NO145732B - ADJUSTABLE STILLAS (FORSCALING) SUPPORT. - Google Patents

Description

The present invention relates to an adjustable support for use in various scaffolding/formwork works, which is intended for building work and which comprises a first, outer tube which is provided with at least one through hole and a second, inner tube which is displaceably arranged in the first tube and which is provided with a number of through holes, the support's two tubes being lockable in connection with each other by means of a locking pin which passes through a through hole in the outer tube and a through hole in the inner tube.

There are previously known adjustable supports which include

two mutually displaceable pipes, the pipes being provided with holes or rows of holes to enable the pipes to be locked in relation to each other by means of a locking pin which is inserted through holes in the two pipes. In the presence of rows of holes, it is possible to gradually adjust the length of the supports according to the current need. Supports of this type are often provided with two hinged parts, so that a length adjustment of the supports can be provided in the intervals between the different steps. A support of this kind can be made continuously adjustable over a large length range.

It is naturally a strong desire that such supports should be as light as possible, so that the supports can be easily moved and processed. In order to reduce the weight of the supports, thin-walled pipes are usually used as material for the mutually displaceable support parts. When using thin-walled pipes, however, the problem arises that the hole edge pressure that occurs at the locking pin under the load of the supports can easily exceed the strength of the material, so that the material is deformed and the supports are bent away. This problem is particularly relevant when using pipes made of light metal, e.g. aluminum.

The main purpose of the invention is to provide an adjustable support which has a low weight, but still has reassuring strength, especially with regard to the hole edge pressure. This purpose is achieved by the support according to the invention being given the characteristic features specified in claim 1.

By giving the inner tube a varying wall thickness and

the through holes are placed in wall parts with greater thickness, the significant advantage is achieved that the weight of the pipe can be reduced

is seen significantly without the strength of the support becoming insufficient. As the hole edge pressure is the most critical dimensioning parameter, more critical than e.g. the breaking strength, the support will gain reassuring strength if the hole edge pressure does not exceed the strength of the material. According to the invention, the hole edge pressure is reduced by placing the through holes in relatively thick wall parts.

With the described design of the wall of the inner tube, the weight of the inner tube is reduced to a minimum. A further object of the invention is also to reduce the weight of the outer tube to a minimum. As the outer tube is only provided with one or a few holes, it is unnecessary to equip the tube with thicker wall parts that extend along the entire length of the tube. The weight of the outer tube is therefore reduced by providing the tube with enclosing rings, in which the through holes are accommodated. As only one or a few rings are required, a further substantial material saving is achieved in this way. When recording a number of holes, e.g. two, in the outer tube at a distance from each other in the tube's longitudinal direction, a larger length regulation area for the support is achieved, and also the possibility of a more convenient working position during insertion of the locking pin. In addition, fewer holes need to be accommodated in the inner tube.

An embodiment of the adjustable support according to the invention shall be described in more detail below with reference to the attached drawings, where:

Fig. 1 shows a support according to the invention.

Fig. 2 shows a cross-section on a larger scale of the support along the line II-II in fig. 1. Fig. 3 shows a cross-section on a larger scale of the support along the line III-III in fig. 1.

The one in fig. The support shown in 1 comprises an outer tube 10 which forms the upper part of the support, and an inner tube 11 which forms the lower part of the support. The inner tube 11 is displaceably arranged in the outer tube 10 and provided with a vertical series of through holes 12, which run essentially perpendicular to the longitudinal direction of the tube. The pipe 11 is provided at its lower end with a support plate 13 which is rotatably supported on the pipe by means of a bolt 14 which is fixed in an end plate 15 attached to the pipe 11. The outer pipe 10 is provided with two attached rings 16 and 17, in which are arranged holes 18 and 19, which pass through the pipe perpendicular to the pipe's longitudinal direction. Holes 18 bg 19

in the outer tube 10 has the same diameter as the holes 12 in the inner tube 11. Between the rings 16 and 17 is attached a thin ring 20 which serves as a fastener for a chain 21, in which is attached a locking pin 22 for locking the tubes 10 and 11 in relation to each other, as more clearly shown in fig. 3. The pipe 10 is provided at its upper free end with a fork-like member 23, which is intended to receive the beam or box to be carried by the support. This fork-like body 2 3 is provided with a threaded pin 2 4 which is arranged in a correspondingly threaded sleeve 25, so that the pin can be moved into or out of the sleeve by turning in relation to the sleeve for continuous length regulation of the support. The pin 24 is provided with threads over such a long part that a continuous regulation is achieved over a length which is at least as large as the distance between two holes 12 in the inner tube 11. Coarse regulation of the length of the support is thus produced by means of the locking pin 22 and the holes in the tubes 10 and 11, and fine adjustment is produced by turning the tube 10 in relation to the fork-like member 23. To facilitate this turning, the rings 16

and 17 provided with handles 2 6 and 27, as more clearly shown at

fig. 3, and is adapted to the rotatably stored support plate 13.

That in fig. 2 shown cross-section through the pipe 11 along the line II-II shows that the wall of the pipe 11 is provided with parts 11a and 11b which have a greater thickness than the other parts of the wall.

In these wall parts, through holes 12 are arranged diametrically. The thicker wall parts 11a and 11b run axially along the entire length of the pipe 11, and all holes 12 in the pipe 11 thus run through the thicker parts of the wall of the pipe 11.

The holes 12 are occupied in a longitudinal recess 28 on the outside of the inner tube 11, as shown in fig. 1 and 2. This recess extends along the entire pipe 11, and the part that extends below the bottom hole 12 indicates the position of the row of holes and thereby facilitates the rough regulation of the length of the support.

In fig. 3 shows a section through the support along the line III-III in fig. 1. The figure shows the locking pin 22 placed in a through hole 18 in the outer tube 10 and the ring 16. The locking pin also passes through a through hole 12 in the inner tube 11, whereby the locking between the two tubes is produced. As will be seen, they are walls in the pipes 10 and 11 through which the holes pass are relatively thick, whereby the hole edge pressure is relatively low, while the other parts of the pipes through which no holes pass are relatively thin, whereby the weight of the pipes is low and the material costs for the support are minimal. If the pipes are made of e.g. aluminium, the shape required for the inner tube with different wall thickness can easily be produced by string pressing, and the rings required for the outer tube can easily be welded to the outer side of the tube.

In fig. 1, for the sake of completeness, the support is shown with a rotatably supported support plate 13 and with a fork-like member 23, which through a threaded pin is rotatably connected to the outer tube in the support, but these parts have no inventive connection with the design of those in the support inlet pipe for recording the hole edge pressures that occur when the support is loaded, which design constitutes the invention itself.

Although only one embodiment of the tubes included in the support is shown and described, it is obvious that a large number of embodiments are possible within the framework of the inventive concept. It is probably appropriate in many cases to give the inner tube a circular outer circumference and in this way to produce the partial increase in wall thickness by a corresponding reduction in the cross-sectional area of the inner, central hole in the tube, but it is also possible to produce the greater wall thickness by placing external ridges or ribs on the pipe, so that the pipe thus does not have a purely circular outer shape. Such a design has the advantage that the inner tube cannot be rotated in relation to the outer tube during length adjustment of the support when moving the locking pin from one hole in the inner tube to another hole, thereby ensuring that the holes in the inner tube always come to

pass in the middle under the holes in the outer tube, so that the

the locking pin in the desired hole in the inner tube is eased. The cut-out in the inner tube which also facilitates the drilling out

the holes, can be replaced by another marking, e.g. a color marking. However, it is possible to replace each through-

walking holes with a pair of holes and to use an essentially U-

shaped locking pin for locking the pipes in relation to each other.

In this way, the hole edge pressure can be further reduced.

Claims (8)

1. Adjustable scaffolding or formwork support, including tend a first tube (10) which is provided with at least one through hole (e.g. 18) which passes through the tube substantially perpendicular to the longitudinal direction of the tube, and a second inner tube (11) which is displaceably arranged in the first tube (10) and which is provided with a number of through holes (12) which pass through the tube substantially perpendicular to the longitudinal direction of the tube at a distance from each other in the longitudinal direction of the tube, under which one tube (11) is arranged to form the lower part of the support part and the remaining tube (10) is arranged to form the upper part of the support, the support's two tubes (10,11) being locked in relation to each other by means of a locking pin (22) which passes through the through hole (18 ) in the outer tube (10) and a through hole (12) in the inner tube (11), characterized in that the cross-section of the inner tube (11) has varying wall thickness along the circumference of the tube, under which the inner tube's through hole (12) goes through wall parts (lia, 11b) with greater thickness. 2. Support as stated in claim 1, characterized in that the two wall parts (lia, 11b) with greater thickness are arranged diametrically opposite each other and that the through holes (12) go through these wall parts. 3. Support as specified in claim 1 or 2, characterized in that the wall parts in the outer tube through which the through hole (18) passes are also thicker than the other wall parts. 4. Support as stated in claim 3, characterized in that a ring (16) is arranged around the outer tube (10) and that the through hole (18) passes through this ring. 5. Support as stated in claim 4, characterized in that a number of rings (16,17) are arranged at a distance from each other around the outer tube (10) and that a through hole (18,19) runs perpendicular to the longitudinal direction of the tube through each call (16,17). 6. Support as stated in one of the preceding claims, characterized in that the inner tube (11) has a non-circular outer circumference. 7. Support as stated in one of claims 1-5, characterized in that the inner tube (11) is provided with an indication indicating the position of the row of holes (12). 8. Support as stated in claim 7, characterized in that the holes (12) in the inner tube (11) are occupied in a cut-out (28) which runs along the entire length of the inner tube and which forms the position indication for the series of holes ( 12).