An autonomously guided industrial truck comprising a vehicle body and a pair of support arms extending from the vehicle body. The vehicle body defines a longitudinal direction and a width direction of the industrial truck in sections in plan view of the industrial truck. Each of the support arms extending from the vehicle body has at least one load wheel. The industrial truck includes a pair of support wheels or drive wheels located underneath the vehicle body on a driving surface and opposite one another relative to the width direction. The industrial truck includes a pair of scanner units arranged vertically above the support wheels or drive wheels. The pair of scanning units defines a scanning plane with respective scanning regions each scanning unit of the pair of scanning units, and wherein the respective scanning units are symmetrically opposite one another within an outline of the vehicle body in the width direction of the industrial truck.

The present invention relates to a base plate (10) for an autonomously guided industrial truck with a longitudinal direction (L) and a width direction (B), which is provided to form a base plate arrangement and to downward delimit a vehicle body of the industrial truck in sections, comprising a plate body (12), which is provided to define an outline of the base plate arrangement at least in sections. Here, the base plate (10) according to the invention has an opening (14) which is central in relation to the width direction (B) and is provided for accommodating a drive wheel of the industrial truck, and at least one recess (16a, 16b) which is offset in relation to a longitudinal center axis (L) in the width direction (B) and is provided for accommodating a support wheel arrangement of the industrial truck.

An autonomously-guided industrial truck comprising a vehicle frame defining, in a plan view, a vehicle contour in sections. The vehicle frame comprises three structural levels, arranged one above the other in a vertical direction, each with its own contour. The three structural levels include a lower structural level in which a base structure is attached, an upper structural level with a covering, and a middle structural level comprising a frame structure for connecting the lower structural level and the upper structural level. The industrial truck includes at least one drive wheel assigned to the vehicle frame to stand below the vehicle frame on a driving surface and at least one scanner unit arranged completely within the vehicle contour such that a scanning plane of the at least one scanner unit lies at least in sections vertically in a region of the middle structural level.

An autonomous guided vehicle includes a frame, a drive section, a payload handler, a sensor system, and a supplemental sensor system. The sensor system has electro-magnetic sensors, each responsive to interaction or interface of a sensor emitted or generated electro-magnetic beam or field with a physical characteristic, the electro-magnetic beam or field being disturbed by interaction or interface with the physical characteristic, and which disturbance is detected by and effects sensing of the physical characteristic. The sensor system generates sensor data embodying at least one of a vehicle navigation pose or location information and payload pose or location information. The supplemental sensor system supplements the sensor system, and is, at least in part, a vision system with cameras disposed to capture image data informing the at least one of a vehicle navigation pose or location and payload pose or location supplement to the information of the sensor system.

Typically, unit loads with wooden pallets in warehouses are moved by pallet lifters or AMRs which are bulkier in size and require more power with high operating costs. This disclosure relates generally to a unit load lifter designed with counterbalance arm mounted on an autonomous mobile robot (AMR) to load and unload unit load from one position to another position autonomously. The unit load lifter includes a horizontal slide unit and a vertical axis fork assembly. The horizontal slide unit include base plate of the unit load lifter is mounted on the AMR. A plurality of fixed guides is integrated with the base plate to house the vertical axis fork assembly by a plurality of rollers on a roller mounting plate. The vertical axis fork assembly include an actuating end of a linear actuator is connected to the sliding plate to drive the at least one fork up and down.

Material logistics system for coordinating transfer of production material so that production material is available as needed at production stations of a manufacturing facility, in particular a series production facility. Thus, multiple sensors are provided for sensing a production material supply at production stations, as well as a central unit in signal-transmitting connection with the sensors and which, based on output signals transmitted from the sensors, determines logistics data relating to the production material for a particular production station. And also, using logistics data, generates control signals for the transfer of production material and provides them for further data processing units. Furthermore, the central unit uses logistics data to control a driverless transport vehicle, having a transport rack including a transport level, for transporting production material accommodated in containers, for a partially automatic container transfer between a transport rack and a storage rack of a production station.

Compact tool carriers having a loader mounted to a low-profile mainframe are disclosed. In some embodiments, the pivot points of the mainframe about which the loader is pivoted are low relative to the mainframe to reduce the mainframe size and to lower the center of gravity to improve the stability of the compact tool carrier during use.

Compact tool carriers having a loader mounted to a low-profile mainframe are disclosed. In some embodiments, the pivot points of the mainframe about which the loader is pivoted are low relative to the mainframe to reduce the mainframe size and to lower the center of gravity to improve the stability of the compact tool carrier during use.

Systems and methods for towing, hitching, and connecting devices are described. An autonomous guided vehicle includes an automated hitch capable of connecting to a variety of types of containers.

A system includes an article supply location, wherein the article supply location includes a plurality of articles to be sorted, first and second transport vehicles, each having a first position in which an article is stowed about the vehicle and a second position in which the article is deposited into a proximal container. And a control system. The control system is configured to receive an order for a plurality of disparate articles, determine one destination container of a plurality of destination containers to direct the transport vehicle to deposit a selected article, direct the first transport vehicle to transport a selected article to the destination container and deposit the article by manipulation of the first transport vehicle from the first position to the second position for deposit of the selected article in the destination container.