FI90684B - I liked the racks for the railings - Google Patents

Abstract

Attached to the pole (31.1) of a scaffold is a small wedge box (33), in the insertion space of which either one tab or two tabs (35) of railing bars (34) can be inserted. A wedge (65) which is displaceable and swivellable on a bolt (70) has an elongated hole (75) and an outer pressing surface (78) which is located at an appropriate wedge angle thereto and at the top end of which a lifting cam (97) is formed. The mounting and outer contour of the wedge (65) are selected such that insertion clearance (92) remains and the wedge can either slip through or be lifted by means of the cam surface (100) or of the lifting cam (97) during insertion. The outer pressing surface (78) and the elongated hole (75) are sufficiently long, taking the wedge angle into consideration, to clamp one tab (35) or two tabs (35) securely. <IMAGE>

Description

1 90684

I liked the racks for the railings. - Hallare för ställningars ledstängar.

The invention relates to a holder for railings in racks with a wedge housing and a pivotable, non-disappearing wedge supported thereon.

According to DE-PS 27 57 189, the handrails of the racks are provided with connecting plates which extend downwards at their ends and can be pushed into the wedge housing. In this case, a non-disappearing wedge is provided with suitable wedge devices with a sufficient feed length, which makes it possible to fasten either only one or also two connecting plates with the same wedge. This known system has suitable support surfaces and separate members to prevent disappearance. During installation, make sure that the wedge is out of the push-in space and is suspended in the one and only possible place provided for it. If this is not taken into account, the installer must go to a possibly high rack without side securing at that point and turn the wedge to the suspended position. This is inconvenient and in some situations also dangerous. Due to the two grooves, the wedges extend relatively far into the working and passage space of the rack.

Other older structures have a similar wedge housing with a transversely extending notch in front of the post wall with connecting plate responses and a wedge guided laterally into the insertion space by protruding support surfaces. In the newer device according to DE-GM 87 06 723 = DE-OS 38 01 354 A1, it is arranged that, without other support measures, the long-hole wedge is supported on the screw threads. In this case, both pressing outer surfaces have different distances from the long hole on both sides of the wedge to take into account the different thicknesses that occur depending on whether one connecting plate or two connecting plates are placed. Such a wedge hangs in the wrong position in case of doubt if another joint plate is to be installed. As a result, before inserting the splice plate, it must first be determined whether only one splice plate or two splice plates are installed and the user must be able to assess the position of the wedge with its different widths, possibly even remotely, to hang it in each end position. If an error assessment is made here, the connecting plate can be pushed in, but the wedge can no longer be brought into the locking position. It is also difficult to lift out the connecting plate, because the wedge in the wrong position now partially fixes the inserted connecting plate. To insert the second connecting plate, the wedge must be raised to a suitable position. Thus, the wedge must in each case be held with a raised hand, in which case the person assembling or disassembling the scaffold has only one hand free for the handrail. In this system and structure, large parts of the rack can only be installed by two people. In a one-person installation, it must be possible to assess the correct position of the wedge at any given time in order to bring the wedge into the correct position in each housing in advance. Such requirements are difficult in practice. Turning the wedge with a high rack without railing securing is not safe. Supporting the wedge on one simple pin, in addition to a threaded pin, results in very fast, high wear and undefined wedge ratios. The support on the wedge slabs and the clamping forces securing the slabs are applied directly to the wall of the post, thus providing unfavorable support conditions. The connection plates of the side walls of the push-in space, which are individually welded to the supports, must be made very stable and oriented very precisely in order to obtain a usable system. Despite this, there are large loads and stress peaks in the corners.

U.S. Pat. No. 2,878,079, DE 2,634,465 and CH 638,859 also disclose various wedge structures, which, however, have the disadvantage of e.g. the fact that the wedge cannot be rotated freely a full 3 90654 turns or that the structure is technically cumbersome and expensive to manufacture.

The patent (patent application) deals with a group of related inventions in such a way that they implement a single general inventive idea, which consists in shaping the wedge holder, fastening and support devices and related elements of such railing holders in such a way that the manufacture and use are improved. the structure and support of the forces present is improved and optimized.

The object of the invention is to provide such a holder for rack railings as mentioned at the beginning with a support and wedge device which allows the railing to be hung without sticking to the wedge in all wedge positions and possibly with additional measures to reduce wear and stability and provide simple and safe manufacture.

Holder for rack railings according to the invention; having the following characteristics: the racks have vertical posts; a wedge housing is attached to the post at a predetermined height, each having at least an upwardly open insertion space; the railings have downwardly extending railing connecting plates that can be pushed into the wedge housing insertion space; the insertion space is limited by the side walls, a vertical connecting plate stop is formed at the post wall; a wedge holder is provided on the insertion space side opposite the connecting plate stop; the wedge holder has slit walls connected to the side walls and delimiting a gap radially with respect to the post and into the insertion space and open upwards, downwards and outwards; a pin horizontal and transverse to the post axis pierces the Slit Walls; a wedge is movably and reversibly arranged in the wedge holder 4 vΠ 6 8 4 to fasten the connecting plate of at least one handrail; the wedge has a long hole through which the pin extends; the wedge has at least one pressing outer surface which comes into contact with the outer wall of the connecting plate of the respective handrail; a wedge angle is provided between the compression outer surface and the long hole reference line; the outer circumferences surrounding the ends of the long hole have a distance with respect to the axis of the pin which is less than the distance between the axis of the pin and the splice-plate stop minus twice the thickness of the splice splice plate; is characterized by the following features: the length of the long hole and the pressing outer surface as well as the wedge angle are adapted to the thickness of the connecting plates so that one connecting plate or two connecting plates can optionally be pressed against the connecting plate stop on the same pressing outer surface; in the mounting wedge position at the upper end of the pressing outer surface there is a lifting cam; the outer circumferential surface opposite the compression outer surface is at most a distance from the long hole reference line less than the distance between the center of the pin and the splice plate minus twice the thickness of the splice splice plate or wedge formed in the middle of the long hole; the long hole in the wedge and the other parts of the pin are shaped so that the wedge can be freely pivoted in at least both of its suspension positions.

Because the shape of the wedge and the length and position of the long hole with respect to the outer circumference have fully defined and optimized ratios, the wedge can hang in any desired end position and it is possible to insert one connecting plate or two connecting plates simultaneously or two connecting plates in succession without handling the wedge. The wedge can then be brought into the fastening position without obstruction and struck there. When the wedge is removed, it is possible to raise the connecting plate without sticking thanks to the skillful shape selection of the wedge. In addition, the procedures are deceptively simple and ensure significant simplification of installation without any increase in manufacturing costs. The safety during the installation and disassembly of the scaffolds is improved because the installation person does not have to go anywhere without the safety of the handrail to hang the handrail, because the hanging position of the wedge does not have to be checked and the wedge cannot be adjusted. Thanks to the freedom of infection, only one person is required for this work during disassembly and installation.

In order to solve the problem of shaping the wedge circumference in such a way that the wedge does not prevent insertion in any position, does not prevent retraction in the disengagement position and nevertheless in the manufacturing position allows securing both one and two connecting plates, there are two principles for choosing dimensions, angle and circumference. select the perimeter so that the essential wedge end allows either the wedge to be slid between the support and the connecting plate stop or the connecting plate to be inserted, or the hanging wedge moves to a partially raised position due to a suitable guide cam structure, namely the lifting cam, but with no design forces do not occur when pulled out. In this case, the lifting principle can be used twice. In this case, no through-sliding is required. This results in a symmetrical wedge or the slipping conditions can be maintained at one end and the lifting conditions at the other. This results in an asymmetrical wedge with only one side of the connecting plate pressing surface. Both slightly different structures in these two possibilities solve the same task.

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Due to the appropriate design of the lifting cam extending into the insertion space, the suspended wedge automatically moves to a partially raised position, regardless of whether one or two connecting plates are fitted in place and without any wedge effect. Thus, one person can fit either only one railing slab or, after fitting one rail slab, another rail slab without having to use one hand to hold the wedge in place. The wedge is then moved from its partially raised position to the securing position and possibly struck with a hammer. Once removed, it can, like other wedges, hang down and the wedge no longer prevents disassembly, which again can be done by a single person.

If the wedge is formed as a double wedge with a symmetrical appearance, then the length of the wedge angle, the long hole and the pressing outer surface and the distance from the long hole reference line are dimensioned so that in both possible positions the wedge has an impact that optionally prevents one or two connecting plates, during installation, it needs to be moved to a specified position and only needs to be turned up when attached.

The walls surrounding the receiving space for forming the wedge housing and the appropriate shapes of the wedge housing are discussed in other claims and in the specification, whereby a one-piece structure with a notch in which the splice plate response is formed provides a large support surface and a low tendency to turn up. The gap may be suitably limited depending on the thickness of the wedge.

To date, quality structures of wedge housings of this type have had a separate surface supporting the wedge force, as in DE-PS 27 57 189, or shoulder-supported support surfaces projecting laterally next to the wedge. Both measures li 7 90634 result in relatively high surface pressures. If the possibilities discussed above are transferred to an appropriate reversible wedge, support for the wedge forces on the pin is obtained. In this case, the surface pressures become so high with a simple line contact and possibly only with the tip of the thread that the wear of the long hole wall of the pin and the wedge reaches considerable dimensions in a short time. Here, the provision of an aid to a circumferential wedge, either symmetrical or asymmetrical or possibly without a lifting cam, can be carried out as set out in claim 7.

Accordingly, it has been proposed to provide an enlarged support surface on the pin and to fit it appropriately with respect to the width of the long hole. Thanks to the increased support surface, low-cost, low-wear, simple-to-manufacture and simple-to-build solutions can be achieved with suitable materials, the details of which are discussed in other claims and in the following description together with other features, advantages and various aspects of the whole arrangement.

Embodiments and modifications of the invention will be described below with reference to the accompanying drawings.

Figure 1 shows an oblique part of a rack with handrail rods attached to wedge housings.

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Fig. 2 shows an internal view of the wedge housing with the railing pressure of the handrail with the connecting plate inserted, the column post being, however, not shown.

Fig. 3 shows a top view of the wedge elements and the rack post cut away and a top view of the two inserted handrail ends, the wedge housing being bent from the steel plate and having an inclined rotating pin with a chamfer.

Fig. 4 shows a view similar to Fig. 3 with a wedge housing made of light metal and an accompanying rotating pin with two chamfers for a double wedge.

Fig. 5 shows a side view of a wedge housing next to a post without inserted railing connecting plates, the wedge with a single lifting cam shown in a first embodiment hanging in place.

Fig. 6 shows a view corresponding to Fig. 5, in which the inserted railing connecting plate is fixed with a wedge.

Fig. 7 shows a view corresponding to Fig. 5, in which the two railing plates of the handrail are arranged in place, but not yet fixed with a wedge.

Fig. 8 shows a view similar to Fig. 7 with a partially hand-raised wedge just before the fastening position.

Fig. 9 shows a view corresponding to Figs. 7 and 8, in which the wedge is in the fastening position, the parts, in particular to show the bevel of the pin, being shown cut in a vertical plane immediately in front of the wedge.

h 9 90684

Fig. 10 shows a view similar to Fig. 5, in which the wedge hangs at one end of the long hole so that the lifting cam is in the insertion tube.

Fig. 11 shows a view corresponding to Fig. 10, in which already one connecting plate is in the insertion path while the other is partially pushed and raises the wedge by hitting the lifting cam.

Fig. 12 is a view similar to Fig. 11, in which both connecting plates of the handrail are fitted and the wedge is shown in an intermediate position which has been turned by hand after it was first slightly raised by the insertion plate and lifting cam compared to Fig. 11 and slips further past the connecting plates to turn the other end of the long hole to the mounting position.

Fig. 13 shows a view corresponding to Fig. 5 of a double wedge. . another variant of the wedge in the form of.

Fig. 14 shows a view similar to Fig. 13 in a situation where the connecting plate of the handrail is slightly pushed into the insertion space and raises the wedge slightly as a result of hitting the lifting cam.

Fig. 15 shows a view corresponding to Fig. 14, in which one railing connecting plate is arranged in place and fastened by a wedge.

'! Fig. 16 shows a view corresponding to Fig. 14, in which one handrail connecting plate is fitted and the second handrail connecting plate at the beginning of the insertion has raised the wedge.

10 90634

Fig. 17 shows a view corresponding to Fig. 16, in which the two connecting plates of the handrail are arranged in place and fastened with a wedge, the parts, in particular to show both chamfers of the pin, shown in a vertical plane immediately in front of the double wedge.

Fig. 18 shows an enlarged partial vertical section along the line 18-18 in Fig. 2, showing the bevel of the pin, its other structure and support together with a simple wedge and its long hole.

Fig. 19 shows a schematic representation of a wedge with a long hole and a support for a chamfered support 1 rotating on a support pin.

Fig. 20 is a schematic representation corresponding to Fig. 19 of a second embodiment with a fixed support pin and a long hole end structure for rotation.

Fig. 21 shows a partial view corresponding to the previous figures of a long hole and a fixed, beveled support pin.

Fig. 22 shows a view corresponding to Fig. 21 at the attachment of the support pin without a wedge.

For example, the rack 30 shown schematically in Figure 1 has vertical posts 31.1 and 31.2 connected by means of transverse horizontal supports 32 to form a frame. Two wedge housings 33 are attached to the posts 31.1 external to the building at predetermined heights suitable for the inside of the frame - as is customary in such scaffolding 33. They are used to fasten the horizontal handrail bars 34.

They have a width 36 of about 33 mm and a thickness 37 of about 6 mm. From the support surface 38 they extend down to a length 39 down to the end edge 40 cut from the corners. The connecting plates 35 of the handrail are pushed upwards in a known manner and here also downwards into the open-in wedge housing 41 in the known way. The push-in spaces 41 are delimited by side walls 42.1 and 42.2. The side walls 42.1 and 42.2 are connected to them at the post wall 43 by means of a notch 44 formed in one piece. This section 44 is adapted to the cylinder of a cylindrical post with a tubular abutment surface 45.

In this case, there are two construction alternatives according to Figures 3 and 4. The alternative according to Figure 3 is formed as a bent steel plate part. In this case, the notch 44 has a central abutment part 46 which is formed straight. It is bent by two oblique arms 47 approximately tangentially to the post wall 43 at about 30 ° C. At the ends 48 of the branches, in the slightly rounded corners 48, the side walls 42.1 and 42.2 are bent parallel to each other so as to obtain an inner gap 49 which, as can be seen, is considerably larger than the width 36 of the railing plate 35. The abutment portion 46 forms a joint aa 41 .11 response 50. At the corners 48, the wedge housing 33 is welded to the post 31.1 by means of two vertical V-seams 51, as shown in Fig. 3. Due to the bent shape, small cavities are formed 52.

The embodiment according to Fig. 4 differs from the above only in that it is a light metal extrusion profile in which the inner abutment surface 55 of the notch 44 is formed in the shape of a circular arc. All other elements are essentially similar. The wedge housing structures of both options are therefore discussed together.

12 90684

A wedge holder 60 is formed on the opposite side of the splice plate stop 50. It has a slot 61 radially with respect to the post cross-section, the width 62 of which is sufficiently clearance greater than the outer width 63 of the corrugated ridges 64 of the corrugated wedge 65, as shown in Figures 2 and 3. Due to the corrugated shape of the wedge shown in Fig. 2, dirt is easily removed and easy sliding through the gap is achieved.

Slit 61 is bounded by both Slit Walls 66.1 and 66.2. They are arranged parallel to the inwardly displaced side walls 42.1 and 42.2 and connected to the side walls 42.1 and 42.2 by means of connecting arms 67.1 and 67.2 which are perpendicular between them and delimit the insertion space 41 outwards. As can be seen, the gap 61 is open up and down and towards the insertion space 41. Thus, the suitably constructed wedge 65 can be turned freely.

To support the wedge 65, there is a pin 70 extending through the slit walls 66.1 and 66.2, which may be shaped differently, as will be described later. The pin 70 extends through the long hole 75 of the wedge 65. Together, they provide support for the wedge forces and also prevent the wedge from disappearing.

In the case of the wedge 65, there are in principle two outer circumferential shapes, as shown in Figures 5 to 12 and 13 to 17.

The wedge 65 of Figures 5-12 is an asymmetrical outer circumference with one lifting cam 97, and the wedge of Figures 13-17 is a symmetrical wedge with two lifting cams 97.1 and 97.2. Both wedge shapes have only one long hole 75, the length of which is indicated by reference numeral 76 and the width by reference numeral 77, and which hole extends through a flat wedge. The wedge consists of a suitably cut steel plate or possibly a light metal plate or reinforced plastic, depending on the design and operating requirements of the rest of the rack. Each wedge has a pressing outer surface li 13 90684 78. It extends along the wedge angle 79 with respect to the reference line 80 of the long hole 75. The pressing outer surface 78 is formed straight. According to an important feature of the invention, the length 81 of the straight pressing outer surface 73 and the length 76 and the wedge angle 79 of the long hole 75 are arranged so that either one railing connecting plate 35 or two railing connecting plates 35 can be fastened to one another by means of the same pressing outer surface 78.

The reference line 80 passes through the axis of rotation or pivot axis of the key 70 formed by the shaft 90 of the pin 70 and is offset by a recess of the bevel 121 relative to the longitudinal central axis of the long hole 75 with respect to the removed jacket line of the pin in the compression outer surface 78 as shown in Figures 5 and 9. In the wedge 115, which has two lifting cams 97.1 and 97.2 and two chamfers 121, 141, as shown in Figs. 13 to 17, both lines coincide with the reference line 80.

In the example of the wedge 65 according to the first embodiment of Figures 5-12, the second long outer circumferential surface 82 is parallel to and spaced 83 from the reference line 80 of the long hole 75, as will be described in more detail below.

;;; The connecting ring 85 in the narrower portion 84 of the wedge 65 from the pressing outer surface 78 to the outer circumferential surface 32 is formed by a portion 85.1 adjacent to the outer circumferential surface 82 - · in the shape of a quarter arc 78 to transition point 88.

The distance 89 (Fig. 3) from the splice plate stop 50 to the shaft 90 of the pin 70 is adapted to the thickness 37 and distance 83 or radius 87 of the railing connecting plates 35 so that when two railing connecting plates 35 are inserted - as shown in Fig. 7 - the wedge 65 hangs down and rests no contact is made with the end 91 of the long hole 75 at the narrow side 84 of the wedge 65. The distance 89 is thus greater than the sum of the two thicknesses 37 and the distance 83 or radius 87, so the insertion clearance 92 remains and the railing slabs can be pushed into place without wedge contact either as single slabs or both simultaneously or sequentially without blocking the wedge or the wedge 65 without gripping the railing slabs 35 slide freely with their outer surfaces. On the other hand, the distance 89 is dimensioned so that in the fastening position of the wedge 65 (Figs. 6 and 9), one or two railing joints 35 can be securely fastened by means of its compression outer surface 78 and its wedge angle 79.

The wedge 65 of the outer periphery of the wedge 95 is provided with a wider side 96 of the lifting cam 97 and configured such that the outer compression surface 78 is derived from a figure appearing in the drawing way with the long hole 103 from the pivot point 102 over 80 normal direction of the reference line 105 to the corner. It then leads to the end 98 of the transition ring portion 99 continuously on the cam surface 100, whereby the distance 101 from the pivot point 102 of the long hole end 103 in the wide wedge portion 96 is greater than the radius 87. The transition ring portion 99 is guided to the end 104 of the parallel outer circumferential surface 82. In this case, the distances from the pivot point 102 are formed larger than in the narrower part so that when inserting the railing slabs - whether or not one or two railing slabs 35 are pushed - the corner 105 or cam surface 100 of the lifting cam 97 is pounded so that the lifting cam 97 pivots around the pivot point 102. to the center of the pin 70 or its shaft 90, as shown in Fig. 11. Thus, although the lifting cam 97 depends on the insertion path 41, the insertion of the plate 35 can also be performed remotely from a distance and the handrail bars 34 are at the same time secured with respect to lateral fall to the extent that the mounting spirit can safely go up to the wedge housing 65 in a disadvantageous position. through the intermediate position according to Fig. 12 and through the narrower part 84 to the fastening position shown in Figs. 6 and 9. In it, the wedge 65 is suitably attached from above with a hammer stroke. The wedge 65 can be removed by hitting from below. The figures show that the wedge 65 also protrudes downwards slightly past the side walls 42 and the slit walls 66 in the case of the connecting plate 35 of the two fitted railings and can thus be used properly.

In this asymmetrical wedge 65, the reference line 8C does not coincide with the longitudinal central axis of the long hole 75 but is further displaced by the amount of the bevel 121 described above and passes through the shaft 90 of the pin 70, as shown in particular in Figure 9. Thus, the radius 87 is also guided around the axis 90.

Preferably, due to the shape or outer circumference of the wedge 60 selected and optimized in many respects, its length, angle, end rounding and lift cam design will never require the wedge to turn the wedge before inserting one or two connecting plates, even if the wedge 65 does not prevent entry. in the fastening position according to Fig. 6 for fastening the handrail bar. In this case, there is of course a handrail near the wedge housing which can be gripped by the installation person and is thus safe.

The previously described shape of the wedge uses the principle of sliding through the outer circumferential part of the wedge when the wedge is not in the securing position. The application example discussed in Figs. 13 to 17 shows a wedge housing of the same shape and with the same reference numerals, but a wedge 115 symmetrical about the center of the reference line 80 between the pivot point 102 and the end 91 of the long hole 75. It has two compression outer surfaces 78.1 and 78.2 and two lifting cams 97.1 and 97.2. is formulated in the same manner as shown in connection with the first application example.

As can be seen from the drawings, one or two connecting plates are struck into the insertion space 41 when one of the lifting lugs 97.1 or 97.2 is pushed and the wedge 115 is brought into its partially raised position. By simply raising it, the wedge can then be moved to the locking position. Also in this wedge 115, there is no situation in which the insertion of one or two connecting plates is prevented when the wedge is not in the securing position. The wedge 115 can likewise be struck or detached. It still has the advantage that it only needs to be raised to make it slide into the safety position.

In this embodiment, the longitudinal centerline of the long hole 75 and the centerline 80 of the displacement of the wedge 115 and the outer circumferential dimension coincide, since both long hole walls of the long hole 75 each rest on one of the two opposite bevels of the pin.

In order to allow the wedge to turn and nevertheless to support the forces present in a good and meaningful way, the pin 70 must be shaped in a meaningful manner in the slotted walls 65.1 and 66.2. Long hole design and support are discussed with application examples in the following.

The meaningful design of the pin can be clearly seen e.g. of Figures 3, 6 and 18.

The entire clamping force for clamping the rails 1 of your railing must be supported by a long hole wall 120 adjacent the compression outer surface 78. In order to reduce the surface compression in the wall of the pin 70, the pin is therefore provided with a chamfer 121 in the support area. The chamfer is in the gap 61 between the slit walls 66.1 and 66.2.

Near the end 122 of the pin 70 is a cylindrical support surface 123 having a diameter 124 corresponding to the diameter of the support hole 125 taking into account the rotational clearance. At one end is a locknut 126 having a shoulder 127 and a support stop 128. The support stopper 128 has the same outer diameter 124 as the support surface 123. The locknut 126 is threaded against the support surface 129 of the pin 70 by the outer threads 130 of the pin so that the end 122 and shoulder 131 are slightly axially spaced from the slit walls. 66.1 and 66.2 on both sides so that even in the event of contamination of the pin 70, the support surfaces can rotate properly. The distance of the chamfer 121 from the outer wall line opposite the pin 133 is slightly less than the width 77 of the long hole, whereby the chamfer 121 is formed so deep that, taking into account the clearance and wear of the pin 70, the wedge 65 turns and the pin always rotates properly with cylindrical support surfaces with the stops 123 and 128 in the support holes 125 of the slit walls 66.1 and 66.2. In this case, the support force is also transferred to the slit walls 66.1 and 66.2 at a low surface pressure. As shown in Fig. 18, the thickness 136 of the wedge 65 is smaller than the outer width 63 of the corrugated wedge 65 due to its corrugated shape. However, the material thickness is adjusted according to the size of the chamfer 121 taking into account the forces and the size of the bearing surfaces in the slit walls 66.1 and 66.2.

In contrast to the previously known, only very inadequately dimensioned wedge supports for bushings or bolts, a simple, safe and durable solution has been proposed here, which on the one hand allows the wedge to be turned in each position and on the other hand supports the tightening forces without much wear.

The pin shown in Figure 3 has - without further explanation - two chamfers at the same distance from the shaft 90. .. and the pin is thus intended for a symmetrical wedge 115, the wedge having two lifting cams 97.1 and 97.2. The bearing of the pin is suitably arranged.

90684 BC

Another possibility for the low-wear support of the reversible symmetrical wedge 115 or possibly also the simple wedge on the large chamfered support surfaces 141 is shown in Fig. 19. In this case there is a support cylinder 140 rotatably supported on the fixed pin 139. It is shaped taking into account the clearance and gap width 62. rotatably fitted on pin 133. In this case, a simple, fixed pin can be pushed and fastened to a suitably large bore in the slit walls 66.1 and 66.2.

Another alternative for supporting wedge forces over a relatively large surface is shown in Figure 20, which has a long hole comprising rotating portions 150.1 and 150.2 extending at approximately 180 ° at both ends, the radius 151 corresponding exactly to the outer wall of the support pin 152 secured between the slit walls 66.1 and 66.2. The support pin 152 has a chamfer 121. As shown in the figure, the wedge can be moved in the desired wedge position in the long hole 155 over the entire area so that when wedging one or also two connecting plates there is always a large abutment surface for supporting the forces. However, if the wedge is in its end position, it can rotate freely due to the circular design of the rotating parts 150.1 and 150.2 of the long hole 155.

Another conversion option for large-area support of wedge forces is shown in Figures 21 and 22.

In this case, the flat-shaped, oval-shaped support pin 160 is fixed to the slit walls 66.1 and 66.2 through them and non-rotatably relative thereto. For this purpose, each slit wall may have a suitable long oval and oblique profile hole 161. The ends may be fastened in a suitable manner with screws, shocks, wedges or the like. The flat oval profile is dimensioned so that the bevel 121 in response is dimensioned according to the supporting forces present, while the two outer end portions in this exemplary cat 90684 are formed into semicircles 162 and the intermediate transition surface 163 is formed planar. It may well be curved as well. The outer distance 165 between the two vertices of the arcs 162 arranged on the end faces is slightly smaller than the width 77 of the gap 75.

Thus, the wedge can be supported on the chamfer 121 - as described above - however, it can also be freely pivoted in the region between the ends of the long hole to achieve the application described above. Various other designs of large wedge support and free rotation at the ends of the long hole are within the scope of the invention. The wedge can also be made thicker and the Slit Walls can be moved farther apart. However, the housing shape shown is optimized in terms of stability, material consumption and size due to practical problems, as the outer corners of the wedge housing and the wedge itself do not extend very much into the rack workspace. it would be achieved that the wedge housings with their wedges are not an obstacle when moving from one field to another. Also in this respect, the wedge and housing structures shown in the drawings are optimal in terms of material consumption, forces and solutions.

Claims (14)

1. Tackle for scaffold handrails with the following determinations: - scaffolding (30) has vertical posts (31; 31.1); - at the posts (31.1), at a predetermined height, a ladle (33) is fastened, each having a rainstorm up open space (41); - the handrails (34) have in the locking space (41) in the cage dance (33), adjustable, downwardly sealed closure plates (35); - the enclosure area (41) is delimited by side walls (42.1), (42.2); - a vertical joint plate (50) is formed at the post wall (43); - a wedge holder (60) is arranged on the exterior stuffing compartment side opposite the joint plate assembly (50); - the wedge holder (60) has slit walls (66) which are joined to the side walls and delimit a radially tiled post and into the enclosure space (41) and uptight, downtight and leaky open slit (61); a horizontal and relative transverse pin (70 ;; 152; 139, 140; 160) to the chair shaft penetrates the slit walls; - in order to attach at least one closing joint plate, a wedge (65; 115) has been slidably and pivotally arranged in the wedge holder (60); - the wedge (65; 115) has a long heel (75) through which the pin (70, ...) extends; - the wedge has at least one pressure outer surface (78.1, 78.2), which will abut the outer wall of the joint plate in the respective case, outside the closed case; - a wedge angle (79) has been formed between the pressure surface area and the reference line (80) of the long heel (75); the ends of the long heels surrounding the outer contours (85, 95) have a distance (87, 101) to the shaft (90) which is less than the distance (89) between the shaft (90) and the joint plate (50) minus two times the thickness of the closing plate; Characterized by the following features: - the length of the heel and the pressure exterior surface adjusted to the wedge angle according to the thickness of the joint plates in such a way that with the same pressure exterior surface a joint plate or two joint plates can optionally be pressed against the joint plate insert; - in the fastening position at the pressure-exterior surface (78; 78.1, 78.2) The upper end has a lifting cam (97); - the outer contour surface (82) located opposite the pressure exterior surface (78) is at a maximum distance (83) from the longitudinal line (75) boundary line (80) which is less than the distance (89) between the center portion of the tape and the joint plate minus two threads of the closure plate the thickness or the wedge (115) forms a center between the ends of the long heel (75) center symmetrical double wedge with two lifting lugs (97.1, 97.2); the longitudinal heel (70, 155) of the wedge (65) and the other parts of the pin (70; 139, 140; 152; 160) are designed so that the wedge (65, 115) is at least freely pivotable in both of its suspension positions. 2. A holder according to claim 1, characterized in that the side walls (42; 42.1, 42.2) and the joint plate (50) forming the threshold (44) in the sliding outer frame of the cowl (33) are made in one piece and fixed welded close to the corners between the threshold (44) and the side walls (42; 42.2, 42.2) of the bar (31.1). 3. A pourer according to claim 1 or 2, characterized in that the chain (33) is formed by an extruded cut-out section of light metal. 4. A heater according to Claim 1 or 2, characterized in that the cow chain (33) is formed by a curved part of a bracket. I:: 27 90684 5. A holder according to claim 1 or 2, characterized in that the guy (33) is formed as a metal molded part. 6. A bracket according to any of the preceding claims, characterized in that the slot (61), delimited by the slots (61) in the wedge bracket (33) in the wedge bracket (33) has a width (62) corresponding to the outer width (63) of the cradle cams (64) of the corrugated wedge (65) increased by a sufficient clearance even during soiling, and that the slit walls (66.1, 66.2) are joined by connecting branches (67.1, 67.2) to the side walls (42.1, 42.2). Holder according to any of the preceding claims: characterized in that the support surface, on which the longitudinal wall (120) at the pin (70; 152; 139, 140; 160) supports, is formed as a pian support surface (bevel 121, 141) . 8. A holder according to claim 7, characterized in that the support element (pin 70; the support cylinder 140) is rotatably supported with the flat support surface against the slit walls (66.1, 66.2) and the width (77) of the longitudinal heel (75) corresponds to the support surface (bevel 121, 141). distance (133) from the casing line (70) of the opposite pin (70) or the distance of the support surface (141) increased with the displacement clearance. Holder according to claim 8, characterized in that the pin (70) at the slot (61) has a bevel (102.1) and at the ends of the pin at least to a large extent cylindrical support surfaces (123, 128) which are rotatably connected thereto and rotatably stored in the slit walls (66.1, 66.2). 10. A holder according to claim 9, characterized in that the pin (70) has a fixed head (122), a support shaft (123) and a counter nut (126) arranged therefor with a 28 90 684 support shaft (128) and which support shafts ( 123, 128) are rotatable in the support heels (125) of the slit walls (66.1, 66.2). 11. Holder according to claim 9, characterized in that the pin has a head and a shaft part connected thereto, which over a certain length is cylindrical, which length corresponds to the outer width of the slit wall, and which has a continuous chamfering length over a supporting part. and an axial fuse resting on the outer surface of the second slot wall. 12. A hanger according to claim 8, characterized in that the pin (139) is fixed between the slit walls (66.1, 66.2) and carries a support cylinder (140) rotatable in the long heel (75) which extends over the width (77) of the longitudinal heel (75). ) correspondingly spaced from the existing cylinder shell line or or from a second pianos red surface (141) has a pian support surface (141). 13. Holder according to claim 8, characterized in that the support pin (152) is rotatably arranged between the slit walls (66.1, 66.2) and has an angular bevel (121) at an angle to the wedge angle (79) and the longitudinal heel (155) has cylindrical pivots at its end ends. (150.1, 150.2), the diameter of which corresponds to the outer diameter of the fixed support pin (152) increased by rotation clearance. Holder according to claim 8, characterized in that the support pin (160) is formed into a rotatable between the slit walls (66.1, 66.2) arranged in profile flat oval shaped element, arranged below the wedge angle (79) at a distance from the joint plate (50) correspondingly. the wedge wedge and the width (77) of the long heel (75) correspond to the support spacer (162) of the support pin (160) of both top points (165) increased by twisting clearance. n