An autonomous mobile system (100) used in an industrial plant as a mobile operator system, suitable to be easily reconfigured according to the needs of each specific application. The system (100) includes an autonomous vehicle (1), in the form of an autonomous mobile robot, and a transport carriage (10) including one or more operating units (12) configured to receive a load thereon to be transported. The autonomous vehicle (1) includes a coupling device (5) to couple the autonomous vehicle to the carriage (10) to move the carriage (10) along a path, while the weight of the load carried on the carriage (10) rests solely on the carriage (10). The autonomous vehicle (1) is configured to control the devices onboard the carriage (10).

A server includes a communication device configured to communicate with a plurality of vehicles, a controller configured to receive location information of the vehicles, generate route information based on the received location information of the vehicles and goods transport information, transmit the generated route information to a first vehicle among the plurality of vehicles, select a second vehicle among the plurality of vehicles and a takeover location to take over goods based on delivery point information including a delivery point and location information of the vehicles when the delivery point information among the goods transport information is changed during traveling of the first vehicle, generate route information of the first and second vehicles based on waypoint information for the takeover location, and transmit the generated route information of the first and second vehicles to the first and second vehicles

A server includes a communication device configured to communicate with a plurality of vehicles, a controller configured to receive location information of the vehicles, generate route information based on the received location information of the vehicles and goods transport information, transmit the generated route information to a first vehicle among the plurality of vehicles, select a second vehicle among the plurality of vehicles and a takeover location to take over goods based on delivery point information including a delivery point and location information of the vehicles when the delivery point information among the goods transport information is changed during traveling of the first vehicle, generate route information of the first and second vehicles based on waypoint information for the takeover location, and transmit the generated route information of the first and second vehicles to the first and second vehicles

The present invention provides a ground-contour-following autonomous obstacle avoidance mower for hillside orchards and a control method thereof. Through cooperation of a push rod motor and a rotating pair, multi-angle cutting is achieved, and energy consumption needed by mowing operation is reduced. A connecting rod is arranged and forms a flexible mechanism together with an upper base bearing, a lower base bearing and a base-connecting unthreaded shaft. The flexible mechanism interacts with the push rod motor to achieve ground contour following operation, so that the mower as a whole can conduct ground-contour-following mowing operation on a complex orchard terrain, with a better cutting effect than that of a traditional mower. The use of a right-angle bypassing obstacle avoidance mode realizes precise obstacle avoidance of the mower, and achieves the operation purpose of not excessively relying on operators.

An electronic control unit that is installed on a vehicle connected to a trailer and capable of towing the trailer changes travel control of the vehicle according to a type of the trailer when the trailer is connected to the vehicle.

The present invention relates to a transport wagon consisting of a base frame, wherein the base frame comprises a rotatable bogie assembly on its front side for attachment to a powered tow or push truck and comprises one or more front steering wheels placed on the front side of the base frame and one or more rear steering wheels placed on the rear side of the base frame, wherein the one or more front steering wheels and the one or more rear steering wheels are coupled in such a way to the rotatable bogie assembly, that in operation the one or more front steering wheels rotate along with the rotatable bogie assembly and that the one or more rear steering wheels rotate in opposite direction with respect to the rotatable bogie assembly, wherein the base frame comprises at least one longitudinal beam to which a front cross beam, a rear cross beam and at least one intermediate cross beam are arranged with intermediate spaces, wherein at least one intermediate space is arranged for receiving goods, wherein an intermediate wheel suspension with two or more intermediate wheels is arranged under one or more of the intermediate cross beams. The present transport wagon provides a transport wagon that remains well steerable on uneven floors.

A work vehicle includes a vehicle body, a plurality of traveling devices disposed on the right and left sides on the front and rear sides of the vehicle body respectively, a plurality of bending link mechanisms configured to liftably support each one of the traveling devices to the vehicle body and a plurality of drive operating devices capable of changing the posture of each one of the plurality of bending link mechanisms. The vehicle body is split into a front side body section and a rear side body section. The front side body section and the rear side body section are configured to be bendably pivotable relative to each other via a pivot interlocking mechanism.

A work vehicle includes a vehicle body, a plurality of traveling devices disposed on the right and left sides on the front and rear sides of the vehicle body respectively, a plurality of bending link mechanisms configured to liftably support each one of the traveling devices to the vehicle body and a plurality of drive operating devices capable of changing the posture of each one of the plurality of bending link mechanisms. The vehicle body is split into a front side body section and a rear side body section. The front side body section and the rear side body section are configured to be bendably pivotable relative to each other via a pivot interlocking mechanism.

In one example, a mother cart is provided that is suitable for transporting a daughter cart. The mother cart includes a lower frame, an upper frame connected to the lower frame, and the lower frame includes wheels configured to allow the mother cart to be moved. The lower frame also includes support guides configured to support the daughter cart in a raised position to provide a predetermined ground clearance, and the lower frame has two open sides so as to provide for two-way loading and unloading of the daughter cart on the mother cart.

An articulated vehicle assembly comprising a master vehicle having a master steering system and an onboard sensor arrangement configured to monitor at least said master steering system; a slave vehicle having a slave steering system and an onboard actuator arrangement configured to manipulate at least said slave steering system; an articulation system for articulating in a queue the master and the slave vehicles along a common longitudinal axis; and a processing unit configured to receive input signals from the onboard sensor arrangement and produce corresponding output signals to the onboard actuator arrangement to manipulate said slave steering system so as to maintain the master vehicle and the slave vehicle aligned along the common longitudinal axis, at least when the master vehicle performs a turn on a horizontal plane.