FR2501755A1 - Solar energy trap - includes panel of dark fibres-contg. cement and second plastics panel - Google Patents

Abstract

Solar energy trap uses plain, undulating or ribbed panels of dark coloured fibre-filled cement as a 'thermal diode' to capture incident heat and release it to a gaseous heat exchange fluid flowing over or beneath the cement panel. The gaseous carrier, pref. air, is enclosed between the fibrocement panel and a second impermeable panel mounted above or beneath the fibrocement on spacers deeper than any variations in the surface profile of the cement panel. The second panel is pref. of polyester, PVC or polycarbonate, opt. reinforced. Suitable in appearance and structure for application to complete conventional roof structures without introducing problems of anchoring independent structures or a strongly contrasting appearance. Simple, robust, esp. suitable for agricultural applications.

Description

 The subject of the invention is a solar covering or cladding system using flat, corrugated or ribbed fiber cement sheets, making it possible to convert and recover energy in the form of hot air. solar radiation thanks to the solar thermal properties of the material, while ensuring the traditional functions of roofing or cladding elements.

 For the production of integrated solar collectors, it is known to use a glazing arranged above an absorbent surface enclosed in an insulated trunk, these elements being held by a profiled frame which ensures the mechanical rigidity and the tightness of the 'together.

 The complexity and heterogeneity of such a system does not make it possible to ensure the traditional functions of a roofing or cladding over the long term without a high initial cost and frequent maintenance of the solar collectors.

 In addition, the solar collectors thus produced impose characteristics of air passage sections, direction of flow and connection incompatible with most possible thermal uses of air collectors. The significant needs for local heating or drying of mainly industrial or agricultural products can hardly be met by solar collectors of this kind.

 To these technical design problems are added those relating to the integration into the architecture of buildings, mainly in existing buildings, which limits all the possible applications of such solar collectors.

 The various drawbacks described above and encountered on currently existing systems constitute as many obstacles to their industrialization and therefore to the significant reduction in their manufacturing costs.

The present invention specifically aims to remedy these drawbacks by proposing a solar roofing or cladding system based on the use of fiber cement products allowing - good performance of the solar absorber thanks to the optimal use of
solar thermal properties of the fiber cement material.

- perfect integration of the roofing or solar cladding into the cons
truction through the use of standardized industrial products and very
widespread in roofing and cladding of agricultural and industrial buildings
mainly.

- a much lower investment cost than existing solar collectors,
solar roofing or cladding using elements
common and easy to use.

It is essentially in the mode of association of the constituent elements that the novelty of the invention resides. She permits; while retaining the principles of traditional implementation of corrugated materials (laying by covering), ensuring the recovery of solar energy by the use or not of the greenhouse effect.

Corrugated or ribbed flat plates in fibers-iment of dark reel with fcrt coeffirient 3'absorbptic) n of solar radiation t-rerment the ne them with the air which circulates behind or in front of the absorbent plates.

 Such a solar absorber has good thermal performance due to the thermal diode effect obtained with the fiber-cement material which promotes the transmission of solar energy to the heat transfer fluid while limiting losses in the opposite direction, and the he thermal regulator effect of solar radiation absorbs thanks to the appropriate heat capacity of the fiber-cement material which absorbs sudden variations in sunlight.

The flat, corrugated or ribbed absorbent fiber cement sheets can be optionally lined, partly on the top, with corrugated sheets of glass or transparent plastic to obtain the greenhouse effect. The plastic used will be, for example, polyester reinforced with calendered glass fibers or extruded polyvinyl chloride. In certain applications, calendered or extruded cellular polycarbonate and formed into corrugated sheets will be preferred for its excellent optical and thermal insulation qualities. In another case, it
In another case, it is also possible to double at the bottom the planar or corrugated absorbent fiber cement sheets with corrugated or ribbed flat plates mainly made of cement fibers. We can also provide additional rear insulation using panels thermal insulation with flat, wavy or ribbed surfaces.

 The constituent elements of the solar collector according to the instruction are made integral by means of linear spacers perpendicular to the undulations of the plates and to the right of the fastenings which, ensure the cohesion of the cover or the solar cladding and maintain a spacing between the plates covering or cladding to ensure an air passage section calculated according to the air flow and temperature required for the thermal installation.

The direction of air circulation in the roofing or solar cladding, according to the invention, is independent of the direction of the corrugations of the plates. Indeed, the aerodynamic shape of the spacers does not oppose significant resistance to the transverse circulation of air, which allows any parallel, perpendicular or diagonal circulation with respect to the ondulatintis
Thanks to this freedom of air circulation in the roofing or solar cladding, the air inlets and outlets can be done easily.
either free or boxed cover or cladding, or punctually through special connection plates which simply replace a current cover plate.

 If collecting boxes or special connection plates are used, the connection between solar cover and thermal installation is ensured by a network of suction or blowing ducts.

 The invention will be better understood on reading the description which follows and on examining the appended drawings which show, by way of nonlimiting examples, some embodiments of solar energy recovery elements according to the invention .

Figures i and 2
Cross and longitudinal sections of an insulated solar greenhouse covering or cladding, with air circulation in front of the corrugated fiber cement sheets.

Figures 3 and 4
Cross and longitudinal sections of an insulated solar roofing or cladding, with greenhouse effect, with air circulation behind the corrugated fiber cement sheets.

Figures 5 and 6
Cross and longitudinal sections of a roofing or solar cladding without greenhouse effect with corrugated fiber cement sheets.

Figures 7 and 8
Cross and longitudinal sections of a roofing or solar cladding without greenhouse effect with insulating flat fiber cement insulated sheets.

Figures 9 and 10
Aerial view and longitudinal section of an example of general mounting of the solar cover according to the invention.

 Each embodiment of solar roofing or cladding from corrugated or flat fiber cement sheets is different as presented in the examples below, depending on whether it integrates the greenhouse effect insulation and front ventilation functions. or back.

Example 1: insulated solar roofing or cladding, with greenhouse effect, with air circulation in front of the corrugated fiber cement sheets.

 Figures 1 and 2 show us in section an embodiment where we see the corrugated fiber cement plate 1 playing the role of a cover or a waterproof cladding as well as absorber of solar radiation thanks to a matt coating dark, preferably black, or else to a treatment in the mass of the material and pre-insulated from the rear using an insulator (2) to the profile of the corrugated plate, preferably of rigid plastic foam.

 It is surmounted by a transparent plastic corrugated sheet cover (3) with 1 and a half wave of overlap to ensure good airtightness, which is maintained at a determined distance, by a set of tabs (4), depending the air flow and temperature characteristics necessary for the thermal installation.

 These spacers are linear and perforated in order to offer minimal resistance to the passage of ais in the direction of the undulations. They are made from two flat strips constituting its wings and a wavy strip with a profile preferably identical to that of the corrugated plate.

 The interlayer will generally be made of metal or plastic and assembled by welding or gluing.

Example 2: insulated solar cover or cladding, with greenhouse effect, with air circulation behind the corrugated fiber cement sheets.

 Figures 3 and 4 show in section an embodiment which differs from the previous one essentially by its type of air circulation.

We find the corrugated fiber cement board (l) absorbban.te vis I vis the solar radiation, with an insulator 2 this time away from the cover to allow, indifferently, the transverse or longitudinal circulation of air compared ripples. The insulation, preferably made of polystyrene, one not expanded, has at least SuT7des faces a corrugation similar to that of the corrugated plate, with at the edge of each insulating panel sockets with grooves and tabs ensuring good airtightness.

 The distance between the corrugated plate and the insulation is obtained in this case by a linear boss (3) of the corrugated face of the insulation at the level of the fasteners. The spacing can be increased by using the tab in the previous example.

 In order to maintain the optimum spacing necessary to create the greenhouse effect, the glazing in transparent plastic corrugated sheet (4) is placed on a set of spacers (5) of the rigid and corrugated strip type at low amplitude, metallic or plastic.

Example 3: solar roofing or cladding without greenhouse effect with corrugated fiber cement sheets.

 The embodiment according to FIGS. 5 and 6 presents a type of roofing or solar cladding for large air flows requiring a large spacing between the roofing and the under-roofing.

 In this case the two cover plies in corrugated fiber cement sheets (1) ett2; the top plate being treated absorbing solar radiation, are strongly spaced by metal spacers (31 of the lattice beam type made up of a concrete iron core bent according to the drawing of the figures and welded to a large flat iron as a lower member and to an angle with unequal wings for the upper chord.

 If the interlayer has sufficient mechanical strength, it can then replace the cover support failures.

Example 4: solar roofing or cladding without greenhouse effect with sub-roofing in insulated fiber cement flat sheets.

 Figures 7 and 8 show a variant of the previous embodiment.

 The corrugated absorbent and solar radiation plate is associated with an under-roof (2) of flat fiber-cement plates laminated with insulating panels (3).

 The ibres-eiment flat plate is chosen in preference to the corrugated plate if the air circulation is preferentially in the direction of the corrugations, thus guaranteeing a constant cross-section.

 The spacing being smaller than in the previous embodiment, it can be ensured by a double corrugated interlayer (4) or else by the superimposition of two dividers similar to those used for Example 1.

 Figures 9 and 10 show an example of general mounting of the solar cover from corrugated fiber cement sheets according to Example 1 clearly show the path of the air in the roof.

 In FIG. 9, the outside air inlets take place along the ends of the cover (1) and (2) 1 left free at the level of the sandpit and the ridge. The edges of the cover are closed by a simple airtight shutter (3) incorporated in the solar cover.

 The air flows in the direction of the corrugations inside the cover before directing itself towards the various points of tapping (4) located on special plates of connection to the module of the current plates in fiber cement.

FIG. 10 shows us in section the solar cover according to example 1 with the corrugated fiber-cement plate (1), the thermal insulation (2), the undulating glazing (3 and the interlayer (14). the air entering (5) and (6) is sucked by the connection plate (7) into the ventilation network (8) of the thermal installation
The simplicity of design and implementation of the roofing or solar air cladding from fiber cement sheets object of the present invention makes it easy to install on all types of new or existing buildings. solarization of a roofing or cladding in corrugated sheets does not involve the removal of the initial roofing and allows the use of it as solar absorber or under-roofing. This possibility is particularly interesting for the improvement of existing roofs or cladding and widely used in industrial and agricultural buildings, especially in the context of energy savings.

 Of course, the invention is in no way limited to the embodiments described above and which have only been shown as examples.

 In addition it is quite obvious that without making novation to the present patent, the principle described above applies as well to a cover as to a cladding whatever its profile.

Claims (13)

 1. Solar roofing or cladding system using flat, corrugated or ribbed fiber cement sheets to ensure the conversion and recovery, in the form of hot air, of the energy of solar radiation thanks to the properties solar thermal of the material, while ensuring the traditional functions of the elements of cover or cladding.  2. A solar air covering or cladding system according to claim 1 characterized in that the solar absorber is a flat, corrugated or ribbed plate of dark-colored fiber cement with a high absorption coefficient of solar radiation.  3. Solar air covering or cladding system according to claims 1 and 2 characterized in that the fiber cement material behaves like a thermal diode, storing and regulating the recovered solar energy.  4. Solar air roofing or cladding system according to claim 1 characterized in that the fiber cement plate can be lined at the top with a corrugated or ribbed plate of glass or transparent plastic to obtain the effect. Greenhouse.  5. Solar air cladding or cladding system according to claim 4 characterized in that the corrugated or ribbed plate in transparent plastic can be polyester reinforced with glass fibers, pplyvinyl chloride or polycarbonate in solid panel or alveolar.  6. Solar air covering or cladding system according to claim 1 characterized in that the fiber cement plate can be lined at the bottom with a flat, corrugated or ribbed plate.  7. Solar air covering or cladding system according to claims 1 to 6 characterized in that the heat transfer fluid is the air which circulates in front of and / or behind the absorbent fiber-cement plate.  8. Solar air covering or cladding system according to claim 7 characterized in that the air can circulate in a direction independent of the corrugations of the plates due to the aerodynamic shape of the spacers.  9. Solar air covering or cladding system according to claim 8, characterized in that special linear spacers make it possible to maintain a spacing between the two covering or cladding plates adapted to the required air flow and temperature. to the thermal installation.  10. Solar air covering or cladding system according to claims 7 to 9, characterized in that the air inlets and outlets can be made in the middle of the cover by means of special plates for punctual connection to the module. common cover plates.  11. A solar air covering or cladding system according to claim 1 characterized in that it can include rear thermal insulation in a panel with flat, undulating or ribbed surfaces.  12. Solar air covering or cladding system according to claim 11 characterized in that the insulating panel has integrated bosses, mainly in line with the fasteners, which act as spacers between the fiber cement board and the 'insulating.  13. Solar air covering or cladding system according to claims 1 to 12 characterized in that it can be applied to any existing construction without removing the covering or cladding which thus becomes solar absorber or under-roof.