A manufacturing system includes: a first tank configured to store generation fuel; a manufacturing device having a first power generation device configured to generate power using the generation fuel, the manufacturing device being configured to operate using power supplied from the first power generation device; and a transport robot configured to transport the generation fuel from the first tank to the manufacturing device.

An autonomous moving apparatus control system including a range sensor, a reflection plate, and a control unit. The range sensor is installed in a cage of an elevator and detects a distance to an object by receiving reflected light of signal light applied to the object. The reflection plate is disposed in an elevator hall of a floor on which the elevator stops, and reflects the signal light. The control unit determines whether or not a mobile robot, which is an autonomous moving apparatus, can get on and off the elevator based on a detected distance, the detected distance being a distance to the reflection plate detected by the range sensor.

According to one embodiment, a handling system includes a first mobile robot, a first transfer robot, and a picking robot. The first mobile robot transports a first container out of a loading location of the first container. An article is stored in the first container. The first transfer robot transfers the first container from one of the first mobile robot or a first loading platform to the other of the first mobile robot or the first loading platform. The picking robot moves the article from the first container placed on the first loading platform to a second container placed on a second loading platform.

A system, in particular a manufacturing system, the system including machines, especially stationary and mobile machines, and at least one vehicle and a control, the vehicle having at least one sensor for ascertaining the relative position of a person, in particular a sensor for ascertaining the distance between the vehicle and the person, and for ascertaining the angle between the driving direction of the vehicle and the connecting line between the person and the vehicle, the vehicle having a position acquisition means for sensing the position of the vehicle, in particular a GPS system or a triangulation system for ascertaining the position of the vehicle, the control including a means for ascertaining the safety zone around the person and the machines situated therein, a data transmission channel being provided between the control and the machines.

A system for performing autonomous agriculture within an agriculture production environment includes one or more agriculture pods, a stationary robot system, and one or more mobile robots. The agriculture pods include one or more plants and one or more sensor modules for monitoring the plants. The stationary robot system collects sensor data from the sensor modules, performs farming operations on the plants according to an operation schedule based on the collected sensor data, and generates a set of instruction for transporting the agriculture pods within the agriculture production environment. The stationary robot system communicates the set of instructions to the agriculture pods. The mobile robots transport the agriculture pods between the stationary robot system and one or more other locations within the agriculture production environment according to the set of instructions.

According to an embodiment, a transport control device includes a storage unit, a control unit, and a communication unit. The storage unit is configured to store positional information relating to racks included in a plurality of rack groups provided at predetermined intervals, an outer aisle around the rack groups, an under-rack aisle under each of the racks, and a rack area in which a rack retrieved from the rack groups by a transport vehicle is placed, and management information for managing the racks. The control unit is configured to output a control signal for controlling the transport vehicle based on the positional information and the management information. The communication unit is configured to transmit the control signal to the transport vehicle.

Disclosed herein is an automated conveyance robot (ACR) for conveying movable platforms (MPs) in and out of trailers. A lift carriage at a first end of the ACR is configured to couple to the MP during movement and disengage after movement. A counterweight system at a second end of the ACR counterbalances the ACR during conveyance. The ACR comprises a front drive assembly and a rear drive assembly which are independently steerable to allow for different steering methods. The ACR can function fully automated or can be controlled

A method, apparatus, and system for controlling an automated guided vehicle. An embodiment of the method comprises: receiving a fault message comprising travel state information for indicating the travel state of a faulty automated guided vehicle and position information of a fault point where a fault occurs (201); determining a fault region, and sending an instruction for indicating prohibition of passing in the fault region to a non-faulty automated guided vehicle (202); determining a target automated guided vehicle from the automated guided vehicles currently not executing a task, and sending a task execution instruction to the target automated guided vehicle (203); and in response to determining that the faulted automated guided vehicle is transferred to a maintenance region, sending an instruction for indicating cancel of the prohibition of passing in the fault region to the non-faulty automated guided vehicle that is executing a task (204).

A transport device according to the present invention includes: a transport unit that transports a transport object; a moving unit that controls movement of the transport device; and a control unit that controls an operation of the transport unit and the moving unit according to an instruction. In a case that the instruction includes forming group transport, the control unit controls the moving unit to move to a position where a group for implementing the group transport is formed, and controls the transport unit to transport the transport object at the position. In a case that the instruction includes implementing individual transport, the control unit controls the moving unit to move from the transport source to the transport destination.

A method for controlling a handling of a further object (90) which is handled at a site (10) by at least two different workstations (51, 52) and which is moved between the at least two different workstations,—determining a site plan of the site (10), the site plan indicating the at least two workstations at predefined positions in the site plan,—determining a trajectory of a first object (90) moving in the site (10) in an absolute coordinate system of the site,—deducing absolute positions of the at least two workstations (51, 52) in the absolute coordinate system from the determined trajectory of the first object,—using the absolute positions of the at least two workstations (51, 52) for controlling the handling of the at least one further object handled by the at least two workstations.