The present invention relates to a forklift capable of mounting a door in a state in which a pipe for forming a cabin frame is not drilled, the forklift having: a door mounting bar, which is mounted on the outer surfaces of rear pipes at both left and right surfaces of the cabin frame of the forklift, has a bent part formed at the upper end thereof, and has a fastening part formed on one side surface thereof by bending so as to be positioned at the rear surface of the rear pipe; a rear window frame which is mounted between both the left and right rear pipes at the rear of the cabin frame and is formed as a square frame having, at both the left and right sides thereof, engagement fastening parts coupled to the fastening part of the door mounting bar; connecting brackets which simultaneously fasten the door mounting bar and the rear window frame while coming in close contact with the rear pipe at the inner side of the cabin frame; and a hinge bracket which is provided at the upper and lower ends of the outer surface of the door mounting bar, is integrally provided with threads so as to ensure the thread thickness of bolt fastening for the assembly of a hinge for opening and closing the door, and has a predetermined thickness.

The invention relates to a transport vehicle for transporting at least one transport unit. The transport vehicle including at least one drive unit having at least one electric drive, at least one steerable vehicle wheel, at least one standing platform, at least one control unit (6), and at least one loading fork, and at least two longitudinal outriggers, which are arranged parallel to one another and at a distance from one another and extend in a longitudinal direction of the transport vehicle and between which the loading fork is arranged so as to be height-adjustable and which are in each case connected to the drive unit by one end section and at the respective other end section of which in each case at least one non-steerable vehicle wheel is arranged.

A method and apparatus for moving trailers using a trailer moving apparatus coupled to a forklift is shown and described herein. The method and apparatus for moving trailers uses a trailer moving apparatus engageably coupled to a forklift when lifted off a surface with a plurality of hitches at different heights. The method for moving trailers using a trailer moving apparatus operatively coupled to a forklift tine via a guided channel on a channel member and not requiring an operator to leave the cabin of the forklift during operation.

A system for reconfiguring a factory having equipment at different workstations throughout the factory and a plurality of sensors disposed throughout the factory includes a factory configuration module configured to store a plurality of predetermined factory configurations and a plurality of mobile transporters configured to engage and transport the equipment to the different workstations throughout the factory based on the predetermined factory configurations and dynamic inputs, where the dynamic inputs include a status of the equipment, a status of the plurality of mobile transporters, sensor data output by the plurality of sensors, or a combination thereof.

An insulated metal panel (IMP) assembly system includes a panel assembly table and a boom IMP attachment. The panel assembly table allows for assembly of a panel module at ground level. The boom IMP attachment features a quick-coupler couplable to the boom of a telehandler, a swivel coupler column, one or more tilt linear actuators configured to tilt the orientation of a panel module, and one or more hydraulic rotation linear actuators configured to rotate the orientation of the panel module. The boom IMP attachment also includes a jib frame, a plurality of jib arms spanning outwards from the jib frame, and one or more clamp header rails having a plurality of clamp assemblies, each configured to grip a frame member of the panel frame of the panel module. The boom IMP attachment may hoist, tilt, and rotate the panel module.

The invention relates to an industrial truck comprising

a chassis (6),
a mast (8) arranged on the chassis (6) in an upright position, a load-carrying apparatus (36), which has at least one load-receiving means (42) for receiving a load that is to be transported,
a support structure (9) that supports the load-carrying apparatus (36) on the mast (8) and can be moved, together with the load-carrying apparatus (36), upwards and downwards on the mast (8), and comprising
a device (54) for reducing vibrations,
wherein the device (54) for reducing vibrations has at least one additional mass body (60), which is supported by the mast (8) or the components connected thereto and is not constantly rigidly coupled to the mast (8) or the support structure (9) or the load-carrying apparatus (36), but is movably mounted by means of a bearing arrangement (62) such that it is movable relative to the mast (8) in response to mast vibrations, in particular to mast vibrations having horizontal vibration components, in order to counteract mast vibrations.

A multi-function camera system, applied to a forklift truck, includes a camera device and a display device installed on the forklift truck, and an image processing unit coupled between the camera device and the display device, capable of shooting and displaying a corresponding real image in order to assist operations of the forklift truck. In addition, the camera device is equipped with a fill light module capable of providing multiple light colors, and the image processing unit includes an identification module capable of identifying the optical identification code. Accordingly, the camera system with multiple functions of monitoring, fill light, identification and positioning etc. is achieved.

The invention relates to a transport vehicle for transporting at least one transport unit. The transport vehicle including at least one drive unit having at least one electric drive, at least one steerable vehicle wheel, at least one standing platform, at least one control unit (6), and at least one loading fork, and at least two longitudinal outriggers, which are arranged parallel to one another and at a distance from one another and extend in a longitudinal direction of the transport vehicle and between which the loading fork is arranged so as to be height-adjustable and which are in each case connected to the drive unit by one end section and at the respective other end section of which in each case at least one non-steerable vehicle wheel is arranged.

A variety of vehicle-based and warehouse-based solutions are provided to increase the adaptability, utility, and efficiency of materials handling vehicles in the warehouse environment, such as a materials handling vehicle comprising a hand-held drive unit comprising a user interface and an operational command generator responsive to the user interface. The hand-held drive unit is configured to send operational commands generated in response to user input at the user interface to the vehicular controller(s) to control operational functions of the traction control unit, the braking system, the steering assembly, the mast assembly, the picking attachment, or combinations thereof.

The present disclosure relates to a fork-lift truck, comprising, a housing, a mast, an actuating device, a framework extension assembly, a control unit, a pair of support legs. The fork-lift truck is provided with a sensor device that is arranged to detect a predetermined rotary position of at least one rotary axis of the framework extension assembly. The control unit is arranged to determine and set a maximal speed and/or a maximal acceleration, and/or a maximal deceleration, and/or a maximal lift height, and/or a maximal load weight, of the fork-lift truck based on the detected predetermined rotary position of the said at least one rotary axis.