DE29716084U1 - Arrangement for fastening hanging pipelines - Google Patents

Description

Arrangement for fastening hanging pipes

The invention relates to a system for fastening hanging pipelines, which are fastened in particular to inclined trusses, a ceiling following the roof slope and/or the like and, as is usual in the field of industrial and power plant pipelines, have larger dimensions.

It is known to hang pipe clamps on threaded rods that can also act on two levels, as described in DE-OS 39 36 198. Since these are also subject to wind loads, structural movements, thermal stresses and the like in the transverse direction to the pipe axis, an almost immovable rigid fixed point for hanging such pipes is problematic in practice. There has therefore been no lack of attempts to reduce these movements by means of a relative mobility of the suspension and/or to transfer forces to the supporting structure via a correspondingly statically favorable design. This particularly applies to transverse forces that arise due to wind loads introduced into the system, which can be converted into bending forces and act on the fastening points.

DE-PS 30 44 008 describes a solution in which the pipeline is suspended via a vertically divided pipe clamp and a bolt attached to the flange, so that in the event of excessive stress, a relative mobility in the longitudinal axis of the pipeline is effective in the system. High-

horizontal movements across the central axis insofar as these must be absorbed by the supporting structure. The same applies to the solution described in DE-OS 36 21 484. This is one of the reasons why this led to the solution according to DE-OS 2 923 530. According to the solution proposed there, the suspension is at a single point via elastic links.

A particular feature of these solutions is that they require extensive assembly work. This is a hindrance when building longer suspended pipeline sections and makes such projects more expensive.

According to DE-Gm 94 20 235, a pendulum support is therefore proposed in which a threaded rod, which is usually used to suspend pipes, enables constant pendulum movement. In this case, all static forces must be absorbed by the fastening points of the pendulum support.

Another solution therefore provides for the use of an element consisting of two U-shaped components inserted into one another in opposite directions and screwed together several times as an intermediate element when hanging on the supporting structure. Here, a high level of assembly work is required due to the multiple screw connections. Other solutions that work with screw connections that overlap transversely and longitudinally to the pipeline axis, in which counter elements in the form of nuts are also used for securing, are also common.

The object of the invention is therefore to develop a suspension for hanging pipelines in which static and dynamic transverse forces are equally absorbed by an appropriate design of the arrangement for suspending the pipeline and introduced into the supporting structure and

the assembly effort is further reduced while improving the creep strength of the individual components.

The problem is solved by the pipe to be suspended having a pipe clamp at the suspension point, which has a flange eye on each side in the area of the largest diameter of the pipe. This is already the case with a horizontally divided pipe clamp. However, to make assembly easier, the solution according to the invention is based on a vertical division of the pipe clamp and on the arrangement of a further suspension point on both sides of the pipe clamp in the form of a further flange eye, which has a downward-pointing radius at the end and is slotted in the longitudinal axis. The tangent applied to the respective radius of the flange eye forms a right angle with the suspension elements arranged on the supporting structure at the same or greater distance from one another.

In order to allow relative mobility of the suspension elements used for suspension, the respective through-hole in the flange eyes is at least slightly larger than the diameter of the suspension element passing through or even widened in the bending direction.

Standard threaded rods or other elements fitted with appropriate adapters, such as appropriately trimmed flat profiles or the like, can be used as suspension elements.

If lateral support of the system is also required, an angle piece is attached to the flange eye facing a wall, other trusses or similar attachment points, in which a tension and compression strut

suitable component and the pipeline is arranged horizontally relative to this fastening point.

Furthermore, the two suspension elements are supported at their upper fastening points in inclination compensators. According to the invention, these consist of flat material, which of course in principle has a cross-section suitable for the necessary load bearing. These inclination compensators are designed with their longitudinal extension transverse to the center axis of the pipeline to be suspended and each have two fastening points for fastening to the supporting structure. Starting from the course of a fixed point, designated as the first fastening point, the flat material is then bent downwards at an angle almost at a right angle, with the preferred solution providing a bend of 75 degrees. Following the further course, the bend then continues evenly curved with a radius that corresponds to several times the material thickness of the flat material back into a straight line that is parallel to the imaginary projected continuous edge that forms the suspension surface. This creates a circular path section in the area of the curve and facing the supporting structure.

After reaching the parallel position, the flat material is bent back towards the imaginary projected continuous edge. When it reaches this, it is bent again following the line corresponding to the imaginary projected continuous edge. This is where the second mounting surface of the fastening elements for the second fastening point on the supporting structure is located. Both bending angles, which are in opposite directions to each other, correspond to the structurally predetermined inclination of the supporting structure from which the pipeline is suspended.

The radius in the area of the bend of the inclination compensator is of course also dependent on the necessary material thickness, but is essentially determined by the diameter and resulting rolling radius of a transverse receiving element for the downward-leading suspension element for hanging the pipeline, the dimensions of which are determined by the design. So that this can be fastened centrally within a preselected tolerance range, the element known as the inclination compensator has a long yoke-like recess in the area of the bend. The length of this long hole-like recess is basically determined by the various inclinations that occur in a structure.

In the preferred solution, the slot-like recess forms an angle of 75 degrees starting from the vertical line following the imaginary projected continuous edge.

It is crucial that the imaginary center line of the suspension element is preferably at right angles to a tangent to the curvature line of the inclination compensator.

The bending radius of the curved surface can be selected in relation to the distance between the two mounting points of the inclination compensator so that the extension of the imaginary center line of the downward-leading suspension element intersects the center axis of the fastening point closest to the opposite bend in the area of the supporting structure.

If the hanging pipeline is suspended by parallel suspension elements, both slope compensators are regularly arranged in one direction so that the curved part of each slope compensator faces the falling slope of the supporting structure. If, on the other hand, the suspension elements are

elements for supporting the pipeline are arranged in a V-shape, both slope compensators are mounted regularly facing the curved part of the pipeline to be suspended.

The solution according to the invention advantageously leads to the introduction of the transverse forces occurring on the suspended pipeline into the structure. The system is statically designed in such a way that excessive stress does not occur and displacement of the suspension element in the inclination compensator and in the curved flange eye of the vertically divided pipe clamp is excluded. This increases the creep strength of the system.

The invention will be described in more detail below using an exemplary embodiment. The accompanying drawing shows

Fig. 1 shows the cross section of a suspension designed according to the invention with parallel arrangement of the suspension elements,

Fig. 2 the inventive arrangement of a flange eye for parallel arrangement of the suspension of the suspension elements,

Fig. 3 the inventive arrangement of a flange eye for V-shaped arrangement of the suspension of the suspension elements,

Fig. 4 the inventive design of a tilt compensator

A pipeline 1 is suspended from a crossbeam 2 inclined at an angle of 12 degrees, in which the pipeline 1 is suspended with a vertically divided pipe clamp 3 in a parallel arrangement. The pipe clamp 3 has downwardly bent

Flange eyes 4 are arranged in such a way that a tangent applied to the respective radius of a flange eye 4 forms a right angle with the suspension elements arranged at the same distance from one another on the supporting structure. Furthermore, the flange eyes 4 have holes 9 widened in the bending direction with a slight longitudinal extension. Here, usual suspension elements such as threaded rods 5 are attached, which are fastened with usual standard parts such as nuts, washers and the like. The illustration of the suspension elements was omitted as not essential to the invention. Each of the suspension elements not shown is supported at its opposite end in the inclination compensator 7 by usual standard parts with a curved U-disk with its outside facing the inner curvature of the inclination compensator 7. This inclination compensator 7 consists of flat material! of suitable cross-section and suitable quality and has two fastening points for fastening to the supporting structure.

Starting from the area of a fixed point designated as the first attachment point, the flat material is bent downwards at an angle of 75 degrees. Following the further course, the curvature then returns with a radius that corresponds to a multiple of the material thickness to a line that is parallel to the imaginary projected continuous edge, which usually follows the suspension surface on each crossbeam 2, so that in the area of the curvature and facing the crossbeam, a circular section is created. This has an elongated hole 10 running in the middle in the bending direction. After reaching the parallel position, the flat material is bent back towards the imaginary projected continuous edge at an angle of 12 degrees. When it reaches the same, it is bent in the opposite direction to the bend that has already taken place, towards the imaginary projected continuous edge at an angle of 12 degrees, so that the subsequent second mounting surface of the bent flat material, referred to as inclination compensator 7, is again flat on the

This means that when transverse forces are introduced into the system, the curved U-disk 6 can be pivoted on the inner circular path of the inclination compensator during assembly, just like each of the lower suspension points in each of the flange eyes 4, so that the tangent applied to the respective radius of the flange eye 4 forms a right angle with the suspension elements arranged at the same or greater distance from each other on the supporting structure. Since the force is always introduced at a right angle, the system aligns itself to the center of the load during assembly and can then be firmly screwed in place.

Alternatively, instead of a curved U-disk 6, a spherical intermediate piece, a cross bolt or similar standard part with a curved outer surface and facing the inner circular path of the inclination compensator 7 can be used.

In the parallel arrangement shown, the system is supported against a nearby wall or the like by a strut that is not essential to the invention. So that this strut can support the pipeline 1 from the side, an angle piece 12 is arranged by screwing it onto the flange eye 4 facing this side.

Reference number:

Pipeline 1

Crossbar 2

Pipe clamp 3

Flange eyes 4

Threaded rod 5

Cross bolt 6

Tilt adjuster 7

inner orbit 8

expanded in bending direction

Holes 9

Slot 10

Strut 11

Angle piece 12

Claims (7)

Protection claims: 1. System for supporting hanging pipelines (1) which are fastened in a preferably vertically divided pipe clamp (3) via threaded rods (5) or similar suspension elements, the pipe clamp (3) has radial flange eyes (4) on both sides, whose fastening points are arranged on both outer sides of the pipe clamp (3) in such a way that a tangent applied to the flange eyes (4) forms a right angle with the suspension elements to be fastened to the flange eyes (4), the flange eyes (4) are bent downwards in a circular arc, recesses in the flange eyes are holes (9) widened in the bending direction, an inclination compensator (7) is used as the upper suspension, which consists of flat material and has two fastening points transverse to the central axis of the pipeline (2) to be suspended and is bent downwards from the area of the first fastening point in relation to the mounting surface, then with a curvature that corresponds to multiple material thickness, back into a line parallel to the imaginary projected continuous edge that follows the suspension surface, over which, after reaching the parallel position, a bend is again made towards the imaginary projected continuous edge, when reaching the same, in contrast to the previous bend, there is again a bend to the line corresponding to the imaginary projected continuous edge, to which the &iacgr;&idigr; second mounting surface of the fastening elements for the second fastening point and the bending angle of the bend follows the projected inclination of the supporting structure from which the pipeline (1) is to be suspended, and in the area of the bend with the radius of multiple material thickness an elongated hole (10) is present, 2. System for supporting hanging pipelines (1) according to claim 1, in which the slot (10) in the inclination compensator (7) covers an angle of 75 degrees with respect to a perpendicular line corresponding to the imaginary projected continuous edge. 3. System for supporting hanging pipelines (1) according to one of claims 1 or 2, in which the bending radius of the curved surface in relation to the distance between the two mounting points of the inclination compensator (7) is selected so that the extension of the imaginary center line of the downward-leading suspension element intersects the center axis of the fastening point closest to the opposite bend in the area of the supporting structure. 4. System for supporting hanging pipelines (1) according to one of claims 1 to 3, in which if the suspension elements are arranged parallel and the supporting structure is arranged at an incline and two inclination compensators (7) are used, these are arranged in one direction. 5. System for supporting hanging pipelines (1) according to one of claims 1 to 3, in which If the suspension elements are arranged in a V-shape and two inclination compensators (7) are used, they are arranged in opposite directions in a mirror image. 6. System according to one of claims 1 to 5, in which on the flange eye (4) facing a horizontally spaced fastening point, an angle piece (12) is arranged which serves to fix the system laterally, to which a strut (11) is further fastened. 7. System according to claim 6, wherein the strut (11) is designed to be adjustable as a tension and compression element.