DE3641349A1 - Structural support - Google Patents

Abstract

The invention relates to a telescopic structural support, in the case of which the inner tube bears, on its casing surface provided with a thread, an adjusting nut which is supported at one end of the outer tube. In order to achieve a form of construction which is, in particular, advantageous for use, the invention proposes that the casing surface of the outer tube (1) be provided with undercut grooves (11) which run in the axial direction and are intended for receiving the bracing-type fastening screws (30) of supplementary struts (23, 24). <IMAGE>

Description

The invention relates to a telescopically displaceable arranged outer tube and inner tube existing building support, at wel cher the inner tube on its threaded outer surface an adjusting nut carries, which is at one end of the outer tube supports.

Building supports of this type are known. They are made of steel and are e.g. B. inserted as variable-length individual supports for formwork purposes puts. As a rule, such props weigh up to 4 m in length not more than 25 kg, which enables quick assembly and disassembly light. The disadvantage, however, is that the floor heights vary greatly different construction props are always needed and that in higher area a work scaffold and a planned buckling bracing are missing and the construction supports weigh up to 40 kg. An implementation a formwork scaffold made of such construction supports in the block or in a network is not possible.

The invention has for its object a generic construction support so that in addition to easy and easy to handle construction share a great adjustability in height, and that they can Create an adaptable formwork scaffold from a few, many mutually usable components allowed.

This object is achieved in that the outer surface of the outer tube with undercut grooves for receiving in the axial direction the fastening clamping screws are equipped with additional struts.  As a result of such a configuration, the utility value of a genus according construction support increased. The on the outer surface of the outer tube provided, undercut grooves and the associated cross Sectional profiling leads to greater resilience of the building support. It is therefore possible to manufacture the outer tube from aluminum. Against The permissible load capacity is then above a steel construction support the aluminum construction prop about twice as high with almost the same Weight. This fact allows larger support distances. Further only need 30-50% of the props that have been used so far to be assembled and transported. Then the grooves allow that Create an adaptable formwork scaffold from a few, many mutually usable components. The supplementary struts are preferred used for heights of 4-11 m. Compared to the well-known Rah support and work scaffolding is the amount of buckling stiffening a formwork scaffold created with construction supports according to the invention considerably less because of the free, unsupported kink length on the outside tube of a construction support made of aluminum is approx. 3.5 m in order to deduct a permissible load of 50 KN. That he accordingly Formwork scaffold combines the advantages of a high work area speed when assembling and disassembling non-stiffened Construction supports with the advantages of the inevitable buckling bracing. The Supplementary struts can then be steplessly along the outer tube be moved. This means advantages for any to be provided Work platform. In addition, this brings flexibility to the Walking or driving inside the formwork scaffold. Also turns out this turns out to be convenient if the building supports at different heights stand level.  

Manufacturing advantages result from the fact that the grooves the wall material of the outer tube are formed. For example, this is He witness the profile made of aluminum in the extrusion process possible.

Another advantage is that the outer tube is polygonal Cross-section and the outer surface of the inner tube on the grooves floor leads. If essentially a square plan of the outside tube is selected, can accordingly also four by 90 ° to each other staggered grooves are provided for creating the quadrangle in plan Ger scaffolding allow such that the supplementary struts are centric are connected to the building supports, so that no additional forces or Additional moments occur in the formwork system. The same in scope Distributed groove bottom leads to a favorable Ab support of the outer surface of the inner tube to achieve an ins overall very rigid construction prop.

An advantageous development can be seen in the fact that the adjusting nut in a contact position at the front end of the outer tube from one Spring action is engaged in the release position movable pawl. As long as the underhand grip does not take place, the adjusting nut can be opened the external thread of the inner tube can be moved by swirling around the make appropriate rough adjustment. Only when the jack the Adjustment nut is gripped under, fine adjustment is given.

The area of application is enlarged in that one end of the outside tube is equipped with a head plate, the through holes for the outside pipe connecting screws. The maximum length of a construction is sufficient  do not support, so you can the outer pipes of two building supports to the Connect the head plates to each other with the inside arranged at the end pipes. In this way you get a double spindle travel. This is advantageous with an appropriate formwork scaffold to support beams to submerge and dismantle the entire formwork frame with one Moving the slab formwork to the side.

The area of application of the building support is further increased by the fact that the head plate has a push-through hole for the inner tube. To this It is possible to make a single outer tube two with an external thread assigned inner tubes.

In order to ensure a stable definition of the supplementary struts are on both sides Each groove is provided with flat contact surfaces for the additional struts.

It proves advantageous that the supplementary struts are part of a are two frame connecting frame. Stabilize such frames several struts of a formwork scaffold in their position. Furthermore the frames can be used to support a walkable scaffold covering.

The easy assembly of the supplementary struts or the frame is there by allowing the fastening turnbuckles, with a ham mer-like head equipped, turn in the groove in the rear grip position bar and are loaded by a spring in the clamping direction. Before Mon animals of the frame, the fastening screws are aligned tet that their hammer head can enter the groove. When connecting  the clamping process is a rotation of the hammer head by 90 ° in the Rear grip position.

The additional struts are thus against lateral displacement ensures that it overlaps the edges of the flat surfaces Own shoe.

The invention is illustrated below with the aid of a drawing clear embodiment explained. It shows

Fig. 1 is a view of a means of the inventive props he presented formwork scaffolding,

Fig. 2 is a top view of the shuttering framework,

Fig. 3 in an individual representation a view of a construction support,

Fig. 4 shows the section along the line IV-IV in Fig. 3,

Fig. 5 is a section, along the line VV in Fig. 3

Fig. 6 is a fragmentary view of the construction support in the region of the adjusting nut engages under pawl,

Fig. 7 is a longitudinal section through Fig. 6 in the region of the latch,

Fig. 8 is a cross section of two through the outer tube of the construction support with ver tensioned supplement strut framework,

Figure 9 is also a cross section through the outer tube in dash-illustrated single-complement struts punctured.,

Fig. 10 is a view of the supplement struts having frame,

Fig. 11 is an end view of the frame facing the shoe,

Fig. 12 a plurality of frames of varying length in view,

Fig. 13, the compounds obtainable by means of the illustrated in Fig. 12 Frame column grid,

Fig. 14 is a view of a formwork with scaffold to the head plates to sammengeschraubten outer tubes and

Fig. 15 is also a long shuttering scaffold with different, wherein the foot-side inner tubes supported on the head plates bolted together outer pipes, at different levels.

The building support has an outer tube 1 and an inner tube 2 which is telescopic to it. The insertion end 2 ' opposite end 2''of the inner tube 2 is based on a base plate 3 . Both the inner tube 2 and the base plate 3 are made of aluminum and are connected to one another by means of a weld 4 . The outer surface of the inner tube 2 is equipped with a trapezoidal thread 5 on which an adjusting nut 6 runs. At its insertion end 2 'of the inner tube 2 facing the adjusting nut 6 forms a flange 7 with an upstream ramp 8 . At the other end of the adjusting nut 6 , two diametrically opposed rotary cams 9 and two impact cams 10 located between them are provided. The rotary cams 9 and the impact cams 10 are arranged in the same angular distribution and are made of the same material from the adjusting nut.

The outer tube 1 , which is also made of aluminum, has a polygonal layout, and an octagon is selected, cf. in particular FIGS. 8 and 9 . Two opposing octagon sides of this profile are longer and are at right angles to each other. From these four sides of the octagonal profile extending in the axial direction of the outer tube, undercut grooves 11 , which grooves from the wall material of the outer tube 1 z. B. are formed by extrusion. From Fig. 7 shows that the outer surface of the inner tube 2 carries at the groove bottom 12th The grooves 11 have a rectangular plan, which is open to the lateral surface of the outer tube 1 via the longitudinal insertion gap S.

The adjusting nut 6 facing the front end 1 'of the outer tube 1 is fitted with a shim 13 made of plastic, to reduce the friction between the outer tube 1 and made of steel locknut. 6 The outline shape of the shim 13 corresponds to that of the outer tube. The compensating disc 13 is anchored by means of two plug pins 14 which extend from the same material and enter frictionally in two diametrically opposed grooves 11 . In the middle, the shim 13 is equipped with a passage opening 15 for the inner tube 2 .

On one with a groove side of the outer tube 1 is in the region of the front end 1 ' a pawl 16 by means of a lug 17 GE is stored. The lug 17 is fixed by means of two screws 18 entering the material of the outer tube 1 . The pawl 16 is double-armed and pivots about a bearing pin 19 of the bracket 17 . The lower lever arm 20 of the pawl 16 projects beyond the compensating disk 13 and engages under the flange 7 of the adjusting nut 6 , see in particular FIG. 7. The other lever arm 21 is longer than the lower lever arm 20 and serves as a handle. The pawl 16 he extends at the level of the entry gap S of the groove 11 in order to be able to pivot the pawl counterclockwise against the force of a spring (not shown).

The other end 1 '' of the outer tube 1 is a head plate 22 with a rectangular plan. In this head plate passage holes 22 'are provided to z. B. to connect the head plates of two outer tubes by means of outer tube connecting screws, not shown, cf. B. two mutually braced outer tubes in Fig. 1, 14 and 15. Furthermore, the head plate 22 contains a central inner tube push-through opening 22 '' .

If the construction support described above is used as a single support, the adjusting nut 6 can be whirled on the thread 5 of the inner tube 2 in order to achieve a rough adjustment. This is only possible because then the handle 16 does not grip the handle. After the rough adjustment has been completed, the inner tube 2 is pushed into the outer tube until the flange 7 acts on the pawl 16 . About the ramp 8 of the flange, the pawl 16 is pivoted against the spring load. Is after the flange 7 against the disc-compensation entered 13, the pawl 16 may be spring loaded to pivot back to yield the sub-grip, the pawl underpins with its hook end 20 'of the flange. 7

A formwork scaffold can also be created using several construction supports. Supplementary struts 23, 24 are required for this purpose, which are part of a frame 25 connecting two construction struts. In the embodiment example, the supplementary struts 23, 24 form the two parallel, longer spars of the frame, which emanate from the supplementary struts connecting shoes 26 . The supplementary struts 23, 24 step with their ends against the vertically aligned shoes 26 and are fixed there by welding. For stabilization extend in the open angles between the supplementary struts 23, 24 and the shoes 26 stabilizing webs 27 , which have a T-shaped cross-sectional profile, see FIG. 10, and are also fixed by welding on the shoes and on the additional struts .

According to Fig. 12, five different lengths designed frame 25 a to 25 e illustrated in such a way that the sitting frame 25 a is the smallest length BE. The two longer frames 25 d and 25 e are stabilized in the middle by the additional struts 23, 24 cross members 25 ' .

Both sides of the groove 11 forms the outer surface of the outer tube 1 contact surfaces A. The shoes 26 of the supplementary struts 23, 24 of the frame 25 step against them. The shoes 26 facing these flat contact surfaces A overlap the edge edges R of the flat contact surfaces A with claws 28 on the edge to achieve a centering effect.

Each shoe 26 is equipped with two superimposed sleeves 29 which face the interior of the frame. Each sleeve is secured to shoe 26 by welding. Both the sleeve 29 and the shoe 26 are penetrated by the threaded shaft of a fastening clamping screw 30 . The corresponding bore 31 for the shaft of the fastening screw 30 equipped with a hammer-like head 32 is smaller than the inner diameter of the sleeve 29th Therefore, can be supported on the shoe 26 extending within the sleeve 29 compression spring 33 which presses against the wing nut 34 of the clamping screw 30 and loaded the hammer-like head 32 in the clamping direction. The smallest width of the head 32 corresponds to the width of the gap S of the groove 11 . Accordingly, with appropriate alignment of the heads 32 of the fastening clamping screws 30 of the frame men 25 can be attached to the outer tube 1 so that the two heads 32 dip into the corresponding groove 11 . Only when the wing nut 34 is subsequently rotated is the head 32 frictionally carried along the shaft, wherein it creates the undercut in the undercut groove 11 and permits tensioning. Due to the longitudinally oriented grooves 11 in the outer tubes 1 , a stepless adjustment of the frame 25 can be made.

From Fig. 9 it can be seen that in addition to the frame-side supplementary struts 23, 24 further supplementary struts 35, 36 can be provided. These are not part of a frame and are used exclusively for stiffening. The corresponding clamping screws 37 are just equipped with a hammer-like head 38 , see FIG. 9.

With the five different frames 25 a to 25 e illustrated in FIG. 12, as shown in FIG. 13, 15 different square support grids can be produced for optimal adaptation to the load that occurs. This allows a large variation of the Bausützenab stands, which ensures load transfer with good utilization of the construction supports. In this way, the requirement on the construction sites is taken into account, namely the same device for a construction site.

From Fig. 10 it can be seen that the frame 25 support one or more rer scaffolding planks 39 can be. In this figure, only a single scaffold 39 is shown in dash-dotted lines, which extends in the gusset between the left lower stabilizing web 27 and the lower supplementary strut 24 .

In the formwork scaffold illustrated in FIGS. 1 and 2, two outer tubes 1 are each connected to their head plates 22 . In the free ends of the outer tubes 1 enter the threaded inner tubes 2 . The adjustment path is therefore very large. The individual building supports are connected by appropriate frames 25 d, which are clamped at the insertion end of the outer tubes 1 . By diagonal struts 40 shown in dash-dotted lines in FIG. 2, additional reinforcement of the formwork scaffold can be achieved.

A formwork scaffold is also illustrated in FIG. 14. However, this sits at a greater height than that previously described and is intended as a scaffolding. Corresponding scaffolding planks 39 are inserted for the purpose of inspection. The frame 25 carrying these also receive their bracing in the region of the insertion ends of the outer tubes 1 .

A formwork scaffold is shown in FIG. 15, wherein two outer tubes 1 which are clamped to one another each have different lengths. In this way, the construction supports on the left side of the formwork scaffold can have a shorter length than those on the right. Therefore, the corresponding lower inner tubes 2 associated with the shorter structure can be supported at a higher level than the lower inner tubes 2 arranged on the right. In contrast, the upper support points are at one level. In this solution, the outer tubes of the building supports are connected by frames 25 , which in turn carry planks 39 of a scaffolding.

All mentioned in the description and shown in the drawing new features are essential to the invention, also as far as they are in the An are not expressly claimed.

Claims (10)

1. From telescopically slidably arranged outer tube and inner tube existing building support, in which the inner tube carries on its threaded jacket surface an adjusting nut, which is supported on one end of the outer tube, characterized in that the outer surface of the outer tube ( 1 ) with in Axial direction ver running, undercut grooves ( 11 ) for receiving the fastening clamping screws ( 30 , 37 ) of additional struts ( 23 , 24 and 35 , 36 ) is equipped. 2. Building support according to claim 1, characterized in that the grooves ( 11 ) are formed from the wall material of the outer tube ( 1 ). 3. Building support according to one or more of the preceding claims, characterized in that the outer tube ( 1 ) has a polygonal cross section and the outer surface of the inner tube ( 2 ) on the groove bottom ( 12 ). 4. construction support according to one or more of the preceding claims, characterized in that the adjusting nut (6) is engaged from below in its contact position at the front end (1 ') of the outer tube (1) from a against spring action is movable in the release position pawl (16). 5. Construction support according to one or more of the preceding claims, characterized in that an end face ( 1 '') of the outer tube ( 1 ) is equipped with a head plate ( 22 ) which carries through holes ( 22 ') for outer tube connecting screws. 6. Construction support according to one or more of the preceding claims, characterized in that the head plate ( 22 ) has a push-through hole ( 22 '') for the inner tube ( 2 ). 7. Construction support according to one or more of the preceding claims, characterized in that on both sides of each groove ( 11 ) flat contact surfaces ( A ) for the additional struts ( 23 , 24 or 35 , 36 ) are provided. 8. Construction support according to one or more of the preceding claims, characterized in that the supplementary struts ( 23 , 24 ) are part of a frame ( 25 ) connecting two construction supports. 9. Building support according to one or more of the preceding claims, characterized in that the fastening clamping screws ( 30 ), equipped with a hammer-like head ( 32 ), rotatable in the groove ( 11 ) into the rear grip position and by a spring ( 33 ) are loaded in the clamping direction. 10. Construction support according to one or more of the preceding claims, characterized in that the supplementary struts ( 23 , 24 ) have a shoe ( 26 ) overlapping the edge edges ( R ) of the flat contact surfaces ( A ).