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.

A bumper assembly for a material handling vehicle is provided. The material handling vehicle includes a vehicle frame. The bumper assembly includes a first bumper coupled to a first side of the vehicle frame and having a first slot extending along a portion of the first bumper and a first protruding portion. The first protruding portion extends outwardly at an angle past a plane defined by the first side of the vehicle frame. The bumper assembly further includes a second bumper coupled to a second side of the vehicle frame opposite to the first side and having a second slot extending along a portion of the second bumper and a second protruding portion. The second protruding portion extends outwardly at an angle past a plane defined by the second side of the vehicle frame.

A lift device includes a base, an arm, a tractive element, and a steering actuator. The arm has a base end coupled to the base and a tractive element end. The arm includes a steering actuator interface positioned along an exterior surface of the arm. The tractive element is coupled to the tractive element end. The steering actuator has a first end coupled to the steering actuator interface and an opposing second end coupled to the tractive element. The arm includes a plate extending from the exterior surface of the arm at an upward angle and past the steering actuator.

A carrier vehicle includes a front frame and a rear frame conveniently attachable to and detachable from the front frame. The front frame includes a frame body, at least one battery structure installed along an inner front side wall of the frame body and a connecting rod wheel component at a transverse bottom of the frame body. The rear frame comprises an operating handle, a handle joint base, a hydraulic component having an oil cylinder, a bearing component and a driving assembly. A bottom end of the operating handle is rotatably connected to the handle joint base, which includes a joint fixing base and a microswitch. The bearing component includes a bearing bridge having bridge lugs detachably connected to ends thereof, and a middle part sleeved on the oil cylinder. The front frame and rear frame are transportable in a separated compact configuration, with later simple and fast assembly.

Disclosed herein is an automated conveyance robot (ACR) for conveying movable platforms (MPs) in and out of trailers. A lift carriage at a first end of the ACR is configured to couple to the MP during movement and disengage after movement. A counterweight system at a second end of the ACR counterbalances the ACR during conveyance. The ACR comprises a front drive assembly and a rear drive assembly which are independently steerable to allow for different steering methods. The ACR can function fully automated or can be controlled

A base frame for a reach truck comprises a wheel arm subassembly comprising two wheel arms each having a front end and an opposing rear end. A load wheel receiver is positioned on each rear end and a counterweight is positioned at the front end of the wheel arms and coupled to the wheel arm subassembly by a plurality of screw connections. The plurality of screw connections comprise a first portion of screw connections and a second portion of screw connections. The first portion of screw connections each extend in a first direction and the second portion of the screw connections each extend in a second direction which is different from the first direction.

A transport robot is configured to transport a transported object(s) in a state of sandwiching the transported object(s) by cooperating with another transport robot when transporting the transported object(s).

The present disclosure is a lift attachment apparatus for construction and farm equipment, including a loader. In an embodiment of the disclosure, lift apparatus may include a frame including an attachment device configured to attach to a tilting plane of a loader having a forward facing loader arm, a pair of wheels connected to the frame, a first wheel of the pair of wheels located on a first side of the frame and a second wheel of the pair of wheels located on a second side of the frame. The lift attachment apparatus may further include a boom or forks connected directly or indirectly to the frame, wherein control of the boom or forks is provided by application of force to the attachment device by the forward facing loader arm in a downward direction to create lift and rotation of the tilting plane causing rotation of an end of the boom or forks about the first wheel and the second wheel. The first wheel and second wheel being mechanically aligned to act as a stable fulcrum.