WO2023099334A1 - Pièce d'assemblage pour assembler des éléments d'échafaudage - Google Patents

Pièce d'assemblage pour assembler des éléments d'échafaudage Download PDF

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Publication number
WO2023099334A1
WO2023099334A1 PCT/EP2022/083162 EP2022083162W WO2023099334A1 WO 2023099334 A1 WO2023099334 A1 WO 2023099334A1 EP 2022083162 W EP2022083162 W EP 2022083162W WO 2023099334 A1 WO2023099334 A1 WO 2023099334A1
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WO
WIPO (PCT)
Prior art keywords
carrier
interface
spatial direction
scaffolding
connection
Prior art date
Application number
PCT/EP2022/083162
Other languages
German (de)
English (en)
Inventor
Rainer Klima
Original Assignee
Peri Se
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Peri Se filed Critical Peri Se
Publication of WO2023099334A1 publication Critical patent/WO2023099334A1/fr

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Classifications

    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G7/00Connections between parts of the scaffold
    • E04G7/02Connections between parts of the scaffold with separate coupling elements
    • E04G7/06Stiff scaffolding clamps for connecting scaffold members of common shape
    • E04G7/20Stiff scaffolding clamps for connecting scaffold members of common shape for ends of members only, e.g. for connecting members in end-to-end relation
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G1/00Scaffolds primarily resting on the ground
    • E04G1/24Scaffolds primarily resting on the ground comprising essentially special base constructions; comprising essentially special ground-engaging parts, e.g. inclined struts, wheels
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G5/00Component parts or accessories for scaffolds
    • E04G5/04Means for fastening, supporting, or bracing scaffolds on or against building constructions
    • E04G5/045Means for fastening, supporting, or bracing scaffolds on or against building constructions for fastening scaffoldings on profiles, e.g. I or H profiles
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G7/00Connections between parts of the scaffold
    • E04G7/02Connections between parts of the scaffold with separate coupling elements
    • E04G7/06Stiff scaffolding clamps for connecting scaffold members of common shape
    • E04G7/22Stiff scaffolding clamps for connecting scaffold members of common shape for scaffold members in end-to-side relation
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G7/00Connections between parts of the scaffold
    • E04G7/02Connections between parts of the scaffold with separate coupling elements
    • E04G7/06Stiff scaffolding clamps for connecting scaffold members of common shape
    • E04G7/24Couplings involving arrangements covered by more than one of the subgroups E04G7/08, E04G7/12, E04G7/20, E04G7/22
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G17/00Connecting or other auxiliary members for forms, falsework structures, or shutterings
    • E04G17/04Connecting or fastening means for metallic forming or stiffening elements, e.g. for connecting metallic elements to non-metallic elements
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G17/00Connecting or other auxiliary members for forms, falsework structures, or shutterings
    • E04G17/14Bracing or strutting arrangements for formwalls; Devices for aligning forms
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G1/00Scaffolds primarily resting on the ground
    • E04G1/24Scaffolds primarily resting on the ground comprising essentially special base constructions; comprising essentially special ground-engaging parts, e.g. inclined struts, wheels
    • E04G2001/248Inclined struts
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04GSCAFFOLDING; FORMS; SHUTTERING; BUILDING IMPLEMENTS OR AIDS, OR THEIR USE; HANDLING BUILDING MATERIALS ON THE SITE; REPAIRING, BREAKING-UP OR OTHER WORK ON EXISTING BUILDINGS
    • E04G7/00Connections between parts of the scaffold
    • E04G2007/005Adaptors to adapt the connection means of one manufacturer's scaffold system to the one of another manufacturer

Definitions

  • Connection component for connecting scaffolding elements
  • the invention relates to a connecting component for connecting at least two scaffolding elements, comprising a holder with a carrier, an inner interface and at least one outer interface, with the carrier at least partially enclosing the inner interface, with the inner interface being formed by an opening in the carrier, which opens the carrier in a completely penetrates the first spatial direction and the at least one outer interface is formed by a recess in the carrier, which is arranged adjacent to the inner interface or at a distance from the inner interface.
  • the connection component also comprises at least one additional interface, which is connected to the carrier of the holder, the additional interface having a rod-shaped or tubular connection area which extends in a second spatial direction.
  • the invention further relates to a scaffolding section with a connecting component and a method for constructing a scaffolding section.
  • Facade scaffolding is used to design the outer surfaces of buildings, for example to paint them.
  • Façade scaffolding is usually constructed from façade scaffolding frames as the main components, and more recently these have also been constructed from modular scaffolding.
  • shoring is used to bring a wide variety of building components into position and hold them there.
  • building parts can be, for example, prefabricated concrete parts, steel girders or steel structures.
  • elements required for the erection of buildings, such as makeshift constructions or formwork with shoring can be positioned.
  • scaffolding is also used in the service or revision area, for example to bring workers safely to the parts of the plant to be overhauled in large process engineering plants, such as refineries.
  • scaffolding systems In general, the basic requirements for scaffolding are that they must be easy to transport and set up. Different scaffolding systems exist for different applications. Such scaffolding systems are built like a modular system and make it possible to assemble individual scaffolding shapes from standardized components in a simple manner. However, these components can usually only be efficiently combined with components from the same scaffolding system and can only be connected to another scaffolding system with great effort.
  • system scaffolds from civil engineering as construction aids for bridges which are very stable and are intended to temporarily support components of the bridge during construction.
  • the construction aid for the bridge must also have steps, railings, ladders and the like.
  • these elements are typically created using a different scaffolding system, such as facade scaffolding.
  • the assembly aid or support structure of the bridge which is formed by a first scaffolding system, must be connected to work surfaces for working people, which are formed by a second scaffolding system.
  • interfaces must be provided that allow a second scaffolding system to be connected to a first scaffolding system.
  • this is often realized by individually adapted connection components that are created on site at the construction site.
  • the disadvantage of such self-made connecting parts is that their load-bearing capacity is often not correctly estimated and, in addition, a lot of work is required to create such connecting parts.
  • connection component which has an interface for connecting to an I-beam of a supporting structure and a further interface for connecting a post which can be part of a facade scaffolding, for example.
  • connection components can usually only be attached in one orientation to one or two scaffolding systems.
  • the attachment is usually complex and often no longer possible when a scaffolding system is already fully assembled.
  • known connection components only one connection of two different scaffolding systems or two different types of scaffolding elements is required possible. In practice, however, there is an increasing requirement to be able to connect at least three differently designed scaffolding elements that belong to two or more scaffolding systems.
  • the object of the invention is therefore to propose solutions with which at least three scaffolding elements can be connected to one another in a simplified and yet secure manner, with the at least three scaffolding elements belonging to at least two different scaffolding systems.
  • a holder with a carrier, an inner interface and at least one outer interface, the carrier at least partially enclosing the inner interface, the inner interface being formed by an opening in the carrier which completely penetrates the carrier in a first spatial direction, and the at least one outer interface being formed by a Recess is formed in the carrier, which is arranged adjacent to the inner interface or at a distance from the inner interface,
  • the additional interface has a rod-shaped or tubular connection area, which extends in a second spatial direction, wherein the first spatial direction is oriented essentially perpendicular to the second spatial direction and the at least one external interface extends in the direction of the first spatial direction and penetrates the carrier at least partially in the direction of the first spatial direction.
  • the connection component according to the invention is used to connect at least two scaffolding elements. These framework elements are preferably parts of different framework systems.
  • a scaffolding system is a system that includes several different scaffolding elements that can be connected to one another via interfaces that are standardized in the scaffolding system. The scaffolding elements within a scaffolding system are matched to one another and enable the construction of different scaffolding sections or scaffolding in the manner of a modular system. Scaffolding systems are offered by different manufacturers.
  • a scaffolding system is usually only intended for the construction of a single type of scaffolding, for example for a facade scaffolding, a shoring, in formwork scaffolding or the like.
  • the scaffolding elements of different scaffolding systems therefore usually differ from one another in the form, size and type of interfaces for the connection.
  • connection component enables a connection between scaffolding elements that belong to different scaffolding systems.
  • a scaffolding system can also be understood to mean a formwork system for forming part of a building. Formwork systems and scaffolding systems are often used on the construction site in direct interaction with one another and are connected to one another in different ways.
  • the connection component according to the invention also enables the connection of at least one formwork system to correspondingly designed interfaces.
  • the connection component comprises a holder which comprises a carrier, an inner interface and at least one outer interface.
  • the carrier positions the inner interface and the outer interfaces and forms a load-transmitting element of the mount.
  • the inner interface is provided for connecting the connection component to a framework element of a first framework system.
  • the inner interface is formed by an opening in the carrier, which completely penetrates the carrier in a first spatial direction.
  • a skeleton member of a first skeleton system can be slid into the internal interface and then penetrates through the bracket and the connection component.
  • the carrier at least partially encloses the internal interface in a plane perpendicular to the first spatial direction. It is also possible for the carrier to completely enclose the internal interface in such a plane.
  • the first scaffolding system is preferably a shoring with a high load-bearing capacity.
  • a framework element that can be connected to the internal interface can be a carrier element, for example an I-beam, also called an I-rail.
  • the shape of the opening in the carrier, which forms the internal interface is preferably adapted to the shape of a framework element of a first framework system, which is intended to be connected to the connecting component.
  • the at least one external interface forms a connection interface which is provided for connecting the connection component to a further framework element, preferably to a further framework element of a second framework system.
  • the external interface is formed by a recess in the carrier. Such a recess can penetrate the carrier or also be arranged at least partially within the carrier.
  • the external interface can also be formed by a combination of several recesses which merge into one another or are arranged on the carrier.
  • the at least one external interface is preferably arranged at a distance from the internal interface. Alternatively, however, the external interface can also be arranged adjacent to the internal interface. It is also possible to provide multiple external interfaces at different positions on or in the carrier.
  • a framework element connected to the inner interface extends essentially along the first spatial direction.
  • a framework element connected to the external interface can extend in a direction essentially perpendicular to the first spatial direction.
  • connection component also includes at least one additional interface which is connected to the holder.
  • This additional interface is provided for connection to a further framework element, which preferably belongs to a third framework system.
  • the third skeleton system is different from the first skeleton system and the second skeleton system.
  • the third scaffolding system is preferably a facade scaffolding which has, for example, a post that can be connected to the connecting component via the additional interface.
  • the additional interface includes a connection area which is designed in the form of a rod or tube and is therefore particularly well suited for a form-fitting connection with a post of a third scaffolding system.
  • connection area of the additional interface extends in a second spatial direction.
  • the first spatial direction and the second spatial direction are oriented essentially perpendicular to one another. This results in a framework element connected to the inner interface being oriented essentially perpendicularly to a framework element connected to the additional interface.
  • This arrangement of the internal interface and additional interface allows the connection component to be used as a node between two scaffolding systems.
  • the external interface extends at least in regions in the first spatial direction and at least partially penetrates the carrier.
  • the external interface is formed by a recess in the carrier, which has a three-dimensional shape. This three-dimensional recess extends firstly in the first spatial direction and secondly in other spatial directions, such as the second spatial direction.
  • the external interface enables the connection of a scaffolding element of a second scaffolding system, which is in different directions to the Connecting component can extend.
  • the connection component according to the invention can also be connected to other components.
  • the external interface can, for example, be connected directly to a formwork element, such as a switchboard, and thereby enables scaffolding systems to be connected to another component, such as a formwork element.
  • the dimensions of the connecting component are selected in such a way that they match the grid of one or more scaffolding systems that are to be connected to the connecting component.
  • a grid of a scaffolding system is to be understood as meaning an interaction of the dimensions of the individual scaffolding elements, which allows scaffolding sections of different shapes and sizes to be constructed from standard components.
  • a scaffolding system has one or more dimensions that are repeated in a scaffolding section.
  • scaffolding elements can be arranged in parallel or in series one behind the other and can thus be individually combined to form a scaffolding section suitable for the application.
  • the connection component according to the invention has at least partially standardized dimensions which are identical to the standardized dimensions which are provided for the grid of one or more of the connected scaffolding systems.
  • the scaffolding elements can be connected to the connecting component in such a way that the grid of the individual scaffolding systems is continued across the connecting component as if the scaffolding elements were directly connected to one another.
  • the connection component can be optimally integrated into one or more scaffolding systems, in a manner in which the modular principle of the individual scaffolding systems is retained.
  • the connection component according to the invention comprises at least three interfaces, which allow the connection of scaffolding elements from different scaffolding systems. It is also possible to connect three scaffolding elements from two different scaffolding systems.
  • a connecting component according to the invention simplifies the construction of a scaffolding section with scaffolding elements from different scaffolding systems compared to the prior art.
  • the connection component according to the invention can directly and without individual adjustment work can be combined with all scaffolding systems and scaffolding elements. In this way, the safety of a scaffolding section that uses the connection component according to the invention as a node is improved, in particular compared to solutions in which such a node has to be produced and adapted individually at the construction site.
  • connection component according to the invention can be developed and calculated before it is used, so that it has the mechanical properties required for the application, such as load-bearing capacity. Furthermore, the connection component according to the invention is easy to handle and thus enables a scaffolding section to be erected quickly with scaffolding elements from different scaffolding systems. Of course, the connection component according to the invention can also only be used to connect two scaffolding elements. It is thus possible to connect one type of connection component to scaffolding elements in different ways. This also improves the logistics on the construction site, since only one type of connection component has to be provided. In the prior art, different connection components are required for different applications between the scaffolding systems. A further advantage of the connection component according to the invention is that it can be used to connect three scaffolding elements which extend in three different directions in space.
  • the carrier has two carrier plates which are connected to one another at a distance from one another in the direction of the first spatial direction.
  • such a two-part design of the carrier leads to a weight saving compared to a solution in which the carrier is designed in one piece.
  • the two carrier plates are preferably oriented parallel to one another. More preferably, one or both carrier plates are aligned perpendicular to the first spatial direction.
  • the at least one external interface is arranged in one carrier plate, in both carrier plates and/or between the two carrier plates.
  • the external interface can be arranged at different positions relative to the two carrier plates.
  • the external interface can be arranged in the space between the two carrier plates.
  • the external interface through a recess is formed which penetrates one or both carrier plates.
  • the external interface can be formed in some areas by the intermediate space between the two support plates and in some areas by a recess in the support plates.
  • the external interface can also include other components which are connected to one or both of the carrier plates.
  • the additional interface comprises a base plate, which is connected to the connection area, with the extension direction of the connection area being oriented essentially perpendicularly to the base plate.
  • the auxiliary interface includes a footplate that supports the connection area.
  • the base plate is oriented perpendicularly to the connection area and thus perpendicularly to the second spatial direction.
  • the base plate can be connected to the connection area via a welded connection, for example.
  • the base plate can have a rectangular shape, for example.
  • the base plate is connected to the carrier, with the base plate in particular connecting the two carrier plates to one another and positioning them in relation to one another.
  • the base plate is connected to the carrier and thus connects the connection area of the additional interface to the carrier.
  • the base plate simultaneously connects the two carrier plates to one another.
  • the base plate thus serves on the one hand as a connecting element for the individual components of the carrier and on the other hand as a connecting link between the carrier and the additional interface. In this way, fastening elements for connecting the two carrier plates of the carrier can be saved.
  • the support plates each have a recess
  • the base plate is inserted in a form-fitting manner on a first of its sides into a recess of a first support plate and on a second of its sides into a recess of a second support plate, in particular with the base plate and the both carrier plates are additionally connected to each other by a welded joint.
  • each support plate has a recess or opening into which a partial area of the base plate is introduced. In this way, the base plate and the two support plates are positively connected to each other.
  • the base plate and the support plate can be by a Press fit can also be connected to one another in a non-positive manner.
  • a welded connection is additionally provided.
  • connection area is formed by a tube section which has a circular cross section.
  • connection area is formed by a tube section, which is particularly well suited as a connection interface to a scaffolding element designed as a post.
  • a connection area formed by a pipe section can be pushed into a handle.
  • Such a connection interface is often used in scaffolding systems for facade scaffolding, reinforcement scaffolding or industrial scaffolding.
  • the connection area is preferably dimensioned in such a way that it is identical to an interface within such a scaffolding system, at least in some areas.
  • a plug-in opening can be provided in the connection area, which penetrates the connection area perpendicularly to the second spatial direction.
  • connection area can also be shaped differently and have a rectangular cross-section, for example, if this is required for connection to a scaffolding system.
  • the additional interface has at least one clamping mechanism, the clamping mechanism being provided for clamping a framework element introduced into the inner interface, the clamping mechanism having at least one clamping body which can be moved in a direction parallel to the second spatial direction.
  • the additional interface comprises a clamping mechanism which is intended to act on a framework element introduced into the internal interface. With such a clamping mechanism, a framework element introduced into the inner interface can be clamped in the connection component and thus fixed in a non-positive manner.
  • the clamping mechanism comprises at least one movable clamping body, the position of which can be adjusted relative to the base plate. This clamping body is shaped and positioned in such a way that it projects into the inner interface at least in certain areas.
  • the clamping body When connecting a scaffolding element to the internal interface the clamping body is first moved out of the internal interface, then the framework element is inserted into the internal interface, and finally the clamping body is moved back into the internal interface in order to clamp the framework element there.
  • a clamping mechanism on another component of the connection component, for example on the carrier.
  • the clamping body is designed as a clamping screw or threaded bolt and the base plate has at least one internal thread into which the clamping body is screwed.
  • the clamping body is formed by a clamping screw or a bolt with an external thread.
  • At least one internal thread which extends in the second spatial direction, is provided in the base plate for receiving the clamping body.
  • the clamping mechanism preferably has at least two clamping bodies, both of which are movably arranged parallel to the second spatial direction.
  • a clamping body can also be formed by the piston of a hydraulic cylinder, which can be moved hydraulically in a direction parallel to the second spatial direction in order to clamp a scaffolding element in the inner interface.
  • the carrier has two carrier plates which are oriented parallel to one another and which are connected to one another by at least one spacer element.
  • at least one spacer element is arranged between two carrier plates. This spacer element positions the two support plates relative to one another in addition to the connection that exists between the support plates through the base plate. This gives the wearer additional stability.
  • the spacer element can be designed, for example, as a sleeve, which is frictionally inserted between the two support plates using a screw connection. It is also possible to arrange several spacer elements between two support plates.
  • the external interface is arranged between two carrier plates of the carrier and furthermore comprises at least one recess which at least completely penetrates one of the support plates in the direction of the first spatial direction.
  • the external interface is arranged in some areas between two support plates and in some areas within one of the support plates.
  • the external interfaces are thus formed by at least two partial areas, which are each formed by a recess in the carrier. These sections merge into one another.
  • Such an external interface makes it possible to insert a scaffolding element between the two connecting plates in some areas and thereby already create a form fit between the scaffolding element and the connecting component.
  • a connecting element for example a screw
  • a connecting element can be introduced into a recess in at least one of the support plates for additional fixing of the framework element.
  • a recess can be provided in each of the carrier plates, with the recesses preferably being aligned with one another.
  • a bolt or a screw can be guided through two such mutually aligned recesses in order to clamp a framework element relative to the carrier.
  • the recess, which penetrates at least one of the carrier plates is preferably completely surrounded by the carrier plate.
  • This recess can have a circular cross section, for example.
  • this recess can also be designed in the manner of an elongated hole, which allows the introduction of a connecting element with a screw at different positions.
  • the outer interface of the holder is arranged on or in the edge of the carrier facing away from the inner interface, the outer interface being open on its side facing away from the inner interface and completely penetrating the carrier in the direction of the first spatial direction.
  • the outer interface is arranged in such a way that it is open on its side facing away from the inner interface.
  • a framework element can be inserted into the external interface in a direction perpendicular to the first spatial direction.
  • such an external interface can be designed, for example, as rectangular, with one side of the rectangle being designed to be open to the outside. The external interface penetrates the carrier in the first spatial direction.
  • the external interfaces completely penetrate both of these carrier plates.
  • the outer interface is formed by at least one recess which at least partially penetrates the carrier in the direction of the first spatial direction, this recess being arranged at a distance from the edge of the carrier facing away from the inner interface.
  • the external interface is located inside the carrier.
  • the outer interface is not open to the edge of the carrier facing away from the inner interface.
  • the outer interface is preferably also arranged in the carrier at a distance from the inner interface.
  • Such an external interface can be formed, for example, by a bore that is made in one of the carrier plates. Alternatively, such an external interface can also have the shape of an elongated hole. In this embodiment, too, the external interfaces can penetrate the carrier in the first spatial direction.
  • the carrier has two carrier plates which are connected to one another by at least one base plate.
  • two carrier plates of the carrier are connected to one another by a base plate of the additional interface.
  • the additional interface it is also possible for the additional interface to have two base plates, which are in particular arranged parallel to one another and are both connected to both carrier plates. As a result, the stability of the connection component can be increased.
  • the base plate penetrates the carrier plates and the base plate protrudes in the direction of the first spatial direction beyond the two surfaces of the carrier plates pointing away from one another.
  • the base plate and the support plates are connected to one another in such a way that the base plate penetrates at least one of the support plates and projects outwardly beyond the surface thereof.
  • This protruding area of the base plate can be used as an assembly stop when connecting the connecting component to scaffolding elements, which simplifies the positioning of the connecting component to a scaffolding element.
  • the base plate penetrates through both carrier plates and protrudes over both carrier plates on the outward-facing side of the carrier. In this way, a mounting stop can be provided on both sides of the beam.
  • the carrier completely encloses the inner interface.
  • the carrier encircles the interior interface circumferentially around the first spatial direction complete.
  • the carrier is designed to be particularly stable and can transmit large forces and moments from the connection component to a framework element introduced into the internal interface and vice versa. It is also possible to design the carrier so that it can be divided so that it can be opened and closed as required in order to introduce a framework element into the inner interface. Furthermore, it is possible to open the carrier in a partial area in the circumferential direction around the first spatial direction.
  • the inner interface to have a center point in a top view of the carrier, which is arranged in the second spatial direction, starting from the connection area.
  • an imaginary center point of the inner interface is arranged in such a way that it lies in the central axis of the connection area of the additional interface.
  • the center point is to be understood as the centroid of the area of the inner interface in a view from the first spatial direction onto the carrier.
  • the inner interface is positioned relative to the additional interface in such a way that the center point of the inner interface lies at the point of intersection between the first spatial direction and the second spatial direction. In this way, a particularly efficient transmission of force between a framework element connected to the additional interface and a framework element introduced into the inner interface is possible.
  • these framework elements are oriented at right angles to one another when connected to the connection component, with the direction of extension of the two framework elements intersecting one another.
  • the flow of forces from one scaffolding element to the other scaffolding element through the connection component is thus guided directly, which contributes to a particularly stable and secure connection.
  • two opposing additional interfaces are provided, their connection areas are both arranged coaxially to the second spatial direction, whereby the framework elements connected to the connection component are also oriented at right angles to one another in this embodiment and their direction of extension intersect at the same time.
  • the shape of the inner interface in a plan view of the carrier is axisymmetric to the second spatial direction and axisymmetric to a direction which is perpendicular to the first spatial direction and perpendicular to the second spatial direction.
  • the inner interface which represents a recess in the carrier, is axially symmetrical to two of each other in a plan view from the first spatial direction vertical axes. One of these axes is formed by the second spatial direction. The other of these axes runs both perpendicularly to the first spatial direction and perpendicularly to the second spatial direction.
  • Such a shaping of the inner interface makes it possible to introduce a framework element in different rotational orientations or rotational positions around the first spatial direction.
  • this embodiment enables the inner interface to be connected to a carrier element.
  • a support element which can be formed, for example, by an I-beam, also called a double T-beam, or a double C-beam, also called a double U-beam, is in practice preferably installed in two different rotational orientations about its longitudinal axis , which differ from each other by 90°.
  • an inner interface designed in this way also offers the possibility of arranging the connecting component in two different rotational positions relative to the carrier element in each rotational position of the carrier element. For example, it can be selected whether an additional interface of the connection component is oriented in a first direction or in a direction that differs by 180°.
  • the inner interface has a square shape in a view of the carrier from the first spatial direction.
  • This embodiment corresponds to a refinement of the embodiment described above, in which the shape of the internal interface axes is symmetrical with respect to two axes which are perpendicular to one another.
  • a square shape of the inner interface is particularly suitable for receiving and for positive connection with a carrier element, which is designed as an I-beam or double C-beam.
  • an inner interface with a square shape enables connection of one Scaffolding element with the inner interface in different rotational orientations or rotational positions of the connecting component relative to the scaffolding element.
  • the edge length of an inner interface configured as a square recess is between 100 mm and 200 mm.
  • the edge length of the inner interface is preferably selected to be greater than the edge length of a framework element to be connected to the inner interface.
  • the inner interface can also have an edge length that is outside of the aforementioned range.
  • the inner interface can also have a rectangular cross section.
  • two cut-outs are arranged, which are located outside of the square shape and of which one in the direction of the second spatial direction and one in a direction that is perpendicular to the first Direction in space and perpendicular to the second direction in space extends.
  • These recesses are provided so that framework elements that are not square in their external dimensions can also be inserted into an internal interface that has a square basic shape.
  • the cutouts extend outwards. In each corner of the basic square shape, two such cutouts are arranged, which extend away from the basic square shape at right angles to one another.
  • Framework systems exist which have support elements formed by double C-beams.
  • carrier elements initially have a non-square cross-section.
  • the width of such support elements is slightly larger than their height.
  • the cutouts at the corners of the inner interface enable such a carrier element to be inserted into the inner interface by accommodating partial areas of the carrier element which protrude beyond an imaginary, square cross section of the carrier element.
  • the tips of the legs of a double C-beam are introduced into a free stress at each corner of the basic square shape. Due to the fact that two mutually perpendicularly oriented recesses are arranged at each corner, it is also possible in the case described to introduce the carrier element in different rotational positions or rotational orientations about the first spatial direction relative to the connecting element.
  • the connecting element can be arranged in different positions relative to a carrier element with a non-square cross-section.
  • the flexibility in Structure of a scaffolding section, in which a connecting component is used as a node, can be significantly increased as a result.
  • the holder to comprise two or more external interfaces which are arranged on or in the carrier at different positions relative to the center point of the internal interface. It is possible for several external interfaces to be arranged on the mount. These external interfaces can have the same shape and size or can differ in shape, size and arrangement. In principle, the previously described embodiments of an external interface can be freely combined with one another. For example, an outer interface can be provided which is open to the edge of the carrier facing away from the inner interface. In addition to this, one or more external interfaces can be provided, which are arranged at a distance from the edges of the carrier and partially or completely penetrate it in the first spatial direction. The flexibility of the connection component is increased by the arrangement of several external interfaces on the carrier.
  • scaffolding elements can be connected to the connecting component in different ways and in different positions.
  • the multiple external interfaces have the same shape or different shapes. Different embodiments of external interfaces can be arranged in combination with one another on or in the carrier.
  • the carrier and in particular the connecting component, is divisible in a plan view from the first spatial direction and comprises two partial carriers, the dividing plane for this divisibility running through the inner interface and preferably parallel to the first spatial direction and in one Angle of 45 ° is oriented to the second spatial direction.
  • the carrier consists of two sub-carriers, which are connected to each other via a detachable connection. Such an embodiment makes it possible to connect the carrier to an already positioned framework element, for example a carrier element.
  • a framework element In a non-divisible embodiment of the carrier, in which it completely encloses the inner interface, a framework element must be pushed into the inner interface along its longitudinal axis or, conversely, the carrier must be pushed over the framework element. In some applications this is not possible, particularly when the scaffolding element is already connected to other scaffolding elements and such a postponement is not possible because of collisions with other scaffolding elements.
  • the connecting component when attaching the connecting component, the carrier is broken down into the two partial carriers and the partial carriers are positioned at the desired location around the scaffolding element. The two partial beams are then connected to one another again, as a result of which the beam completely encloses the scaffolding element when connected.
  • the parting plane in which the two partial carriers can be separated from one another, preferably runs at an angle of 45° to the second spatial direction in a plan view from the first spatial direction. At the same time, the parting plane runs through the inner interface. In an embodiment in which the inner interface is square and two of the side edges of the inner interface are oriented parallel to the second spatial direction, the parting plane runs diagonally through the inner interface. In such an embodiment, the sub-carriers can be ergonomically separated from one another and connected to one another. At the same time, the diagonal division leaves a large area on the carrier where external interfaces can be arranged. In this way, the divisibility of the carrier only impedes the connectability of the connection component with framework elements to a small extent.
  • the two sub-carriers can be connected to one another, for example, by screw connections. It is of course also possible to arrange the parting plane in a different way, in particular at a different angle to the second spatial direction. It is also possible to divide the carrier into more than two, ie for example three or four, sub-carriers which are each detachably connected to one another.
  • the dividing plane for the divisibility of the carrier bisects the inner interface.
  • Such a halving results in a symmetrical structure and an essentially identical weight of both sub-carriers. In this way, the carrier is in easier way to connect and disconnect.
  • the symmetrical structure is also favorable for an even distribution of force and transmission of force in the wearer in the application.
  • connection component includes two additional interfaces, one of which is connected to a sub-carrier.
  • an additional interface is arranged on each of the two sub-carriers of a divisible carrier.
  • the two connection areas of the additional interfaces are preferably arranged coaxially to one another and both extend in the second spatial direction.
  • two structural elements of the same type can each be connected to one of the two additional interfaces, these two structural elements being aligned with one another in the connected state with the connecting component.
  • the distance between the two connection areas in a direction parallel to the second spatial direction is chosen so that it fits the grid of the framework system to which the framework elements to be connected with the additional interfaces belong.
  • this scaffolding system can be continued in the second spatial direction, with the connecting component being interposed, in an identical manner to a scaffolding section without the interposition of a connecting component.
  • the distance between the additional interfaces can be 250 mm or 500 mm, for example.
  • the fact that the carrier can be divided also makes it easier to connect the additional interfaces to the corresponding framework elements.
  • the two sub-carriers are detachably connected to one another via at least one screw connection.
  • a bolted joint is easy to use and has predictable, high strength.
  • each partial carrier comprises two partial carrier plates which are arranged parallel to one another and which are connected to one another by at least two spacer elements, the spacer elements being arranged at a distance from one another.
  • each sub-carrier has two sub-carrier plates arranged at a distance from one another. This makes it possible to arrange one or more external interfaces between the two partial carrier plates.
  • the two sub-carrier plates are firmly connected to one another by spacer elements.
  • the spacers can be arranged, for example, via a welded connection between the two sub-carrier plates.
  • the spacer elements have a connection area, which is designed in particular as an opening, with the sub-beams being connected by connecting elements, which each pass through a connection area of one sub-beam and a connection area of the other sub-beam and are positively and/or non-positively connected to these connection areas are connected.
  • connection areas are provided in the spacer elements, which are provided for the introduction of connection elements, such as screws. The spacer elements thus serve to position the two partial carrier plates relative to one another and at the same time to connect the two partial carriers to one another.
  • the connection component has a simple and stable structure and at the same time is light in weight.
  • a framework section with a connection component further comprising at least two framework elements which are connected to the connection component, with a first framework element being formed by a carrier element which is introduced into the inner interface and a second skeletal element is formed by a stem connected to the connection area of the additional interface or by a connecting element connected to an external interface.
  • a scaffolding section according to the invention comprises at least one connecting component, which serves as a node between at least two scaffolding elements.
  • the scaffolding elements belong to different scaffolding systems and the connecting component provides suitable connection interfaces for each of the two different scaffolding systems.
  • the connecting component thus enables a secure connection that is easy to produce between two scaffolding systems.
  • a first frame element is formed by a carrier element, which preferably belongs to a frame system that provides a support frame.
  • the support element can be formed, for example, by an I-beam or a double C-beam.
  • the carrier element is inserted into the inner interface of the Introduced connecting component and fixed in this. This connection can be designed in a positive and/or non-positive manner.
  • a second scaffolding element can be formed by a post, which preferably belongs to a scaffolding system that provides a facade scaffolding.
  • the second scaffolding element can also be formed by a connection element, which preferably belongs to a scaffolding system that provides scaffolding that is different from a supporting scaffolding and a facade scaffolding.
  • the post can be a vertical post, for example, which is preferably oriented vertically in a facade scaffolding system.
  • Such a post is connected to an additional interface in the scaffolding system according to the invention.
  • the connection area of the connection component is connected in a form-fitting manner to the handle.
  • the second framework element is formed by a connecting element, this is connected to at least one external interface of the connecting component.
  • a partial area of the connection element is introduced into the external interfaces on the carrier of the connection component and connected to it in a form-fitting manner.
  • a scaffolding section according to the invention comprises at least two scaffolding elements which are connected with a connecting component.
  • the connecting component has at least three interfaces, at least a third framework element can in any case be added to the framework section and connected to the connecting component.
  • a scaffolding section according to the invention thus enables the connection or combination of at least three scaffolding elements from at least two different scaffolding systems.
  • the scaffolding section according to the invention also enables the combination or connection of three different scaffolding systems.
  • the connection of these scaffolding systems is possible in a simple and safe manner, since the connecting component provides the necessary connection interfaces without individually manufactured connecting parts being required to connect the different scaffolding systems.
  • One of these scaffolding systems can also be formed by a formwork scaffold or by formwork.
  • a scaffolding section according to the invention can also comprise a formwork, which is connected to one or more scaffolding systems by the connecting component.
  • formwork for forming part of a building can often only be used in combination with scaffolding erected or used as scaffolding is required to operate the formwork. In the state of the art, such a combination can only be produced with great difficulty, since formwork systems and scaffolding systems usually differ significantly from one another in terms of their interfaces.
  • a scaffolding section according to the invention can provide such a combination or connection of formwork and scaffolding in a simple manner, since the connecting component provides interfaces for connection both to scaffolding systems and to a formwork system.
  • the term scaffolding system used can therefore also include a formwork system for the formwork of a part of a building.
  • the relationships and properties described for a scaffolding system also apply analogously to a formwork system.
  • the scaffolding section according to the invention can be varied in a simple manner according to the individual needs of the scaffolding section. Already existing different scaffolding systems and formwork systems can be easily combined in a scaffolding section according to the invention by the connecting component. The functionality of these existing systems can thus be improved and expanded.
  • the frame section comprises three frame elements, with a carrier element being connected to the inner interface, a post to the connection area of the additional interface and a connecting element to an outer interface.
  • the skeleton section comprises three or more skeleton elements, each of which is connected to one of the connection interfaces of the connection component.
  • the three framework elements preferably differ from one another.
  • the carrier element is fixed positively and non-positively in the inner interface, the relative position of the connecting component to the carrier element being infinitely adjustable and the connecting component being non-positively connected to the carrier element by the clamping mechanism of the additional interface.
  • the connection between the inner interface and a framework element designed as a carrier element is frictional. This enables steplessly adjustable positioning between the carrier element and the connecting component in the first spatial direction.
  • the carrier element is clamped in the internal interface by actuating the clamping mechanism. This clamping is done by Movement of at least one clamping body of the clamping mechanism.
  • Such an infinitely adjustable, relative position between the connecting component and the carrier element enables an individual configuration of the framework section.
  • the clear width of the inner interface in the second spatial direction is greater than the outer dimensions of the carrier element in the second spatial direction and the connecting component comprises two additional interfaces arranged opposite one another and the carrier element is fastened in a non-positive manner between the two clamping mechanisms, the relative position of the carrier element to the connecting component can be adjusted by the clamping mechanisms.
  • the position of the carrier element relative to the connecting component is adjustable in the second spatial direction.
  • two additional interfaces located opposite one another, each with a clamping mechanism, are provided on the connecting component.
  • the carrier element is fixed in the internal interface by cooperation of the two opposing clamping mechanisms.
  • the clear width of the inner interface is slightly larger than the outer dimensions of the carrier element.
  • the clear width can be made larger in a range between 0.5 mm and 40 mm than the external dimensions of the carrier element in the second spatial direction.
  • the relative position of the carrier element to the inner interface can be individually adjusted within this dimensional difference.
  • the clamping mechanisms are actuated such that the carrier element is clamped at the desired position in the inner interface.
  • the carrier element has a longitudinal axis which is oriented parallel to or congruent with the first spatial direction and the carrier element can be introduced into the internal interface in different rotational positions around the first spatial direction, in particular with the carrier element being able to be introduced into four different rotational positions around the first spatial direction can be introduced into the inner interface, with the rotational positions around differ from each other by 90° around the first spatial direction.
  • the connection component has an inner interface which, in a view from the first spatial direction, is embodied symmetrically about two axis axes which are perpendicular to one another. In this view, for example, the inner interface can be square in shape.
  • a support member having a square cross-sectional shape can be inserted into the internal interface in four different rotational positions. In this way, the relative orientation of the connecting component to the carrier element can be adjusted individually as required.
  • the provision of cut-outs at the corners of the inner interface also makes it possible to introduce a carrier element with a non-square cross-section in different rotational positions relative to the inner interface.
  • a post is formed by a vertical post, the post being pushed onto the connection area or pushed into it, in particular the post being positively connected to the connection area in the direction of the second spatial direction.
  • the post is formed by a vertical post of a facade scaffolding system.
  • the connection area is identical or at least partially identical to an interface that is also used within the facade scaffolding system.
  • a connection is established in that the vertical post is pushed onto the connection area in the second spatial direction.
  • the pushed-on vertical post can also be positively connected to the connection area by a plug-in element, with the plug-in element being guided through an opening in the vertical post and a pegging opening in the connection area.
  • connection area is preferably designed as a tube section, which can have a diameter of between 20 mm and 50 mm, for example.
  • the length of the connection area in the second spatial direction can be between 100 mm and 200 mm, for example.
  • a handle, for example, which has an inner diameter of between 40 mm and 55 mm, can be attached to such a connection area.
  • connection component comprises two additional interfaces, each connection area being connected to a post and the two posts extending away from each other endang in the second spatial direction, the Distance between interfaces on the standards, which are provided for connecting the standards to other scaffolding elements of the same scaffolding system, between the two standards connected to the connecting component is the same as their distance in the scaffolding system to which the standards belong, whereby the grid of the Scaffolding system to which the posts belong, is continued in the scaffolding section in the second spatial direction, in particular the distance between interfaces on the posts, which are provided for connecting the posts to other scaffolding elements of the same scaffolding system, is 250 mm or 500 mm.
  • two additional interfaces arranged on the connecting component are each connected to a handle.
  • the distance between the two connection areas on the connection component in the second spatial direction corresponds to the grid dimension that is used within the scaffolding system to which the two posts belong.
  • Crucial in a scaffolding system is the location or spacing between interfaces intended to connect scaffolding members within the scaffolding system.
  • the two posts connected to the additional interfaces are positioned relative to one another in such a way that the distance between their connection interfaces, which are arranged on the posts, is positioned in the same grid dimension as in a scaffolding section that only has scaffolding elements of the scaffolding system. to which the stems belong.
  • the connection interfaces on the stems can be formed, for example, by connecting disks or rosettes, which are fastened to the outer circumference of the stems.
  • the scaffolding section can be fully integrated into the scaffolding system to which the standards belong.
  • the arrangement of the connecting component in the scaffolding section between two posts therefore does not affect the grid of the scaffolding system to which the posts belong and at the same time enables a simple connection to other scaffolding systems.
  • a connection element is introduced at least in regions into an external interface and is connected to it in a form-fitting manner, the external interface being arranged on or in the edge of the carrier facing away from the internal interface, the external interface being open on its side facing away from the internal interface and completely penetrates the carrier in the direction of the first spatial direction.
  • a connecting element is introduced in a form-fitting manner into an outer interface of the connecting component that is open towards the edge.
  • the connecting element can be a scaffolding element of a scaffolding system or an element of a formwork system, for example a formwork panel.
  • connection between the connecting element and the connecting component is established in that the connecting element is inserted into the external interface from a direction perpendicular to the first spatial direction or, conversely, the external interface is guided over the connecting element in this direction.
  • the shape of the external interface viewed from the first spatial direction, corresponds to a partial area of the connecting element. Due to the connection of the external interface to the connection element, there is a form fit at least in the second spatial direction.
  • connection elements can be provided which fix the connection element and the connection component to one another in a direction perpendicular to the second spatial direction and perpendicular to the first spatial direction.
  • connection element is introduced at least in regions into an external interface and is positively connected to it, the external interface being arranged between two carrier plates and/or in at least one carrier plate.
  • a connection element is introduced into an external interface of the connection component, which is located between two carrier plates and/or in at least one carrier plate.
  • the connecting element can be a scaffolding element of a scaffolding system or an element of a formwork system.
  • the connection element is preferably inserted between the two support plates from a direction perpendicular to the first spatial direction, so that a positive fit is created between the connection element and the connecting component in the first spatial direction.
  • the connecting element can then be connected to the carrier in a non-positive and/or positive manner by inserting a connecting element, such as a screw.
  • a connecting element such as a screw.
  • the external interface can have a recess which penetrates at least one or even both of the carrier plates in the first spatial direction.
  • an external interface of the connecting component is introduced at least in regions into a connecting element and is connected to it in a form-fitting manner, with a partial area of the carrier being incorporated into the connecting element and the external interface being formed by at least one recess which extends the carrier in the direction the first spatial direction penetrates at least partially, this recess being spaced apart from that facing away from the inner interface Edge of the carrier is arranged and the external interface is connected by a connecting element to the connection element.
  • an external interface is introduced into a cavity of a connection element.
  • the connection element can be a carrier element of a scaffolding system or a formwork system.
  • the external interface can be placed in the space between two C-beams of a double C-beam.
  • This introduction already creates a form fit between the connection component and the connecting element in the first spatial direction.
  • the external interface can be formed at least in regions by the surfaces of the carrier facing outwards in the first spatial direction.
  • the external interface is formed by a recess in the carrier, which is arranged at a distance from the outer edge.
  • a connection element is introduced into a partial area of the external interface, which also penetrates through a partial area of the connection element.
  • a connecting element can be formed, for example, by a connection made up of a screw and a nut.
  • the carrier of the connecting component has two carrier plates, which are connected to one another by at least one base plate, the base plate penetrating the carrier plates and the base plate protruding in the direction of the first spatial direction beyond the two surfaces of the carrier plates pointing away from one another, the External interface and a portion of the carrier are introduced into a connection element, wherein the on the support plates protruding area of the base plate abuts on an outer surface of the connection element.
  • at least one base plate protrudes outwards in the first spatial direction beyond the two surfaces of the support plates. This protruding area serves as a stop for the positioning of the connection component relative to a connection element. This stop facilitates assembly of the scaffold section.
  • the object of the invention is finally achieved by a method for constructing a scaffolding section according to one of the previously described embodiments using a connecting component according to one of the embodiments described above, comprising the method steps a) preparing the connecting component for the introduction of a framework element into the inner interface, the at least one clamping body of the clamping mechanism being positioned in such a way that the clear width in the inner interface is greater than the outer dimensions of the carrier element in the second spatial direction, b) connecting a carrier element to the connecting component, the carrier element being introduced into the inner interface and being fixed by the clamping mechanism, c) connecting at least one second framework element to the connecting component, wherein either a post is connected to the connecting area of the additional interface is connected or a connection element is connected to an external interface.
  • the method according to the invention is used to construct a scaffolding section with a connecting component and a plurality of scaffolding elements. At least one of these scaffolding elements can also be formed by an element of a formwork system.
  • the process is preferably carried out in the described order of process steps a) to c).
  • the method according to the invention can also be carried out in reverse order of the method steps for dismantling a scaffold section.
  • a first method step a the inner interface of a connecting component is prepared for the introduction of a carrier element.
  • the clamping mechanism is set in such a way that the clear width in the inner interface is greater than the dimension of the carrier element in the second spatial direction. In this way there is play between the carrier element and the inner interface or the clamping mechanism.
  • the clear width is to be understood here as the clear width which is present between the elements of the clamping mechanism, ie in particular between the clamping bodies of the additional interfaces located opposite one another.
  • the clearance may also be between an edge of the internal interface and the clamping mechanism opposite that edge.
  • a second method step b the carrier element is introduced into the inner interface and thus connected to the connecting component.
  • the connecting component relative to the carrier element or the carrier element relative to
  • the connecting component is positioned at the desired position relative to the carrier element and the clamping mechanism is then actuated. With this actuation of the clamping mechanism, at least one clamping body is moved towards the carrier element introduced into the inner interface, which is clamped or fixed in the inner interface by this relative movement.
  • the connecting component and the carrier element are firmly connected to one another in a non-positive manner.
  • a handle can be connected to an additional interface or a connection element can be connected to an external interface. This connection takes place both positively and preferably also non-positively.
  • the method according to the invention makes it possible to construct a scaffolding section which comprises a number of different scaffolding elements from different scaffolding systems. No individually manufactured or adapted components are required for the construction of the scaffold section, the connection component provides all the interfaces required for the connection.
  • the production of the connections in process steps b) and c) can be carried out easily and ergonomically.
  • the individual elements of the framework section can be fixed to one another with the aid of a simple hand tool, such as a wrench.
  • One embodiment of the method provides that method step c) is carried out before method step b).
  • a framework element is connected to the additional interface or to the external interfaces before a framework element is connected to the internal interface. In this way, the process can be individually adapted to the current situation on the construction site.
  • At least one further framework element is connected to the connecting component, the at least one further framework element being connected to an additional interface or to an external interface.
  • the at least one additional framework element can be connected to an additional interface or an external interface. It is also possible to connect four, five or more scaffolding elements with the connecting component to construct a scaffolding section.
  • the connecting component has two additional interfaces and in method step b) the relative position of the carrier element to the connecting component is adjusted by moving the clamping bodies of the clamping mechanisms.
  • the position of the carrier element relative to the internal interface is adjusted by two clamping mechanisms. In this way, an adjustment of the relative position between the carrier element and the connecting component is possible. Such an adjustment may be necessary when scaffolding elements to be added to the scaffolding section are already positioned and dimensional deviations from the ideal position occur in this positioning.
  • the carrier of the connecting component is designed to be divisible and comprises two part carriers and in method step a) the two part carriers are separated from one another and in method step b) the two part carriers are connected to one another so that they enclose the carrier element.
  • the carrier of the connecting component is divisible.
  • the carrier can be positioned around the carrier element when connected to a carrier element and does not have to be pushed onto the carrier element endang the longitudinal axis of the carrier element. This allows a connection component to be attached to a support element which is already integrated into an assembled scaffolding section and is connected to other scaffolding elements.
  • the carrier is divided in method step a) and reassembled in method step b), the two partial carriers first being positioned around the carrier element in method step b) and then connected to one another.
  • the process is significantly simplified due to the divisibility of the carrier.
  • the relative position of the connecting component to the carrier element is adjusted in the direction of the first spatial direction. This setting of the relative position is carried out in that the connecting component is displaced along the first spatial direction relative to the carrier element. Due to the non-positive fixing of the inner interface on the carrier element by the clamping mechanism, it is possible to fix the connecting component in any desired position relative to the carrier element.
  • connection component and the framework section are also deemed to be disclosed in connection with the method. The same applies in reverse, features, effects and advantages which are disclosed in connection with the method also apply in connection with the connection component and the framework section as disclosed.
  • FIG. 1 shows a perspective view of a first embodiment of a connecting component according to the invention
  • FIG. 2 shows a second embodiment of a connecting component according to the invention in FIG. 2a a perspective view in the assembled state and in FIG. 2b a perspective view of an individual part,
  • FIG. 3 shows a perspective, sectioned view of the connecting component from FIG. 2a
  • FIG. 4 shows a sectional front view of the connecting component from FIG. 2 with a carrier element connected to the connecting component
  • 5 shows a perspective view of a first embodiment of a scaffolding section according to the invention
  • 6 shows a perspective view of a second embodiment of a scaffolding section according to the invention
  • FIG. 7 shows a perspective view of a third embodiment of a scaffolding section according to the invention.
  • FIG. 1 shows a perspective view of a first embodiment of a connecting component 1 according to the invention.
  • the central component of the illustrated embodiment forms the holder 2 .
  • the holder 2 In a plan view from the first spatial direction RI, the holder 2 has an essentially rectangular shape.
  • the holder 2 comprises a carrier 21 which encloses an inner interface 22 .
  • the inner interface 22 is formed by an opening in the carrier 21 and penetrates it completely in the direction of the first spatial direction RI.
  • the inner interface 22 is provided for receiving a framework element, for example a support element 4 .
  • the holder 2 comprises a plurality of external interfaces 23 which are all arranged at a distance from the internal interface 22 .
  • Each of these external interfaces 23 is formed by a recess in the carrier 21 .
  • a recess is to be understood here as a hollow space which is delimited at least in regions by the carrier 21 .
  • An external interface 23c can be seen, for example, on the edge of the carrier 21 facing to the right in the illustration. This outer interface 23c is open on its side facing away from the inner interface 22 and completely penetrates the carrier 21 in the first spatial direction RI.
  • This external interface 23c can be plugged onto a framework element, for example onto the frame of a control panel.
  • the connection component 1 also comprises two additional interfaces 3, which protrude above and below the carrier 21 in the illustration and connected to the carrier 21.
  • Each of the additional interfaces 3 has a tubular connection area 31 which extends along a second spatial direction R2. This second spatial direction R2 is oriented perpendicular to the first spatial direction RI.
  • Each of the additional interfaces 3 is intended for connection to a scaffolding element, in particular to a scaffolding element of a facade scaffolding.
  • a handle 5 can be attached to the connection area 31 .
  • Frame sections 100 which, in addition to a connecting component 1, have further frame elements which are connected to the inner interface 22, the outer interface 23 and/or the additional interface 3 are shown in FIGS. 5 to 7 and described in relation thereto.
  • the first spatial direction RI intersects the second spatial direction R2, with the two spatial directions being oriented perpendicular to one another.
  • Scaffolding elements which are connected to one another by the connecting component 1, preferably extend along the spatial directions R1 and R2.
  • Framework elements that are connected to an external interface 23 can also extend in a direction that is perpendicular to the first spatial direction RI and/or perpendicular to the second spatial direction R2, or at a different angle to the first spatial direction RI and/or to the second spatial direction R2 .
  • the connecting component 1 is provided as a node in a scaffolding section which is formed from at least two different scaffolding systems. Due to the interfaces arranged along the two spatial directions R1 and R2, scaffolding elements can be optimally connected to the connecting component 1 serving as a node.
  • the connecting component 1 allows a safe transmission of forces and moments between scaffolding elements in three-dimensional space.
  • the carrier 21 comprises two carrier plates 211 oriented parallel to one another. These carrier plates 211 are arranged at a distance from one another and have the same size and shape.
  • the two support plates 211 are connected to one another by the two additional interfaces 3 .
  • Each additional interface 3 includes a base plate 32, which is connected to the connection area 31 and is oriented essentially at right angles to the connection area 31 and to the second spatial direction R2. In a plan view from the second spatial direction R2, each base plate 32 has a rectangular shape.
  • Each of the two carrier plates 211 has two recesses, which are each arranged between the inner interface 22 and the edge facing upwards or downwards in the illustration. This Recesses correspond in shape and size to a base plate 32 in a side view from the first spatial direction RI.
  • the base plate 32 is thereby formed into a cuboid plate which, viewed from the first spatial direction RI, has a rectangular shape. Accordingly, the recesses in the support plates 211 also have a rectangular shape when viewed from the first spatial direction RI.
  • a first side of the base plate is introduced into a recess in a first support plate 211.
  • a second side of the base plate 32 is introduced in a form-fitting manner into a recess in the other, second carrier plate 211 .
  • Each footplate 32 can be connected to a carrier plate 211, for example by an interference fit.
  • the base plate 32 is preferably connected to the carrier plates 211 using additional measures.
  • the base plate 32 can be welded to the carrier plate 211 .
  • additional connecting elements such as screws, can be provided for the connection.
  • the connection between the base plate 32 and the support plates 211 is already sufficient to give the connecting component 1 sufficient strength to transmit forces and moments between scaffolding elements connected to it.
  • the two carrier plates 211 can additionally be connected by at least two spacer elements 25 arranged between the carrier plates 211 . These spacer elements can be formed by tubular sleeves, which are fastened with screws and nuts with bores in the support plates 211.
  • the spacer elements 25 can thus be positively and non-positively connected to the two carrier plates 211 and additionally stabilize the connection of the two carrier plates 211 to one another. Furthermore, the spacer elements 25 are provided to align the two carrier plates 211 parallel to one another. However, the spacer elements 25 are not absolutely necessary. A plurality of openings, which are described below, are made in the two support plates 211 .
  • the inner interface 22 forms the largest opening in the inner carrier 21 and in the carrier plates 211.
  • the inner interface 22 has a center point M in a plan view from the first spatial direction RI. This center point M is in particular the centroid of the inner interface 22.
  • Each of the connection areas 31 of the additional interfaces 3 extends along the second spatial direction R2. In other words, the second spatial direction R2 is through the central axis of each of the two connecting areas 31 is clearly defined.
  • the center point M of the inner interface 22 lies on or in this second spatial direction R2. The second spatial direction R2 thus intersects the inner interface 22 through its center point M in a plan view from the first spatial direction RI.
  • the inner interface 22 is formed axisymmetrically to the second spatial direction in a plan view from the first spatial direction RI.
  • the inner interface 22 is formed axially symmetrically to a direction that runs perpendicularly to the second spatial direction R2 and perpendicularly to the first spatial direction RI and intersects the center point M in this plan view.
  • This shape of the inner interface is particularly favorable since it allows a framework element, for example a carrier element 4, to be introduced into the inner interface 22 in different directions of rotation about the first spatial direction RI.
  • the connecting component 1 can be connected to a framework element, for example a carrier element 4, in different orientations relative to the latter.
  • a framework element for example a carrier element 4
  • Two recesses 221 are arranged adjacent to the corners of this square basic shape.
  • framework members to be incorporated into the internal interface 22 are embodied as I-beams or double C-beams. In this case, portions of these beams protrude beyond the square cross-section of the beams.
  • the recesses 221 are provided to accommodate such protruding partial areas of scaffolding elements.
  • 4 shows how the recesses 221 accommodate protruding partial areas of a framework element, which is formed by a support element 4 in the form of a double C-beam.
  • One of the two cutouts 221 at each corner of the square inner interface 22 extends in the direction of the second spatial direction and another in a direction that runs perpendicular to the first spatial direction RI and to the second spatial direction R2.
  • the cutouts 221 are not absolutely necessary; the inner interface 22 can also just have a square shape without additional cutouts.
  • the mount 2 of the illustrated embodiment of a connecting component 1 comprises a plurality of external interfaces 23.
  • An external interface 23b is arranged in the upper corner on the side of the mount 2 which faces left in the illustration.
  • This external interface 23b comprises two cylindrical openings which are made in the two carrier plates 211 in alignment with one another. These cylindrical openings extend in the first spatial direction RI.
  • a recess, which is arranged between the two carrier plates 211, also belongs to this external interface 23b. This recess between the support plates 211 also extends in the direction of the first spatial direction RI.
  • the external interface 23b can be connected to a framework element, for example to a connection element 6, in various ways.
  • a partial area of a connected framework element can be introduced into the recess between the carrier plates 211 and secured by a fastening element introduced through the two cylindrical openings in the carrier plates 211 .
  • a fastener can be a screw with a nut, for example.
  • the outer interface 23b can be introduced into a connected framework element in certain areas, delimited by the two carrier plates 211 . With this use, too, the framework element can be secured relative to the outer interface 23b by a fastening element, which is introduced through the two cylindrical openings in the carrier plates 211.
  • a connected framework element can also be arranged on an outer side of one of the support plates 211 and fixed through one or both of the cylindrical openings in the support plates 211 using a fastening element.
  • the external interface 23b can thus be used in various ways to connect to scaffolding elements.
  • Another external interface 23a is also arranged on the left-hand side of the holder 2 and is designed similarly to the external interface 23b.
  • the two cylindrical openings in the support plates 211 which belong to the outer interface 23a have a smaller diameter than the two cylindrical openings which belong to the outer interface 23b.
  • a further external interface 23d can be seen on the right-hand side of the holder 2 opposite the external interface 23a. This external interface 23d is identical to the external interface 23a.
  • the two external interfaces 23a and 23b can also be connected to a framework element in various ways.
  • a further external interface 23c is arranged on the right-hand side of the holder 2 in the illustration above the external interface 23d.
  • This External interface 23c differs from external interfaces 23a, 23b and 23d both in terms of its shape, its size and its relative position and distance from internal interface 22.
  • External interface 23c is located on the edge of support plates 211 facing away from internal interface 22.
  • the outer interface 23c is open on its side facing away from the inner interface 22 .
  • the outer interface 23c extends in the direction of the first spatial direction RI and has a rectangular cross section in a plan view from this direction.
  • the outer interface 23c penetrates both carrier plates 211 in the same way.
  • a framework element for example a connecting element 6, a portion of this framework element can be inserted into the external interface 23c, which is open to the outside.
  • This application is shown in Fig. 6a and 6b.
  • two or more of the external interfaces 23 can also be used jointly or in addition to one another.
  • the embodiment shown comprises a plurality of external interfaces 23 which are arranged on or in the carrier 21 at different positions relative to the center point M of the internal interface 22 . In the embodiment shown, all the external interfaces 23 are arranged on the side of the carrier 21 on which none of the additional interfaces 3 are located.
  • external interfaces 23 can be arranged on the carrier 21 or on the holder 2, also on the sides in which an additional interface 3 is located.
  • external interfaces 23 can also be provided which differ in shape and size from the external interfaces 23a to 23d shown.
  • Such a differently designed external interface 23 can have an additional component, for example, which is formed by an insert between the two carrier plates 211 .
  • Such an insert can, for example, be designed to complement a scaffolding element to be connected.
  • such an insert can also have an internal thread, for example, into which a partial area of a scaffolding element to be connected can be screwed.
  • the illustrated embodiment of a connecting component 1 comprises two additional interfaces 3 which are fastened on the side of the carrier 21 facing upwards and on the side facing downwards.
  • Each additional interface 3 is connected to the carrier 21 via a base plate 32 which is guided through a recess in each carrier plate 211 and protrudes outwards over both carrier plates 211 .
  • the connection area 31 is firmly connected to the base plate 32 and extends at right angles away from the base plate 32 in the second spatial direction R2.
  • the connecting area 31 is formed by a tube section which is rounded off at its end pointing away from the base plate 32 .
  • a framework element for example a post 5 , can be plugged onto the connection area 31 . Such an application can be seen in FIG. 5, for example.
  • connection area 31 pointing away from the base plate 32 can also be designed to be open, so that a framework element can be inserted into the interior of the connection area 31 .
  • Two plug-in openings 311 are arranged in each case in the connection area 31 , which extend at right angles to the second spatial direction R2 and completely penetrate the connection area 31 .
  • a framework element can be plugged onto the connection area 31 and fixed by a pin or other plug-in element along the second spatial direction R2, with the pin radially to the second spatial direction R2 passing through one of the plug-in openings 311 and through an opening in the Scaffolding element is inserted.
  • connection component 1 has only one additional interface 3 .
  • further external interfaces 23 can be provided, for example.
  • Each additional interface 3 also includes a clamping mechanism 33 which is provided for the purpose of fixing a framework element introduced into the inner interface 22 in a non-positive and/or positive manner.
  • the clamping mechanism 33 comprises two clamping bodies 331, which are formed here by screws.
  • the clamping bodies 331 are movably connected to the base plate 32 in a direction parallel to the second spatial direction R2.
  • two internal threads are cut into the base plate 32, into which the clamping bodies 331 are screwed.
  • these have an actuating area which is formed as a screw head as a result.
  • the two clamping bodies 331 are arranged on opposite sides of the connection area 31 .
  • the clamping bodies 331 are moved in the direction of the center point M by actuating the actuating area.
  • the clamping bodies 331 of the two additional interfaces 3 arranged opposite allow the position of a framework element introduced into the inner interface 22 to be adjusted relative to the connecting component 1. Details on this are described in connection with FIG.
  • the clamping mechanism 33 can also be designed differently from the illustrated embodiment.
  • a clamping body 331 can be formed by a wedge, which is moved linearly from a direction perpendicular to the second spatial direction R2 relative to the base plate 32 in order to clamp a framework element introduced into the inner interface 22 .
  • Fig. 2 shows a second embodiment of a connecting component 1 according to the invention.
  • the connecting component 1 according to the second embodiment is largely identical to the first embodiment, but differs from the first embodiment in that the carrier 21 is divisible and has two sub-carriers 21a and 21a that can be connected to one another 21b.
  • FIGS. 2a and 2b only the differences between the second embodiment and the first embodiment are described.
  • FIGS. 2a and 2b For the other components and structural elements shown in FIGS. 2a and 2b, reference is made to the description of the first embodiment in FIG.
  • the carrier 21 is divided in a direction diagonally to the inner interface 22 .
  • the carrier 21 can be divided in a simple manner, so that in the divided state the inner interface 22 is no longer completely surrounded by the carrier 21 but is open in certain areas.
  • the holder 2 can be connected to a framework element, for example a carrier element 4, from a direction perpendicular to the longitudinal axis of the latter.
  • the two sub-beams 21a and 21b are positioned around the framework element in the divided state, so that the framework element is surrounded by the two halves of the inner interface 22 .
  • the two sub-beams 21a and 21b are then connected to one another and the framework element is enclosed in the inner interface 22 .
  • the connection component 1 does not have to be pushed onto a framework element in the axial direction in order to guide this through the inner interface 22 . Rather, the connecting component 1 can be placed around a scaffolding element from the side and attached be attached to this. As a result, it is not necessary for the framework element to be accessible from a front side in order to push the carrier onto the framework element.
  • a connecting component 1 according to the second embodiment can also be connected to a scaffolding element that is already built into a scaffolding section 100 and connected to other scaffolding elements that protrude in a direction perpendicular to its longitudinal axis.
  • the divisibility thus simplifies the use and fastening of the connecting component 1 and enables subsequent attachment of the connecting component 1 to an already erected scaffolding section 100 of a scaffolding system.
  • the dividing plane in which the carrier 21 is divided into the two sub-carriers 21a and 21b, runs through the inner interface 22. In the illustrated embodiment, the dividing plane bisects the inner interface 22 endang a diagonal through the square basic shape of the inner interface 22.
  • the dividing plane is parallel to the first spatial direction RI and at an angle to the second spatial direction R2, which is 45 °.
  • the parting plane can also be arranged differently.
  • the dividing plane could be arranged parallel to the first spatial direction RI and perpendicular to the second spatial direction R2 and divide the inner interface 22 perpendicular to the second spatial direction R2.
  • What is particularly advantageous about a division at an angle of 45° to the second spatial direction R2 is that most of the edges of the carrier 21 on which no additional interface 3 is arranged are available for arranging a plurality of external interfaces 23 .
  • the components or elements which are provided for connecting the two sub-beams 21a and 21b are arranged in two corners of the beam 21, take up little space there and are nevertheless easily accessible. Each subcarrier 21a and 21b is connected to an additional interface 3 in each case.
  • FIG. 2b shows a perspective detail view of the second embodiment of a connecting component 1 from FIG. 2a.
  • the connecting component 1 from FIG. 2a can be seen before it is assembled.
  • the two additional interfaces 3 can be seen on the left-hand side. As described in detail above with reference to FIG. 1, these each comprise a base plate 32, a connecting region 31 and two clamping elements 331 which, in combination with two receptacles in the base plate 32, form the clamping mechanism 33.
  • the holder 2 can be seen on the right-hand side, which comprises a carrier 21 which can be divided.
  • the two sub-carriers 21a and 21b are shown separately from one another.
  • Each of the two partial carriers 21a and 21b comprises two partial carrier plates 211a and 211b, which are parallel to one another and at a distance from one another are arranged.
  • the two partial carrier plates 211a and 211b are each firmly connected to one another via two spacer elements 2111 .
  • the two spacer elements 2111 are oriented with their largest surface parallel to the first spatial direction RI and at a 45° angle to the second spatial direction R2.
  • the two spacer elements 2111 are spaced apart from one another and connected parallel to one another with the partial carrier plates 211a and 211b. This connection can be made, for example, by a welded connection.
  • all components of the beam 21 or the sub-beams 21a and 21b are made of steel plates.
  • Each of the spacer elements 2111 has a connecting area, which is designed as a cylindrical opening in the illustrated embodiment.
  • a connecting element here in the form of a screw, is introduced through these connecting areas of two opposing spacer elements 2111.
  • the connecting element is introduced after the two partial carriers 21a and 21b have been positioned around a framework element which is introduced into the inner interface 22 .
  • the connecting elements are then actuated and the two partial supports 21a and 21b are thus fixed to one another and around the framework element. Details of this connection can be seen in FIG.
  • FIG. 3 shows a perspective, sectional view of the connecting component 1 from FIG. 2a.
  • the connecting component 1 from FIG. 2a is shown in section in a plane which runs perpendicularly to the first spatial direction RI and parallel to the second spatial direction R2.
  • the connection between the two sub-beams 21a and 21b can be seen clearly.
  • the carrier 21 is cut in the middle of the distance between the two carrier plates 211 .
  • This sectional plane also runs through the center of the total of four spacer elements 2111.
  • the spacer elements 2111 are arranged at right angles to the partial carrier plates 211a and 211b. In the state shown, screws with nuts are inserted through the connection areas of two spacer elements 2111 arranged adjacent to one another.
  • these connecting elements which are formed by the screws and the nuts, are actuated. This can be done, for example, using wrenches.
  • the advantage of this solution is that the connecting elements are formed by standard parts be, which can be replaced easily and inexpensively in the event of contamination or wear.
  • part of the connecting elements for example the nut, can also be firmly connected to a spacer element 2111, which can be done, for example, by a welded connection.
  • other connecting elements can also be used which are suitable for drawing together and fixing the two spacer elements 2111 arranged adjacent to one another.
  • connection areas in a part of the spacer elements 2111, which projects outwardly beyond the partial support plates 21a and 21b.
  • connecting elements introduced into the connecting areas can be reached particularly easily and can therefore be actuated in a simple manner.
  • the illustrated arrangement of the connecting elements between the part carrier plates 211a and 211b in turn has the advantage that the outer surfaces of the carrier 21 can be used as external interfaces 23 to a greater extent, since the components for dividing and connecting the carrier 21 are inside between the carrier plates 211 are arranged.
  • Fig. 4 shows a sectional front view of the connecting component from Fig. 2 with a carrier element 4 connected to the connecting component 1.
  • This view shows the divisible second embodiment of a connecting component 1, which is in a plane perpendicular to the first spatial direction RI and parallel to the second Direction in space R2 is shown in section.
  • This view serves to explain the functioning of the clamping mechanism 33.
  • a framework element in the form of a carrier element 4 is introduced into the inner interface 22.
  • This support element 4 is formed by a double C-beam, the longitudinal axis of which extends into the plane of the drawing. The four ends of the C-beams pointing outwards in the sectional view are each introduced into a recess 221 of the inner interface 22 .
  • clamping bodies 331 lying opposite one another are moved towards one another.
  • the position of the carrier element 4 relative to the inner interface 22 can be adjusted in the second spatial direction R2 by varying the path of the individual clamping bodies 331 relative to the base plates 32 .
  • the carrier element 4 is positioned and clamped in the second spatial direction R2 approximately in the center of the inner interface 22 .
  • the two upper clamping bodies 331 can be moved upwards and then the two lower clamping bodies 331 can be moved upwards for fixing purposes until the supporting element 4 is again fixed between the total of four clamping bodies 331 is. In this way, the position of the carrier element of FIG. 4 relative to the inner interface 22 can be continuously adjusted.
  • the clear width inside the inner interface is preferably selected to be larger than the external dimensions of a framework element to be introduced, in particular a carrier element 4 .
  • a distance or play between the two elements of between 2 and 10 mm is preferably selected.
  • FIG. 5 shows a perspective view of a first embodiment of a frame section 100 according to the invention.
  • the frame section 100 comprises a connecting component 1 according to the first embodiment shown in FIG.
  • a connecting component according to the second embodiment shown in FIG. 2 could also be used in the same way.
  • a carrier element 4 in the form of a double C-carrier is introduced into the inner interface 22 and fixed in it.
  • the open sides of the C-beams are each oriented in the direction of the two additional interfaces 3 .
  • the connecting component 1 is connected to two further scaffolding elements. Each of the two facing downwards and upwards in the depiction Additional interfaces 3 is connected to a post 5 of a facade scaffolding.
  • connection can be used to connect the carrier element 4, which belongs to a shoring system, to a facade scaffolding system, for example to connect walk-on platforms, ladders or the like.
  • an external interface 23 of the connection component 1 is connected to a further framework element in the form of a connection element 6 .
  • This closing element 6 is formed by a vertically oriented double C-beam.
  • the connection element 6 is dimensioned larger and more stable here than the support element 4.
  • the illustrated embodiment of a scaffolding section 100 can, for example, be part of an enclosure with which still open floors of a shell can be temporarily closed.
  • a plurality of vertically oriented connection elements 6 and a plurality of horizontally oriented carrier elements 4 are used for such an enclosure, which cross one another as shown.
  • the enclosure also includes a facade scaffolding system that closes the gaps between the other scaffolding elements and can serve as fall protection, for example.
  • a facade scaffolding system that closes the gaps between the other scaffolding elements and can serve as fall protection, for example.
  • an external interface 23 is pushed into the connection element 6 in some areas, namely between the two C-beams.
  • the two base plates 32 of the additional interfaces 3 protrude in the first spatial direction RI beyond the outwardly facing surfaces of the carrier 21 .
  • These protruding areas of the base plates 32 serve as an assembly stop when the outer interface 23 is pushed into the connection element 6 .
  • the protruding areas of the base plates are each in contact with one of the two C-beams of the connection element 6 .
  • the external interface 23 used for attachment comprises at least one recess or opening, which penetrates the carrier 21 in the first spatial direction RI in the area that is pushed into the connection element 6 .
  • Fixing takes place in that a connecting element, such as a screw or a pin, is introduced through the recess in the outer interface 23 and a corresponding recess in the connection element 6 .
  • the connection component 1 is fixed in relation to the connection element 6 in the second spatial direction R2.
  • this fixation is hidden, but on the side facing away from the carrier element 4 there are recesses or openings in the Connection element 6 can be seen, which can be used for fixing a further connection component 1 on the opposite side of the connection element 6 .
  • FIG. 6 shows a perspective view of a second embodiment of a scaffolding section 100 according to the invention.
  • the connecting component 1 from FIG. 1 is connected to a total of three different scaffolding elements.
  • the connection order differs from the connection order in the embodiment illustrated in FIG. 5 .
  • 6a shows a first assembly step within this connection sequence, in which an external interface 23 is connected to a connection element 6 in a form-fitting manner.
  • the connection element 6 is formed by a frame strut of a control panel of a formwork system.
  • the outer interface 23 used for the connection is arranged on the edge of the carrier 21, penetrates the carrier completely in the first spatial direction RI and is open on its side facing away from the inner interface 22.
  • This anchor A ensures that the outer interface 23 can no longer be accidentally pulled off the connection element 6 and fixes or braces the carrier element 4 to the connection component 1 and the connection element 6 the anchor A transmits horizontal loads between the scaffolding members connected to the connecting member 1, and the connecting member 1 transmits vertical loads between the scaffolding members connected to the connecting member 1.
  • FIG. 7 shows a perspective view of a third embodiment of a scaffolding section 100 according to the invention.
  • a connecting component 1 according to the first embodiment from FIG. 1 is connected to three different scaffolding elements from different scaffolding systems.
  • a carrier element 4 formed by a double C-carrier is introduced into the inner interface 22 .
  • the open side of the C-beam in the third embodiment is oriented towards the sides of the inner interface 22 which are not adjacent to an additional interface 3.
  • the carrier element 4 is thus rotated by 90° about its longitudinal axis relative to the connecting component 1 in comparison to the embodiments in FIGS.
  • both additional interfaces 3 are connected to posts 5 of a facade scaffolding system. These stems 5 are slipped onto the respective connection areas 31 and fixed there by means of plug-in elements in the axial direction relative to the second spatial direction R2.
  • An external interface 23 which is arranged in the illustration at the lower left corner of the connecting component 1, is connected to a connecting element 6, which hereby forms a support.
  • the connecting element 6 is introduced in regions into a recess between the two support plates 211 which belongs to the external interface 23 .
  • This outer interface 23 is arranged on the edge of the carrier 21 facing away from the inner interface 22 .
  • This recess between the two support plates 211 is open to the outside.
  • the external interface 23 also includes a recess in the two support plates 211, which is formed here by a cylindrical opening which extends along the first spatial direction RI and penetrates both support plates. A connecting element for fixing the connecting element 6 between the two carrier plates 211 can be inserted through this recess.
  • a total of three connecting components 1 are shown in the scaffold section 100 shown, two of these connecting components 1 already being connected to various scaffolding elements.
  • the connection component 1 arranged furthest to the front on the right in the illustration is only connected to the carrier element 4 with its inner interface 22 . Additional scaffolding elements can be connected to this connecting component 1 .

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  • Engineering & Computer Science (AREA)
  • Architecture (AREA)
  • Mechanical Engineering (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Mutual Connection Of Rods And Tubes (AREA)

Abstract

L'invention concerne une pièce d'assemblage pour assembler au moins deux éléments d'échafaudage, cette pièce comprenant un moyen de retenue pourvu d'un support, d'une interface intérieure et d'au moins une interface extérieure, le support entourant au moins en partie l'interface intérieure, l'interface intérieure étant formée par une ouverture dans le support qui traverse complètement le support dans une première direction dans l'espace et la ou les interfaces extérieures étant formées par un évidement dans le support qui est adjacent à l'interface intérieure ou situé à distance de celle-ci. La pièce d'assemblage comprend en outre au moins une interface supplémentaire reliée au support du moyen de retenue, cette interface supplémentaire présentant une zone d'assemblage en forme de tige ou de tube qui s'étend dans une deuxième direction dans l'espace. L'invention concerne en outre une partie d'échafaudage comprenant une pièce d'assemblage, ainsi qu'un procédé de construction d'une partie d'échafaudage.
PCT/EP2022/083162 2021-12-01 2022-11-24 Pièce d'assemblage pour assembler des éléments d'échafaudage WO2023099334A1 (fr)

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DE102021131584.0 2021-12-01
DE102021131584.0A DE102021131584A1 (de) 2021-12-01 2021-12-01 Verbindungsbauteil zur Verbindung von Gerüstelementen

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WO2023099334A1 true WO2023099334A1 (fr) 2023-06-08

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Citations (6)

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Publication number Priority date Publication date Assignee Title
JPH0925720A (ja) * 1995-07-11 1997-01-28 Tootex:Kk 屋根足場固定用ジャッキ構造
NZ314027A (en) * 1997-01-07 1998-11-25 Dgs Property Pty Ltd Clamp type bracket for mounting an upright post or support of a safety rail or balustrade or stanchion assembly has non circular opening and recess
EP3147424A2 (fr) * 2015-09-24 2017-03-29 Wilhelm Layher Verwaltungs-GmbH Support de grille et systeme de support de grille, en particulier pour utilisation universelle dans un echafaudage de protection ou de travail connu
EP3301311A1 (fr) * 2016-09-15 2018-04-04 Peri Gmbh Couplage
CN207749816U (zh) 2017-10-18 2018-08-21 中交第四公路工程局有限公司 一种立杆固定件
CN108708548A (zh) * 2018-06-26 2018-10-26 中建四局第三建筑工程有限公司 一种工具式悬挑脚手架立管定位装置

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Publication number Priority date Publication date Assignee Title
WO2005028762A2 (fr) 2003-09-14 2005-03-31 Simmons Robert J Procede et dispositif rotatifs pour souder une structure de support de poutre au(x) cote(s) d'une colonne
CN106677505A (zh) 2017-03-22 2017-05-17 成都市工业设备安装公司 一种可调式钢管支撑件及其安装方法
CN212799312U (zh) 2020-07-02 2021-03-26 中铁十五局集团有限公司 一种用于钢轨吊装的液压夹具

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH0925720A (ja) * 1995-07-11 1997-01-28 Tootex:Kk 屋根足場固定用ジャッキ構造
NZ314027A (en) * 1997-01-07 1998-11-25 Dgs Property Pty Ltd Clamp type bracket for mounting an upright post or support of a safety rail or balustrade or stanchion assembly has non circular opening and recess
EP3147424A2 (fr) * 2015-09-24 2017-03-29 Wilhelm Layher Verwaltungs-GmbH Support de grille et systeme de support de grille, en particulier pour utilisation universelle dans un echafaudage de protection ou de travail connu
EP3301311A1 (fr) * 2016-09-15 2018-04-04 Peri Gmbh Couplage
CN207749816U (zh) 2017-10-18 2018-08-21 中交第四公路工程局有限公司 一种立杆固定件
CN108708548A (zh) * 2018-06-26 2018-10-26 中建四局第三建筑工程有限公司 一种工具式悬挑脚手架立管定位装置

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