The invention relates to a mobile crane having an undercarriage and a superstructure rotatable with respect to the undercarriage about an axis of rotation and to a ballast receiving apparatus arranged at the superstructure and having at least one ballasting cylinder for receiving ballast.
Mobile cranes require a working space determined by the type of construction at a construction site to ensure a full and safety-compliant mode of operation. There is often only limited space available due to projecting edges at the construction site which can be produced by walls, planting or further work equipment.
In this respect, the required working space is substantially determined by two factors. Whereas the first factor is represented by the support base which is defined by the respective support apparatus depending on the equipping state, the superstructure radius of rotation as the second major factor, that is the outermost edge of the superstructure on the rotation of the superstructure about the undercarriage, determines the working space of the mobile crane. As a rule this superstructure radius of rotation is influenced by the mounted ballast plates or by the apparatus for receiving the ballast plates since an installed ballast receiving apparatus, including the ballast plates, frequently projects the furthest out of the superstructure.
If the superstructure radius of rotation is reduced, the required working space for the mobile crane admittedly reduces on the one side. However, on the other side, the distance from the center of gravity of the ballast to the axis of rotation of the superstructure about the undercarriage is reduced. This in turn, however, reduces the torque which acts against the load torque caused by the load.
DE 20 2010 002 364 U1 already looks into this problem and provides a mobile crane which has a first and a second ballast receiving apparatus which differ from one another with respect to their physical dimensions and which are selectively releasably connected or connectable to the superstructure of the mobile crane. The ballast receiving apparatus used defines the superstructure radius of rotation which is described by the outermost component or the outermost edge of the ballast receiving apparatus in the radial direction on a rotary movement of the superstructure. The support base and the superstructure radius of rotation can be matched to one another by the selective installation of the first or second ballast receiving apparatus on the mobile crane. This solution admittedly optimizes the superstructure radius of rotation, but has the result that two separate ballast receiving apparatus have to be provided and have to be kept available by the operator of the mobile crane.
It is therefore the object of the invention to further develop a mobile crane of the category whose construction space minimizes the required working space at the construction site with as few additional components as possible.
The object is solved in accordance with the invention by the combination of the features herein. A mobile crane is accordingly provided having an undercarriage and a superstructure rotatable with respect to the undercarriage about an axis of rotation and a ballast receiving apparatus arranged at the superstructure and having at least one ballasting cylinder for receiving ballast, wherein the position of the ballasting cylinders receiving the ballast in the ballast receiving apparatus is variable such that the ballast can be received in positions of different distance from the axis of rotation of the superstructure.
It is therefore particularly advantageously no longer necessary with the mobile crane in accordance with the invention to keep differently dimensioned ballast receiving apparatus available. A different superstructure radius of rotation can rather be provided with a variably arranged ballast receiving apparatus. In this respect, the ballast receiving apparatus can receive the ballast in at least two different positions. Each position has its own distance from the axis of rotation of the superstructure about the undercarriage. The same counterweight can thus exert a different counterweight torque and can act against the respective load torque to be taken up.
It is generally more sensible not to generate the static torque by the increase of the counterweight, but rather by the enlarging of the radius of the ballast since the counterweight itself also acts as a normal force on the undercarriage. The undercarriage can therefore be relieved by reducing the taken along counterweight due to the possibility of increasing the superstructure radius of rotation.
Preferred embodiments of the invention result from the description herein.
In accordance with a first specific solution for the positional variation of the ballasting cylinders, provision can be made in accordance with the invention to support the ballasting cylinders on rails and to displace the them in accordance with the longitudinal axis of the superstructure in order thus respectively to increase or decrease the distance from the axis of rotation. On a displaceability of the ballasting cylinders along corresponding rails, a drive, for example a hydraulic piston-in-cylinder arrangement, is preferably provided for displacing the hydraulic cylinders along the rails. On provision of a corresponding drive, the ballasting cylinders can be positioned at any desired distance from the axis of rotation within the displacement range and can be fixed in position by fixing the drive.
In accordance with an alternative solution within the framework of the invention, ballasting cylinders fixed in position can also be used instead of the movable ballasting cylinders. In this case, four ballasting cylinders are preferably arranged fixed in position at the superstructure, with them each being arranged in pairs behind one another with respect to the axis of rotation of the superstructure. In this respect, the respective pair of ballast cylinders disposed closer to the axis of rotation or the pair of ballasting cylinders disposed further away from the axis of rotation can be activated for receiving the ballast. In this preferred embodiment, the counterweight radius is therefore fixed by the selection of the ballasting cylinders used.
Finally, in accordance with a further preferred aspect of the invention, the at least one ballasting cylinder is pivotable about a pivot axis vertical with respect to the superstructure. In this respect, the ballasting cylinder is advantageously fixable in its position via a locking mechanism. In this solution, two lockable positions are advantageously provided. More lockable positions for fixing the respective pivot angle of the at least one pivotable ballasting cylinder can, however, also be provided in a step-wise manner.
Two pivotable ballasting cylinders are preferably provided which are received in pivot consoles which are in turn pivotable about the vertical pivot axes.
In a particularly favorable embodiment variant, a manual operation, that is muscular strength, is provided for pivoting the ballasting cylinders. To keep the required forces in a reasonable framework, a smooth-motion support, for example from bronze or polyamide, is preferably provided. In a somewhat more complex embodiment, a drive can alternatively naturally also be provided, for example, via a pneumatic piston-in-cylinder arrangement, a hydraulic piston-in-cylinder arrangement or also a hydraulically driven spindle unit.
The locking mechanism for fixing the ballasting cylinder in a specific pivot position advantageously comprises a spring-loaded pin which can be drawn against the spring force. The pivoting of the respective ballasting cylinders arranged at a pivot console can thereby be carried out from the ground. A spring-loaded pint can her be drawn by the operator via a rod here and the pivot console can subsequently be rotated. The pin itself then automatically locks in one of the correspondingly provided end positions due to the spring load.
Finally, a location monitoring of the position of the respective ballasting cylinder is advantageously integrated which is able to forward the respective position of the monitored ballasting cylinder to the crane control. The position of the counterweight, which can be determined by the respective position of the ballasting cylinder, is a criterion for the payload table of the crane to be used. Human error on the inputting of the data underlying the payload table can be precluded by the monitoring of the position of the pivot consoles since the input is automated.
Further features, details and advantages of the invention will be explained in more detail with reference to an embodiment shown in the drawing. There are shown:
In accordance with the invention, the ballast receiving apparatus is arranged at the superstructure 18 such that it is positionally variable. The superstructure radius of rotation can hereby be converted from a small radius (
The positional variation of the ballast receiving apparatus is implemented in the embodiment described here by pivotable ballasting cylinders 20 (cf. enlarged detailed representation of
A manual operation, that is muscular strength, is preferably provided as the drive for the pivot movement. The design of the ballast receiving apparatus can hereby be substantially simplified. To keep the required forces in a reasonable framework a smooth-motion support can be used, for example of bronze sleeves or polyamide sleeves. Alternatively, a drive can naturally also be provided here via a pneumatic piston-in-cylinder arrangement, a hydraulic piston-in-cylinder arrangement or a spindle unit (not each shown here).
The ballasting cylinders 20 which can be used here can be of the same construction or almost of the same construction as the ballasting cylinders of the prior art. The basic mode of operation of the ballasting cylinders is also exactly the same as in the prior art in accordance with the present invention, apart from their positional variation by the pivoting. Reference can be made here to the mode of operation such as is described, for example, in DE 20 2010 002 364 U1.
The supply of the energy and signals for the ballasting cylinders 20 takes place via a hose/cable winding or an energy supply chain in a manner not show in any more detail in the Figure. Electrical, hydraulic and, optionally, pneumatic lines are to be provided correspondingly in the energy supply chain.
The ballasting cylinders 20 can therefore be brought into two positions and respectively locked by a corresponding pivoting. In the position in accordance with
As is known from the prior art, an apparatus 28 can be provided at the undercarriage 14 to receive the ballast 12. Once the ballast 12 has been placed on in this manner, it is ready for ballasting by the ballasting cylinders 20. Since the ballast 12 can, however, be received with two different radii of rotation, associated cut-outs 30 for each provided radius of rotation are applied in the receiver of the ballast. These cut-outs correspond to corresponding projections 32 on the apparatus 28 so that the ballast 12 can be received in both positions, that is both in the position of the large counterweight radius and in the position of the small counterweight radius.
Alternatively, however, separate apparatus having corresponding cut-outs can also be provided for every ballast radius. To design the receiving of the ballast 12 on the apparatus 28 in a simple manner, ballast stops 34 and 36 respectively, such as likewise known from the prior art, are installed. The ballast stops 36 for the smaller radius (cf.
Due to the construction, the center of gravity of the ballast 12 projects far beyond the rear of the revolving deck with a large pivot radius b. In order nevertheless to be able to clamp the ballast horizontally to the revolving deck when pulling up, corresponding stops 34 are provided at the pivot consoles 22 or at the ballasting cylinders 20 themselves.
The enlarged representation in accordance with
Alternatively, the pivot console 22 can also be rotated and locked from a platform of the revolving deck, for example by means of a fixed or pluggable lever (not shown in any more detail here).
The position of the ballast is a criterion for the payload table of the mobile crane 10 to be used. To be able to reliably preclude human error here, the position of the ballasting cylinder pivot consoles 22 is monitored by the crane control.
In general, a switch at a pivot console 22 can be sufficient to be able to determine the position of the two pivot consoles 22 and thus of the ballast 12. Since for geometrical reasons no ballast can be received as long as the ballast cylinder pivot consoles 22 have not been located at the same position.
In this solution, a switch having two transponders per pivot console is selected to be able to detect each position. Alternatively, however, it is naturally also possible to provide as a minimum a mechanical switch, for example a roller limit switch, or as a minimum an inductive switch or as a minimum a switch plus as a minimum a transponder.
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5199583 | Weider | Apr 1993 | A |
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Entry |
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Applicants' Answer to Examiner's Questions regarding the Application dated Aug. 21, 2018 (Attached). (Year: 2018). |
Number | Date | Country | |
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20160185576 A1 | Jun 2016 | US |