A materials handling vehicle including a load handling assembly having a mast assembly, and a fork carriage assembly including a fork support and at least one fork assembly, the at least one fork assembly including a first fork member, which is fixed to the fork support, and a second fork member. The vehicle includes a tilt assembly that tilts the fork support relative to the mast assembly such that a central axis of the at least one fork assembly is positionable in a plurality of different positions relative to a horizontal direction. The vehicle includes a fork extension/retraction assembly that moves the second fork member relative to the first fork member in a first direction that is parallel to the central axis such that the fork extension/retraction assembly selectively moves the second fork member toward or away from the fork support in the first direction.

A bale loading apparatus has a base frame mounted to a loader vehicle operative to move the base frame up and down. Right and left fork frames are connected to right and left portions of the base frame by corresponding right and left linkages, and right and left fork pairs extend away from the loader end of the base frame. A right actuator is operative to pivot the right fork pair with respect to the base frame upward and outward to the right of a path of the loader vehicle from a lowered right position to a raised right position, and a left actuator is operative to pivot the left fork pair with respect to the base frame upward and outward to the left of the path of the loader vehicle from a lowered left position to a raised left position.

A configurable-width industrial weighing scale configured to hang directly from one of multiple engine-powered lifting machines and/or to couple to a quick-attach plate or other attachment means of an engine-powered lifting machine and configured to directly support a lifting element and/or couple to a quick-attach plate or other attachment means of a lifting element. A weighing element includes front and rear plates in parallel with one another and a weighing assembly therebetween. The weighing assembly may include a strain gauge-based load cell, a shock absorber, a mechanical preload adjustment to control a vertical difference between the front and rear plates, a mechanical linearity control to adjust an angle of the weighing assembly, a carriage alignment bolt to compensate for an uneven surface of a lifting carriage of the engine-powered lifting machine, and/or a mechanical adjustment to compensate for a distance between the front plate and a load.

A configurable-width industrial weighing scale configured to hang directly from one of multiple engine-powered lifting machines and/or to couple to a quick-attach plate or other attachment means of an engine-powered lifting machine and configured to directly support a lifting element and/or couple to a quick-attach plate or other attachment means of a lifting element. A weighing element includes front and rear plates in parallel with one another and a weighing assembly therebetween. The weighing assembly may include a strain gauge-based load cell, a shock absorber, a mechanical preload adjustment to control a vertical difference between the front and rear plates, a mechanical linearity control to adjust an angle of the weighing assembly, a carriage alignment bolt to compensate for an uneven surface of a lifting carriage of the engine-powered lifting machine, and/or a mechanical adjustment to compensate for a distance between the front plate and a load.

A tote mover includes a base and a plurality of wheels supporting the base. A backrest is moveable relative to the base. A hook assembly is moveable relative to the backrest between a first rotational position and a second rotational position.

An automatic guided vehicle for handling reels includes a telescopic upright integral with a vehicle frame bearing a fork carriage provided with at least one pair of forks and connected to the telescopic upright with an equipment. The equipment includes a plurality of actuators and a plurality of sensors, the equipment including a pair of actuators for tilting the fork carriage, an actuator to control the global lateral translation of the fork carriage, at least one pair of actuators for the symmetrical movement of the forks towards and away from each other. Each fork has a substantially rectangular section with a height greater than the base. Opposite facing walls of the forks are flat and can be approached in direct contact with each other, the two coupled forks having bevels along all the four edges facing outwards. Each fork can have a “V” shaped seat on the upper face.

A lift for lifting a vehicle above a ground surface comprising an elongated front module insertable under the vehicle and a rear module extending longitudinally from the front module. The front module includes a truck supporting four support arms usable for supporting the vehicle and a pair of front wheels assemblies. The rear module includes a head frame, an actuator assembly mounted to the head frame and a rear wheel assembly. The actuator assembly is operatively coupled to the front and rear wheel assemblies to selectively raise and lower the head frame and the truck by moving the front and rear wheels relative to the truck and head frame.

The application relates to a carrying robot including a fork. The fork includes a telescopic arm and a temporary storage tray. The telescopic arm includes a fixed arm and a movable arm connected to the fixed arm. The movable arm is telescopically movable relative to the fixed arm. The temporary storage tray is mounted to the fixed arm and is configured to temporarily store goods. The temporary storage tray is able to extend relative to the fixed arm. An extending direction of the temporary storage tray is consistent with an extending direction of the movable arm. When the fork pulls in or pushes out the goods, containers can be stably transferred between a stationary rack and the temporary storage tray.

The invention relates to a drive unit for a device for lifting and transporting loads, which is attached or to be attached to a further device. A drive device according to the invention for the lateral movement of at least two load lifting elements of a device for lifting and transporting loads for mounting on a movable or stationary device comprises a first drive element and a second drive element, wherein the first load lifting element is movable by the first drive element and the second load lifting element is movable by the second drive element laterally in the axial direction of a first guide profile of the device for lifting and transporting loads, wherein the at least two load lifting elements are supportable by the first guide profile. The two drive elements can be driven by exactly one drive unit, the exactly one drive unit being positioned between the two drive elements.

An loading equipment and a conveying system for tank track moving supports are provided, the loading equipment includes an circular conveyor line and a loading device; the circular conveyor line includes a support frame, a baseplate is connected with the support frame, an circular guide rail is connected with the baseplate, trays are connected above the circular guide rail, fixture assemblies are connected with the trays, an circular driving part is connected with the trays; tracking cars are fixedly connected with the trays and slidably connected with the circular guide rail; the circular driving part is fixedly connected with the tracking cars. Seamless involvement of moving support from the blank transmission to the processing output process is achieved, the processing efficiency is improved, and the position of the moving support in the transportation process is definite.