NO148898B - BUILDING SCAFFOLDING - Google Patents

Description

Construction scaffolding is generally rectangular and made up of components of the desired height to form a platform from which workers can perform necessary work tasks on a building. It is common to equip building scaffolding with rollers, so that they can be moved from one place to another.

It is known to arrange a largely rectangular (e.g. square) building scaffold, constructed of tubular steel components, "where the main component is a largely rectangular frame, two short sides of which project past the long sides for the arrangement of pins and pin bearings0 The scaffold is thereby built up from a number of "layers" of such frames, and in each such layer there are two opposite sides of the "square". for a nearby layer. The bottom layer is attached to a foundation (which may consist of steel rudder components and may carry pulleys) and the top layer is connected to a platform, which may also include steel rudder components. Such building scaffolding will hereinafter be called "mentioned type". Because rotation is possible between each tenon and the tenon bearing it is fitted into, building scaffolding is usually braced by means of diagonal horizontal braces, which run between the corners of the scaffolding r. Construction scaffolding of this type must be able to be assembled and dismantled repeatedly and the requirement for diagonal braces increases the necessary assembly and dismantling time, which is an obvious disadvantage.

The present invention is to provide a building scaffolding, where the aforementioned disadvantages of the mentioned type of building scaffolding are eliminated.

According to the invention, a building scaffolding of the mentioned type has been provided, where each pin bearing and each pin is designed with cooperating parts, which prevent or limit rotation of the frame that carries the pins in relation to the one that carries the pin bearings.

Such obstruction or limitation of the relative rotation reduces or eliminates the need for diagonal bracing.

Preferably, each pin bearing comprises a transverse pin, while each pin is formed with a slot which fits over the pin"

An embodiment of the invention will now be described with reference to the drawing, where

fig. 1 is a rendering in perspective of a building scaffold according to the invention,

fig. 2 and 3 are a front view respectively. an elevation of a frame which is used in the building scaffold according to fig. 1,

fig. 4 shows how the pin on one frame fits into the pin storage in another frame and

fig. 5 is a side view of an alternative pin design.

In fig. 1, 2 and 3, the building scaffold is largely rectangular and mainly made up of eighteen frames 1, which are shown in detail in fig. 2 and 3, as well as comprising nine "layers" of such frames 1. As shown in fig. 2 and 3, each frame is generally rectangular with rudder 2 forming the long sides and rudder 3 forming the short sides. The long sides 2 are connected by inclined struts 4. The short sides 3 extend above and below the long sides 2 and form pin bearings 5 at the upper ends, while they have downwardly extending pins 6 at the lower ends.

As shown in fig. 1, each frame layer consists of two frames 1 facing each other, and except at the bottom layer, the pins at the end of each frame 1 fit into corresponding and opposite pin storage 5 for the two frames "under the former frames, so that the pins 6 on each frame 1 fits into the pin bearings 5 in the frames 1 and the pin bearings 5 in each frame 1 occupy the pins 6 for the two frames. In Fig. 1, the top and second top and with these parallel layers are denoted by 7 and 8 respectively.

The studs 6 on the frame 1 for the bottom layer 7 fit into stud bearings in beams 9, which run at right angles to said frames 1 and parallel to the frames 1 for the layers 8. The studs on the frames 1 for the top layer 7 carry the platform 10 and surrounding railings 11.

As shown in fig. 4, each pin 6 is tightly fitted into the tube-shaped frame component 3, from which it projects down and is prevented from rotating in relation to said frame component 3 by means of a pin 12, which extends through holes located flush with each other in the frame component 3 and pin 6.

Each pin bearing 5 is designed at the top of a frame component 3 and comprises a transverse pin 13 at right angles to the pins 12. Each pin 6 is provided at the lower end with axially extending slots 14, in line with each other, which must fit over the pin 13. The slots 14 dimensions are such that, when the pin 6 is quickly fully inserted into the pin bearing 5, no relative rotation of the upper frame component 3 in relation to the lower frame component 3 can occur.

Between the corners of the scaffolding, immediately above and below the bottom layer of the "frames" 1, a pair of diagonal braces 15 run. The beams 9 are equipped with hanging rollers 16.

The arrangement of the pins 6 and the pin bearings 5 with the pins 12 and 13, which prevent relative rotation of each assembled pair of frame components 3, prevents rotation of each frame component 3 in relation to the frame components 3 to which it is connected. In the absence of such an anti-rotation device, rotation would take place and would have to be prevented with diagonal braces. Two diagonal struts 15 are arranged, which will help to absorb loads when the scaffolding is moved. It has been shown that diagonal braces are not necessary if no rollers are provided and the scaffolding is only intended to be used in a single position.

By the fact that diagonal braces can be dispensed with or present in reduced numbers, the advantage of a price reduction is achieved, as the number of components is reduced«, At the same time, the speed of assembly and disassembly is increased. If there are no diagonal braces, the building scaffold can be mounted around a projecting part, e.g. a pipe, which is not possible when using diagonal braces. The absence of diagonal braces also makes it possible, if desired, to arrange an intermediate slab frame.

All frame components and other metal parts shown in fig. 1 consists of aluminium, which is considerably lighter than steel, which has hitherto been used for such scaffolding. Consequently, the height of each frame component can be increased, so that the number of frame layers can be reduced for a given height.

During assembly, the beams 9 are first fitted with the diagonal braces 15 and the pulleys 16. The bottom layer 7 of the frame 1 is then put in place and the upper diagonal brace 15 is fitted. The bottom layer 8 is installed, the next layer 7 follows, etc., until the desired height is reached. Two beams are then mounted in line with the layers 8 for the frames 1 and placed in the same horizontal plane as the upper frame components 2 in the top layer 7 for the frames 10

Railing posts 17 provided with downward-pulling pins are then put in place and the railings 11 are mounted. The tables for the platform floor 10 are mounted and edge tables 18 can be mounted to help prevent someone falling from the work platform.

Fig. 5 shows a modified pin 20 with a bore 21, which is to be attached to a side frame component 3 by means of a pin, not shown, which is inserted into the bore 21 as well as in the frame part 3. The pin 20 is designed with a flange 22, which shall limit the movement of the pin in a pin bearing, as with slots 33 which correspond to the slots 14.

Claims (4)

1. Scaffolding comprising several layers of two opposite and largely rectangular frames, which are made up of cylindrical tubes, where the short sides of each frame project beyond the long sides of the frame for the provision of pins and pin bearings, where the pins for each frame in each layer, except from an end layer, fit into corresponding pin bearings in the frames for a nearby layer, so that the frames for alternating layers are located in parallel planes at right angles to the frame plane of the intermediate layer, and where the bottom and top layers of the frames are connected with a foundation or a platform , characterized in that either each pin bearing (5) or each pin (6) carries a transverse pin (13), whereby depending on which part is provided with said cross-section, the other is provided with slots (14) that fit over the pin (13) ), whereby the cross pin (13) and the slots (14) prevent or limit rotation of the frame that carries the pin (6) in relation to the frame that carries the pin bearing (5). 2. Scaffolding that. stated in claim 1, characterized in that each pin bearing (5) carries a transverse pin (13) and that each pin (6) is designed with slots (14) that fit over the pin (13). 3. Construction scaffolding as stated in claim 1, characterized in that the foundation is provided with pulleys and braced with diagonal braces (15). 4. Scaffolding as specified in claim 1, characterized in that the lower surface of the foundation is designed so that it rests on the ground and that it does not include diagonal braces.