EP3999808A1

EP3999808A1 - Method for guiding a motor vehicle

Info

Publication number: EP3999808A1
Application number: EP20740309.8A
Authority: EP
Inventors: Philipp Wagner; Jan Fleischhacker; Christian Haupt; Julius Engasser; Dieter Lutz; Susann Hofmann
Original assignee: MAN Truck and Bus SE
Current assignee: MAN Truck and Bus SE
Priority date: 2019-07-19
Filing date: 2020-07-14
Publication date: 2022-05-25
Also published as: DE102019005062A1; WO2021013626A1

Abstract

The invention relates to a method for guiding a motor vehicle (10), which preferably is driven electrically or by means of hydrogen, particularly preferably a utility vehicle. The method comprises the determining of at least one route guidance suggestion from a starting point to a destination on the basis of a break time rule, the current range and energy supply devices between the starting point and the destination. The method comprises the outputting of at least one route guidance suggestion. The method can be advantageous with regard to needs specific to utility vehicles.

Description

Method for driving a motor vehicle Description

The invention relates to a method for driving a, preferably electric or what hydrogen-powered motor vehicle, particularly preferably a commercial vehicle. The invention also relates to a motor vehicle designed to carry out the method, preferably a utility vehicle.

Vehicles, such as passenger cars and commercial vehicles, with internal combustion engines can be refueled in a simple manner due to the good availability of filling stations on long journeys, without relevant waiting times and without prior planning. In comparison, alternatively powered vehicles, in particular battery-powered vehicles or hydrogen vehicles, have a considerable disadvantage. The availability of charging points is lower, especially on motorways. In the case of battery electric vehicles, the charging process also takes significantly longer.

DE 10 2010 039 075 A1 discloses an output system for information about an electrical cal amount of energy in a motor vehicle. According to the system, charging stations can be reserved temporarily or formally.

The previously known solutions for route planning are mainly based on the needs of the car driver, who generally does not have to take into account anything other than planning routes and possibly charging stops.

The invention is based on the object of creating an alternative and / or improved technology for driving a motor vehicle, which preferably integrates requirements specific to commercial vehicles.

The object is achieved by the features of independent claim 1. Advantageous further developments are given in the dependent claims and the description.

The invention provides a method (e.g. data processing method) for driving a motor vehicle, preferably (e.g. partially or fully) electrically or (e.g. partially or fully) powered by hydrogen, particularly preferably a commercial vehicle (e.g. Trucks or buses), in particular for route planning and / or for operating the motor vehicle. The method includes specifying a starting point and a destination point of a route. The method includes specifying a time interval regulation for a driver break of a driver of the motor vehicle. The method includes determining a current range of the motor vehicle. The method includes determining (e.g. stationary) energy supply devices, preferably electrical charging locations for charging the motor vehicle or (e.g. hydrogen) filling stations for refueling the motor vehicle, between the starting point and the destination point. The method includes determining at least one route guidance suggestion from the starting point to the destination point based on the time interval regulation, the current range and the energy supply devices. The method includes outputting the at least one route guidance suggestion (for example by means of a user interface of the motor vehicle).

The method can help to lower the total costs or the total effort of the trip, and at the same time relieve the driver of stress. The method can expediently bring together commercial vehicle and driver-specific issues and thus plan a route proposal with regard to tour, route and break planning (driving and rest times, working hours, parking space availability, charging options) with the aim of minimizing overall costs. For commercial vehicles, the individual driving and rest times of the driver can be important boundary conditions, since the breaks can be used in a time-efficient manner, preferably when the vehicle is time-consuming to recharge or refuel. The technology can be used particularly advantageously in a motor vehicle that is driven electrically or by means of hydrogen. It is also possible to use the technology in a motor vehicle with diesel, gasoline, natural gas or another internal combustion engine.

In one embodiment, the at least one suggested route is determined in such a way that the driver's break and charging or refueling of the motor vehicle at an energy supply device are coordinated with one another. The driver's break can preferably fall during a period in which charging or refueling of the motor vehicle is planned at an energy supply device, and / or charging or refueling of the motor vehicle at an energy supply device can occur in a period in which the driver's break is planned. At least part of the driver's break can thus be spent in a particularly time-efficient manner when charging or refueling the motor vehicle.

In one embodiment, the temporal break regulation can have a driver break with a predefined length and / or after a predefined travel duration. The temporal break regulation can, for example, have a statutory driving time, rest time, break time and / or working time for the driver of the motor vehicle. The time interval regulation can be a have driver break desired by the driver (z. B. entered via a user interface of the motor vehicle). The temporal pause regulation can particularly advantageously be provided by a tachograph of the motor vehicle (for example automatically). The temporal break regulation can have regional driving bans, preferably including Sunday driving bans and / or holiday driving bans, and / or temporary driving bans. Frequently occurring requirements regarding the break planning of professional drivers can thus be taken into account directly when planning the route, in particular automatically or after manual input, and can be appropriately linked with the loading or tank planning.

In a further exemplary embodiment, when energy supply devices are determined, only those energy supply locations are determined whose charging technology is compatible with a charging technology of the motor vehicle. As an alternative or in addition, when determining energy supply facilities, only those energy supply locations are determined which are available and / or can be reserved for the planned arrival. As an alternative or in addition, a respective charging power and / or a charging duration are also determined when determining energy supply devices. For example, the determination of the at least one route guidance suggestion can additionally be based on the charging power (= refueling output) and / or the charging time (= refueling time). In this way, route planning can be further optimized and specified in relation to the energy supply facilities. The corresponding data can, for example, be received via a communication interface of the motor vehicle and / or provided by a navigation system of the motor vehicle.

In one embodiment, the method further includes specifying a minimum state of charge or a minimum tank level of the motor vehicle, which should not be undershot during the route guidance (specifying, for example, by means of a user interface of the motor vehicle). For example, the determination of the at least one route guidance suggestion and / or the current range can also be based on the minimum charge level or the minimum tank filling. Thus, for example, a desired safety buffer can be taken into account in order to prevent the motor vehicle from standing still or to guarantee a remaining range to continue driving to a destination without charging or refueling facilities.

In a further embodiment, determining a current range comprises at least one of: determining a current vehicle mass and / or a current payload mass of the motor vehicle; Determining a state of wear of a traction battery or a fuel cell device of the motor vehicle; Obtaining topography information (e.g. curves, inclines, declines, etc.), (e.g. current or forecast) traffic flow information (e.g. traffic density, traffic jam, congestion forecasts, construction sites, average speed, etc.) and / or (e.g. current or forecast) weather information (e.g. temperature, precipitation, visibility, etc.), preferably with regard to possible routes or route sections between the starting point and the destination; Determination of the energy consumption of at least one other, preferably comparable (e.g. same or comparable type, same or comparable mass, same or comparable motorization) motor vehicle on possible routes or route sections between the starting point and the destination point; Determining a current electrical charge level or a current tank filling of the motor vehicle. Depending on the number and type of parameters taken into account, the current range can thus be calculated (estimated) particularly precisely. Relevant parameters that can cause a significant change in consumption can be, for example, a planned loading or unloading at the starting point or at an intermediate destination, (strong) headwind, slow-moving traffic, many uphill and / or downhill slopes, outside temperature, etc.

According to an independent or combinable aspect of the present disclosure, the method furthermore has a specification of an intermediate destination with a planned change in a payload mass of the motor vehicle (for example passenger and / or transport goods payload mass). The determination of the at least one route guidance proposal and / or the current range can preferably also be based on the intermediate destination and / or the planned change in the payload. This aspect can, for example, also take place without specifying a break regulation and determining the at least one suggested route based on the break regulation.

In one embodiment variant, the method also has a determination of parking spaces, rest areas and / or hotels between the starting point and the destination point. The determination of the at least one route guidance suggestion can preferably also be based on the determined parking spaces, rest stops and / or hotels.

In a further embodiment variant, the method also has a reservation or booking of at least one energy supply device, a parking lot and / or a hotel of a route guidance proposal selected by the driver, e.g. B. by means of a communication interface of the motor vehicle. In a further embodiment variant, the method also has a determination of autonomously and / or automatically navigable route sections which are preferably section-wise between the starting point and the destination point. The determination of the at least one route guidance suggestion can preferably also be based on the autonomously and / or automatically navigable route sections. This means that the route guidance can also be optimized with a view to automated or autonomous driving of the motor vehicle.

In one embodiment, the method includes an adaptation of a route proposal selected by the driver while driving the motor vehicle along the selected route proposal based on the time interval regulation, a current range, energy supply devices between a current location and the destination point and / or real-time data, preferably with regard to a current range of the motor vehicle, traffic flow information, weather information and / or consumption information. This means that the planned route can be updated, checked for plausibility and / or further optimized while driving.

In a further exemplary embodiment, the method also has an adaptation of an operation of the motor vehicle in order to reduce consumption. The operation can preferably be adapted if it is determined that a current range of the motor vehicle is not sufficient to reach the next or next planned energy supply device or that the next planned energy supply device is occupied on arrival.

In a further development, the adaptation of the operation includes at least one of: reducing a speed in an automated or autonomous operating mode of the motor vehicle; Reducing a power consumption of at least one secondary consumer of the motor vehicle, preferably a heater, a cooling system, an air conditioning system and / or a loading user interface of the motor vehicle; and limiting a maximum drive power output of the motor vehicle.

In a further exemplary embodiment, the method also includes monitoring of a driver's condition, preferably a fatigue condition, of the driver of the motor vehicle while driving the motor vehicle along a selected route proposal (e.g. by monitoring steering activity, glancing the eyes and / or keeping to a lane - assets). For example, the method can additionally adapt the selected route proposal based on the monitored driver state, preferably such that charging or refueling of the motor vehicle at an energy supply device and / or the driver's break is brought forward or delayed.

The invention also relates to a motor vehicle, preferably a utility vehicle (e.g. trucks or omnibus), having a control unit which is preferably permanently installed in the motor vehicle or included in a mobile terminal. The control unit is designed to carry out a method as disclosed herein.

The term “control unit” can preferably refer to electronics (e.g. with microprocessors and data storage) which, depending on the design, can take on control tasks and / or regulation tasks. Even if the term “control” is used here, it can also expediently include “control” or “control with feedback”.

The preferred embodiments and features of the invention described above can be combined with one another as desired. Further details and advantages of the invention are described below with reference to the accompanying drawings. Show it:

Figure 1 is a schematic representation of a motor vehicle according to an embodiment of the present disclosure; and

FIG. 2 shows a schematic illustration of a method for planning a route according to an exemplary embodiment of the present disclosure.

FIG. 1 shows, purely schematically, an exemplary motor vehicle 10 with which the techniques disclosed herein for driving or operating a motor vehicle can be used. The motor vehicle 10 can in particular be a utility vehicle, preferably a truck or a bus.

The motor vehicle 10 expediently has one or more electric motors as a drive unit. The electric motors can be supplied with electrical energy from a rechargeable traction battery or a fuel cell device. The traction battery can be charged at electric charging stations, for example. The fuel cell device can be supplied with hydrogen from a hydrogen tank of the motor vehicle 10 in order to generate electrical energy. The hydrogen tank can, for example, be refueled at hydrogen tank locations. It is also possible for the motor vehicle 10 as a drive unit for example, an internal combustion engine that can be driven with hydrogen. It is also possible that the motor vehicle 10 has at least one further drive unit and / or the motor vehicle 10 is a hybrid motor vehicle.

The motor vehicle 10 has a navigation system 12. The motor vehicle 10 can furthermore have an autonomous driving system 14, a location determination device 16, an environment detection sensor system 18, a communication interface 20, a user interface 22 and / or a tachograph 24. The components 12 to 24 can each be in communication with one another. The navigation system 12 and / or the autonomous driving system 14 can, for example, be part of a control unit of the motor vehicle 10 or be connected to such a control unit.

The navigation system 12 is used to determine route suggestions for the motor vehicle 10. Based on a predeterminable starting point and a predeterminable destination point, the navigation system 12 can submit one or more route proposals for driving the motor vehicle 10 from the starting point to the destination point. The navigation system 12 can receive data from the components 14-24 for route planning and possibly route updates while the motor vehicle 10 is driving. The navigation system 12 is adapted in such a way that the most varied of parameters, in particular relevant for commercial vehicles, can be taken into account for the determination of route suggestions, as is described in more detail herein, for example with reference to FIG.

The autonomous or automated driving system 14 is used for automated or autonomous driving of the motor vehicle 10. The autonomous driving system 14 can operate the motor vehicle 10 in different degrees of automation partially or fully autonomously (automated), depending on the design. The autonomous driving system 14 can, for example, receive data from the components 12 and 16-24 for driving the motor vehicle 10. In addition to fully manual operation of the motor vehicle 10, the motor vehicle 10 can, for example, in several, z. B. five different degrees of automation can be operated automatically, namely assisted driving (level 1), partially automated driving (level 2), highly automated driving (level 3), fully automated driving (level 4) and / or autonomous driving (level 5).

The location determination device 16 is designed to determine a current location of the motor vehicle 10. For example, the location device 16 may be a satellite-based and / or global location device, e.g. B. a GPS Positioning device, a Galileo positioning device, a GLON-ASS positioning device and / or a Beidou positioning device.

The environment detection sensor system 18 is designed to detect an environment of the motor vehicle 10 sen-supported, z. B. an environment in front of, next to and / or behind the motor vehicle 10. The environment detection sensor system 18 can, for example. A camera device, a Radarvorrich device, a lidar device, a laser scanning device and / or close-range sensors, eg. B. ultrasonic sensors have.

The communication interface 20 is designed to send and / or receive data, preferably wirelessly. For example, the communication interface 20 can enable communication with other motor vehicles, with infrastructure facilities, with the Internet and / or with a central control center.

The user interface 22 is designed to output information to a driver of the motor vehicle 10 and to receive inputs from the driver of the motor vehicle 10. For example, the user interface 22 can output information acoustically, visually and / or haptically. The user interface 22 preferably has, for example, a touch sensitive display device, a loudspeaker and / or one or more input devices, such as. B. buttons or switches. The user interface 22 can be permanently integrated into the motor vehicle 10 and / or as a mobile, expediently also outside the motor vehicle 10 usable terminal, eg. B. a smartphone, a tablet computer or a notebook, executed.

The tachograph or tachograph 24 is designed to directly or indirectly record the driving times, rest times and break times in a driver-specific manner (e.g. identification via a driver card and / or reading out the driver card). The recorded data can be called up by the tachograph 24, in particular by the navigation system 12.

FIG. 2 shows, purely by way of example, a method for route planning. It is possible that the method is carried out at least partially in a different sequence, additional steps are added and / or alternative steps are carried out, provided that no contradictions arise. Components 12-24 can be used individually or in any combination to carry out the method. In a method step S10, boundary conditions for route planning can first be specified. The specification can be made, for example, by user input using the user interface 22 or automatically z. B. can be received by means of the communication interface 20. For example, a starting point and a destination point can be specified. The starting point can be, for example, the current location or whereabouts of the motor vehicle 10, which can expediently be determined with the location determination device 16. In addition, for example, a start time, an arrival time and / or at least one intermediate stop or intermediate destination can be specified. It is possible to specify optimization goals for route planning, e.g. B. Minimum travel time, minimum charge level at the destination, etc.

Appropriately, in method step S10, specifications relevant to route planning, in particular for commercial vehicles, can also be made, as is explained below. The individual aspects can be used individually or in any combination as a default for route planning. A time interval regulation for a driver break of a driver of the motor vehicle 10 can advantageously be specified. The break regulation has a specification for the length of a driver break and / or for taking a driver break after a certain driving time. The specification can expediently correspond to statutory provisions, e.g. B. have legally prescribed or permitted driving times, rest periods, break times, working times for the driver of the motor vehicle. In this context, current data relating to the time interval regulation can preferably be provided by the tachograph 24 of the motor vehicle 10. The temporal break regulation can also have regional driving bans, preferably including Sunday driving bans and / or holiday driving bans, and / or temporary driving bans, in particular for commercial vehicles such as trucks. It is possible for the temporal break regulation to have a driver break desired by the driver of motor vehicle 10, which can be entered manually, for example. For example, the driver of the motor vehicle 10 can specify that he would like to take a rest break with a specifiable or variable length of the break after a certain driving time. The pause regulation can for example be received manually by means of the user interface 22 and / or automatically by means of the communication interface 20.

Expediently, one or more intermediate destinations for the route can also be specified in method step S10. Preferably, in addition to the at least one Intermediate goal can be specified how a payload changes at the respective intermediate goal. The payload can relate to a passenger payload, in particular if the motor vehicle 10 is an omnibus, such as a touring coach. The payload mass can alternatively or additionally relate to a (transport) freight payload mass, in particular if the motor vehicle 10 is a transport truck. It is possible that the payload and / or the at least one intermediate destination is received manually by means of the user interface 22 and / or automatically by means of the communication interface 20. The payload can be specified, for example, directly in kilograms and / or indirectly, for example in the form of a number of people, a number of piece goods, etc.

In addition, there may be the possibility in method step S10 of specifying, for example, a minimum charge state of the action battery that is not to be fallen below or a minimum level of the hydrogen tank that is not to be undercut. This minimum state of charge or the minimum tank filling must not be undercut with a predefinable or predetermined degree of certainty while driving along the route to be planned.

In method step S12, a (preliminary) route planning can take place in which one or more candidates for route proposals that connect the starting point with the destination point are determined. It is possible to take into account desired intermediate destinations for the candidates for route suggestions. The route planning can also refer to data D10, for example. The data D10 can, for example, be provided by the navigation system 12 itself or can be received by means of the communication interface 20. The data D10 can have topography (e.g. curves, inclines, slopes, etc.) and climatic data, such as map data, navigation data, congestion data (current and / or forecast), weather data (e.g. temperature forecast and precipitation forecast, counter - or tail wind forecasts) etc.

In method step S14, vehicle data or parameters (data D12) can be called up and evaluated. For example, the data can be captured by sensors of the motor vehicle 10, calculated based on sensor measurements and / or model-based using appropriate simulation models, e.g. B. be determined in the control units involved. The data D12 can include, for example, an engine output, efficiency, a capacity, aging conditions (e.g. the traction battery or the fuel cell device), a charge level or a tank filling, a quick charge option, a range of an optionally available range larger (range extender), a total mass or a load mass, a tempera ture of the traction battery, loss maps, etc. of the motor vehicle 10 concern. Thus, for example, a current range of the motor vehicle 10 can be determined in method step S14.

The determination of the current range can take into account additional parameters, such as, for example, the data D10 on the topography, the traffic flow and / or the weather with regard to the candidates for possible routes. For example, slopes, inclines, traffic jams and / or the need to use the air conditioning system or certain headlights of the motor vehicle 10 have an influence on the consumption of the motor vehicle 10.

Additionally or alternatively, for example, a planned change in the payload (for example specified in method step S10) of the motor vehicle 10 can be taken into account. For example, the payload at an intermediate destination can change significantly as planned by loading or unloading the motor vehicle 10, which from this intermediate destination results in a significant change in consumption and thus the range.

It is also possible, for example, by means of the communication interface 20, to receive energy consumption data from comparable motor vehicles (for example, comparable type, comparable total mass and / or comparable motorization), which the candidates for possible routes have already driven or have driven at least in part, and when Determine the current range to be taken into account.

In method step S16, the candidates for possible routes with regard to charging and / or refueling options for the motor vehicle 10 can be optimized and / or adapted, taking into account the current range (and future ranges). For this purpose, for example, stationary energy supply devices that are located between the starting point and the destination point can initially be determined. Depending on the design of the motor vehicle, energy supply locations can be, for example, electrical charging stations or hydrogen filling stations. The determined energy supply devices are included in the route planning so that the motor vehicle 10 can be charged or refueled at the energy supply devices when driving to the destination point, if necessary. In method step S18, a check can be made with regard to the availability of parking spaces, rest stops, hotels and / or energy supply facilities planned in the candidates for routes. For this purpose, corresponding data D14 can be sent and received by the communication interface 20. The data D14 can in particular have current and / or planned infrastructure information. These include, for example, a fast charging capability with regard to the energy supply facilities, a parking space availability, a commercial vehicle charging facility, a capacity utilization, an energy supply facility availability, a charging capacity, a charging duration, a charging technology, a reservation facility, etc. The route planning can be improved as a result, since For example, only those energy supply devices are determined whose charging technology is compatible with the charging technology of the motor vehicle 10 and / or which are (likely) available and / or can be reserved for the planned arrival.

If desired, the determined available energy supply devices can be coordinated with the specified pause regulation in method step S18. In this way, for example, those, in particular available, energy supply devices can be selected for the routes which, when they are reached in the planned / precalculated manner, a driver break according to the break regulation is necessary or would be shortly. For example, the required driver break or driving time interruption can expediently be spent at least partially while charging or refueling motor vehicle 10. For route planning, parking spaces, rest stops and / or hotels can also be taken into account, if necessary, where the driver's break (s) can also be taken in accordance with the break regulations.

The route planning can thus be specified in method step S18 in such a way that suitable route suggestions are determined, for example, by selecting, adapting or optimizing the candidates for routes. An optimization method can optimize a number, a duration and / or a location for the required loading or refueling stops, taking into account the criteria mentioned. The suggested routes can, as described above, be determined taking into account the determined energy supply devices, the range of the motor vehicle, the break control and / or the change in the payload specified with regard to possible intermediate destinations. At least one suggested route can thus preferably be output visually via the user interface 22. The suggested routes can have one or more stops at energy supply devices, which are preferably coordinated with one or more driver breaks according to the break regulation. The driver of the motor vehicle 10 or the operator of the user interface 22 can directly confirm one of the output route suggestions via the user interface 22 (method step S20). The method can then continue with a method step S24. It is also possible for manual adjustments to be made to a desired route proposal using the user interface 22 (method step S22). The method can then, for example, continue again with method step S16, if desired, or, if necessary according to the adaptations, continue with an even earlier method step, for example method steps S10, S12, S14.

If possible and / or desired, in method step S24, for example, reservations and / or bookings can be requested for the energy supply facilities, parking spaces or hotels contained in the selected route proposal. In this case, the communication interface 20 can exchange data D16 with a server-based booking system, for example. The booking system can for example be implemented as a web service and / or have an accounting system.

In method step S26, the reservations and / or bookings are confirmed in a binding or non-binding manner. This means that the suggested route can be implemented as required. The motor vehicle 10 can now be driven off in method step S30 and guided by the navigation system 12 along the selected route proposal while driving. During the journey, the selected route proposal can be continuously updated and checked for plausibility, particularly if, for example, unforeseen or unplanned changes occur in the data D10-D16. In particular, real-time or current data can be taken into account here, in particular with regard to the current range of the motor vehicle 10, traffic flow information, weather information, consumption information, etc.

However, it is also possible that in method step S28 at least one of the reservations and / or bookings is not confirmed or rejected. The method can then be continued again with method step S16, for example.

It is possible that, if the motor vehicle 10 has the automated or autonomous driving system 14, additional autonomous drivable route sections are determined for the route suggestions. These route sections can be displayed, for example, via the user interface 22, for example when the route suggestions are output and / or while the motor vehicle 10 is being guided along the selected route. The The driver can thus recognize which portion of the route the motor vehicle 10 is likely to be able to drive automatically or autonomously. In this way, the driver can see how much time he can plan for professional or private secondary activities and in what period of time during the journey (e.g. beginning, middle or end of the journey) the secondary activities can be carried out.

During the journey of the motor vehicle 10 along the selected suggested route, the operation of the motor vehicle 10 can be optimized or adapted, if desired and / or available.

For example, it can be determined while driving that a current range of the motor vehicle 10 is not sufficient to reach the next or next planned energy supply device. It can also be determined that the next planned energy supply facility is occupied on arrival. In such cases, an automatic or manually confirmable adaptation of an operation of the motor vehicle 10 with the aim of current consumption reduction can be carried out. This can be done both in manual, automated or autonomous operation of motor vehicle 10. For example, a speed of the motor vehicle 10 can be reduced in an automated or autonomous operating mode of the motor vehicle 10. The reduction in power consumption of secondary consumers of motor vehicle 10, which are not required for safe operation of motor vehicle 10, can also reduce consumption. Such secondary consumers can be, for example, heating, cooling, air conditioning and / or a display of the user interface 22 of the motor vehicle 10, etc. It is possible, for example, to regulate the secondary consumers down or to switch them off completely. Alternatively or additionally, for example, a maximum drive power output of the drive unit of the motor vehicle 10 can be reduced.

As a further example, the driver state, preferably a state of fatigue, of the driver of motor vehicle 10 can also be determined while driving. The suggested route can be adjusted accordingly, e.g. B. automatically or after manual confirmation. For example, a driver break, charging or refueling of the motor vehicle 10 can be brought forward if driver fatigue is determined, or delayed if the current range of the motor vehicle 10 etc. allows this and no driver fatigue is determined. The invention is not restricted to the preferred exemplary embodiments described above. Rather, a large number of variants and modifications are possible which also make use of the inventive concept and therefore fall within the scope of protection. In particular, the invention also claims protection for the subject matter and the features of the subclaims independently of the claims referred to. In particular, the individual features of independent claim 1 are disclosed independently of one another. In addition, the features of the subclaims are also disclosed independently of all the features of independent claim 1 and, for example, independently of the Merkma len with regard to the individual method steps of independent claim 1.

List of reference symbols

10 motor vehicle

12 Navigation system

14 driving system

16 Positioning device

18 Environment detection sensors

20 communication interface

22 User Interface

24 tachograph

S10-S30 process steps

D10-D16 information / data

Claims

1. A method for driving a motor vehicle (10), preferably electric or hydrogen-driven, particularly preferably a commercial vehicle, comprising:

Specifying a starting point and a destination point of a route;

Specifying a time interval regulation for a driver break for a driver of the motor vehicle (10);

Determining a current range of the motor vehicle (10);

Determining energy supply devices, preferably electrical charging locations for charging the motor vehicle (10) or hydrogen filling stations for tanking the motor vehicle (10), between the starting point and the destination point;

Determination of at least one route guidance proposal from the starting point to the destination point based on the time interval regulation, the current range and the energy supply devices; and

Output of the at least one route guidance proposal.

2. The method of claim 1, wherein:

the at least one suggested route is determined in such a way that the driver's break and charging or refueling of the motor vehicle (10) at an energy supply device are coordinated with one another,

where preferably:

the at least one route guidance proposal is determined in such a way that the driver's break falls within a period in which charging or refueling of the motor vehicle (10) is planned at an energy supply device; and or

the at least one route guidance proposal is determined in such a way that charging or refueling of the motor vehicle (10) at an energy supply device occurs during a period in which the driver's break is planned.

3. The method of claim 1 or claim 2, wherein:

the temporal break regulation requires a driver break with a predetermined length and / or after a predetermined journey time; and or

the temporal break regulation has a statutory driving time, rest time, break time and / or working time for the driver of the motor vehicle (10); and or

the temporal break regulation has a driver break desired by the driver and / or the time interval regulation is provided by a tachograph (24) of the motor vehicle (10); and or

the temporal break regulation has regional driving bans, preferably including Sunday driving bans and / or holiday driving bans, and / or temporary driving bans.

4. The method according to any one of the preceding claims, wherein:

when determining energy supply facilities, only those energy supply locations are determined whose charging technology is compatible with a charging technology of the motor vehicle (10); and or

when determining energy supply facilities, only those energy supply locations are determined that are available and / or can be reserved for the planned arrival; and or

when determining energy supply devices, a respective charging power and / or a charging time is additionally determined, and the determination of the at least one route guidance proposal is additionally based on the charging power and / or the charging time.

5. The method according to any one of the preceding claims, further comprising:

Specifying a minimum charge level or a minimum tank filling of the motor vehicle (10), which must not be undercut during the route guidance,

wherein the determination of the at least one route guidance suggestion and / or the current range is additionally based on the minimum charge level or the minimum tank filling.

6. The method according to any one of the preceding claims, wherein determining a current range comprises at least one of:

Determining a current vehicle mass and / or a current payload mass of the motor vehicle (10);

Determining a state of wear of a traction battery or a fuel cell device of the motor vehicle (10);

Determination of topography information, traffic flow information and / or weather information, preferably with regard to possible routes or route sections between the starting point and the destination point; Determining an energy consumption of at least one other, preferably comparable, motor vehicle (10) on possible routes or route sections between the starting point and the destination point;

Determination of a current electrical charge level or a current tank filling of the motor vehicle (10).

7. The method according to any one of the preceding claims, further comprising:

Specifying an intermediate destination with a planned change in a payload of the motor vehicle (10); and

wherein the determination of the at least one route guidance suggestion and / or the current range is additionally based on the intermediate destination and the planned change in the payload.

8. The method according to any one of the preceding claims, further comprising:

Determining parking lots, rest stops and / or hotels between the starting point and the destination point; and

the determination of the at least one route guidance proposal is additionally based on the determined parking spaces, rest stops and / or hotels.

9. The method according to any one of the preceding claims, further comprising:

Reserve or book at least one energy supply device, a parking lot and / or a hotel of a route guidance proposal selected by the driver.

10. The method according to any one of the preceding claims, further comprising:

Determination of autonomously and / or automatically navigable route sections which lie in sections between the starting point and the destination point,

wherein the determination of the at least one route guidance suggestion is additionally based on the autonomously and / or automatically navigable route sections.

11. The method according to any one of the preceding claims, further comprising:

Adaptation of a route proposal selected by the driver while driving the motor vehicle (10) along the selected route proposal based on the time interval regulation, a current range, energy supply device services between a current location and the destination point and real-time data, preferably with regard to a current range of the motor vehicle (10), traffic flow information, weather information and / or consumption information.

12. The method according to any one of the preceding claims, further comprising:

Adapting an operation of the motor vehicle (10) to reduce consumption when it is determined that:

a current range of the motor vehicle (10) is not sufficient to reach a next or next planned energy supply device; or

the next planned energy supply facility is occupied on arrival.

13. The method of claim 12, wherein adapting the operation comprises at least one of:

Reducing a speed in an automated or autonomous Be operating mode of the motor vehicle (10);

Reducing a power consumption of at least one secondary consumer of the motor vehicle (10), preferably a heating, cooling, air conditioning and / or a user interface (22) of the motor vehicle (10); and

Limiting a maximum drive power output of the motor vehicle (10).

14. The method according to any one of the preceding claims, further comprising:

Monitoring a driver condition, preferably a fatigue condition, of the driver of the motor vehicle (10) while driving the motor vehicle (10) along a selected suggested route; and

Adaptation of the selected route proposal based on the monitored driver's state, preferably such that charging or refueling of the motor vehicle (10) at an energy supply device and / or the driver's break is brought forward or delayed.

15. Motor vehicle (10), preferably commercial vehicle, comprising:

a control unit (12, 14), which is preferably permanently installed in the motor vehicle (10) or included in a mobile terminal, the control unit (12, 14) being designed to carry out a method according to one of the preceding claims.