METHOD FOR CONTROLLING AN INDUSTRIAL TRUCK AS WELL AS A SYSTEM COMPRISING A SUPERORDINATE CONTROL UNIT AND AN INDUSTRIAL TRUCK

Abstract

A method for controlling at least one industrial truck comprising determining a driving job using a superordinate control unit and sending the driving job from the superordinate control unit to a transceiver of the at least one industrial truck. The driving job is transmitted from the transceiver to a vehicle controller. A position of the at least one industrial truck within a previously known route to be driven is determined via the superordinate control unit. An upcoming driving situation is identified using the superordinate control unit and is based on the position of the at least one industrial truck and the driving job. A protective field is generated with a collision protection apparatus, wherein the protective field is monitored by the at least one industrial truck based on the upcoming driving situation even before the at least one industrial truck reaches the driving situation.

Claims

1. A method for controlling at least one industrial truck, the method comprising: determining a driving job using a superordinate control unit; sending the driving job from the superordinate control unit to a transceiver of the at least one industrial truck; transmitting the driving job from the transceiver to a vehicle controller; determining via the superordinate control unit a position of the at least one industrial truck within a previously known route to be driven; identifying an upcoming driving situation using the superordinate control unit depending on the position of the at least one industrial truck and the driving job; and generating a protective field with a collision protection apparatus, wherein the protective field is monitored by the at least one industrial truck based on the upcoming driving situation even before the at least one industrial truck reaches the driving situation.

2. The method according to claim 1, wherein a control command for setting the protective field is sent to the at least one industrial truck by the superordinate control unit in response to the upcoming driving situation.

3. The method according to claim 1, wherein the at least one industrial truck is an autonomously or automatically driving industrial truck.

4. The method according to claim 2, wherein the upcoming driving situation involves driving in a curve, and wherein the protective field is already generated in a direction of the curve before the at least one industrial truck starts driving in the curve.

5. The method according to claim 2, wherein the upcoming driving situation is driving at an increased speed, and wherein the protective field is expanded to cover a larger area in front of the industrial truck before the industrial truck starts driving at an increased speed.

6. The method according to claim 1, wherein the monitored protective field continues to be monitored after the respective driving situation has passed.

7. The method according to claim 1, wherein the at least one industrial truck is a tow car of a tugger train comprising at least one trailer, and wherein the monitored protective field continues to be monitored even after the tow car leaves the respective driving situation until the at least one trailer has also left the respective driving situation.

8. The method according to claim 1, further comprising monitoring a steering angle adopted by the at least one industrial truck, wherein the at least one industrial truck is stopped if the adopted steering angle exceeds a maximum angle specified by the driving job.

9. The method according to claim 1, further comprising monitoring a steering direction adopted by the at least one industrial truck, wherein the at least one industrial truck is stopped if the monitored steering direction deviates from a steering direction specified by the driving job.

10. The method according to claim 1, further comprising monitoring a speed adopted by the at least one industrial truck, wherein the at least one industrial truck is stopped if the monitored adopted speed exceeds a maximum speed specified by the driving job.

11. The method according to claim 8, wherein the protective field is positioned depending on a discrete steering angle.

12. The method according to claim 1, wherein the superordinate control unit is a server.

13. A system for controlling at least one industrial truck comprising: a superordinate control unit configured to, determine a position of the at least one industrial truck within a driving job to be performed by the at least one industrial truck, identify an upcoming driving situation depending on the position of the industrial truck and the driving job to be performed by the industrial truck, and set a protective field monitored by the industrial truck based on the upcoming driving situation even before the industrial truck reaches the upcoming driving situation.

14. The system according to 13, wherein the at least one industrial truck is an autonomously driving industrial truck.

15. The system according to claim 13, wherein the superordinate control unit is a server.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] One exemplary embodiment of the invention is explained below using figures. In the figures:

[0021] FIG. 1 illustrates a side view of an embodiment of an industrial truck; and

[0022] FIG. 2 illustrates a top view of the industrial truck from FIG. 1 in positions 2a-2e while driving in a curve.

[0023] If not otherwise specified, the same reference numbers indicate the same objects below.

DETAILED DESCRIPTION OF THE INVENTION

[0024] FIG. 1 shows an industrial truck 10 which has a drive part 12. The industrial truck 10 is configured as a truck without a load part. The industrial truck 10 also has a schematically shown vehicle controller 16, a schematically shown transceiver 18 as well as a collision protection apparatus 20. The collision protection apparatus 20 serves to generate protective fields 22, 24 (FIG. 2 at steps 2b-2d) in the vicinity of the industrial truck for the purpose of monitoring the vicinity for obstacles, as will be explained in greater detail below. The industrial truck 10 is in contact with a schematically shown, superordinate control unit 40 via the transceiver 18. The superordinate control unit 40 can be for example a central warehouse management system. An obstacle 30, which lies in a driving direction F in front of the industrial truck 10, can also be seen in FIG. 1. If the industrial truck 10 approaches the obstacle 30, it enters the first protective field 22 lying in front of the industrial truck, whereupon the vehicle controller 16 initiates a braking action of the industrial truck.

[0025] The superordinate control unit 40 sends a driving job to the industrial truck 10, which receives it via the transceiver 18 and forwards it to the vehicle controller 16. The vehicle controller 16 controls the industrial truck 10 through a warehouse or production hall based on the driving job. The industrial truck 10 hereby negotiates several consecutive driving situations. The industrial truck 10 sends its position within the driving job, i.e. within the route to be driven based on the driving job, to the superordinate control unit 40 at regular intervals. The superordinate control unit 40 determines based on the driving job as well as the current position of the industrial truck 10 the next upcoming driving situation and sends the industrial truck 10 a control command for setting the protective field generated by the collision protection apparatus 20.

[0026] The method according to the invention is explained in detail below based on FIG. 2. Two protective fields 22 and 24 can be seen in positions 2b-2d of FIG. 2. Referring to position 2a of FIG. 2, the industrial truck 10 is driving in a straight line and only a first protective field 22 arranged in front of the industrial truck is activated. Referring to position 2b, the industrial truck 10 is approaching a left turn but is still driving in a straight line. The now upcoming driving situation consequently involves driving in a curve. The superordinate control unit 40 now sends the industrial truck 10 the command to activate the protective field for driving in a curve. The second protective field 24 is thus activated on the left side of the industrial truck 10 in the driving direction and thus monitors the following curve to be negotiated. Moreover, the first protective field 22 is enlarged in the present exemplary embodiment. Referring to position 2c, the industrial truck 10 now drives around a 90? left curve with the activated protective fields 22, 24. Referring to position 2d, the industrial truck 10 has already reached a straight line of travel again, wherein the second or lateral protective field 24 continues to remain active. The curve area can thus continue to be monitored, which makes sense in particular in the case of the presence of trailers following behind the industrial truck, which can still be driving in a curve at this point in time. Finally, at position 2e, the industrial truck is driving in a straight line at a sufficient distance from the negotiated curve, whereupon the lateral protective field 24 is deactivated. Moreover, the first protective field 22 is also reduced again here. The first protective field 22 can be enlarged in particular in that it is pushed forward in the driving direction. For example, a protective field sensor of the collision protection apparatus can be tipped for this, wherein the angle a shown in FIG. 1 is then reduced.

[0027] With the method or respectively the system according to the invention, a predictive activation or respectively adjustment of the protective fields is achieved, which leads to a particularly high collision safety as well as negotiating curves at higher speeds.

REFERENCE LIST

[0028] 10 Industrial truck [0029] 12 Drive part [0030] 16 Vehicle controller [0031] 18 Transceiver [0032] 20 Collision protection apparatus [0033] 22 First protective field [0034] 24 Second protective field [0035] 30 Obstacle [0036] 40 Superordinate control unit