ITSR20090001A1 - PREFABRICATED MODULE IN REINFORCED, CONCRETE, ASSEMBLED, ANTISISMIC AND HABITABLE CONCRETE - Google Patents

Description

PREFABRICATED MODULE IN REINFORCED CONCRETE. TRANSPORTABLE.

ASSEMBLY. SEISMIC AND HABITABLE

Premise

To make the process by which the prefabricated module in question can have structural, transportability, assembly characteristics, but also habitability, functionality and innovation more understandable and easy to read, it was decided to adopt a logical process that starts from description of the individual "systems" or "elements" up to the resolution of problems such as transport, assembly and aggregation. To do this, the following topics will be dealt with, one at a time: description of usefulness: structure; seismic isolation; system ventilation and external cladding; ventilated roof; internal partitions; floor: coatings, plasters and colors for the exterior: coatings, plasters and colors for internal P; waterproofing and insulation; external and internal fixtures; hydro system; electrical system; photovoltaic system and solar-thermal system; air conditioning system; fire-fighting system; transport, assembly assembly and technical specifications of the finished prefabricated module; aggregation of modules.

Utility description

The configuration of the prefabricated module in transportable reinforced concrete, which can be assembled. anti-seismic and habitable, it is tridimensionally attributable to the geometric shape of the parallelepiped. Dimensionally, however, the module can be traced back to the idea of the common transportable container (figure 1). In fact, although slightly different from those of the classic container, the dimensions of the maximum overall dimensions of the finished module are: width 2.50 m length 5.60 m, height 3.00m "However, in the production of the modules there may be small dimensional variations ( maximum dimensional variation equal to 3%) deriving from finishes and coatings. These dimensions have been chosen for greater ease of both transport, by land and sea, and assembly. The idea relating to this patent arises from the attempt to create real single-family dwellings by using prefabricated modules (although in reality it was subsequently thought that they could also be used with other functions other than residential), which can be customized by the user according to needs. personal and taste inclinations through a series of scenes and finishing options that follow precise modularity criteria. This idea is translated into the realization of the smallest possible number of basic modules and pieces to be assembled, achieving at the same time the most suitable result in the possibility of variant, the final result is a single structural typology of assemblable module consisting of a reinforced concrete structure and a system of internal partitions and external cladding with practically unlimited customization possibilities. To comply with this purpose, the following guidelines were followed: maximum flexibility, in such a way as to allow a very high variation of the assemblies in housing units, to respond to the most diverse requests for cuts and needs; maximum dimensions that can be transported by road (for this reason it was decided to use modules with the dimensions of the container, so as to make both transport and assembly operations more agile and streamlined); possibility of joining together the single units obtained with processing and finishing on site / plant and with on-site joining and sealing allowing various typological aggregations (example of residential typological aggregation shown in figure 7).

The internal ventilation system, the seismic dissipation system, the insulation and waterproofing system, all the systems (water, electrical, photovoltaic, soy-thermal, air conditioning, etc.) and all the internal and external finishes described better in below are only indicative as they are an expression of the umpteenth possibility of making the building (functional unit) made up of the repetition of the module object of this patent usable and functional. It will be demonstrated, through the description of appropriate finishes and systems reported below, that the finished building possesses all the habitability requirements. In fact, Γ aggregation of two or more modules together with this complex of finishes and systems will constitute a real home. The term "home must be understood in a broad sense as the residential function is not the only one conceivable and other forms of use are compatible with the aggregation system of this module (examples: garage, warehouse, home, retirement home, nursing home, hotel, tourist village, farmhouse, camping facilities, wellness center, accommodation facilities in general, restaurant, bar, kiosk, etc.). The flexibility of the modules, juxtaposed and assembled together, further enriched by the possibility of choosing details and partitions, will allow a practically infinite number of housing cuts, arrangements, dimensions, final image, responses to contingent and cultural needs of users. more diversified. Furthermore, through various technical measures of a construction and plant engineering nature, described below, and making use of the simplicity of transport and assembly of the prefabricated modules in question, users will obtain considerable savings in economic and time terms compared to traditional construction techniques.

Structure

The structure of the prefabricated modules is made of reinforced concrete. This structure was calculated with the current legislation on construction (Ministerial Decree, 14/01/2008 and supplementary circular no.

617/2009), considering the most unfavorable geotechnical conditions, and will be recalculated in the event of changes and / or additions to current legislation. One of the technical characteristics of the aforementioned structure is represented by the total load that it can withstand equal to 800 kg / ml on each beam or about 13,000 kg in total (this entails the possibility of overlapping the various modules). The external dimensions of the assembled module structure are 2.50x5.60xH2.80m. The structure in question is composed of: n. 1 reinforced concrete slab at zero height with dimensions 2.50xH5.60m and thickness equal to 10 cm (as better indicated in figure 3); n. 4 reinforced concrete partitions with section 0.15x0.40m placed at the four corners of the module as shown in figure 2; n. 4 reinforced concrete beams at a height of 2.80 with a section of 0.20xH0.30m (figures 5 and 6) due to the development of the perimeter of the structure (as shown in figure 2).

Seismic isolation

Given that the structure of the prefabricated module that can be assembled complies with the current regulations on anti-seismic constructions, a distinction must be made between anti-seismic system and seismic isolation. Very simplistically, in the first case the structure is calculated to withstand the stresses deriving from the earthquake, while with Γ seismic isolation these stresses are transmitted only in part to the structure (about 10-20%) and therefore it follows that if the structure is already able to withstand all seismic stresses for sure it will be able to withstand some of them, thus ensuring even greater resistance and structural safety in the event of an earthquake

Having said this, the seismic isolation system consists in placing under the supports of the single modules some mats consisting of a vulcanized and expanded elastomeric compound with closed cells or neoprene; alternatively, elastomeric insulators with or without lead core or viscous dissipators or materials with chemical-physical characteristics similar to those listed above can be used for this purpose; in any case, all the aforementioned devices perform very well the task of considerably limiting the transmission of stresses in the event of an earthquake.

Ventilation system and external cladding

The ventilation system is applied to the structure of the modules and includes walls and ceiling. This system consists in the construction of an enclosure inside and one outside the parts of the module that will border on the external environment. To this end, special panels of suitable material and with physico-chemical characteristics suitable for carrying out the task of being used as external cladding and as cover of the module in question will be used. As an alternative to panels, hollow bricks, poroton, gasbeton bricks, bricks with a mixture of resin and cement, and any material capable of creating two envelopes with an air chamber in the middle can also be used. The typical section has a cavity that varies from 5 to 15 cm depending on the energy input to be assigned to the ventilation system. The internal dimensions in the aggregation of some modules are therefore slightly variable and will change according to the thickness of the cavity. The systems and insulation will also be inserted inside the cavity. The anchors / supports of the ventilation system vary in shape, size and material according to the application to the wall or ceiling, according to the material used and according to the thickness of the cavity to be made. As regards the perforations of the infill panels for the installation of the fixtures, they will be entirely chosen by the user both in terms of number and shape and size. From the attached drawings, and precisely from figure 7, a functional example of holes in the external infill panels can be seen, which allows air circulation and correct natural lighting.

Ventilated roof

the project of the ventilated roof consists in applying on the aforementioned modules, already equipped with internal ventilation, an additional structure that can be in galvanized steel or alternatively stainless steel, aluminum, laminated wood and any material with structural properties such as to be able to withstand the structural stresses deriving from the own weight of the structure, the cladding materials, the snow load and the load of the wind faction so that an additional ventilation is created above the modules which contributes to the thermal insulation of the assembled module complex. The structure of the ventilated roof will be modular and will use the same modularity as! prefabricated assemblable module object of this patent (figure S). This means that any number of reinforced concrete modules will correspond to the same number of roof modules which, assembled together, will form the ventilated roof structure. The ventilated roof is one of the various additional coverage options that the user can choose. Alternative options will be discussed and planned from time to time.

Internal partitions

The partitions present inside the modules will be made with special panels of suitable material and with physico-chemical characteristics suitable for carrying out the task of being used as internal partitions. Alternatively, hollow bricks, poroton, gasbeton bricks, bricks with a mixture of resin and cement, and any material capable of creating a vertical internal partition wall can also be used.

Floor

The floor will be in laminated parquet strips that can be assembled with or without glue, or alternatively in ceramic, stoneware, resins and cement, terracotta, wood, PVC and any other material that can be used for the flooring and chosen by the user.

Plaster and color coatings for

The external cladding will consist of tiles applied directly to the external walls of the prefabricated modules using suitable glue. This cladding will consist of ceramic tiles, or alternatively assembled laminate tiles, stoneware, resins and cement, terracotta, wood, PVC and any other material with any format that can be used for wall cladding. Alternatively, the external wall cladding can be made up of plaster coatings (Cement plaster or lime plaster or single-layer plaster etc.), by cladding of stone material slabs, by metal cladding, by cladding of book-concrete slabs or from wood siding. The external painting in the case of use of plaster coatings will be of any color requested by the user and can be either potassium silicate-based paint or quartz-flour-based acrylic-siloxane paint. Alternatively, all types of finishing and painting known on the market can be used.

Coatings, plasters and colors for interiors

The lining of the internal walls, with the exception of the toilets and part of the kitchen, is made up of cement plaster finished with any color required by the user, as an alternative to cement plaster, all types of plaster on the market can be used. The cladding of the walls (up to H = 2.00 m) of the sanitary rooms and part of the kitchen will consist of tiles applied to the walls using suitable glue. This coating consists of ceramic tiles, or alternatively laminated parquet tiles that can be assembled. in ceramic, in stoneware, in resins and cement, in terracotta In wood and any other material with any format that can be used for wall cladding, alternatively, the internal wall cladding can be made up of tile cladding, cladding of stone material slabs, metal cladding, fiber cement slab cladding or wood cladding and whatever else corresponds to the tastes of the user.

Waterproofing and insulation

For the waterproofing of the floor and roof, the liquid sheath is used or alternatively the prefabricated sheath based on bitumen with a minimum thickness of 4 mm with polyester reinforcement or any other type of material suitable for carrying out the waterproofing task (eg. asphalt mortar and bkume. etc). Insulation panels with a thickness varying between 5 and 12 cm are used for the insulation. Alternatively, all types of insulation on the market can be used as long as the energy requirements of the building are respected.

External and internal fixtures

The window frames consist of thermal break aluminum profiles with insulated thermoacoustic glass (double glazing) minimum thickness 4 mm and aluminum shutters with RAL painting or wood color. Alternatively, wooden or PVC window frames and shutters will be used with the possibility of using all types of painting: it will also be possible to customize the external frames with shading systems other than those mentioned above (by means of shutters or roller shutters), in any case both the external fixtures and the internal fixtures (doors) will be completely at the user's choice.

Waterworks

The water system used will be placed in the cavity of the walls and the floor and complies with all applicable regulations. It will consist of: 11, 00 ml of high density polyethylene pipe 0 = 20 mm (cold water); 11.00 m of insulated copper pipe 0 = 14 mm (hot water); 9.00 m of high-density polyethylene pipe 0 = 50 mm (secondary drains: washbasins, bidets and showers); 2.00 m of PVC pipe 0 = 100 mm (main drain); n.

11 water points; n. 4 discharge point (with high density polyethylene pipe); n. 1 discharge points (with PVC pipe); n. 1 toilet bowl; n. ì Bidet; n. shower; n. 2 washbasins (kitchen and bathroom); n,! electric water heater: n. 1 sanitary water inlet well (placed). this system is purely indicative as it represents only one of the innumerable possible solutions, the user can customize the system in any way according to his needs and tastes.

Electrical system

The electrical system used will be located in the cavity of the walls and floor and ceiling and complies with all applicable regulations. It will consist of: n. 1 general flush-mounted electrical panel (size 24 DIN modules) consisting of n. 1 differential magnetothermic switch and n. 4 bipolar switches; n. 13 sockets; n. 8 10 A switches (of which 2 are infrared); n, 1 bipolar switch 16 A; n. 5 indoor lighting bodies; n. 4 outdoor lighting bodies: n.l prefabricated well for grounding; n. 1 x 1.50 m grounding pole; 50 ml of PVC-based self-extinguishing thermoplastic conductor; 150 ml of single-core 2.5 mm electrical cables; n. 20 ceiling lights with 18W FLC type lamp; n. 1 complete intercom system; n. 1 entrance door bell. This system is purely indicative as it represents only one of the innumerable possible solutions. the user will be able to customize in any way regretted according to their needs and tastes.

Photovoltaic system and solar-thermal system

The aggregation system of prefabricated assemblable modules is absolutely ready for photovoltaic and solar-thermal regrets.

air conditioning system

The air conditioning is guaranteed through the use of an external machine with two internal splits that will ensure conditions of well-being within the building both in summer and in winter. The finisher will be able to customize in any way he regrets according to his own needs and tastes.

Fire system

The aggregation of modules or functional units may require a fire-fighting system. This system consists of the installation on one of the assembled modules of a foam extinguishing system consisting in simplistic terms of a fire extinguisher applied to the roof with a temperature detector calibrated so as to activate it automatically in the event of a fire.

Transport, assembly and technical specifications of the finished prefabricated module

The modules will be partially finished and prepared for transport and assembly on site / factory. Once ready to be transported (figure 9) and arrived at their destination, they will be assembled (figure IO) forming a functional unit (example: home) as shown in figures 7, 8, 11 and 12. the transport of the prefabricated modules takes place via trucks (figure 10) capable of loading and transporting such modules. The dimensions of each single module (2.50 m x 5.60 m x H 3.00 m) are such as to allow ordinary transport by road as they do not exceed the maximum transportable dimensions. Loaded on the trucks, all the prefabricated modules will be transported to the place where the installation is planned and then proceed with the assembly operations. The modules can be placed directly on the ground on a special base or alternatively they can be raised (at a height of about 50 cm from the ground) by resting on curbs, partitions or rungs in order to avoid direct contact with the underlying surface without the need for leveling the ground and creating a reinforced concrete base. To avoid losing the uniformity of the elevations, this elevation can be hidden by Γ using panels that reflect the geometries AND colors of the elements above. The connection between the different functional units (each formed by the juxtaposition of two or more modules) will take place through Γ direct juxtaposition with subsequent sealing (Figure 10).

The on-site joining of the ventilation system of the various modules takes place through the use of appropriate glue or alternatively with the aid of nails, dowels, screws and anything else that has the property of joining two contiguous surfaces. The ventilated roof system is pre-assembled on site and assembled in modules on site (figures 11 and 12) by bolting. The assembly of the floor in the case of laminate-type parquet can only be partially carried out on site (only along the joining band of the modules) according to an interlocking scheme provided for in the technical specifications of this flooring. If the user chooses another type of floor other than the one mentioned above, he will proceed to assembly entirely on site. The partitions are made on site / plant and will be joined on site according to the needs expressed by the user (architectural project). The assembly of all the systems can take place partly on site / plant and partly on site or entirely on site.

Form aggregation

The assembly of multiple modules, characterized by the same structure, generates a functional unit (example of functional unit shown in Figure 7) to which various intended uses can be attributed (depending on the use chosen by the user). It is emphasized that the module necessary for the constitution of the aforementioned functional unit is always of the same structural type (figure 1 and 2) which is the subject of this patent, in other words all the assembled modules, if stripped of infill panels, partitions, finishes in genus and implants are perfectly identical to each other. With the aggregation of different functional units it is possible to create various complexes of buildings such as garages, warehouses, homes, retirement homes, nursing homes, hotels, tourist villages, agritourisms, camping facilities, wellness centers, accommodation facilities in general, restaurants, bars, kiosks, etc. Furthermore, as already said before, the structure has been calculated in such a way as to withstand a load resting on it equal to about 13,000 kg or 800 kg / ml on each beam. This means that each module can safely resist the loads generated by another stacked module. It will thus be possible to create another floor above ground and have one or more functional units that develop on two levels.

Claims (1)

CLAIMS PREFABRICATED MODULE IN REINFORCED CONCRETE. TRANSPORTABLE. ASSEMBLY. SEISMIC AND HABITABLE 1. Prefabricated module in reinforced concrete, transportable, assembled, anti-seismic and habitable, the load-bearing structure in reinforced concrete is claimed with the maximum overall dimensions; width 2.50m, length 5.60m and height 2.80m (with a maximum tolerance of 3%), calculated according to the current legislation on construction (Ministerial Decree 14/012008 and supplementary circular no. 617/2009), 2. Prefabricated module in reinforced concrete, transportable, assemblable, anti-seismic and habitable, as in the previous claim, characterized by the material used consisting of reinforced concrete with the following minimum characteristics: minimum compressive strength concrete Rck = 250 kg / cmq, class of steel used FeB44k and with all the other characteristics listed in the attached "description". 3. Prefabricated module in reinforced concrete, transportable, assemblable, anti-seismic and habitable, as in the previous claim, characterized by the characteristic of easy transportability as the maximum dimensions (2.50m x 5.60m x H3.00m) allow ordinary transport on road (by land), but also sea transport. 4. Prefabricated module in reinforced concrete, transportable, assembled, anti-seismic and habitable, as in the previous claim, characterized by the characteristic of assembling by means of suitable adhesives or joining systems so as to form together with other modules a functional unit (building) or a complex functional units of completely customizable shape and size and of variable function according to the user's needs (examples: garage, warehouse, home, retirement home, nursing home, hotel, tourist village, farmhouse, camping facilities, wellness center, accommodation facilities in general, restaurant, bar, kiosk, etc.). It should be noted that the assemblability feature provides, in addition to the assembly on a single level, also the possibility for the modules in question to be positioned one above the other with the consequent formation of functional units that develop on two levels. 5. Prefabricated module in reinforced concrete, transportable, assembled, anti-seismic and habitable, as in the previous claim, characterized by special panels, of suitable material and with physico-chemical characteristics suitable to perform the task of being u zza as outdoor and as possible cover and mo u o c e ra as applied coupled (one internal, the other external) to the load-bearing structure so as to form, in addition to a horizontal closure (cover) and one or more vertical closures (walls), a chamber of air for ventilation, where the systems and insulation will also be located and the consequent improvement of the energy parameters of the functional unit results from the aggregation of various modules. 6. Prefabricated module in reinforced concrete, transportable, assemblable, anti-seismic and habitable, as in the previous claim, characterized by the predisposition to all the finishes, devices and systems present in the attached "description" and necessary to make it functional and / or habitable. 7, Prefabricated module in reinforced concrete, transportable, assemblable, anti-seismic and habitable, as in the previous claim, characterized by everything that is claimed and depicted in the attached tables.