The invention relates to a delivery system having a delivery goods vehicle for delivering inward goods, and having at least one automated transfer assembly which for transferring the goods in an automated manner from the delivery goods vehicle to a goods store comprises an object detection device. The delivery system moreover has a safety installation for securing a movement range of the transfer assembly when unloading the goods.

A materials handling vehicle comprises a distributed processor system including a vehicle network that facilitates an exchange of information with vehicle electronic components, and a distributed multi-processor vehicle control architecture. The distributed multi-processor vehicle control architecture includes an embedded information core having a core processor communicably coupled to the vehicle network, and a tablet having a tablet processor, where the tablet is communicably couplable to, and detachable from the distributed multi-processor vehicle control architecture. When the tablet is detached from the distributed multi-processor vehicle control architecture, the core processor functions as a primary processor that communicates with vehicle electronic components by communicating therewith across the vehicle network. When the tablet is communicably attached to the distributed multi-processor vehicle control architecture, the tablet processor functions as the primary processor, and the core processor functions as a subordinate processor.

An operation assisting apparatus for a load handling vehicle conveying a load carried on a load handling apparatus includes a sensor, an object extraction unit configured to extract, as objects, a group of points representing parts of the objects from a result detected by the sensor in a coordinate system in a real space, a load handling space derivation unit configured to derive a load handling space occupied by the load during load handling work performed by the load handling apparatus in the coordinate system in the real space, a clearance derivation unit configured to derive a value of a clearance between the load handling space and an adjacent object adjacent to the load handling space, and an informing unit configured to inform an operator of the load handling vehicle of information about the value of the clearance.

Described is an electric telehandler (1) comprising: one or more traction apparatuses (3, 51, 6) equipped with a drive wheel (3); movement means comprising a plurality of hydraulic actuators, a hydraulic distributor (2) to actuate the actuators and a pump (21) for supplying the distributor (2); and an electric motor (4, 41, 42, 43, 44, 45, 46, 47, 48, 49) connected directly to the traction apparatus and/or to the pump (21) of the movement means.

A system and a method for remotely controlling a vehicle for safe loading and unloading of cargo, may include a vehicle, and a remote control device that performs data communication with the vehicle control device of the vehicle, and the vehicle sends a request to the remote control device for remote control when arriving at a destination, moves to a work location and performs work under control of the remote control device, requests the remote control device to deactivate the remote control when the work is completed, and performs exit of the destination through autonomous driving of the vehicle.

A system is provided comprising: a materials handling vehicle; a wearable remote control device comprising: a wireless communication system including a wireless transmitter; and a rechargeable power source; a receiver at the vehicle for receiving transmissions from the wireless transmitter; a controller at the vehicle that is communicably coupled to the receiver, the controller being responsive to receipt of the transmissions from the remote control device; and a charging station at the vehicle. The charging station may charge the rechargeable power source of the wearable remote control device. The charging station may comprise a visual indicator.

A machine includes a base, a lift assembly, a first wireless transceiver, a plurality of second wireless transceivers, and a processing circuit. The lift assembly is coupled to and repositionable relative to the base. The first wireless transceiver is coupled to a portion or component of the lift assembly. The first wireless transceiver is configured to transmit a first wireless signal. The plurality of second wireless transceivers are coupled to the base. The plurality of second wireless transceivers are configured to detect the first wireless signal and transmit a plurality of second wireless signals in response to detecting the first wireless signal. The first wireless transceiver is configured to detect the plurality of second wireless signals. The processing circuit is communicably coupled to the first wireless transceiver. The processing circuit is configured to determine a position of the portion or component based on information acquired from the first wireless transceiver.

A machine for handling heavy components in a heavy equipment environment. In an example implementation, the machine includes a truck having at least two front wheels and at least one rear wheel. A outrigger portion extends forward from the truck. The front wheels are attached at a forward end of the outrigger portion. A mast extends vertically from a track extending forward from the truck on a base of the outrigger portion. The mast is movably extendable or retractable along the track. A carriage is mounted on the mast and configured to move vertically on the mast. A pair of forks are mounted on the carriage to move vertically when the carriage is controlled to move. A personnel platform is mounted on the carriage independent of the mounting of the forks on the carriage. A remote control panel is configured to override a cab control panel under operator control. The remote control panel includes a plurality of controls for moving the carriage and for extending or retracting the mast.

A vehicle system includes a first work machine including a first actuator and a first control system, a second work machine including a second actuator and a second control system, and a user input system including a transceiver and a user interface. The user input system is configured to receive a user input via the user interface and provide a signal to both the first control system and the second control system. The first control system and the second control system are configured to receive the signal and thereafter operate the first actuator of the first work machine and the second actuator of the second machine in a coordinated mode of operation. The user input system is configured to provide, and the first control system and the second control system are configured to receive, the signal simultaneously thereby reducing latency between motion of the first work machine and the second work machine in the coordinated mode of operation.

A system for automatic generation of a work site equipment grouping is provided. The system includes a plurality of work machines, each work machine configured to wirelessly communicate with other work machines. The system also includes a local area network including a plurality of communicatively connected nodes. The nodes include the work machines. The work machines are configured to create and join the local area network when the work machines are within a signal range of one or more of the plurality of nodes.