An operating method for an industrial truck. The industrial truck includes a hydraulic pump which provides a hydraulic output, an output setpoint value generator which controls the hydraulic output to influence a traveling speed, two drive wheels which respectively comprise a hydraulic drive unit driven via the hydraulic pump, and a hydraulic device. The hydraulic device is switchable between a first switching state, where the hydraulic drive units are supplied with hydraulic outputs which are different, and a second switching state, where the hydraulic drive units are supplied with hydraulic outputs that have a particular ratio with respect to each other. The operating method includes detecting at least one operating parameter of the output setpoint value generator, comparing the at least one operating parameter with a predefined threshold value, and moving the hydraulic device from the first switching state to the second switching state based on the comparison.

A transportation arrangement for transportation of an object on a surface comprises at least one transportation unit. The transportation unit comprises a housing comprising a vertical front surface, two arms movably connected to the housing at each side of the vertical front surface, at least one rolling element arranged at a lower portion of the housing, and a power source connected to the rolling elements and the movable arms. The rolling element are configured to roll in any horizontal direction on the surface.

In embodiments, an automatic guided vehicle includes a vehicle, a lift unit, a bumper, an extension detector, and a bumper controller. The vehicle is movable in at least a first direction. The lift unit is provided in the vehicle and lifts an object from below the object. The bumper is provided in the vehicle and is extendable and contractible in the first direction. The extension detector detects that the bumper has extended outward from the object in the first direction. The bumper controller controls a state of the bumper according to a conveyance state of the object by the vehicle.

A carrier for transporting goods includes a supporting mechanism, a lifting mechanism, a first detection component, and a controller. The supporting mechanism includes at least one entrance and connected to a mobile robot. The lifting mechanism includes a lifting driving member and a bearing part. The lifting driving member is arranged on the supporting mechanism, and the bearing part is arranged on the lifting driving member to be driven to be elevated or lowered by the lifting driving member. The first detection component is arranged on the bearing part and is located in front of the at least one entrance for detecting a position of the goods. The controller is arranged on the supporting mechanism and is respectively communicatively connected with the lifting driving member, the first detection component, and the mobile robot. A mobile lifting conveyor having the carrier is also provided.

The present invention relates to a method for controlling a torque generated by at least one electric motor (130) of an electric lift truck (100), the method comprises: detecting (210) a fulfilment of at least one criterion when the torque of the at least one electric motor (130) is in a first mode, the fulfilment of the at least one criterion indicating insufficient amount of the torque in to maintain a motion of the electric lift truck (100), triggering (220) an electrical drive (140) of the at least one electric motor (130) to generate a control signal to generate a torque being larger than the torque of the at least one electric motor (130) in the first mode to change the torque to an increased torque mode. Some aspects relate to a control unit (150), to a computer program product and to an electric lift truck (100).

Truck mounted forklift (200) for mounting on the rear of a vehicle. The truck mounted forklift comprises a u-shaped chassis (201) with a linkage (103) lifting assembly mounted thereon. The linkage lifting assembly comprises a carriage (101) slidably mounted on the chassis and a linkage, the linkage comprising a first link (105) connected to the carriage by a pivot joint (107) and a second link (109) connected to the first link by a pivot joint (111). A fork carriage (113) is connected to the other end of the second link. The second link comprises a telescopic link having a plurality of link sections nested together. Cylinders (115,117) are provided to operate the links and the telescopic link. The linkage is more compact than other duplex (i.e. two part) linkages, will not protrude rearwardly increasing the overhang of the forklift and will be able to be mounted and dismounted in a substantially vertical direction, obviating the need for reinforced, heavier tines.

A tiller head for an industrial truck is shown which comprises a central portion, a left handle portion that is attached to a left side of the central portion and a right handle portion that is attached to a right side of the central portion, which is opposite to its left side, and an actuating element. The handle portions and the central portion define a front side of the tiller head and a back side of the tiller head, which is opposite to its front side. The front side of the tiller head and the back side of the tiller head extend transverse to the left side of the central portion and the right side of the central portion. The actuating element has an operable front surface and an operable back surface, and the actuating element is mounted to a front side of the central portion.

A support system for a vehicle includes a base and at least a first and a second support arm. Each of the first and the second support arms include a base end pivotally coupled to the base through a respective hinge assembly. Each of the first and the second support arms further include a distal end opposite the base end. The support system also includes a respective wheel assembly coupled to each distal end. Each wheel assembly includes an independently powered and steerable wheel configured to engage a travel surface, a propelling motor configured to drive a respective first support arm between a stowed condition and a deployed condition unaided while the vehicle remains stationary, and a steer actuator configured to change an angle of the wheel with respect to a respective support arm.

A delivery system includes a handheld electric lift configured to lift at least one vaporizer vessel, and a cabinet configured to hold the at least one vaporizer vessel. The lift includes an elongated mast, an effector attached to the mast, a handler configured to move the lift, and at least one caster. The effector is controlled by an electric power source to move along the mast. Each of the at least one caster includes a stopper and a wheel. The stopper is elongated and is disposed above the wheel. The stopper is configured to engage with the wheel to prevent the wheel from swiveling when the stopper is pushed down. The stopper is further configured to disengage with the wheel to allow the wheel to swivel when the stopper is released. The cabinet includes at least one channel configured to accommodate the at least one caster.

A lift truck clamp assembly with replaceable wear elements. The clamp assembly comprises a clamp plate, a shoe plate, a plurality of wear elements, and one or more grip elements. The shoe plate is harder and more wear resistant than the clamp plate and is detachably coupled to a lower inside surface of the clamp plate. The wear elements are coupled to a bottom edge of the shoe plate and extend below the clamp plate. Through the shoe plate pass a plurality of grip element holes. Each grip element has a plateau and a lip. The lip is on a periphery of the grip element, surrounding the plateau. Each of the grip elements is positioned with the pad plateau protruding through one of the plurality of grip element holes, with the pad lip held between the shoe plate and the inside surface of the clamp plate.