DE102022107159A1 - Vertical support for a scaffold, scaffold and method for producing a vertical support - Google Patents

Abstract

The invention relates to a vertical support (10) for a scaffolding (100), in particular for a modular scaffolding, wherein the vertical support (10) comprises a tube (11) with a longitudinal axis (A) which is located in at least one tube section (12) - an external one Connecting element (20) for connecting the vertical handle (10) to a horizontal bar (40) and an internal reinforcing element (30) for reinforcing the pipe section (12) in a contact area (13) of the vertical handle (10) with the horizontal bar (40). , wherein the reinforcing element (30) is elongated and extends transversely to the longitudinal axis (A) from a first wall region (14) to a second wall region (15) of the tube (11), which is preferably diametrically opposite the first wall region (14). The invention further relates to a scaffolding (100), in particular a modular scaffolding, with a vertical support (10) according to the invention and a method for producing a vertical support (10).

Description

The invention relates to a vertical support for a scaffolding, in particular a modular scaffolding, and a scaffolding, in particular a modular scaffolding, with a corresponding vertical support. Furthermore, a method for producing a vertical support is proposed.

Technical background

In order to enable scaffolding to be assembled and dismantled quickly, prefabricated, standardized scaffolding components are usually used. The scaffolding components are connected to one another via standardized connecting elements and/or connection nodes, which ideally enable connections from different spatial directions. The scaffolding components can thus be assembled into complex surface or spatial scaffolding.

The higher the height of a scaffold, the greater the loads that act on the scaffold components and their connections. Particularly in the connection area of a horizontal beam to a vertical support, overstress can occur, so that there are limits to the maximum scaffolding height. To remedy this, a vertical support can be used, which is made from a tube with an enlarged outside diameter and/or with an increased wall thickness. However, this measure leads to an increased weight of the vertical handle, making handling of the vertical handle more difficult.

From the EP 0 990 748 A1 a vertical scaffolding tube is known, on which at least one holding device is attached, into which horizontal and / or diagonal scaffolding tubes can be suspended. To improve the load-carrying capacity of the vertical scaffolding tube, it is reinforced in the area in which the holding device is attached. This means that the scaffolding tube is only locally reinforced, so that the weight only increases slightly. Various measures are proposed for local reinforcement, but these either lead to changed external dimensions of the vertical scaffolding tube, so that compatibility with other standardized scaffolding components is no longer guaranteed, or are complex and therefore costly.

The present invention is therefore concerned with the task of improving the load-carrying capacity of a vertical support in such a way that the above-mentioned disadvantages do not arise.

To solve the problem, the vertical support with the features of claim 1, the scaffold with the features of claim 7 and the method for producing a vertical support with the features of claim 10 are proposed. Advantageous developments of the invention can be found in the respective subclaims.

Disclosure of the invention

• - ein außenliegendes Verbindungselement zur Verbindung des Vertikalstiels mit einem Horizontalriegel sowie
• - ein innenliegendes Verstärkungselement zur Verstärkung des Rohrabschnitts in einem Kontaktbereich des Vertikalstiels mit dem Horizontalriegel aufweist. Das Verstärkungselement ist dabei länglich geformt und erstreckt sich quer zur Längsachse A von einem ersten Wandungsbereich bis zu einem zweiten Wandungsbereich des Rohrs, der vorzugsweise dem ersten Wandungsbereich diametral gegenüberliegt.

A vertical support is proposed for a scaffold, in particular for a modular scaffold. The vertical stem comprises a tube with a longitudinal axis A, which is in at least one tube section

• - an external connecting element for connecting the vertical stem with a horizontal bar and
• - Has an internal reinforcing element for reinforcing the pipe section in a contact area of the vertical stem with the horizontal bar. The reinforcing element is elongated and extends transversely to the longitudinal axis A from a first wall region to a second wall region of the tube, which is preferably diametrically opposite the first wall region.

With the help of the reinforcing element extending from the first wall area to the second wall area, the vertical support is locally reinforced. The vertical support is therefore able to absorb high loads that are introduced in the contact area by the adjacent horizontal bar. The load-carrying capacity of the vertical support increases accordingly. At the same time, the risk of deformation of the vertical stem in the contact area with the horizontal bar due to excessive loads is reduced.

Since the vertical stem is particularly exposed to an increased pressure load due to the adjacent horizontal bar, the reinforcing element preferably extends parallel to the horizontal bar. Furthermore, the reinforcing element is preferably arranged in an extension of the horizontal bar. The compressive force introduced via the horizontal bar is then absorbed directly by the reinforcing element. For example, the reinforcing element can be arranged such that in the floor plan projection a longitudinal axis of the reinforcing element coincides with a longitudinal axis A` of the horizontal bar. In this case, the longitudinal axis A' preferably intersects the longitudinal axis A of the tube of the vertical stem. The reinforcing element then extends from a first wall region to a second wall region of the pipe that is diametrically opposite the first wall region, so that it is optimally reinforced or stiffened.

The merely local reinforcement of the vertical stem by the reinforcing element increases the weight of the vertical stem only insignificantly, even if the vertical stem is locally reinforced by reinforcing elements in several contact areas and/or in several pipe sections. The single or multiple reinforced vertical handle remains easy to handle. Because the at least one reinforcing element is also arranged on the inside, the external dimensions of the vertical support remain unchanged. In this way, the compatibility of the vertical support with other standardized scaffolding components is maintained.

The reinforcement of the vertical support with the help of the at least one reinforcing element can also be realized easily and cost-effectively. This is particularly true when a simple bolt or pin is used as a reinforcing element. The reinforcing element can also be a simple elongated plate which extends transversely to the longitudinal axis A in a web-like manner from the first wall region to the second wall region.

An opening is advantageously formed in the first wall region and/or in the second wall region, in which the reinforcing element is received at the end. In this way, a positive connection is achieved between the reinforcing element and the tube, which holds the reinforcing element in position. Preferably, an opening is formed in both the first wall region and the second wall region, into which the reinforcing element is embedded at each end. Furthermore, at least one opening is preferably designed such that it passes through the wall of the tube. The reinforcing element can thus be inserted from the outside into the opening and thus into the pipe section to be reinforced during the production of the vertical stem. This makes it easier to make the vertical stem. If the reinforcing element remains visible from the outside, the vertical support on a construction site can be identified at any time as a locally reinforced vertical support.

Preferably, the length of the reinforcing element is not chosen to be greater than the pipe diameter of the vertical stem, so that it is ensured that the reinforcing element does not protrude outwards. This is because the external dimensions of the vertical support should not be changed by the reinforcing element. According to a particularly preferred embodiment of the invention, the length of the reinforcing element corresponds to the pipe diameter of the vertical stem, so that the reinforcing element is flush with the pipe diameter. This avoids setbacks where surface water can collect.

Furthermore, the shape of the opening receiving the reinforcing element is preferably adapted at least in sections to the cross-sectional shape of the reinforcing element. In this way, the positive connection between the reinforcing element and the tube can be optimized, so that the reinforcing element is securely held in the opening. For example, if the reinforcing element has a circular cross section, the opening can also be circular or at least shaped as a semicircle, for example as an elongated hole with a semicircular end section for receiving the reinforcing element. A circular cross-sectional shape of the reinforcing element enables the use of a simple bolt as a reinforcing element. In addition, a variety of other cross-sectional shapes are also conceivable.

The reinforcing element is preferably made of steel because steel has high strength.

Furthermore, it is proposed that the reinforcing element is firmly connected, preferably welded, to the tube of the vertical stem. The firm connection, in particular welding, ensures that the reinforcing element is held captively in the tube of the vertical support. This is particularly advantageous when setting up and dismantling a scaffold using a vertical handle according to the invention. If at least one opening receiving the reinforcing element is designed in such a way that the opening passes through the wall, the welding can be carried out in a simple manner from the outside.

Furthermore, the reinforcing element is preferably arranged at an axial distance from the connecting element. This means that the height of the reinforcing element and the height of the connecting element differ. This means that a conventional vertical support can be subsequently reinforced and thus strengthened with at least one connecting element for connecting to a horizontal bar.

Preferably, at least one reinforcing element is arranged above and/or below the connecting element with respect to the final installation position of the vertical support. This applies in particular if the contact area of the horizontal bar extends from above the connecting element to below the connecting element or if there is a first contact area above and a second contact area below the connecting element. The vertical stem is then attached to each particularly stressed and therefore critical areas.

According to a preferred embodiment of the invention, the tubular section of the vertical stem is reinforced in the area of contact with the horizontal bar by several reinforcing elements. Since usually at least two horizontal bars, which are arranged in a scaffolding plane and run transversely to one another, are connected to the vertical bar via the connecting element, the vertical post can be reinforced with a horizontal bar in each contact area. The plurality of reinforcing elements are preferably arranged offset from one another with regard to their height and/or angular position. Due to the height and/or angular offset, the multiple reinforcing elements can be arranged in a cross or star shape, so that the vertical post is optimally reinforced in the different contact areas with one and/or with several horizontal bars.

Each reinforcing element is preferably accommodated in an opening at both ends, so that at least two openings are always opposite one another. With two reinforcing elements arranged in a cross shape, four openings must be provided in the pipe at the same angular distance from one another, so that two openings are opposite each other. In order to simplify the insertion of reinforcing elements arranged in a cross or star shape, the openings are preferably not only angularly offset, but also vertically offset. The height offset can be chosen so small that the reinforcing elements touch each other.

Since each horizontal bar adjoining the vertical stem can have several contact areas with the vertical stem, openings for receiving reinforcing elements are preferably provided above and below the rosette-like connecting element of the vertical stem. These are preferably arranged where the largest pressure points of the horizontal bar resting on the vertical support are located. These can lie exactly one above the other, so that in this case the openings for receiving the reinforcing elements are arranged above and below the rosette-like connecting element in the same angular position. This means that the openings and the reinforcing elements accommodated therein also lie exactly one above the other in the floor plan projection above and below the rosette-like connecting element.

In a further development of the invention, it is proposed that the connecting element for connecting the vertical stem to the horizontal bar is designed like a rosette and has at least one receiving opening for receiving connecting means of the horizontal bar. The rosette-like connecting element is preferably arranged coaxially or concentrically with respect to the longitudinal axis A on the tube of the vertical stem, so that connection options arise for connecting horizontal bars from different directions. Furthermore, the connecting element preferably has a plurality of receiving openings arranged at the same angular distance from one another for receiving connecting means of horizontal bars. In addition, the connecting element can have further recesses that offer connection options for further scaffolding components.

The proposed vertical stem preferably has a plurality of rosette-like connecting elements which are distributed over the length of the vertical stem, that is to say are arranged in different pipe sections. This increases the connection options on the vertical support. Preferably, all pipe sections in which a rosette-like connecting element is arranged are reinforced by at least one reinforcing element accommodated in the pipe. At least one reinforcing element is preferably arranged above and below a rosette-like connecting element.

Since the preferred area of application of a vertical support according to the invention is a scaffolding, in particular a modular scaffolding, a scaffolding, in particular a modular scaffolding, with a vertical support according to the invention and a horizontal bar is also proposed. The horizontal bar is connected to the vertical handle via the connecting element of the vertical handle. Because the vertical support according to the invention is locally reinforced in the contact area with the horizontal bar, the load-carrying capacity of the vertical support increases. Loads introduced by the horizontal bar, in particular pressure loads, can therefore be better absorbed. As a result, the risk of the vertical beam deforming under load is reduced.

In the proposed framework, the connecting element is preferably designed like a rosette and the horizontal bar has connecting means which engage in at least one receiving opening of the connecting element. The connecting means can comprise a wedge element for locking the connecting means within the receiving opening of the connecting element, so that undesirable slipping out of the connecting means from the receiving opening is prevented. The wedge element can, for example, be driven into the receiving opening from above after the connecting means have been inserted.

The horizontal bar preferably rests on the vertical stem in the contact area via its connecting means and/or an end face area which is preferably concavely shaped. This means that the vertical support can also have several contact areas with the horizontal bar. For example, in a first contact area, the horizontal bar can rest on the vertical stem via a preferably concavely shaped end face area, the first contact area preferably being arranged above the connecting element receiving the connecting means of the horizontal bar. In a second contact area, which is preferably arranged below the connecting element, the horizontal bar can rest on the vertical stem via its connecting means. The load introduced from the horizontal bar into the vertical bar is thus distributed, which also has a positive effect on the load-carrying capacity of the vertical support. Furthermore, the vertical stem is preferably locally reinforced in both contact areas by an internal, elongated reinforcing element. For this purpose, the two reinforcing elements are arranged at an axial distance from one another, so that a first reinforcing element is arranged above the connecting element and a second reinforcing element is arranged below the connecting element.

• - Bereitstellen eines Rohrs mit einer Längsachse A,
• - Befestigen eines Verbindungselements zur Verbindung des Vertikalstiels mit einem Horizontalriegel in zumindest einem Rohrabschnitt des Rohrs,
• - Einbringen einer Öffnung in einen Wandungsbereich des Rohrabschnitts, wobei vorzugsweise die Öffnung die Wandung des Rohrs durchsetzt,
• - Einsetzen eines länglich geformten Verstärkungselements in die Öffnung, so dass sich das Verstärkungselement quer zur Längsachse A vom ersten Wandungsbereich bis zu einem zweiten Wandungsbereich des Rohrabschnitts erstreckt, der vorzugsweise dem ersten Wandungsbereich diametral gegenüberliegt.

In addition, a method for producing a vertical support for a scaffold, in particular for a modular scaffold, is proposed. The procedure has the following steps:

• - Providing a pipe with a longitudinal axis A,
• - Fastening a connecting element for connecting the vertical stem to a horizontal bar in at least one pipe section of the pipe,
• - introducing an opening into a wall area of the pipe section, the opening preferably passing through the wall of the pipe,
• - Inserting an elongated reinforcing element into the opening, so that the reinforcing element extends transversely to the longitudinal axis A from the first wall region to a second wall region of the pipe section, which is preferably diametrically opposite the first wall region.

The sequence of procedural steps can vary. For example, an opening can first be made in the pipe, the reinforcing element inserted and then the connecting element attached to the pipe. The fastening of the connecting element can also be carried out before inserting the reinforcing element.

With the help of the reinforcing element, the load-bearing capacity of the vertical support can be improved, since the reinforcing element extends from a first wall section of the pipe to a second wall section, which is preferably diametrically opposite the first wall section. The reinforcing element thus connects the two wall cross sections, so that the load-bearing cross section extends from the first wall region via the reinforcing element to the second wall section.

The reinforcing element and the connecting element are preferably aligned with one another in such a way that in the floor plan projection a horizontal bar connected to the vertical stem via the connecting element and the reinforcing element have a common longitudinal axis. This means that the reinforcing element is arranged in an extension of the horizontal bar. The load introduced into the vertical support via the horizontal bar can then be absorbed directly by the reinforcing element.

Because the reinforcing element is inserted into an opening, it is held in a form-fitting manner in the pipe. If the opening penetrates the wall of the pipe, the reinforcing element can be inserted from the outside, which significantly simplifies the production of the vertical support. Furthermore, the vertical support can later be identified as a reinforced vertical support based on the opening visible from the outside and the reinforcing element inserted therein.

A further opening is preferably formed in the second wall region and the reinforcing element is inserted into the further opening at the end. The reinforcing element is then received at both ends in an opening in the pipe and is thus optimally held in the pipe. The further opening can also pass through the wall of the pipe, so that both openings and both ends of the reinforcing element inserted therein remain clearly visible for identifying the vertical stem.

Advantageously, the reinforcing element is firmly connected to the tube of the vertical stem, preferably welded. This ensures that the reinforcing element is permanently held captive in the pipe. This applies in particular if the reinforcing element is inserted from the outside into the at least one wall-side opening of the pipe. The firm connection, in particular welding, prevents the reinforcing element from slipping out of the opening, for example when setting up or dismantling a scaffold. The reinforcing element is preferably welded to the pipe at both ends particularly when both ends of the reinforcing element are received in openings in the pipe. The welding can then be carried out easily from the outside.

If the reinforcing element is to be welded to the pipe, a reinforcing element can be used that has a recess in at least one end section. Welding can then be carried out in the area of the recess so that the weld seam remains within the recess and does not spread to the outside. The weld seam can also be designed and arranged in such a way that the recess is no longer visible after welding. To form the recess, for example, the reinforcing element can be designed to be stepped at the end.

Furthermore, it is proposed that the shape of the at least one opening for receiving the reinforcing element is adapted at least in sections to the cross-sectional shape of the reinforcing element. Any recess at the end of the reinforcing element for receiving welding material is not taken into account, otherwise the recess can no longer fulfill its purpose. Alternatively or in addition to the end recess of the reinforcing element, the opening accommodating the reinforcing element can be made larger in sections so that the weld seam can be placed in this area. For example, the opening can be designed as an elongated hole, the shape of which is at least partially adapted to the cross-sectional shape of the reinforcing element.

The at least one opening for receiving the reinforcing element is preferably introduced into the pipe section at an axial distance from the connecting element, so that after inserting the reinforcing element into the at least one opening, the pipe section is locally reinforced above or below the connecting element with respect to the final installation position of the vertical stem becomes. The exact position depends on the position of the contact area of the vertical post with the horizontal bar, which is connected to the vertical post via the connecting element. For example, the horizontal bar can have connecting means that can be brought into engagement with a receiving opening of the connecting element and which rest on the vertical stem below the connecting element. Alternatively or additionally, the horizontal bar can have an end face area which rests on the vertical stem above the connecting element. If the latter is the case, the end face area is preferably concave in order to increase the contact area and improve the load distribution.

Since the vertical post can have several contact areas with the horizontal bar, it is proposed in a further development of the invention that the vertical post is locally reinforced both above and below the connecting element for connecting the horizontal bar to the vertical post. This means that at least one opening for receiving a reinforcing element is made in the pipe both above and below the connecting element. If the connecting element is only attached to the pipe after the opening has been made, the later position of the connecting element must be taken into account when making the openings.

The connecting element can be, for example, a rosette-like connection plate, which is arranged coaxially or concentrically with respect to the pipe and enables the connection of several horizontal bars from different directions via several receiving openings arranged at the same angular distance from one another. In this way, for example, two horizontal bars that run perpendicular to one another can be connected to the vertical stem via the connecting element.

As a further development measure, it is therefore proposed that several openings for receiving several reinforcing elements are introduced into the pipe section of the vertical stem, which are arranged offset from one another with regard to their height and/or angular position. This enables a cross or star-shaped arrangement of several reinforcing elements so that they can each be arranged in an extension of a horizontal bar. In this way, the different connection options that the connecting element offers are optimally taken into account.

According to a preferred embodiment of the invention, the vertical stem has two reinforcing elements running perpendicular to one another both above and below the connecting element, which are arranged slightly offset from one another in their height so that they can be guided past one another. This results in a cross-shaped arrangement in the floor plan projection. In the final installation position of the vertical support, the longitudinal axes of the reinforcing elements then preferably coincide with the scaffolding axes.

To expand the connection options on the vertical stem, it is also proposed that several rosette-like connecting elements be arranged distributed over the length of the vertical stem. Preferably, all pipe sections that have rosette-like connecting elements are then locally reinforced with the help of at least one reinforcing element accommodated in the pipe.

• 1 eine perspektivische Darstellung eines erfindungsgemäßen Vertikalstiels,
• 2 eine perspektivische Darstellung des Vertikalstiels der 1 und eines mit dem Vertikalstiel verbundenen Horizontalriegels und
• 3 eine Draufsicht auf die Anordnung der 2.

A preferred embodiment of the invention is described in more detail below with the aid of the accompanying drawings. These show:

• 1 a perspective view of a vertical handle according to the invention,
• 2 a perspective view of the vertical stem of the 1 and a horizontal bar connected to the vertical support and
• 3 a top view of the arrangement of the 2 .

Detailed description of the characters

The Indian 1 The vertical stem 10 according to the invention shown has a tube 11 with a longitudinal axis A and a tube section 12 on which a rosette-like connecting element 20 for connecting the vertical stem 10 to a horizontal bar 40 (see 2 ) is arranged. For this purpose, the connecting element 20 has a plurality of receiving openings 21, which are arranged at the same angular distance from one another.

Above and below the connecting element 20, openings 16 are provided in the pipe section 12, which in the present case are designed as an elongated hole. A bolt-like reinforcing element 30 is inserted into the openings 16 and runs transversely to the longitudinal axis A of the tube 11. The openings 16 each pass through the wall of the tube 11, so that the reinforcing elements 30 can be inserted into the openings 16 from the outside. By designing the openings 16 as an elongated hole, the reinforcing elements 30 inserted therein can be welded to the pipe 11 in a simple manner. The welding ensures a firm connection of the reinforcing elements 30 to the vertical post 10, so that the reinforcing elements 30 do not fall out of the openings 16. Again 1 As can be seen, the reinforcing elements 30 or openings remain visible, so that the vertical post 10 can be identified as a locally reinforced vertical post 10.

The position of the reinforcing elements 30 is predetermined by a contact area 13 of the vertical stem 10 with a horizontal bar 40, which is later connected to the vertical stem 10 via the connecting element 20. The two reinforcing elements 30 arranged above and below the connecting element 20 run parallel to one another. This means that the openings 16 lie one above the other at an axial distance from one another. The same applies to one of the four receiving openings 21 of the connecting element 20, so that it is ensured that the horizontal bar 40 connected thereto comes to rest in the contact areas 13 on the vertical stem 10. The vertical stem 10 is thus locally reinforced by the reinforcing elements 30 in the contact areas 13.

In the 2 a section of a scaffold 100 is shown, which supports the vertical handle 10 1 and a horizontal bar 40 includes. The horizontal bar 40 has connecting means 41 which engage in a receiving opening 21 of the connecting element 20. The connecting means 41 include a wedge element 43, with the help of which the connecting means 41 are locked in the receiving opening 41. The wedge element 43 presses the connecting means 41 against the vertical stem 10 so that they come into contact with the vertical stem 10 in a first contact area 13. Since a first reinforcing element 30 is arranged in the first contact area 13, the load introduced by the horizontal bar 40 is absorbed by the reinforcing element 30. This means that the load-carrying capacity of the vertical support 10 in the first contact area 13 increases. In a second contact area 13, in which the horizontal bar 40 also comes into contact with the vertical stem 10 via a concavely shaped end face area 42, the introduced load is absorbed by the second reinforcing element 30 arranged in this area. This also contributes to increasing the load-carrying capacity of the vertical support 10.

When the horizontal bar 40 is hung, at least the openings 16 designed as elongated holes, in which the two reinforcing elements 30 are accommodated, remain visible. This means that it remains visible to everyone that the vertical post 10 of the scaffold 100 is locally reinforced.

3 shows the scaffolding 100 in a top view of the vertical support 10. 3 makes it clear that the two reinforcing elements 30 each extend from a first wall region 14 to a second wall region 15, which is preferably diametrically opposite the first wall region 14. This is particularly advantageous if the horizontal bar 40 is connected in the manner shown, so that a longitudinal axis A' of the horizontal bar 40 intersects the longitudinal axis A of the tube 11 of the vertical stem 10. Because then the two reinforcing elements 30 are each arranged in an extension of the horizontal bar 40, in the middle with respect to the longitudinal axis A 'of the horizontal bar 40. This means that in the floor plan projection, the longitudinal axes of the two reinforcing elements 30 are aligned with the longitudinal axis A' of the horizontal bar 40 coincide.

In the 3 The horizontal bar 40 connects to the vertical stem 10 coming from the right. Becomes the scaffolding 100 is extended, another horizontal bar 40 can be connected coming from the left. Since the reinforcing elements 30 each extend from the first wall region 14 to the second wall region 15, which in the present case is diametrically opposite the first wall region 14, the reinforcing elements 30 achieve an improved load-carrying capacity of the vertical support 10, regardless of whether the connection of a horizontal bar 40 is from the right and/or from the left.

The rosette-like connecting element 20 shown also enables the connection of two further horizontal bars 40 (not shown), which run transversely to the horizontal bar 40, so that they - in relation to the 3 - Connect to the vertical support 10 from above or below. In order to further optimize the load-carrying capacity of the vertical support 10, two further reinforcing elements 30 (not shown) can be provided, which run perpendicular to the reinforcing elements 30 shown or in an extension of the further horizontal or crossbars (not shown). The arrangement is then offset in terms of its height and angular position from the reinforcing elements 30 that are already present. This results in a cross-shaped arrangement, which is ideally based on the scaffold axes (not shown) of the scaffold 100.

Reference symbol list

10

vertical stem

11

Pipe

12

pipe section

13

Contact area

14

Wall area

15

Wall area

16

opening

20

connecting element

21

Recording opening

30

Reinforcement element

40

Horizontal bars

41

lanyard

42

Frontal area

43

Wedge element

100

framework

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0990748 A1 [0004]

Claims (15)

Vertical support (10) for a scaffolding (100), in particular for a modular scaffolding, wherein the vertical support (10) comprises a tube (11) with a longitudinal axis (A) which is in at least one tube section (12). - an external connecting element (20) for connecting the vertical handle (10) to a horizontal bar (40) and - has an internal reinforcing element (30) for reinforcing the pipe section (12) in a contact area (13) of the vertical stem (10) with the horizontal bar (40), the reinforcing element (30) being elongated and extending transversely to the longitudinal axis (A). extends from a first wall region (14) to a second wall region (15) of the tube (11), which is preferably diametrically opposite the first wall region (14). vertical support (10). Claim 1 , characterized in that in the first wall region (14) and / or in the second wall region (15) an opening (16) is formed, in which the reinforcing element (30) is received at the end, the shape of the opening preferably adapting at least in sections to the cross-sectional shape of the reinforcing element (30) is adapted. vertical support (10). Claim 1 or 2 , characterized in that the reinforcing element (30) is made of steel and/or is firmly connected, preferably welded, to the tube (11) of the vertical stem (10). Vertical support (10) according to one of the preceding claims, characterized in that the reinforcing element (30) is arranged at an axial distance from the connecting element (20), with preferably at least one reinforcing element (30) above and/or below the connecting element (20). Relative to the final installation position of the vertical handle (10) is arranged. Vertical support (10) according to one of the preceding claims, characterized in that the pipe section (12) in the contact area (13) is reinforced by a plurality of reinforcing elements (30), which are preferably arranged offset from one another with regard to their height and/or angular position. Vertical handle (10) according to one of the preceding claims, characterized in that the connecting element (20) for connecting the vertical handle (10) to the horizontal bar (40) is designed like a rosette and at least one receiving opening (21) for receiving connecting means (41) of the Horizontal bar (40). Scaffolding (100), in particular modular scaffolding, with a vertical support (10) according to one of the preceding claims and a horizontal bar (40) which is connected to the vertical support (10) via the connecting element (20) of the vertical support (10). Scaffolding (100). Claim 7 , characterized in that the connecting element (20) is designed like a rosette and the horizontal bar (40) has connecting means (41) which engage in at least one receiving opening (21) of the connecting element (20). Scaffolding (100). Claim 7 or 8th , characterized in that the horizontal bar (40) rests on the vertical stem (10) in the contact area (13) via its connecting means (41) and/or an end face area (42), which is preferably concavely shaped. Method for producing a vertical support (10) for a framework (100), in particular for a modular framework, comprising the steps: - Providing a tube (11) with a longitudinal axis (A), - Fastening a connecting element (20) for connecting the vertical stem (10) to a horizontal bar (40) in at least one pipe section (12) of the pipe (11), - introducing an opening (16) into a wall region (14) of the pipe section (12), the opening (16) preferably passing through the wall of the pipe (11), - Inserting an elongated reinforcing element (30) into the opening (16), so that the reinforcing element (30) extends transversely to the longitudinal axis (A) from the first wall region (14) to a second wall region (15) of the pipe section (12). , which is preferably diametrically opposite the first wall region (14). Procedure according to Claim 10 , characterized in that a further opening (16) is formed in the second wall region (15) and the reinforcing element (30) is inserted into the further opening (16) at the end. Procedure according to Claim 10 or 11 , characterized in that the reinforcing element (30) is made of steel and / or is firmly connected, preferably welded, to the tube (11) of the vertical stem (10). Procedure according to one of the Claims 10 until 12 , characterized in that the shape of the at least one opening (16) is at least is adapted in sections to the cross-sectional shape of the reinforcing element (30). Procedure according to one of the Claims 10 until 13 , characterized in that the at least one opening (16) for receiving the reinforcing element (30) is introduced into the pipe section (12) at an axial distance from the connecting element (20), so that after the reinforcing element (30) has been inserted into the at least an opening (16) of the pipe section (12) above or below the connecting element (20) is reinforced with respect to the final installation position of the vertical handle (10). Procedure according to one of the Claims 10 until 14 , characterized in that a plurality of openings (16) for receiving a plurality of reinforcing elements (30) are introduced into the pipe section (12), which are preferably arranged offset from one another with regard to their height and / or angular position.

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