A mobile device for handling objects includes a radio frequency identifier reader for receiving radiation emitted by object-specific radio frequency identifiers attached to the objects and radiation emitted by fixed radio frequency identifiers. The mobile device includes a processing system that computes a speed estimate for the mobile device based on a distance between two fixed radio frequency identifiers and a time-difference between receptions of radiation from these fixed radio frequency identifiers. The processing system determines, based on radiation received from each object-specific radio frequency identifier, a movement indicator indicative of movement of the mobile device with respect to the corresponding object. When the speed estimate exceeds a threshold, the processing system classifies objects which are moving in accordance with the movement indicator to be objects non-belonging to a load of the mobile device. The mobile device can be for example a forklift.

The present disclosure relates to a rotary encoder utilized in cooperation with existing rotary motion of a vehicle mast configured to raise and lower relative to the ground. In particular, an exemplary embodiment of the present disclosure relates to a rotary encoder integrated within a mounting boss of a sheave of a lifting tether pulley to ascertain and communicate mast height to a user and a safety system of the associated vehicle.

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 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.

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.

A boom extension monitoring system is provided that uses a combination of sensors to determine an absolute location and a relative location of the boom. As the boom extends or retracts, the monitoring system can determine the absolute location of the boom as the sum of the absolute at relative distances. These distances can be obtained through a combination of a grid, low-resolution sensors, high-resolution sensors, counters, processors, and other components according to various embodiments described herein. A process to obtain the total boom extension of multiple telescoping beams by monitoring the extension of a single beam element is also described.

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.

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.

The initial setting method for the unmanned forklift includes a step of acquiring a measurement value of floor surface inclination of a stop position where the unmanned forklift stops when the unmanned forklift unloads a palette on a rack, a step of setting the stop position where a predetermined inclination pattern is detected, as a precise adjustment position, from the acquired measurement value, a step of causing the unmanned forklift to unload the palette in accordance with an operation program, and measuring a deviation amount of the palette unloaded by the unmanned forklift, at the precise adjustment position, and a step of correcting a command value of the unmanned forklift at the stop position, based on the measured deviation amount.