A method for operating a crane, comprising providing a crane with a jib element and an indicator element, wherein the jib element and the indicator element are arranged in a first position; moving the indicator element manually from the first position to a second position; triggering a movement of the jib element from the first position to the second position after the indicator element is arranged in the second position.

A crane with a crane control, wherein the crane control includes rises a coordinate control system with a plurality of nodes defined in the crane, a three-axis coordinate system including x, y and z axes that intersect each other in orthogonal main planes in the space, a node information processing module, a route establishment module and an operation processing module, wherein the node information processing module is configured to collect and store node information in an initial state of the crane, and the route establishment module is configured, based on a control command indicated by a crane operator, to establish an effective operation path for each node to a route in which the operation module is used, in an actual route, for displacing a crane tip included in the crane from a current starting or initial coordinate position in the initial state to a desired target coordinate position in the space.

A crane with a crane control, wherein the crane control includes rises a coordinate control system with a plurality of nodes defined in the crane, a three-axis coordinate system including x, y and z axes that intersect each other in orthogonal main planes in the space, a node information processing module, a route establishment module and an operation processing module, wherein the node information processing module is configured to collect and store node information in an initial state of the crane, and the route establishment module is configured, based on a control command indicated by a crane operator, to establish an effective operation path for each node to a route in which the operation module is used, in an actual route, for displacing a crane tip included in the crane from a current starting or initial coordinate position in the initial state to a desired target coordinate position in the space.

A lifting device on a heavy goods vehicle is described, for lifting and emptying waste collection containers, having a telescopically extensible boom, which has a coupling tool for coupling to a waste collection container. An extensible support is attached on a rotating platform and has at least one interleaved, telescopically extensible profile, wherein the boom is provided at the upper end of the support with a pivot element between boom and support, so that the boom is pivotable in a vertical plane about a pivot axis. The extensible profile is designed as an internal runner having a fixed tube and runners having a polygonal footprint, and a carrier head is provided at the end of the support, which is formed as L-shaped having an overhanging carrier plate in relation to the support, which carrier plate has the pivot axis of the boom and a support for the pivot element.

Hoists, platforms and davits are described as well as methods of securing same to telecommunication and other towers. The hoists, platforms and davits may be secured to the towers on a temporary basis using clamps. The clamps may include brackets and cables. The cables may be attached to the brackets, may wrap around the outer surface/perimeter of the tower pole/leg and may use tension to keep the bracket in place.

Hoists, platforms and davits are described as well as methods of securing same to telecommunication and other towers. The hoists, platforms and davits may be secured to the towers on a temporary basis using clamps. The clamps may include brackets and cables. The cables may be attached to the brackets, may wrap around the outer surface/perimeter of the tower pole/leg and may use tension to keep the bracket in place.

A computer-controlled mobile crane is disclosed herein, comprising a column which is rotatable around its vertical axis, a hydraulically actuated primary arm, a hydraulically actuated secondary arm, and an attachment point to which a gripping assembly is attached. The components are actuated by a hydraulic control unit controlled by a computer control unit and corresponding software that generates an internal coordinate system on the basis sensors mounted on the crane and an optical measuring unit. The crane is capable of automatically using the gripping assembly to transport a load from an initial point to an end point where the load should be deposited while avoiding one or more obstacles in the path of travel of the gripping assembly and the load.

A crane with a crane control, wherein the crane control includes rises a coordinate control system with a plurality of nodes defined in the crane, a three-axis coordinate system including x, y and z axes that intersect each other in orthogonal main planes in the space, a node information processing module, a route establishment module and an operation processing module, wherein the node information processing module is configured to collect and store node information in an initial state of the crane, and the route establishment module is configured, based on a control command indicated by a crane operator, to establish an effective operation path for each node to a route in which the operation module is used, in an actual route, for displacing a crane tip included in the crane from a current starting or initial coordinate position in the initial state to a desired target coordinate position in the space.

This crane control device controls the operation of a boom and a winch and transports a load from a start point to an end point, the control device comprising: an acquisition unit that acquires position information of the start point and position information of the end point; a horizontal trajectory generation unit that, by using an optimal control theory, generates a horizontal trajectory for a distal-end part of the boom as represented by a horizontal-direction component of a straight line linking the start point and the end point; a movement trajectory generation unit that generates a trajectory of movement of the boom for transporting the load so as to follow the horizontal trajectory, and a trajectory of rotational movement of the winch; and a movement control unit that controls the boom and the winch based on the trajectory of movement of the boom and the winch.

This crane control device controls the operation of a boom and a winch and transports a load from a start point to an end point, the control device comprising: an acquisition unit that acquires position information of the start point and position information of the end point; a horizontal trajectory generation unit that, by using an optimal control theory, generates a horizontal trajectory for a distal-end part of the boom as represented by a horizontal-direction component of a straight line linking the start point and the end point; a movement trajectory generation unit that generates a trajectory of movement of the boom for transporting the load so as to follow the horizontal trajectory, and a trajectory of rotational movement of the winch; and a movement control unit that controls the boom and the winch based on the trajectory of movement of the boom and the winch.