ES2835076T3 - Frame element with support head and construction scaffold comprising said frame element - Google Patents

Abstract

Frame member (10) for a scaffold (74), wherein the frame member (10) comprises the following: a) a support head (76) having a threaded spindle (16); b) a frame tube (12) vertically mountable on the scaffold (74), said frame tube having a spindle receiving section (14) at a first axial end of the frame tube (34), wherein the threaded spindle (16) is partly inserted into the spindle receiving section (14); c) a spindle nut (20) that is mounted on the threaded spindle (16), wherein the support head (76) in the assembled state of the frame element (10) introduces its vertical load into the frame tube ( 12) through the threaded spindle (16); wherein the spindle receiving section (14) comprises a first spindle positioning groove (24) that reduces the inner diameter of the frame tube (12), characterized in that the spindle receiving section (14) comprises a second groove spindle positioning groove (26) that is axially separated from the first spindle positioning groove (24) and reduces the inner diameter of the frame tube (12), wherein the second spindle positioning groove (26) reduces the diameter inside the frame tube (12) precisely to the first spindle positioning groove (24).

Description

DESCRIPTION

Frame element with support head and construction scaffold comprising said frame element

The invention relates to a frame element for a construction scaffold, the frame element having the following:

a) Support head with threaded spindle;

b) a scaffold tube that can be vertically mounted on the building scaffold and has a spindle receiving section at a scaffold tube first axial end, the threaded spindle partially inserted into the spindle receiving section;

c) a spindle nut mounted on the threaded spindle, the support head introduces its vertical load into the scaffold tube through the threaded spindle in the assembled state of the frame member.

The above-described support head of the frame member is generally used to transfer a vertical load to a construction scaffold. For example, the concrete formwork can be placed or mounted on the support head. The support head can also be used as a temporary support during renovations.

Document DE4027739 describes such a frame element.

The object of the present invention is now to provide a frame member that can transfer a significantly greater vertical load through the support head without becoming significantly more massive and heavy. The object of the present invention is also to provide a construction scaffold with such a frame element.

The object of the invention is achieved by a frame element with the features of claim 1 and a construction scaffold according to claim 12. Convenient developments can be found in the dependent claims.

The object of the invention is thus achieved by means of a frame element for a construction scaffold. The frame member has a support head with a threaded spindle. The frame member also has a scaffold tube with a spindle receiving section. The threaded spindle is partially inserted into the spindle receiving section. The screw receiving section is located at a first axial end of the scaffold tube. A spindle nut is mounted on the threaded spindle in such a way that the support head, when the frame member is vertically mounted, introduces its load into the scaffold tube through the threaded spindle. The spindle receiving section has a first spindle positioning groove that reduces the inside diameter of the scaffold tube.

The first spindle positioning slot significantly improves the vertical load capacity of the frame member without significantly increasing the weight of the frame member. The first spindle positioning groove increases the load capacity of the frame member in two ways: On the one hand, the strength of the scaffold tube in the area of the first spindle positioning groove increases due to the shape of the first groove. spindle positioning. On the other hand, the threaded spindle is better aligned in the scaffold tube due to the reduced inside diameter of the scaffold tube in the first spindle positioning slot. In general, this results in considerably improved suitability of the frame member for vertical load transfer.

Preferably, the threaded spindle is aligned as centrally as possible in the scaffold tube by the first spindle positioning slot, with a clearance fit between the threaded spindle and the scaffold tube to insert the threaded spindle into the scaffold tube. The longitudinal axis of the threaded spindle has the angle p relative to the longitudinal axis of the scaffold tube, the angle p being less than 1 °, in particular less than 0.8 °, preferably less than 0.7 °. In this way, the vertical load is introduced as centrally as possible in the scaffold tube to keep the moments that occur in the scaffold small.

The first spindle positioning groove may extend parallel to the longitudinal axis of the scaffold tube. Preferably, at least three grooves distributed over the circumference of the scaffold tube are provided to align the threaded spindle. In a preferred embodiment of the first spindle positioning slot, however, it extends in the circumferential direction of the scaffold tube. The first spindle positioning groove can be interrupted in the circumferential direction of the scaffold tube or formed circumferentially.

Particularly efficient centering of the threaded spindle in the scaffold tube occurs when the axial distance of the first spindle positioning groove from the first axial end of the scaffold tube is less than the inside diameter of the spindle receiving section.

The spindle receiving section also has a second spindle positioning groove. The second spindle positioning groove is axially spaced from the first spindle positioning groove and reduces the inner diameter of the scaffold tube. Second spindle positioning groove defines alignment of the threaded spindle in the scaffold tube by at least two axially spaced spindle positioning grooves, whereby the alignment, in particular the centering, of the threaded spindle is particularly precise.

The second spindle positioning groove may extend parallel to the longitudinal axis of the scaffold tube. Preferably, at least three grooves distributed over the circumference of the scaffold tube are provided to align the threaded spindle. Alternatively, the second spindle positioning groove may extend in the circumferential direction of the scaffold tube. In this case, the second spindle positioning groove can be interrupted in the circumferential direction of the scaffold tube or formed circumferentially.

In a further preferred embodiment of the invention, the spindle receiving section has a third spindle positioning groove. The third spindle positioning groove is axially further from the first spindle positioning groove than the second spindle positioning groove. The third spindle positioning groove reduces the inside diameter of the scaffold tube. The alignment, in particular the centering, of the threaded spindle in the scaffold tube is further improved by the third spindle positioning groove.

The third spindle positioning slot can extend parallel to the longitudinal axis of the scaffold tube. Preferably, at least three grooves distributed over the circumference of the scaffold tube are provided to align the threaded spindle. Alternatively, the third spindle positioning groove may extend in the circumferential direction of the scaffold tube. The third spindle positioning groove can be interrupted in the circumferential direction of the scaffold tube or formed circumferentially. The third spindle positioning groove is preferably less axially spaced from the second spindle locating groove than the second spindle locating groove is spaced from the first spindle locating groove.

The second spindle positioning groove reduces the inside diameter of the scaffold tube as much as the first spindle positioning groove. The third spindle positioning groove can also reduce the inner diameter of the scaffold tube. The radial clearance of the threaded spindle in the scaffold tube is thus significantly reduced, however the threaded spindle remains easy to insert into the scaffold tube. The scaffold tube may have a pin receiving section at its second axial end of the scaffold tube, which is opposite the first axial end of the scaffold tube, into which a pin from another scaffold member can be inserted. The pin receiving section may have a first pin positioning slot that reduces the inside diameter of the scaffold tube. The scaffold tube is mechanically reinforced in the area of the pin receiving section by the first pin positioning slot.

The first positioning groove of the pin may extend parallel to the longitudinal axis of the scaffold tube. Preferably, at least three grooves distributed over the circumference of the scaffold tube are provided to align the threaded spindle. Alternatively, the first pin positioning slot may extend in the circumferential direction of the scaffold tube. The first positioning groove of the pin can be interrupted in the circumferential direction of the scaffold tube or designed to be circumferential.

The axial distance between the first pin positioning slot and the second axial end of the scaffold tube is preferably less than the inside diameter of the first pin positioning slot.

More preferably, the pin receiving section has a second pin locating slot that is axially spaced from the first pin locating slot and which reduces the inside diameter of the scaffold tube. In this way, the pin of another frame member is centered in two pin positioning grooves that are axially spaced from each other in the pin receiving section.

The second positioning groove of the pin may extend parallel to the longitudinal axis of the scaffold tube. Preferably, at least three grooves distributed over the circumference of the scaffold tube are provided to align the threaded spindle. Alternatively, the second pin positioning groove may extend in the circumferential direction of the scaffold tube. The second positioning groove of the pin can be interrupted in the circumferential direction of the scaffold tube or formed circumferentially.

In another preferred embodiment of the frame member, the scaffold tube has a node in which

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

b) a coupling point is formed to connect a cross bar, the scaffold tube having a first reinforcing groove in the area of the node. The first reinforcing groove is spaced less than 15 cm from the node in a first axial direction and reduces the inner diameter of the scaffold tube or increases the outer diameter of the scaffold tube. The frame member is reinforced by the first reinforcing groove in an area where it is specially loaded in the assembled state, that is, in the area of the node. Thanks to the first reinforcing groove, the scaffold tube offers increased strength and moment of inertia in the area of the pressure point of the crossbar. The coupling point can be designed in a rosette shape to connect a crossbar.

More preferably, the scaffold tube has an additional reinforcing groove in the node area, which is spaced less than 15 cm from the node in a second axial direction and reduces the inside diameter of the scaffold tube or increases the outside diameter of the scaffold tube. scaffold tube. The second axial direction is opposite to the first axial direction. In other words, the node is reinforced with an additional reinforcing groove in both axial directions by means of a reinforcing groove.

The spindle positioning groove (s) and the reinforcing groove (s) preferably reduce the inside diameter of the scaffold tube by the same amount.

The object of the invention is also achieved by a scaffold with a frame element described above.

Other features and advantages of the invention will be apparent from the following detailed description of various embodiments of the invention, from the claims, and with reference to the drawing figures, which show details that are essential to the invention.

The elements shown in the drawings are represented so that the features according to the invention can be made clearly visible. The various features can be implemented individually per se or in a plurality in any combination in variants of the invention.

In the drawings:

Figure 1 is a sectional view of a prior art frame member;

Figure 2 is a sectional view of a frame element according to the invention;

Figure 3 is a plan view of a node of a frame element according to the invention; Y

Figure 4 is a perspective view of a construction scaffold according to the invention.

Figure 1 shows a frame element 10 according to the state of the art. The frame member 10 has a scaffold tube 12 . A spindle receiving section 14 is formed in the scaffold tube 12. A threaded spindle 16 is inserted into the spindle receiving section 14. The threaded spindle 16 has an external thread 18 . The known frame member 10 also has a spindle nut 20 . The spindle nut 20 has an inner thread 22 with which the spindle nut 20 is joined to the outer thread 18 of the threaded spindle 16.

The screw receiving section 14 has the same inside diameter throughout the axial direction. The threaded spindle 16, which is supported axially on the scaffold tube 12 through the spindle nut 20, is inclined at the angle p. More precisely, the longitudinal axis 23a of the threaded spindle 16 is inclined at the angle p with respect to the longitudinal axis 23b of the scaffold tube 12. The angle p is typically 1.29 °.

In contrast to Figure 1, Figure 2 shows a frame member 10 according to the invention. The frame element 10 according to Figure 2 has a scaffold tube 12 with a spindle receiving section 14. Furthermore, the frame element 10 has a threaded spindle 16 on which a spindle nut 20 is arranged. Spindle receiving section 14 has a first spindle positioning groove 24, a second spindle positioning groove 26, and a third spindle positioning groove 28 . The spindle positioning slots 24, 26, 28 define the effective inside diameter of the spindle receiving section 14 for the threaded spindle 16. As a result of the spindle positioning slots 24, 26, 28, the threaded spindle 16 is arranged in the scaffold tube 12 in a significantly less inclined manner. The angle p 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 the frame member 10 according to Figure 1, the vertical load capacity of the frame member 10 increases by approximately 10%. Furthermore, the screw receiving section is mechanically reinforced against buckling by the screw positioning grooves 24, 26, 28.

In Figure 2, another frame member 30 is shown (dashed), the pin 32 of which can be inserted into the scaffold tube 12.

The scaffold tube 12 thus has a first scaffold tube axial end 34 into which the threaded spindle 16 can be inserted. Furthermore, the scaffold tube 12 has a second scaffold tube axial end 36 into which the threaded spindle can be inserted. the pin 32 of the additional frame member 30. A pin receiving section 38 for receiving the pin 32 in the scaffold tube 12 is formed at the second axial end of the scaffold tube 36. A mechanical reinforcement of the scaffold receiving section pin 38 as well as improved centering of pin 32 takes place via a first pin positioning slot 40 and a second pin positioning slot 42.

Figure 3 shows another frame member 10 according to the invention. The frame member 10 has a node 44 with an attachment point 46 . The coupling point 46 is in the present case in the form of a rosette. The cross bars 48, 50 are arranged at the coupling point 46.

It can be seen from Figure 3 that the scaffold tube 12 has a first reinforcing slot 54 which is formed in a first axial direction 56 at a distance from the coupling point 46 on the scaffold tube 12. A second slot reinforcement 58 is formed in the first axial direction 56 at a distance from the point of attachment 46 on the scaffold tube 12. The flanges 60, 62 of the cross bars 48, 50 rest on the scaffold tube 12 between the first slot of reinforcement 54 and the second reinforcement groove 58 in the area of the scaffold tube 12. The first reinforcement groove 54 and the second reinforcement groove 58 thus form a particularly stable and mechanical area of the scaffold tube 12 in which, in particular , the mechanical stability against impacts of the scaffold tube 12 is very high.

Scaffold tube 12 has an additional reinforcing groove 64 . The additional reinforcing 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 run along the longitudinal axis 23b of the scaffold tube 12, the second axial direction 66 is opposite the first axial direction 56. Through the additional reinforcing groove 64, lugs Insertions 68, 70 of the cross bars 48, 50 can be mechanically pressed particularly firmly onto the scaffold tube 12 without plastic deformation of the scaffold tube 12 when the cross bars 48 and / or 50 are loaded.

Alternatively or in addition to the stiffening grooves 54, 58, 64 described, the frame member 10 may be formed between axially adjacent coupling points, of which only one coupling point 46 is shown in Figure 3, at least one coupling groove additional reinforcement 72 in the scaffold tube 12.

Figure 4 shows a scaffold 74 with several frame elements, of which only a first frame element 10 is provided with a reference number for clarity in Figure 4. The frame element 10 exhibits, for example, a node 44 in which, also by way of example, a crossbar 48 is arranged. Due to the small representation of the construction scaffold 74, no groove according to the invention is seen in Figure 4. To transfer a load, the frame member 10 has a carrier head 76 .

Taking all the figures of the drawing together, the invention relates in summary to a frame member 10 with a scaffold tube 12 into which a threaded spindle 16 is partially inserted at one end. The threaded spindle 16 is guided in the scaffold tube 12 by at least one spindle positioning groove 24, 26, 28, in particular a plurality of spindle positioning grooves 24, 26, 28. The scaffold tube 12 is reinforced mechanically in the area of the threaded spindle 16 received in the scaffold tube 12 by the spindle positioning groove (s) 24, 26, 28. At the same time, the maximum inclination of the threaded spindle 16 in the scaffold tube 12 is reduced by the spindle positioning groove (s) 24, 26, 28. In general, the frame member 10 can be subjected to a significantly greater force in the direction of the longitudinal axis 23b of the scaffold tube 12. At the other end, the scaffold tube 12 can have at least one pin positioning groove 40, 42, in particular several pin positioning grooves 40, 42. Alternatively or additionally, the scaffold tube 12 can have at least a reinforcing groove 54, 58 , 64 in the area of a node 44. As an alternative or in addition to this, the scaffold tube 12 may have at least one additional reinforcing groove 72 between two nodes 44.

Claims (12)

1. Frame element (10) for a scaffold (74), wherein the frame element (10) comprises the following: a) a support head (76) having a threaded spindle (16); b) a frame tube (12) vertically mountable on the scaffold (74), said frame tube having a spindle receiving section (14) at a first axial end of the frame tube (34), wherein the threaded spindle (16) is partly inserted into the spindle receiving section (14); c) a spindle nut (20) which is mounted on the threaded spindle (16), wherein the support head (76) in the assembled state of the frame element (10) introduces its vertical load into the frame tube ( 12) through the threaded spindle (16); wherein the spindle receiving section (14) comprises a first spindle positioning groove (24) that reduces the inner diameter of the frame tube (12), characterized in that the spindle receiving section (14) comprises a second groove spindle positioning groove (26) which is axially spaced from the first spindle positioning groove (24) and reduces the inner diameter of the frame tube (12), wherein the second spindle positioning groove (26) reduces the diameter inside the frame tube (12) precisely to the first spindle positioning groove (24). Frame element according to claim 1, wherein the first spindle positioning groove (24) radially centers the threaded spindle (16) in the frame tube (12) such that the longitudinal axis (23a) of the threaded spindle (16) is inclined at the angle p with respect to the longitudinal axis (23b) of the frame tube (12), where the angle p is less than 1 °. Frame element according to claim 1 or 2, wherein the first spindle positioning groove (24) extends in the circumferential direction of the frame tube (12), wherein the first spindle positioning groove ( 24) is interrupted in the circumferential direction of the frame tube (12) or is made circumferentially. Frame member according to any one of the preceding claims, wherein the axial distance of the first spindle positioning groove (24) from the first axial end of the frame tube (34) is less than the inner diameter of the spindle receiving section (14). Frame member according to any one of the preceding claims, wherein the spindle receiving section (14) comprises a third spindle positioning groove (28) which is further axially spaced from the first spindle positioning groove ( 24) than the second spindle positioning groove (26) and the inside diameter of the frame tube (12). Frame element according to claim 5, wherein the third spindle positioning groove (28) reduces the inner diameter of the frame tube (12) exactly to the first spindle positioning groove (24). Frame member according to claim 5 or 6, wherein the third spindle positioning groove (28) is axially spaced closer to the second spindle positioning groove (26) than is the second spindle positioning groove. spindle (26) is spaced from the first spindle positioning slot (24). Frame element according to any of the preceding claims, wherein the frame tube (12) comprises at its second axial end of the frame tube (36) a spigot receiving section (38) in which it is possible inserting a tenon (32) of an additional frame member (30), wherein the tenon receiving section (38) comprises a first tenon positioning groove (40) that reduces the inside diameter of the frame tube (12) . Frame member according to claim 8, wherein the pin receiving section (38) comprises a second pin positioning slot (42) which is axially spaced from the first pin positioning slot (40) and reduces the inside diameter of the frame tube (12). Frame element according to any one of the preceding claims, wherein the frame tube (12) comprises a place of attachment (44) in which a) a transverse beam (48, 50) of the frame element (10) is connected to the frame tube (12) or b) a coupling location (46), in particular in the form of a rosette, is configured to connect a transverse beam (48, 50), wherein the frame tube (12) comprises a first reinforcing groove (54) that is spaced less than 15 cm in a first axial direction (56) from the attachment site (44) and i. reduces the inside diameter of the frame tube (12) or ii. The outer diameter of the frame tube (12) increases. Frame element according to claim 10, wherein the frame tube (12) comprises an additional reinforcing groove (64) in the area of the attachment site (44), said reinforcing groove being spaced less than 15 cm in a second axial direction (66) opposite the first axial direction (56) from the junction site (44) and i. reduces the inside diameter of the frame tube (12) or ii. The outer diameter of the frame tube (12) increases. 12. Scaffold (74) having a frame member (10) according to any one of the preceding claims.