Mobile operating machine, provided with at least a work device (11) supported by a movement turret (14), at least a pair of stabilizing front legs (12a, 12b) and at least a pair of stabilizing back legs (13a, 13b); the mobile operating machine also comprises a support structure (18) provided with at least a pair of box-like elements (19a, 19b) configured to house the stabilizing front legs (12a, 12b) or back legs, and at least a positioning seating (20) of the movement turret (14) made in a crossing zone (Z) of the box-like elements (19a, 19b); each box-like element (19a, 19b) is provided with a first end (23a, 23b) that is open and through which a respective stabilizing front leg (12a, 12b), or back leg, is slidingly mobile and a second end (25a, 25b), opposite the first end (23a, 23b) and in correspondence with which a respective stabilizing back leg (13a, 13b), or front leg, is pivoted, so as to rotate around a corresponding axis of rotation (R1, R2).

A vehicle leveler spacer and method of using the vehicle leveler spacer that may be selectively attached to a retracted leveler of a vehicle, such as a trailer or motor home. The spacer at least partially supports the vehicle upon extension of the leveler to the ground. The spacer includes at least one connector to selectively connect the spacer to the retracted leveler. The connector may be a magnet, strap, clamp, or another mechanical connector. The top surface of the spacer may include a rim along its perimeter configured to retain a pad of a leveler. The spacer may form a gap between the bottom surface and a supporting surface, e.g. the ground, when the spacer is connected to a retracted leveler. The connectors enable the spacer to be quickly attached or removed from a retracted leveler of a vehicle.

A vehicle leveler spacer and method of using the vehicle leveler spacer that may be selectively attached to a retracted leveler of a vehicle, such as a trailer or motor home. The spacer at least partially supports the vehicle upon extension of the leveler to the ground. The spacer includes at least one connector to selectively connect the spacer to the retracted leveler. The connector may be a magnet, strap, clamp, or another mechanical connector. The top surface of the spacer may include a rim along its perimeter configured to retain a pad of a leveler. The spacer may form a gap between the bottom surface and a supporting surface, e.g. the ground, when the spacer is connected to a retracted leveler. The connectors enable the spacer to be quickly attached or removed from a retracted leveler of a vehicle.

A landing pad that mounts to a foot of a vehicle support. The landing pad includes a bottom with an opening. A side wall extends upward from the bottom with the side wall positioned around a perimeter of the bottom. A top shelf extends radially inward towards the opening from the side wall with the top shelf extending over and being spaced away from the bottom. One or more slots extend from the top shelf to the opening. Each of the one or more slots includes a first section that extends into a lower surface of the top shelf and a second section that extends into a top surface of the bottom with the first section and the second section of each of the one or more slots being aligned to direct water to the opening.

The invention relates to, inter alia, a thick matter conveying system (10) comprising a thick matter pump (16) for conveying a thick matter; a thick matter distributing mast (18) for distributing the thick matter to be conveyed, said thick matter distributing mast (18) having a rotary mechanism (19) which can be rotated about a vertical axis and a mast assembly (40) comprising at least two mast arms (41); a substructure (30) on which the thick matter distributing mast (18) and the thick matter pump (16) are arranged, said substructure (30) comprising a support structure (31) for supporting the substructure (30) by means of at least one horizontally and/or vertically movable support leg (32); a sensor unit (11) comprising a plurality of sensors (111, 112, 113, 114, 115) for detecting a respective piece of operating information, wherein the sensor unit (11) is at least designed to detect a first piece of operating information which indicates the position of the rotary mechanism (19), a second piece of operating information which indicates the position of at least one of the mast arms (41), a third piece of operating information which indicates the position of the support leg (32), and a fourth piece of operating information which indicates the inclination angle of the thick matter conveying system (10); and a processing unit (12) for determining a stability parameter of the thick matter conveying system (10) on the basis of the at least one detected piece of operating information.

The invention relates to, inter alia, a thick matter conveying system (10) comprising a thick matter pump (16) for conveying a thick matter; a thick matter distributing mast (18) for distributing the thick matter to be conveyed, said thick matter distributing mast (18) having a rotary mechanism (19) which can be rotated about a vertical axis and a mast assembly (40) comprising at least two mast arms (41); a substructure (30) on which the thick matter distributing mast (18) and the thick matter pump (16) are arranged, said substructure (30) comprising a support structure (31) for supporting the substructure (30) by means of at least one horizontally and/or vertically movable support leg (32); a sensor unit (11) comprising a plurality of sensors (111, 112, 113, 114, 115) for detecting a respective piece of operating information, wherein the sensor unit (11) is at least designed to detect a first piece of operating information which indicates the position of the rotary mechanism (19), a second piece of operating information which indicates the position of at least one of the mast arms (41), a third piece of operating information which indicates the position of the support leg (32), and a fourth piece of operating information which indicates the inclination angle of the thick matter conveying system (10); and a processing unit (12) for determining a stability parameter of the thick matter conveying system (10) on the basis of the at least one detected piece of operating information.

A support jack including a support foot and a force measuring element, wherein the support jack has an outer tube and an inner tube movably mounted therein, and the support foot the force measuring element is attached to the foot receiving element is pivotally secured to the inner tube by a foot receiving element. The support allows a quantitative and reproducible measurement of the forces transmitted by the support jack to the underlying surface. This is achieved in that the force measuring element is attached to the foot receiving element.

A support jack including a support foot and a force measuring element, wherein the support jack has an outer tube and an inner tube movably mounted therein, and the support foot the force measuring element is attached to the foot receiving element is pivotally secured to the inner tube by a foot receiving element. The support allows a quantitative and reproducible measurement of the forces transmitted by the support jack to the underlying surface. This is achieved in that the force measuring element is attached to the foot receiving element.

The present disclosure relates to outrigger pads, and specifically outrigger stabilizer pads providing a three-dimensional frictional surface, which provides additional stability between the outrigger foot and the staging ground surface. The frictional surface provides the pad with a non-slip feature when the pad is used on slippery surfaces, such as mud, snow and ice. Additionally, the frictional surface of the present outrigger pads provide the pad with interlocking capabilities, either for stacking complimentary outrigger pads on top of one another, or for engagement with another object such as a cribbing block, for changing the height of the outrigger pad.

The present disclosure relates to outrigger pads, and specifically outrigger stabilizer pads providing a three-dimensional frictional surface, which provides additional stability between the outrigger foot and the staging ground surface. The frictional surface provides the pad with a non-slip feature when the pad is used on slippery surfaces, such as mud, snow and ice. Additionally, the frictional surface of the present outrigger pads provide the pad with interlocking capabilities, either for stacking complimentary outrigger pads on top of one another, or for engagement with another object such as a cribbing block, for changing the height of the outrigger pad.