This invention relates to a truck mounted forklift for mounting on the rear of a carrying vehicle, the truck mounted forklift having a lifting assembly mounted on the chassis, the lifting assembly comprising a linkage, the linkage comprising: an elongate first link connected at its proximal end to the chassis by a pivot joint; an elongate second link connected at its proximal end to the distal end of the first link by a pivot joint; a fork carriage connected to the distal end of the second link by a pivot joint; a plurality of link cylinders for actuating the links; and a tilt cylinder for actuating the fork carriage. By having such a truck mounted forklift, top far side loads will be accessible without the lifting assembly coming into contact with the roof of the carrying vehicle or with bottom near side loads. Additionally, the front wheels of the truck mounted forklift will not need to be positioned under the carrying vehicle to reach top far side loads. This will minimise the time needed to load and unload carrying vehicles.

Forklift truck (1) mounted on a carrier vehicle and comprising a frame (16), forks (2), a lifting cylinder (4) for relatively moving the forks (2) and the frame (16) so as to allow, in a handling mode of operation, wherein the forks (2) are mounted so as to move freely upwards and downwards relative to the ground, the forks (2) to be lifted, and in a carrying mode of operation, wherein the forks (2) are in the high position and immobilised so that they do not move upwards and downwards relative to the ground, to allow the frame to be lifted (16), each chamber (7, 8) of the cylinder (4) being provided with a connecting fluid duct which connects the chamber (7; 8) to a hydraulic source. In the handling mode of operation, the forks (2) form an element which is used to actuate the lifting cylinder (4) in the direction in which the forks (2) are lowered, the fluid ducts of the chambers (7, 8) of the lifting cylinder (4) being connected to one other by a fluid connection provided with a closing member in the closed position at least in the carrying mode of operation when the frame (16) is being driven in the direction in which the frame (16) is lifted.

A layover bracket system is provided for supporting an industrial vehicle in a horizontal position on a floor surface. The layover bracket system includes a base section removably attached to a first portion of the vehicle at a first location, and an extension section removably attached to a second portion of the vehicle at a second location spaced apart in a first direction from the first location. The first direction is parallel to a vertical axis of the vehicle when positioned in an upright position. The extension section is pivotably coupled to the base section.

This invention relates to a truck mounted forklift (TMFL), more specifically an electrically powered TMFL. The TMFL comprises a U-shaped chassis having a pair of side bars bridged by a rear cross bar, a pair of front wheels, and a rear wheel. The TMFL further comprises a lifting assembly, a driver's station, and a battery pack mounted on the chassis. Each of the front wheels is provided with a dedicated electric wheel motor assembly. The electric wheel motor assemblies each comprise an interior permanent magnet (IPM) motor having a drive shaft, and a planetary gear box coupled to the IPM motor. The planetary gear box is mounted axially in-line with and is driven by the drive shaft. The IPM motor is mounted substantially internal the side bar and the planetary gear box is mounted substantially internal the bounds of the wheel rim. In this way, a very compact configuration of drive assembly for the front wheels is provided.

A conveyance apparatus according to an embodiment includes a fork unit, a lift unit, a movable cart unit, an auxiliary leg, and a distal end support mechanism. The lift unit is configured to drive the fork unit upward and downward. The movable cart unit is configured to support the lift unit and be movable on a traveling surface by driving a drive wheel. The auxiliary leg unit is provided for the movable cart unit, and is movable along a longitudinal direction of the fork unit and having an auxiliary wheel a position of which is changeable relative to the movable cart unit. The distal end support mechanism is provided on a distal end side of the fork unit and is switchable between a non-contact state with the traveling surface and a contact state with the traveling surface.

A conveyance apparatus according to an embodiment includes a fork unit, a lift unit, a movable cart unit, an auxiliary leg, and a distal end support mechanism. The lift unit is configured to drive the fork unit upward and downward. The movable cart unit is configured to support the lift unit and be movable on a traveling surface by driving a drive wheel. The auxiliary leg unit is provided for the movable cart unit, and is movable along a longitudinal direction of the fork unit and having an auxiliary wheel a position of which is changeable relative to the movable cart unit. The distal end support mechanism is provided on a distal end side of the fork unit and is switchable between a non-contact state with the traveling surface and a contact state with the traveling surface.

A layover bracket system is disclosed for supporting an industrial vehicle in a horizontal position. The layover bracket system includes a layover bracket removably coupled to a proximal end portion of the industrial vehicle, the layover bracket including at least one wheel for moving the layover bracket system with the industrial vehicle supported thereon while the industrial vehicle is in the horizontal position. The layover bracket supports the proximal end portion of the industrial vehicle when the industrial vehicle is in a horizontal position and allows the layover bracket system and industrial vehicle to roll on the at least one wheel of the layover bracket. The layover bracket system may also include a support bracket for supporting a distal end of the industrial vehicle while the vehicle is in the horizontal position.

A forklift includes a vehicle frame, wherein at least one load rest platform is movably arranged on the vehicle frame. The at least one load rest platform is movable between a storage position, in which no load can be deposited on the at least one load rest platform, and a working position, in which a load can be deposited on the at least one load rest platform. The at least one load rest platform is aligned essentially horizontally when moved to the working position, and the at least one load rest platform is movably arranged on an upper surface of the vehicle frame via at least one articulating joint. The at least one articulating joint connects the at least one load rest platform with a side face of the vehicle frame.

A vehicle includes an electric machine, a detachable lift, and a controller. The detachable lift has a lift battery that is electrically connected to the electric machine. The controller is programmed to, responsive to the vehicle traveling on a predetermined route, transfer power between the electric machine and lift battery such that a lift battery charge is within a desired range at an end of the route.

Methods and systems for assembling and using a hydraulic pallet jack box actuation system for a refuse truck are disclosed. The system includes an assembly that supports a pallet jack box sized and configured to contain at least a portion of a pallet jack. The assembly includes a top portion including a linkage connection portion that connects to a cross member of a truck frame, a bottom portion that includes a pallet box support member configured to be raised and lowered between the truck frame and a ground, and a hydraulic cylinder disposed between and connecting the top portion and the bottom portion. The hydraulic cylinder includes a top cylinder portion and a bottom portion configured to extend between an extended position to place the assembly in an extended configuration closer to the ground and a retracted position to place the assembly in a retracted configuration.