The present application claims priority to German Patent Application No. 10 2020 131 617.8 filed on Nov. 30, 2020. The entire contents of the above-listed application is hereby incorporated by reference for all purposes.
The disclosure relates to a mobile crane comprising a superstructure having at least one bearing point for pinning on a boom.
As a rule, mobile crane comprise an undercarriage as a chassis. A superstructure can be rotatably placed onto the undercarriage via a rotary connection about a vertical axis. The crane boom is pivotally connected to the superstructure. A decisive criterion in the design of a mobile crane is the total weight as legally regulated maximum axle loads have to be observed for driving operation in public road transport. A possibility of dismantling the boom is therefore frequently provided with large mobile cranes.
Such a dismantling capability of the boom is, however, only offered at the request of the customer since it is associated with a substantial increased effort. A pin pulling device thus has to be installed on the crane, for example, to be able to push/pull the pins for the fastening of the boom to the superstructure for installation/disassembly. The typically hydraulic drive of the pin pulling device requires the laying of any required hydraulic and control lines. The pin connection of the luffing cylinder to the boom also has to be retrofitted accordingly.
The pin connection between the superstructure and the boom comprises two spaced apart side parts of the superstructure between which a connection part of the boom can be introduced. A connection pin is subsequently pushed through the aligned bores within the side parts and the connection part. The spacing of the side parts, i.e. their clear width is coordinated with the width of the connection part to limits the axial play of the connection part, i.e. a relative movement between the connection part and the side parts, as much as possible in the axial direction of the pin. There is, however, a disadvantage in that the installation/dismantling of the boom is made more difficult as the play decreases.
An auxiliary crane, for example, takes up the boom on the dismantling of the boom. The pin pulling device subsequently pulls out the two boom pins and the connection to the luffing cylinder is released. The boom is thereby free and the auxiliary crane can lift it and subsequently place it onto a transport apparatus. On the installation or dismantling of the boom with only an auxiliary crane, however, the small play between the steel construction of the superstructure and the boom can have the result that the boom can rotate about the longitudinal boom axis due to tolerances in the chain suspension, the suspension lugs, and the fastening points on the linkage piece. If such a rotational movement occurs, the boom can jam within the side parts of the bearing points of the superstructure, which can represent a situation for the total installation procedure that is complicated to overcome.
It is therefore necessary to find a compromise between axial play and handling during the installation/dismantling of the boom. However, a setup with as little play as possible is desirable to avoid relative movements between the boom and the superstructure construction, but to increase the play for the installation procedure to simplify the work there.
It is proposed in accordance with the disclosure that the clear width between the side parts of the bearing point of the superstructure has larger dimensions than the width of the connection part of the boom to be inserted there. This is a requirement for an axial play between the side parts and the inserted connection part. An axial play of, for instance, 5 mm between each side of the connection part and the oppositely disposed side part is ideal, for example. In this case, the clear width between the side parts is 10 mm larger than the width of the connection part. An axial play of at least 5 mm per side would be sufficient for a smooth and fast installation and dismantling procedure. It is pointed out that the disclosure is independent of the exact dimensioning of the play. The key idea of the disclosure namely comprises compensating an axial play provided for construction reasons due to the above-described design specification by means in accordance with the disclosure in crane operation. The use of such means is, however, independent of the actual play.
To compensate the structurally induced axial play in the installed state of the crane ready for operation, it is proposed in accordance with the disclosure to use a step pin as the connection pin. Such a step pin is characterized by a step-like diameter change, whereby the step pin forms a step that is also called a shoulder in the following. The shoulder that is formed serves as an axial abutment for the connection part in the pushed-in state of the step pin to limit the axial play between the side part and the connection part.
In this respect, the shoulder projects at least partially into the space between the side parts, i.e. into the remaining free space between the connection part and the oppositely disposed side part. The bore diameter of the connection part has smaller dimensions than the diameter of the shoulder. In this manner, a sufficient play for a smooth installation/dismantling is provided between the connection part and the side part with a pulled-out connection pin. After the pushing in of the connection pin, this play is bounded by the shoulder so that no or only a considerably reduced relative movement is possible between the connection part and the side parts in the axial direction of the connection pin.
The pin is typically pushed in the direction of the boom luffing axis to connect the boom to the superstructure. At least two pin connections may be pushed in separately for the boom installation, with the at least two pins ideally both being designed as step pins. In some embodiments, the step pins are pushable in the direction toward the luffing axis, with the shoulder of each pin connection in this case being between the outwardly disposed side part and the connection part.
The connection part of the boom comprises a bore for receiving the step pin. A bushing may be inserted into the bore with an exact fit. The diameter of the pronounced shoulder of the step bolt has larger dimensions than the diameter of the bushing so that the outwardly disposed front face of the bushing abuts the oppositely disposed shoulder of the pushed-in step pin and a movement of the boom toward the superstructure in the axial direction is thereby prevented.
At least one pin pulling device that is typically designed as a hydraulic device is respectively provided for the automatic actuation of the one or more step pins. It is conceivable in this connection that the step pin is designed as hollow and thus itself serves as a cylinder for the hydraulic drive of the pin pulling device. The required setting piston is fixed in a static manner to the superstructure and projects into the hollow space of the step pin. By applying pressure to the hollow space of the step pin, the latter can be actuated and can be moved in the linear direction on the static setting pin. A termination of the open pin side with an integral rod leadthrough provides the pressure-tight closure of the hollow step pin.
Since the bore diameter of the side parts, at least that of the outwardly disposed side part, is coordinated with the shoulder diameter and since the pin diameter, however, varies over the possible displacement path on the pushing/pulling of the pin due to the step, an additional guidance of the step pin has to be provided over the total displacement path to support its own weight. A possible approach provides for one or more guide rods that are arranged in parallel with the step pin. The guide rods can be fixed to the superstructure configuration, such as to the side part, whereby any forces introduced into the guide rods by the pin can be introduced on a direct path into the superstructure construction. The step pin has corresponding sliding surfaces that slide along the guide rods on the pin actuation.
The provision of a total of four or more guide rods is conceivable that are arranged symmetrically around the periphery of the step pin. The guide rods can be connected at the end sides, i.e. at their free ends, by means of a connection plate. The free rod end of the setting piston can also engage at this connection plate.
The configuration of the connection pin in accordance with the disclosure with at least one shoulder as an abutment surface has the result where applicable that the step pin additionally has to take up forces acting in the axial direction. Such axial forces are caused by the rotational movement of the superstructure, such as on the acceleration or deceleration of the superstructure. Since the step pin would forward the forces acting in the axial direction to the pin pulling device, but the latter is not designed for such forces under certain circumstances, it either has to be provided with larger dimensions or alternatively an additional force limitation device has to be provided. The latter could be provided by one or more additional locking means that block a linear movement of the pin during crane operation. Such locking means are directly connected to the superstructure construction to ensure a direct force transmission. In accordance with an embodiment variant, the locking means can be configured as locking pins that extend transversely to the axial axis of the pin. It is conceivable to fasten the locking pins to the superstructure construction via one or more force baffles. At the same time, the locking pins are indirectly or directly fastened to the step pin by corresponding mating connection means so that said step pin is fixed as a result and the acting axial forces can be introduced into the superstructure construction via the locking pins. The connection of the locking pins to the force baffles and/or mating connection means is designed as releasable to be able to release the lock connection to pull out the step pin.
It is conceivable that such locking pins can be installed directly at the surface structure at the end side by suitable force baffles, for instance while forming a form fit, whereby a direct leading off of the axial forces that occur into the superstructure construction is possible. The mating connection elements can be relief plates that are fixed to the step pin. The connection can also take place here between the relief plates and the locking pin.
Further properties of the disclosure will be explained in more detail in the following with reference to an embodiment shown in the Figures. There are shown:
The installation and dismantling of a boom at the superstructure of a mobile crane should be simplified by the solution in accordance with the disclosure.
Details of the pinning points 5 in accordance with the disclosure will be discussed in the following with reference to the detail views shown in
To simplify the installation/dismantling of the boom 4, the width of the boom 4 that is defined via the outer spacing of the end faces of the boom bushing 7 is kept smaller than the clear width of the steel construction in the superstructure 3, i.e. between the side parts 31b on the left and right sides. The axial play of the connection part 4a and of the respective side wall 31b thus achieved on the left and right sides should respectively be in the range of 5 mm. This would be sufficient for a substantially faster installation and dismantling of the boom 4.
The connection pin 50 used is designed as a step pin 50 that has a shoulder 51 having a larger diameter as a substantial feature. The shoulder 51 projects slightly out of the bore 31c of the right side wall 31b into the clear space between the side walls 31a, 31b in the installed state (see
The design is mirror inverted, but otherwise identical, for both pin points in accordance with
In the dimensioning of the step pin and also of the bearing points within the side walls 31a, 31b, the statistical notch in the pin 30 has to be observed that is present due to the diameter variation. The boom bushing 7 introduces a perpendicular force (radial to the bearing point) into the bearing region (side walls 31a, 31b) of the step pin 50. One of the two abutments of the step pin 50, the outer side wall 31b here, has a larger bore diameter for the pin leadthrough since the shoulder 51 of the step pin 50 has to be supported in this region. The cross-sectional change is thus located in the heavily loaded region of the step pin 50. The step pin 50 does not only have to be able to endure this load without damage and in the long term, but this capability must also be demonstrated by calculation with the necessary safety supplements.
An axial force, i.e. in the axial direction of the pin 50, can arise in crane operation in addition to the radial force. This force is mainly caused by starting or braking in slewing gear operation. The load here has to be laterally accelerated, whereby lateral forces arise in the pin connection 5 of the boom 4. This axial force predominantly has to be taken up by the shoulder 51 in the solution in accordance with the disclosure and the step pin 50 would forward the force to a pin pulling device 10 installed outwardly at the superstructure construction 3.
The pin pulling device 10 is hydraulically actuable, with the hollow step pin 50 forming the cylinder chamber 50a. A setting piston 57 is disposed within the chamber 50a and the latter is closed in a pressure-tight manner by means of the termination plate 58. The rod of the setting piston 57 is led through to the outside via a rod leadthrough of the termination plate 58.
The design of the inner hydraulic components of the pin pulling device 10 can, however, not be designed as so strong that it could take up the axial force to be borne by the shoulder 51 in crane operation. The pin pulling device 10 has to be protected from the axial force in crane operation for this reason. This is achieved by a latch device 101 (
The upper end of the latching pins 313, 314 projecting over the upper force baffle 311 has an eyelet through which a securing pin 315 can be pushed. When not in use, i.e. when the step pin 50 is to be pulled, the securing pin 315 is removed and the latching pins 313, 314 can be pulled out upwardly out of the plates 311, 312, 52, 53. The latching pins 313, 314 can be stowed at the superstructure 3 by means of the holder 316.
Due to the step-like design of the step pin 50, its diameter additionally varies in the direction of displacement. The bore diameter of the outer side part 31b of the superstructure 3 is coordinated with the diameter of the shoulder 51. If the step pin 50 is pulled by the pin pulling device 10, the diameter-reduced part of the step pin 50 is located in the bore 31c of the side part 31b and a sufficient support is no longer ensured (see
The free end of the piston rod 57 is additionally installed at the end plate 59; a connection position for the hydraulic supply of the pin pulling device are equally accommodated there.
The following claims particularly point out certain combinations and sub-combinations regarded as novel and non-obvious. These claims may refer to “an” element or “a first” element or the equivalent thereof. Such claims should be understood to include incorporation of one or more such elements, neither requiring nor excluding two or more such elements. Other combinations and sub-combinations of the disclosed features, functions, elements, and/or properties may be claimed through amendment of the present claims or through presentation of new claims in this or a related application. Such claims, whether broader, narrower, equal, or different in scope to the original claims, also are regarded as included within the subject matter of the present disclosure.
Number | Date | Country | Kind |
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10 2020 131 617.8 | Nov 2020 | DE | national |
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