EP4396425A1 - Connecting disc for a scaffold - Google Patents

Abstract

The invention relates to a connecting disc for connecting at least two scaffold elements, comprising: a basic body having a first main surface and a second main surface which is disposed opposite the first main surface, and having an edge surface which runs round the basic body and connects the first main surface and the second main surface to one another; at least one longitudinal connecting opening which passes completely through the basic body; and at least two transverse connecting openings, each of which passes completely through the basic body, each transverse connecting opening being delimited by a peripheral contour in a plan view of the first main surface, said peripheral contour having a receiving region and at least one blocking region which interrupts the receiving region and is disposed outside the receiving region. The at least two transverse connecting openings are disposed on mutually opposing sides of the longitudinal connecting opening, the blocking regions of the at least two transverse connecting openings are directed away from one another. The invention further relates to a standard having a connecting disc and to a scaffold section having a standard.

Description

Connecting disc for a scaffold

The invention relates to a connecting disc for connecting at least two scaffolding elements, comprising a base body with a first main surface and a second main surface, which is arranged opposite the first main surface, and with an edge surface, which runs around the base body and the first main surface and the second main surface together connects, at least one longitudinal connection opening, which completely penetrates the base body, and at least two transverse connection openings, each of which completely penetrates the base body, each transverse connection opening being delimited by a peripheral contour in a plan view of the first main surface, the peripheral contour having a receiving area and having at least one blocking area , which interrupts the recording area and is located outside the recording area. The at least two transverse connection openings are arranged on opposite sides of the longitudinal connection opening, with the blocking areas of the at least two transverse connection openings facing away from one another. The invention also relates to a vertical post with a connecting disc and a scaffolding section with a vertical post.

Scaffolding is used in the construction sector for various tasks. 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. In civil engineering, shoring is used to bring a wide variety of building components into position and hold them there. Such building parts can be, for example, prefabricated concrete parts, steel girders or steel structures. Furthermore, elements required for the erection of buildings, such as makeshift constructions or formwork with shoring, can be positioned. Finally, scaffolding is also used in the service or revision area, for example to ensure that workers in large process engineering plants, such as refineries, safely get to the plant parts to be overhauled bring. In general, the basic requirements for scaffolding are that they must be easy to transport and set up.

Scaffolding usually essentially has vertically oriented elements, also called scaffolding standards, and essentially horizontally oriented elements, also called scaffolding bars or bar elements. A three-dimensional scaffolding section is assembled from these scaffolding elements, with the scaffolding posts and locking elements being connected to one another by connection interfaces. Forces and moments are transmitted between the individual scaffolding elements in the erected scaffolding section via these connection interfaces. The interfaces must be designed in such a way that they can be connected and disconnected from one another in a simple manner in order to enable the scaffolding section to be erected and dismantled quickly and easily.

A well-known interface, which is usually arranged on vertically oriented vertical posts, is a connecting disk, which is oriented perpendicular to the longitudinal axis of a vertical post and projects beyond it. A number of openings are usually made in such a connecting disc, which serve as a connection area with other scaffolding elements. These openings are dimensioned somewhat larger than corresponding counter-elements, which are arranged as an interface on other scaffolding elements, for example on a horizontal bar. In this way, a simple establishment and release of the connection via the connecting disk is ensured. In addition, the play between the connecting disk and the counter-element enables a certain amount of tolerance compensation with regard to position and angle when connecting two scaffolding elements to one another. This tolerance compensation is important because in reality the scaffolding elements can hardly be exactly aligned in position and angle to each other. With the known solutions, however, only small moments can be transmitted between the connecting disk and a scaffolding element connected to it, in particular a horizontal bar. As a result, scaffolding sections that use known connection disks as an interface are unsuitable in some applications, since larger moments acting on the connection lead to movement, for example a swaying of the scaffolding section, which can create hazards for the people working on the scaffolding. The object of the invention is therefore to propose solutions with which it is possible to transmit greater moments via an interface designed as a connecting disk and with which incorrect positioning of frame elements connected to the connecting disk can be compensated for at the same time.

This object is achieved by a connecting disc for connecting at least two scaffolding elements, comprising

- a base body with a first main surface and a second main surface, which is arranged opposite the first main surface, and with an edge surface, which runs around the base body and connects the first main surface and the second main surface to one another,

- at least one longitudinal connection opening, which runs from the first main surface to the second main surface and completely penetrates the base body and which extends essentially at right angles to the first main surface or to the second main surface,

- at least two transverse connection openings, each of which runs from the first main surface to the second main surface and completely penetrates the base body and of which each extends essentially at right angles to the first main surface or to the second main surface and of which each of which is arranged adjacent to or spaced from the longitudinal connection opening , wherein each cross-connection opening is delimited by a peripheral contour in a plan view of the first main surface, wherein the peripheral contour has a receiving area which is intended for receiving a connection of a scaffolding element and wherein the peripheral contour has at least one blocking area which interrupts the receiving area, wherein the at the two ends of the receiving area adjoining the blocking area converge and/or imaginary continuous extensions of the two ends of the receiving area adjoining the blocking area intersect and the locking area for receiving a bolt lelement of a scaffolding element is provided, with the blocking area being arranged outside a continuous connection between the two ends of the contour of the receiving area adjoining the blocking area, outside the receiving area and at least a partial area of the contour of the blocking area running at an angle to the continuous connection, which angle varies from 0 ° differs, wherein the at least two cross-connection openings are arranged on opposite sides of the longitudinal connection opening, wherein the blocking areas of the at least two cross-connection openings point away from each other and an imaginary line between the two blocking areas defines a first connection direction, and the base body has at least two additional connection openings, each of which runs from the first main surface to the second main surface and completely penetrates the base body, and each of which extends essentially at right angles to the first main surface or to the second main surface, each additional connection opening having a peripheral contour, which is provided for receiving a connection and a locking element of a scaffolding element, the circumferential contour of each additional connection opening having a curved contact area and the at least two additional connection openings being arranged on opposite sides of the longitudinal connection opening, the contact areas of the two additional connection openings pointing away from one another and an imaginary line A second connection direction is defined between the two contact areas, the first connection direction being oriented perpendicular to the second connection direction.

A connecting disc according to the invention is used to connect several scaffolding elements in a scaffolding section. The connecting disc is based on a base body. This base body includes a first main surface and a second main surface, which represent the largest surfaces of the connecting disk. The first main surface and the second main surface are arranged opposite one another and are preferably oriented parallel to one another. The outer boundary of the base body forms an edge surface which runs around the base body and borders on the first main surface and the second main surface. Several openings are made in the base body: a centrally located longitudinal connection opening, two transverse connection openings and two auxiliary connection openings. In addition, further openings can be made in the base body. The transverse connection openings and the auxiliary connection openings differ in shape from each other and from the longitudinal connection opening. In the following, the individual openings will first be discussed and then the interaction and the relative positioning of these openings to one another will be described.

The longitudinal connection opening penetrates the base body and forms the central opening of the connection disk, around which the other openings are arranged. The longitudinal connection opening is intended to receive a scaffolding element that is vertically oriented in the application and to be firmly connected to it. For example, the connecting disk can be connected to a vertical post via the longitudinal connecting opening. Furthermore, at least two cross-connection openings are introduced into the base body, which completely penetrate it. These cross-connection openings have a special shape, which enables the transmission of torques, which act about an axis perpendicular to the first main surface or to the second main surface, between the connecting disc and the scaffolding elements connected to it. In a plan view of the first main surface or the second main surface, each cross-connection opening has a circumferential contour which includes two partial areas. A first partial area of the circumferential contour is the receiving area, which surrounds the part of the cross-connection opening that is provided for receiving a connection of a scaffolding element. A second sub-area of the circulation contour is the restricted area, which is arranged outside of the receiving area. The blocking area is intended to accommodate a locking element of a scaffolding element. This locking element protrudes beyond the connection of the scaffolding element. The blocking area is provided for receiving the locking element in a form-fitting manner and thereby blocking it. This positive fit prevents the connected scaffolding element from twisting relative to the connecting disk. The blocking area can be designed, for example, as a notch or groove and is always complementary in shape to at least a portion of the locking element. The blocking area interrupts the recording area and is located outside the recording area. In this case, two ends of the receiving area each adjoin the blocking area on one side. These two adjoining ends of the receiving area run towards one another or can be thought of as continuously lengthened. This imaginary continuation of the recording area in the area where it is interrupted by the restricted area serves to define the shape of the restricted area. If the ends of the receiving area adjoining the blocking area are continuously lengthened, a continuous connection is created between these two ends of the receiving area. This imaginary continuous connection delimits the recording area compared to the blocking area. The restricted area is located outside of this continuous connection. The connection of the scaffolding element is positioned within the receiving area, within the imaginary boundary of the continuous connection. The locking element, on the other hand, protrudes beyond the continuous connection into the blocking area. The blocking area itself also has a contour which, at least in some areas, is oriented at an angle different from 0° to the continuous connection between the two ends of the receiving area. A contour of the blocking area arranged at an angle of this type enables torque to be transmitted between the locking element and the blocking area. At least part of the is preferred Contour of the restricted area oriented at an angle of 90° +/- 10° to the continuous connection and also to the ends of the recording area adjacent to the restricted area. However, it is also possible to arrange the blocking area at a smaller angle to the continuous connection or also at a varying angle to the continuous connection. Essentially, the exact geometry of the contour of the blocking area depends on the contour of the locking element, which is to be introduced into the blocking area in a form-fitting manner. In a connecting disc according to the invention, two such transverse connection openings are arranged in the base body on opposite sides of the longitudinal connection opening. The blocking areas of the two transverse connection openings point away from each other and away from the longitudinal connection opening. An imaginary line between the two blocking areas, in particular between the middle of the two blocking areas, defines a first connecting direction of the connecting disk.

Furthermore, the base body of a connecting disk according to the invention has at least two additional connection openings, which also completely penetrate the base body. Each additional connection opening also has a circumferential contour which, however, differs from the circumferential contour of the cross-connection openings. The peripheral contour of the longitudinal connection opening has no blocking area, which forms an undercut. Instead of the blocking area, the peripheral contour of the additional connection opening has a curved contact area. The circumferential contour of the additional connection opening is intended to accommodate both the connection and the locking element of a scaffolding element. When connecting a scaffolding element with an additional connection opening, there is no exact form fit between the circumferential contour and the locking element. Rather, the locking element, which protrudes beyond the connection, can slide at least in regions inside the peripheral contour along the curved contact surface, thereby enabling at least regionally a rotary movement of the framework element connected to the connecting disk relative to the connecting disk. This rotary movement allows tolerance compensation when connecting a scaffolding element to the connecting disk. In particular, a scaffolding element that is not aligned exactly at right angles to other scaffolding elements in the same scaffolding section can still be connected to the connecting disc without any problems due to the degree of freedom provided by the additional connection opening. Because of this degree of freedom, at least one allows partial rotational movement of a scaffolding element about an axis of rotation perpendicular to the first main surface, the transferability of torques in this orientation is only possible to a limited extent. An additional connection opening thus makes it possible to connect a scaffolding element in which tolerances with regard to positioning can be compensated for, but in which the transferability of torques is lower. In contrast to this, a cross-connection opening enables the connection of a scaffolding element in which the transferability of torques is high, but there is only a small tolerance compensation with regard to the relative position of a scaffolding element to the connecting disk. The at least two auxiliary connection openings are on opposite sides of the

Arranged longitudinal connection opening, wherein the contact areas on the

Longitudinal connection opening are arranged opposite side of the peripheral contour. An imaginary line between the two contact areas, in particular between the two centers of these contact areas, defines a second connecting direction of the connecting disk. According to the invention, the first connection direction between the two cross-connection openings is oriented at right angles to the second connection direction between the two additional connection openings.

A connecting disk according to the invention has a first connecting direction in which two cross-connecting openings are arranged, which enable the transmission of high torques between the connecting disk and a scaffolding element connected thereto. These cross-connection openings each have a blocking area, which can be brought into positive locking with a locking element of the framework element. Rotational movements of the scaffolding element relative to the connecting disk about an axis of rotation perpendicular first to the main surface are completely or at least largely blocked and prevented by this form fit. The first connection direction is intended to connect scaffolding elements which are to be rigidly connected to the connecting disc. In addition, the connecting disk according to the invention has a second connecting direction in which two additional connecting openings are arranged. These additional connection openings have an abutment area for a locking element of a framework element, which allows a partial rotary movement of a framework element which is connected to the connection disk. In this way, incorrect positioning between the connecting disk and a scaffolding element connected to it can be compensated for. In other words, the connection allows one or more other scaffolding elements via the additional connection openings a slight deviation in the alignment of these scaffolding elements to the second connection direction. Due to the right-angled arrangement between the first connection direction and the second connection direction, different properties of the connection disk are deliberately produced in two mutually perpendicular directions. This is particularly advantageous when used in a scaffold section in which there are usually requirements for the transmission of high torques in one connection direction on the connecting disk, whereas flexibility of the connection is required in another connection direction, for example around a scaffold section endang an irregularly shaped object such as a building to set up. With a connecting disk according to the invention, increased torques can thus be transmitted through connections in the first connection direction and at the same time incorrect positioning of connected scaffolding elements can be compensated for by connections in the second connection direction. The vertical alignment between the two connection directions is particularly advantageous if the connection disk is installed in such a way that the first connection direction is aligned parallel to the transverse direction of the scaffold and the second connection direction is aligned parallel to the longitudinal direction of the scaffold.

In one embodiment it is provided that the blocking area is U-shaped in a plan view of the first main surface, the two legs of the U being arranged at an angle which differs from 0° for continuous connection and/or the two legs of the U are arranged at an angle which differs from 0° to the area of the receiving area adjacent to the blocked area. The blocking area can be U-shaped, with the two legs of the preferably being arranged at right angles to the area of the receiving area which adjoins the blocking area. Such an arrangement of the legs favors the transmission of high torques.

Provision is preferably made for the blocking area to be designed axisymmetric to an axis which runs through the center point of the longitudinal connection opening. The longitudinal connection opening has a center point, which can also be the center point of the entire connection disk. A design of the blocking area, in which this is axisymmetric to an axis that extends radially away from the center, has the advantage that a torque transmission between a framework element and the Connection disc in two opposite directions of rotation is possible. An equally large moment can be transmitted in the two opposite directions of rotation, since the contact surfaces between the locking element and the blocking area are identical in both directions of rotation.

Furthermore, it is provided that the blocking area runs in a straight line, at least in certain areas. A particularly good transmission of torque is made possible by a partially straight course of the contour of the blocking area. One or more rectilinear areas can also be connected by curved areas.

Provision is made for the longitudinal connection opening and the receiving area to be arranged at a distance from one another and for the blocking area to be arranged on the side of the receiving area opposite the longitudinal connection opening. In the case of each transverse connection opening, the blocking area is arranged on the side of the receiving area which is remote from the longitudinal connection opening. The blocking area is thus arranged on the radially outer side in relation to the center point of the longitudinal connection opening. As a result, the blocking area is easily accessible for inserting the locking element. The center point of the longitudinal connection opening and the center point of the area of the receiving area are spaced apart from one another. The longitudinal connection opening and the transverse connection openings can be separated from one another by a partial area of the base body or merge into one another, which will be described later.

It is advantageously provided that the longitudinal connection opening delimits a circular area. The connecting disc is intended for fixed connection to a framework component, which usually has a circular outer cross section. For this reason, at least partial areas of the longitudinal connection opening are designed in a plan view in the shape of an arc of a circle. As a result, the longitudinal connection opening delimits a circular area into which a framework component can be inserted, which is then firmly connected to the connection disk.

Provision is preferably made for the longitudinal connection opening to have a transition to the receiving area. In this embodiment, the longitudinal connection opening goes into the Recording areas of a cross-connection openings. This has the advantage that a connection of a scaffolding element introduced into the receiving area can be brought into contact with a scaffolding component which is arranged within the longitudinal connection opening. A direct force and torque transmission can thus take place between a framework element connected to the connecting disk, which is connected to a transverse connection opening, and a framework component, which is fastened in the longitudinal connection opening. As a result, the power flow is guided directly, which increases the stability and rigidity of such a connection. The transition between the longitudinal connection opening and the receiving area is arranged on the side of the receiving area facing away from the blocking area. In a plan view of the first main surface, the receiving area is preferably delimited in some areas by straight edges which run parallel to the first connection direction.

Furthermore, it is provided that the longitudinal connection opening and the additional connection opening are arranged at a distance from one another and the contact area is arranged on the side of the additional connection opening opposite the longitudinal connection opening. In this embodiment, the center of the area of the auxiliary connection opening is spaced from the center of the longitudinal connection opening. Starting from the center point of the longitudinal connection opening, each contact area of an additional connection opening points outwards in the radial direction. A transition can also be provided between the additional connection opening and the longitudinal connection opening.

It is provided that the longitudinal connection opening has a center point and a surface of the contact area pointing towards the center point and a surface of the blocking area pointing towards the center point are arranged on a common circular path around the center point or are arranged on circles concentric with the center point, the diameters of which differ by differ by up to 10%. In this embodiment, the distance from the center point of the longitudinal connection opening to the area of the blocking area and the abutment area that is furthest away in relation to the center point is the same. This means that the blocking area and the contact areas extend equally far outwards, starting from the center in the radial direction. This has the advantage that a scaffold element with a connection and a locking element is in the same relative position in the radial direction to the center point are attachable. In relation to the center point of the longitudinal connection opening, a locking element which rests against the contact area of an additional connection opening has the same radial position as a locking element which is introduced into the blocking area of a transverse connection opening. The maximum radial extent from the center point is therefore the same for a cross-connection opening as for an additional connection opening. It is also possible that these radial extents or the distance between the outermost points of the blocking area and contact area are located on concentric circles around the center, which differ in diameter by up to 10%.

It is optionally provided that the base body has at least one connection opening which runs from the first main surface to the second main surface and completely penetrates the base body and which is arranged at a distance from the longitudinal connection opening and the transverse connection opening. In this embodiment, at least one further connection opening is made in the base body in addition to the two cross-connection openings and the two additional connection openings. This connection opening is also intended for connection to scaffolding elements and can be shaped and dimensioned differently. It is also possible to provide several connection openings, which can also differ from one another in shape and size.

It is advantageously provided that the base body consists of an iron-based material and the longitudinal connection opening and the transverse connection opening represent cutouts in the base body, which are connected to one another and which are introduced into the base body by stamping or laser cutting. In this embodiment, the base body and thus the connecting disk consists of an iron-based material, such as steel. As a result, the connecting disc can be connected in a simple manner to a framework component which is introduced into the longitudinal connection opening. Iron-based materials are particularly easy to weld, which enables a simple and strong connection to a scaffolding component.

The object of the invention is further achieved by a vertical post comprising at least one connecting disk according to one of the previously described embodiments, further comprising at least one connecting sleeve which is inserted and fixed in the longitudinal connection opening connected to it, wherein the connecting sleeve has a central axis which extends in its longitudinal direction, wherein the central axis is oriented essentially perpendicular to the first main surface and/or to the second main surface, wherein the connecting sleeve has a connecting interface in or on at least one of its front ends , which is intended for connection to a scaffolding element.

A vertical post according to the invention comprises at least one connecting disk according to one of the previously described embodiments. A connecting sleeve is introduced into the longitudinal connecting opening of the connecting disc and extends along its central axis. The connecting sleeve preferably has a cylindrical outer cross section. The connecting sleeve has an interface on at least one, preferably both, of its front ends, with which the connecting sleeve can be connected to other connecting sleeves. A vertical post according to the invention is preferably significantly longer in the direction of its central axis than its diameter in a direction perpendicular to the central axis. In particular, the length of the connecting sleeve is greater than the diameter by a factor of at least five. However, it is also possible to make the connecting sleeve shorter, for example in such a way that its length is only three times greater than its diameter. In this shorter embodiment, the vertical post can be used as a scaffolding node into which other vertically oriented scaffolding posts are inserted. A vertical post according to the invention provides the same advantages which were described above for the connection disk. In particular, other scaffolding elements can be connected to the vertical post in the direction of the first connection direction in such a way that a transmission of high torques between the components is possible. At the same time, further scaffolding elements can be connected to the vertical post in the direction of the second connection direction. Tolerance compensation is possible at the end of the second connection direction, which compensates for incorrect positioning of these scaffolding elements relative to the vertical post.

In one embodiment of the vertical post, it is provided that the connecting sleeve is formed by a tube section and the connecting interface is formed by a receptacle which extends from a front end into the interior of the connecting sleeve. In this embodiment, the connecting sleeve consists of a pipe section, preferably with a annular cross-section produced. The hollow interior of the tube section can be used to insert other scaffolding elements.

Furthermore, it is provided that the connecting sleeve has at least one connecting hook which, starting from the outer peripheral surface of the connecting sleeve, extends in a direction radially away from the central axis, the connecting hook being arranged at a distance from the connecting disk in the direction of the central axis and, in a plan view of the first main surface and/or the second main surface, the connection hook extends parallel to a direction running from the center point of the longitudinal connection opening to the blocking area of a transverse connection opening. In this embodiment, the vertical post comprises at least one connection hook, which is provided for connection to other scaffolding elements. For example, a railing rod can be hung on such a connecting hook. This connecting hook is arranged at a distance from the connecting disk in the direction of the central axis of the connecting sleeve in order to avoid collisions between scaffolding elements that are connected to the connecting disk and scaffolding elements that are connected to the connecting hook.

It is preferably provided that, in a plan view of the first main surface and/or the second main surface, the connecting hook extends in the first connecting direction. The connection hook is preferably oriented endang the first connection direction, in which the transverse connection openings are also oriented relative to the center point of the longitudinal connection opening or the central axis of the connection sleeve.

The object of the invention is also achieved by a scaffolding section comprising at least one vertical post according to one of the embodiments described above, further comprising at least one scaffolding element which has an interface with a connection and a locking element, the locking element being designed to be movable with respect to the connection and in a locked state the locking element protrudes over the terminal, the terminal being inserted into the receiving area of a cross-connection opening of the connecting disc and the locking element being inserted into the locking area of the same cross-connecting opening, wherein between the locking area and the Locking element at least partially there is a form fit, which prevents a rotational movement of the scaffolding element relative to the scaffold node in an axis of rotation parallel to the central axis.

In addition to a vertical standard, a scaffolding section according to the invention comprises at least one scaffolding element which is connected to the connecting disk of the vertical standard via a transverse connection opening. The scaffolding element can be formed, for example, by a horizontal bar. The framework element comprises at least one interface which is provided for connection to the connecting disk. This interface includes a connection which is designed to be immovable with respect to the remaining area of the scaffolding element. Furthermore, the interface includes a locking element, which is designed to be movable with respect to the rigid connection. The locking element can assume a locking state in which it protrudes over the connection. In addition, the locking element can also assume an unlocked state in which it protrudes less far than in the locked state or not at all over the connection. In the frame section according to the invention, the locking element of the interface of the frame element is introduced into a blocking area of a cross-connection opening of the connecting disk. There is a form fit between the locking element and the locking area, which locks the scaffolding element relative to the vertical post. This blocking prevents a rotational movement of the scaffolding element relative to the vertical post in an axis of rotation parallel to the central axis. A scaffolding section according to the invention has the advantage that high torques can be transmitted via the connection between the interface of the scaffolding element and the connecting disk of the vertical standard, which improves the load-bearing capacity of the scaffolding section. There is also the option of connecting further scaffolding elements to the scaffolding section.

Provision is made in the frame section for the locking element to protrude beyond the continuous connection of the receiving area. The locking element can be arranged in areas in the receiving area. However, it always protrudes beyond the continuous connection of the recording area into the restricted area. This applies to the locking state of the locking element. In an unlocked state, the locking element can also be arranged completely in the receiving area. Provision is made for the locking element to be insertable into the connection in an unlocked state, with the locking element being arranged in a state inserted into the connection within the continuous connection of the receiving area and not protruding into the blocking area. This introduction of the locking element into the connection serves to facilitate the connection of the interface to the connecting disk. In the unlocked state there is still no form fit between the blocking area and the locking element.

Furthermore, it is provided that the locking element and the connection penetrate the connecting disk. The locking element and the connection are preferably longer in a direction parallel to the central axis than the thickness of the connecting disk. In this way, there is a secure connection between the scaffolding element and the connecting disk.

Provision is preferably made for the frame section to have at least one further frame element with a locking element and a connection, with the further frame element being connected to an additional connection opening, with the locking element and the connection being introduced into the additional connection opening and the locking element lying against the curved contact area, with the other scaffolding element can be rotated relative to the vertical standard in an axis of rotation parallel to the central axis by an angle of up to 60°. In this embodiment, at least one second scaffolding element is connected to the vertical post. The interface of this second framework element is introduced into an additional connection opening. The locking element bears against the curved contact area of the additional connection opening and can move there relative to the curved contact area. As a result, there is no complete form fit between the second frame element and the additional connection opening. The connected second scaffolding element can thus be twisted in some areas in an axis of rotation parallel to the central axis. This gives this connection flexibility with regard to the orientation of the scaffolding element relative to the vertical post.

It is provided that when the further scaffolding element rotates relative to the vertical post and/or the additional connection opening in an axis of rotation parallel to the central axis, the locking element slides endang on the curved contact area. The radius of curvature of the curved contact surface is significantly larger, at least by a factor of ten larger than a Radius of curvature or an outer radius on the locking element. This allows the locking element to slide along the contact surface. This enables a rotational movement about an axis of rotation parallel to the central axis. At the same time, however, the locking element is in contact with the contact area, so that a relative translational movement of the interface or the framework element to the connecting disk is prevented. Such a connection thus only allows a relative rotational movement, but no displacement between the connected scaffolding element and the vertical post.

It is advantageously provided that the vertical post is oriented in the scaffolding section in such a way that the first connection direction between two cross-connection openings runs in the transverse direction of the scaffolding and the second connection direction between two additional connection openings runs in the longitudinal direction of the scaffolding, with the longitudinal direction of the scaffolding being the direction in which the scaffolding section has its longest dimension and wherein the transverse direction of the frame is oriented perpendicular to the longitudinal direction of the frame. In this embodiment, the second connection direction of the connecting disk is oriented parallel to the longitudinal direction of the structure of a structure in which the structure section is installed. The longitudinal direction of the scaffold is to be understood as meaning the direction in which the scaffold section or the scaffold in which it is installed has its longest dimension. The longitudinal direction of the scaffolding is usually oriented parallel to a facade or another surface of a building on which the scaffolding is erected. In many cases, a facade or other surface of a building is not straight, but is curved or has cracks. As a result, a skeleton section or skeleton along this direction must also deviate from a rectilinear shape in order to be oriented parallel to the surface. In a scaffolding section it must thus be possible to position scaffolding elements in relation to one another other than in a rectilinear form. This can be achieved by allowing twistability at the connection points between scaffolding elements. Precisely this twistability is achieved in a framework section according to the invention in that a framework element is connected to an additional connection opening of the connection disk. The framework section is also oriented in such a way that the first connection direction runs parallel to the transverse direction of the framework. The transverse direction of the scaffolding runs perpendicular to the longitudinal direction of the scaffolding. It is thus possible to transmit high torques in the transverse direction of the frame between two frame elements which are connected to a cross-connection opening via an interface. This stabilizes the scaffold section and in particular, a movement of the scaffold section in the longitudinal direction of the scaffold is prevented. In this embodiment of a scaffold section it is thus achieved that it can be easily adapted to the course of a building or a facade at the end of the longitudinal direction of the scaffold and at the same time is more load-bearing and more stable in the transverse direction of the scaffold.

It is possible for at least three framework elements to be provided, with the locking element and the connection of the first framework element being introduced into a cross-connection opening and the locking elements and connections of the two other framework elements each being introduced into an additional connection opening. In this embodiment, a total of three scaffolding elements are connected to a vertical post. In a plan view from the direction of the central axis of the connecting sleeve, two skeleton members are arranged along the skeleton longitudinal direction and the third skeleton member is arranged perpendicularly thereto in the skeleton transverse direction. Of course, this frame section can be extended by further frame elements or further frame sections, as a result of which a stable and at the same time flexible frame is provided.

It is optionally provided that the connecting sleeve of the vertical standard is connected to at least one further scaffolding element via the connection interface. In this embodiment, the connecting sleeve of the vertical standard is also connected to at least one other scaffolding element in the scaffolding section. This at least one further framework element is connected via a connection interface in the connection sleeve. In this way, the framework section can be extended by further framework elements in a direction parallel to the central axis.

Also disclosed is a method for connecting a vertical post to a scaffolding element in a scaffolding section according to one of the previously described embodiments, comprising the steps

A) Insertion of the connection of the scaffolding element in the receiving area of a cross-connection opening,

B) Rotational movement of the scaffolding element around an axis of rotation parallel to the central axis of the connecting sleeve of the vertical standard until the locking element is oriented towards the locking area, C) Movement of the locking element relative to the connection, as a result of which the locking element penetrates into the blocking area and as a result of which a positive connection is produced between the locking element and the blocking area.

This method is used to connect a vertical standard with a connecting disc to a scaffolding element. A scaffolding section with a vertical post and at least one scaffolding element is thereby obtained. A vertical standard is used to construct a section of scaffolding. The process is preferably carried out in the described order of process steps A) to C). In a first method step A), an interface of the framework element is introduced into a cross-connection opening of the connecting disc. The interface is in the unlocked state and the locking element does not protrude or protrudes only slightly beyond the connection of the interface of the framework element. In a second method step B), a rotary movement of the framework element is carried out until the locking element is arranged congruently with the blocking area of the cross-connection opening. In a third method step C), the interface is then transferred from the unlocked state to the locked state, with the locking element moving relative to the connection and penetrating into the blocked area. This creates a form fit between the locking element and the blocking area and the connection between the framework element and the connecting disk no longer has any degree of freedom in a direction of rotation perpendicular to the central axis of the vertical post. The advantage here is that the locking element can only penetrate into the blocking area when the correct orientation of the framework element to the connecting disk in a direction of rotation parallel to the central axis has been achieved in method step B). If this correct orientation is not achieved, no form fit between the interface and the connecting disc is possible. This can be determined visually and haptically in a simple manner, so that the method according to the invention ensures that the framework element is correctly positioned in relation to the connecting disk before a fixed connection between the two components is possible. It is optionally provided that the connection and the locking element are connected to one another by a spring which presses the locking element out of the connection. In this embodiment, once proper relative positioning between the interface and the cross-connect opening is achieved, the latch member automatically snaps into the locking area of the cross-connect opening. In particular, in this embodiment, correct positioning between the framework element and the Connecting disc almost automatically possible. The method thus simplifies the correct construction of a scaffold section.

Features, effects and advantages that are disclosed in connection with the connecting disk and the vertical post are also deemed to be disclosed in connection with the scaffolding section. The same applies in reverse, features, effects and advantages which are disclosed in connection with the scaffolding section are also deemed to be disclosed in connection with the connecting disk and the vertical post.

In the figures, embodiments of the invention are shown schematically. show it

1 shows a perspective view of an embodiment of a connecting disc according to the invention,

2 shows a plan view of the underside of an embodiment of a connecting disk according to the invention with a framework element connected to it and

3 shows a perspective view of an embodiment of a scaffolding section according to the invention.

The same elements are provided with the same reference symbols in the figures. In general, the properties of an element that are described for one figure also apply to the other figures. Directional information such as above or below relates to the figure described and is to be transferred to other figures accordingly.

1 shows a perspective view of an embodiment of a connecting disk 1 according to the invention. The connecting disk 1 is based on a base body 2, which in the illustrated embodiment is formed by a disk or plate made of an iron-based material. In the embodiment shown, the base body 2 has a square basic shape in a plan view from above, which is rounded at the corners. The base body 2 comprises a main surface 21 which faces upwards in the illustration and is planar. On the lower side of the base body 2, opposite the first main surface 21, there is one second main surface 22, which is also planar. The first main surfaces 21 and the second main surfaces 22 are arranged parallel to one another and delimit the base body 2 in the thickness direction. The second main surface 22 can also be curved at least in certain areas. Furthermore, it is possible that the first main surface 21 and the second main surface 22 are not oriented parallel to one another. The edge surface 23 of the base body 2 runs around the base body and connects the first main surface 21 to the second main surface 22. The edge surface 23 is irregularly shaped and has both flat and curved areas. A longitudinal connection opening 3 is introduced in the center of the illustrated embodiment of a connecting disk 1 , which extends perpendicularly to the first main surface 21 and to the second main surface 22 and completely penetrates the base body 2 . The longitudinal connection opening 3 has a center M on. The longitudinal connection opening 3 delimits a circular area which is intended for receiving another element, for example a connection sleeve 30 . A part of the boundary surfaces of the longitudinal connection opening 3 has the shape of a cylinder jacket.

In the illustrated embodiment, two transverse connection openings 4 are provided, which are each arranged at a distance from the longitudinal connection opening 3 . Each of the cross-connection openings 4 extends perpendicularly from the first main surface 21 to the second main surface 22 and completely penetrates the base body 2 . An open transition is arranged between each of the two transverse connection openings 4 and the longitudinal connection opening 3 . Thus, the longitudinal connection opening 3 and the transverse connection openings 4 merge into one another. Each cross-connection opening 4 is delimited by a peripheral contour 41 . This peripheral contour 41 is formed by the edge of the cross-connection opening 4 in a top view of the first main surface 21 or the second main surface 22 . The peripheral contour 41 can be seen particularly well in FIG. 2 and the plan view shown therein. The peripheral contour 41 has a receiving area 411 which is a partial area of the peripheral contour 41 . The remaining partial area of the peripheral contour 41 is formed by a blocking area 412 . In the illustration, the blocking area 412 is identified by a dashed line running parallel thereto. In the embodiment shown, the receiving area 411 is designed in the shape of a bell and is intended to receive a connection 201 of a framework element 20 , in particular an interface S of the framework element 20 . The receiving area 411 extends from a first side of the transition from the transverse connection opening 4 to the longitudinal connection opening 3 to a second side of this transition. The receiving area 411 is interrupted by the blocking area 412 which is arranged opposite the transition to the longitudinal connection opening 3 and the longitudinal connection opening 3 . In a plan view of the first main surface 21 or the second main surface 22, the blocking area 412 is U-shaped, with the two legs of the U being connected to the adjacent areas of the receiving area 411 in a rounded manner. In the illustrated embodiment, the blocking area is designed to be axially symmetrical to an axis which runs through the center point M of the longitudinal connection opening 3 . Such an axis is, for example, the illustrated first connection direction VR1. The axis described through the center M and the first connection direction VR1 are imaginary axes and represent geometric auxiliary elements that facilitate the description of the embodiment. In the embodiment shown, the blocking area 412 runs in a straight line in some areas, which means that there are flat contact surfaces inside the cross-connection opening 4 which promote the transmission of moments from or to another scaffolding element 20 . Such planar contact surfaces ensure that when there is a form-fitting connection with another scaffolding element 20, there is uniform surface pressure, which enables high torques to be transmitted without damaging the connection partners. In the illustrated embodiment, the straight portions of the blocking portions 412 are interconnected by curved portions. These curved areas avoid sharp edges, which are disruptive when connecting to a scaffolding element 20 . The blocking area 412 is intended to receive a locking element 202 in a form-fitting manner when the connecting disk 1 is connected to a framework element 20 . The blocking area 412 is arranged outside the area enclosed by the receiving area 411 . In the illustrated embodiment, there are two transverse connection openings 4 which are arranged opposite one another and at a distance from the longitudinal connection opening 3 . The blocking areas 412 of the two transverse connection openings 4 each point away from one another and from the longitudinal connection opening 3 . An imaginary direction or line between the two blocking areas 412 of the opposite transverse connection openings 4 defines the first connection direction VR1, which also runs through the center point M of the longitudinal connection opening 3. The first connection direction VR1 bisects the blocking area 412 in a plan view of the first main surface 21. In the embodiment shown, the receiving area 411 is also executed axially symmetrically to the first connection direction VR1. In an alternative embodiment, several blocking areas 412 can also be provided, each of which interrupts the receiving area 411 . The provision of several locking areas 412 can be used, for example, so that a framework element 20 can be connected with its locking element 202 in different positions or directions of rotation relative to the connecting disk 1 . In this case, the plurality of blocking regions 412 are arranged at a distance from one another. In addition, the blocking area 412 can also be shaped differently from the illustrated embodiment. For example, the blocking area 412 may be semi-circular, triangular, rectangular, or otherwise shaped in a plan view of the first major surface 21 . Furthermore, the shape of the receiving area 411 can also differ from the illustrated bell shape. The recording area 411 can, for example, be circular, rectangular, polygonal, trapezoidal or have another shape. Furthermore, in addition to the blocking area 412, the receiving area 411 can have further interruptions which are arranged outside of the shape or area continuously enclosed by the receiving area 411. Such interruptions can be provided, for example, as cut-outs for components of the framework element 20 . In addition, such interruptions can be provided to reduce the weight of the connecting disk. Depending on the embodiment of the interface S of the scaffolding element 20, the transverse connection opening 4 can also be designed separately from the longitudinal connection opening 3, where a partial area of the base body 2 is arranged between the longitudinal connection opening 3 and the transverse connection opening 4 and thus there is no transition between the two openings. Finally, it is also possible to provide more than the two cross-connection openings 4 shown in the base body 2 . For example, three, four, five or six cross-connection openings 4 can be made in the base body 2 regularly or irregularly.

In addition, two additional connection openings 5 are introduced into the base body 2 of the illustrated embodiment of a connecting disk 1 , which completely penetrate the base body 2 and run perpendicularly, starting from the first main surface 21 to the second main surface 22 . The two additional connection openings 5 are arranged opposite one another, at a distance from one another and from the longitudinal connection opening 3 . In the embodiment shown, the two auxiliary connection openings 5 are axisymmetric to the first Connection direction VR1 positioned. The additional connection openings 5 are also provided for receiving an interface S of a framework element 20 . In contrast to the cross connection openings 4, the additional connection openings 5 do not have a blocking area 412. Each additional connection opening 5 is delimited by a peripheral contour 51 . This peripheral contour 51 is formed by the edge of the additional connection opening 51 in a top view of the first main surface 21 or the second main surface 22 . On the side facing the center M, there is a transition between each additional connection opening 5 and the longitudinal connection opening 3. On the side facing away from the center M, each circumferential contour 51 of each additional connection opening 5 has a curved contact area 511, which is a partial area of the circumferential contour 51. The peripheral contour 51 is intended to accommodate a connection 201 and a locking element 202 of a framework element 20 . The entire peripheral contour 51 accommodates the connection 201 and the locking element 202 in a form-fitting manner. However, when an interface S of a scaffolding element 20 is accommodated in an additional connection opening 5, at least a partial degree of rotational freedom remains for the scaffolding element 20 in an axis perpendicular to the first main surface 21 or to the second main surface 22. This rotational degree of freedom is given by the fact that when a connection is made Locking element 202 rests against the curved contact area 511 and can slide endang on this. As a result, there is no form fit between the locking element 202 and the contact area tangential to the contact area 511 . In contrast, in the case of a connection between an interface S of a scaffolding element 20, in particular between its locking element 202, and the blocking area 412 of a cross-connection opening 4, there is a form fit in the tangential direction to the area of the blocking area 412 that has the greatest distance from the center point M. Thus, a framework element 20 which is connected to a cross-connection opening 4 has no rotational degree of freedom about an axis perpendicular to the first main surface 21 or to the second main surface 22 . In the illustrated embodiment, the area of the peripheral contour 51 which is not formed by the contact area 511 is bell-shaped. The contact area 511 here has the shape of an arc of a circle, which merges into the remaining area of the circumferential contour 51 in a rounded manner. The arrangement of the two additional connection openings 5 around the longitudinal connection opening 3 defines a second connection direction VR2. This second connection direction VR2 runs through the center point M and through the two points of the contact areas 511 that are furthest from the center point M. The second connection direction VR2 runs perpendicular to the first connection direction VR1 and parallel to the first main surface 21 or to the second main surface 22. In the illustrated embodiment of a connection disk 1, the intersections of the first connection direction VR1 with the two blocking areas 412 and the two intersections of the second connection direction VR2 with the contact areas 511 lie on a common circular path around the center M of the longitudinal connection opening 3. The outermost points of the additional connection openings 5 and the transverse connection openings 4, based on the center M, are thus equidistant from the center M and thus also equidistant from the outer edge of the circular longitudinal connection opening 3. In this way, interfaces S of framework elements 20 of the same shape and dimensions can be connected both to a transverse connection opening 4 and to an additional connection opening 5 . A connecting disk 1 of the illustrated embodiment thus enables a connection to a scaffolding element 20 with the cross-connection opening 4, in which there is no rotational degree of freedom about an axis perpendicular to the first main surface 21 or to the second main surface 22, and a connection to the additional connection opening 5 in the a rotational degree of freedom about an axis perpendicular to the first main surface 21 or to the second main surface 22 remains. The distances between the points of the cross-connection opening 4 and the additional connection opening 5 which are furthest away from the center point M can also be designed to be different. In order to enable a connection with the same interfaces S of a scaffolding element 20, the points of intersection of the blocking area 412 with the first connection direction 1 and of the contact area 511 with the second connection direction are preferably arranged on concentric circles, the diameters of which differ from one another by up to 10%. In the illustrated embodiment, two transverse connection openings 4 and two auxiliary connection openings 5 are arranged in a cross shape around the longitudinal connection opening 3 arranged in the middle. Alternatively, it is also possible to provide a larger number of additional connection openings 5 . Furthermore, it is possible to design the distribution of cross connection openings 4 and additional connection openings 5 differently. For example, two transverse connection openings 4 can be arranged adjacent to one another, offset by 90° from one another around the center point, and two additional connection openings 5 offset by 90° from one another around the center point can be arranged opposite one another.

In the illustrated embodiment, a total of four circular connection openings 6 are introduced into the base body 2 , which are perpendicular starting from the first main surface 21 extend to the second main surface 22. These connection openings 6 are provided for connecting further framework elements 20 to the connecting disk 1 . Furthermore, starting from the first main connecting surface 21 , a number of troughs 7 are introduced into the base body 2 , which do not completely penetrate the base body 2 . The troughs 7 in the illustrated embodiment correspond to part of a sphere and are also provided for the attachment or attachment of further framework elements 20 . At the edges of the base body 2, a total of four recessed areas 231 are introduced as part of the edge surface 23, which here have the shape of part of a circular cylinder. These set-back areas 231 are provided for receiving or supporting a partial area of a scaffolding element 20 .

2 shows a plan view of the underside of an embodiment of a connecting disk 1 according to the invention with a framework element 20 connected to it. FIG. 2 shows the connecting disk from FIG. The connecting disk 1 is connected to a framework element 20 shown at the bottom right. The framework element 20 is formed here by a horizontal bar. The scaffolding element 20 was introduced from the first main surface 21, which is opposite the illustrated second main surface 22, into a cross-connection opening 4 and connected to it in a form-fitting manner. The locking element 202 of the framework element 20, which is pointing downwards to the right in the illustration, was introduced into the blocking area 412 in a form-fitting manner. The connection 201 of the framework element 20 was introduced into the receiving area 411 . A partial area of the connection 201 is introduced into the transition between the transverse connection opening 4 and the longitudinal connection opening 3 . There is a form fit between the transition between the transverse connection opening 4 and the longitudinal connection opening 3 and the partial area of the connection 201 introduced into this transition. Alternatively, it is also possible that there is no such transition between the transverse connection opening 4 and the longitudinal connection opening 3, or that no partial area of the Connection 201 is introduced into this transition. In the embodiment shown, two mutually opposite cross-connection openings 4 are provided, which are arranged axially symmetrically with respect to the second connection direction VR2 and which are each formed axially symmetrically with respect to the first connection direction VR1. The cross-connection opening 4 shown at the top left thus corresponds to a reflection of the cross-connection opening 4 shown at the bottom right about the second connection direction VR2. In the following, the circumferential contour 41 of the top left illustrated cross-connection opening 4 described. Accordingly, the description also applies to the circumferential contour 41 of the cross-connection opening 4 shown at the bottom right. The peripheral contour 41 comprises a receiving area 411, which is bell-shaped here and which runs from a first side of the transition between the longitudinal connection opening 3 and the transverse connection opening 4 to the second side of this transition. In the embodiment shown, the entire receiving area 411 is continuous and has no sharp edges or cracks. The blocking area 412 interrupts the recording area 411 on its side facing away from the center M. In the representation, the blocking area 412 is also identified by dashed lines in FIG. 2 . To describe the arrangement of the blocking area 412, imaginary auxiliary geometry is introduced below. In the embodiment shown, the two ends of the receiving area 411 adjoining the blocking area 412 run towards one another in their extension. These lengthenings are in a constant relationship to the ends of the receiving area 411 adjoining the blocked area 412. The constant lengthenings of the ends of the receiving area 411 adjoining the blocked area 412 are symbolized in the illustration by dotted lines. These continuous extensions conceptually close the enclosed area defined by the receiving areas 411 . The continuous extensions intersect here at the intersection with the first connection direction VR1. The continuous intersecting extensions form a continuous connection SV between the two ends of the contour of the receiving region 411 adjoining the blocking region 412 . This imaginary auxiliary geometry is used, together with the contour of the receiving area 411 , to define a delimitation of the area enclosed by the connection area 411 . The continuous connection SV thus represents an imaginary extension of the connection area 411 and delimits part of the area enclosed by the receiving area 411 . According to the invention, the blocking area 412 extends outside of this area enclosed by the connection area 411 . The result of this is that a locking element 202 protruding over the connection 201 of a framework element 20 can be positively introduced into the blocking area 412 arranged outside of the connection area 411 . In the connected state between connecting disk 1 and framework element 20 there is then a form fit which is designed in such a way that rotation of the framework element 20 about an axis perpendicular to the second main surface 22 is not possible. In other words, the positive connection between the locks Blocking area 412 and the inserted locking element 202 each rotational degree of freedom about such an axis perpendicular to the main surface 22. This form fit means that a connection between the cross-connection opening 4 and a framework element 20 can transmit significantly greater torques than a connection between such a framework element 20 and an additional connection opening 5. At the same time, the alignment of the framework element 20 to the connecting disk 1 is clearly defined by the insertion or latching of the locking element 202 in the locking area 412. In the case shown in Fig. 2, the longitudinal axis of the framework element 20, which here runs downwards to the right, is aligned parallel to the first connection direction VR1 and perpendicular to the second connection direction VR2 by the engagement of the locking element 202 in the blocking area 412. Due to the positive fit, this alignment is maintained very precisely, which improves the stable and precise construction of a scaffolding section from several scaffolding elements. Both the receiving area 411 and the blocking area 412 can have different shapes. Preferably, neither the receiving area 411 nor the blocking area 412 have sharp edges. At least a partial area of the contour of the blocking area 412 is arranged at an angle W to the continuous connection SV, which differs from 0°. This means that at least a partial area of the contour of the blocking area 412 is arranged at an angle to the continuous elongation SV, which accommodates the transmission of a moment that acts in the circumferential direction of the receiving area 411. In the illustrated embodiment, the blocking area 412 is U-shaped and the two legs of the U, or tangents T to the legs, are arranged essentially at a 90° angle for the continuous connection SV of the receiving area 411 . Such a 90° angle of the adjoining areas enables a torque to be transmitted particularly well. However, it is also possible to arrange partial areas of the blocking area 412 at a smaller angle, for example at a 60° angle to the continuous extension SV. In addition, it is possible for the blocking area 412 to extend at many different angles to the continuous elongation SV. This is the case, for example, when the blocking area 412 is formed by an arc of a circle which, starting from the continuous extension SV, extends outside the area enclosed by the receiving area 411 . What is essential about blocking area 412 is that it is arranged outside the area enclosed by receiving area 411 and that blocking area 412 is oriented, at least in certain areas, in such a way that effective transmission of a moment from locking element 202 to blocking area 412 is possible. For the connections

ti and the function of the other elements of the connecting disk, such as the connection openings 6, is referred to the description of FIG.

3 shows a perspective view of an embodiment of a scaffolding section 100 according to the invention. The scaffolding section 100 comprises a vertical post 10, which is oriented vertically with its central axis MA in the illustration. A connecting disk 1 according to the embodiment shown in FIGS. 1 and 2 is fastened to the vertical post 10 . A total of three scaffolding elements 20 are connected to the vertical post 10 via this connecting disk 1 . The scaffolding elements 20 are all designed here as horizontal bars and extend in different directions in a common horizontal plane.

The vertical post 10 is based on a connecting sleeve 30 which is formed here by a tubular section with a circular cross-section. The connecting sleeve 30 can also be made longer or shorter than shown. In addition, the connecting sleeve 30 can also have a different cross-sectional shape, for example a rectangular or square cross-section. The connecting sleeve 30 has two ends 301, of which only the upper end 301 is shown in FIG. A connection interface 302 is introduced on or in the upper front end 301, which is used to connect the vertical post 10 to other scaffolding elements. For example, two identically designed vertical posts 10 can be connected to one another via the connection interface 302 in the direction of the central axis MA. For this purpose, the lower connection interface 302 (not shown) can be designed to complement the shape of the upper interface 302. In this case, the lower connection interface 302 of a first vertical post 10 can be plugged into the upper connection interface 302 of a second vertical post 10 and thus connected to it. On the outer peripheral surface of the connecting sleeve 30, a connecting disk 1 is fixed. The connecting sleeve 30 is guided through the longitudinal connecting opening 3 of the connecting disk and inserted into it. A connection between the connecting sleeve 30 and the connecting disc 1 can be produced, for example, by welding. Alternatively are others

Connection techniques possible, such as a press fit or a

screw connection. The connecting disc 1 is oriented perpendicularly to the central axis MA of the connecting sleeve 30 with its first main surface 21 facing upwards and with its second main surface 22 facing downwards. The direction of extension of the two Cross connection openings 4 and the two additional connection openings 5 runs parallel to the central axis MA. The transition from each transverse connection opening 4 and each additional connection opening 5 to the centrally arranged longitudinal connection opening 3 is limited by the outer surface of the connection sleeve 30 . For details of the connecting disc 1, reference is made to Figs. 1 and 2. The vertical post 10 further includes a connecting hook 303 which is fixed to the outer peripheral surface of the connecting sleeve 30 and which extends radially away from the central axis MA. There is a distance between the connecting disk 1 and the connecting hook 303 in the direction of the central axis MA. The connecting hook 303 is provided for connecting the vertical post 10 to another scaffolding element. This additional scaffolding element can be formed, for example, by a railing that is hung on the connecting hook 303 . The connecting hook 303 extends radially away from the central axis MA and the outer peripheral surface of the connecting sleeve 30 toward the first connecting direction VR1. Thus, the connecting hook 303 is oriented in the same direction in which one of the two cross-connecting openings 4 is oriented. The connecting hook 303 thus extends in a direction which runs from the center point M of the longitudinal connection opening 3 of the connecting disk 1 to the blocking area 412 of the transverse connection opening 4 there, which faces to the rear right in the illustration. Preferably, the connecting hook 303 is oriented in the scaffolding section 100 such that it points towards the area of the scaffolding section 100 in which a step covering is attached, which is stepped on by persons being worked. In this way, a railing can be hung on the connecting hook 303, which protects the working persons from falling off the scaffolding section and the step covering. In the illustrated embodiment, the connecting hook 303 points in the direction in which the tread covering is to be attached. The direction that runs from the central axis MA in the direction of the step covering in a horizontal plane is defined as the transverse frame direction GQ. A direction perpendicular to the transverse direction of the scaffold is defined as longitudinal scaffold direction GL. The scaffolding section 100 is preferably significantly longer in the longitudinal scaffolding direction GL than in the transverse scaffolding direction GQ. In the transverse direction GQ of the scaffold, usually only two vertical posts 10 are provided parallel to one another in a row in the scaffold section 100 . In contrast, in the longitudinal direction GL of the scaffolding, a large number of vertical standards 10 are preferably arranged in parallel in a row. The longitudinal direction GL of the scaffolding usually runs parallel to a facade or another surface of a building that is to be worked on from the scaffolding section 10 . The transverse direction of the scaffolding GQ usually extends perpendicularly to such a facade or to another surface of a building. In the illustrated embodiment of a scaffolding section 100, the vertical post 10 is oriented about its central axis MA in such a way that the first connection direction VR1 of the connecting disk 1 runs parallel to the transverse direction GQ of the scaffolding and the second connecting direction VR2 of the connecting disk 1 runs parallel to the longitudinal direction GL of the scaffolding.

The three framework elements 20, which are formed by horizontal bars, are only partially shown in FIG. One end of each scaffolding element 20 can be seen with an interface S arranged on its front side. The interface S is used to connect to the vertical standard 10, in particular to the connecting disk 1. The scaffolding elements shown and their interfaces S are designed in such a way that they can also be used with known Vertical posts or connecting discs can be connected. Each interface S comprises a connection 201 which is immovable relative to the rest of the framework element 20 and which, when connected to the connecting disc, is introduced into a transverse connection opening 4 or an additional connection opening 5 and completely penetrates this in the connected state. Each interface S also includes a locking element 202 which is designed to be movable relative to the connection 201 . Due to this mobility, the locking element 202 can be introduced into the connection 201 at least in certain areas. This state is referred to as the unlocked state. To establish the connection between the interface S and the connecting disk 1, the locking element 202 is then moved relative to the connection 201 in such a way that it protrudes further beyond the connection 201. In this way, a positive fit is produced between the interface S and the connecting disk 1, which stably connects the vertical post 10 and the scaffolding element 20 to one another. The movement of the locking element 202 relative to the connection 201 creates a form fit in a plane perpendicular to the central axis MA, at least when the interface S is connected to a cross-connection opening 4 . In this case, the locking element 202 penetrates into the blocking area 412 and thus creates a form fit which prevents a rotational movement of the scaffolding element 20 relative to the vertical post 10 about an axis parallel to the central axis MA. As can be seen in FIG. 3, the locking element 202 projects further below the connecting disk 1 beyond the connection 201 than above the connecting disk 1. This also produces a form fit in a direction oriented vertically in the illustration. This form fit in one direction parallel to the central axis MA is also established when the interface S is connected to an auxiliary connection opening 5.

The longitudinal axis of the scaffolding element 20 arranged at the rear right in the illustration is aligned parallel to the transverse scaffolding direction GQ. This framework element 20 is connected to one of the two cross-connection openings 4 via its interface S, with the locking element 202 of the interface S being introduced into the blocking area 412 . In this way, the framework element 20 is positively secured against rotation about an axis parallel to the central axis MA. This connection can thus also be used to transmit moments which act on the framework element 20 about an axis parallel to the central axis MA. The scaffold section shown is therefore particularly stable in the transverse direction GQ of the scaffold, as a result of which movement, in particular swaying, of the scaffold section is greatly reduced or prevented entirely. The longitudinal axes of two further scaffolding elements 20 are oriented parallel to the scaffolding direction GL and are each connected with their interfaces S to an additional connection opening 5 . In these two framework elements 20, the locking element 202 rests against the curved contact area 511 and can slide along it. This gives the two frame elements 20 a degree of freedom, which is connected to an additional connection opening 5, in the direction of rotation about an axis parallel to the central axis MA. However, this degree of freedom is limited since the locking element 202 can only slide along in the curved contact areas 511 . At the edge of this curved contact area 511, the locking element 202 then strikes the remaining peripheral contour 51 and further relative movement of the framework element 20 relative to the connecting disk 1 is prevented. Due to this limited rotational degree of freedom, which an interface S has when connected to an additional connection opening 5, a scaffolding section 100 can be adapted in scaffolding direction GL to a non-linear course of a facade or another building surface. In practice, such an easy adaptability of the profile of the scaffold longitudinal direction GL is of great importance, since in very few cases does a scaffold section actually have to be erected in a straight line. The illustrated embodiment of a vertical standard 10 and a scaffolding section 100 is particularly advantageous because along the longitudinal scaffolding direction GL there is a limited rotational degree of freedom for the connection of scaffolding element 20 to the vertical standard 10 and at the same time perpendicular thereto, in the transverse scaffolding direction GQ there is no rotational degree of freedom for a relative movement of the framework element 20 to Vertical post 10 is given, whereby a very stable connection is provided. A scaffold section 10 designed accordingly is therefore flexible and adaptable in its structure in the longitudinal direction GL of the scaffold and enables the transmission of greater moments in the transverse direction GQ of the scaffold, as a result of which a high degree of stability is provided for the scaffold section 100 .

The interaction of a cross-connection opening 4 with a locking element 202 is also advantageous during a method for connecting a vertical standard 10 to a scaffolding element 20 in a scaffolding section 100, since this interaction facilitates and ensures correct alignment of a scaffolding element 20 to the vertical standard 10 in the transverse direction of the scaffolding GQ. In such a connection method, the connection 201 is first introduced into the receiving area 411 of a cross-connection opening 4 . In this introduction, the interface S is in the unlocked state. The framework element 20 is then rotated about an axis of rotation parallel to the central axis MA until the locking element 202 is aligned with the blocking area 412 . It is only possible in this orientation to move the locking element 202 relative to the connection 201 in such a way that it penetrates into the blocking area 412 . This intrusion is easily recognizable visually and can also be felt haptically. If the scaffolding element 20 and the vertical post 10 are not correctly aligned with one another, it is not possible to introduce the locking element 202 into the locking area 412, which the person assembling the scaffolding section 100 will notice. If such an incorrect alignment is noticed, the person can change the alignment until the locking element 202 can be introduced into the blocking area 412 . In this way it is ensured that a scaffolding element 20 connected to a cross-connection opening 4 is always connected to the connecting disk 1 correctly and stably in the correct alignment.

Reference list:

1 connecting disc

2 base bodies

21 first major surface

22 second major surface

23 edge surface

231 recessed area

3 longitudinal connection opening

4 cross-connect hole

41 circulation contour

411 recording area

412 restricted area

5 Auxiliary Connection Port

51 circulation contour

511 investment area

6 port hole

7 hollow

20 framework element

201 connection

202 locking element

30 connecting sleeve

301 front end

302 connection interface

303 connection hook

MA central axis

VR1 first connection direction

VR2 second connection direction

SV steady connection

M midpoint

S interface T tangent

GL Longitudinal direction of scaffolding

GQ Transverse direction of scaffolding

Claims

patent claims

1. Connecting disk (1) for connecting at least two scaffolding elements, comprising

- a base body (2) with a first main surface (21) and a second main surface (22) which is arranged opposite the first main surface (21), and with an edge surface (23) which runs around the base body (2) and the first connects the main surface (21) and the second main surface (22),

- at least one longitudinal connection opening (3) which runs from the first main surface (21) to the second main surface (22) and completely penetrates the base body (2) and which is essentially at right angles to the first main surface (21) or to the second main surface ( 22) extends,

- at least two transverse connection openings (4), each of which runs from the first main surface (21) to the second main surface (22) and completely penetrates the base body (2) and each of which is substantially at right angles to the first main surface (21) or to the second main surface (22) and each of which is arranged adjacent to or at a distance from the longitudinal connection opening (3), each transverse connection opening (4) being delimited by a peripheral contour (41) in a plan view of the first main surface (21), the peripheral contour (41) has a receiving area (411) which is provided for receiving a connection (201) of a scaffolding element (20) and wherein the peripheral contour (41) has at least one blocking area (412) which interrupts the receiving area (411), wherein the the two ends of the receiving area (411) adjoining the blocking area (412) converge and/or imaginary continuous extensions of the adjoining the blocking area (412). n the two ends of the receiving area (411) intersect and the locking area (412) is provided for lockingly receiving a locking element (202) of a framework element (20), the locking area (412) outside of a continuous connection (SV) of the two to the locking area (412) adjacent ends of the contour of the receiving area (411), outside of the receiving area (411) and at least a partial area of the contour of the blocking area (412) runs at an angle (W) to the continuous connection (SV), which extends from 0 ° differs, where the

35 at least two transverse connection openings (4) are arranged on opposite sides of the longitudinal connection opening (3), the blocking areas (412) of the at least two transverse connection openings (4) pointing away from one another and an imaginary line between the two blocking areas (412) points in a first connection direction (VR1 ) defined, and the base body (2) has at least two additional connection openings (5), each of which runs from the first main surface (21) to the second main surface (22) and completely penetrates the base body (2) and each of which is essentially in the at right angles to the first main surface (21) or to the second main surface (22), each additional connection opening (5) having a peripheral contour (51) which is provided for receiving a connection (201) and a locking element (202) of a framework element (20). is, wherein the peripheral contour (51) of each additional connection opening (5) has a curved contact area (511) and the at least at least two additional connection openings (5) are arranged on opposite sides of the longitudinal connection opening (3), the contact areas (511) of the two additional connection openings (5) pointing away from one another and an imaginary line between the two contact areas (511) indicates a second connection direction (VR2) defined, wherein the first connection direction (VR1) is oriented perpendicularly to the second connection direction (VR2). Connecting disc (1) according to Claim 1, characterized in that the blocking area (412) is U-shaped in a plan view of the first main surface (21), the two legs of the U being at an angle which differs from 0°. are arranged for continuous connection (SV) and/or the two legs of the U are arranged at an angle which differs from 0° to the area of the receiving area (411) adjoining the blocking area (412). Connecting disk (1) according to one of the preceding claims, characterized in that the blocking area (412) is designed to be axisymmetric to an axis which runs through the center point (M) of the longitudinal connecting opening (3).

36 Connecting disc (1) according to one of the preceding claims, characterized in that the blocking area (412) runs in a straight line at least in areas. Connecting disc (1) according to one of the preceding claims, characterized in that the longitudinal connection opening (3) and the receiving area (411) are arranged at a distance from one another and the blocking area (412) on the side of the receiving area (411) opposite the longitudinal connection opening (3) on is ordered. Connecting disk (1) according to one of the preceding claims, characterized in that the longitudinal connecting opening (3) delimits a circular area. Connecting disc (1) according to one of the preceding claims, characterized in that the longitudinal connection opening (3) has a transition to the receiving area (411). Connecting disc (1) according to one of the preceding claims, characterized in that the longitudinal connection opening (3) and the additional connection opening (5) are arranged at a distance from one another and the contact area (511) is arranged on the side of the additional connection opening (5) opposite the longitudinal connection opening (3). is. Connecting disk (1) according to one of the preceding claims, characterized in that the longitudinal connecting opening (3) has a center (M) and a surface of the contact area (511) pointing towards the center (M) and a surface pointing towards the center (M). of the blocking area (412) are arranged on a common circular path around the center (M) or are arranged on circles concentric to the center (M), the diameters of which differ from one another by up to 10%. Connecting disc (1) according to one of the preceding claims, characterized in that the base body (2) has at least one connection opening (6) which runs from the first main surface (21) to the second main surface (22) and completely penetrates the base body (2). and which is spaced from the longitudinal connection port (3) and the transverse connection port (4). Connecting disc (1) according to one of the preceding claims, characterized in that the base body (2) consists of an iron-based material and the longitudinal connection opening (3) and the transverse connection opening (4) represent cutouts in the base body (2), which are connected to one another and which are connected through Stamping or laser cutting are introduced into the base body. Vertical post (10) comprising at least one connecting disk (1) according to one of the preceding claims, further comprising at least one connecting sleeve (30) which is introduced into the longitudinal connecting opening (3) and firmly connected to it, the connecting sleeve (30) having a central axis (MA ) which extends in its longitudinal direction, the central axis (MA) being oriented substantially perpendicularly to the first main surface (21) and/or to the second main surface (22), the connecting sleeve (30) being in or on at least one of its front ends (301) has a connection interface (302) which is provided for connection to a framework element. Vertical post (10) according to the preceding claim, characterized in that the connecting sleeve (30) is formed by a tube section and the connecting interface (302) is formed by a receptacle which extends from a front end (301) into the interior of the connecting sleeve (30 ) extends. Vertical post (10) according to one of Claims 12 or 13, characterized in that the connecting sleeve (30) has at least one connecting hook (303) which, starting from the outer peripheral surface of the connecting sleeve (30), extends in a direction radially away from the central axis (MA ) extends, wherein the connecting hook (303) in the direction of the central axis (MA) is spaced from the connecting disc (1). and, in a plan view of the first main surface (21) and/or the second main surface (22), the connection hook (303) extends parallel to a direction which runs from the center point (M) of the longitudinal connection opening (3) to the locking area (412) a cross-connection opening (4). Vertical post (10) according to the preceding claim, characterized in that the connecting hook (303) extends in the first connecting direction (VR1) in a plan view of the first main surface (21) and/or the second main surface (22). Scaffolding section (100) comprising at least one vertical post (10) according to one of Claims 12 to 15, further comprising at least one scaffolding element (20) which has an interface (S) with a connection

(201) and a locking element (202), wherein the locking element (202) is designed to be movable relative to the connection (201) and the locking element in a locking state

(202) protrudes over the connection (201), the connection (201) being introduced into the receiving area (411) of a cross-connection opening (4) of the connecting disk (1) and the locking element (202) being introduced into the blocking area (412) of the same cross-connection opening (4) is introduced, with a form fit between the blocking area (412) and the locking element (202) at least in some areas, which prevents a rotational movement of the scaffolding element (20) relative to the vertical post (10) in an axis of rotation parallel to the central axis (MA). Scaffold section (100) according to the preceding claim, characterized in that the locking element (202) projects beyond the continuous connection (SV) of the receiving area (411). Scaffolding section (100) according to one of Claims 16 or 17, characterized in that the locking element (202) can be introduced into the connection (201) in an unlocked state, the locking element (202) being introduced into the connection (201) inside the continuous connection (SV) of the receiving area (411) and does not protrude into the blocking area (412).

39

19. Scaffold section (100) according to any one of claims 16 to 18, characterized in that the locking element (202) and the connection (201) penetrate the connecting disk (1).

20. Scaffolding section (100) according to one of Claims 16 to 19, characterized in that the scaffolding section (100) has at least one further scaffolding element (20) with a locking element (202) and a connection (201), the further scaffolding element (20 ) is connected to an additional connection opening (5), the locking element (202) and the connection (201) being introduced into the additional connection opening (5) and the locking element (202) resting against the curved contact area (511), the additional framework element (20) can be rotated relative to the vertical post (10) in an axis of rotation parallel to the central axis (MA) by an angle of up to 60°.

21. Scaffolding section (100) according to one of Claims 16 to 20, characterized in that when the further scaffolding element (20) is rotated relative to the vertical post (10) and/or the additional connection opening (5) in an axis of rotation parallel to the central axis (MA) the locking element (202) slides along the curved contact area (511).

22. Scaffolding section (100) according to one of Claims 16 to 21, characterized in that the vertical post (10) is oriented in the scaffolding section (100) in such a way that the first connection direction (VR1) between two cross-connection openings (4) is in the transverse direction (GQ) of the scaffolding. and the second connection direction (VR2) runs between two additional connection openings (5) in the longitudinal direction (GL) of the structure, the longitudinal direction (GL) of the structure being the direction in which the structure section (100) has its longest dimension and the transverse direction (GQ) of the structure being vertical is oriented to the longitudinal direction (GL) of the scaffold.

23. Scaffolding section (100) according to one of claims 16 to 22, characterized in that at least three scaffolding elements (20) are provided, the locking element (202) and the connection (201) of the first scaffolding element (20) being inserted in a cross-connection opening (4th ) and the locking elements (202) and connections (201) of the two other frame elements (20) are each introduced into an additional connection opening (5).

40 Scaffolding section (100) according to one of Claims 16 to 23, characterized in that the connecting sleeve (30) of the vertical post (10) is connected to at least one further scaffolding element via the connection interface (302).

41