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.

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.

The present invention relates to a load part (10) for an autonomously-guided industrial truck having a longitudinal direction and a width direction (B), comprising a pair of fork prongs (12a, 12b) extending substantially horizontally and arranged next to one another in the width direction (B), or a mono fork extending substantially horizontally and having two extension sections and a connecting section, and a load stop (14) connected to the pair of fork prongs (12a, 12b) or the extension sections and extending substantially in the vertical direction above the fork prongs (12a, 12b) or the mono fork. According to the invention, the load stop (14) has a cutout (22a, 22b) on at least one of its outer sides in the width direction (B) adjacent to the corresponding fork prongs (12a, 12b) or extension section. Furthermore, the present invention relates to an industrial truck equipped with such a load part.

A material transport cart includes a cart body, a material support body coupled to the cart body, a wheel coupled to the cart body, a motor operable to drive the wheel, and a powered lift assembly. The powered lift assembly is coupled to the cart body and to the material support body. The powered lift assembly is operable to lift the material support body relative to the cart body. A removable battery is electrically coupled to and operable to supply power to both the motor and the powered lift assembly.

To realize a fork lift device capable of contributing to space-saving for an aisle width at a warehouse. A fork lift device according to an embodiment of the present includes: a first fork and a second fork moveable in a lateral direction and a vertical direction with respect to a traveling direction; and an interchanging mechanism configured to interchange vertical positions of the first fork and the second fork.

A system for replacing a reel of material for the production of electrical energy storage devices and comprising a self-driving vehicle for transporting a reel from a storage or receiving station to a change station is described; at least one support spindle carried by the vehicle and configured to support the reel and to transfer it, at the change station, to a feeding unit of an automatic machine for the production of the storage devices; and a gripping member carried by the vehicle and comprising at least one gripper configured to receive and grip an initial flap of the reel supported by the support spindle and to keep such initial flap tensioned along an unwinding path of the same.

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.

Some illustrative embodiments of a fire tube implement for extraction and insertion of a fire tube may include an elongate shaft that is configured to extend outward and to be received within an opening in the fire tube. In some embodiments, the elongate shaft may carry at least one extender that is moveable between an extended position and a retracted position normal to a longitudinal axis of the elongate shaft. The at least one extender may be configured to engage an internal surface of the fire tube within the opening when the at least one extender is in the extended position. In some embodiments, a stabilizer may be laterally disposed from an exterior surface of the elongate shaft and securable to the fire tube. The elongate shaft may be operable by a powered machine.

A low-lift industrial truck (2) and a method for operating the same. The industrial truck includes a load fork (4) for picking up a load. Fork tines (6a, 6b) of the load fork (4) each include at least one load roller (8) in a region of fork tine tips (28). The industrial truck also includes a load lifting assistance system having a distance sensor (16) and a processing unit (14). The distance sensor is configured to measure a distance between the load and a front wall (12) of the industrial truck facing the load fork. At least one distance between the load and the front wall is saved in the processing unit and corresponds to a predetermined stop position. The processing unit is configured to process measured values of the distance sensor and to generate a stop signal when a distance corresponding to the stop position (20a, 20b) is determined.

A low-lift industrial truck (2) and a method for operating the same. The industrial truck includes a load fork (4) for picking up a load. Fork tines (6a, 6b) of the load fork (4) each include at least one load roller (8) in a region of fork tine tips (28). The industrial truck also includes a load lifting assistance system having a distance sensor (16) and a processing unit (14). The distance sensor is configured to measure a distance between the load and a front wall (12) of the industrial truck facing the load fork. At least one distance between the load and the front wall is saved in the processing unit and corresponds to a predetermined stop position. The processing unit is configured to process measured values of the distance sensor and to generate a stop signal when a distance corresponding to the stop position (20a, 20b) is determined.