WO2018134180A1

WO2018134180A1 - Pillar with load-branching nodes and adjustable run-out angle

Info

Publication number: WO2018134180A1
Application number: PCT/EP2018/050943
Authority: WO
Inventors: Michael BRÜGGENBROCK; Andreas Cott; Stephan Drewes; Lothar Patberg; Marcus Rauhut; Ingo Rogner; Ralf Stegmeyer; Klaus Plaumann
Original assignee: Thyssenkrupp Steel Europe Ag; Thyssenkrupp Ag
Priority date: 2017-01-17
Filing date: 2018-01-16
Publication date: 2018-07-26
Also published as: CN110177910A; EP3571353A1; DE102017200671A1; US20190376244A1

Abstract

The invention relates to a pillar (1) comprising a shaft (2), a branching node (3) which is provided at the upper end of the shaft, and at least two cantilever arms (4), each of which is connected to the branching node at one end and supports the superstructure (5) at the other end. The invention is characterized in that the branching node (3) comprises a coupling surface (31) and a number of cantilever arm attachments (32), said number corresponding to the number of cantilever arms (4), and the cantilever arm attachments (32) are arranged such that the central axes of the cantilever arm attachments (32) and the shaft (2) meet in a common intersection.

Description

description

Pillar with lastverzweiqendem node and adjustable outlet angle Technical Field (Technical Field)

In construction, pillars have long been known for supporting higher-level construction elements. Usually, these are carried out in the form of columns, which have a uniform cross-section or a suit, ie a taper, from the base to the superstructure. For the support of superstructures with extensive extension a load-split structure with increased span is necessary, which directs forces from a larger area on the pillar, if the superstructure is not self-supporting or dynamic loads occur. For this purpose, the use of crossbars or Auflagerbalken, especially in conjunction with several columns or the use of truss structures is common. Technical Background (Background Art)

From CN 102259166 A, a spherical casting node is known in which a plurality of attachment flanges are distributed over the surface to allow the connection of struts. This casting node is intended in particular for use in truss constructions. The disadvantage here, however, the costly production and the inflexible design, so the lack of possibility to make later adjustment to the positioning, size and number of Anbindungsflansche, since the angle and positions may be different depending on the version of each application.

Summary of Invention

The invention is therefore based on the object to provide a pillar, which has an enlarged span and is flexibly adaptable to the circumstances of the particular application. Another object of the invention is to achieve the aforementioned object with identical or similar components as possible and the smallest possible space requirement. Side tasks are an aesthetic appearance and cost manufacturability.

This object is achieved by a free pillar, hereinafter also generally referred to as a pillar, with the features of claim 1. According to the invention, a free pier with a shank, a branching node provided at the upper end of the shank and at least two cantilevers each connected at one end to the branching node and carrying the superstructure at the other end, is characterized in that the branching node has a branching point Dome surface and a number of cantilevers corresponding number of Kragarmanbindungen comprises, and that the Kragarmanbindungen are arranged such that the center axes of the Kragarmanbindungen and the shaft meet at a common point of intersection. By such a configuration, a relatively filigree appearance of the pillar structure can be achieved, especially when using steel as a material. Thus, only a relatively small footprint is required and it arises, especially in conjunction with a corresponding also relatively filigree superstructure, only a little shading of the underlying areas.

Preferred embodiments of the pillar are characterized in that the dome surface has a shape which is symmetrical at least to a plane passing through the central axis of the shaft symmetry plane or rotationally symmetrical to the central axis of the shaft. This creates shapes, such as pyramids, cones and domes, which allows a correspondingly symmetrical arrangement of the cantilevers or the Kragarmanbindungen. The symmetrical structure around the center axis improves the force transmission to the shaft, whereby the power flow can be optimized. Depending on the design and the design requirements, the shapes of the dome surface may have rounded edges and / or z. B. be designed as a pyramid or truncated cone. With this training, the areas are simplified, with which the Kragarmanbindungen are connected to the dome surface. In the case of, for example, ellipsoidal dome surfaces, a 3D trimming may nevertheless be necessary.

A particularly preferred embodiment of the pillar is characterized in that the dome surface is formed substantially in the form of a spherical segment, and that the Kragarmanbindungen are connected via annular surfaces with the dome surface, whereby the common intersection of the central axes lies in the center of the spherical segment. By appropriate 3D trimming instead of the simple pipe sections, of course, embodiments are possible in which the outlet angle of the cantilevers relative to the dome surface can be set different. The spherical segment is a special form of rotationally symmetrical design of the dome surface, can be used as a Kragarmanbindungen simple pipe sections and the outlet angle of Kragarmanbindungen based on the shaft can be set arbitrarily, at the same time an alignment of the central axes is guaranteed. It is preferred here that the segment height is less than or equal to the radius, particularly preferably less than or equal to half the radius of the dome surface. In order to arrange the at least two Kragarmanbindungen on the dome surface, without having to be connected directly to each other, the minimum height of the ball segment must meet the following condition, however, where h _K for the height of the ball segment, r _K for the radius of the ball segment and d _A for the diameter of the cantilever connection on the dome surface is:

hK ^~ 2 xr _K

In a further preferred embodiment of the invention, the dome surface is produced by a forming process from a steel sheet. Corresponding methods for forming steel sheets are known per se to the person skilled in the art. The advantage of this preferred embodiment is that correspondingly produced dome surfaces have substantially more constant wall thicknesses than, for example, dome surfaces produced by cast steel.

In a further preferred embodiment of the invention, the dome surface is located in the upper region of the branching node and comprises the connections to the cantilever arms completely. In a further preferred embodiment of the invention, the dome surface is curved upwards and outwards.

In further embodiments of the invention, the pillar is characterized in that the cantilevers are connected by means of screw flanges with the Kragarmanbindungen. Depending on the span and the ratio of shaft height and overall height of the pier, long cantilevers may be necessary. In order to simplify the assembly and alignment of the cantilever connections to the dome surface here, these are formed separately from the cantilevers. The connection of the cantilevers with the

Kragarmanbindungen is then via screw flanges, in particular internal flanges, for which, if necessary, a mounting opening must be provided on at least one of the two components.

In alternative embodiments to the aforementioned, especially at relatively low pillar heights, the pillars are characterized in that the Kragarmanbindungen are integrally formed with the cantilevers. As a result, the number of parts is reduced, which reduces the transport and manufacturing costs.

Further embodiments of the pillar are characterized in that the branching node comprises a transition, wherein the dome surface is connected by means of the transition to the shaft, and wherein the transition between different diameters and / or cross-sectional shapes of the shaft and the dome surface compensates. With regard to the design, generally the same cross-sectional shapes of the shaft and the dome surface are preferred, usually round or with a polygonal cross-section, although the diameters may differ, in this case in the application with diameter as a designation also the appropriate dimension, such as edge length, Um-, Inkreis etc. are included in polygons. Different diameters can be provided, for example, due to the space required on the dome surface for the Kragarmanbindungen, if sufficient for the shaft, a smaller diameter for the support load.

In embodiments of the pillar with transition, the pillar may be characterized in that the transition has a continuously varying diameter and / or cross section. For round cross sections, conical transitions, for example, which extend the shaft diameter upwards to the diameter of the dome surface, are created for this purpose. Alternatively, the transition can also be designed to produce a mushroom-shaped appearance as a solid flat plate or from the upper shaft end downwardly directed cone.

Embodiments of the pillar are characterized in that the parts of the branching node are welded together. When using steel as a material for the components of the pillar, these are preferably welded together, in particular the parts of the branching node can be connected to form an assembly, whereby the transport and assembly costs can be reduced.

For reinforcement, in embodiments of the invention, pillars may be characterized in that bulkhead plates are provided in the branching node. In particular, with larger diameters so the rigidity of the components can be improved without increasing the wall thicknesses.

Embodiments of the pillar are characterized in that the cantilevers are designed as a tube with a constant or conical cross section. The easiest and most cost-effective way of manufacturing the cantilevers is to produce tubes of constant diameter. Due to the force curve and in view of the design also conically tapered cantilever arms are sufficient, which at the same time enable weight savings.

Embodiments of the pillar according to the invention are characterized in that the cantilevers are bent or 3D-shaped. Mainly for design reasons or to ensure certain clearances, such as clearance height on a certain width of the span between two pillars, the cantilevers can also have a curved course. Under 3D-shaped cantilevers cantilevers are understood to be deformed whose central axis over the length of the cantilever in more than one direction.

Pillars of embodiments according to the invention are characterized in particular in that the shaft is designed as a spiral seam welded tube. As a result, just any diameter and tube lengths are possible, which allow a constant or conical cross-sectional profile. In a further preferred embodiment of the invention, the outline of the center line of at least two cantilevers is not parallel to the floor plan of the carriageway centerline of the bridge structure.

Short description of the drawings (Brief Description of Drawings)

In the following the invention will be explained in more detail with reference to schematic drawings, wherein similar components are provided with the same reference numerals. In detail show:

Fig. 1 shows a pillar in an embodiment of the invention,

Fig. FIG. 2 is another view of the upper part of the embodiment of FIG. 1; FIG.

Fig. 3 shows an alternative embodiment of the invention analogous to FIG. 2,

Fig. 4 shows an embodiment of the lower parts of a pillar according to the invention,

Fig. 5 shows a further embodiment of the lower parts of a pillar according to the invention,

Fig. 6 shows a further embodiment of the lower parts of a pillar according to the invention, including cantilever connections,

Fig. Fig. 7 shows an exemplary use of columns according to the invention in a bridge.

Description of the Preferred Embodiments (Best Mode for Carrying Out the Invention)

Fig. 1 shows a perspective view of a free pillar (1) according to the invention in an embodiment with four cantilever arms (4), which have a conical basic shape and are slightly bent. These cantilevers (4) are connected by means of screw flanges (6) with the branching node (3), which will be explained in more detail in the following figures. The branching node (3) adjoins a shaft (2) at the top at the top.

Fig. 2 shows a branching node (3) and parts of the cantilever arms (4) according to FIG. 1. Here, the cantilever arms (4) are connected by means of screw flanges (6) to a respective cantilever connection (32) which are connected to a coupling surface (31) has a curvature upwards. At the edge of the dome surface (31), a transition (33) closes down, the lateral surface tapers conically downwards in the direction of the shaft (2), not shown. In Fig. 3 is an alternative embodiment to that shown in FIG. 2 shown variant. The structure with respect to the cantilever arms (4) via the screw flanges (6) and the Kragarmanbindungen (32) to the coupling surface (31) are identical. However, the transition (33) smaller diameter, so the transition (33) is not connected to the edge but the inside of the dome surface (31). As a further difference, the transition (33) tapers conically to a smaller diameter compared to the shank (2), which is not shown. To compensate for this difference in diameter, the transition (33) has a connecting plate adjoining the cone.

Fig. 4 and FIG. 5 each show the lower components of various embodiments. Common to these embodiments is that the shank (2) extends from bottom to top and at the top of a conical transition (33) is provided which widens to the diameter of the dome surface (31). The dome surface (31) is in each case formed as a spherical segment. Due to the design as spherical segments can be used for the Kragarmanbindungen not shown (32) pipe sections with a circular cross-section.

The difference is that in FIG. 4 the dome surface (31) represents a hemisphere, thus thus the height of the ball segment or the dome surface (31) corresponds to the radius of the ball segment. In this way, a relatively large dome surface (31) is provided which provide corresponding space for an arrangement for the Kragarmanbindungen (32) and at the same time, in particular for large spans, allow a large outlet angle between Kragarmanbindung (32) and the central axis of the shaft (2) ,

In contrast, in Fig. 5, the height of the ball segment is less than the radius of the ball segment. This forms a coupling surface (31) which is formed significantly flatter, whereby a smaller outlet angle between Kragarmanbindung (32) and central axis of the shaft (2) is formed, which improves the flow of force in the components.

FIG. 6 shows a shaft (2) of a pillar (1) according to the invention, at the upper end of which the dome surface (31) adjoins directly. In this embodiment, no transition (33) is provided. The dome surface (31) here has a symmetrical structure to the perpendicular to the plane of representation through the central axis of the shaft (2) extending plane and is designed for two Kragarmanbindungen (32). As shown, the center axes of the Kragarmanbindungen (32) and the shaft (2) meet in one point. The position of this point on the central axis of the shaft (2) can in this embodiment by changing the height of the shown in the view triangular cross section of the dome surface (31) and / or a different angle of the surfaces of the Kragarmanbindungen (32) for connection to the Dome surface (31) can be changed, whereby the power flow in the pillar is changeable. Fig. 7 illustrates an exemplary use of pillars (1) according to the invention by means of a bridge as superstructure (5). In this example, the pillars (1) support the superstructure (5) in that a shaft (2) extends from the floor upwards and branched at the branching node (3) in the cantilevers (4). The cantilever arms (4) branch to allow a larger contact surface or span and are connected to the superstructure (5).

The various features of the invention can be combined with one another as desired and are not limited to the described or illustrated examples of embodiments.

LIST OF REFERENCE NUMBERS

1 (free) pillar

2 shaft

3 branch nodes

31 dome area

32 cantilever connection

33 transition

4 cantilever

5 superstructure

6 screw flanges

Claims

claims

1. free pillar (1) with a shank (2), provided at the upper end of the shaft branch node (3) and at least two cantilevers (4), which are each connected at one end to the branching node and at the other end of the superstructure (5 ) wear,

characterized in that the branching node (3) comprises a coupling surface (31) and a number of cantilever arms (4) corresponding number of Kragarmanbindungen (32), and that the Kragarmanbindungen (32) are arranged such that the central axes of Kragarmanbindungen ( 32) and the shaft (2) meet in a common point of intersection.

2. pillar (1) according to claim 1, characterized in that the dome surface (31) has a shape which is at least symmetrical to a plane passing through the central axis of the shaft (2) symmetry plane or to the central axis of the shaft (2) rotationally symmetrical.

3. pillar (1) according to any one of the preceding claims, characterized in that the

Dome surface (31) is formed substantially in the form of a spherical segment, and that the Kragarmanbindungen (32) are connected via annular surfaces with the dome surface (31), whereby the common intersection of the central axes lies in the center of the spherical segment.

4. pillar (1) according to one of the preceding claims, characterized in that the

Cantilevers (4) by means of screw flanges (6) with the Kragarmanbindungen (32) are connected.

5. pillar (1) according to one of claims 1 to 3, characterized in that the

Kragarmanbindungen (32) are integrally formed with the cantilever arms (4).

6. pillar (1) according to any one of the preceding claims, characterized in that the

Branching node (3) comprises a transition (33), wherein the coupling surface (31) by means of the transition (33) with the shaft (2) is connected, and wherein the transition (33) between different diameters and / or cross-sectional shapes of the shaft (2 ) and the dome surface (31) compensates.

7. pillar (1) according to claim 6, characterized in that the transition (33) has a continuously changing diameter and / or cross-section.

8. pillar (1) according to any one of the preceding claims, characterized in that the parts of the branching node (3) are welded together.

1

9. pillar (1) according to one of the preceding claims, characterized in that in

Branching node (3) bulkhead plates are provided.

10. pillar (1) according to any one of the preceding claims, characterized in that the

Cant arms (4) are designed as a tube with a constant or conical cross-section.

11. pillar (1) according to claim 10, characterized in that the cantilever arms (4) are bent or 3D-shaped.

12. pillar (1) according to any one of the preceding claims, characterized in that the shaft (2) is designed as a spiral seam welded pipe.

2