WO2003001628A2 - Method and securing device for securing supports on roofs - Google Patents

Abstract

According to the inventive method and the inventive securing device, a support or a support system is fastened to the framework or structure/ construction of a roof. According to the invention, the support or the support system does not rest on the floor of the roof; the supporting or retaining forces of the secured support are introduced into the construction of said roof. As a result, the device for securing a support or support system is embodied in such a way that it bears a support or a plurality of supports and is secured to the roof structure or roof construction.

Description

Method and fastening device for fastening support poles to roofs

The present invention relates to a method and a device for fastening support masts to roofs. The present invention relates in particular to a method and a device for fastening support masts formed from support masts, for example in the form of antenna support structures for mobile radio systems.

Support masts, in particular for antennas, are usually constructed from a plurality of support masts fastened to one another at their ends, in order on the one hand to obtain support masts with a height sufficient for the respective intended use and on the other hand to enable the support masts to be constructed from components, in particular support masts, with a manageable length. The individual masts of such a structure are also referred to as shots.

An antenna support structure is made up of 3 sections, for example, the diameter of the individual sections decreasing with increasing height. The top shot carries the respective antennas and associated components such as amplifiers, connection boxes and the like. To attach the antenna support structure to the roof of buildings, the antenna support structure is usually passed through the roof and is supported vertically on the attic with its lowest shot. Usually the bottom shot is attached to the attic. The antenna support structure is held laterally by the roof leadthrough and / or by supports extending essentially perpendicular to the longitudinal direction of the supporting masts.

A majority of the antenna structures that have been erected are license-free antenna structures. Approval-free antenna structures are antenna structures, depending on the building regulations of the federal states, for example, a construction height of up to 10 m, the height of the structure being determined from the length of the masts. Approval-free antenna structures of this type are particularly important for the construction of the recently expanding mobile radio networks, specifically for the establishment of the base stations of the individual radio cells.

The method according to the invention and the fastening device according to the invention provide for fastening a supporting mast or a supporting mast structure to the roof truss or roof structure / roof construction of a roof. This means that the supporting mast or the supporting mast structure is not supported on the attic of the roof, but the supporting or holding forces of the attached supporting mast are introduced into the roof structure. For this purpose, the fastening device for fastening a mast or mast structure is designed such that it receives one or more masts on the one hand and is itself attached to the roof structure or the roof structure on the other hand.

The present invention has the following advantages in particular. It enables universal mounting of masts on different roof types, for example on loft, saddle, hip roofs etc., regardless of the respective roof pitch, i.e. essentially for any roof pitch. The invention can also be applied to flat roofs which are designed as rafters roof and have a slight slope.

Since the approval-free overall height of e.g. Determined 10 m according to the length of the mast and not according to the height above the ridge, larger antenna heights can be achieved above the roof. Higher antenna positions lead to improved reception and transmission properties, especially with regard to the transmission and reception range at low building heights.

In the fastening device according to the invention, low local vertical loads which result from the wind moments advantageously occur. In addition, the deformation of the roof Chair against the deformation or bending of the supporting masts due to the attacking wind, so that the deformations at least partially cancel each other out and only slight alignment deviations of the supporting masts or antennas occur even under different weather or weather conditions. Accuracy and stability of the antenna alignment are also important criteria for the transmission and reception properties.

Due to the exclusive attachment of the mast or mast structure to the roof structure, there is no immediate load distribution, e.g. from a snow load, into the underlying building parts via the mast or antenna structure. In addition, structure-borne noise is avoided in living room ceilings. Furthermore, it is advantageous that the fastening device according to the invention has no or only a slight loss of usable space for the existing donor.

The fastening device according to the invention is preferably connected to or fastened to at least two roof beams, in particular rafters. For the most uniform possible introduction into or large-area distribution of the forces on the roof structure, several fastening points between the fastening device and the roof structure, in particular roof beams / rafters, are advantageous. For this purpose, the fastening device according to the invention preferably has side members and a supporting structure. The longitudinal beams are preferably each fastened to a plurality of roof beams and introduce the holding or supporting forces of the supporting mast into the roof structure. The side members are preferably characterized by a high level of bending stiffness, which is achieved by a suitable choice of material and / or construction of the side members. The side members can be made of steel tubing, for example. The side members and supporting structure of the fastening device form a spatial framework, which is characterized by a high stability.

With special requirements, for example high weight of the supporting mast or supporting mast structure to be fastened and / or less The load-bearing capacity of a roof can consist entirely or partially of special materials such as aluminum or composite materials, which have high strength or bending stiffness with low weight. The holding and carrying forces of the mast or mast structure can also be introduced into the roof structure over a large area using a complex fastening device which extends correspondingly in the roof space, the weight of the fastening device contributing only as little as possible to the additional roof load ,

The support structure or support structure of the fastening device for holding or carrying the at least one support mast is stretched between the longitudinal beams. The supporting structure comprises a plurality of carriers and holding means for carrying and holding the mast or mast structure. The support structure has, in particular, cross members which connect the longitudinal members to one another and supports for the holding means.

The shape of the holding means which serve to receive a supporting mast is adapted to the shape of the supporting mast and is connected to the longitudinal beams via the supports. The carriers are preferably arranged such that the forces occurring ^'and in particular as a tensile or compressive forces are transmitted to the longitudinal member. In practice, however, it will not be possible to prevent moments from occurring to a certain extent.

At least two holding means spaced apart from one another and aligned vertically to one another are preferably provided for each supporting mast. In this way, forces acting laterally on the supporting mast or structure, for example as a result of wind loads, can be absorbed particularly effectively and introduced into the roof structure via the fastening device according to the invention. The spacing of the holding means from one another depends on the structural conditions, for example roof height, height of the mast or mast structure. NEN) add-ons or superstructures, and location, e.g. expected wind speeds and snow loads as well as static specifications or requirements. Two holding means provided for a supporting mast are preferably arranged such that a holding means is arranged above and a holding means is arranged below a plane spanned by the longitudinal beams. Such an arrangement is particularly advantageous also with regard to vertical forces that occur, that is to say in particular the weight of the mast or mast structure. The support structure, comprising the cross beams, the supports for the holding means and the holding means, and the longitudinal beams together with the supporting mast base span a three-dimensional framework. Such a framework advantageously leads to additional stiffening of the roof. As a result, with the fastening device according to the invention, support masts or antenna structures can also be attached to roofs which, due to their static load-bearing capacity, are not suitable for attaching such antenna structures with conventional fastening means.

However, only one holding means can be provided above, below or in the plane of the side members. In addition, the supporting mast can also be additionally fastened in the area of the roof duct.

The fastening device according to the invention can, however, also be provided without a longitudinal beam, in particular in the case of roofs which are designed to be particularly strong. Then the support structure of the fastening device acts directly on several fastening points of the roof truss, for example on several roof beams in the form of rafters or preferably on so-called purlins. However, this can require a more complex support structure. The advantages of a more resilient, in particular largely wind load-stable fastening of a supporting mast and the uniform, large-scale introduction of force into the roof structure by means of the fastening device according to the invention are essentially based on a plurality, namely of at least three distributed fastening points and the formation of a spatial lent truss by means of the supporting structure or by the interaction of the supporting structure and the longitudinal beam, which can also be understood as a load distribution beam.

Further advantages and refinements of the invention result from the description and the accompanying drawing.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the combination specified in each case, but also in other combinations or on their own without departing from the scope of the present invention.

The invention is illustrated schematically in the drawings using two exemplary embodiments and is described in detail below with reference to the drawings.

1 shows a sectional side view of a first exemplary embodiment of a fastening device according to the invention,

FIG. 2 shows a sectional top view of the first exemplary embodiment of the fastening device according to the invention

Figure 3 shows a sectional side view of a second embodiment of a fastening device according to the invention and

Figure 4 shows a sectional plan view of the second embodiment of the fastening device according to the invention.

FIG. 1 shows a sectional side view of a first exemplary embodiment of a fastening device according to the invention. direction 30. A mast 20, which in the present example is composed of three masts 21, is fastened to the roof structure 11 of a roof 10 by means of the fastening device 30 according to the invention. The antenna structures attached to the mast 21 are not shown.

The fastening device 30 comprises side members 31, a support structure 32 with supports 33 and holding means 34 for holding the supporting mast 21. The side members 31 have the function of load distribution supports. The support structure 32 comprises a plurality of supports 33a, 33b which connect the mast support means 34 to the side members 31 and cross members 33c which connect the side members 31. The cross member 33 c can also be understood as a connecting member of the load distribution member 31.

The longitudinal beams 31, and thus the fastening device 30, are connected to roof beams 12 of the roof frame 11 by means of first connecting means 35. The connections or connection means can be provided as permanent or detachable, positive and / or non-positive connections. Screw connections are preferably used.

The beams 33a, 33b, 33c, the mast support means 34 and the longitudinal beams 31 are connected via second holding means 36. The connections or connection means 36 can also be provided as permanent or detachable, positive and / or non-positive connections.

The connecting means 36 can comprise adjustable (for example displaceable) connecting elements (not shown). These can also include means (not shown) for articulated connection. The connecting means 36 or connecting elements preferably cooperate with counterparts (not shown) on supports 33a, 33b, 33c, support mast holding means 34 and / or longitudinal supports 31, for example fastening catches, bores, guides or the like, which have different and / or the same catch width are provided. This enables flexible and simple adaptation to the respective structural conditions. In addition, a modular construction of the fastening device 30 or a construction based on the modular principle can be achieved. However, this can also be achieved, for example, if the supports 31, 33 and the connecting means 36 are designed in the manner of a pipe-pipe clamp connection. Screw connections are preferably used to connect supports 33a, 33b, 33c, support mast holding means 34, side members 31 and second holding means 36. The support mast holding means 34 can also be provided integrally formed on the support mast 21.

The beam structure 32, which is stretched between the longitudinal beams 31, comprises beams 33a which are subjected to tension and beams 33b which are subjected to pressure. In a plane 37 spanned by the longitudinal beams 31, beams 33 c are preferably arranged which connect the longitudinal beams 31. The beams 33c also counteract torsion of the longitudinal beams 31. The torsion of the longitudinal beams 31 is brought about in that the intersection of the center lines of the tension beams 33a and the pressure beams 33b, which ideally lies in the center in the rafters or longitudinal beams 31, is in practice off-center, which enables a simpler construction.

Side members do not have to be arranged at the same height and the side members themselves do not have to be aligned horizontally. In other words: the plane 37 spanned by the longitudinal beams 31 does not have to run horizontally but can also be inclined.

The longitudinal beams 31 also do not necessarily have to be attached to opposite roof sides. For example, these can also be provided on adjacent roof sides. Attaching to opposite sides of the roof is particularly advantageous statically. Furthermore, more than two longitudinal beams 31 can also be provided for holding the beam structure 32 or the fastening device 30. For example, two longitudinal beams 31 can also be arranged at different heights on opposite roof sides are connected via brackets 33a, 33b to support mast holding means 34 which engage the support mast 21 at different heights.

FIG. 2 shows a sectional top view of the first exemplary embodiment of the fastening device according to the invention. The combination of FIGS. 1 and 2 shows in particular the exemplary design of the support structure 32. The longitudinal beams 31 are each fastened to two roof beams 12 by means of the first connecting means 36. The longitudinal beams 31 themselves are connected to one another via two beams 33c of the beam structure 32. The support mast 21 is held by two support mast holding means 34, which are each connected to the longitudinal supports 31 by four supports 33a and 33b. The two mast support means 34 can also be designed as a single elongate mast support means. The support structure 32 with its cross members 33c and tensile and compressive members 33a, b dissipate occurring loads via tensile and compressive forces and largely avoid bending moments. As a result, a high degree of stability can be achieved with a small dimensioning of the carrier of the fastening device and thus a low weight fraction. The longitudinal girders 31 and the girder construction 32 span a stable spatial truss with the supporting mast 21 or supporting mast base. This also stiffens the roof 10, since the bending and buckling lengths of the roof beams in the form of the rafters 12 are shortened. In addition, wind loads from the antenna mast (not shown) transmitted from the support mast 21 are divided into very low individual loads of the rafters 12 via the longitudinal members 31.

Figure 3 shows a sectional side view of a second embodiment of a fastening device according to the invention, in which the same reference numerals designate the same elements. The exemplary embodiment shown in FIG. 2 differs from the one shown in FIG. 1 primarily in that the support structure 32 is designed for holding or carrying two supporting masts 21. First and second supporting mast holding means 34 are each arranged above the plane 37 spanned by the longitudinal beams. Figure 4 shows a sectional plan view of the second embodiment of the fastening device according to the invention. The support mast holding means 34 of the two support masts 21 are additionally connected to one another by a support 33 d of the support structure or support structure 32. The longitudinal beams 31 are each attached to a plurality of roof beams 12, which ensures that force is introduced into the roof structure 11 over a large area.

The procedure for attaching a mast 21 to a roof 10 is as follows.

Since with the fastening device according to the invention a largely tolerance-independent fastening, ie fastening or adaptable fastening of the supporting mast 21 or supporting mast mechanism in a wide range is possible, it is not necessary to carry out a detailed measurement. As a rule, the fastening device 30 can be adapted to the respective structural conditions with simple means on the construction site in the manner of a modular system. In the case of very unusual roof trusses, special supports, side members etc. can be manufactured or adapted in the workshop before assembly. Pre-assembly of individual assemblies is also possible. When mounting the fastening device 30 according to the invention, the longitudinal members 31 are first fastened to roof beams 12 at suitable points. These are then connected to each other via beams 33 c in order to create a stable basic construction. Starting from this construction, the support structure 32 is then built up with tension and compression supports 33a, 33b and support mast holding means 36. The support mast 21 is then attached to the support mast holding means 36. Another method provides for first connecting the longitudinal beams 31 to the cross beams 33c on the roof structure. By mounting the tension and compression beams 33a, b and the mast support means 34 on the frame thus created, the support structure 32 is constructed. Together with the mast 21 or mast foot or by using an elongated mast support means 34, stable spatial truss. This is lifted onto the rafters 12 and fastened to the rafters 12 with connecting means 35. A particular advantage of both assemblies is that no time-consuming detailed measurement is required as preliminary work. Furthermore, the fastening device 30 according to the invention enables rapid assembly, including variable adaptation of the fastening device 30 on the construction site.

Claims

claims 1. Fastening device for fastening at least one supporting mast (20, 21) to a roof (10), so that the fastening device (30) comprises means (31, 32, 33, 34, 35, 36) which support the at least one supporting mast (20, 21) and ensure that the fastening device (30) is attached to the roof structure (11, 12). 2. Fastening device according to claim 1, characterized in that the fastening device (30) side members (31) and a support structure (32), wherein the longitudinal support (31) is attached to the roof structure (11, 12) and the support structure (32) is attached to the longitudinal supports (31). 3. Fastening device according to claim 1 or 2, characterized in that the support structure (32) comprises tension and compression supports (33a, 33b) and holding means (34). 4. Fastening device according to one of claims 1 to 3, characterized in that the support structure (32) spans between the longitudinal beams (31). 5. Fastening device according to one of claims 1 to 4, characterized in that at least two holding means (34) are provided, the one holding means (34) below and the other holding means (35) above one of the longitudinal members (31) spanned Level (37) is arranged. 6. Fastening device according to one of claims 1 to 5, characterized in that the support structure (32) comprises cross members (33b) which connect the longitudinal members (31). 7. Fastening device according to one of claims 1 to 6, characterized in that the supporting fastening of the supporting mast (20, 21) by means of the fastening device (30) is provided exclusively on the roof structure (11, 12). 8. Antenna system, in particular for mobile radio, characterized in that the antenna system comprises a mast (20, 21) and a fastening device (30) according to one of claims 1 to 7. 9. A method for attaching at least one mast (20, 21) to a roof (10), wherein - longitudinal members (31) are attached to a roof structure (11, 12), - A support structure (32) is clamped between the longitudinal supports (31) by means of supports (33), holding means (34) for at least one support mast (20, 21) being provided on the support structure (32), - At least one support mast (20, 21) is attached to the holding means (34). 10. A method for fastening at least one supporting mast (20, 21) to a roof (10), wherein, - the longitudinal members (31) are first connected to the cross members (33c) in the attic, a support structure (32) is built up by attaching tension and compression supports (33a, b) and support mast holding means (34) to the frame of longitudinal supports (31) and cross supports (33c) thus created, - A spatial truss is built from the support structure (32) and side members (31) together with the support mast (21) or by using an elongated support mast holding means (34), and - the spatial truss is lifted to the rafters (12) and connected with connecting means ( 35) is attached to the rafters (12).