EP0430308A2 - Metal scaffolding for buildings - Google Patents

Abstract

In the case of a metal stand scaffold for buildings, in particular a tubular scaffold, the elements (1, 2) of which are connected to couplings (4, 9), the halves (4, 9) of which are fixed to one element (1, 2) and each with a positive fit Wedge gears (8) can be braced, one flank (32, 53) of the driving wedge (12) being assigned to an inclined surface (7) of a coupling half (4) and the flank (13) opposite this being designed as a wedge surface, the driving wedge (12 ) runs in a gap (11) which is recessed in the other coupling half, it is provided according to the invention that the wedge tightening surfaces (40, 41) of the driving wedge (12) are formed on both sides of the driving wedge (12) and their surface planes within the driving wedge (12) converge behind the wedge flank (13), the gap (11) having a wedge groove (43), on the flanks (44, 45) of which the friction surfaces for the wedge tightening surfaces (40, 41) of the driving wedge (12) are formed.

Description

The invention relates to a metal stand scaffold for buildings, in particular a tubular scaffold according to the preamble of claim 1.

Stand scaffolds of this type can be designed as so-called bar scaffolds. In particular, however, the invention relates to tubular rod structures, the elements of which predominantly consist of steel tubes. With these scaffolds, the standpipes are connected to the various bars, which also consist of pipe sections, via the coupling. In particular, the invention relates to modular stand scaffolding, which allow the scaffolding to be largely adapted to the respective building.

In these and other stand structures according to the invention, the couplings are screwless. This makes assembly and disassembly of the scaffolding easier and faster. Nevertheless, the stand scaffold according to the invention is accident-proof, because its couplings can be assembled without error and only with the prescribed elements, but on the other hand can not be unexpectedly released under any circumstances.

The invention is based on a previously known stand structure (EU-PS 0 116 679) whose couplings implement a wedge gear. One on a standing element coupling half is designed as a flange ring and forms the slide of the wedge gear, while the other coupling half is provided with a hook to be hung on the flange ring, which ensures the positive connection.

The gap for the driving wedge lies behind the hook, so that this coupling half forms the frame of the wedge gear. The driving in of the driving wedge leads to the interlocking parts being braced, the coupling half forming the frame in particular being elastically deformed.

Such couplings are functional in stand scaffolding. The driving wedges can be easily driven and unscrewed from unsafe positions when assembling the scaffolding. They can be accommodated captively in the gap, which inevitably guarantees the functional condition of the couplings. You can also run space-saving, so that the coupling halves build small and u. a. assume a crucial weight for the usability of the standing scaffolding. The invention therefore relates to this basic embodiment.

Since the coupling halves described have only one degree of freedom in the known metal stand structure, their driving wedge is guided in the gap only with its wedge flank; it serves as the gear's tightening surface. The driving wedge also only runs with its opposite straight flank on the inclined surface of the flange ring. Such a driving wedge must have a wedge angle that ensures self-locking. This results in a slender flat wedge, the wedge angle of which cannot be made arbitrarily small, however, because the wedge's travel must be limited for functional reasons. In practice, this means that the driving wedges can loosen or even jump out when the scaffolding is shaken. The stress on the couplings of the scaffolding is of considerable magnitude on when swelling stresses occur in the vicinity of the scaffold, such as z. B. triggered by heavy traffic in bridge structures and in the subsoil. If the separating forces of the coupling halves assume significant orders of magnitude, this will lead to the couplings becoming free with loosened or jumped-out driving wedges and thus from u. U. essential scaffolding parts, so that security is no longer guaranteed.

The invention has for its object to provide a functional solution to the problem that has arisen by the loosening driving wedges for the safety of metal stand scaffolding of the type described.

This object is achieved according to the invention with the features of patent claim 1. Useful embodiments of this solution are the subject of subclaims 2 to 4.

According to the invention, the previously unused sides of the driving wedge serve as wedge tightening surfaces, while the wedge flank of the driving wedge is assigned to the bottom of the keyway, but does not come into effect with it and therefore does not adversely affect the driving wedge effect. The wedge tightening surfaces form a separating wedge which elastically deforms the coupling half provided with it via the driving wedge gap when it is driven into the keyway when driving with the wedge flank running on the inclined surface of the other coupling half. As a result, even considerable vibrations of the wedge gear can no longer unexpectedly loosen the driving wedge.

The invention therefore has the advantage that it avoids the previously occurring dangerous conditions with simple means, namely by a shape of the driving wedge which deviates from the known, and thus retains the basic advantages of the screwless driving wedge couplings.

Preferably and with the features of claim 2, the invention is carried out so that the driving wedge attracts over the full length of the driving path, because the wedge surfaces of the separating wedge start directly on the back of the driving wedge and end at the driving wedge tip. This makes it possible to let the additional preload of the coupling halves with the separating wedge occur with the first hammer blow on the back of the driving wedge and to keep the number of hammer blows low until the final preload.

It is also possible to keep the dimensions of the driving wedge and thus also the size of the gap small without reducing the effect and reducing the pretension. This is achieved with the features of claim 3.

• Fig. 1 teilweise im Schnitt und in Seitenansicht sowie in abgebrochener Darstellung ein Metallstandgerüst gemäß dem zweiten Lösungsgedanken der Erfindung und
• Fig. 2 eine Teildraufsicht auf den Gegenstand der Fig. 1.

The invention is explained in more detail below on the basis of exemplary embodiments of its two solution ideas, which are shown in the drawings. These show in longitudinal section the two coupling halves on a pipe stand with the broken tubes shown, broken off, namely in

• Fig. 1 partially in section and in side view and in a broken view, a metal stand frame according to the second solution of the invention and
• FIG. 2 is a partial top view of the subject of FIG. 1.

A standpipe (1) of a pipe stand frame (not shown) is connected to a frame latch (2) with the aid of a mechanical coupling. One half (4) of the coupling (3) consists of a ring which is attached to the standpipe (1). The ring forms a flange (5) which forms a conical surface (6) which is inclined upwards in the direction of the standing tube (1) and an oppositely inclined lower conical surface which is designated by (7) and as a bearing surface for a wedge gear (8). serves. It serves to connect the coupling half (4), which is fixed to the standing tube (1) and is formed by the described ring (4), with the other coupling half (9) so as to be vibration-proof.

The coupling half (9) consists of a molded part, for example, which has a hollow cylindrical section (10) to which the bolt (2) consisting of a tube is welded. In the front part of section (10) there is a gap (11) for a driving wedge (12). The driving wedge is shown in Fig. 1 in its rest position. He takes this when the driving wedge is in its upper end position. Then the wedge surface (13) of the driving wedge (12) is supported on the lower end of the bottom (14) of the gap (11) with a recess (15) on a shoulder (16) of the bottom. A semicircular thickening (17), which attaches to the driving wedge tip, prevents the driving wedge from being released from the guide slot (11).

According to the embodiment according to FIGS. 1 and 2, the driving wedge of the wedge gear is on the annular inclined surface (7) of the frame Flange ring (5) supported by the wedge suit. In contrast, the opposite driving wedge flank (3) is no longer supported and is also no longer used to tighten the wedge for tightening the clutch.

The two side surfaces (40, 41) of the driving wedge (12) form the flanks of a separating wedge and its wedge surfaces. Their levels converge behind its wedge flank (13).

2, a keyway (43) is formed for the separating wedge in the gap (11), the friction surfaces (44, 45) outside of the gap, i. H. converge on the side facing away from the hook (5). From Fig. 2 it can be seen that the inner cylinder (10) interrupts the groove bottom (46) in the gap (11) at (47).

According to the illustrated embodiment, the wedge surfaces (40, 41) begin at the edges of the back (46) of the driving wedge (12). Therefore, the separating wedge is tightened simultaneously with the wedge gear. This is also ensured by the parallel wedge surface sides (48, 49), which are located on the wedge tip (15). The keyway side surfaces (44, 45) above the keyway bottom section (50) are assigned to these.

In the position of the parts shown in FIG. 1, the driving wedge (12) is driven by hammer blows on the back of the wedge (51), its tightening surface (13) being above the bottoms (50, 52) of the keyway in the gap (11). When the driving wedge is loosened, the separating wedge surfaces (40 and 41) are detached from the groove side surfaces (44 and 45) of the keyway. However, if the wedge is driven, it also moves towards the bottom of the groove, whereby the separating wedge is tightened.

This tightening of the driving wedge (12) allows the straight flank (53) of the driving wedge to slide on the inclined surface (7), the separating wedge being driven into the keyway (47) as a result of the wedge flank (13). The friction occurs on the partial surfaces of the wedge flanks (44, 45) which come into contact with the wedge surfaces (40, 41) of the separating wedge.

The back of the wedge (54), the wedge flank (13) and the wedge surfaces (40, 41) form the edges of a trapezoidal profile which has inclined edges which run symmetrically to a central perpendicular (55). In the case of a driving wedge suit, the outer inclined surface (6) and the opposite inclined surface (57) bear against the surfaces (58, 59) of the inside conical hook jaw (60) assigned to them. The coupling half (9) is preferably elastically deformed and in this way brings about the bracing with the other coupling half (4).

According to the embodiment shown, it is also provided that the end (55) which is to be attached to the driving wedge tip (15) is to be penetrated with a double-head rivet (56). The end (55) therefore consists of a flat profile. The two rivet heads serve to prevent the driving wedge (12) from being driven upwards.

In general, an upper wedge lock, which prevents the driving wedge from being driven downward out of the gap (11), is not required. If it is provided, it can consist of a lateral thickening of the driving wedge (12).

Claims (4)

1. Metal stand scaffolding for buildings, in particular tubular scaffolding, the elements of which can be connected with the aid of couplings, the halves of which are fixed on one element and form-fit and can be preloaded with a driving wedge gear, one flank of the driving wedge one on an inclined surface of a coupling halves preferably fixed to a standing element has guided wedge tightening surface and the flank opposite it is designed as a wedge surface and the driving wedge runs in a gap which is recessed in the other coupling half, characterized in that the wedge tightening surfaces (40, 41) of the driving wedge (12) on both sides of the driving wedge ( 12) are formed and their surface planes converge outside the driving wedge (12) behind the wedge flank (13), and that the gap (11) has a wedge groove (43) with the flanks (44, 45) of which the friction surfaces for the wedge tightening surfaces of the driving wedge (12) are formed. 2. Metal stand according to claim 1, characterized in that one side of each wedge surface (40, 41) is formed by an edge of the back of the wedge (51) of the driving wedge (12). 3. Metal stand frame in particular according to one of claims 1 or 2, characterized in that the wedge surfaces (40, 41) of the driving wedge (12) with the wedge flank (13) and the wedge tightening surface (53) form a trapezoidal profile, the short side of which (3) is arranged parallel to the bottom surface (50, 52) of the keyway (43), the bottom (50, 52) of the keyway being recessed between the two groove ends. 4. Metal stand according to one of claims 1 to 3, characterized in that the end (55) attached to the driving wedge tip (15) has a flat profile and is penetrated with a rivet (56), the heads of which serve as a backstop of the driving wedge (12) .

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