The present invention relates to a method of constructing buildings having a reticular structure, a method comprising the emplacement “in situ” of prefabricated slabs, strongly attached to the vertical columns of the reticular structure.
The present invention also relates to a building constructed in accordance with the aforementioned method.
Numerous methods for constructing frame structures for buildings are known in the state of the art. These are the most common, as this method is that used in the majority of buildings to be seen in any city. They are based on a three-dimensional network of latticework of strong vertical elements (pillars and columns) and horizontal elements (beams, joists, girders, tympans and stringers) to distribute and to balance the weight of the structure. These latticework structures are lighter, as they require fewer elements than, for instance, arched structures; thus, buildings of great height can be achieved. The strength-giving elements are attached one to another by means of welding or by bolted joints, depending on the results of the calculations and on the type and degree of elasticity required for the particular building. These structures may be built entirely of, or feature elements of, metal, concrete, and even wood.
The most common method of construction consists of a sequential process whereby the pillars are vertically installed, linked at their lower part to the foundations or to piles. Next, the girders are linked to the pillars and subsequently the stringers to the girders, thus completing the metallic structure. Next, the slab is constructed upon the horizontal structure of girders and stringers. The slab is the load-bearing structure of the floor, responsible for distributing the stresses to the girders and also horizontally. Currently, a very common example may be found in the combined steel and concrete slabs, or “composite slabs”, normally consisting of steel girders or stringers, a ribbed steel sheet (“composite deck”) disposed upon the girders and stringers, and finally a compression layer of concrete, with supplementary reinforcement.
Finally, the work may be finished by paving with floor tiles on the concrete. Alternatively, the use of technical floors or ceilings is currently very common, wherein piping, nodes and utilities outlets (water, electricity, optic fibre for communications, hot air for heating and cold air for air conditioning, underfloor heating, domotics, sensorics, etc.) are installed in the ceiling below the joists and stringers, or on the cement forming the floor, subsequently to be covered with parquet flooring sheets, or vinyl or PVC tiling on a supporting framework, in the case of flooring.
On the one hand, the constriction of a slab is a highly labour and time intensive process, as it consists of a batch of various sequential stages, wherein the next stage must await the completion of the previous stage. Here, the construction of the slab represents a bottleneck, as it is necessary to wait for the concrete to set. On the other hand, the installation of the utilities also requires a considerable amount of labour. Therefore, the labour factor represents one of the most significant items in the cost of construction of building structures with utilities included. Finally, the vertical divisions and façade must be installed.
The inventors have performed a background study and have concluded that document WO2015131334A1 may be quoted as the closest state of the art. The patent application PCT WO2015131334A1 describes a method for the construction of buildings wherein the slabs, prefabricated and equipped at source with horizontal beams and stringers, are placed by means of cranes upon the main girders and beams attached to the columns or pillars of the building. The object of this patent enables the achieving of economy in its construction, but presents the drawback that the slab of each storey must be hoisted “in situ” at the workface by large, costly cranes and, furthermore, the construction of vertical walls or divisions, and also the façade, is still required, and a solution is not provided to the financial drawback of having to construct and install ceilings, flooring and utilities once the slabs are in place.
The object of the present invention is to provide a simultaneous solution to these issues and drawbacks.
To this end, the object of the present invention, in a first aspect, is an innovative method of constructing buildings having a reticular structure, new in concept and in function, which is characterised essentially in that it is comprised of the following stages:
In accordance with another characteristic of the present invention, the method provides, at each storey module, the slab corresponding to one of the floors, and at least one of the following construction elements, to be selected from among the following set:
In accordance with another characteristic of the present invention, each storey module is constituted by two halves of the storey, said halves being linked by means of bolting once disposed side-by-side in their respective positions at the workface. In accordance with a preferred characteristic of the present invention, the storey modules are hoisted by means of an elevation system.
Preferably, although not exclusively, the elevation is executed by means of cranes installed at the apex of the columns, in collaboration with pull cables to hoist the storey modules vertically upwards.
In a particular case, the final storey module corresponds to the roof of the building.
In a particular embodiment of the invention, the storey modules comprise the deck of an upper storey, the horizontal slab, the horizontal load-bearing joists and stringers, and the ceiling of the storey below.
In the preferred embodiment, the storey modules hoisted include the piping and service outlets for electricity, signal, water and ventilation for the lower storey, and illumination, domotics, signage, and optionally an enclosure equipped with ventilation outlets and grilles, luminaires, smoke detectors, etc., for the lower floor.
The stage of hoisting the storey modules preferably includes the guiding of the slabs via a number of protrusions on the columns, these acting as a slide for the guides disposed on the storey modules.
Preferably, the stage of attaching the storey modules includes the supporting of the storey modules on brackets incorporated in the columns; said brackets being articulated in order to open with the passage of the storey modules and to spring back once the storey module has passed, activated by a number of return springs, and then a structural girder or beam from the storey is attached to the column by bolting.
In one variant, the vertical division elements, such as the internal walls and the façades of the building, are assembled on the upper face of the storey module, and subsequent to the stage of attaching the storey modules to the columns, they are raised and affixed to the structure, forming the divisions and façades of the upper storey.
Alternatively, the vertical division elements, such as the internal walls and the façades of the building, are assembled on the lower face of the storey module, and subsequent to the stage of attaching the storey modules to the columns, they are raised and affixed to the structure, forming the divisions and façades of the storey below.
A single storey module can incorporate both vertical and horizontal divisions simultaneously.
In a second aspect of the present invention, a building constructed in accordance with the method above is provided.
A detailed description of preferred, but not exclusive, embodiments of the method for constructing buildings having a reticular structure, which is the object of the invention, is given below; for the better understanding thereof a set of drawings is attached wherein, by way of a non-limitative example, embodiments of the present invention are portrayed.
In said drawings:
In said drawings, the operational mode and the advantages of the method of construction of buildings 101 having a reticular structure 100, in accordance with the present invention, may be clearly seen.
The method is applicable to buildings of the type comprising the emplacement “in situ” of prefabricated slabs, which are strongly attached to the vertical columns (1-4) of the reticular structure by means of bolting, welding, riveting or equivalent procedure.
The invention is based on the following stages:
The columns (1-4) may be particularly metal profiles of any type, such as HEB, IPE or IPN profiles, although the inventors have foreseen that the vertical structure may be partially or totally made from other construction materials, for example concrete. In accordance with an essential characteristic of the method of the invention, each storey module 6 should be prefabricated in its entirety, featuring at source the slab 7 corresponding to one of the floors, and one or several of the following strengthening construction or installation elements:
In the preferred embodiment of the invention, which greatly facilitates the transport and installation of the storey modules, these are formed by two halves 61, 62 of the storey.
As the typical measurement of the spaces between the columns of buildings is 6×6 metres or similar, it seems appropriate that a storey module 6 can be prepared in two half-sections 61, 62, measuring 3×6 metres each; these can be carried in a standard truck container, with no need for recourse to heavy haulage, which would increase the expense of the transport. Both halves 61, 62, once unloaded from the transport, are linked together by means of bolting once disposed side-by-side in their respective positions at the workface.
Next, the hoisting of the storey modules 6 is executed by means of cranes or winch engines, installed preferably at the apex of the columns (1-4), in collaboration with pull cables to hoist the storey modules 6 vertically upwards and in unison. To this end, the consecutive storey modules 6 are linked by means of cables (19).
In a preferred embodiment, the final storey module 6, or upper module 60, is that which corresponds to the roof of the building 101, and incorporates the corresponding enclosure elements.
In both
A fastening profile 25 links the half-slabs 61, 62 of the module 6, 60 via the interior of an overlapping pipe between halves 61 and 62. This fastening profile may be seen slightly above the linking plates 26 of the two halves 61, 62 of the module.
At the extremities of the beams 10 a number of plates 11′ and 11″ may be seen; the function thereof being to link the storey modules 6 to the columns 1-4. A number of welded eyebolts 27 are provided for the hoisting system.
A water-repellent panel 28 seals the upper surface of the module 6 and also enables the supporting of the deck 20 of the storey, to be covered with the appropriate flooring material; parquet, tiling, PVC, etc.
Below the beam 10 there is an auxiliary structure forming a false ceiling 32, with thermal and/or acoustic insulation, and a number of false ceiling plates 31 cover inferiorly the module 6, 60, and may incorporate luminaires, diffusers, smoke detectors, water sprinklers, motion sensors, light sensors, or other installations related to domotics or the internet of things, all installed priorly at source.
In one variant (not portrayed), the primary girder or beam 10 is at the highest point, and the joists 15 and facilities are below.
In another possibility, the slab 7 may be supplemented, as required by calculations, with a metal composite deck filled with concrete, and to bear thereon the necessary flooring, with parquet, tiles, PVC, etc.
In the storey module forming the roof 60 in
To guide the hoisting of the storey modules 6, the columns (1-4) feature a number of protrusions 9 (
To attach the storey modules 6 to the structure 100, the columns 1, 2, 3, 4 are equipped with a number of articulated brackets 8, especially designed to open for the passage of the storey module 6 on being pushed upward by the edge of a beam 10 of the latter, and adapted to spring back due to the effect of a return spring 12 when the storey module 6 has surpassed it in height. The structural girder or beam 10 of the module 6 is attached to the corresponding column 1-4 by resting the edge of the beam 10 on the bracket 9 and affixing the same by means of bolting the plates 11′ and 11″ to the protrusions 9 of the beams (1-4).
The walls 13 and façades 14 of the building 101 may be pre-installed on the storey module 6, as portrayed in
In
Finally,
The nature of the present invention having been sufficiently described, likewise the method for putting the same into practice, it is stated that anything that does not alter, change or modify the fundamental principle thereof shall be subject to variations in detail.
Number | Date | Country | Kind |
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P201531853 | Dec 2015 | ES | national |
Filing Document | Filing Date | Country | Kind |
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PCT/ES2016/070870 | 12/9/2016 | WO | 00 |