The invention relates to a substructure for a construction that is self-supporting without the substructure, which construction has at least one carrying component accommodating a force. The invention also relates to the use of a substructure of this type.
Constructions, of whatever type, have some or other form of carrying components, for example walls, carriers, roof carriers, struts, frames or a carrying structure in general, which impart to the construction its static strength or its static carrying force and make the construction a self-supporting construction. The term “a self-supporting construction” therefore refers to a construction which is, owing to its design having carrying components, per se capable of carrying. The constructions are designed in such a way that at least one carrying component of the construction can accommodate at least one force, generally a plurality of forces, be it weights, compressive or tensile forces.
Constructions, such as for example houses and buildings, can in this case be at least partly protected from atmospheric influences by an external cladding and/or a roof. However, there are also constructions, such as for example antenna systems, pylon systems or power pylons, which have for example a latticed carrying structure which is directly exposed to atmospheric influences.
Irrespective of whether the construction is a closed construction, for example in the form of a building, or an open construction, for example in the form of a power pylon having a latticed carrying structure, said constructions can change, generally reduce, in particular under the influence of weather, above all if they are exposed to weather for years and years, their carrying properties, in particular their carrying capacity, as far as the influence of the forces acting on them is concerned. Thus, the influence of cold, heat, moisture, snow and ice has, inter alia, repeatedly led to the caving-in of roofs of buildings, in particular of halls, injuring persons. Furthermore, the influence of cold, heat, moisture, snow, ice and winds has lead to the breakage of latticed carrying structures, for example of power pylons, as a result of which the supply of electrical power to a portion of the population was interrupted, in some cases for days on end.
The invention is therefore based on the object of specifying a substructure of the type mentioned at the outset and a use therefor so as to provide at least a certain protection for a construction.
According to the invention, this object is achieved by a substructure for a construction that is self-supporting without the substructure, which construction has at least one carrying component accommodating at least one force, wherein the substructure can be arranged relative to the construction in such a way that it is located at least partly in direct proximity to the at least one carrying component, accommodating at least one force, of the construction. The invention therefore proposes providing on a self-supporting construction a substructure for protecting at least one carrying component, accommodating for example a weight, tensile or compressive force, of a construction. The construction can be a building, a pylon or the like, but also a roof structure, a carrying frame or a carrying structure in general. The carrying component of the construction can for example be in the form of individual carriers, struts or the like. The substructure is in this case, as mentioned hereinbefore, not necessary in order to impart to the construction per se its carrying force or carrying capacity, but rather serves merely to protect the construction, be it in such a way that the substructure is at least partly arranged at a specific distance in direct proximity to at least one carrying component, accommodating at least one force, of the construction or that the substructure even contacts at least one carrying component, accommodating at least one force, of the construction in order if necessary to be able to accommodate a force or forces.
According to a variant of the invention, the substructure has at least one structure portion. The substructure or the structure portion comprises in turn at least one structure element which can for example be a rod, a pipe, an angle profile, a cord, a cord net and/or a connecting element for at least two structure elements of this type. The substructure does not in this case necessarily have to have a plurality of structure portions, but rather can also have only one structure portion. It is also possible for the structure portion to be or to embody the substructure.
A suitable substructure has been found to be a three-dimensional framework which generally comprises pipes or rods which are made of steel, can be tapered at their ends and can be connected to one another using spherical connecting elements to form larger, in particular static structures. Three-dimensional frameworks of this type are known from MERO-TSK International GmbH & Co. KG having its registered office in Würzburg, Germany. Moreover, the spherical connecting element is also referred to as a so-called Mero node which has a plurality of portions for fastening pipes or rods or for connecting pipes and/or rods to one another.
Embodiments of the invention make provision for the substructure to have what is known as an underpinning structure for at least a part of the construction. The term “underpinning” refers in this case to the fact that the substructure is not connected directly to or does not contact at least one carrying component, accommodating a force or forces, for the introduction of the force or of forces, but rather that the underpinning structure or a structure portion of the underpinning structure is located at a specific distance, selected in a defined manner, from the at least one carrying component of the construction. Preferably, the at least one structure portion of the substructure or the underpinning structure is located in direct proximity to a carrying component, accommodating a force, of the construction, i.e. at a distance selected in a defined manner from the carrying component, in such a way that the structure portion or the underpinning structure can support the carrying component at least for a specific time during static yielding of the carrying component, accommodating the force, of the construction. All references hereinbefore to an arrangement of the structure portion or of the substructure in direct proximity to the carrying component of the construction refer to the fact that the distance between the structure portion or the substructure and the carrying component of the construction is preferably as small as possible, but is selected in a defined manner in such a way that, for example, season-induced and/or weather-induced material expansions and/or contractions and also oscillations of the carrying component of the construction, in a conventional tolerance range which is to be expected, do not lead to contacting of the substructure or the structure portion with the carrying component of the construction. It is therefore clear that the distance between the structure portion or the substructure and the carrying component is accordingly selected as a function of the type of the construction and also of the material of the carrying component and also as a function of the forces and influences normally acting on the carrying component, additional account if appropriate being taken of a safety requirement.
The substructure is provided, for example, for a roof of a building, for example a hall, wherein the substructure or a structure portion of the substructure can run substantially parallel to the roof. If the building is for example a hall having a flat roof, then the structure portion or the substructure runs substantially horizontally parallel to the flat roof, if appropriate so as also to be adapted to the pitch of the roof. However, the structure portion or the substructure can also run in an arcuate manner or in adaptation to the carrying component to be protected, adapted to the shape thereof.
The substructure or the structure portion of the substructure is located at least partly within or below the construction and/or within or below or next to the carrying component, accommodating at least one force, of the construction. For example, the structure portion or the substructure can be located below a roof structure of a construction or within a ceiling or a carrying structure of a construction.
Depending on the design conditions and the requirements placed on the construction or the use of the construction, the structure portion or the substructure can extend, for example in the case of a building, at least partly through a wall of the construction if said structure portion or said substructure cannot be mounted within the construction.
According to a variant of the invention, the structure portion or the substructure can be arranged at least on a support, wherein the support can be located within or outside the construction. If the support is located outside the construction, the substructure or the structure portion of the substructure extends, for example in the case of a building, at least partly through a wall of the construction. Should the design conditions of the construction and also the use of the construction permit it, the substructure or the structure portion of the substructure can be mounted at least partly on a part of the construction or on an attachment to the construction. For example, the structure portion or the substructure can be mounted on a part of the wall of a construction or on an attachment to the wall of the construction or on a foundation of the construction.
In addition, the substructure can have at least one guy which is preferably located outside the construction and generally brought about using a cord or pipes.
According to a further variant of the invention, the substructure is provided for a bridge and can, in particular for this purpose, be embodied in an at least partly arcuate manner.
According to one embodiment of the invention, a measuring means is associated with the substructure for determining the distance between the carrying component, accommodating at least one force, of the construction and the substructure or the structure portion of the substructure. A measuring means of this type comprises for example a plurality of distance sensors which can be arranged for example on the substructure and detect continuously or at specific discrete points in time measured values from which the distance between the carrying component of the construction and the substructure can be determined. If the distance between the carrying component, accommodating at least one force, of the construction and the substructure reaches or even drops below a preferably predefinable limit value, an alarm can be triggered based on the measured value or values of the measuring means. This allows, on the one hand, changes in the carrying properties of at least one carrying component of the construction to be registered comparatively rapidly and, on the other hand, measures, such as for example the evacuation of a building, to be introduced in order to avoid injury to persons, resulting for example from the roof of the construction caving in.
According to a variant of the invention, the substructure is located preferably at least partly within the construction and contacts the carrying component, accommodating the force, of the construction at least one specific point for the introduction of force from the construction into the substructure. Generally, the substructure is in this case designed and arranged at least partly in the construction in such a way that the substructure and the force-accommodating carrying component contact each other as continuously as possible for the introduction of a force from the construction into the substructure. However, it can occasionally occur, depending on the atmospheric conditions and also on the materials of the carrying component of the construction and of the substructure, that the carrying component of the construction and the substructure do not enter into contact. However, the distance between the carrying component of the construction and the substructure is in this case generally so small that, in the case of marked stressing of the carrying component of the construction as a result of the introduction of forces into the carrying component of the construction, be it as result of atmospheric influences or other influences, the carrying component of the construction and the substructure enter into contact, thus allowing force again to be introduced from the construction into the substructure. As the substructure is generally embodied in such a way that it contacts a plurality of force-accommodating carrying components of the construction at a plurality of specific points, it is almost impossible, even under disadvantageous ambient conditions, for there to be any contact whatsoever between the construction and the substructure. Variants of the invention make provision in this case for a structure element of the substructure, preferably a connecting element such as the Mero node, to contact a force-accommodating carrying component of the construction at a specific point for the introduction of force from the construction into the substructure.
The substructure is provided, for example, for a construction having a latticed structure and/or carrying structure comprising struts. A construction of this type is for example a pylon, for example a power pylon. A pylon of this type can have a tower-like pylon body and/or at least one carrying arm, but generally a plurality of carrying arms, arranged on the pylon body. The substructure is, in the case of a pylon of this type, arranged at least partly in the pylon body and/or in a carrying arm of the pylon body.
In the case of a pylon of this type, provision may be made to have at least one supporting strut run between a carrying arm of the pylon and a structure portion, arranged in the pylon body, of the substructure and/or between a structure portion, arranged in the carrying arm of the pylon, of the substructure and a structure portion, arranged in the pylon body, of the substructure.
According to a variant of the invention, the substructure can be arranged at least partly on a foundation of the construction. In the case of the pylon, the foundation of the pylon can for example be used to arrange the substructure thereon. In addition, provision may in this case be made for the substructure at least substantially to follow the latticed structure of the carrying structure of the pylon. However, the substructure does not necessarily have to be arranged on the foundation of the construction or the pylon.
According to one embodiment of the invention, the substructure is preferably configured in such a way that it can be retrofitted in a simple manner in or on a construction. The retrofitting of the substructure does not in this case generally require the use of heavy lifting apparatuses or the provision of additional foundations. In addition, the substructure, especially if it is embodied as a three-dimensional framework, does not alter the external appearance and also it does not restrict the use of the construction.
The invention provides for the use of one of the foregoing substructures for supporting at least one carrying component, accommodating at least one force, of a construction in the event of static failure of the carrying component, accommodating the force, of the construction. In this case, the substructure is therefore a pure auxiliary structure for the purposes of safety, should static failure of a carrying component of a construction, for example failure of a roof, occur.
However, the substructure can also be used to reinforce a self-supporting construction; this is beneficial when constructions are to be protected, owing to years of operation and owing to atmospheric influences acting thereon, wherein in this case the substructure and the construction are preferably brought into contact at specific points, thus allowing force to be introduced from the construction into the substructure.
Exemplary embodiments of the invention are illustrated in the appended schematic drawings, in which:
The roof carriers 3 of the hall 1 are, in the case of the present exemplary embodiment, wooden beams extending transversely over the hall 1. The wooden beams can be solid wood beams but also beams made of glued wood. However, it is also possible to make the roof carriers 3 from steel or from another suitable material which is capable of carrying. A covering 4, which is mounted on the roof carriers 3, is arranged on the roof carriers 3 in the case of the present exemplary embodiment. The roof carriers 3 are carrying components of a carrying or roof structure, carrying the covering 4, of the hall 1. The roof carriers 3 each accommodate, as carrying components of the hall 1, a part of the weight of the covering 4 and also further forces acting in particular on the covering 4, be it compressive or tensile forces or the like.
The roof structure of the hall 1, in particular the roof carriers 3 of the hall 1, are subjected to particularly high loads whenever, in addition to the weight of the covering 4, other loads also act on said covering; this can be the case for example in winter, when masses of snow and ice are located on the covering 4. Phenomena of ageing and influences which can be undesirable, such as for example moisture seeping onto the roof carriers 3 through the covering 4, can cause individual roof carriers 3 or else all the roof carriers 3 to change their carrying properties and no longer to be able permanently to withstand the forces acting thereon, so that in particular in the event of high loads acting on the roof structure (this can be the case as a result of masses of snow and ice in winter) there is a risk that the roof will cave in.
It is therefore proposed, as a safety measure, in particular at times when high loads act on the roof carriers, to arrange, in the case of the present exemplary embodiment, below the roof structure of the hall 1 or below the force-accommodating carrying components in the form of the roof carriers 3, at least one substructure 5 below at least one roof carrier 3 in such a way that at least one structure portion 6 of the substructure 5 is located at least partly in direct proximity to a carrying component, accommodating a force, in the form of a roof carrier 3. The substructure can in this case also extend over the entire extension of the roof structure of the hall 1. However, it is also possible to assign a substructure of this type only to individual roof carriers 3 which are exposed to particular loads, or else to arrange the substructure, unlike as shown in
In the case of the exemplary embodiment shown in
The dimensions of the opening 9 are embodied in such a way that the structure portion 6, which is associated with a roof carrier 3 and has, in the case of the present exemplary embodiment, a beam-like or right parallelepiped outer structure, can be guided through the opening 9. As previously mentioned, the structure portion 6 is mounted outside the hall 1 on supports 7 and 8.
In the case of the present exemplary embodiment, a structure portion 6 is embodied as a three-dimensional framework and has accordingly rods 21 and/or pipes and also connecting elements 22 for connecting the rods and/or pipes to one another. The connecting elements are generally what are known as Mero nodes 22, such as are used for example by MERO-TSK International GmbH & Co. KG for constructing three-dimensional frameworks. In the case of the present exemplary embodiment, the support 8 is also embodied as a three-dimensional framework. However, alternatively, the support can also be, as shown based on the example of the support 7, a pylon which is made of wood or steel or another suitable material and can be provided with a guy 10 for reinforcing the underpinning structure 5. The guy 10 is generally a steel cord or a pipe system which is accordingly fastened in the ground and allows corresponding bracing of the substructure 5.
Moreover, the openings 9 in the side walls 2 of the hall 1 are, in a manner not illustrated in
As may be seen from
The variant shown in
As may be seen in particular from
The variant of a substructure according to
The exemplary embodiment shown in
In the case of the exemplary embodiment shown in
Moreover, any desired mixed forms between the exemplary embodiments shown in
In the case of the exemplary embodiment shown in
A further exemplary embodiment, in the case of which a substructure is Mused as an underpinning structure, is shown in
Moreover, the underpinning structure 16 can also have, in a comparable manner to the exemplary embodiment described in relation to
The substructure has been described hereinbefore based on the example of a three-dimensional framework having inter alia pipes, rods and/or connecting nodes. However, the substructure does not necessarily have to be embodied in the form of a three-dimensional framework, but rather can also be a cord structure, for example using cord nets, or a structure using other suitable materials. As the substructure does not have any carrying function, it can be embodied in a comparatively compact manner and is thus suitable for subsequent integration into an existing construction.
Furthermore, the underpinning structure can be provided for constructions other than the roof of a building or a bridge.
Moreover, components which, in the exemplary embodiments shown, correspond at least substantially with regard to their function and configuration are provided with the same reference numerals.
The invention therefore proposes arranging a substructure within a construction, which has at least one carrying component accommodating at least one force, in the case of the present exemplary embodiment within the pylon 40 which has components, accommodating at least one force, in the form of rods 45, in such a way that the substructure contacts the carrying components, accommodating at least one force, in the form of rods 45 at specific points for the introduction of force from the pylon 40 into the substructure, thus reinforcing the pylon 40 and leading to substantial rigidity and an increase in the carrying capacity of the pylon 40.
As illustrated in
The substructure 50 is, in the case of the exemplary embodiment shown in
However, the embodiment of the substructure as a three-dimensional framework allows comparatively good adaptation to an existing geometry such as that of the pylon 40, so that a force can be introduced in the desired manner, if possible on each node element 52.
The substructure 50 does not in this case necessarily have to reinforce the pylon 40 completely over its entire internal volume. On the contrary, it is possible, as shown in
It is however also possible additionally to reinforce all carrying arms 42 or, as shown in
In order further to increase the load, a supporting strut 55 can be arranged between the carrying arm 42 of the pylon 40 and a structure portion 56, arranged in the pylon body, of the substructure 50 and/or between a structure portion 54, arranged in the carrying arm 42 of the pylon 40, of the substructure 50 and a structure portion 56, arranged in the pylon body, of the substructure 50. Four supporting struts of this type are shown in
The reinforcement of a construction with the aid of the substructure has been described hereinbefore based on the example of a pylon, in particular a pylon for overhead power lines. However, other constructions can also be reinforced using a substructure of this type, thus increasing the rigidity and the carrying capacity thereof.
The described substructure can in this case be retrofitted into a construction in an advantageously simple manner, as the substructure can be embodied in a comparatively compact manner.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE06/01350 | 8/2/2006 | WO | 00 | 3/16/2009 |