The telescopic lift arm (1) for self-propelled operating machines (10), such a lifters, telehandlers and the like, comprises three tubular elements (21, 22, 23, 24, 25, 26), having a decreasing section and telescopically connected to one another to define a support structure which is able to move between a retracted configuration in which the tubular elements (21, 22, 23, 24, 25, 26) are inserted in one another, and an elongate configuration, in which two tubular elements are extracted. The arm (1) comprises a hydraulic actuator (4), associated to the support structure (21, 22, 23, 24, 25, 26) and provided with three hydraulic elements (41, 42, 43) telescopically connected to one another, each of which is connected to a respective tubular element of the support structure.

The overhanging storage mechanism for a jib is provided with: a guide roller (31) provided to a jib (15); a guide (32) provided to a base end boom (14a); a jib-fixing pin (43) provided to the base end boom (14a); and a pin socket (45) that is provided to the jib (15) and that comprises insertion holes (48), (49). The jib-fixing pin (43) and the insertion holes (48), (49) are arranged so that the jib-fixing pin (43) is inserted in the insertion hole (48) when the jib (15) moves along the base end boom (14a) together with contraction of a boom (14). The inner dimensions of a front end opening (48) are larger than the outer dimensions of the jib-fixing pin (43). It is thus possible to absorb positional displacement between the jib-fixing pin (43) and the insertion hole (48).

A system and method of this disclosure control an on/off state of a power take-off by monitoring the power demand of a fluid power circuit that includes the power take-off and a piece of equipment connected to the power take-off. The power demand may be indicated by a pressure or temperature of a fluid power circuit, by a motion of the equipment or its hand-held controller, or by an engine torque of an engine driving the power take-off. When the equipment transitions between an off state and an on state, the controller automatically engages the power take-off. When the equipment is in the on-state for a predetermined amount of time and the power demand is at or below a predetermined threshold during the predetermined amount of timethereby indicating idle time or an inactive state of the equipmentthe controller automatically disengages the power take-off.

A mobile crane comprising a telescopic boom which has a main casing with linearly moveable inner casings. Guying equipment can be added to the telescopic boom, where at least one securing region arranged on the main casing is provided for the fixing of the guying equipment. In order for the adding and removal of the guying equipment to and from from mobile crane to be carried out more easily and safely, at least one coupling region is arranged on one of the inner casings for adding and/or removing the guying equipment and which can be connected to the same. In this way, the guying equipment can be received directly from a transport unit by the at least partially extended telescopic boom, the guying equipment can be moved onto the main casing by retracting the telescopic boom and coupled to the same.

A mounting framework of a vehicle crane in which at least one bracing arm of a bracing apparatus of the vehicle crane can be temporarily stored on the mounting framework, where the mounting framework comprises at least one displaceable sliding frame and a single bracing arm can be temporarily stored on the sliding frame. In order to provide a mounting framework of a vehicle crane with an optimized placing option for a bracing apparatus on the lower carriage, the mounting framework comprises one displaceable sliding frame. A vehicle crane is configured with such a mounting framework and embodiments include a method for mounting a bracing apparatus on a telescoping jib of a vehicle crane comprising such a mounting framework.

A boom system includes a base assembly, a boom assembly coupled to the base assembly, and a controller. The boom assembly includes a boom including a series of boom sections, a first implement coupled to a first boom section, a second implement coupled to a second boom section, and an actuator configured to vary a lateral distance between the first implement and the second implement. The controller is communicably coupled with the boom assembly and configured to control the actuator to prevent the lateral distance between the first implement and the second implement from falling below a minimum distance.

A boom truck having a grapple bucket with first and second jaws which controllably pivot on an axle from an open to partly closed jaw positions. The bucket picks up a debris-carrying bag via lifting straps. The bucket has an elongated hanger, one end mounted on the first jaw and an opposing strap carrying, terminal end which transverses the axle in open jaw position. Bucket a wiper mounted on bucket's second jaw with a wiper surface adjacent hanger's strap carrying region in open position. Hanger's terminal end region is foreshortened such that the end arcuately bypasses wiper's surface during pivotal movement of both jaws during transition from open to partly closed jaw positions. method of lifting, carrying and depositing a debris-carrying bag having at least one lifting strap. Method includes placing lifting strap on strap carrying region and lifting the bag in the open jaw position. With grapple in final deposition position, jaws pivot from open position to partly closed jaw position and strap is pushed off the strap carrying region by a wiper mounted on the second jaw. Creating gap between strap carrying region and wiper off-loads strap via gap in the closed, bag deposition position.

The disclosure relates to a driving apparatus for a mobile crane comprising an internal combustion engine, an electric machine, and a transfer case for selectively distributing power outputted to the transfer case to a driving mechanism, and to a pump arrangement for performing crane operation, wherein the internal combustion engine cooperates with an input shaft of the transfer case that cooperates with the driving mechanism, the electric machine cooperates with an intermediate shaft of the transfer case, and the pump arrangement cooperates with an output shaft of the transfer case. The driving apparatus comprises a first clutch arranged between the input and intermediate shafts for coupling them to each other or decoupling them from each other as required, and a second clutch arranged between the intermediate and output shafts for coupling them to each other or decoupling them from each other as required.

Provided is a crane including: an operable function part; an actuator; a generation part; a filter part filtering a first control signal and generating a second control signal; a control part controlling the actuator based on the second control signal; and a computation part computing information relating to a flow quantity estimated as the operable function part moving, if a stop signal has been inputted into the actuator at the present position of the operable function part, from when the stop signal has been inputted into the actuator to when the operation of the operable function part stops. The control part outputs the stop signal to the actuator if information relating to the present position of the operable function part, information relating to a target stop position whereat the operable function part is to be stopped, and the information relating to the flow quantity satisfy prescribed conditions.

A crane includes a lower works having one or more ground engaging elements, an upper works connected to the lower works, the upper works having a boom, and a system for determining a crane status. The system includes a sensor assembly positioned to have a line of sight along at least a portion of a length of the boom or the lower works. The sensor assembly configured to detect light transmission and output sensor information. The system further includes a computer configured to receive the sensor information and determine the crane status based on the sensor information. A method of determining the crane status is also provided.