according to the invention in a possible embodiment in a plan view; and FIG. 2 shows an alternative scenario analogous to the representation in FIG. 1 from the perspective of a person driving a vehicle.

A scenario for explaining the method according to the invention is shown in FIG. A vehicle 1 according to the invention approaches a charging station, designated in its entirety by 2, in order to charge or recharge its traction battery. The charging station 2 was selected, for example, using a system known from the prior art mentioned at the outset, and one of the charging stations 3 located there was reserved in the charging station 2 for recharging the traction battery of the vehicle 1 . Only some of these charging stations 3 are provided with a reference number. Next to them is a parking space for one vehicle during charging. When reserving one of the charging stations 3 for the vehicle 1, it can already be negotiated which requirements the charging station 3 must meet. For example, the desired charging parameters can be taken into account when making a reservation. This can be, for example, the charging power, the charging voltage, the available charging connection and/or whether DC voltage or AC voltage is required to charge the traction battery.

An operator or the controller of the charging station 2 now selects one of the charging stations 3 that is available in the corresponding period of time and is suitable with regard to the desired parameters. This is marked 3' in the illustration and is referred to below as the reserved charging station 3'. Typically, the operator of the charging station 2 will only determine when the vehicle 1 arrives at the charging station 2 which of the charging stations 3 is the charging station 3' reserved for the respective vehicle 1.

When the vehicle 1 arrives at the charging station 2, as shown in FIG. 1, the vehicle 1 or a control unit 4 of the vehicle 1 indicated in FIG Time the exact geo-coordinates of the vehicle 1 reserved charging station 3 '.

The vehicle 1 or a person using the vehicle 1 must now find this reserved charging station 3 ′ within the charging station with its large number of charging stations 3 . An optical marking 6 is now used for this purpose, which is created starting from the vehicle 1 in order to indicate the reserved charging station 3 to a person located in the vehicle 1 . The optical marking 6 is indicated by an oval in the representation of FIG. This optical marking 6 can now be generated via pixel headlights 7 of the vehicle 1, for example. This scenario is indicated in the depiction in FIG. 1, in which the left-hand pixel headlight of the vehicle 1 in the direction of travel illuminates the reserved charging station 3′ and thus generates the optical marking 6 of the reserved charging station 3′. In addition to this, it is possible in principle to use the control unit 4 of the vehicle 1 and a locating module installed in the vehicle 1, for example the locating module of a navigation device, to also display a potential route to the reserved charging station 3'. In the illustration in FIG. 1, this is done by the right-hand pixel headlight 7, which projects a bending arrow at the entrance to the row with charging stations 3, which contains the charging station 3'. During the entire journey within the charging station 2, the optical marking 6 remains and is tracked, so that a person using the vehicle 1 can find the charging station 3 reserved for them extremely simply and easily.

When the vehicle 1 enters the charging station 2, the parameters that have already been defined in principle can be compared again between the control unit 4 of the vehicle 1 and the controller 5 of the charging station 2, so that the reserved charging station 3' is already set in such a way that all desired charging parameters are present accordingly and a person charging the vehicle 1 only has to identify himself and/or the vehicle 1 at the reserved charging station 3' and start charging. When exchanging information between the control unit 4 of the vehicle 1 and the controller 5 of the charging station 2, the data required for cashless payment can also be exchanged and stored for the reserved charging station 3', so that payment can also be made easily and efficiently, in particular by the Identification of the person or vehicle 1 at the reserved charging station 3' carried out before the start of charging. This can be done, for example, via near-field communication (NFC) between a token of the person and a reader of the respective charging station 3, in this case the reserved charging station 3'.

In addition to these possibilities of optical marking 6 and a directional indication 8 by the pixel headlights 7 of the vehicle 1, ie marking outside the vehicle 1, other methods for marking the reserved charging station 3' are of course also conceivable. Two such alternatives are indicated schematically in the illustration in FIG. In the illustration in FIG. 2, the vehicle 1 is shown from the inside, essentially from the viewing direction of a person driving the vehicle 1 . Through a windshield 9, the person sees the charging columns 3 of the charging station 2, including the charging column 3' reserved for them. The marking 6 for visual identification of the reserved charging station 3' can also be seen here. It is now not or not exclusively generated via one of the pixel headlights 7, but is generated inside the vehicle 1 via a schematically indicated head-up display 10 and played into the windshield 9 or, if necessary, into a side window labeled 11. The person driving the vehicle 1 thus recognizes by looking at the individual charging columns 3 of the charging station 2 which of the charging columns 3 is the charging column 3' reserved for them. Alternatively or in addition to this, and this is also shown in FIG. 2, a display 12 or a screen can also be used inside the vehicle. On this, for example, upon arrival at the charging station 2, after transmission of the corresponding data by the controller 5 to the vehicle 1, an overview map can be displayed, as indicated schematically in the illustration in FIG. Within this overview map, the individual charging stations 3 can be seen in a manner similar to the bird's-eye view of FIG. 1, together with the visual marking 6 of the reserved charging station 3'. In addition, the position of vehicle 1 is shown via arrow symbol 13, similar to a conventional navigation system. She can do that too Vehicle using person easily and efficiently get to the reserved charging station 3.

As a further alternative, it would also be conceivable, for example, to display an image captured by a camera of the vehicle 1 (not shown here) on the screen 12 and to fade in the optical marking 6 accordingly within this live image.

All variants can be used as an alternative or in addition to one another, which may require a split view of screen 12 or another screen inside vehicle 1 (not shown here).

Of course, it would also be conceivable here with the options for displaying the optical marking 6 explained with reference to FIG , Display navigation instructions 8 in order to facilitate orientation for the person driving the vehicle 1, which can be particularly advantageous in the case of very large charging stations 2 with a large number of individual charging stations 3.

Claims

patent claims

1. A method for locating a reserved charging station (3') within a charging station (2) for charging a traction battery of an at least partially electrically powered vehicle (1), a control unit (4) of the vehicle (1) receiving geo-coordinates of the reserved charging station (3 ') are made accessible, characterized in that when the charging station (2) comprising a large number of charging stations (3) is reached, the reserved charging station (3') is optically marked for a person using the vehicle (1).

2. The method as claimed in claim 1, characterized in that the optical marking (6) takes place on a screen (12) by displaying an overview map of the charging station (2) and marking the reserved charging station (3') therein.

3. The method according to claim 1 or 2, characterized in that the optical marking (6) of the reserved charging station (3') is superimposed on a real view and/or a view captured by a camera.

4. The method according to claim 3, characterized in that the superimposition takes place by means of a head-up display (10).

5. The method according to claim 3, characterized in that the superimposition takes place on a screen (12) on which a camera image of the surroundings is reproduced.

6. The method as claimed in claim 3, characterized in that the optical marking (6) is projected into the vehicle environment by means of at least one controllable pixel headlight (7) of the vehicle.

7. The method according to any one of claims 1 to 6, characterized in that the optical marking (6) further includes navigation instructions (8) for reaching the reserved charging station (3 ').

8. The method according to any one of claims 1 to 7, characterized in that the exact geo-coordinates of the reserved charging station (3 ') in the charging station (2) when the vehicle (1) arrives at the charging station (2) its control unit (4) transmitted or retrieved from this at a controller (5) of the charging station (2).

9. The method according to any one of claims 1 to 8, characterized in that in the period before charging the traction battery, in particular after the arrival of the vehicle (1) at the charging station (2), identification data and/or data serving for cashless payment are sent to the reserved charging station (3') are transmitted.

10. The method according to any one of claims 3 to 9, characterized in that a charging power of the charging station is received, from the charging power that can be taken from the vehicle and a capacity to be charged, a charging time is determined, the charging time of the charging station being displayed superimposed.

11. The method according to any one of claims 3 to 10, characterized in that if another vehicle is occupied, the expected occupancy time for the charging process of the charging station is displayed superimposed.

12. The method according to any one of claims 3 to 11, characterized in that POIs determined from a database are displayed superimposed on the charging station with directions and/or distances.

13. The method according to any one of claims 3 to 12, characterized in that a current and after the charging time available range is determined based on the current state of charge and a charging process with a predetermined charging time/charging capacity and is displayed superimposed on the charging station.

14. At least partially electrically powered vehicle (1) with a traction battery, with a control unit (4) and with at least one display device, characterized in that the control unit (4) together with the at least one display device (7, 10, 12) is set up for this purpose is to carry out a method according to any one of claims 1 to 13.