WO2024017709A1 - Building aid and adjustment method - Google Patents

Abstract

The invention relates to a building aid and a method for adjusting a building aid. A building aid (10) comprises a vertical component (11) for fastening to a produced part of a construction (19) in a vertical orientation and a horizontal component (12) for forming a platform (14). The vertical component (11) is laterally movable with respect to the horizontal component (12). In this way, it can be ensured that the horizontal components and the platform have a custom-fit position even if the distance of the wall fastenings deviates from the relevant target position.

Description

Construction aids and adjustment procedures

Description

The invention relates to a construction aid and a method for adjusting a construction aid.

A construction aid is an aid that is used for the construction of buildings. Examples of structures are buildings, bridges or walls. To erect such structures, cranes, scaffolding and formwork are used. With such construction aids, there may be a risk that people and objects such as tools, bolts, screws, rubble, etc. could fall from a great height. In order to avoid associated risks, construction aids can have protective devices that protect against falling. Protective devices may include railings, grilles, nets, walls, etc.

A formwork is a mold. Fresh concrete can be poured into the mold. After the concrete has hardened, the formwork can usually be removed. For example, components of buildings or bridges can be manufactured. Examples of components are walls, ceilings, shafts and supports.

A formwork can be formed from a plurality of formwork panels. A formwork panel is a panel made of wood or plastic, for example. A formwork panel can be flat and/or at least partially curved. Supporting elements may be present on the back of the panel, such as a frame, side members and/or cross members. The supporting elements can be made of wood or steel, for example. A front side of the formwork panel contacts and limits the poured concrete and in this way shapes the surface of the component.

A frame of a formwork panel generally does not protrude from the front of the panel. A formwork panel can include one or more anchor holes. An anchor can be inserted through opposing anchor holes in two opposing formwork panels. The ends of an anchor can be secured so that an anchor can no longer be pulled out of the anchor holes. The two ends of an anchor can be attached to the Backs of formwork panels, for example, can be fastened in such a way that an anchor can absorb at least compressive forces, preferably also tensile forces. Two opposing formwork panels can be connected to each other using one or more anchors.

An example of a construction aid is scaffolding. Scaffolding can be attached to an already completed section of a structure. A stage can be attached to the scaffolding and can be moved to a desired height. The stage can be walked on. One or more formwork panels can be present on or on the stage or independently of the stage in order to form a formwork. A protective device such as a safety device can be installed on the stage. B. a railing can be attached to protect against falling.

An example of a scaffold is a climbing frame. A part of the climbing frame, for example a climbing rail, can be moved upwards and then held, in particular by means of at least one anchoring part such as. B. a climbing shoe. After completion of a concreting section, at least part of the construction aid, in particular the entire construction aid, can be pushed upwards in order to prepare a following concreting section. . Likewise, at least part of the construction aid, in particular the entire construction aid, can be lifted upwards or moved in some other way. The pushing, lifting or moving takes place with a suitable pushing device, for example hydraulically driven. This way no crane is needed for this. You can also climb down, for example to demolish at least part of a building or component. Here, a downward push and/or a downward movement due to gravity can take place. A climbing frame with additional components attached to it such as a platform, formwork panel and/or protective device is called a climbing system.

An anchoring part, for example a climbing shoe, is used to hold the scaffolding or climbing frame on the manufactured component. An anchoring part is attached to a manufactured concrete component, typically to a completed concreting section, preferably by means of at least one screw. A climbing shoe allows the construction aid to move upwards. For this purpose, a climbing shoe typically contains a mechanism that enables the construction aid to be moved upwards and/or that enables the construction aid to be held in different positions of the construction aid. A After moving, the climbing shoe holds the construction aid in the pushed-up position. Typically, each climbing rail is held with at least two climbing shoes arranged at different height positions. If a climbing shoe is no longer needed, for example because the lowest climbing shoe is arranged too low to hold the construction aid that has been moved upwards, it is removed from the manufactured component and, in particular, reattached at a higher position. This means that the climbing shoe can be used for a subsequent concreting section.

The above-mentioned features, effects and definitions can be combined individually or in a plurality with the claimed and described subjects.

The attachment of an anchoring part, e.g. B. a climbing shoe, on the manufactured component takes place at an attachment point, typically by means of a climbing cone. Fastening points are installed during the manufacture of the component and cast into the concrete. A fastening section of the anchoring part can then be screwed to the fastening point and/or the component. The exact positioning of the climbing cone in the desired horizontal position is essential for the horizontal arrangement of the stage. A deviation in the lateral position of two cones leads to constraints and to difficult to predict and possibly dangerous loads and/or deformations of the anchoring parts, the construction aid and/or the manufactured component.

The exact positioning of the climbing cone in the desired horizontal position is also essential for guided climbing. A deviation in the lateral position of two cones leads to an undesirable inclined suspension of the climbing rail. In contrast to the attachment points on the construction aid, the attachment points on the component are no longer on the same line. When climbing, constraints and the described loads and/or deformations can occur.

However, the exact positioning of the climbing cones on the desired horizontal position is hardly possible in practice due to the required precision in the millimeter range and the unavoidable inaccuracies in the concreting process. It is therefore known to subsequently correct the position of a climbing cone. To do this, the cone is removed, the opening is filled with a filling compound and then A new hole is drilled after the filling compound has hardened. This is time and labor intensive. Another solution is to design the components such as anchoring parts or construction aids with generous clearance. However, this leads to large deviations from target positions and thereby reduces the overall quality of the manufactured components.

Some anchoring parts, e.g. B. Climbing shoes, which are designed to rest on a substantially horizontal component, can have an elongated hole. In this case, the horizontal position can be adjusted slightly by loosening the screw connection on the component, moving the climbing shoe relative to the screw using an elongated hole and tightening the screw again. However, this is not possible when simply wall-mounted, as central load application is essential and otherwise twisting will occur.

In principle, another solution is also possible for anchoring parts that are designed to be attached to a substantially vertical component. Two climbing cones can be installed per attachment point, to which a rail is attached. A horizontal shift can then take place on this rail to ensure that the attachment points are aligned on a line. However, due to the double number of climbing cones, the effort and costs are significantly increased. In addition, the transfer of force in the horizontal direction is not clear.

It is the object of the invention to provide a further developed construction aid and a method for adjusting a construction aid. In particular, the disadvantages mentioned should be at least partially eliminated.

A construction aid according to claim 1 and a method for adjusting a construction aid according to the independent claim are used to solve the problem. Advantageous refinements are specified in the subclaims.

A construction aid is used to solve the problem, comprising a vertical part for fastening in a vertical orientation to a manufactured component and a horizontal part for forming a stage. The vertical part is movable laterally in relation to the horizontal part. The stage construction determines the distance between the horizontal parts. By setting a desired lateral position of the vertical part in relation to the horizontal part, the invention enables a precisely fitting position of the horizontal parts even if the distance between the vertical parts does not exactly match the distance between the horizontal parts due to deviations. Installation under constraints is avoided. Corrections to the horizontal position of climbing cones are no longer necessary. When sliding up or down, friction is reduced so that less force is sufficient for the desired movement. In some cases, a smaller hydraulic system may be sufficient.

According to the invention, the lateral movement takes place between the horizontal and vertical parts. The components of the anchoring part, e.g. B. the climbing shoe, remain in the same position relative to one another, at least in the lateral direction. This makes it possible to enter the vertical forces centrally into the anchoring part even in the event of deviations. No torque is exerted on a screw axis of the anchoring part and the anchoring part does not twist. Any torques that occur are absorbed by the climbing rail. In the case of a climbing shoe, the guidance of the vertical part, for example a climbing rail, is not influenced by the guide claws of the climbing shoe when moving between the vertical part and the horizontal part.

Directional information generally refers to a viewing direction of the surface of the manufactured component, in particular along a surface normal. A lateral movement therefore means a movement along a horizontal direction essentially parallel to the surface (direction of movement). The lateral movement is preferably a lateral displacement, in particular a linear displacement.

The vertical part is movable laterally in relation to the horizontal part. This means a relative movement between the vertical part and the horizontal part. Accordingly, the horizontal part is laterally movable in relation to the vertical part. During operation, the platform specifies the typically uniform distances between the attachment points. Deviations in the attachment points on the manufactured component result in the vertical part attached or to be attached to the component having to be moved laterally relative to the horizontal part. However, if no stage is yet formed on the horizontal part, the horizontal part is moved in relation to the vertical part. A vertical part is an elongated part that is designed to be used as intended in a vertical orientation. The vertical part is used to be attached to the manufactured component in the vertical direction. The attachment takes place in particular parallel to the surface of the component. The vertical part therefore does not necessarily have to be aligned vertically when attached, but can also be inclined in the case of inclined walls, for example at an angle of ± 30° to the vertical. This angle then corresponds to a deviation of an angle measured between the vertical part and the horizontal part from a right angle. Viewed perpendicular to any direction of inclination of the wall of the manufactured component, the vertical part is typically arranged straight. The vertical part in particular has a longitudinal extent that is at least a factor of 5 larger than a transverse extent of the vertical part.

The vertical part is part of the construction aid and serves as an attachment for the other components of the construction aid, in particular for the horizontal part, a stage and/or formwork. In particular, the vertical part or a part connected to it is designed to be held on the component and/or moved upwards in the vertical direction by means of anchoring parts such as climbing shoes. The vertical part can be or include a climbing rail. The vertical part includes in particular a support or a profile and can therefore also be referred to as a vertical profile.

The vertical part can, for example, be attached to the component with two anchoring parts. For example, a climbing shoe can serve as an anchoring part. A climbing shoe can have a fastening section for fastening to a manufactured concrete component and two guide claws for gripping around the vertical part. The climbing shoe can also have a latch device for holding the vertical part. The vertical part can be moved upwards relative to the climbing shoe, guided by the guide claws, in order to enable the construction aid to climb.

The vertical part can be or include a climbing rail head. A climbing rail head is an upper end part for a climbing rail, which can be firmly connected to the climbing rail. A climbing rail head in particular has at least a similar profile to the climbing rail and/or serves as an upward extension of the climbing rail. This enables the Climbing rail head is held by a climbing shoe and/or guided movement in relation to the climbing shoe just like with the climbing rail. If the vertical part is a climbing rail head, it is used for indirect attachment to the manufactured component, since the climbing rail is attached directly to the component and the climbing rail head is attached directly to the climbing rail. The vertical part can include climbing rail head and climbing rail.

At least two anchoring parts are in particular arranged one above the other. An upper anchoring part can be arranged approximately at the height of the horizontal part and/or can be set up to transmit horizontal forces. A lower anchoring part can be arranged under the upper anchoring part and/or at least primarily be set up to transmit vertical forces. For this purpose, a lower anchoring part can have, for example, a latch device. A vertical distance between the anchoring parts can be greater than 1 m and in particular 1.5 m and/or smaller than 5 m, in particular 3.5 m.

A horizontal part is an elongated part that is designed to be used as intended in a horizontal orientation. The horizontal part is used to form a stage. The horizontal part can be part of a stage and/or serve to rest and/or support a stage. The horizontal part can be a stage support, i.e. a support on which a stage covering such as panels or boards can be arranged directly or indirectly. The horizontal part can be a T-beam, for example. In addition, cross beams can be arranged, which can be located between the horizontal part and the stage covering or under the horizontal part and/or run perpendicular to the horizontal part. In one embodiment, the construction aid includes the stage, a railing and/or a formwork. The horizontal part projects in particular away from the wall of the manufactured component. It can have an extent perpendicular to the wall that at most corresponds to the extent of the stage measured perpendicular to the wall.

A stage is an essentially horizontal platform on which people can move to carry out work. Examples are work platforms, which make up the main work platforms and allow, for example, the adjustment and removal of the formwork, concreting platforms, which are arranged higher than work platforms and are used for concreting and/or follow-up platforms, which are arranged lower than work platforms and, for example can be used to remove anchors and/or for rework. There may be intermediate stages. Stages can be arranged across the entire width of a manufactured wall and/or all around it. In one embodiment, the construction aid comprises a stage formed by the horizontal part.

The horizontal part can also carry a railing and/or a protective device to protect against falling objects and/or include such a device.

In particular, the horizontal part is attached to the vertical part or can be attached to it. In particular, the vertical part is designed to absorb weight forces of the horizontal part, objects attached to it or located on it, the stage and/or people, as well as any loads that occur during use, such as. B. to carry wind loads.

In one embodiment, the vertical part has a support element, in particular a plurality of support elements arranged at a distance, preferably support elements arranged at regular intervals. A support element can be a bolt or a strut. A support element is designed to transfer at least a proportion of the weight of the construction aid to an anchoring part. A support element is in particular aligned essentially horizontally. In particular, the vertical part is designed to be gripped by a guide claw. In one embodiment, the vertical part has two handle sections, each of which can be gripped by a guide claw. The handle sections can be arranged parallel, in particular in one plane. A handle portion may be provided by a strap or part of a strap of a steel beam. The construction aid can typically be pushed up and held there. The gripping takes place in such a way that any lateral movement is blocked.

In one embodiment, the construction aid further has a diagonal part in order to connect the vertical part and the horizontal part to one another. Diagonal means diagonally and is not limited to a specific angle. Typically, the diagonal part has an angle between 30° and 60° to the vertical, preferably between 40° and 50°. The connection is typically spaced from a fastening area in which the horizontal part and the vertical part fasten to one another are. The diagonal part typically serves to transfer compressive forces and in particular to introduce forces from the platform into the vertical part. The diagonal part can be attached in particular to the area of the horizontal part facing away from the wall and/or to the lower area of the vertical part.

In one embodiment, the lateral movement of at least 10 mm, in particular at least 30 mm and/or at most 140 mm, in particular at most 100 mm and in one example at most 84 mm is possible. In one embodiment, the lateral movement of at least 10 mm, in particular at least 30 mm and/or at most 80 mm, in particular at most 60 mm is possible. In particular, lateral movement of approximately 40 mm is possible. This makes it possible to compensate for all commonly occurring deviations with a simple and cost-effective solution. Lateral movement that goes beyond the specified range is prevented, in particular by means of suitable stops.

In one embodiment, the vertical part can be fixed in relation to the horizontal part against lateral movement and/or in different positions. In particular, this means different horizontal positions between which the lateral movement can take place. In particular, fastening against unplanned lateral displacement can be achieved. Fixing means blocking against further lateral relative movement between the vertical part and horizontal part. In particular, what is meant is a positive fixation.

In one embodiment, the vertical part can be attached to the horizontal part in a direction perpendicular to the direction of movement. In one embodiment, the vertical part can be attached to the horizontal part in all directions perpendicular to the direction of movement.

In one embodiment, the horizontal part can be fastened to the vertical part in a form-fitting manner in all directions, in particular using a screw or a fastening means. All features mentioned in relation to the screw apply analogously to a fastener. So any relative displacement (translation) between the two parts is positively prevented. In this way, the horizontal part can be held particularly securely. In particular, rotation about one or more axes of rotation is also prevented. In particular, the horizontal part is with Exactly one screw can be attached to the vertical part, with a hollow shaft possibly surrounding the screw. The screw is aligned in particular along the direction of movement. This allows you to set an angle between the vertical part and the horizontal part in order to create non-vertical walls. The screw ensures positive connection in both directions perpendicular to the direction of movement. Spacers in particular are used to ensure positive locking along the direction of movement. The positive fastening can take place in such a way that rotation about at least one axis is possible. The at least one axis can be a longitudinal axis of the fastening means, e.g. B. the screw included.

In one embodiment, several spacers are provided. Each spacer can be arranged either on a left or right side to fix the vertical part to the horizontal part in a desired position against lateral movement in relation to the horizontal part. A spacer can be designed in the shape of a plate and can also be referred to as a lining plate. In one embodiment, spacers of different thicknesses are provided. In an alternative or additional embodiment, spacers of the same thickness are provided. In one embodiment, a large number of spacers of the same, in particular small, thickness are provided. For example, two thicker spacers, for example with a thickness of approximately 10 mm, and four thinner spacers, for example with a thickness between 1 mm and 4 mm, can be provided. Using suitable combinations of spacers, almost any position of the vertical part relative to the horizontal part can be adjusted and fixed. A spacer may have a sloped surface on at least one side to facilitate insertion. In particular, a spacer can be removed without loosening the fastening of the vertical part relative to the horizontal part.

In particular, there are two gaps between the vertical part and the horizontal part along the direction of movement, a right gap and a left gap. Preferably, the vertical part is in two parts and at least a region of the horizontal part is arranged between the two parts of the vertical part, so that there is a gap between each part of the vertical part and the horizontal part. The vertical part can be moved to the desired position relative to the horizontal part. Then in a space or One or more spacers can be arranged in both spaces. If the vertical part is pushed all the way to the right, the right-hand space may no longer be present, so that it is impossible to move the vertical part further to the right, and the left-hand space may be at its maximum size. Then suitable spacers can be placed in the left gap to prevent the vertical part from shifting to the left and to fix the vertical part in the desired position. If a position is desired that lies between the far right and the far left position, spacers in particular can be used in both spaces

In one embodiment, a securing part is provided with which the spacers arranged on the right and/or left side can be held in position. In particular, what is meant is a positive hold, so that unplanned removal of the spacers is reliably prevented. The securing part can be, for example, a securing bolt. The securing bolt can be arranged parallel to the direction of movement. The spacers can have a recess with which they can be pushed onto locking bolts. Alternatively or additionally, the spacers can have through holes and/or the securing bolt can be removable in the axial direction, so that the spacers are held in a form-fitting manner in all directions perpendicular to the axis of the securing bolt. The safety bolt can have a handle for manual handling and/or can be secured with a safety pin.

In one embodiment, a guide element is present which enables a guided movement of the vertical part in relation to the horizontal part. This allows the lateral movement to be guided. In particular, the guide element or at least one guide surface or guide edge of the guide element is aligned along the direction of movement. In particular, there is a further element on the vertical part and/or on the horizontal part, which contacts the guide element and is movable relative to it, so that the guided movement is possible in this way.

There can be a through opening in the horizontal part and/or in the vertical part and the guide element can run through the at least one through opening, so that a guided relative movement between the vertical part and the horizontal part is made possible. The guide element can be part of the vertical part or of the horizontal part. In particular, however, the guide element is a separate component and there are respective through openings for the guide element in both the vertical part and the horizontal part. The guide element is therefore displaceable in the vertical part and in the horizontal part. In particular, the guide element is a separate part from the securing bolt. The guide element can be, for example, a bolt. The guide element or the bolt can be designed as a hollow shaft to enable a smaller bolt to be passed through.

In one embodiment, the guide element is secured by two stops against, in particular, axial displacement beyond respective external positions. Axial displacement means displacement along the lateral direction of movement. A first stop can be made in one piece with the guide element. A second, for example disk-shaped stop can have been firmly connected to the guide element, for example by soldering or welding. In one embodiment, the guide element is secured in its position by two stops. The guide element cannot therefore fall out of its position or be lost.

The guide element can have a length greater than 30 mm, in particular greater than 45 mm and/or less than 100 mm, in particular less than 75 mm. In one embodiment the length is approximately 60 mm. This enables a particularly compact design and yet sufficient mobility for most applications.

In one embodiment, the guide element and one of the vertical part and the horizontal part are set up so that a rotation of the guide element leads to a lateral movement of the one of the vertical part and the horizontal part relative to the guide element. In particular, the guide element is elongated and the rotation is a rotation about the longitudinal axis of the guide element. For example, the guide element is a screw or a bolt. For example, the guide element and the vertical part or the horizontal part have a thread, which interact accordingly. Instead of a thread, one of the interacting parts can also simply have form elements that are coordinated with the thread. In this way, the displacement between the horizontal part and vertical part can be carried out particularly easily and without additional parts. In one embodiment, the guide element has a recess in the axially central region. The recess is not present, particularly in the end regions of the guide element. In particular, respective edges or surfaces in end regions of the guide element, which delimit the recess, serve as a stop. The recess defines the range of motion. In particular, through openings in the horizontal part and/or in the vertical part are shaped in such a way that they are displaceable in the area provided with the recess, but not in the area that does not have a recess. In this way, the guide element is held captively and lateral movement is limited. This design makes this possible with minimal space requirements, since no part protrudes beyond the guide element and the end regions without the recess require a maximum length of a few millimeters in the axial direction. This is particularly advantageous due to the reduced space available due to the vertical part. In particular, the guide element is captively secured to the horizontal part in this way. In particular, the guide element moves together with the vertical part during the movement according to the invention.

The recess can have the shape of a circular segment, particularly in the case of an externally circular cross section of the guide element. Instead of a circular arc, a circular chord then limits the outer cross section in the area of the recess. Such a recess can also be referred to as a gate.

In one embodiment, the guide element is designed as a hollow shaft. In particular, a screw is arranged inside the guide element. The screw runs lengthwise through the hollow shaft. The screw is used to attach the horizontal part to the vertical part. The screw is supported by the guide element. The screw in particular has a head which is located on an end face of the guide element. The screw is secured in particular with a nut which is located on the opposite end face of the guide element. In this way, a particularly secure attachment is possible.

In one embodiment, the vertical part has two side walls. In particular, an area of the horizontal part is located between the side walls of the vertical part. A side wall is a wall part arranged laterally. The side wall can limit the vertical part laterally at least in some areas. For example, a flange of a steel profile can represent the side wall. On In this way, the area of the horizontal part is movable laterally between the two side walls. In particular, the two side walls serve as stops and thus as a limit for the relative movement. In this way, movement can be limited particularly safely.

In one embodiment, the construction aid is set up to accommodate a pressing mechanism by means of which pressure can be exerted on the horizontal part or the vertical part in order to cause the vertical part to move laterally in relation to the horizontal part. The pressing mechanism is a separate part that can be picked up by the construction aid. The construction aid can include the pushing mechanism. The push mechanism is only needed when it is to be used. Typically only one pressing mechanism is necessary for the entire construction aid. A separate aspect of the invention is a system consisting of several construction aids, in particular according to the invention, and only one pressing mechanism or at least a number of pressing mechanisms that is less than the number of construction aids. The pushing mechanism can be used with any of the construction aids.

In other words, a force can be exerted from the vertical part or the horizontal part to the other part in order to displace the other part relative to the vertical part or horizontal part. In particular, the pressing mechanism has a movable pressing element for this purpose. Basically, the pushing mechanism serves to overcome friction that occurs when pushing the vertical part. In particular, if a stage and/or other structures are already attached, friction occurs during the relative movement according to the invention between the horizontal part and the vertical part, which can be easily overcome in this way. In this way, the relative movement can be carried out particularly easily. In particular, it is made possible for the relative movement to also take place under load, i.e. e.g. B. with a stage arranged. This means that the position can be subsequently corrected as soon as a deviation from the target position is apparent.

In one embodiment, a height adjustment device for a climbing shoe can be used as a pressing mechanism for adjusting a height position of a latch device of the climbing shoe in relation to an attachment section of the climbing shoe. The construction aid is then set up so that the height adjustment device can be accommodated and z. B. using a screw The height adjustment device can be used to exert pressure on the horizontal part or vertical part. A height adjustment device has one or more support areas for resting on one or more support surfaces of the climbing shoe.

In one embodiment, a through hole is present in a wall of the vertical part and/or a receptacle for inserting the pressing mechanism is arranged on the outside of the vertical part in the area of the through hole. In particular, pressure can be exerted on the horizontal part through the through hole by means of the pressing mechanism in order to displace the horizontal part relative to the vertical part.

The pressing mechanism is suitable for being inserted into the receptacle and for exerting pressure on the horizontal part through the through hole by means of a pressing element. Inserting into the receptacle means positioning in such a way that the pressing mechanism is at least secured against falling down. In particular, the pressing mechanism is held in the receptacle in such a way that a counterforce that arises as a result of the pressing force on the pressing element is counteracted. In other words, the receptacle supports the pressing mechanism in such a way that it cannot be moved counter to the pressing direction. Alternatively, the pressing mechanism can have a gripping element behind, with which a part of the vertical part can be gripped behind for this purpose.

The pressing mechanism may include a screw that can be screwed into a main body and that can protrude through the through hole as a pressing member and apply the pressure. Screwing allows the vertical part to be moved comparatively easily with little effort and therefore easy to handle. The screw holds the pressing mechanism in place in relation to the through hole so that it does not shift unplanned when pressed.

The receptacle can be U-shaped, for example, to enable easy insertion of the pressing mechanism. The receptacle can be designed in such a way that a space is created in the lateral direction between the receptacle and the outside of the vertical part, into which a part of the pressing mechanism can be hung so that it is secured against lateral displacement. A further aspect of the invention is a method for adjusting a construction aid, in which a vertical part for fastening in a vertical orientation to a manufactured component is moved laterally in relation to a horizontal part to form a stage. This can be done under the pressure of a pressing element. The adjustment is carried out in particular with the aim of compensating for a horizontal positional deviation of an attachment point in the manufactured component. All features, advantages and effects of the construction aid described above can apply to the process and vice versa.

Exemplary embodiments of the invention are explained in more detail below using figures. Features of the exemplary embodiments can be combined individually or in a plurality with the claimed subjects, unless otherwise stated. The claimed areas of protection are not limited to the exemplary embodiments.

Show it:

Figure 1: a side view of a construction aid,

Figure 2: a perspective detail of a construction aid in use,

Figure 3: a top view of a construction aid in use with a first

position of the horizontal part,

Figure 4: a top view of a construction aid in use with a second

position of the horizontal part,

Figure 5: a top view of a construction aid during adjustment, as well

Figure 6: a sectional view of the construction aid from Figure 5.

Figure 1 shows a construction aid 10 according to the invention in use. The construction aid 10 comprises a vertical part 11, a horizontal part 12, a stage 14 constructed using the horizontal part 12 and a railing 18 which is attached to the stage and/or the horizontal part 12. The vertical part 11 and the horizontal part are connected to one another at their intersection point. The construction aid 10 further comprises a diagonal 17 which connects sides of the vertical part 11 and the horizontal part 12 that project away from the crossing point, so that a triangular basic structure is created.

The vertical part 11 is with an anchoring part 15, namely a climbing shoe 16, in vertical alignment on a manufactured component 19, here an example Concrete wall, fixed. The climbing shoe 16 transmits in particular horizontal forces of the construction aid 10 into the component 19 and typically no or only a small amount of vertical forces. Vertical forces of the construction aid 10 are transferred to the component by means of the lower anchoring part 15, which can also be a climbing shoe.

Figure 2 shows an enlarged detail of the connection of vertical part 11 and horizontal part 12, in particular of the construction aid from Figure 1, from diagonally above. A wall element 13 is screwed to the wall and serves as a holder for the climbing shoe 16. The climbing shoe 16 includes two guide claws 20 which hold and guide the vertical part 11 in such a way that it can be moved in the vertical direction. In this way, climbing a climbing formwork can be realized. The vertical part 11 includes support elements 21 arranged at regular intervals, by means of which a latch and/or latch device of the climbing shoe 16 can hold the vertical part 11. The vertical part 11 is a climbing rail or a climbing rail head and/or comprises two supports arranged opposite one another and/or connected to one another by means of horizontal support elements and/or vertically aligned.

A lateral relative movement along the direction of movement 25, in particular parallel to the manufactured surface of the component 19 and/or in the horizontal direction, is possible between the horizontal part 12 and the vertical part 11. The movement is possible in particular by approximately 40 mm, for example 20 mm to each side. There is a guide element 23 in the form of a hollow shaft 24, which is arranged to be movable in relation to the horizontal part 11 and/or the vertical part 12. The guide element 23 enables a guided displacement of the vertical part 12 in relation to the horizontal part 11 along the longitudinal axis of the guide element 23. The guide element 23 has a length that extends a few millimeters beyond the distance between the outer surfaces of the supports of the vertical part 11. The guide element 23 is secured against axial displacement beyond the ends by means of two stops in the areas of the guide element 23 near the ends.

The horizontal part 12 is fastened to the vertical part 11 by means of a screw 22 in such a way that a translational relative movement of the horizontal part 12 in relation to the vertical part 11 is positively blocked in any direction. Rotation around two axes is also blocked. Only the rotation about a horizontal axis axially through the Screw 22 may be possible. An area 31 of the horizontal part 12 is located in the region of the screw 22 between two side walls 30 of the vertical part 11. The screw 12 runs lengthways through the hollow shaft 24. The side walls are central areas or webs of steel profiles, in particular of II(UNP) or UPE profiles.

The position shown of the horizontal part 12 in relation to the vertical part 11 is an approximately central position. A distance between the area 31 of the horizontal part 12 and the left side wall 30 of the vertical part 11 is approximately the same as the corresponding distance from the right side wall 30. There are one or more spacers 26 on the left side 27 between the area 31 and the left side wall 30. Between the area 31 and the right side wall 30 there are one or more spacers 26 on the right side 28, the total thickness of which corresponds to the one or more spacers 26 on the left side 27. In this way, a relative displacement along the direction of movement 25 is blocked in both directions in a positive manner.

Figure 3 shows a comparable relative position of vertical part 11 and horizontal part 12 in a top view. It can be seen that in the central position shown, the center line of the vertical part 41 and the center line of the horizontal part 42 lie one above the other. Furthermore, it can be seen that here, for example, only one spacer 26 is arranged on each side 27, 28. The spacers 26 are held in position with a securing part 29 designed as a bolt.

Figure 4 shows the same construction aid 10, but here the horizontal part 12 is pushed laterally to the right in relation to the vertical part 11. The center line of the vertical part 41 and the center line of the horizontal part 42 fall apart. In particular, the horizontal part 12 is in its rightmost position in relation to the vertical part 11. There are one or more spacers 26 only on the right side 27 (corresponds to the side shown on the left in FIG. 4). The information “left” and “right” refer to a viewing direction perpendicular or along the surface normal to the surface of the manufactured component 10 (see Fig. 2). For this reason, the directions shown in Figures 3 to 6 are reversed. Any inaccuracy in the position of the anchor point in the manufactured wall can be easily compensated for. Figure 5 shows a similar top view to Figure 3. It is also a pressing element

37 is present, which is anchored in the vertical part 11 and presses against the horizontal part 12 from the left in order to move it to the right. The pressing element 37 is a screw with which sufficient force to carry out the relative movement can be easily generated by turning. The pressing element is

Part of a pressing mechanism, not shown in Figure 5, which is anchored on the vertical part 11.

Figure 6 is a sectional view of Figure 5 taken along the line shown in Figure 5. It can be seen that in both walls 32 of the vertical part 11, namely both side walls 30, there is a receptacle 36 for inserting the pressing mechanism

38 is available. Adjacent to the receptacle 36 there is a through hole 35 running along the direction of movement 25. The pressing mechanism 38 comprises a main body 39 and a pressing element 37 in the form of a screw which can be screwed into the main body 39. The main body 39 is supported on the receptacle 36 in such a way that by screwing the screw, a force is exerted by the vertical part 11 on the

Horizontal part 12 can be exercised. The tip of the screw then presses against the area 31 of the horizontal part 12 and pushes the horizontal part to the right.

Reference symbol list

Construction aids 10

Vertical part 11

Horizontal part 12

Wall element 13

Stage 14

Anchoring part 15

Climbing shoe 16

Diagonal 17

Railing 18

Component 19

Guide claw 20

Support element 21

Screw 22

Guide element 23

Hollow shaft 24

Direction of movement 25

Spacer 26 left side 27 right side 28

Safety part 29

Side wall 30

Area 31

Wall 32

Through hole 35

Recording 36

Pressing element 37

Push mechanism 38

Main body 39

Center line of the vertical part 41

Center line of the horizontal part 42

Claims

Expectations

1. Construction aid (10), comprising a vertical part (11) for fastening in a vertical orientation to a manufactured component (19) and a horizontal part (12) for forming a stage (14), the vertical part (11) being laterally relative to the horizontal part (12) is movable.

2. Construction aid (10) according to the preceding claim, characterized in that the lateral movement of at least 10 mm, in particular at least 30 mm and / or at most 140 mm, in particular at most 100 mm is possible.

3. Construction aid (10) according to one of the preceding claims, characterized in that the vertical part (11) can be fixed in different positions in relation to the horizontal part (12) against lateral movement.

4. Construction aid (10) according to the preceding claim, characterized in that the horizontal part (12) can be fastened to the vertical part (11) in a form-fitting manner in all directions, in particular using a screw (22).

5. Construction aid (10) according to one of the two preceding claims, characterized in that a plurality of spacers (26) are provided, each spacer (26) being able to be arranged either on a left side (27) or a right side (28), in order to fix the vertical part (11) in a desired position against lateral movement in relation to the horizontal part (12) on the horizontal part (12).

6. Construction aid (10) according to the preceding claim, characterized in that a securing part (29) is provided with which the arranged spacers (26) can be held in position.

7. Construction aid (10) according to one of the preceding claims, characterized in that a guide element (23) is present which enables a guided movement of the vertical part (11) in relation to the horizontal part (12).

8. Construction aid (10) according to the preceding claim, characterized in that the guide element (23) is secured by two stops against displacement beyond respective external positions.

9. Construction aid (10) according to one of the two preceding claims, characterized in that the guide element (23) and one of the vertical part (11) and horizontal part (12) are set up so that a rotation of the guide element (23) results in a lateral movement one of the vertical part (11) and horizontal part (12) leads relative to the guide element (23).

10. Construction aid (10) according to one of the two preceding claims, characterized in that the guide element (23) has a recess in the axially central region, the recess not being present in end regions of the guide element (23) and respective edges or surfaces in end regions of the guide element (23), which limit the recess, serve as a stop.

11. Construction aid (10) according to one of the four preceding claims, characterized in that the guide element (23) is designed as a hollow shaft (24) and a screw (22) is arranged inside the guide element (23).

12. Construction aid (10) according to one of the preceding claims, characterized in that the vertical part (11) has two side walls (30) and a region (31) of the horizontal part (12) is between the side walls (30) of the vertical part (11). located.

13. Construction aid (10) according to one of the preceding claims, characterized in that the construction aid (10) is set up to accommodate a pressing mechanism (38) by means of which pressure can be exerted on the horizontal part (12) or the vertical part (11). to cause the movement of the vertical part (11) laterally in relation to the horizontal part (12).

14. Construction aid (10) according to the preceding claim, characterized in that in a wall (32) of the vertical part (11). Through hole (35) is present and on the outside of the vertical part (11) in the area of the through hole (35) a receptacle (36) for inserting the pressing mechanism (38) is arranged, so that by means of the pressing mechanism (38) through the through hole (35) a pressure can be exerted on the horizontal part (12) to move the horizontal part (12) relative to the vertical part

(11) to move. Method for adjusting a construction aid (10), in which a vertical part (11) for fastening in a vertical orientation to a manufactured component (19) is moved laterally in relation to a horizontal part (12) to form a stage (14).