WO2020001883A1 - System and method for determining the orientation of a target object in relation to a vehicle - Google Patents

Abstract

The invention relates to a system for determining the orientation of a target object (2) in relation to a vehicle (1) at least during a process in which the target object is received by the vehicle (1), which system comprises a number of sensors (3, 4, 5, 6), each of which can be attached to the vehicle (1) at a predefined position in such a way that a predefined interaction between guiding elements (13, 14, 15, 16) of the vehicle (1) and guiding elements (17, 18) of the target object (2) can be sensed selectively for each of the predefined positions, an output signal thus being output. Furthermore, a signal-processing device (30) is provided, which is designed to generate an orientation signal on the basis of the output signals supplied by the sensors (3, 4, 5, 6), which orientation signal comprises information regarding the orientation of the target object (2) in relation to the vehicle (1).

Description

 System and method for determining alignment

 of a target object in relation to a vehicle

Technical field

The present invention relates to a system and a method for determining an orientation of a target object in relation to a vehicle, and to a vehicle with such a system. In particular, the invention relates to a system and a method for supporting a recording process of a target object, in particular a swap body, by a vehicle.

State of the art

In connection with vehicles which are intended to accommodate interchangeable load carriers, also known as swap bodies, systems for supporting the engagement process of the vehicle under the swap body are already known from the prior art. For example, document DE 10 2006 057 610 A1 discloses a system in which the engagement process of a vehicle under a swap body is supported by image-based sensors. With this system, distance information between the vehicle and swap body can be determined and can thus be appropriately intervened in the single-track process.

Presentation of the invention

According to the invention, a system is provided for determining an orientation of a target object in relation to a vehicle. The system can be provided for determining the orientation of a target object in relation to a vehicle during a recording process of the target object by the vehicle. The system has a number of sensors, each of which can be attached to a predetermined position on the vehicle in such a way that a predetermined interaction between guiding elements of the vehicle and guiding elements of the target object can be detected selectively for each of the predetermined positions by emitting an output signal. Furthermore, a signal processing device is provided in the system with which each of the sensors can be connected to supply their output signals. The signal processing device is set up to generate an alignment signal based on the output signals supplied by the sensors, which includes information on the alignment of the target object in relation to the vehicle.

The sensors can comprise at least a first pair of sensors and a second pair of sensors and can be mounted on the vehicle in such a way that the sensors of the first pair of sensors are spaced apart from one another in the transverse direction with respect to a longitudinal direction of the vehicle, and the sensors of the second pair of sensors are spaced apart in the transverse direction and the first pair of sensors is spaced apart from one another by the second pair of sensors in the longitudinal direction of the vehicle. It should be noted that the number of sensors is not limited to the number given above. Rather, further sensors or sensor pairs can be provided.

The system can include a single-track sensor which can be mounted on the vehicle in order to detect a relative position between the vehicle and the target object in the longitudinal direction of the vehicle and can be connected to the signal processing device. The signal processing device can be set up to take into account the relative position detected by the single-track sensor when generating the output signal.

The predetermined interaction described above may include contact between one or more of the guide elements of the vehicle and one or more of the guide elements of the target object during the acquisition process. The sensors can each be designed as structure-borne noise sensors and can be mounted in the area of the guide elements of the vehicle. Furthermore, the area of the guide elements on which the sensors designed as structure-borne noise sensors can be mounted can be selected such that structure-borne noise generated by the interaction can be detected by the corresponding sensor and the interaction can be assigned to that of the guide elements of the vehicle. in the area of which the sensor is mounted.

The predetermined interaction may be an approximation of one or more of the guiding elements of the vehicle and one or more of the guiding elements. te of the target object during the recording process. The sensors can each be designed as a proximity sensor and can be mounted in the area of the guide elements of the vehicle or on the guide elements of the vehicle. Furthermore, the proximity sensor can detect a dynamic approach between the guide elements of the vehicle and the guide elements of the target object. It is also possible to determine the distance between the guide elements of the vehicle and the guide elements of the target object.

The predetermined interaction may include a force between one or more of the guide elements of the vehicle and one or more of the guide elements of the target object during the recording process. The sensors can each be designed as a force measuring sensor and can be mounted on the guide elements of the vehicle. In this way, a force effect from one or more of the guide elements of the target object on one or more of the guide elements of the vehicle can be detected during the recording process.

Each of the sensors can be configured to quantitatively measure the extent of the predetermined interaction and to output an output signal which indicates the extent of the predetermined interaction. All of the above-mentioned variants of the sensors can be used for this as long as there is the possibility of generating a quantitative signal due to the interaction.

Each of the sensors can be configured to emit a qualitative output signal upon detection of an extent of the predetermined interaction that exceeds a predetermined threshold value, which indicates that the predetermined one

Threshold is exceeded. This further simplifies the system since the sensors each emit the occurrence of an event in connection with the predetermined interaction. For this purpose, a means can be provided for each sensor in order to generate a corresponding signal when the predetermined threshold value is exceeded. It is also possible to make the threshold value adjustable. The invention further relates to a vehicle for receiving a target object. In this case, the vehicle can have a frame on which guide elements are provided, which are used to engage between guide elements provided on the target object. elements are designed. The vehicle may further include a system with one or more features of the system described above.

The vehicle can have a control device for autonomous operation. The control device can enable an autonomous mode of operation at least while the target object is being recorded. The control device for autonomous operation can be supplied with the output signal of the signal processing device.

The control device for autonomous operation and the signal processing device can be designed as separate units. Means can be provided that enable communication between the control device and the signal processing device. However, it is also possible to integrate the control device for autonomous operation and the signal processing device with one another. It is also possible to integrate the signal processing device and the control device for autonomous operation into a higher-level control system which is set up for controlling the vehicle.

The vehicle can be designed to accommodate a swap body as a target object. In this case, guide elements are provided on the swap body, into which the guide elements of the vehicle can engage during the recording process.

A method is also provided for determining an orientation of a target object in relation to a vehicle during a recording process of the target object by the vehicle. The method may be performed on a vehicle that has one or more of the features of the vehicle described above. If the target object is designed as a swap body, the recording process includes an engagement of the vehicle under the swap body. In addition, the method is not limited to the recording process, but the method can also be applied to a depositing process of the target object. The vehicle is removed from the target object during the drop-off process. In particular, when a swap body is used as the target object, the vehicle is moved out of the swap body.

The method can have the following steps: Detection of interactions between guide elements of the vehicle and guide elements of the target object during the recording process by means of a number of sensors,

 Evaluating the detected interactions in a signal processing device, taking into account the position at which the respective interaction is recorded,

 - Outputting an alignment signal, which includes information on the alignment of the target object in relation to the vehicle, on the basis of the evaluation of the detected interaction.

The method can further comprise the step of detecting a relative position between the vehicle and the target object in the longitudinal direction of the vehicle. In the step of evaluating the detected interaction, the detected relative position between the vehicle and the target object in the longitudinal direction of the vehicle can also be taken into account. This consideration can be made by means of an output signal which is emitted by the single-track sensor, which can be mounted on the vehicle.

The method may include the step of detecting a relative position between the vehicle and the target object in the longitudinal direction of the vehicle to determine whether

 - the vehicle is outside the target object,

 the vehicle is partially under the target object so that two of the guide elements of the vehicle are positioned under the target object, and

 - The vehicle is completely under the target object, so that four of the guide elements of the vehicle are positioned under the target object.

With this step, the basis for the detection of the orientation of the vehicle to the target object can be created, so that conclusions about the relative position based on the output signals of the sensors are made possible.

The method can further comprise the following step

- Detect whether the vehicle is partially under the target object, and - If an interaction with one of the guide elements of the target object is detected on one of the two guide elements of the vehicle, which is positioned under the target object, a lateral offset of the vehicle with respect to the target object is determined in the direction of that guide element of the vehicle on which an interaction with one of the guide elements of the target object is detected.

In the state in which the vehicle is partially below the target object, a lateral offset of the vehicle can thus be detected using the sensor pair positioned under the target object.

The method can further comprise the following step:

 - Detect whether the vehicle is completely under the target object, and

if, on two of the guide elements of the vehicle, which are positioned below the target object and which are arranged on the same side of the vehicle, an interaction is detected on one of the guide elements of the target object, a lateral offset of the vehicle with respect to the target object is determined, and wherein

 - If an interaction on the guide elements of the target object is detected on two of the guide elements of the vehicle, which are positioned below the target object and which are arranged at diagonally opposite positions of the vehicle, a rotation of the vehicle with respect to the target object is determined.

Brief description of the drawings

1 shows a vehicle and a swap body to which an embodiment of the invention is applicable;

2 shows a schematic top view of an arrangement of sensors on a vehicle to which an embodiment of the invention is applicable; Fig. 3 shows a lower portion of a swap body to which an embodiment of the invention is applicable;

4 shows a schematic illustration of the arrangement of sensors on a vehicle according to one embodiment;

5 shows various positions of the vehicle relative to the swap body to explain the concept of the invention;

6 schematically shows various situations which are possible during the detection of interactions with a partially engaged vehicle;

FIG. 7 schematically shows various situations that are possible during the detection of interactions when the vehicle is fully engaged.

Description of the embodiments

In the following, embodiments of the present invention are described with reference to the drawings.

1 shows a vehicle 1 which is suitable for receiving a target object, the target object being designed as a swap body in this embodiment. 1 also shows an example swap body 2 that can be picked up by the vehicle 1. The swap body 2 is designed to accommodate cargo. For this purpose, a case 22 is provided on the swap body 2 for receiving the load. The vehicle 1 has a driver's cab 12 at the front section and a frame 19 at the rear section. In the illustration, the vehicle 1 is shown with a front axle and two rear axles, but different arrangements with more or fewer axles are conceivable.

1, the swap body 2 is placed on support elements 21 in the longitudinal direction behind the vehicle 1. In the configuration shown in FIG. 1, the vehicle 1 is prepared for receiving the swap body 2. Recording the Swap body 2 is carried out by moving vehicle 1 under swap body 2.

2 shows the arrangement of guide elements in a schematic plan view

13, 14, 15, 16 shown on the frame 19 of the vehicle 1. In particular, guide elements 13, 14 are attached to a rear section of the frame 19 of the vehicle 1 and are spaced apart from one another in the transverse direction of the vehicle 1. On the front area of the frame 19 of the vehicle 1, guide elements 15, 16 are shown, which are also spaced apart in the transverse direction of the vehicle 1. The guide elements 13, 14, which are mounted on the rear region of the frame 19, form a first pair of guide elements. The guide elements 15, 16, which are attached to the front region of the frame 19, form a second pair of guide elements. The first pair of guide elements 13, 14 are spaced longitudinally from the second pair of guide elements 15, 16. In the present exemplary embodiment, four guide elements 13, 14, 15, 16 are thus provided on the frame 19, which are each mounted at four corners of an imaginary rectangle.

The vehicle 1 shown in FIG. 2 also has a number of sensors 3, 4, 5, 6. Each of the sensors 3, 4, 5, 6 is one of the guide elements 13 shown in FIG. 2,

14, 15, 16 assigned. In particular, sensor 3 is assigned to guide element 13, sensor 4 is assigned to guide element 14, sensor 5 is assigned to guide element 15, and sensor 6 is assigned to guide element 16.

In the present exemplary embodiment, the guide elements 13, 14, 15, 16 are designed as single-track rollers, which are mounted on the frame 19 of the vehicle 1 so as to be rotatable about an axis, which is oriented essentially vertically or upwards. The engagement rollers in the present exemplary embodiment are also designed with a conical shape, so that the diameter of each of the engagement rollers is larger in the lower region than in the upper region.

One of the sensors 3, 4, 5, 6 is mounted in the area of each of the engagement rollers 13, 14, 15, 16. In the present exemplary embodiment, each of the sensors 3, 4, 5, 6 is as Structure-borne noise sensor executed. In particular, each of the sensors 3, 4, 5, 6 can be designed as a piezo element-based sensor which is fixedly mounted on the frame 19 of the vehicle 1 in the region of each of the engagement rollers 13, 14, 15, 16. The attachment of sensors 3, 4, 5, 6 is carried out in such a way that structure-borne noise generated in the area of the single-track rollers is detected by the corresponding sensor and an output signal of the sensor can be assigned to the respective single-track roller.

The function of the guide elements 13, 14, 15, 16 of the vehicle 1 designed as single-track rollers will be described with reference to FIG. 3. In the view shown in FIG. 3, a single-track channel is provided on an underside 23 of the swap body 2, which is delimited by laterally spaced guide elements 17, 18. The guide elements 17, 18 are designed as guide rails which extend in the longitudinal direction of the swap body 2 and are fixedly mounted on the underside 23 of the swap body.

3, four support elements 21 are provided on the swap body 2, which are suitable for supporting the swap body 2. The support elements 21 are locked relative to the swap body 2 in the situation shown in FIG. 3 and can be unlocked and pivoted upwards if necessary, in particular after the swap body 2 has been received by the vehicle 1. In addition, it can be provided that the support elements 21 are designed to be adjustable in the transverse direction to the swap body 2 in order to improve the safety against tipping of the swap body 2.

Referring back to the illustration in FIG. 1, the basic sequence of the engagement of the vehicle 1 under the swap body 2 is described. As a starting point, the vehicle 1 is moved in the longitudinal direction in front of the swap body 2. Make sure that the vehicle 1 and swap body 2 are aligned as precisely as possible in the longitudinal direction. To accommodate the swap body 2, the vehicle 1 must then be driven under the swap body 2. In this process, the first pair of guide elements 13, 14 is first inserted into the single-track tunnel, which is formed from the guide elements 17, 18 of the swap body 2. With optimal alignment between vehicle 1 and swap body 2, the guide elements 13, 14 on the rear section of the frame 19, the inner surfaces of the guide elements 17, 18 of the swap body 2 are not. When the vehicle 1 continues to enter under the swap body 2, the second pair of guide elements 15, 16 enter the single-track tunnel of the swap body 2. With an optimal course, none of the guide elements 13, 14, 15, 16 of the vehicle 1 touches the guide elements 17, 18 of the swap body second

In normal operation, however, deviations with regard to the alignment between vehicle 1 and swap body 2 cannot be ruled out and rather the normal case. There is therefore the possibility that during the engagement process of the guide elements 13, 14, 15, 16 of the vehicle 1 into the engagement tunnel of the swap body 2, one or more of the guide elements of the vehicle 1 touch the guide elements 17, 18 of the swap body 2. With such a contact, in the present embodiment, structure-borne noise is generated in the region of the frame 19 on which the corresponding guide element of the vehicle 1 is mounted by the contact of the corresponding guide element of the vehicle 1 and one of the guide elements of the swap body 2.

The present invention is based on the approach of detecting interactions between the guide elements of the vehicle 1 and the guide elements of the swap body 2 and determining the relative orientation between the vehicle 1 and the swap body 2 from the detected interactions. For this purpose, a signal evaluation device 30 is provided in the vehicle 1, which is connected to the sensors 3, 4, 5, 6 mounted on the vehicle 1 and receives output signals from these. The signal evaluation device 30 is provided with means to generate an alignment signal from the detected interactions, which can be used to infer the alignment of the vehicle 1 relative to the swap body 2.

For this evaluation, it is advantageous to take into account the relative position between vehicle 1 and swap body 2 in the longitudinal direction. For this purpose, an in-line sensor 11 is provided on the front area of the frame 19 of the vehicle 1, which detects the extent to which the vehicle 1 is in under the swap body 2 can. In particular, the single-track sensor 11 can be used to measure how far the vehicle 1 has entered under the swap body 2 by means of a distance measurement.

A distinction is essentially made between three cases, which are shown in FIG. 5. 5, the vehicle 1 is still outside the swap body 2. In the illustration marked B in FIG. 5, the vehicle 1 is partially moved under the swap body 2. In particular, the guide elements 13, 14, which are mounted on the rear area of the vehicle 1, are already inside the single-track tunnel of the swap body 2, in particular between the guide elements 17, 18 of the swap body 2. In the illustration denoted by C in FIG. 5, this is Vehicle 1 is fully retracted under swap body 2 and all guide elements of vehicle 1 are engaged in the single-track tunnel of swap body 2.

Taking into account the cases discussed above in FIG. 5, the basic concept of detecting the relative position of vehicle 1 to swap body 2 is explained below on the basis of the representations in FIGS. 6 and 7.

6 shows the vehicle 1 outside the swap body 2 in the illustration of A in FIG. 5, the situation in which the guide elements 13, 14 mounted on the rear section of the vehicle 1 move into the single-track tunnel of the swap body 2 is first achieved. The following situations can arise with regard to the interaction between the guide elements of vehicle 1 and the guide elements of swap body 2:

A: The vehicle 1 is outside the swap body 2 and none of the sensors 3, 4, 5, 6 detects an interaction.

B1: The vehicle 1 has partially entered the swap body 2 and none of the sensors 3, 4, 5, 6 detects an interaction. In this situation, it is determined that there is no lateral offset between vehicle 1 and swap body 2. B2: The vehicle has partially moved under the swap body 2 and the rear right sensor 3 detects an interaction, while the other sensors 4, 5, 6 do not detect any interaction. In this situation, a lateral offset of the vehicle 1 relative to the swap body 2 to the right is determined.

B3: The vehicle 1 has partially moved under the swap body 2 and the rear left sensor 4 detects an interaction. In this situation, it is determined that there is a lateral displacement of the vehicle 1 relative to the swap body 2 to the left.

Thus, with the vehicle 1 partially retracted, information about the orientation of the vehicle 1 relative to the swap body 2 can be provided. It should be taken into account that in cases B1, B2 and B3 only the two sensors 3, 4 are available for the detection.

When vehicle 1 continues to enter under swap body 2, all sensors 3, 4, 5, 6 are finally located within the single-track tunnel, which is formed from guide elements 17, 18 of swap body 2. The following situations can arise in this state:

C1: None of the sensors 3, 4, 5, 6 detects an interaction when the vehicle 1 is completely retracted. From this it can be deduced that the vehicle 1 was positioned under the swap body 2 without lateral displacement and without twisting.

C2: When the vehicle is completely retracted, the two right sensors 3, 5 detect an interaction, while the two left sensors 4, 6 detect no interaction. From this it can be deduced that the vehicle 1 is positioned with a lateral offset to the right side relative to the swap body 2.

C3: When the vehicle is completely retracted, the two left sensors 4, 6 detect an interaction, while the two right sensors 3, 5 do not detect any interaction. From this it can be deduced that the vehicle 1 is positioned with a lateral offset to the left side relative to the swap body 2. C4: When the vehicle 1 is completely retracted, the rear right sensor 3 and the front left sensor 6 detect an interaction, while the rear left sensor 4 and the front right sensor 5 detect no interaction. From this it can be deduced that the vehicle 1 is positioned rotated counterclockwise relative to the swap body 2.

C5: When the vehicle 1 is completely retracted, the rear left sensor 4 and the front right sensor 5 detect an interaction, while the rear right sensor 3 and the front left sensor 6 detect no interaction. From this it can be deduced that the vehicle 1 is positioned rotated clockwise relative to the swap body 2.

In addition, it is also possible for only one of the sensors 3, 4, 5, 6 to detect an interaction when the vehicle 1 is completely retracted. It can be deduced from this that there is a lateral offset between vehicle 1 and swap body 2 at the corresponding position at which the interaction is recorded.

With the aid of the signals emitted by sensors 3, 4, 5, 6 and single-track sensor 11, which are introduced into signal evaluation device 30, geometric assumptions about vehicle 1 and swap body 2 can be used to determine the relative orientation of vehicle 1 to swap body 2 can be inferred during the single-track process. In this context, the signal processing device 30 forms an alignment signal that contains information regarding the alignment of the vehicle 1 with the swap body 2.

The geometric information about the vehicle 1 includes dimensions between the guide elements 13, 14, 15, 16 in the lateral and longitudinal directions of the vehicle 1. Furthermore, the geometric information includes information on wheelbases, track gauges, etc., which can be advantageous for determining precise results. A diagram with exemplary dimensions of the vehicle 1 is shown in FIG. 4. 4 shows some of the dimensions of the vehicle 1. The center line of the vehicle 1 is designated by M. The distance between the outwardly facing regions of the guide elements 13, 15 on the right side with respect to the center line M are denoted by R and the distance between the outwardly facing regions of the guide elements 14, 16 on the left side with respect to the center line M is denoted by L. The wheelbase R can also be seen from the figure.

In the present embodiment, the alignment signal generated by the signal processing device 30 is made visible to the driver of the vehicle 1 using a display device (not shown). Thus, the driver can receive information under a swap body 2 when the vehicle 1 is engaged, whether and how the route of the vehicle 1 must be corrected during the engagement process.

In an alternative embodiment, the alignment signal is made available to a control device which enables autonomous operation at least for the pick-up process of swap bodies 2. As a result, the autonomous operation can be significantly optimized since, in addition to position information, for example based on GPS data, relevant interactions between elements of the vehicle 1 and the swap body 2 also flow into the control for the autonomous operation.

In the above-mentioned embodiments, 1-track rollers are mentioned as guide elements of the vehicle. However, the guide elements can also be designed as single-track plates or the like, as long as the interaction between the guide elements of the vehicle and the guide elements of the swap body 2 can be detected by sensors.

Furthermore, it was assumed in the above-mentioned embodiments that the sensors are designed as structure-borne noise sensors. However, it is also possible to use other sensors, such as proximity sensors or force measuring sensors. In particular, it is possible not only to detect the contact between the guide elements as an interaction, but also to take into account an approach or a force effect between the guide elements of the vehicle and the guide elements of the swap body.

In the event that truncated cone-shaped rollers are used as guide elements of the vehicle 1, at least in sections, the distance between the Single-track rollers and the guide rails of the swap body depending on a level difference between single-track rollers and guide rails. When using a vehicle with level control, in which the level of single-track rollers can be adjusted with respect to a road surface, a corresponding signal from a sensor provided for this purpose can be available. Therefore, in a modified embodiment, the signal processing device 30 is additionally supplied with a signal that detects the level of single-track rollers with respect to the road surface. This signal is taken into account for the generation of the alignment signal.

In a further modified embodiment, guide plates are used as guide elements 13, 14, 15, 16 instead of the single-track rollers, which are mounted stationary on the vehicle 1 at predetermined positions. In this embodiment, the interaction consists in a contact between the guide plates and the guide elements 17, 18 of the swap body 2. In one embodiment, the guide plates are inclined to the vertical direction to the central axis of the vehicle, so that the distance between the outer surfaces of the vehicle varies in the vertical direction Guide plates results.

reference numeral

vehicle

 Swap body (target object)

, 4, 5, 6 sensor

0 signal evaluation device 1 single-track sensor

2 cab

3, 14, 15, 16 guide element of the vehicle 7, 18 guide element of the swap body 9 frame

1 support element

2 suitcases

3 underside of the swap body

0 control device

Claims

claims

1 . System for determining an orientation of a target object (2) in relation to a vehicle (1) during a recording process of the target object by the vehicle (1), characterized in that the system has a number of sensors (3, 4, 5, 6), Each of which can be attached to the vehicle (1) at a predetermined position such that a predetermined interaction between guide elements (13, 14, 15, 16) of the vehicle (1) and guide elements (17, 18) of the target object (2) is selective for each of the predetermined positions can be detected by emitting an output signal, and has a signal processing device (30) with which each of the sensors (3, 4, 5,

6) can be connected to feed their output signals, the signal processing device (30) being set up to generate an alignment signal on the basis of the output signals supplied by the sensors (3, 4, 5, 6) which contains information on the alignment of the target object (2 ) in relation to the vehicle (1).

2. System according to claim 1, characterized in that the sensors (3, 4, 5, 6) comprise at least a first pair of sensors (3, 4) and a second pair of sensors (5, 6) and can be mounted on the vehicle (1) in this way that with respect to a longitudinal direction of the vehicle (1) the sensors of the first sensor pair (3, 4) are spaced apart in the transverse direction, the sensors of the second sensor pair (5, 6) are spaced apart in the transverse direction and the first sensor pair (3, 4) is spaced apart from one another by the second pair of sensors (5, 6) in the longitudinal direction of the vehicle (1).

3. System according to any one of the preceding claims, characterized by a single-track sensor (1 1) which can be mounted on the vehicle (1) in order to detect a relative position between the vehicle (1) and the target object (2) in the longitudinal direction of the vehicle (1) and with which Signal processing device (30) can be connected, the signal processing device (30) being set up to take into account the relative position detected by the single-track sensor (11) when generating the output signal.

4. System according to any one of the preceding claims, characterized in that the predetermined interaction is a contact between one or more of the guide elements (13, 14, 15, 16) of the vehicle (1) and one or more of the guide elements (17, 18) of the Target object (2) during the recording process The sensors (3, 4, 5, 6) are each designed as structure-borne noise sensors and can be mounted in the area of the guide elements (13, 14, 15, 16) of the vehicle (1).

5. System according to any one of claims 1-3, characterized in that the predetermined interaction is an approach of one or more of the guide elements (13, 14, 15, 16) of the vehicle (1) and one or more of the guide elements (17, 18th ) of the target object (2) during the recording process, the sensors (3, 4, 5, 6) each being designed as a proximity sensor and in the area of the guide elements (13, 14, 15, 16) of the vehicle (1) or on the guide elements (13, 14, 15, 16) of the vehicle (1) can be mounted.

6. System according to any one of claims 1-3, characterized in that the predetermined interaction is a force between one or more of the guide elements (13, 14, 15, 16) of the vehicle (1) and one or more of the guide elements (17, 18th ) of the target object (2) during the recording process, the sensors (3, 4, 5, 6) each being designed as a force measuring sensor and being mountable on the guide elements (13, 14, 15, 16) of the vehicle (1).

7. System according to one of the preceding claims, characterized in that each of the sensors (3, 4, 5, 6) is set up for quantitatively detecting the extent of the predetermined interaction and for outputting an output signal which indicates the extent of the predetermined interaction.

8. System according to one of claims 1-6, characterized in that each of the sensors (3, 4, 5, 6) is set up to output a qualitative output signal upon detection of an extent of the predetermined interaction that exceeds a predetermined threshold value, that indicates that the predetermined threshold has been exceeded.

9. Vehicle (1) for receiving a target object (2), the vehicle having a frame (19) on which guide elements (13, 14, 15, 16) are provided, which are provided for engagement between the target object (2) Guide elements (17, 18) are configured, the vehicle (1) further comprising a system according to one of claims 1-8.

10. The vehicle (1) according to claim 9, characterized in that the vehicle (1) has a control device for autonomous operation, which enables an autonomous mode of operation at least during the recording of the target object (2), the control device for autonomous operation Output signal of the signal processing device (30) is supplied.

1 1. Vehicle according to one of claims 9-10, characterized in that the vehicle is designed to receive a swap body as the target object (2).

12. A method for determining an orientation of a target object (2) in relation to a vehicle (1) during a recording process of the target object by the vehicle (1) according to one of claims 9-1 1, with the following steps:

 - Detection of interactions between guide elements (13, 14, 15, 16) of the vehicle (1) and guide elements (17, 18) of the target object (2) during the recording process using a number of sensors (3, 4, 5, 6),

 - evaluating the detected interactions in a signal processing device (30) taking into account the position at which the respective interaction is recorded,

 - Outputting an alignment signal, which includes information on the alignment of the target object (2) in relation to the vehicle (1), based on the evaluation of the detected interaction.

13. The method according to claim 12, characterized by the step of detecting a relative position between the vehicle (1) and target object (2) in the longitudinal direction of the vehicle (1), wherein in the step of evaluating the detected interaction additionally the detected relative position between the vehicle (1) and target object (2) in the longitudinal direction of the vehicle (1) is taken into account.

14. The method according to any one of claims 12 or 13, characterized by the step of detecting a relative position between the vehicle (1) and target (2) in the longitudinal direction of the vehicle (1) to determine whether

 - the vehicle (1) is outside the target object (2),

 - The vehicle (1) is partially under the target object (2), so that two of the guide elements (13, 14, 15, 16) of the vehicle (1) are engaged under the target object (2), and

 - The vehicle (1) is completely under the target object (2), so that four of the guide elements (13, 14, 15, 16) of the vehicle (1) are engaged under the target object (2).

15. The method according to claim 14, characterized by the step:

 - Detect whether the vehicle (1) is partially under the target object (2), and - if on one of the two guide elements (13, 14, 15, 16) of the vehicle (1) that is engaged under the target object (2) an interaction with one of the guide elements (17, 18) of the target object (2) is detected, a lateral offset of the vehicle (1) with respect to the target object (2) in the direction of that guide element (13, 14) of the vehicle (1) is determined on which an interaction with one of the guide elements (17, 18) of the target object (2) is detected.

16. The method according to claim 14, characterized by the step:

 - Detect whether the vehicle (1) is completely the target object (2), and

 - If on two of the guide elements (13, 14, 15, 16) of the vehicle (1), which are engaged under the target object (2) and which are arranged on the same side of the vehicle (1), an interaction on one of the guide elements ( 17, 18) of the target object (2) is detected, a lateral offset of the vehicle (1) with respect to the target object (2) is determined, and wherein

 - If two of the guide elements (13, 14, 15, 16) of the vehicle (1) that are engaged under the target object (2) and that are arranged at diagonally opposite positions of the vehicle (1), an interaction on the guide elements ( 17, 18) of the target object (2) is detected, a rotation of the vehicle (1) with respect to the target object (2) is determined.