EP3511287A1 - Method for exchanging information between industrial trucks and intralogistics system with corresponding industrial trucks - Google Patents

Abstract

The invention relates to a method for operating semi-automated or automated industrial trucks (11, 12) and an intralogistics system comprising at least two semi-automated or automated industrial trucks (11, 12). It is proposed that at least two industrial trucks (11, 12) exchange information via a wireless data link.

Description

The invention relates to a method for operating semi-automated or automated industrial trucks and an intralogistics system comprising at least two semi-automated or automated industrial trucks.

Industrial trucks are used, for example, for order picking, that is, for putting together goods in a warehouse. For this purpose, very often picking trucks are used as a form of material handling equipment. In this case, the order-picking trucks are moved with a load carrier on load carriers, such as a pallet or a wire mesh basket, through the aisles of a warehouse in which the goods to be picked or picked up are stored. Depending on the order, the picker or executive removes the goods located on the shelf, places them on or in the load carrier of the picking truck and then has to drive to the next pickup location within the goods warehouse or the racking of the goods warehouse for the next goods. When the respective order for picking has been completely processed, the order picker moves to a goods delivery with the order picking conveyor. The routes from one location to the next are in the great majority short to very short straight sections within a shelf aisle or along a shelf in the warehouse. In the sum, however, due to the large number of required travel movements of the industrial truck, which must be made by the order picker, a considerable amount of time, since the order picker has to go to a control station of the picking truck to operate the corresponding drive switch and the vehicle in the driving movement control, and then back to the position for picking up the goods.

There are therefore known methods and trucks for semi-automated order picking. This semi-automated picking is done in principle similar, only the order picker has the truck at least no longer guide the straight routes along a shelf, but the truck moves automatically, so that the order picker can leave the picking truck in the aisle aisle. The control of the truck while driving to the next receiving station can be done for example by a radio remote control, such as a wireless glove with a radio remote control function, or by controlling the truck via voice commands or by a visual identity.

For example, a solution with a wireless glove is known, which attracts the picking person and through which the control of the truck is made possible. It can be integrated as a command button in the glove individual functions such as "forward", "back", etc., which can be pressed by the picking person or the order picker. After picking up a certain product at a pickup location, thus after picking, for example, the "before" command key on the glove can be pressed by the order picker and the truck continues to move in the aisle as long as the order picker presses the command key on the glove holds. Due to the integration of the radio command transmitter in the glove, it does not have to be worn as a separate object by the order picker and does not disturb the latter in its freedom of movement.

A disadvantage of this prior art, however, is that the use of such a glove by a plurality of persons can lead to acceptance problems. Also every time an operation with the other hand must be done. The wireless gloves have the further disadvantage that they wear out through daily handling and thus need to be replaced regularly. This causes additional, ongoing costs.

In the case of the system described above, there is also the fundamental necessity for the employees carrying out the order picking to be trained and instructed in the system.

From the EP 2 533 119 A1 a device for radio remote control of a truck with a wireless glove is known, which can be used for picking.

In the EP 2 851 331 B1 a method for controlling a picking truck is described in which a visual recognition of persons by means of laser scanner. If the order picker exceeds a virtual threshold in the direction of travel, the vehicle automatically follows the order picker and follows it. If the order picker stops, the vehicle also stops.

All semi-automated or automated industrial trucks have an environmental sensing system, e.g. a 2D or 3D laser scanner, a mono or stereo camera, or a 3D ToF (time of flight) camera, and at least one data processing unit for evaluating the sensor data. Depending on the capability of the truck, the sensor data are used for tasks in localization, navigation, load handling or other interaction with the environment.

In the simplest case, the truck keeps at least independently in the aisle, it is oriented to the environment. A laser scanner is usually used for this case, with which the contour of the aisle can be detected and tracked with the truck.

The environment perception is limited, e.g. by the range of the sensors, shading of the detection area by the truck itself or by other objects around the truck (e.g. goods, racks, other vehicles, people, etc.).

Another disadvantage is that each truck evaluates only its own sensor data and the vehicle's own state and used to cope with their own task.

The present invention has for its object to provide a method of the type mentioned above and an intralogistics system in such a way that when operating with multiple trucks a vote of the individual trucks is enabled to each other.

According to the invention, this object is achieved in that at least two forklifts exchange information via a wireless data connection.

Since all semi-automated and automated trucks have data processing equipment, the information exchange can be done easily between the respective data processing equipment. For this purpose, the data processing units must be provided only with data transmission and data reception equipment. In this way, the respective industrial truck can share its available data, in particular sensor data and / or vehicle condition data, beyond its own system boundary with other industrial trucks so that they can use the data from other industrial trucks for their own orders.

Expediently, a radio connection, in particular a WLAN (Wireless Local Area Network) connection or Bluetooth connection (data transmission between devices over a short distance by radio technology) or mobile radio connection, is used as the data connection. In this case, the data connection is constructed in an advantageous embodiment decentralized from truck to truck. In another preferred embodiment, the data connection is centrally via at least one central communication beacon (transmit and receive beacon), in particular a router (a network device that can forward network packets between multiple computer networks) or repeaters (signal amplifier or conditioner to increase the Range of a signal) or server (computer to provide computer functionality for accessing other computers or programs).

The trucks can exchange different information. Preferably, sensor raw data from sensors of the industrial trucks are used as information. These may be, for example, measuring points in a coordinate system. If several industrial trucks with identically constructed or compatible sensors and data processing equipment are used for sensor data evaluation, the sensor raw data can be taken over and processed directly by the other industrial truck.

A further embodiment provides that sensor data of sensors of the industrial trucks are used as information in data processing devices of the industrial trucks. This may be e.g. act around bounding spaces, features, vehicle or object positions. Raw data processing in the data processing device of the receiving industrial truck is therefore no longer necessary.

In a particularly advantageous application of the invention, in a common traffic jam situation of the industrial trucks, at least one truck following behind accesses the sensor data of at least one preceding industrial truck. The received sensor data can be processed in the same way as on-board sensor data. The truck traveling behind can thus relate the received sensor data to its own vehicle position. The sensor data received by the at least one trailing truck are thus treated exactly as if they had been acquired with the own sensor system.

A development of the invention provides that the sensor data received from the preceding truck are fused with the vehicle's sensor data, whereby the sensor detection range is expanded. The trailing forklift can therefore by means of the sensors of other trucks beyond the own detection area, e.g. Even beyond obstacles or other industrial trucks, perceive a larger environment than would be possible only with their own sensors.

It is also possible to use vehicle status information as information. In this way, e.g. Critical driving conditions of preceding material handling vehicles are recognized early on by subsequent industrial trucks and taken into account for their own driving behavior.

Data on the order status of the trucks can also be used as information. As a result, orders can be meaningfully coordinated.

A further development of the invention provides that the information used is navigation data for the current position of the industrial trucks. This is special during the commissioning of automated or semi-automated forklifts of advantage. Automated or semi-automatic forklift trucks that are switched on again do not yet know their current position in the warehouse. If such an industrial truck is detected and located by an already active industrial truck, the active industrial truck can communicate its position to the newly switched-on industrial truck. As a result, orders from the newly switched-on truck can be accepted immediately.

The invention further relates to an intralogistics system comprising at least two semi-automated or automated industrial trucks.

In such a system, the object is achieved in that the trucks are equipped with such a set data processing facilities and data transmission and data reception equipment that a method according to any one of claims 1 to 11 can be executed.

The invention offers numerous advantages:
A vehicle-to-vehicle communication with a data exchange between a plurality of automated or semi-automated industrial trucks is achieved.

The exchange of sensor data and optionally extracted therefrom functional features and / or vehicle states allows a forward-looking vehicle / driving behavior of one or more industrial trucks. An intelligent interaction of the industrial trucks with each other is possible without explicit intervention by a human or a higher-level system. Sensor data, environmental information, such as obstacles, traverses, vehicle positions can be exchanged for newly connected forklifts. In addition, recognized objects and paths (eg traverse paths) can be confirmed. Autonomous vehicles can exchange orders with each other if due to circumstances (eg battery status, local proximity, vehicle characteristics) a more effective order processing by another truck is possible. In addition, the autonomous vehicles can implement a self-organized traffic control.

Figur 1

ein Flurförderzeug mit Packstücken auf der Lastaufnahmeeinrichtung in der Draufsicht und

Figur 2

zwei hintereinanderfahrende Flurförderzeuge in der Draufsicht.

Further advantages and details of the invention will be explained in more detail with reference to the embodiments illustrated in the schematic figures. Show here

FIG. 1

an industrial truck with packages on the load receiving device in plan view and

FIG. 2

two consecutive forklifts in the plan view.

In the FIG. 1 is a designed as a picking 1 truck 1 with a designed as a load fork 2 lifting device 2 shown in plan view. On the forks 2 are one or more consecutively arranged pallets 3. On the pallets 3 are two packages 4 and 5. The automated or semi-automatic picking 1 has not shown sensors for environmental detection or environment perception, such as a 2D or 3D laser scanner , a mono or stereo camera, or a 3D ToF (time of flight) camera, and has a data transmitting and receiving device 6, via which a data exchange with other industrial trucks is made possible.

The FIG. 2 shows two consecutive forklift trucks 11 and 12 of the FIG. 1 in a common traffic jam situation. The industrial trucks 11 and 12 are located in a rack aisle between shelves 13. The trained as a laser scanner sensors of industrial trucks 11 and 12 have detection areas 14 and 15. The sensors detect measurement data 16 and can be oriented in space. The operator 17 of the rear truck 11 is located in the detection area 15 of the front truck 12. The rear truck 11 can access the sensor data of the front truck 12 and relate the information to its own vehicle position. The sensor data emitted by the front industrial truck 12 and received by the rear industrial truck 11 can be processed by the rear industrial truck 11 as if it had been acquired with its own sensors. Thus, the rear truck 11 also recognizes the operator 17, which is located in front of the front truck 12 and is actually outside the detection range of the sensor of the rear truck 11.

Claims (12)

Method for operating semi-automated or automated industrial trucks, characterized in that at least two industrial trucks (11, 12) exchange information via a wireless data connection. Method according to Claim 1, characterized in that a radio connection, in particular a WLAN connection or Bluetooth connection or mobile radio connection, is used as the data connection. A method according to claim 1 or 2, characterized in that the data connection is constructed decentralized from truck (11, 12) to truck (11,12). Method according to one of claims 1 to 3, characterized in that the data connection is established centrally via at least one central communication beacon, in particular a router or repeater or server. Method according to one of claims 1 to 4, characterized in that as raw sensor information data from sensors of the trucks (11, 12) are used. Method according to one of Claims 1 to 5, characterized in that sensor data of sensors of the industrial trucks (11, 12) prepared as information in data processing devices of the industrial trucks (11, 12) are used. A method according to claim 5 or 6, characterized in that in a common congestion situation of the trucks (11, 12) at least one hinterherfahrendes truck (11) accesses the sensor data of at least one preceding truck (12) and processes the received sensor data as in-vehicle sensor data. A method according to claim 7, characterized in that the data received from the preceding truck (12) sensor data are fused with the vehicle's sensor data, whereby the sensor detection area is extended. Method according to one of claims 1 to 8, characterized in that are used as information data on the vehicle status. Method according to one of claims 1 to 9, characterized in that as information information on the order status of the trucks (11, 12) are used. Method according to one of claims 1 to 10, characterized in that are used as information navigation data for the current position of the trucks (11, 12). Intralogistics system comprising at least two semi-automated or automated industrial trucks, characterized in that the material handling equipment (11, 12) are equipped with such data processing equipment and data transmission and data receiving equipment (6) that a method according to one of claims 1 to 11 can be executed ,

Images