EP1460024A1 - Anchorng for column of swivel crane - Google Patents

Abstract

A davit rests on a concrete foundation (14). The davit has an upright column (1) with a small first circular base ring (4) that is bolted (5, 6) on top of a second much larger base ring (7). The large ring (7) outer margin rests on a third spacer ring (8) forming a void under the second ring. The spacer ring has a link passage between the outer margin and the void.

Description

The invention relates to the attachment of a column slewing crane on a finished concrete floor at any point without an additional foundation or anchor under the floor, the column slewing crane essentially consisting of the column, the horizontally and pivotably arranged swivel arm at its upper free end with a longitudinally movable lifting mechanism and there is a foot flange at the lower end of the column and the foot flange is screwed to an adapter plate that is attached to the concrete floor.

Slewing cranes (see DE-Z: Conveying and lifting, 1971, No. 8, page 444) usually have tubular columns, at the foot end of which are welded annular or square flanges or base plates, by means of which they can be fastened to a foundation. The attachment to the foundation is done by screwing, welding or similar, common in steel construction.

In most cases, if no other option is available, the foundation chosen is a concrete foundation that has appropriate facilities for fastening the crane. The foundation is manufactured in the manner customary in concrete construction, the device for later attachment of the crane being provided during the manufacture of the foundation. Here, according to a design known from practice, anchor shafts are provided for the later use of anchor bolts. In this known design, the anchor bolts are inserted into the anchor shafts after the concrete foundation has set, aligned using a template and poured with concrete. After the concrete setting time, the Crane column attached, aligned with nuts on the anchor bolts and screwed. Subsequently, a concrete grouting of the base flange of the crane column is absolutely necessary in order to achieve a flat support of the base flange of the crane column. After a further period of time, which is necessary to set the concrete base, the crane can be accepted with the appropriate test load and the crane can be put into operation.

In a further known version of the concrete foundation, the anchor bolts are cast directly into the foundation, the alignment of the anchor bolts being carried out with the aid of templates. The crane column is then assembled in the same way as in the first described version. Here, too, it is always necessary to either screw nuts onto the anchor bolts or to place wedges on which the crane column is placed and then aligned.

Due to the concrete underpouring of the foot flange of the crane column, the rigid and statically secure attachment of the crane column to the foundation also takes place in this version.

This known design of a device for fastening a crane has decisive disadvantages. Thus, the recessing of the anchor holes in the foundation manufacture according to the drawing is necessary and difficult, since the exact hole divisions must be observed and, for structural reasons, the anchor shafts have to be tapered downwards, which in turn leads to difficulties in the manufacture, arrangement and subsequent removal of the corresponding ones Formwork leads. Another disadvantage of this design is that the anchor shafts are very difficult to clear out and any waste that is present hinders the structurally safe fastening of the anchor bolts. Another disadvantage is that after the actual foundation production, the anchors have to be concreted in later and after a minimum setting time of the concrete, only the crane assembly can take place, in which case the base flange of the crane must in turn be cast in concrete. The crane can only be accepted and put into operation after the underpour has set, which in turn leads to a considerable time delay.

These types of fastening of the column of a column slewing crane on a foundation described above have the further disadvantage that the arrangement of the crane must be planned in order to bring the concrete foundation in the right place or it is necessary to destroy the existing floor over a large area or in a complex manner to incorporate the necessary equipment for fastening the column of the column slewing crane. In particular, each of the versions described above has the disadvantage that the required approval must be obtained for the erection or leasing of halls when erecting pillar jib cranes and the hall floor must be restored in a complex manner when leaving the hall or dismantling the pillar jib crane.

It is known to provide cranes at their lower foot end for fastening to an existing concrete floor with large rectangular, welded plates and stiffened with large gusset plates. These plates can only be rotated by 90 ° each, which can lead to difficulties with regard to the required swivel angle in the case of brackets which cannot be swiveled 360 °.
It is also known to anchor large rectangular slabs either by anchors below the concrete floor or by dowels. The holes (approx. 80 - 100 mm ⌀) for the anchors have to be made in a complex manner. The panels are then to be poured over the entire surface. The bottom casting requires additional effort (hardening, concrete shrinkage) and a large construction dimension up to the top edge of the slab in order to be able to insert the bottom casting.

Another disadvantage of the above-described, known designs of column-mounted jib cranes and their attachment is that the base plates or foot flanges often have to be very large for structural reasons and thus adversely affect the transport of the column of the column-mounted jib crane and a considerable amount of space is required when storing several column-mounted jib cranes is.

Another disadvantage of the previously known designs is that the base plate of the jib crane is generally quadrangular and frequently destroy concrete reinforcements embedded in the existing floor. A further disadvantage of the rectangular base plates is that the concrete floor is destroyed in a line through the required bores, and reinforcements present in the concrete floor then either act as an obstacle or are destroyed over a longer length. Another disadvantage of rectangular base plates is that they take up a lot more space than round base plates and form trip corners on the floor.

The object of the present invention was now to find a way, in particular in the case of existing concrete floors, to design the fastening of the column of a column slewing crane in such a way that the concrete floor does not have to be cut open extensively for a foundation and does not have to be destroyed and removed so that the column slewing crane can be attached to any Place of the concrete floor can be set up, that no approval procedure is required, that no complicated reworking of the concrete floor is required when dismantling the column slewing crane, that if there are obstacles in the concrete floor, these can be taken into account by rotating the adapter plate accordingly, that the plate is under-poured can be dispensed with, a low construction height up to the top edge of the slab can be achieved, a linear perforation / load on the concrete floor Avoid the energy supply in the shortest possible way without prying open the floor and enable quick commissioning.

This object is achieved according to the invention in a pillar jib crane of the type mentioned at the outset in that the adapter plate is ideally round, has at least one circumferential stand frame on its underside and that this stand frame has at least one radially extending downwardly open groove (opening). having. This embodiment according to the invention achieves decisive advantages. For example, by rotating the adapter plate, it can be positioned in such a way that the cable feed, e.g. coming from a wall or support, can be guided through the groove in the stand frame of the composite anchor plate in the shortest possible way. Due to the round shape of the adapter plate and the arrangement of the fastening dowels on a bolt circle near the periphery of the adapter plate, the fastening dowels do not lie in a line in the concrete floor (there is a risk of cracking), but are always offset to one another, thereby avoiding the risk of cracking. Furthermore, a reinforcing bar in the concrete floor is not destroyed several times by the dowels arranged on a bolt circle. With expansion joints in the concrete floor, the staggered, round arrangement of the adapter plate means that only one dowel is closest to the concrete edge or expansion joint. The adjacent dowels are then already at a greater distance from the concrete edge or the expansion joint. In the case of round adapter plates, the jib pivot point can be adapted much more precisely to the on-site situation with regard to the usable swivel angle for slewing cranes with a limited swivel range, since the round adapter plate can be rotated on the outer bolt circle due to the even division of the large number of dowels. The round design of the composite anchor plate eliminates trip corners. Due to the simple, geometric, round shape, a bevel can easily be attached to the circumference on the upper side, which prevents tripping edges. Further advantages are uniform loading of the individual dowels in every position of the swivel arm, a considerable gain in space or gain in overhang / Gain in size for the arrangement of the column slewing crane through the round adapter plate, easier transportation due to the small foot flange without the large adapter plate, easier handling when assembling the column slewing crane.

According to the invention, the adapter plate ideally has two concentric rows of holes.

It is favorable to provide the adapter plate with a chamfer on its upper edge.

The adapter plate is advantageously attached to the concrete floor using heavy-duty dowels, threaded rods, washers and nuts embedded in the concrete floor.

The adapter plate advantageously has a hole in the center for the passage of power lines.

It also makes sense that the composite mass for the dowel attachment consists of 2-component material that hardens after a very short time (usually in an hour) and that the column slewing crane can be commissioned after a short time.

The further advantageous embodiment of the invention is described in the subclaims.

• Fig. 1
  Die Ansicht eines Säulenschwenkkranes, dessen Befestigung auf einem Betonfußboden, zum Teil im Schnitt.
• Fig. 2
  Die Einzelheit "A" der Fig. 1 in vergrößerter Darstellung.
• Fig. 3
  Die Draufsicht auf die Einzelheit nach Fig. 2 (ohne Kranfuß)

Details of the invention are explained using an exemplary embodiment in the drawing.
Show it

• Fig. 1
  The view of a pillar jib crane, its fastening on a concrete floor, partly in section.
• Fig. 2
  The detail "A" of Fig. 1 in an enlarged view.
• Fig. 3
  The top view of the detail according to FIG. 2 (without crane foot)

Column slewing cranes usually consist essentially of the vertical column (1), the swivel arm (2), which is horizontally swivel-mounted at its upper end, with the lifting mechanism (3), which is longitudinally displaceably mounted on the swivel arm (2) and a foot flange (4) on lower end of the column (1). The foot flange (4) is screwed to a round adapter plate (7) using threaded holes (5) in a bolt circle (11) with screws (6). The underside of the adapter plate (7) has a flat stand frame (8) on the outside, which has at least one radially extending, downwardly open groove (opening) (9). On its upper side, the adapter plate (7) is provided with a bevel (10) on its outer edge. The adapter plate (7) has an inner bolt circle (11) and an outer bolt circle (12). The adapter plate (7) is connected to the foot flange (4) of the column (1) via the inner bolt circle (11). The holes (13) in the outer bolt circle (12) of the adapter plate (7) are screwed to the concrete floor using heavy-duty dowels (15), threaded rods (16) and nuts (17) embedded in the concrete floor (14). A hole (18) is arranged centrally in the adapter plate (7), through which the energy supply lines are introduced into the pillar jib crane. The groove (9) in the stand frame (8) of the adapter plate (7) can be arranged by rotating the adapter plate in such a way that the energy supply lines through this groove (9) take place in the shortest possible way.
The number of dowels (15) is advantageously 1.33 to 3 times larger than the number of screws (6) in the foot flange (4).

Claims (14)

Fastening a column slewing crane on a finished concrete floor (14) at any point without additional foundation or anchor under the floor, the column slewing crane essentially consisting of the column (1), with the swivel arm (2) arranged horizontally and pivotably at its upper free end this longitudinally movable hoist (3) and a foot flange (4) at the lower end of the column (1), and the foot flange (4) is screwed to an adapter plate (7) which is fastened to the concrete floor (14), characterized that the adapter plate (7) is ideally round, has at least one circumferential stand frame (8) on its underside and that this stand frame (8) has at least one radially extending groove (opening) (9) which is open at the bottom having. Fastening according to claim 1, characterized in that the adapter plate (7) has two concentrically running rows of holes (11 and 12). Fastening according to claims 1 and 2, characterized in that the adapter plate (7) has a bevel (10) on its upper edge. Fastening according to claims 1 to 3, characterized in that the adapter plate (7) is fastened to the concrete floor (14) by means of heavy-duty dowels (15) embedded in the concrete floor (14), threaded rods (16), washers and by nuts (17) , Fastening according to claims 1 to 4, characterized in that the adapter plate (7) has a hole (18) in the center. Fastening according to claims 1 to 5, characterized in that the heavy-duty dowels (15) are anchored in the concrete floor (14) by means of two-component material. Fastening according to claims 1 to 6, characterized in that the adapter plate (7) receives a non-slip paint / covering for the inspection. Fastening according to claims 1 and 3 to 7, characterized in that the adapter plate (7) has two concentrically arranged rows of holes (12) for fastening dowels and a bolt circle (11) for fastening the foot flange. Fastening according to claims 1 to 8, characterized in that two stand frames (8) are used under the adapter plate (7). Fastening according to claims 1 to 8, characterized in that the stand frame (8) is arranged on the periphery of the adapter plate (7). Fastening according to claims 1 to 10, characterized in that the bores (13) for the heavy-duty dowels (15) are arranged in the adapter plate (7) in the region of the stand frame (8). Fastening according to claim 1, characterized in that the center axis of the bolt circle (11) for the crane fastening is arranged offset to the center axis of the bolt circle (12) for fastening the adapter plate (7) on the concrete floor (14). Fastening according to claim 1, characterized in that the adapter plate (7) and the bores (13) for fastening the adapter plate (7) on the concrete floor (14) are oval or elliptical. Fastening according to claim 1, characterized in that the adapter plate (7) is designed as a polygon approximating a rounding.

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