A transport system for picking products and/or goods. The transport system includes an order-picking device with a rigid base frame and a transport and/or work platform, and two individual vehicles each of which are couplable to the order-picking device and each of which have a drive device, a steering device, and a lifting device which can raise and lower a load-carrying device. The two individual vehicles, when in a decoupled state from the order-picking device, are each operatable completely independently of one another, and, when in a coupled state to the order-picking device, are coupled with the order-picking device so as to provide a driving and steering behavior of a rigid overall vehicle made up of the two individual vehicles and the order-picking device, and a lifting behavior of a complete lifting device made up of the lifting device of each of the two individual vehicles.

A handling machine control method, a handling machine control system and a control host are provided. The method includes: detecting a handling instruction which instructs a handling of a first object; reading handling information of the first object according to the handling instruction; if the handling information of the first object is read, control, according to the handling information, a first handling machine to move to a first position and perform a first operation to lift up the first object at the first position; after the first object is lifted up, control the first handling machine to move to a second position and perform a second operation to put down the first object at the second position; and in response to that the first object is put down at the second position, updating the handling information of the first object.

The invention relates to a forklift truck (101) with at least two environment sensors (105a, 105b) attached to different fork arms (103a, 103b). These are orientated with at least part of their detection zones (111a, 111b) directed outward and transversely to the forklift truck (101).

A forklift includes a vehicle body, a fork that mounts a pallet, and a sensor provided in an insertion portion of the fork. The forklift inserts the insertion portion into an insertion opening, while moving the fork. When the sensor detects a proximity state, in which the insertion portion has approached a facing surface to such an extent that a distance between the insertion portion and the facing surface is less than or equal to a specified value, the forklift executes a stopping process that stops movement of the fork. The forklift executes an avoidance process that tilts and vertically moves, after the stopping process, the fork to separate the insertion portion away from the facing surface such that a position of the insertion portion with respect to an entrance of the insertion opening does not change in an up-down direction of the vehicle body.

A method and system are herein disclosed wherein a robot handles objects that are large, unwieldy, highly-deformable, or otherwise difficult to contain and carry. The robot is operated to navigate an environment and detect and classify objects using a sensing system. The robot determines the type, size and location of objects and classifies the objects based on detected attributes. Grabber pad arms and grabber pads move other objects out of the way and move the target object onto the shovel to be carried. The robot maneuvers objects into and out of a containment area comprising the shovel and grabber pad arms following a process optimized for the type of object to be transported. Large, unwieldy, highly deformable, or otherwise difficult to maneuver objects may be managed by the method disclosed herein.

Production system for series production of in particular motor vehicles, includes a container storage area storing containers containing components for production, production shelves, remote from container storage area, from which workers remove components from containers. Transport for transporting containers from container storage area to production shelves. Transport has automated guided vehicle (AGV) on which transport shelf is situated and designed so containers are automatically delivered from transport shelf to production shelves in a conveying direction (delivery direction). Handling device situated on AGV, has a base body and a handling unit situated on base body. Handling unit removes containers from transport shelf in conveying direction and delivering containers to production shelf. Relative to base body, handling unit is linearly adjustable along first linear adjustment axis in conveying direction, along a second linear adjustment axis transverse to conveying direction, height-adjustable along a third adjustment axis, and rotatable about vertical fourth adjustment axis.

A CPS-based smart forklift truck management device includes a space information collector collecting distribution warehouse space information, a distribution warehouse visualizer which generates a digital twin for a distribution warehouse space based on the collected distribution warehouse space information and visualizes a loading situation of an article storage and a movement situation of a forklift truck on the distribution warehouse space digital twin, a movement path information provider which selects a target location at which an article is to be stored based on the visualized distribution warehouse space digital twin and provides information a path through which the forklift truck is movable to the target location, and a height adjustment information provider which provides forklift height adjustment information of the forklift truck according to a location of a storage cell corresponding to the article storage when the forklift truck arrives at the article storage corresponding to the target location.

An intelligent forklift and a method for detecting a pose deviation of a container are provided. The intelligent forklift includes a working state monitor, an image sensor, and a processor. The working state monitor is configured to monitor a working state of the intelligent forklift while the intelligent forklift is carrying and moving a stock container and send a trigger to the image sensor based on the working state. The image sensor is configured to capture an RGBD image frame containing the stock container in response to the trigger and to transmit the RGBD image frame to the processor. The processor is configured to receive the RGBD image frame, detect a pose deviation degree of the stock container and provide an alarm and/or a prompt based on a detection result of the pose deviation degree for adjusting the pose of the stock container.

A refuse collection vehicle includes a fork assembly that is operable to engage one or more fork pockets of a refuse container, a lift arm that is operable to lift a refuse container, and at least one sensor that is configured to collect data indicating a position of the one or more fork pockets of the refuse container. A position of at least one of the fork assembly or the lift arm is adjusted in response to the data collected by the at least one sensor.

A position and posture estimation apparatus includes: a laser sensor configured to be disposed on at least one of left and right sides of a forklift, to emit laser light to a side surface of a pallet lifted by a fork, and to receive reflected light of the laser light and acquire a laser measurement point group; and an estimation calculation unit configured to estimate a position and a posture of the pallet with respect to the fork based on the laser measurement point group acquired by the laser sensor.