ITPD20080240A1 - INDUSTRIAL OR CIVIL MODULAR COVER - Google Patents

Description

INDUSTRIAL OR CIVIL MODULAR COVERAGE

DESCRIPTION

This patent relates to industrial and civil roofing and in particular concerns a new modular roofing for industrial or civil buildings suitably conformed for the installation of fully integrated photovoltaic systems.

Covers are particularly known for buildings with large spans, intended for industrial or civil use, comprising a plurality of panels or cupels designed to be laid on parallel Y beams in prestressed concrete of the roofing of the building.

In particular, flat or corrugated panels made of asbestos cement, a resistant material with good thermal insulation capacity, are known. Since the 1990s, following studies that have verified the health risks caused by the inhalation of asbestos dust, regulations have been enacted that provide for the prohibition of using asbestos, the obligation to register artefacts containing asbestos and to perform a risk analysis on the artifacts themselves to evaluate any remediation operations.

The use of ribbed elements laid on Y-beams is known to replace the asbestos-fiber cement roofing.

Known panels for industrial and civil roofing are generally flat or corrugated, possibly coated at the bottom with polyester or other heat-insulating material. The roofs made up in this way can also include the use of waterproofing sheaths and vapor barriers.

Provisions have recently been issued regarding photovoltaic systems which provide for an increase in economic incentives for photovoltaic systems which, in addition to producing energy, take into account in their construction phase, the total functional and architectural integration with the building on which such implants are installed.

In particular, the functional integration of the system consists in the implementation of dependent processes between the photovoltaic system and the roof or facade on which the system is installed

Architectural integration, on the other hand, consists in limiting the visual impact of the panels, avoiding highlighting or making the effect of subsequent application of the photovoltaic system appear.

The same provisions provide for a further increase in the incentive if the construction of the new photovoltaic system is combined with the removal of roofing or facade cladding made of fiber cement containing asbestos fibers and / or the significant improvement of the building's insulation parameters.

These provisions in fact aim to encourage investments in structural changes to buildings with the aim of limiting energy consumption.

In order to satisfy the relevant provisions, a new type of modular roofing for prefabricated structures was studied and created, with elements for the installation of fully integrated photovoltaic systems. The main task of the present invention is to provide industrial or civil roofs which allow the total functional and architectural integration of photovoltaic panels with the roof itself, in compliance with the provisions relating to photovoltaic systems.

The present invention also exploits the large surfaces of the roofs of industrial buildings for the integrated installation of photovoltaic panels, realizing the best solar irradiation conditions to obtain high yields. The new roof also maximizes the yield from photovoltaic systems ensuring optimal lower ventilation of the panels.

Another object of the present invention consists in being able to replace the asbestos fiber cement roofing with roofing having mechanical and energetic performances equal to or superior to the pre-existing roofing, satisfying the provisions of the law.

Another advantage of the present invention is that it can be installed quickly, allowing immediate covering and securing of the spaces.

The new modular roofing has a weight per square meter lower than or equal to the known roofing in asbestos fiber cement.

Another object of the present invention is to ensure structural resistance and water and wind tightness.

Another object of the present invention is to provide insulated roofs, to contain the energy consumption of heating and / or cooling of the underlying environments and also respecting the provisions of the law on the subject.

Another object of the present invention consists in being predisposed to the integrated installation of photovoltaic panels, which can be installed either during the first assembly of the new roof or even afterwards.

Another object of the present invention is to contain the costs of installation, maintenance and also of any subsequent removal, further facilitating these operations given the modular nature of the cover itself.

Another advantage of the present invention consists in the fact of reducing the bulk in the warehouse and during the transport phase, thanks to the modularity of the new cover which allows the stacking of the modular elements.

These and other direct and complementary purposes are achieved by the new industrial or civil modular roof for prefabricated structures, with elements for the installation of fully integrated photovoltaic systems. The new roof includes in its main parts a plurality of modular elements or modular cupels designed to be installed on prefabricated structures and in particular each modular element being able to be positioned and fixed to two parallel beams for example Y of the building structure and constrained to the adjacent modular elements to form a continuous cover between each pair of Y-beams.

In the preferred embodiment, each of said modular elements comprises a body preferably made of compact thermoformed polycarbonate, said body having a rectangular plan and a cross section of the â € œshedâ € type, ie substantially with an inverted V, comprising at least a first flat part and at least a second flat part, connected between them to identify an upper ridge along the longitudinal edge joining the two parts, and where the lower longitudinal edges of each flat part constitute the two support bases of the modular element to the wings of the beams Y.

Said modular elements therefore form a shed-type cover, where, once said modular elements have been correctly laid and constrained on the Y-beams, said main flat part is preferably inclined with respect to the ground line, while said second flat part is preferably vertical, i.e. orthogonal to the ground line.

Said main flat part, inclined, is also shaped with at least one seat or housing for the integrated installation of photovoltaic panels, arranged parallel to the storage plane of said inclined flat part itself, embedded in the thickness of the modular element and optimally oriented towards the sun.

In particular, at least said main flat part is ribbed, ie comprising a plurality of ribs or ribs arranged in the transverse direction of inclination, and preferably involving the entire width of the main flat part itself.

Said ribs comprise one or more seats or depressions aligned in a direction preferably orthogonal to the direction of the ribs themselves, suitable for housing one or more fixing profiles of said photovoltaic panels.

Each of said ribs further comprises two elevations, each in correspondence with their lower and upper end parts, near the lower longitudinal support edge and the upper longitudinal or ridge edge of said main flat part, and where said elevations identify said seat between them for housing the photovoltaic panels. The height of said elevations, ie the depth of said housing, is preferably at least equal to the thickness of said panels, which are therefore completely embedded in the total thickness of the modular element.

These elevations have the additional function of allowing the channeling and circulation of air under the photovoltaic panels inserted in the housing, between said ribs of the main flat part.

Also said second vertical flat part preferably comprises a plurality of stiffening ribs arranged transversely, ie they are vertical.

Each of said modular elements also comprises lateral transverse edges or overlaps shaped for coupling with adjacent modular elements. This coupling preferably takes place by partially overlapping said transverse edges and by interlocking fixing or by means of fixing means.

The new roof also includes one or more fastening elements of said modular elements to the Y beams. Said modular roof includes one or more pairs of benches or sheet metal profiles anchored to the opposite wings of the two adjacent Y beams and on which they rest and are fixed the support bases of said modular elements.

The new roof can also comprise at least one layer of insulating material foamed or applied to the lower surface of said modular elements and further layers of insulating material applied to the wings of the Y-beams and adequately protected by applying a bituminous sheath. To ensure higher capacities for higher loads, for example due to accidental loads or snow, the new roof can also include one or more metal reinforcement frames suitable for being integrated into said modular elements and in turn constrained to said Y-beams or to said pallets. or sheet metal profiles by means of metal fastening means.

In the attached tables a practical embodiment of the invention is presented, by way of non-limiting example.

Figure 1 shows a front view of the new roof (C) installed on two adjacent parallel Y beams (T), while figure 2 shows in detail the cross section of the new roof (C) installed on two parallel beams. Y (T).

Figures 2a and 2b respectively show, in detail, a cross section of a modular element (M) and a cross section of the benches or sheet metal profiles (A1, A2) for fixing said modular elements to the wings (A1, A2) of the Y-beams (T).

Figure 3 shows a three-dimensional view of the new roof (C) with photovoltaic panels (F) installed and integrated into the modular elements (M) making up the roof (C).

Figure 4 shows a longitudinal section of the main flat part (M1), where the ribs (N) and the lateral transverse edges (M11, M12) for coupling to aligned modular elements (M) are visible in section.

Figure 5 shows a three-dimensional view of the new roof (C) with photovoltaic panels (F) installed and integrated in the modular elements (M) and lower sheet metal ceiling (S).

Figure 6 shows a cross section of the new roof (C) with lower sheet metal ceiling (S).

The new industrial or civil roof (C) includes a plurality of modular elements (M) suitable for installation on prefabricated structures, for example Y (T) beams in reinforced concrete.

Each modular element (M) is able to be positioned and fixed to two parallel Y (T) beams of the building structure and constrained to the adjacent modular elements (M) aligned in the direction of said Y (T) beams, to form a continuous cover between each pair of Y (T) beams.

Each of said modular elements (M) comprises a body having a rectangular plan and a transverse section of the â € œshedâ € type, i.e. substantially with an inverted V, comprising a main flat part (M1) and a second flat part (M2) connected to said main flat part (M1) to form an upper ridge (M5), and where the lower longitudinal edges (M41, M42) of each flat part (M1, M2) constitute the two support bases of the modular element (M) to the wings (T1) of the Y beams (T) side by side.

Said modular elements (M) aligned therefore form a shed-type cover, schematized in part in figure 3, where said main flat part (M1) is inclined with respect to the ground line, while said second flat part (M2) is substantially vertical, that is, orthogonal to the ground line.

Said main flat part (M1), inclined, is also shaped for the integrated installation of photovoltaic panels (F), arranged parallel to the storage plane of said main flat part (M1) inclined itself. At least said main flat part (M1) is ribbed, ie comprising a plurality of ribs (N) or Greek ribs arranged in the transverse direction of inclination, and preferably involving the entire width of the main flat part (M1) itself.

Said ribs (N) comprise one or more seats or depressions (E) aligned in a direction preferably orthogonal to the direction of the ribs (N) themselves, suitable for housing one or more fixing profiles (D) of said photovoltaic panels (F ).

Each of said ribs also comprises two elevations (N1, N2), each in correspondence with their lower and upper terminal parts, near the lower longitudinal edge (M42) of support and the upper longitudinal edge or ridge (M5) of said flat part main (M1), and where said elevations (N1, N2) identify between them the housing (H) of the photovoltaic panels (F).

The height of said terminal elevations (N1, N2), i.e. the depth of said housing (H), is at least equal to the thickness of said panels (F), which are therefore completely embedded in the total thickness of the modular element (M).

Said fixing profiles (D) of the panels (F) protrude from said hollows (E) to distance said photovoltaic panels (F) from said ribs (N) in such a way as to identify a cavity (H1) for circulation of the air below said panels (F). The air is conveyed in said cavity (H1) through said elevations (N1, N2) and circulates in the grooves identified between the ribs (N).

Also said second vertical flat part (M2) preferably comprises a plurality of stiffening ribs arranged transversely, ie vertical.

The new roof is suitable for being adequately insulated, as shown in figures 2 and 4. It is in fact foreseen that at least one layer of insulating material (B) is foamed or in any case applied to the lower surface (M5) of said modular elements (M) , with or without lower coating (L) in micro-perforated sheet metal.

The use of at least one further layer of insulating material (B1) applied and integral with the upper surface of each of the wings (A) of said Y beams (T) is also envisaged, for the insulation of the same.

It is also envisaged the use of at least one element (B2) in insulating material with a prevalently longitudinal development, with a polygonal section having a support surface (B21) to said wing (T1) of the relative Y-beam (T) and a surface opposite (B22) of indirect support of the relative lower edge (M41, M42) of said modular element (M). Said insulating element (B2) is suitable for joining said insulating layer (B) of said modular element (M) and said insulating layer (B) of each of said wings (T1), guaranteeing continuity in the insulation.

In order to anchor said modular elements (M) to said Y beams (T), the new cover (C) includes one or more pairs of pallets or fixing profiles (A1, A2) in sheet metal of said modular elements (M) to said opposite wings (T1) of said Y-beams (T), represented in figure 2b.

Each bench (A1, A2) is folded to identify a first anchoring seat (A11, A21) for the insertion of the corresponding wing (T1), and where a terminal (A14, A24) anchors to the lower part of said wing (T1).

Each bench (A1, A2) also preferably comprises a second seat (A12, A22) for the insertion of the corresponding insulating element (B2), having a substantially flat part (A15, A25), corresponding to said support surface (B22 ) of said insulating element (B2), for the support and fixing of the corresponding lower longitudinal edges (M41, M42) of said modular elements (M).

This fixing takes place for example by means of fixing means such as screws (V) inserted in said lower edges (M41, M42), in said flat parts (A15, A25) of said benches (A1, A2) and in said insulating elements (B2) .

Each bench (A1, A2) further comprises an anchoring terminal (A13, A23) able to be interposed under said insulating layer (B1) of said wing (T1).

Said insulating layers (B1) of said wings (T1) and said insulating elements (B2) are upper coated with waterproofing sheath (G), preferably bituminous sheath, constrained between said flat part (A15, A25) of the bed (A1, A2) and said lower edge (M41, M42) of the modular element (M). It is also envisaged that each of said modular elements (M) comprises along each of said lower support edges (M41, M42), an apron (M31, M32) for the drainage of meteoric water.

For the assembly of the cover (C), each of said modular elements (M) includes lateral transversal edges (N31, N32) shaped for coupling with adjacent modular elements (M).

Said lateral transversal edges (N31, N32) are preferably shaped like an inverted U, as shown in figure 4, and where one of the lateral transversal edges (N31) is suitable for overlapping with the opposite edge (N32) of the modular element (M ) adjacent.

To ensure higher capacities, for example in the event of accidental loads or snow, the new roof (C) can include one or more metal reinforcement frames (P) comprising at least one section of a shape corresponding to the section of said modular elements (M). to be integrated with the relative modular element (M).

In detail, as shown in figure 6, said reinforcement metal frame (P) is inserted and constrained within a groove identified on the lower surface (M5) of said modular element (M) by said ribs (N) or Greek, and comprising brackets (P1, P2) for supporting and fixing to said Y beams (T) or to said benches (A1, A2).

To allow the creation of a flat ceiling below said modular elements (M) constituting the roof (C), the use of brackets (Q1, Q2) and fixing means (Q11, Q21) to said benches (A1, A2) of one or more panels (S) placed substantially horizontal under said modular elements (M), to create said flat ceiling.

These are the schematic modalities sufficient for the skilled person to realize the invention, consequently, in concrete application there may be variations without prejudice to the substance of the innovative concept.

Therefore, with reference to the preceding description and to the attached table, the following claims are expressed.

Claims (1)

CLAIMS 1. Industrial or civil modular roof (C) for prefabricated structures comprising one or more modular elements (M) or shed-type cupels, each comprising an inclined main flat part (M1) and a second vertical flat part (M2) joined to said main flat part (M1) to form an upper ridge (M5), and where the lower longitudinal edges (M41, M42) of each flat part (M1, M2) constitute the two support bases of the modular element (M) at the opposite wings (T1) of two Y-beams (T) side by side, characterized by the fact that on the upper surface (M5) of said main flat part (M1) there is at least one seat or recess (H) for housing one or more photovoltaic panels (F) arranged parallel to the main flat part (M1) itself, and where the depth of said housing (H), is at least equal to the thickness of said photovoltaic panels (F), which are completely embedded in the thickness total of the element or modular (M). 2. Industrial or civil modular cover (C), as per claim 1, characterized by the fact that at least said main flat part (M1) is ribbed, comprising a plurality of ribs (N) or Greek arranged in the direction of inclination of the flat part (N1) itself, each of said ribs (N) comprising two elevations (N1, N2) in correspondence with their opposite end parts, between which said housing (H) of said photovoltaic panels (F) is identified, and where said terminal elevations (N1, N2) have a height at least equal to the thickness of said photovoltaic panels (F). 3. Industrial or civil modular cover (C), as per claims 1, 2, characterized in that said ribs (N) comprise one or more seats or depressions (E), placed between said terminal elevations (N1, N2), called hollows (E) being aligned in a substantially transverse direction to the direction of said ribs (N) for housing one or more fixing profiles (D) of said photovoltaic panels (F), and where said fixing profiles (D) they protrude from said hollows (E) to distance said photovoltaic panels (F) from said ribs (N) to such an extent as to identify a cavity (H1) for the circulation of the air below said panels (F). 4. Industrial or civil modular cover (C), as per the previous claims, characterized by the fact of comprising at least one layer of insulating material (B) applied and integral with the lower surface (M6) of said modular elements (M), with or without lower coating (L) in micro-perforated sheet metal. 5. Industrial or civil modular covering (C), as per the preceding claims, characterized in that it comprises at least one further layer of insulating material (B1) applied and integral with the upper surface of each of the wings (A) of said Y beams ( T), and at least one element (B2) in insulating material with prevalently longitudinal development, with a polygonal section having a support surface (B21) to said wing (T1) of the relative Y-beam (T) and an opposite surface (B22) indirect support of the relative lower edge (M41, M42) of said modular element (M), said insulating element (B2) being able to join said insulating layer (B) of said modular element (M) and said insulating layer (B) of each of said wings (T1). 6. Industrial or civil modular cover (C), as per the previous claims, characterized by the fact of comprising one or more pairs of pallets or fixing profiles (A1, A2) in sheet metal of said modular elements (M) to said wings (T1 ) opposed by said Y beams (T), each bench (A1, A2) being folded to identify: â € ¢ a first seat (A11, A21) for anchoring for the insertion of the corresponding wing (T1); â € ¢ a second seat (A12, A22) for the insertion of the corresponding insulating element (B2), having a substantially flat part (A15, A25), corresponding to said support surface (B22) of said insulating element (B2 ), for the support and fixing of the corresponding lower longitudinal edges (M41, M42) of said modular elements (M); â € ¢ an anchoring terminal (A13, A23) adapted to be interposed under said insulating layer (B1) of said wing (T1). 7. Industrial or civil modular covering (C), as per the preceding claims, characterized in that said insulating layers (B1) of said wings (T1) and said insulating elements (B2) are upper coated with waterproofing sheath (G), said sheath (G) being constrained between said flat part (A15, A25) of the shelf (A1, A2) and said lower edge (M41, M42) of the modular element (M). 8. Industrial or civil modular cover (C), as per the preceding claims, characterized in that each of said modular elements (M) comprises, along each of said lower support edges (M41, M42), an apron (M31, M32 ) for the drainage of rainwater. 9. Industrial or civil modular cover (C), as per the previous claims, characterized by the fact that each of said modular elements (M) includes lateral transversal edges (N31, N32) for coupling with adjacent modular elements (M), said lateral transversal edges (N31, N32) preferably being shaped like an inverted U, and where one of the lateral transversal edges (N31) is suitable for overlapping the opposite edge (N32) of the adjacent modular element (M). 10. Industrial or civil modular cover (C), as per the preceding claims, characterized by the fact that it comprises one or more metal reinforcement frames (P), each comprising at least one section of shape corresponding to the section of said modular elements (M) suitable for to be integrated in the relative modular element (M), being inserted and constrained within a groove identified on the lower surface (M5) of said modular elements (M) by said ribs (N) or Greek, and comprising brackets (P1, P2) of supporting and fixing to said Y beams (T) or to said benches (A1, A2). 11. Industrial or civil modular cover (C), as per the preceding claims, characterized in that it comprises brackets (Q1, Q2) and fastening means (Q11, Q21) to said benches (A1, A2) of one or more panels ( S) placed substantially horizontal under said modular elements (M), to create a flat ceiling.