GB2573382A - Vehicle - Google Patents

Abstract

The invention relates to a vehicle (1) for accommodating a number n ≤ N of delivery robots (50) in a cargo compartment (10) of the vehicle (1), where N is the maximum number of delivery robots (50) which can be accommodated in the cargo compartment (10) and n is the number of delivery robots (50) currently in the cargo compartment (10). The vehicle (1) has the following: - a fixing device (12) for the automatic individual fixing of N delivery robots (50) in the cargo compartment (10), - a communication interface (14) for communication between the vehicle (1) and the n delivery robots (50), and - a number N of charging interfaces (16) for the individual automatic charging of energy stores of the n delivery robots (50) in the cargo compartment (10).

Description

The invention concerns a vehicle and method for picking up delivery robots, as well as a system for delivering parcels I freight to a large number of locally distributed recipients with at least one such vehicle. Furthermore, the invention concerns a method for delivering parcels with such a vehicle.

Today, vehicles that are used to deliver parcels and freight to a large number of recipients have a cargo hold to stow the parcels and freight. The delivery of the individual parcels is then carried out manually by a person who removes the parcels from the hold and delivers them to the recipients.

The task of the invention is to specify a vehicle that enables improved and faster delivery of parcels/freight. Furthermore, it is a task to specify a method and system for delivering packages/freight to a variety of local recipients with an equivalent vehicle. It should be noted that in the following description the terms package and freight are used synonymously.

The invention results from the characteristics of the independent claims. Advantageous further developments and embodiments are the subject of the dependent claims.

A first aspect of the invention concerns a vehicle or a method of picking up a number n < N of delivery robots in a hold of the vehicle, where N is the maximum number of delivery robots that can be picked up in the hold and n is the number of delivery robots currently in the hold. The vehicle comprises: a fixing device for automatically individually fixing N delivery robots in the hold, a communication interface for the vehicle to communicate with the n delivery robots, and a number N of loading interfaces for individually charging energy stores of the n delivery robots in the hold.

The vehicle is preferably a truck, small van, van, delivery van or bus. However, the vehicle can also be a passenger car, rail vehicle, watercraft (e.g. ship), underwater vehicle or aircraft.

The term delivery robot is understood in the present case to mean in particular a selfdriving delivery robot, a self-flying delivery robot (drone), a self-controlling floating vehicle, etc..

The energy storage devices of the delivery robots are advantageous electrical energy storage devices, i.e. accumulators. These are charged by applying an electric current with a certain voltage, preferably by direct current. Alternatively or additionally, the delivery robots can be driven by combustion engines, so that the energy storage units are advantageous fuel tanks in this case. The following fuels can be considered: petrol, hydrogen, liquefied petroleum gas, etc.

The loading space of the vehicle can preferably be accessible from the rear of the vehicle and/or from one side of the vehicle. In particular, the load compartment of the vehicle can be located behind and separated from a driver's cab. Access to the vehicle's loading space can be controlled and automatically opened and closed.

The delivery robots are advantageously designed and set up in such a way that they are controlled and checked automatically, advantageously completely autonomously, i.e. without direct control by a human operator. The delivery robots are therefore equipped in particular with a positioning and navigation system, as well as with a robot guidance computer, which takes over the control of the robot. The delivery robots can thus move autonomously from one position to another (e.g. the address of a parcel recipient) and return again. The robot guidance computer is provided with a current (2D-/3D-) route guidance on the basis of which the delivery robot is controlled. The delivery robots are advantageously equipped with a sensor system for recording the current environment, as well as an evaluation unit for evaluating the recorded environmental data with regard to existing obstacles. The data is also used advantageously to control the delivery robot.

The vehicle is equipped, in accordance with the invention, with a fixing device to hold the delivery robots carried and picked up in the hold in a certain position, even if acceleration due to travel occurs. In accordance with an advantageous design, the vehicle's fixing device is also designed to fix delivery robots already loaded with freight. This is an advantage when it comes to fixing loaded and thus more massive delivery robots. The automatic fixation device can have a mechanical fixation, for example by engaging fixation hooks, by an automatic fixation by belts, etc.

In accordance with an advantageous design, the fixing device has one or more inflatable units which serve to fix the delivery robots. The fixing of the delivery robots is done by a mechanical clamping at the respective position in the vehicle by means of the inflated units. The inflatable units can be filled with a liquid and/or gaseous medium or the liquid or gaseous medium can be released from the units, whereby in the inflated state of the units, the unit is filled with the respective medium. The fixing device can comprise one or more individual, for example cushion-shaped inflatable units for each delivery robot. Alternatively, several delivery robots can be fixed in the hold, for example with an inflatable unit with an advantageous mattress shape. The inflatable units attach themselves to the respective outer contours of the delivery robots for fixing in the inflated state, so that differently shaped delivery robots can be fixed with similar reliability. In other words, the inflatable units are not tied to a specific construction or outer contour of the delivery robot in order to fix it reliably in the loading space of the vehicle.

The inventive communication interface is used for communication between the vehicle and the delivery robots in order to transmit information between the vehicle and the delivery robots. The vehicle's communication interface makes advantageous use of a Bluetooth, WiFi, GSM, UMTS or LTE connection for this purpose.

In an advantageous design, the delivery robots communicate at least one of the following states of a respective delivery robot to the vehicle via the communication interface:

- Loading condition of the respective delivery robot,

- Type of freight (e.g. post/ pa reel/register/ etc.) of the respective delivery robot,

- Identification of the respective freight,

- Position of the respective delivery robot,

- Delivery address reached,

- Available operating energy of the respective delivery robot,

- Error message of the respective delivery robot.

It is advantageous to provide each freight with a unique identifier for identification purposes, for example in the form of a readable RFID chip. This means that the current location of each freight until it is delivered to a recipient can be recorded and communicated to the vehicle.

In another advantageous design, the vehicle communicates via the communication interface at least one of the following information to one or more or all of the n delivery robots:

- Start signal for autonomous unloading of the respective delivery robot(s),

- Delivery address to be driven to by the respective delivery robot,

- Type of handover (storage of cargo with/without interaction with the recipient)

- Parking position in vehicle reached,

- Start of a charging process with energy.

This communication serves to provide the respective delivery robot, for example, with all the information required for delivery of the respective parcel or freight to a recipient. In addition, operational information, such as completion of an automatic unloading process of the delivery robot from the vehicle, start of an automatic loading process of the delivery robot on the vehicle, reaching a parking position of the delivery robot in the vehicle, start of an automatic charging process with energy, etc. can be provided from the vehicle to the respective delivery robot. Based on this information received from the vehicle, automatic control routines can, for example, be started in the respective delivery robot.

The vehicle also has an advantageous communication interface with a control centre. Via this interface, some or all of the information available in the vehicle, for example on the condition of the vehicle, on the condition of the delivery robots, etc., can be advantageously transmitted from the vehicle to the control centre. In addition, information, such as changes to the route of the vehicle, changes to freight-specific data, in particular the recipient data of a freight, etc., can be transmitted from the control centre to the vehicle.

The above-mentioned N charging interfaces of the vehicle enable an individual automatic charging of energy storage devices of the delivery robots in the loading space of the vehicle in order to supply the delivery robots with new energy or to recharge them, especially during a journey of the vehicle. The energy transferred to the delivery robots via the charging interfaces can be transferred in particular in the form of electrical energy and/or fuels (petrol, diesel, liquid hydrogen, liquid gas, etc.). The energy storage devices of the delivery robots are correspondingly accumulators or containers for receiving liquid or gaseous fuels. According to another advantageous design, the charging interfaces transfer energy to the delivery robots according to an inductive principle. Here, a constantly changing electromagnetic field is generated from an electrical energy source, which triggers an induction current in the receiver, which is used to charge an accumulator of a delivery robot in particular. A contactless charging of an accumulator can thus be realized advantageously. The loading interfaces are advantageously designed and set up in such a way that as soon as a delivery robot has taken up a designated position in the loading space of the vehicle and, for example, a release is given for the start of autonomous loading, the loading process begins and, if necessary, a mechanical contact between the vehicle and the delivery robot is automatically established via the loading interface.

According to another advantageous design, the charging interfaces have a mechanical interface for transmitting electrical energy to a delivery robot, which can autonomously establish an electrical contact between the delivery robot and one of the charging interfaces. The loading process of the delivery robots is advantageous without the intervention of an operator, i.e. autonomously possible.

According to another advantageous design, the vehicle has a loading space optimization system with optical sensors to detect the delivery robots present in the loading space, whereby the loading space optimization system controls the positioning of the delivery robots in the loading space via the communication interface. The loading space optimization system comprises an image evaluation processor to determine the current positioning of the delivery robots and a control unit that communicates with and can control the delivery robots in the loading space via the communication interface. The vehicle thus benefits from information on the number and position of the delivery robots in the vehicle's loading space, which makes it possible to control, check and optimise the loading space in particular.

According to a further advantageous design, the vehicle has a device for detecting and providing at least one of the following states in the vehicle:

- Loading of the vehicle with delivery robots (this refers to the loading process),

- Unloading of the delivery robots from the vehicle (this refers to the unloading process),

- Number n of delivery robots already loaded in the vehicle,

- Number F = N - n of the free receiving places for delivery robots in the vehicle,

- Information about a route to be driven by the vehicle,

- Information about a target position to be driven to by the vehicle,

- Error messages from the vehicle.

This information shall be used to record an operational state of the vehicle in order to transmit it to a driver of the vehicle and/or to forward it to a central office. This information can still be used in the vehicle or in the central office to determine operational delays of the vehicle compared to a previously provided delivery schedule.

According to another advantageous design, the loading space of the vehicle has different levels for receiving the delivery robots. This enables an optimised use of the loading space.

According to another advantageous design, the loading space of the vehicle is designed to accommodate pallets already equipped with delivery robots. The pallets are advantageously designed in such a way that they fit into a drawer system in the hold. The pallets have an advantageous size that corresponds approximately to the floor area of the loading space, so that the number of inserted pallets equals the number of levels equipped with delivery robots in the loading space.

According to another advantageous design, the vehicle is equipped with a device for automatic loading and/or unloading of the delivery robots into/from the loading space. Depending on the type of delivery robot and vehicle, this may include a controllable ramp and/or a controllable lifting system and/or a take-off and landing platform and/or a docking and landing interface.

According to another advantageous design, the device for automatic loading and unloading of the vehicle is controlled by a control system of the vehicle depending on a manual input of a driver of the vehicle or automatically depending on the reaching of predetermined delivery positions.

According to another advantageous design, the vehicle has a warning device with which an acoustic and/or visual warning signal for an environment of the vehicle can be emitted before and/or during loading and/or unloading of the loading space. Here the vehicle has at least one electroacoustic transducer (loudspeaker, horn, etc.) and/or one or more light sources, an optical scoreboard, etc.

The proposed vehicle will allow a more efficient delivery of freight to the recipient. In particular, the proposed vehicle will allow parallel delivery of parcels to recipients.

A further aspect of the invention concerns a method of delivering parcels with a vehicle as described above and below to a plurality of locally distributed receivers in an environment of a location 02, the delivery robots each being adapted to receive a freight and autonomously transport it from the location 02 to a predetermined delivery address, deliver the freight and autonomously return to the location 02 to autonomously enter the hold of the vehicle. The method has the following steps.

In a first step, a number of m delivery robots are loaded with one freight each, with m < η < N. In a further step, the vehicle and the delivery robots loaded with the freight are made available at a location 01. In a further step, the loading space of the vehicle is automatically loaded with the m delivery robots loaded with freight at location 01. In a further step, the vehicle is driven from the location 01 to a location 02. In a further step, at least one of the delivery robots loaded with one freight each is automatically unloaded at the 02 location, whereby this delivery robot then travels autonomously from the 02 location to a predefined delivery address, delivers the freight and returns autonomously to the 02 location. In a further step, an autonomous loading of this delivery robot into the loading space of the vehicle takes place.

The delivery robots are preferably loaded with freight at location 01 (e.g. a freight centre). The proposed vehicle will then be made available at location 01. It takes place at site 01 as preferably an automated, autonomous loading of the loading space of the vehicle with the delivery robots. The vehicle then drives from the location 01 to a location 02. Some or all of the recipient addresses of the freight are conveniently located in the vicinity of 02. One or more delivery robots leave the loading area of the vehicle and automatically control the respective recipient of their freight, deliver the freight and in turn control the vehicle automatically in order to reach the loading area of the vehicle automatically. Once there, the respective delivery robot is automatically fixed and, if necessary, charged with energy.

Advantages and advantageous further developments of the proposed methods result from an analogous and logical transfer of the above remarks made in connection with the vehicle.

Another aspect of the invention concerns a system for delivering freight to a variety of locally distributed recipients, including at least one vehicle as described above and below and several delivery robots each designed to do so:

- to take on a cargo,

- automatically enter and leave the vehicle's load compartment, and

- after leaving the hold, to autonomously transport their cargo to a predetermined delivery address, deliver the cargo, autonomously return to the vehicle and autonomously return to the hold.

Advantages and beneficial developments of the proposed system will result from an analogous and logical transfer of the above remarks in relation to the proposed vehicle and the proposed method.

Further advantages, features and details result from the following description, in which at least one example of execution is described in detail, if necessary with reference to the drawings. Identical, similar and/or functionally identical parts have the same reference marks.

Figure Description

Fig. 1 A vehicle with self-driving delivery robots according to an example of the invention,

Fig. 2 A method for delivering packages with a vehicle according to another execution example of the invention, and

Fig. 3 A vehicle with self-driving delivery robots according to another example of the invention.

The representations in the figures are schematic and not to scale.

Fig. la and Fig. lb each show a vehicle 1 for picking up a number n of self-driving delivery robots 50 in a hold 10 of vehicle 1. Vehicle 1 has inflatable cushions as a fixing device 12 for automatically fixing the delivery robots 50 individually in hold 10. In Fig. la the delivery robots 50 are loaded in the loading space 10 of vehicle 1, but are not yet secured by the fixing device 12, as the cushions are not yet filled with air or any other gas. Fig. lb, however, shows the cushions of the fixing device 12 in an inflated state, whereby the delivery robots 50 are held in a predetermined position by the fixing device 12 to prevent the delivery robots 50 from moving relative to vehicle 1 during a journey of vehicle 1. In particular, the fixing device 12 is designed in such a way that it can also fix delivery robots 50 already loaded with freight. Furthermore, vehicle 1 has a communication interface 14 for vehicle 1 to communicate with the n delivery robots 50. The communication interface 14 communicates at least the following states with at least one of the n delivery robots 50 to vehicle 1: loading state of the respective delivery robot 50, type of loading of the respective delivery robot 50, the position of the respective delivery robot 50, the state delivery address reached upon occurrence of the respective event, available operating power of the respective delivery robot 50 and any error messages. The communication interface 14 preferably uses a local WLAN for connection to the vehicle 1. Furthermore, the communication interface 14 communicates the following information from vehicle 1 to at least one of the n delivery robots 50: start signal for autonomous unloading of the respective delivery robot 50, the delivery address to be driven to by the respective delivery robot 50, type of transfer, the status Parking position in vehicle 1 reached and the status Start charging process with electrical energy. For charging batteries of the delivery robot 50, a number N of charging interfaces 16 for individual charging of the n delivery robot 50 is available in the loading space 10 of vehicle 1. The charging interfaces 16 transmit the electrical energy according to an inductive principle. This induction current, which is generated by time-varying electromagnetic fields, charges the batteries of the delivery robots 50. A mechanical interface for transmitting electrical energy to a delivery robot 50 is available for this purpose, which can autonomously establish an electrical contact between the delivery robot 50 and one of the charging interfaces 16. A loading space optimization system 18 also uses optical sensors, preferably one or more cameras, to detect those n delivery robots 50 that are located in loading space 10 of vehicle 1. The information as to which receiving stations for delivery robot 50 in vehicle 1 are already occupied is forwarded by the loading space optimization system 18 to a computer of vehicle 1, whereby the loading space optimization system 18 controls the positioning of the delivery robot 50 in loading space 10 via the communication interface 14. The delivery robots 50 are thus given a command as to which of the respective receiving stations the respective delivery robot 50 is to take. From the number n of already loaded delivery robots 50 in vehicle 1, the information about the loading of vehicle 1 with delivery robots 50, the information about the unloading of the delivery robots 50 from the vehicle 1, the number F = N - n of the free reception places for delivery robots 50 in vehicle 1 and information about a route to be driven by vehicle 1 with the corresponding target positions to be driven to by vehicle 1, a delivery process can be optimized. This information shall in particular be provided by a device 20 for the collection and provision of such information.

Fig. 2 shows a method of delivering packets with a vehicle 1 to a plurality of locally distributed recipients in an environment of a location 02. The delivery robots 50 are each designed to pick up a load and drive autonomously from the location 02 to a specified delivery address, deliver the load and return autonomously to the location 02 in order to autonomously reach loading space 10 of vehicle 1. In a first step SI, a number of delivery robots 50 are each loaded with one freight. In a second step, S2, vehicle 1 and a delivery robot 50 loaded with freight will be provided at a location 01. In a third step, S3, automated loading of loading space 10 of vehicle 1 with the m delivery robots 50 loaded with freight takes place at location 01. Furthermore, the vehicle 1 travels from location 01 to a location 02 in a fourth step S4 in order to have an automated unloading of at least one of the delivery robots 50, each loaded with a freight, carried out at location 02 in a fifth step S5, wherein this delivery robot 50 then travels autonomously from location 02 to a predetermined delivery address, delivers the freight and returns autonomously to location 02. In the final sixth step S6, an autonomous loading of this delivery robot 50 into the loading space 10 of vehicle 1 takes place.

Fig. 3 shows a vehicle 1 in different views or in different states in each of the subfigures. The loading space 10 of vehicle 1 has different levels for receiving the delivery robots 50. In particular, the delivery robots 50 are arranged on pallets. Vehicle 1 is equipped with a device 22 for automatic loading and/or unloading of delivery robots 50 into/from loading space 10. For this purpose, the device 22 for automatic loading and/or unloading is equipped with a controllable ramp and/or a controllable lifting system. This ramp is controlled depending on a manual input of a driver of vehicle 1 or automatically depending on the reaching of predefined delivery positions. If the ramp is actuated and/or if loading and/or unloading of loading space 10 takes place, at least one acoustic warning signal for an environment of vehicle 1 is emitted by a warning device, in particular at the start of loading and/or unloading of loading space 10.

In particular, vehicle 1 is part of a system for delivering parcels to a large number of locally distributed recipients. The delivery robots 50, which are also part of the system, pick up a load, automatically drive into hold 10 of vehicle 1 and leave it automatically when vehicle 1 has reached a corresponding area where one or more of the recipients assigned to the parcels in the respective delivery robot 50 are located. After leaving hold 10, the delivery robots 50 drive autonomously to a specified delivery address, deliver the freight and return autonomously to vehicle 1 to return autonomously to hold 10 of vehicle 1.

Although the invention was illustrated and explained in detail by preferred examples of execution, the invention is not limited by the disclosed examples and other variations can be derived by the skilled person without leaving the scope of protection of the invention. It is therefore clear that a multitude of possible variations exists. It is also clear that the embodiments mentioned as examples are really only examples which are not to be understood in any way as limiting the scope of protection, the application possibilities or the configuration of the invention. Rather, the preceding description and the figure description enable the skilled person to concretely implement the exemplary forms of execution, whereby the skilled person, being aware of the disclosed idea of invention, can make numerous changes, for example with regard to the function or arrangement of individual elements named in an exemplary form of execution, without leaving the scope of protection defined by the claims and their legal correspondences, such as further explanation in the description.

Reference character list

Vehicle

Loading space

Fixing device

Communication interface

Charging interfaces

Loading space optimisation system

Detection and provisioning apparatus

Automatic loading and/or unloading device

Delivery robots

Loading

Deploy

Automated provisioning

Driving

Automated unloading

Autonomous unloading

Claims (15)

Claims

1. A vehicle (1) for receiving a number η < N of delivery robots (50) into a loading space (10) of the vehicle (1), wherein N is the number of maximum receivable delivery robots (50) in the loading space (10) and n is the number of delivery robots (50) currently located in the loading space (10), the vehicle comprising:

- a fixing device (12) for automatically individually fixing N delivery robots (50) in the loading space (10),

- a communication interface (14) for said vehicle (1) to communicate with said n delivery robots (50), and

- a number N of charging interfaces (16) for the individual automatic charging of energy stores of the n delivery robots (50) in the loading space (10).

2. The vehicle (1) according to claim 1, wherein the communication interface (14) communicates at least one of the following states of a respective one of the n delivery robots (50) to the vehicle (1):

- Loading condition of the respective delivery robot (50),

- Type of loading of the respective delivery robot (50),

- Position of the respective delivery robot (50),

- Delivery address reached,

- Available operating energy of the respective delivery robot (50),

- Error messages.

3. The vehicle (1) according to any of claims 1 to 2, wherein the communication interface (14) communicates at least one of the following information from the vehicle (1) to one or more or all of the n delivery robots (50):

- Start signal for autonomous unloading of the respective delivery robot (50),

- Delivery address to be driven to by the respective delivery robot (50),

- Type of transfer,

- Parking position in vehicle (1) reached,

- Start charging with electrical energy.

4. The vehicle (1) according to any of claims 1 to 3, comprising a device (20) for detecting and providing at least one of the following states in the vehicle (1):

- Loading the vehicle (1) with delivery robots (50),

- Unloading the delivery robots (50) from the vehicle (1),

- Number n of delivery robots already loaded (50) in the vehicle (1),

- Number F = N - n of the free receiving places for delivery robots (50) in the vehicle (1),

- Information on a route to be taken by the vehicle (1),

- Information about a target position to be driven to by the vehicle (1),

- Error messages.

5. The vehicle (1) according to any of claims 1 to 4,

Wherein the fixing device (12) comprises one or more inflatable units for fixing the delivery robots (50).

6. The vehicle (1) according to any of claims 1 to 5,

Wherein the loading space (10) of the vehicle (1) comprises different levels for receiving the delivery robots (50).

7. The vehicle (1) according to any of claims 1 to 6, comprising a device (22) for automatically loading and/or unloading the delivery robots (50) into/from the loading space (10).

8. The vehicle (1) according to any of claims 1 to 7, comprising a warning device with which an acoustic and/or optical warning signal for an environment of the vehicle (1) can be output before the start and/or during a loading and/or unloading process of the loading space (10).

9. A method for delivering parcels with a vehicle (1), in particular according to one of claims 1 to 8, to a plurality of locally distributed recipients in an environment of a location 02, wherein the delivery robots (50) are each adapted to receive a freight and autonomously transport it from the location 02 to a predetermined delivery address, deliver the freight and autonomously return to the location 02 to autonomously enter the hold (10) of the vehicle (1), comprising the following steps:

- Loading (SI) a number of m delivery robots (50) with one freight each,

- Providing (S2) the vehicle (1) and the delivery robot (50) loaded with the freight at a location 01,

- Automated loading (S3) of the loading space of the vehicle (1) with the m delivery robots (50) loaded with freight at location 01,

- Driving (S4) the vehicle (1) from location 01 to a location 02,

- Automated unloading (S5) of at least one of the delivery robots (50), each loaded with a freight, at location 02, wherein this delivery robot (50) then autonomously transports the freight from location 02 to a predetermined delivery address, delivers the freight and autonomously returns to location 02,

- Autonomous loading (S6) of this delivery robot (50) into the loading space (10) of the vehicle (1).

10. A method for picking up a number η < N of delivery robots (50) in a loading space (10) of a vehicle (1), in particular according to one of the claims 1 to 8, wherein N is the number of maximum delivery robots (50) which can be picked up in the loading space (10) and n is the number of delivery robots (50) currently located in the loading space (10):

- automatic individual fixing of N delivery robots (50) in the hold (10) by means of a fixing device (12),

- communicating of vehicle (1) with said n delivery robots (50) through a communication interface (14); and

- individual automatic charging of energy stores of the n delivery robots (50) in the hold (10) by a number N of charging interfaces (16).

11. The method according to claim 10, wherein the communication interface (14) communicates at least one of the following states of a respective one of the n delivery robots (50) to the vehicle (1):

- Loading condition of the respective delivery robot (50),

- Type of loading of the respective delivery robot (50),

- Position of the respective delivery robot (50),

- Delivery address reached,

- Available operating energy of the respective delivery robot (50),

- Error messages and/or wherein the communication interface (14) communicates at least one of the following information from the vehicle (1) to one or more or all of the n delivery robots (50):

- Start signal for autonomous unloading of the respective delivery robot (50),

- Delivery address to be driven to by the respective delivery robot (50),

- Type of transfer,

- Parking position in vehicle (1) reached,

- Start charging with electrical energy.

12. The method according to any of the claims 10 to 11, comprising a device (20) for detecting and providing at least one of the following states in the vehicle (1):

- Loading the vehicle (1) with delivery robots (50),

- Unloading the delivery robots (50) from the vehicle (1),

- Number n of delivery robots already loaded (50) in the vehicle (1),

- Number F = N - n of the free receiving places for delivery robots (50) in the vehicle (1),

- Information on a route to be taken by the vehicle (1),

- Information about a target position to be driven to by the vehicle (1),

- Error messages.

13. The method according to any one of the claims 10 to 12,

Wherein the fixing device (12) comprises one or more inflatable units which serve to fix the delivery robots (50) and/or the loading space (10) of the vehicle (1) having different levels for receiving the delivery robots (50).

14. The method according to any of the claims 10 to 13, comprising a device (22) for automatically loading and/or unloading the delivery robots (50) into/from the loading space (10) and/or with a warning device with which an acoustic and/or optical warning signal for an environment of the vehicle (1) can be emitted before and/or during a loading and/or unloading process of the loading space (10).

15. A system for delivering parcels to a plurality of locally distributed recipients comprising at least one vehicle (1) according to any one of claims 1 to 8, and several delivery robots (50), each of which is configured to:

- receive a freight,

- automatically enter and leave the loading space (10) of the vehicle (1), and

- after leaving the loading space (10) to autonomously navigate to a predetermined delivery address, deliver the freight, autonomously return to the vehicle (1) and autonomously return to the loading space (10).