FR2854183A1 - Composite roof construction device for building, has covering modules with row of covering units of same nature and different natures respectively placed in different combinations by lateral and longitudinal stopping - Google Patents

Abstract

The device has a reinforcement (4) on which covering modules are fixed. The covering modules have a row of covering units of same nature and different natures respectively placed in different combinations by a lateral and longitudinal stopping of modular supports (1). The modules have a solar sensor connected with a multi-conductor of the support and a wind mechanism fixed in a hollow part of a hollow covering unit. The hollow covering unit has deflectors (26) for deflecting wind on blades of the wind mechanism and an opening for evacuating the air from the modules.

Description

The present invention relates to a device for producing and constituting

  mixed and energetic and composite and monobloc roofs on buildings to cover buildings.

  The implementation to construct the roofs of buildings traditionally involves multiple successive operations which are carried out on the highest part of the building, which can constitute and multiply the risk of accident, especially in windy and rainy periods.

  The implementation for producing and constituting the covering in 10 tiles of the roof of buildings traditionally comprises several operations and relating in particular to the prior and multiple reporting of the gauge of the cover and taking place on the elements of the framework of the roofs, fixing the batten on the roof reinforcement and on the entire reinforcement, positioning 15 of the tiles which are generally laid one by one on the batten of the roof reinforcement, which may constitute long and binding work.

  The tiles, traditionally and predominantly used to cover the reinforcement of the roof of buildings, are generally not fixed to the reinforcement of the roofs, which can constitute risks of lifting of the tiles by the force of sometimes very strong winds and generally exerting strong pressures on the roofs of buildings.

  The implementation for constructing mixed and energetic roofs and in multiple compositions of covering elements of any kind, on the reinforcement of the same roof, generally requires multiple specific adaptations to assemble these different covering elements of any nature and to achieve in particular the waterproofing of the roof of buildings, which can constitute long, restrictive and expensive implementations.

  The thermal insulation of roofs is generally carried out by insulating panels which are fixed between all the elements of the reinforcement, which can constitute long and restrictive implementations.

  The second sealing of the roof of buildings, is generally carried out by a waterproof film which is placed on the elements of the frame and covering all the elements of the frame and which is pinched between the elements of the frame. and an extension fitting to the elements of the frame, which can constitute long and constraining implementations in particular in windy periods.

  The bracing of the roof of buildings, is generally carried out by the installation of spacers and panels which are fixed on the reinforcement of the roofs and connecting all the elements of the reinforcement between them, which can constitute long implementations and binding.

  The installation of solar collectors on the roofs of buildings is generally carried out by installing solar panels on part of the roofs of buildings, which can constitute a significant change in the general appearance of the roofs of buildings, especially when 'These are roofs with a tiled roof.

  Certain roofs include solar collectors which are constituted by tiles respectively provided with solar collectors located on the roof of the tiles, but not eliminating the constraints of implementation and realization of the roof of the buildings 20 previously stated.

  Wind mechanisms producing electrical energy generally have large blades, which does not always allow the installation of a wind mechanism on the roof of buildings.

  The roofs of buildings are sometimes provided with large luminescent panels of a commercial and decorative nature, which can constitute an overload on the roofs of buildings.

  The wooden covering made on the roofs of buildings is generally made up of wooden tiles positioned respectively 30 and nailed at two points on the battening of the roofing reinforcement, which can constitute long and restrictive implementations.

  The device according to the invention overcomes these drawbacks. According to a first characteristic, it in fact comprises a frame on which are fixed covering modules which are respectively constituted by a modular support and by a row of covering elements of the same nature and of different and energetic nature and which are respectively and simultaneously positioned and fixed to the reinforcement of the roofs by a lateral and longitudinal abutment of the modular supports between them, respectively provided with a row of cover elements in an inclined position relative to the laying plane of the modular support and constituting covering modules of the same nature and of a different nature and energetic and in multiple combinations, respectively constituted as a single piece and respectively fixed on the reinforcement of the roofs and with which the covering modules constitute composite and monoblock roofs. The roofs 10 respectively comprise a seal under the cover and which is produced by the modular supports and by lateral and longitudinal interlocking of the modular supports together and constituting a part of each support overlapping the modular supports fixed immediately downstream on the frame of the roof and 15 by a part of each lateral interlocking between supports and overlapping the support fixed immediately downstream on the roof reinforcement and by interlocking the upper end of the cover elements in the supports and constituting a part of the support overlapping the upper end of the row of roof elements which constitute the roof covering. The thermal insulation of roofs is achieved by the nature and thickness of the elements which constitute the roofing modules of the roof of buildings which comprises energy covering modules respectively comprising a modular support provided with an electric multiconductor and the electrical connection of the electrical multiconductors to each other is effected by interlocking of the electrical multiconductors with one another and by lateral interlockings of the energy coverage modules with each other. The roofs comprise cover modules 30 comprising solar collectors which are connected to the multiconductor of the modular supports and which are located on the post of the row of cover elements. The roofs comprise covering modules comprising wind mechanisms which are fixed in the hollow part of hollow covering elements and which are actuated by the force of the wind penetrating into the hollow part of the hollow covering elements which respectively have directing deflectors the wind on the blades of the wind mechanism and an opening through which the wind escapes. The roofs comprise cover modules comprising hollow cover elements which allow the light to pass through and which are respectively provided with an electric multiconductor which is connected to the electric multiconductor of the support and cassettes which fit into the hollow part of the elements of hollow cover and connecting to the multiconductor of the hollow cover elements. The roofs comprise covering modules covering the ridge of the roof of the buildings and which respectively consist of a roof comprising sections provided with solar collectors and a sole covering the ridge of the roof of the buildings and overlapping the modules roof located on either side of the ridge of the roof of buildings and on which are fixed wind mechanisms actuated by the force of the wind which is channeled by the sides and under the sides and directed on the blade system of the 15 wind mechanisms by deflectors and whose sealing between the covering modules is constituted by interlocking and lateral overlaps of the covering modules between them.

  According to particular embodiments: the row of roofing elements can be constituted by tiles.

  - Cover modules can have several rows of cover elements.

  - The row of roofing elements can be made in one piece.

  - The row of cover elements can be made up of juxtaposed and superimposed strands parallel to each other.

  - The modular support can be constituted by a panel comprising a longitudinal boss on which rests a row of covering elements and a face inclined with respect to the plane of laying of the panel and on which is positioned is fixed the row of blanket.

  - The thermal insulation of roofs can be constituted by modular insulating panels fixed under the cover modules and constituting a monobloc with the cover modules. The accompanying drawings illustrate the invention: Figure 1 shows a partial sectional and perspective view of a modular support.

  FIG. 2 represents a partial view in section and in perspective of a longitudinal interlocking between two modular supports respectively provided with a row of covering elements of the same nature and of different nature.

  FIG. 3 represents a partial and perspective view of a roof comprising covering modules respectively provided with a row of tiles.

  FIG. 4 represents a partial perspective view of a roof which comprises an energy cover module comprising a row of tiles respectively provided with a solar collector which is situated on the roof post of the tile. FIG. 5 represents a partial perspective view of a roof which comprises a covering module comprising a covering panel provided with solar collectors situated on the cap of the covering panel.

  Figure 6 shows a partial perspective view of a mixed cover module, comprising two rows of cover elements. FIG. 7 represents a partial perspective view of a modular support comprising an electric multiconductor. FIG. 8 represents a partial view in partial section and in perspective of an energy cover module comprising a row of cover elements respectively provided with solar collectors connected to the multiconductor of the modular support. FIG. 9 represents a partial perspective view of a composite roof comprising mixed energy cover modules comprising a row of hollow cover elements respectively provided with solar collectors and wind mechanisms and overlapping cover modules comprising respectively a row of tiles. FIG. 10 represents a side view and in partial section of a covering module comprising a row of hollow covering elements and respectively provided with a wind mechanism, fixed in the hollow part of the covering element. FIG. 11 shows a partial perspective view of an energy blanket module comprising a row of hollow roofing elements and allowing the light to pass through. FIG. 12 represents a partial perspective view of an energy cover module comprising a row of hollow cover elements and letting the light pass through and a cassette fitting into the hollow part of one of the cover elements. FIG. 13 represents a partial perspective view of a roof which comprises covering modules respectively comprising a row of covering elements made up of strands juxtaposed and superimposed and parallel to each other. FIG. 14 represents a side and partial view of a roof comprising a mixed energy cover module covering the ridge of the roof.

  FIG. 15 represents a partial and perspective view of a composite roof and comprising covering modules of the same nature and of a different nature and energetic and mixed and covering part of the reinforcement of the roof. FIG. 16 represents a partial view in section and in perspective 15 of a covering module comprising a thermal insulation. Constituted by a modular insulating panel, fixed under the covering module and constituting a monobloc with the covering module. FIG. 17 represents a view in section and in perspective and partial of a modular support comprising a longitudinal boss 20 constituting the laying plane of the row of covering elements.

  FIG. 18 represents a partial view in partial section and in perspective of the longitudinal interlocking of two cover modules respectively comprising a modular support having a longitudinal boss on which rests a row of cover elements.

  With reference to these drawings, the device comprises a frame (4) constituted by a traditional frame comprising arcbouted rafters or rafters resting on a supporting ridge or small trusses and on which (4) are fixed covering modules. These cover modules are fixed directly to the reinforcement (4) of the roofs and are respectively constituted by a modular support (1) and a row of cover elements of the same and different nature (2) and energy. (3) and which are 35 respectively (1) (2) (3) and simultaneously (1) (2) (3) positioned and fixed on the reinforcement (4) of the roofs by a lateral and longitudinal abutment of the supports modular (1) between them respectively provided with a row of cover elements (2) (3) in an inclined position relative to the laying plane (5) of the modular support (1) and constituting cover modules of the same kind and of a different nature (2) and of energy (3) and in multiple combinations, respectively constituted as a single piece and respectively fixed on the frame (4) of the roofs and with which (4) the covering modules constitute composite and single-piece roofs . The fixing of the covering modules on the reinforcement (4) of the roofs, constituting the bracing of the roof which is carried out by fixing the modular supports (1) on the reinforcement (4) and at several non-aligned points and now in position the elements constituting the frame (4). The longitudinal abutment between supports (1) constituting an automatic adjustment of the cover post, the width dimension of the modular supports (1) being identical to the length dimension of the cover post. The lateral abutment between supports (1) and covering modules, constituting the longitudinal positioning of the covering elements. The roof of buildings has a second seal which is produced under the cover and which is constituted by the modular supports (1) and by lateral and longitudinal interlocking of the modular supports (1) between them and constituting a part (6) of each support. (1) overlapping the modular supports (1) fixed immediately downstream on the reinforcement (4) of the roof and by a part (7) of each lateral interlocking between supports (1) and 25 overlapping the support (1) fixed immediately downstream on the reinforcement (4) of the roof and by fitting the upper end (8) of the covering elements (2) (3) into the supports (1) and constituting a part (9) of the support (1) overlapping the upper end (8) of the row of covering elements (2) 30 (3) which constitute the covering of the roofs. The thermal insulation of roofs is achieved by the very nature and thickness of the elements that constitute the modules for covering the roof of buildings. The roofs of buildings include roofing modules respectively comprising a modular support (1) which is provided with an electric multiconductor (15). The electrical connection of the multiconductors (15) to each other, effected by interlocking of the multiconductors (15) with one another and by lateral interlockings of the cover modules with one another. The roofs of the buildings include cover modules comprising solar collectors (11) producing electrical energy. These solar collectors are connected to the multiconductor (15) of the modular supports (1). These solar collectors are located on the pole of the row of covering elements. The roof of buildings has cover modules comprising wind power mechanisms (12) producing electrical energy and which are fixed in the hollow part of hollow cover elements (16). These wind mechanisms are actuated by the force of the wind penetrating into the hollow part of the 10 hollow cover elements (16). The hollow cover elements (16) respectively comprise deflectors (17) which direct the wind on the blades of the wind mechanism (12). The hollow cover elements (16) respectively have an opening (18) through which the wind escapes. The roofs of buildings have 15 covering modules comprising hollow covering elements (19) and allowing light to pass through and which are respectively provided with an electric multiconductor (21) which is connected to the electric multiconductor (15) of the support (1 ). These cover modules comprise interchangeable cassettes (20) which fit into the hollow part of the cover elements (19) and which are connected to the multiconductor (21) of the cover elements (19). These cassettes include solar collectors producing electrical energy, luminescent equipment, video equipment, sound equipment and elements of a different nature. The roof of buildings includes roofing modules which cover the ridge of the roof of buildings. These cover modules respectively consist of a small roof comprising panels (25) which are provided with solar collectors (11) producing electrical energy and a sole (27) which covers the ridge of the roof of the buildings and which overlaps the covering modules located on either side of the ridge of the roof of buildings and on which (27) are fixed wind mechanisms (13) producing electrical energy and which are actuated by the force of wind which is channeled by the sides (25) of the perite 35 roof and under the sides (25) of the small roof and directed on the blade system of the wind mechanism (13) by deflectors (26). The sealing between these covering modules which cover the ridge of the roof of buildings, is achieved and constituted by interlocking and lateral overlaps of the covering modules between them.

  According to Figure 3 and Figure 4, the row of roofing elements is constituted by juxtaposed tiles and fixed on the modular support (1).

  According to FIG. 6, the cover modules comprise several rows of cover elements of the same nature and of a different nature (2) and of energy (3) and in multiple combinations.

  According to a variant illustrated in FIG. 5, the row of covering elements (3) is made in one piece.

  According to a variant illustrated in Figure 13, the row of covering elements consists of thatched strands (22) which are juxtaposed and superimposed and parallel to each other and constituting a modular cover panel which is fixed on the support (1). 15 According to a variant illustrated in FIG. 17, the modular support (1) consists of a panel (30) comprising a longitudinal boss (29) on which rests a row of covering elements and a face inclined (24) relative to the plane laying (5) of the panel (30) and on which (24) is positioned is fixed the row of cover elements (2) which consists of wooden tiles.

  According to a variant illustrated in FIG. 16, the thermal insulation of the roofs is constituted by modular insulating panels (10) which are fixed under the covering modules and constituting a monobloc with the covering modules.

The device according to the invention is particularly intended to reduce the implementation time for producing and constituting composite roofs, of sustainable energy technologies and of renewable natures, on the buildings, to cover the buildings.

Claims (7)

claims   1) Device for producing and constituting mixed and energetic and composed and monobloc roofs on buildings characterized in that it comprises a frame (4) on which are fixed covering modules which are respectively constituted by a modular support ( 1) and a row of covering elements of the same and different nature (2) and energy (3) which are respectively (1) (2) (3) and simultaneously (1) (2) (3 ) positioned and fixed on the frame (4) of the roofs by a lateral and longitudinal abutment of the modular supports (1) between them respectively 10 provided with a row of cover elements (2) (3) in an inclined position relative to the laying plane (5) of the modular support (1) and constituting covering modules of the same nature and of a different nature (2) and energy (3) and in multiple combinations respectively consisting of a single piece and respectively fixed on 15 l '' frame (4) itures and with which (4) the cover modules constitute composite and monobloc roofs and which respectively comprise a seal under the cover and which is produced by the modular supports (1) and by lateral and longitudinal sockets of the modular supports (1) between them and constituting a part (6) of each support (1) overlapping the modular supports (1) fixed immediately downstream on the frame (4) of the roof and by a part (7) of each lateral interlocking between supports (1) and overlapping the support (1) fixed immediately downstream on the reinforcement (4) of the roof and by fitting the upper end (8) of the covering elements (2) (3) in the supports (1) and constituting a part (9) of the support (1) straddling the upper end (8) of the row of covering elements (2) (3) which constitute the covering of roofs whose thermal insulation is made by nature and thick sseur of the elements which constitute the roofing modules of the roof of buildings which comprises roofing modules respectively comprising a modular support (1) provided with an electric multiconductor (15) and whose electrical connection of the electric multiconductors (15) between they are carried out by interlocking of electrical multiconductors 35 with one another and by lateral interlocking of roof covering modules which comprises covering modules comprising solar collectors (11) which are connected to the multiconductor (15) of modular supports (1) and which are located on the column of the row of covering elements and covering modules comprising wind mechanisms (12) which are fixed in the hollow part of hollow covering elements (16) and which are actuated by force wind penetrating into the hollow part of the hollow covering elements (16) which respectively have deflectors (17) directing the wind on the blades of the wind mechanism (12) and an opening (18) through which the wind escapes and covering modules comprising hollow covering elements (19) and 10 allowing the light to pass through and which are respectively provided an electric multiconductor (21) which is connected to the electric multiconductor (15) of the support (1) and cassettes (20) fitting into the hollow part of the hollow cover elements (19) and connecting to the multiconductor (21 ) hollow cover elements (19) and cover modules covering the ridge of the roof of buildings and which respectively consist of a roof comprising sections (25) provided with solar collectors (11) and a sole (27) covering the ridge of the roof of buildings and overlapping the cover modules located on either side of the ridge of the roof of buildings and on which (27) are actuated wind mechanisms (13) by the force of the wind which is channeled by the flaps (25) and under the flaps (25) and directed on the blade system of the wind mechanisms (13) by deflectors (26) and whose sealing between the cover modules 25 is formed by interlocking and lateral overlaps of the cover modules with each other.   2) Device according to claim 1 characterized in that the row of cover elements is constituted by tiles.   3) Device according to any one of the preceding claims, characterized in that the covering modules comprise several rows of covering elements (2) (3).   4) Device according to any one of the preceding claims, characterized in that the row of covering elements (2) (3) is made in one piece. 35 5) Device according to any one of the preceding claims, characterized in that the row of covering elements consists of strands (22) juxtaposed and superimposed and parallel to each other.   6) Device according to any one of the preceding claims, characterized in that the modular support (1) consists of a panel (30) comprising a longitudinal boss (29) on which rests a row of cover elements and an inclined face (24) relative to the laying plane (5) of the panel (30) and on which (24) is positioned is fixed the row of cover elements (2).   7) Device according to any one of the preceding claims, characterized in that the thermal insulation of the roofs 10 is constituted by modular insulating panels (10) fixed under the cover modules and constituting a single piece with the cover modules.