EP3433448A1

EP3433448A1 - Frame element with a support head, and building scaffold comprising such a frame element

Info

Publication number: EP3433448A1
Application number: EP17708472.0A
Authority: EP
Inventors: Andreas Meyer; Erzad MIKIC; Andrew Read; Rudolf Specht
Original assignee: Peri GmbH
Current assignee: Peri GmbH
Priority date: 2016-03-22
Filing date: 2017-03-01
Publication date: 2019-01-30
Anticipated expiration: 2037-03-01
Also published as: CA3016937A1; EP3433448B1; AR107873A1; WO2017162415A1; DE102016204694A1; PL3433448T3; US20200291666A1; ES2835076T3; AU2017236137A1; AU2017236137B2

Abstract

The invention relates to a frame element (10) comprising a frame pipe (12) into which a threaded spindle (16) is partly introduced at one end. The threaded spindle (16) is guided in the frame pipe (12) by at least one spindle positioning groove (24, 26, 28), in particular multiple spindle positioning grooves (24, 26, 28). The frame pipe (12) is mechanically reinforced by the spindle positioning groove(s) (24, 26, 28) in the region of the threaded spindle (16) received in the frame pipe (12). At the same time, the maximum inclination of the threaded spindle (16) in the frame pipe (12) is reduced by the spindle positioning grooves (24, 26, 28). Overall, a force can thus be substantially more strongly applied to the frame element (10) in the direction of the longitudinal axis (23b) of the frame pipe (12). At the other end, the frame pipe (12) has at least one pin positioning groove (40, 42), in particular multiple pin positioning grooves (40, 42). Alternatively or in addition thereto, the frame pipe (12) can have at least one reinforcing groove in the region of a node point. Alternatively or in addition thereto, the frame pipe (12) can have at least one additional reinforcing groove between two node points.

Description

Scaffolding element with a carrier head and scaffolding with such a scaffolding element

The invention relates to a scaffolding element for a scaffolding, wherein the scaffolding element has the following:

a) a carrier head with a threaded spindle;

b) a vertically mounted in the scaffolding scaffolding tube with a

A spindle receiving portion at a first axial skeleton tube end, wherein the threaded spindle is partially inserted into the spindle receiving portion;

c) a mounted on the threaded spindle spindle nut, wherein the carrier head in the assembled state of the scaffold element introduces its vertical load via the threaded spindle in the scaffolding tube.

The above-described carrier head of the scaffolding element generally serves for the removal of a vertical load into a scaffolding. For example, a concrete formwork can be placed or mounted on the carrier head. Furthermore, the carrier head can be used as a temporary support for renovations.

It is an object of the present invention to provide a scaffolding element which can remove significantly more vertical load via the carrier head without being significantly more solid and heavier. Object of the present invention is also to provide a scaffolding with such a scaffold element.

The object of the invention is achieved by a scaffolding element with the features of claim 1 and a scaffolding according to

Claim 12 solved. The dependent claims give appropriate

Further education.

The object of the invention is thus achieved by a scaffolding element for a scaffolding. The scaffolding element has a carrier head with a threaded spindle. The scaffolding element furthermore has a scaffolding tube with a spindle receiving section. In the spindle receiving portion, the threaded spindle is partially inserted. The spindle receiving portion is located at a first axial end of the scaffolding tube. On the threaded spindle a spindle nut is mounted so that the carrier head in the mounted vertical state of the scaffold element introduces its load via the threaded spindle in the scaffolding tube. The spindle receiving portion in this case has a first Spindelpositioniernut, the

Internal diameter of the scaffold tube reduced.

The first spindle positioning groove significantly improves the vertical

Load capacity of the scaffolding element, without significantly increasing the weight of the scaffold element. In this case, the load capacity of the scaffold element is increased in two respects by the first Spindelpositioniernut: Zum One is the strength of the scaffold tube in the area of the first

Spindle positioning groove due to the shape of the first

Spindle positioning groove increased. On the other hand, the threaded spindle is due to the reduced inner diameter of the scaffold tube at the first

Spindle positioning groove better aligned in the scaffold tube. Overall, this results in a significantly improved suitability of the scaffolding element for vertical load transfer.

Preferably, the threaded spindle through the first

Spindelpositioniernut aligned as centered in the scaffold tube, wherein for inserting the threaded spindle in the scaffolding tube a

There is a clearance fit between the threaded spindle and the scaffolding tube. In this case, the longitudinal axis of the threaded spindle on the angle ß relative to the longitudinal axis of the scaffold tube, wherein the angle ß less than 1 °, in particular less than 0.8 °, preferably less than 0.7 °. The vertical load is thereby introduced as centrally as possible into the scaffolding tube in order to keep small moments occurring in the scaffolding.

The first spindle positioning groove may extend parallel to the longitudinal axis of the scaffolding tube. In this case, preferably at least three, distributed over the circumference of the scaffold tube, grooves for aligning the

Threaded spindle provided. In a preferred embodiment of the first spindle positioning groove, however, this extends in the circumferential direction of the scaffold tube. The first Spindelpositioniernut can in

Circumferential direction of the scaffolding tube interrupted or revolving

be educated.

A particularly effective centering of the threaded spindle in the scaffold tube takes place when the axial distance of the first Spindelpositioniernut from first axial stand pipe end is smaller than the inner diameter of the spindle receiving portion.

More preferably, the spindle receiving portion has a second

Spindle positioning groove on. The second Spindelpositioniernut is axially spaced from the first Spindelpositioniernut and reduces the inner diameter of the scaffold tube. By the second

Spindle positioning groove is the orientation of the threaded spindle in

Scaffolding tube by at least two axially spaced apart

Spindle positioning defined, whereby the alignment, in particular the centering of the threaded spindle is very precise.

The second spindle positioning groove may extend parallel to the longitudinal axis of the scaffolding tube. In this case, preferably at least three, distributed over the circumference of the scaffold tube, grooves for aligning the

Threaded spindle provided. Alternatively, the second

Spindle positioning groove in the circumferential direction of the scaffold tube extend. In this case, the second Spindelpositioniernut be interrupted or circumferentially formed in the circumferential direction of the scaffold tube.

In a further preferred embodiment of the invention, the

Spindle receiving portion on a third Spindelpositioniernut. The third spindle positioning groove is axially further spaced from the first spindle positioning groove than the second spindle positioning groove. The third

Spindle positioning groove reduces the inner diameter of the scaffold tube. The third spindle positioning groove further improves the alignment, in particular the centering, of the threaded spindle in the scaffolding tube.

The third spindle positioning groove may extend parallel to the longitudinal axis of the scaffolding tube. In this case, preferably at least three, over the Scope of the scaffolding tube distributed, provided grooves for alignment of the threaded spindle. Alternatively, the third may

Spindle positioning groove in the circumferential direction of the scaffold tube extend. The third Spindelpositioniernut can in the circumferential direction of the

Scaffolding tube interrupted or formed circumferentially.

Preferably, the third spindle positioning groove is spaced axially less far from the second spindle positioning groove than the second spindle positioning groove

Spindle positioning groove from the first spindle positioning groove.

Particularly preferably, the second Spindelpositioniernut and / or the third Spindelpositioniernut reduces the inner diameter of the scaffold tube as far as the first Spindelpositioniernut. The radial play of the threaded spindle in the scaffold tube is thereby significantly reduced, the threaded spindle still easily inserted into the scaffold tube.

The scaffolding tube may have a second skeleton tube end opposite the first axial scaffold tube end

Have journal receiving portion into which a pin of another scaffold element is inserted. The trunnion receiving portion may have a first trunnion position groove that reduces the inner diameter of the scaffolding tube. The scaffold tube is mechanically reinforced in the area of the trunnion receiving section by the first trunnion positioning groove.

The first pin positioning groove may extend parallel to the longitudinal axis of the standpipe. In this case, preferably at least three, distributed over the circumference of the scaffold tube, grooves for aligning the

Threaded spindle provided. Alternatively, the first

Zapfenpositioniemut extend in the circumferential direction of the scaffolding tube. The first pin position groove can be interrupted or circumferentially formed in the circumferential direction of the scaffold tube.

Preferably, the axial distance of the first pin position groove from the second axial frame tube end is smaller than the inner diameter of the first pin position groove.

More preferably, the pin receiving portion has a second

Journal position groove, which is axially spaced from the first journal position groove and reduces the inner diameter of the scaffold tube. The pin of another scaffolding element is characterized in two axially spaced pin positioning grooves in

Spigot receiving section centered.

The second journal position groove may extend parallel to the longitudinal axis of the scaffold tube. In this case, preferably at least three, distributed over the circumference of the scaffold tube, grooves for aligning the

Threaded spindle provided. Alternatively, the second

Zapfenpositioniemut extend in the circumferential direction of the scaffolding tube. The second Zapfenpositioniemut can in the circumferential direction of the

Scaffolding tube interrupted or formed circumferentially.

In a further preferred embodiment of the scaffold element has the

Scaffolding tube on a node on which

a) a crossbar of the scaffold element is connected to the scaffold tube, or

b) a coupling point for connecting a cross bar is formed, wherein the scaffold tube in the region of the node a first

Has stiffening groove. The first stiffening groove is spaced less than 15 cm in a first axial direction from the node and reduces the inner diameter of the scaffold tube or increases the outer diameter of the scaffold tube. Due to the first stiffening groove, the framework element is reinforced in a region in which it is particularly heavily loaded in the assembled state, namely in the area of the nodal point. The scaffolding tube offers a higher resistance and moment of inertia in the area of the pressure point of the cross bar due to the first stiffening groove. The coupling point can in the form of a rosette for

Connection of a crossbar may be formed.

More preferably, the scaffold tube in the region of the node on a further stiffening groove which is spaced less than 15 cm in a second axial direction from the node and the

Reduced inside diameter of the scaffold tube or the

Outer diameter of the scaffolding tube increased. The second axial direction is opposite to the first axial direction. With others

Words is reinforced by a further reinforcing groove of the node in both axial directions by a respective reinforcing groove.

The Spindelpositioniernut (-en) and the stiffening groove (s) reduce the inner diameter of the scaffold tube preferably to the same extent.

The object of the invention is further achieved by a scaffolding with a scaffolding element described above.

Further features and advantages of the invention will become apparent from the following detailed description of several embodiments of the invention, from the claims and with reference to the figures of the drawing showing essential to the invention details. The features shown in the drawing are shown such that the features of the invention can be made clearly visible. The various features may be implemented individually for themselves or for a plurality of combinations in variants of the invention.

Show it :

Figure 1 is a sectional view of a scaffolding element from the prior

Technology;

FIG. 2 shows a sectional view of a framework element according to the invention;

Figure 3 is a plan view of a node of a

scaffold element according to the invention; and

Figure 4 is a perspective view of an inventive

Scaffolding.

FIG. 1 shows a framework element 10 according to the prior art. The scaffolding element 10 has a scaffolding tube 12. In the scaffold tube 12, a spindle receiving portion 14 is formed. In the

Spindle receiving portion 14, a threaded spindle 16 is inserted. The threaded spindle 16 has an external thread 18. The known

Scaffolding element 10 also has a spindle nut 20. The

Spindle nut 20 has an internal thread 22, with which the

Spindle nut 20 is attached to the external thread 18 of the threaded spindle 16. The spindle receiving portion 14 has in the axial direction throughout the same inner diameter. The threaded spindle 16, which is supported axially via the spindle nut 20 on the scaffold tube 12, has a

Misalignment around the angle ß. More precisely, that is

Longitudinal axis 23a of the threaded spindle 16 inclined by the angle ß relative to the longitudinal axis 23b of the scaffolding tube 12. The angle β is typically 1.29 °.

FIG. 2 shows, in contrast to FIG. 1, an inventive device

Scaffolding element 10. The scaffold element 10 according to FIG. 2 has a

Scaffolding tube 12 with a spindle receiving portion 14. Furthermore, the framework element 10 has a threaded spindle 16 on which a spindle nut 20 is arranged. The spindle receiving portion 14 has a first spindle positioning groove 24, a second spindle positioning groove 26, and a third spindle positioning groove 28. The

Spindle positioning grooves 24, 26, 28 define the effective

Inner diameter of the spindle receiving portion 14 for the

Threaded spindle 16. By the Spindelpositioniemuten 24, 26, 28, the threaded spindle 16 is arranged much less inclined in the scaffolding tube 12. The angle β between the longitudinal axis 23a of the threaded spindle 16 and the longitudinal axis 23b of the scaffold tube 12 is in particular less than 0.8 °, preferably less than 0.7 °. Compared to

Scaffolding element 10 according to FIG. 1 thereby increases the vertical load capacity of the scaffold element 10 by approximately 10%. In addition, the spindle receiving portion is mechanically reinforced by the spindle positioning grooves 24, 26, 28 against buckling.

FIG. 2 shows another scaffolding element 30 (dashed line), whose journal 32 can be inserted into the scaffold tube 12. The scaffold tube 12 thus has a first axial scaffold tube end 34 into which the threaded spindle 16 can be inserted. Furthermore, the

Scaffolding tube 12, a second axial skeleton tube end 36 into which the pin 32 of the further scaffold element 30 is inserted. At the second axial frame tube end 36, a pin receiving portion 38 for receiving the pin 32 in the scaffolding tube 12 is formed. A

mechanical reinforcement of the pin receiving portion 38 and an improved centering of the pin 32 is effected by a first

Pin positioning groove 40 and a second pin positioning groove 42.

FIG. 3 shows a further framework element 10 according to the invention. The framework element 10 has a node 44 with a coupling point 46. The coupling point 46 is presently designed in the form of a rosette. Crossbars 48, 50 are arranged at the coupling point 46.

From Figure 3 it can be seen that the scaffold tube 12 is a first

Stiffening groove 54 which is formed in a first axial direction 56 spaced from the coupling point 46 in the scaffold tube 12. A second stiffening groove 58 is formed in the first axial direction 56 at a distance from the coupling point 46 in the scaffold tube 12. Shoulders 60, 62 of the cross bars 48, 50 are in the region of the scaffold tube 12 between the first stiffening groove 54 and the second stiffening groove 58 on the scaffolding tube 12. By the first stiffening groove 54 and the second stiffening groove 58 thus a mechanically particularly stable region of the scaffold tube 12 is formed, in which in particular the mechanical stability against buckling of the scaffold tube 12 is very high.

The scaffold tube 12 has a further stiffening groove 64. The further stiffening groove 64 is spaced from the coupling point 46 in a second axial direction 66. The first axial direction 56 and the second axial direction 66 thereby run along the longitudinal axis 23b of the

Scaffolding tube 12, wherein the second axial direction 66 of the first axial direction 56 is opposite. By further stiffening groove 64 Einstecklaschen 68, 70 of the crossbars 48, 50 are mechanically particularly firmly pressed against the scaffold tube 12, without causing a plastic deformation of the scaffold tube 12 at a load of the crossbar 48 and / or 50.

Alternatively or in addition to the stiffening grooves 54, 58, 64 described, the framework element 10 can be provided between axially adjacent coupling points, of which only one coupling point 46 is shown in FIG.

at least one Zusatzversteifungsnut 72 may be formed in the scaffold tube 12.

FIG. 4 shows a scaffolding 74 with a plurality of scaffolding elements, of which only a first one is shown in FIG. 4 for reasons of clarity

Scaffolding element 10 is provided with a reference numeral. The

Scaffolding element 10 has, by way of example, a node 44 on which - also by way of example - a transverse bar 48 is arranged. Due to the small representation of the scaffolding 74 is in Figure 4 no

groove according to the invention visible. For removing a load, the

Scaffolding element 10 on a carrier head 76.

Taking a synopsis of all figures of the drawing, the invention relates in summary to a scaffolding element 10 with a scaffolding tube 12, in the one end a threaded spindle 16 partially

is introduced. In the scaffolding tube 12, the threaded spindle 16 of

at least one spindle positioning groove 24, 26, 28, in particular a plurality of spindle positioning grooves 24, 26, 28, guided. By the

Spindelpositioniernut (-en) 24, 26, 28, the scaffold tube 12 in the area the recorded in the scaffold tube 12 threaded spindle 16 mechanically reinforced. At the same time, the maximum inclination of the threaded spindle 16 in the scaffolding tube 12 by the Spindelpositioniernut (-en) 24, 26, 28th

reduced. Overall, the scaffold element 10 can thereby be acted upon much more strongly in the direction of the longitudinal axis 23b of the scaffold tube 12 with a force. The scaffolding tube 12 may at the other end at least one pin positioning grooves 40, 42, in particular a plurality

Pin positioning grooves 40, 42, have. Alternatively or additionally, the scaffold tube 12 in the region of a node 44 at least one stiffening groove 54, 58, 64 have. Alternatively or additionally, the scaffold tube 12 between two nodes 44 may have at least one Zusatzversteifungsnut 72.

Claims

claims

1. scaffolding element (10) for a scaffolding (74), wherein the

Scaffolding element (10) has the following:

a) a carrier head (76) with a threaded spindle (16);

b) a scaffolding tube (12) mountable vertically in the scaffolding (74) and having a spindle receiving portion (14) at a first axial scaffolding tube end (34), the threaded spindle (16) being partially inserted into the spindle receiving portion (14);

c) a mounted on the threaded spindle (16) spindle nut (20), wherein the carrier head (76) in the assembled state of

Scaffolding element (10) its vertical load over the

Threaded spindle (16) in the scaffold tube (12) initiates;

characterized in that

the spindle receiving portion (14) has a first

Spindle positioning groove (24) which reduces the inner diameter of the scaffold tube (12).

2. Scaffolding element according to claim 1, wherein the first

Spindle positioning groove (24) the threaded spindle (16) in

Scaffolding tube (12) radially centered so that the longitudinal axis (23a) of the threaded spindle (16) by the angle ß relative to the

Longitudinal axis (23b) of the scaffold tube (12) is inclined, wherein the angle ß is less than 1 °.

A scaffold element according to claim 1 or 2, wherein the first spindle positioning groove (24) extends in the circumferential direction of the scaffolding tube (12), the first spindle positioning groove (24) in

Circumferential direction of the scaffold tube (12) interrupted or

is formed circumferentially.

4. Scaffolding element according to one of the preceding claims, wherein the axial distance of the first Spindelpositioniernut (24) from the first axial Gerüstrohrende (34) is smaller than the inner diameter of the spindle receiving portion (14).

A scaffolding member according to any one of the preceding claims, wherein the spindle receiving portion (14) has a second spindle positioning groove (26) axially spaced from the first spindle positioning groove (24) and reducing the inner diameter of the scaffolding tube (12).

6. scaffolding element according to claim 5, wherein the

Spindle receiving portion (14) a third

Spindle positioning groove (28) which is axially further spaced from the first Spindelpositioniernut (24) than the second

Spindle positioning groove (26) and the inner diameter of the

Scaffolding tube (12) reduced.

7. scaffolding element according to claim 6, wherein the third

Spindle positioning groove (28) axially less far from the second

Spindle positioning groove (26) is spaced as the second

Spindle positioning groove (26) of the first Spindelpositioniernut (24).

8. scaffold element according to one of the preceding claims, wherein the scaffold tube (12) at its second axial end of the scaffolding tube (36) has a pin receiving portion (38) in the one

Spigot (32) of a further scaffold element (30) is insertable, wherein the spigot receiving portion (38) has a first

Pin positioning groove (40) which reduces the inner diameter of the scaffold tube (12).

9. scaffolding element according to claim 8, wherein the

Spigot receiving portion (38) has a second

Journal position groove (42) axially of the first

Pin positioning groove (40) is spaced and the

Reduced inner diameter of the scaffold tube (12).

10. Scaffolding element according to one of the preceding claims, wherein the scaffold tube (12) has a node (44) on which

a) a cross bar (48, 50) of the framework element (10) with the

Scaffolding tube (12) is connected or

b) a coupling point (46), in particular in the form of a rosette, for connecting a transverse bar (48, 50) is formed,

the scaffolding tube (12) having at the node (44) a first stiffening groove (54) spaced less than 15 cm from the node (44) in a first axial direction (56) and

i. reduces the inner diameter of the scaffold tube (12) or ii. increases the outer diameter of the scaffold tube (12).

11. Scaffolding element according to claim 10, wherein the

Scaffold tube (12) in the region of the node (44) has a further stiffening groove (64) which is less than 15 cm in a first axial direction (56) opposite the second axial direction (66) from the node (44) spaced apart and

12. scaffolding (74) with a scaffolding element (10) according to any one of the preceding claims.