FR2465966A1 - Self-supporting solar heat collecting panel - has foam mattress pressing conduits against resin pigment mixture coated plate - Google Patents

Abstract

A back plate and an absorbent plate below which there is a series of pref. rectangular conduits for a heat transporting liquid, are bonded by a mattress of a foam such as an isocyanurate or a polyol, expanded by "FREON" (RTM). This gives a rigid self supporting structure for a solar heat collecting panel which is formed in a mould so that the foam presses the conduits tightly against the absorbent panel. The frame of the panel may support a window enclosing a cavity in which the greenhouse effect is produced. The absorbent panel is coated with a mixture of polyvinylidene-fluoride, acrylic resin and a pigment. The efficiency and reliability for continuous service of the panels are improved, the cost price is reduced, and the self-supporting panels may be used either as wall or roofing sections.

Description

 The present invention relates to a solar collector for heating a heat-carrying fluid, such as water, air ... and which can constitute a self-supporting panel for cladding, roofing ... for buildings various.

 Known solar panels generally comprise, successively from the face exposed to the sun, an absorbent and heat conducting plate, a network of conduits conveying the fluid and placed in thermal contact with the plate and an insulating material. Some of these panels operating at a temperature above 1400 C for example may also include insulating glazing covering at a certain distance said plate.

The invention aims to improve such panels so
- to improve their efficiency,
- to increase their reliability over time from the point of view of performance and construction,
- to reduce their cost price to achieve reasonable depreciation,
- to realize at the same time a self-supporting wall either of cladding or of roof.

 In accordance with the invention, a counter plate and the absorbent plate are connected together by an insulating foam mattress which adheres to their facing surfaces, thus constituting a support structure; during the formation of the foam in a mold which holds the counterplate and the plate in place, this foam swells by applying and definitively pressing the network of conduits against said absorbent plate in order to ensure perfect thermal contact between them.

 Preferably, the foam is composed in particular of an isocyanurate and a polyol, the swelling agent being freon; the plate comprises at least one organic absorbent coating composed, in the proportion of 60 to 85%, of a resin of the family of polyvinylidene fluorides, this resin being mixed with a thermoplastic acrylic resin and with pigments which can be a combination of copper and chromium oxides mixed with smoke black; the plate is a sheet of galvanized steel on each side and receiving, after a pretreatment of chemical conversion such as phosphating, a layer of primer such as an epoxy resin and, on at least one side, the absorbent coating.

 According to a particularly advantageous embodiment, applicable in particular when the heat transfer fluid is water, each conduit is a tube having an elongated rectangular section.

 According to another equally advantageous embodiment, applicable in particular when the heat transfer fluid is air, each duct is an omega profile of open section having marginal edges intended to be applied by the foam against the plate to ensure thermal contact. and form the conduit considered.

 Various other characteristics and advantages of the invention will also emerge from the detailed description which follows.

Embodiments of the object of the invention are shown, by way of nonlimiting examples, in the accompanying drawing
On this drawing
- Fig. 1 is a transverse-ale section of a solar panel according to the invention,
- Figs. 2 to 7 are partial sections similar to FIG. 1, illustrating, on a larger scale, several embodiments of the tubes constituting a panel network, conveying a heat transfer fluid.

- Figs. 8 to 12 are views similar to FIGS. 2 to 7, showing, on a large scale, several embodiments of the profiled conduits constituting a network conveying the heat transfer gas from the network,
- Fig. 12a is a section showing the deformation of the thin section of FIG. 12 under the effect of the pressure exerted by the foam to ensure thermal contact of this profile with the absorbent plate.

As shown in FIG. 1, the solar panel comprises successively, from the face exposed to the sun
- insulating glazing 1,
- a cavity 2 in which a "greenhouse effect" can occur,
an absorbent and heat conducting plate 3, this plate projecting stiffening ribs 4 and marginal edges 5 on which the glazing 1 rests and delimits the cavity 2 containing the layer of air,
a network 6 of conduits conveying the heat-transfer fluid which can be a liquid such as water or a gas such as air, these conduits being placed in perfect thermal contact with the face of the plate 3 located inside of cavity 2,
an insulating material 7,
- And a counterplate 8 which can also have projecting stiffening ribs 9.

 The glazing 1, whether plastic or glass, protects the absorbent plate from drafts and thus reduces convection losses; it also makes it possible to reduce the losses by radiation of said plate by trapping in the cavity 2 the long-drawn-out radiations emitted by this plate.

 The advantage of plastic glazing lies in its unbreakability; in fact, in the event of a disturbance in the installation, it can undergo thermal shock phenomena (expansion and shrinkage) thanks to its deformability which a conventional glass cannot withstand. The sealing of the plastic sheets 1 with one another and with the flanges 5 ensures free flow of rainwater without adaptation or modification of the surrounding elements, and avoiding any penetration of moisture.

 The absorbent plate 3 is a galvanized steel sheet on each face and receiving, after a pretreatment of chemical conversion, of phosphating for example, a layer of primer such as an epoxy resin and, on at least the face exposed to the sun, a coating absorbing solar energy stable over time and possibly having selectivity properties.

 The coating is a specially selected combination of resins and pigments. The binder itself preferably comprises two different thermoplastic resins. A first resin is from the family of polyvinylidene fluorides and its proportion in the binder is between 60 to 85%; it gives the coating a particularly high resistance to degradation caused by prolonged use at a relatively high temperature and by long-term exposure to solar radiation. The second resin is of the thermoplastic acrylic type which allows continuous application on a coil by the process known as "coil-tating".

 Obtaining a particularly high and homogeneous absorption coefficient throughout the wavelength range corresponding to the range of action of solar radiation, is obtained by the selection of a mixture of several pigments. For example, these pigments can be a combination of copper and chromium oxides, mixed with smoke black.

 According to the invention, the insulating material 7 is a foam which, by swelling during formation in a mold holding the plywood 8 and the plate 3 in place, definitively applies and presses the network of conduits 6 against this absorbent plate 3 in order to '' ensure perfect thermal contact between them. I1 is also possible to interpose between the conduits and the plate an adhesive and conductive binder. Whether or not this is the case, the foam adheres to the three elements of the sensor (3, 6 and 8) by joining them together and by forming a homogeneous self-supporting panel of very high rigidity.

This foam is composed of an isocyanurate and a polyol, the swelling agent being freon. It is self-extinguishing. In a particular example, its density is understood
3 between 40 and 45 Kg / m and its compressive strength is
2 1.5 Kg / cm2; the cells are closed in the proportion of approximately 90%; its thermal transmittance is O, G3
2 KCal / m / h / C for a foam thickness of 35 mm.

 Figs. 2 to 7 illustrate several embodiments of tubes brought into perfect contact and pressed against the absorbent plate 3 by the foam 7 in order to constitute a network of heat transfer liquid which can be shaped as a coil or as a ladder.

According to FIG. 2, the tube 10 has a circular section, but its thermal contact and its efficiency can be increased by cooperating
- either with a channel 11 (FIG. 3) of complementary shape formed hollow in the plate 3,
- either with an omega 12 profile (Fig. 1) wrapped around the tube in question and applied by its wings, under the pressure of the foam 7, against the plate 3, the profile being made of an alloy metal metallic good conductor of heat, based on aluminum or copper for example.

 The profiles 12 can be formed (Fig. 4) in a sheet whose planar portions 13 connecting the adjoining wings are perforated; the foam 7 then passes through these perforations to join with the plate 3.

According to FIG. 5, the tube 14 has a rectangular section and one of its wide faces is applied directly by the foam 7 against the plate 3. Its efficiency and its thermal contact can be increased
either by cooperating, as before, with a recess channel 15 (FIG. 6) of complementary shape formed in the plate 3,
- either by lengthening the section of the tube 16 (Fig. 7) to increase the contact width.

 Of course, other shapes can be given to the section of the tube: in a trapezoid, in a circle sector ...

 Figs. 8 to 12a show several embodiments of conduits shaped substantially in omega and having marginal edges intended to be applied by the foam 7 against the plate 3 to close the conduits; the gaseous fluid, air for example, is reheated in these conduits directly by the plate 3 and by means of the body of the profiles whose edges are in thermal contact with said plate.

 The body of the profile 17 (Fig. 8) is rectangular; that of the profile 18 (Fig. 10) is trapezoidal; that of profile 19 (Fig. 11) is shaped into a sector of a circle. Of course, other shapes can be retained as long as the foam 7 applies to said profile a resultant force directed towards the plate 3.

 Whatever this shape, the lateral edges 20 of the profile are coplanar if the rigidity of the body is sufficient so that it does not risk being deformed under the pressure exerted by the foam (FIGS. 8 to 11). On the other hand, if the thickness of the profile 21 is relatively small, the flanges 22 form an open dihedral (Fig. 12) whose angular opening is such that these flanges flatten and become coplanar when the body deforms and s' curved (Fig. 12a) under the effect of the pressure exerted by the foam 7.

 In all cases, the flanges can be simply placed against the plate 3 (Fig. 8, 10 to 12); but, it may be advantageous as before, to embed these flanges in a recess channel 23 (FIG. 9) formed in this plate.

 The invention is not limited to the embodiments shown and described in detail, since various modifications can be made thereto without departing from its scope.

 The panel, object of the invention, is applicable to the capture of solar energy with a view to its transformation into thermal energy for heating residential premises, industrial buildings, sports or cultural complexes, swimming pools, etc. for the production of electricity ... for the drive of various machines, etc ...; it can be used concomitantly as a self-supporting cladding, roofing or other panel.

Claims (14)

 1. - Solar collector for heating a heat-transfer fluid such as water, air, etc. which can constitute a self-supporting panel of siding or roofing for buildings and comprising an absorbent and conductive plate of the heat, a network of conduits conveying the fluid and placed in thermal contact with the plate and an insulating material, this plate possibly being able to be surmounted by an insulating glazing,  characterized  - in that a counter plate and the absorbent plate are connected together by an insulating foam mattress which adheres to their facing surfaces, thus constituting a support structure,  - And in that, during the formation of the foam in a mold which holds the counter-plate and the plate in place, this foam swells by applying and definitively pressing the network of conduits against said absorbent plate in order to ensure between them perfect thermal contact.  2. - A sensor according to claim 1, characterized in that the foam is composed in particular of an isocyanurate and a polyol, the swelling agent being freon.  3. - Sensor according to claim 1 or 2, characterized in that the plate comprises at least one absorbent organic coating composed, in the proportion of 60 to 85 X, of a resin of the family of polyvinylidene fluorides, this resin being mixed with a thermoplastic acrylic resin and pigments which can be a combination of copper and chromium oxides mixed with smoke black.  4. - sensor according to claim 3, characterized in that the plate is a galvanized steel sheet on each side and receiving, apuras a pretreatment of chemical conversion such as phosphating, a layer of primer such as an epoxy resin and , on at least one side, the absorbent coating.  5. Sensor according to any one of claims 1 to 4, using a heat transfer fluid, such as a liquid and for example water, characterized in that each conduit is a tube of closed section having directly or indirectly the most large contact surface possible with the plate.  6. - Sensor according to claim 5, characterized in that each tube has a circular section and cooperates with an omega profile fitting around, the wings of this profile which is made of a metal or metal alloy good conductor of heat such as aluminum or copper, being applied by the foam against the plate.  7. - A sensor according to claim 6 characterized in that the profiles are formed in a sheet whose flat parts constituting the edges of the aforementioned wings, are pressed by the foam against the plate and are perforated for adhesion thereon said foam.  8. - Sensor according to claim 5, characterized in that each tube has a flat section.  9. - A sensor according to claim 5, characterized in that each tube has an elongated rectangular section.  lo. - Sensor according to any one of claims 1 to 4, using a gas such as air, as heat transfer fluid, characterized in that each duct is an omega profile of open section having marginal edges intended to be applied by the foam against the plate to ensure thermal contact and close the duct in question.  11. - Sensor according to claim 10, characterized in that the body of the profile is rectangular.  12. - Sensor according to claim 10, characterized in that the body of the profile is trapezoidal.  13. - Sensor according to claim 10, characterized in that the body of the profile is shaped in a cylindrical sector.  14. - Sensor according to any one of claims 10 to 13, characterized in that the edges of each profile form an open dihedral with an angular opening such that it becomes flat when the body is deformed under the effect of the pressure exerted by the foam.  15. - A sensor according to any one of claims 5, 6 and 8 to 14, characterized in that the plate has recessed channels of complementary section for housing the conduits at least in their thermal contact zone.