FR2938589A1 - Solar protection device i.e. store, for use in e.g. atrium window of building, has small bands arranged side by side for forming store sheets, and professional and raised door-sheet profiles including space formed between store sheets - Google Patents

Abstract

The device has small bands arranged side by side for forming store sheets (TER1, TER5) of larger length. The store sheets include continuous coatings resistant with chemical products, where the coating is made of PTFE or poly-methyl acrylate. Absorbers are arranged on a face of the store sheets, and reflectors are arranged on another face of the store sheets. A transparent hydrophobe film is arranged on a face of the reflectors. Raised door-sheet profiles (PTR) and professional door-sheet profiles (PTM) comprise a space formed between the store sheets.

Description

The present invention relates to a device in the form of awning fabric to protect from the excessive heat darted by the sun any surface, any volume inconvenienced by its radiative heat and also inconvenienced by the various radiations coming from the celestial vault. The present invention relates firstly, but not only, verandas and glass roofs with all the constraints specific to this type of building site and buildings for which everyone considers that there is no acceptable solution and that It is normal that a veranda, because of the heat always observed in summer, is not usable from May to September, and that even the air conditioning is only a second-best solution difficult because of its discomfort. The protection against the awkward consequences of the sun is traditionally obtained by the establishment of an opaque sun-absorbent shade or a sometimes insulating solid opaque surface disposed between the sun and the surface that is to be protected. These current protections do not take into account the fact that the totality of the expected solar protection concerns exclusively exchanges of ENERGY-HEAT BETWEEN TWO SURFACES under the only form of waves, of electro-magnetic radiations, not to be confused with EXCHANGES HEAT BETWEEN TWO BODIES that are made by direct contact, the heat being a state of the material characterized by the temperature depending on the kinetic energy of agitation of the particles that make up the two bodies, temperature measured by the thermometer, completely independent temperature any other parameter. The current thermal protections confuse the heat which is a state of the material which is expressed by a temperature heat transmissible by contact-conduction between two bodies and the heat-energy transmissible between two surfaces by electro-magnetic radiations. Now the solar protection concerns only a transfer of heat-energy, electromagnetic energy, an exchange of energies by radiation between two surfaces - manages surface: the sky of which one of the components is the sun, the sun whose apparent and relative position by compared to the object heated by the sun is constantly moving. - 2nd surface: the veranda of which one of the components is the ground. These current canvases, still made of heat-energy absorbing materials transmissible by electromagnetic radiation, and conductive-contact material heat-state-of-the-material are stretched parallel to the surfaces or to the roof. volumes that we want to protect from the sun, and this through a fixed frame, more generally strained on a so-called awning mechanism consisting of a winder which has at the top a winding tube on which the fabric can be wound and at the bottom a bar of load which serves to stretch it. This load bar is kept separate from the roller tube by arms or any other telescopic system, trolleys, or other.

The results of reducing the overheating due to the sun by the interposition of a classic awning fabric are still insufficient, not only for a user located in the open air because it is refreshed by the evaporation of its perspiration, but especially since that a glazed wall is interposed between the sun and a glazed volume: it is indeed observed that if the temperature of the thermometer in a veranda exposed to the sun without protection can reach 100 ° C in full summer, it is also deplored that the thermometer in a veranda exposed to the sun with a standard outdoor blind can reach 80 ° C in summer. Indeed all current canvases behave as absorbers and all the heat energy received from the sun (1,250 watts per M2) absorbed by a screen located between the sun and a surface is compulsorily restored, re-issued by the back of the store under form of radiation invisible to the eye but perfectly sensitive and perceived by the sensory organs of the skin. The objects absorb this thermal radiation and heat up. Including glass that is completely opaque to infrared, including the glass walls of double glazing, and even more the glass walls of triple glazing. It can thus be seen that the radiative temperature of the interior glazings of a double glazing unit located below or behind an absorber blind easily reaches 75 ° C. while the external glazing only reaches 35 ° C. This is because the glass is a black body which, totally opaque to the infrared, absorbs all the infra-red radiation to transform it into heat. The interior glazed wall of the double glazing of a veranda exposed to the sun behind a standard blind thus becomes a radiator that heats the interior of the living space that is the veranda which, by greenhouse effect, becomes unbearable: - by conduction with the air contiguous under the blind, - by convection because the heated air circulates by chimney effect and will heat the whole room, - by radiations, the measurements made in verandas in full sun show that an energy of 500 to 750 watts / M2 can be emitted by the double glazing of a veranda located behind an absorber cloth exposed to the sun. Somewhat better results have been achieved by the use of blinds with reflectors above verandas, but these results are still unsatisfactory because the temperature can reach 65 degrees, which makes the veranda still unlivable. In addition blinds with reflector top age poorly and see their performance reduced by deposits and dirt that inevitably occur on a surface exposed to the outside. So that the only solutions available to veranda owners, or volumes uncomfortable with solar radiation, to be able to use their veranda in summer are:> install an air conditioning that will cool the veranda by cooling the air through air conditioners. These appliances consume a lot of energy, make noise and spread in the veranda a current of cooling air, painful to bear,> set up an insulating roof that will obscure the veranda permanently, hide the sky and remove the benefits from the veranda in cold season by removing the greenhouse effect so painful only. in summer, but so pleasant in winter. The thermal results obtained by the existing insulating roofs, consisting of a sandwich panel around a panel of cellular insulation, are notoriously insufficient since the temperature of the inner wall can reach 70 ° C in a veranda with the roof porch insulation present on the market; it is indeed well known that a thermal insulator is a retarder of heat transfer, because an insulator, whatever it absorbs heat, heats itself to become a heat emitter in turn,> put in place a current store system above the veranda resigning themselves to not use their veranda during the heat, but to enjoy during pleasant times. The current blinds are not waterproof because they are made from a weave, therefore of discontinuous structure, and let the rainwater bead so that it is very uncomfortable to stay under the awning when it rains, and that It is impossible to leave any furniture other than a garden under the awning. The fabrics according to the invention will therefore have to be waterproof and hydrophobic, for this reason they will not be made from a discontinuous weaving of yarn or ribbons as currently but instead from continuous plastic films that are these films can be sealed by nature, which can be supplemented by the combination with a solid sheet of continuous metal, an aluminum film for example, which is by nature completely watertight more than any other material. The device according to the invention overcomes these disadvantages and others. The accompanying drawing illustrates the invention. <> It comprises in fact according to a first characteristic related to the following, and unlike all other systems, the use of a succession of several Canvas-Screens-Reflectors (TER1, TER2, TER3, TERetc.) Reflectors therefore non-absorbers on one side and also non-emitting reflectors on the other side of the same canvas, different webs applying the principle of the thermos bottle, the Dewar vase without air vacuum, the principle of the shield on which the radiation, such as an arrow will ricochet, the principle of the armor on which the projectile will rebound all the better that it will happen more in oblique, more oblique and the principle of thin insulating reflective. State of the prior art. By publishing its Technical Opinions, and its European Technical Approvals, the CSTB, in September 2008, specifies that for reflective insulators the useful heat transfer coefficient U depends on the thickness, in mm, of the multilayer reflective product. Thus the CSTB, Scientific and Technical Center of Building, official body, publisher of the Thermal Regulation, completely ignores that the quantity of heat transmitted between two surfaces by radiation does not depend in any way on the thickness separating these two surfaces, since the air through which radiant energy-heat transfers are carried out is totally transparent. Thus, in June 2008 CSTB imposes the measurement of the effectiveness of the multi-reflector products according to the present patent by the only method of the guarded hot box which eliminates any heat transfer by radiation and only takes into account the exchange by the only conduction- contact, and the CSTB requires taking into account the thickness of the insulation. The various Reflective Screen Sheets, TER according to the invention, successive according to the accompanying drawing, which is illustrative of the invention, will be separated by spaces constituting strata, these spaces being obtained without having recourse to materials, to bodies spacers. Spacer bodies as mentioned in the patents registered under numbers 81 21 128, number 84 15 558, number 85 02 400, numbers 91 06490, number 04 10 771, number 04 10 884, number 04 12 543, number 05 08 048, number 05 08 650, numbers 05 11 317, number 07 00 971, number 08 01836. Indeed these materials, these spacer bodies particularly effective in terms of heat transfer reductions in building applications, are volumes that make the will fold or roll the awning impossible to achieve under acceptable conditions because of the volume taken by the addition of the thicknesses of these materials, these non-compressible spacer bodies. These spacers are conductive energy state of the material that is transmitted by contact-conduction. In the thermos bottle, the two walls are evacuated to reduce conductive exchanges in the heat conducting gas between the inner wall in contact with the liquid body material, the contained material and the outer wall in contact with the atmosphere. other matter. In thin multi-reflective reflective insulators, fibrous or cellular materials are required to reduce conductive exchange between the solid material of the outer wall and the solid material of the inner wall due to the unavoidable risk of crushing.

But in a heat-energy protection blind radiated by the sky surface with its sun, there is exclusively air totally transparent to solar radiation and solar radiation. And the thickness of the insulation separating the two surfaces of the two bodies has, in this case, no influence. The heat exchanges by the only radiation through the vacuum or through the air are almost the same, and the thickness of the vacuum has no influence on the quantity of these exchanges. Thus in the field of the blind, it is sufficient that there is a non-convective air gap so that the heat exchange between two surfaces is effected by radiation alone. It does not matter the thickness of this air space. The present patent intends to use this new concept which is totally unknown and to manufacture thermally insulating blinds the sky wall surface of the veranda wall or wall surface of any object located under the awning by arranging several, and at least two, reflective canvases. non-transmitters separated from each other. This notion is totally ignored by the technical bodies that are authoritative in this area. Thus the French and European standards: - NF EN 14500 Thermal and luminous comfort closures and blinds - Test methods and calculation - NF EN 410 Determination of the luminous and solar characteristics - NF EN 14501 Thermal and luminous comfort of the closures and blinds, - NF EN 13363 -1 and NF EN 13363 - 2 solar protection device, calculation of the thermal transmission factor - NF EN 12216: Terminology, glossary and definitions - as well as all the literature concerning the NT 2005, including the decree of the 3 May 2007 on the thermal characteristics of buildings and all the thermal regulations both French and foreign are completely ignorant of this concept of multi-walled reflective blinds, but also and especially, that in terms of solar protection it is only transmission of heat-energy transported by radiation without any heat transmission by conduction and by convection. So much so that all these official documents take into account the thickness of the product to determine the thermal characteristics and none of these texts mention the characteristic of non-emissivity of a blind, although the reflection factor is always taken into account. Moreover, in November 2008, the whole of the French official and regulatory technical literature ignores the word reverberate verb: Return the light, the heat, speaking of a surface according to the dictionary Grand Robert to speak only of reflection. In the same way, the English literature uses the word reflect and its derivatives reflective, reflection, and never the word reverberation which nevertheless appears in the English dictionaries and in particular in the big English dictionary the Collins. As a decisive addition to the novelty of the present invention, the attribution of the NF mark Solar protection cloths, published in June 2008 takes into consideration for the criterion of thermal quality and the calculation of the solar factor Sg only the colors, the patterns, the position of the fabric with respect to the glazing and the proportion of radiation transmitted through the fabric. Excluding the reflectivity, non-emissivity characteristics of the products studied in this patent. It must be remembered that CSTB, the official body, is a specialist in the evaluation of innovative techniques, and notes that, in June 2008, the CSTB ignores in general and particularly for verandahs the protruding blinds, the reflective blinds, the multi-blinds -reflectors spaced apart, and generally ignores to reduce the heat transfer by the single radiation between two surfaces, the thermos bottle effect obtained by the juxtaposition of non-contact reflective films, regardless of the thickness of the air gap separating them. reflective surfaces. In all the existing technical or commercial literatures mention is made of reflective ice-glasses filled with rare gases and solar protection films intended to be applied to glazed surfaces. Never mention device approaching the device according to the present invention and implementing what we call thermos bottle effect, without this denomination is well suited because in a thermos bottle Dewar vase there is an air gap between the two reflective surfaces. Moreover, all the literature ignores one of the claims of the present patent which is that the fabric intended to stop the radiation carrying the energy-heat will be a nonabsorbent body and bad conductor of heat-energy. <> According to a second associated characteristic, a blind fabric support system that allows, apart from the presence of mattresses or layers acting as spacers, separators to have at least two reflector-non-emitting shield surfaces below the others or one behind the other by providing an air gap forcing the heat of solar radiation not completely returned by the first reflector to be transmitted by radiation to a second reflector disposed below the first or behind, and so subsequently, possibly to a third reflector, by providing an air gap separating the different reflectors from one another. Indeed a body whose wall is reflector = no emitter exchanges much less heat with its environment than a body whose wall is standard and untreated reflector, and the air, which is completely transparent, is heated only by contact with a warmer surface, or cooled by contact with a cooler surface. According to another characteristic associated with the two previous ones, the sun protection device according to the invention has as a first wall exposed to the sun a reflective surface which will be heated by the solar radiation absorbed in an unavoidable manner. Indeed it is impossible to have a reflector that remains clean and totally reflective in the ambient atmosphere. This reflector, or this succession of non-perfect reflectors will be heated by solar radiation not totally reflected. The present invention intends to take into account an unavoidable phenomenon: the morning dew. It can be seen that in the early morning, and only on certain days, any surface exposed to air is covered with a thin continuous film of water, and this regardless of the surface tension of the material exposed to the atmosphere that this surface is horizontal and even vertical. This water deposit is almost transparent and condenses into droplets at the touch of a finger. This deposit in the form of mist disappears quickly from the first ray of sun. We know that water is a black body that absorbs all the infrared to turn it into heat. Behind and below this first surface is a space support open at its base and at its summit so as to form a fireplace in which the air of the atmosphere will be heated and take away the heat it has received from the canvases. contact of which it will have circulated. This canvas can also have above any decorative aspect to match the particular tastes of the site owner to preserve heat, this independently of the rest of the store. This fabric will preferably be very hydrophilic material so as to absorb as much solar heat as possible to start drying. It is indeed part of the claims of this patent to use the heat energy heat necessary to dry a hydrophilic tissue in order to retard, reduce the heating of a volume exposed to excessive sun, and this by using the humidity always brought at night in the form of dew. We know that it takes about 1.6 kilowatts to evaporate only 1 liter of water.

So a blind that has a hydrophilic wall will absorb the inevitable humidity and the first ray of sun will want to dry. To dry the last wet TER5 fabric will absorb the heat brought by the absorbed solar radiation, and thus avoid the absorbed solar radiation to warm up the space to be protected. This to take into account that it is the thermal emissivity of the bottom of the last fabric TER5 which alone determines the total thermal protection result of all the addition of the components arranged above, the result of thermal protection such as it will be appreciated and judged, without appeal, by the users. This phenomenon is totally ignored by laboratories working in a fixed, dry and constant atmosphere, whereas the atmosphere, the environment around a veranda or in a space subject to the sun, whose apparent position varies constantly, changes all the time, not only in ambient air temperature, but also in the radiative temperature of the medium, but also in the relative humidity of the air, and especially in the speed of movement of the ambient air, and again in the direction of the displacement of the ambient air . Evaporative cooling cloths will be used to absorb the water. This hydrophilic fabric may be installed either above or below the device. This fabric will absorb water in all its forms, liquid or vapor> 1 / by capillarity = blotting effect: this wet cloth must first be dried by evaporation (l Skw / h is necessary to pass / liter of water of / LIQUID state at / VAPOR state at atmospheric pressure and ambient temperature). This canvas will therefore remain cool until it has absorbed enough solar heat energy to be dried. So the verandah beneath a cool store while it evaporates the water it has kept, will stay as cool longer than a veranda under a dry absorbent awning and immediately transmit all the energy radiative heat received from the sun. > 2 / by reversible chemical affinity = the absorption of a liquid by a solid is made chemical affinity: fixation of the molecules of water which cling to the molecules of the solid because of the electrical affinity of the molecules of water with the body: This is a well-known phenomenon in summer, especially when the occupants find it heavy. The present invention utilizes the ability of certain materials to retain water to provide surfaces that require a great deal of water for drying, and will have electroconductive films in proximity to promote electrical discharge promoting the separation of water molecules attached to the water. solid because of electrical affinity. The PVC widely recommended by the experts in the field of sunblinds presents this defect: it is impregnated with water and is thus heated for itself to heat the volumes situated below or behind. The present invention will eliminate the defect of certain components of wanting to retain water by electrical affinity by installing a grounded electrically conductive surface close to the awkward fabric. This electroconductive component may be the aluminum foil used as a totally opaque reflector of the radiation and as completely impermeable sealing means because continuous.

The present invention will eliminate the defect of some fabrics wanting to stay too hot by installing a fireplace underneath that will promote, accelerate, the evaporation of water and cooling of the store wall. It will not be interesting to use as canvas exposed to the sun a canvas that will absorb much heat, radiated by the sun. Indeed, all the heat absorbed will have to be eliminated and will have to be evacuated from below. It is therefore better to use everywhere a reflective screen cloth and constituted in the following manner: a transparent hydrophobic continuous film, with a very low surface tension, on which the water does not spread in droplet, in which the water does not It can not penetrate since this film is continuous and not woven, on which the water does not remain but on the contrary is evacuated, this hydrophobic film will also be antifouling and will be easily cleaned by the rain. Polyvinyl fluoride meets these requirements in the context of the present invention. This transparent hydrophobic film may be metallized at its back and will be laminated to the most reflective face of a metal sheet, for example a solid aluminum film. This solid, continuous aluminum film, totally waterproof reflector, will be glued on a wire mesh grid that can withstand the inevitable heat of the sun,> This grid glass son will reveal between its mesh the other surface of the metal film that will be chosen to have two reflective surfaces of radiation. Below this glass grid will be fixed a transparent film which will retain the non-reflective qualities of any reflector. This film will be fixed under the grid so that the reliefs of the grid appear as much as possible on the surface of the film. These reliefs intended to reduce the possible contacts of the reflective film by providing air blades formed by the hollow mesh of the grid. As a fabric disposed on the side not exposed to the sun, a fabric which absorbs water will be used. According to one particular embodiment, the solar protection device according to the invention aims not to transmit the heat energy which will be absorbed. by the device subject to the heat of the sun. For this purpose the device will consist of a succession of reflector films - non-emitters kept at a distance from each other not by separating materials as in the thin reflective insulators but by regularly arranged mechanical supports which will maintain each film reflector - not a tense emitter separated by a few millimeters at least from its next 30. For this the sun protection device according to the invention will be composed, according to the accompanying drawing Fig.1 which illustrates the invention, a succession of small width widths, strips of non-emitting reflective material stretched between door bars stars, generally obtained by extrusion of aluminum, and comprising splines CN1, CN2, CN33, CN4, CN5, etc. according to the accompanying drawing Fig.1 which illustrates the invention. In these superimposed grooves will be slipped the tenon effect increments formed on each side of these widths or by a rod introduced into a hem which thus becomes tenon, tenon hem created on each side of these widths, or by any other system. This system uses the principle of the tenon hem and the mortise and is commonly used in textiles and in the field of the blind. In a version implementing the claims of the present invention and its progress with respect to the previous versions the device holder-screens-screens-reflectors will be constituted in the following manner: The device aims to stretch between the sun and the surface to to protect a succession of surfaces Canvas Separate Reflector-non emitter screens and INHIBITOR of the transmission of the energy radiative heat transmitted by electromagnetic waves TER1, TER2, TER3, TER4, TER5, etc., separated by a space empty obliging the heat energy to be transmitted without contact and only by radiation. These voids, hollow may be open at each end so as to constitute a chimney effect in which the present air will be heated, expand and circulate upward carrying the heat it has absorbed. Any heat absorbed will be as much heat that will not be transmitted to the spaces that the blind has the mission to protect the heat of the sun.

These spaces can also be closed at least one end to prevent dirt (vegetation, insects, dust) from entering the space: below TER1 with the top of the film TER2, then the bottom of the film TER2 with the top of the film TER3, then the bottom of the film TER3 with the top of the film TER4, then the bottom of the film TER4 with the top of the film TER5. Pieces of self adhesive velcro tape will be prefabricated to the standard length corresponding to the width of the different widths of the succession of inhibiting films and will be put in place at the last moment on the site. The superposed, juxtaposed and spaced non-spaced multi-reflector fabric device will be held in place by extruded or otherwise obtained web bar profiles, which will have the following features, as shown in Fig. 1 which illustrates the invention. 1 / the PTM master rods will have at their summit a groove M recessed which will have an opening of about 6.5 mm to be able to receive a screw at the pitch of M 6 and a flange on each side in the form of a standard countersunk head machine screw. Thus the PTM master rod can be carried by a single screw, which will allow the length of the screw to be adapted to the position of the support bar under the carrier rail to ensure the desired inclination and slope. . 2 / they will have at their base another hollow groove M which will have an opening of about 6.5 mm to be able to receive a metal screw M6 pitch and a flange on each side in the form of a screw to standard countersunk metal. In this way, the PTM master rod can receive under any other product that will be held by a simple screw. It goes without saying that the dimensions of a screw M6 metric pitch applied to the tenons T and mortise M may be replaced by any other dimensions without departing from the scope of the present invention.

The support profile of the spaced webs will then have on each side a succession of partially closed NC grooves to ensure the passage of the fabric and the retention of a bead obtained by the introduction of a flexible rod. This support profile of spaced webs will have as many splines as it is desired to install reflector-non-emitter layers superimposed one after the other to obtain the thermos bottle effect without sufficient air vacuum. A number greater than 5 canopies is rarely needed with good quality reflectors kept clean and efficient, so a profile with 5 splines CN1, CN2, CN3, CN4, CN5 is usually sufficient. And even superabundant in most cases. Also to satisfy all cases, the device according to the present patent will use two support profiles according to Figure 1 attached: A first PTM master profile with 2 or 3 splines CN1, CN2 and CN3 which will be used in all cases CN3 flute receiving the TER5 fabric; and a second support profile raises PTR which will comprise at its top a post T shaped head section of a countersunk head screw that will slide in a groove-shaped mortise M in the lower part PTM master profile with 2 or 3 splines on each side. The profile raises PTR will also comprise, at its base a groove in the form of mortise M, mortise in the shape of the head of a countersunk screw machine, which will be formed in the lower part of the profile raises PTR to a groove of each side. This device makes it possible to have a 2 or 3-spline master PTM master rail in all cases and to have the possibility of having a 4-spline or even 5-spline holder by sliding one or two door-holders. PTR canvases in the PTM master channel when it is desired to have total thermal protection against the radiated heat-energy. The device will consist of a succession of support bars, obtained by extrusion or by any other means, which will comprise on each of the 2 sides a succession of splines CN1, CN2, CN3, CN4, CN5, etc., superimposed, parallel, partially closed capable of receiving any retaining means of a fabric, for example a groove with an internal diameter of about 10 mm with an opening whose lips are separated by about 3 mm. This succession of grooves, superimposed grooves will serve to maintain a succession of screens-screens-reflectors TER1, TER2, TER3, TER4, TER5, etc. The device according to the invention allows to install several canvases one above or behind the others and in particular several reflective fabrics so as to implement the thermo-dewar bottle effect without air vacuum in which are placed face to face, non-contact, reflector-non-emitting surfaces maintained parallel and spaced apart without spacers to form an insulating blind of solar radiation. The fact that the face-to-face surfaces are non-contact forces heat-energy to be transmitted by radiation without contact. The space between these surfaces will be less than the space that allows the natural convection of air at room temperature. For solar shades this space will be less than 15 mm, to prevent dirt from entering the space between two canvases.

The splines of CN1 top left and CN1 left can be opened downwards and have a return to the inside so as to keep as much as possible the seam of the hem inside so sheltered from the rain . The rail bars profiles will comprise between each fabric and in particular between the webs of the top TER1 and the following webs TER2 a space constituted by the space existing between the splines CN1 and the splines CN2. This space necessary for the creation of the thermos bottle effect without air vacuum will be constituted by the distance separating the opening of the flute CN1 with the opening of the flute CN2, then the distance separating the opening of the groove CN2 with opening CN3 flute, and so on.

Thus:> Al above, the surface of the webs-screens-reflector TER1, directed towards the sky and exposed directly to the sun, will absorb the least possible radiation, will be the most smooth, the most closed possible to not keep the defilements brought by the atmosphere. > BI the surface of the TER1 canopies, exposed directly to the weather will preserve its qualities and will not be degraded by the aggressions of the radiation received from the sky, including the moon, the aggressions of the climate, nor by the aggressions transported by the atmosphere, for this the outer surface of the web TER must be as smooth as possible to retain as little soil as possible. > Cl above, the surface of TER1 canvases, oriented towards the sun, will be the most reflective possible of the energy received from the sun in the form of mostly luminous radiation so as to absorb the least possible heat energy received in the form of radiation electromagnetic. In addition it will be completely opaque and will not let any energy in the form of light radiation> Cl variant the top, the surface of the webs TER1, oriented towards the sun, therefore subject to all attacks of radiation received from the sky and all attacks climate change may also be considered sacrificed. The multi-spline system allows you to change only the awning fabric TER1 without having to change the blind as on the current awnings. The canvas TER1 may also be changed when the hostess wants to change the appearance of the top of her blind. > EI the body of the webs TER1, which is the most exposed to the heat will comprise a frame of mechanical reinforcement resistant to the heat and not softening as do the materials of the fibers used in the usual blinds> F 1 the bottom of the TER1 canvases, facing the ground, will emit the least possible heat energy that can be absorbed by the top of the TER2 canvases that will follow it, facing the sun from which comes the heat that must be prevented from passing. > GI the top of the webs TER2, directed towards the sun from which the heat that must be stopped will be realized so as to absorb as little as possible of the thermal radiation emitted by the undersides of the canvases TER1: for this its surface will be the most reflector. > H I the body of the webs TER2 will transmit the least possible heat energy towards the bottom of the webs TER2. > II the underside of the TER2 canvases, facing the ground, emit the least possible heat energy that can be absorbed by the top of the webs TER3 which will follow him, canvas top facing the sun where the heat comes from that must be prevented from passing. > J 1 the top of the webs TER3, directed towards the sun from which the heat that must be stopped will be realized in order to absorb as little as possible of the thermal radiation emitted by the undersides of the canvases TER2: for that its surface will be the more reflector> K 1 the underside of the TER3 canvases, facing the ground, will emit the least possible heat-energy 10 that can be absorbed by the top of the TER4 canvases oriented towards the sun where the heat comes from must be prevented from passing, for that it will be reflector = non emitter. > L 1 the top of the webs TER4, which will follow the webs TER3, facing towards the sun where the heat must come to stop will be realized so as to absorb as little as possible the thermal radiation emitted from the underside of the webs TER3 : for this its surface will be the most reflective 15> M 1 the bottom of the webs TER4, oriented towards the ground, will emit the least possible heat energy that can be absorbed by the top of the webs TER5 which will follow it, top facing towards the sun from which comes the heat that must be prevented from passing. For this, the underside of the TER4 fabric will be a heat emitter towards the top of the TER5 fabric. The top of the webs TER5, which will follow the webs TER4, no longer receives any thermal radiation because the series of effects thermos bottle has managed to ensure that the web TER5 is at the temperature of the ambient environment below, in the shade, sheltered from the succession of reflecting + non-emitting surfaces. However, in order to increase the comfort of the set, the TER5 fabrics will have the following characteristics: - the TER5 fabric will participate in the decoration of the whole and for that it will be able to be printed or receive 25 all the decorative impressions, in total independence of the others characteristics of the awning. - the TER5 fabric will be made of hydrophilic material so as to absorb moisture during the night and the cold period and to want to evaporate this moisture as soon as the temperature of the veranda starts to rise. Thus the 1600 watts necessary to transform 1 kilo of liquid water into 1 kilo of steam water will be taken on the heat wanting to warm the veranda, which will further increase the impression of efficiency, and the tangible efficiency, noticeable. by the skin and measurable by the thermometer, the device according to the invention, device for protecting any surface heat, any volume bothered by the radiative heat darted by the sun's rays. According to a particular embodiment and according to the invention, the TER1 fabric will constitute a complex multi-reflector = multi-layer = multifunctional which will be constituted in the following manner: - the top of the screen fabric TER1 exposed directly to the sun and subjected to all the weather and soiling, to all the radiation will consist of a PTFCH vinyl fluoride film because this film of the Teflon family, polyethylene fluoride is transparent, resists all attacks of chemicals present in the atmosphere, n ' does not absorb light radiation at all while being opaque to the most aggressive ultraviolet rays for the skin, so it does not heat up in the sun unlike PVC or acrylic fabrics which, when exposed to the sun, can rise to 80 ° C, perfectly resistant to Ultraviolet, is anti-stick, is smooth, and will not retain the inevitable stains on a blind installed outside, is hydro phobe so that the water will condense in non-joined droplets instead of spread out like a PVC blind or acrylic fibers. It is known that water is a black body that absorbs all the infrared radiation, which explains the poor thermal protection results obtained with conventional blinds. - In a less elaborate version the top of the screen cloth TER1 exposed directly to the sun and subjected to all weather and dirt may consist of a coating or a film based on poly methacrylate resin methyl, this film technique Continuous being currently ignored, while acrylic resin is used to make fabrics to the general satisfaction. Thus the prescriptions B I are respected. - The back of this film may be metallized according to conventional vacuum metallization techniques. The metallization provided to the back of the outer film has the essential advantage of constituting a reflector that will protect the solar glue from fixing the outer film to form part A of the multi-layer complex = multifunction TER1. - The outer film will be glued by a suitable glue on the glossy reflective side of a solid aluminum film. This reflective solid aluminum film will be a reflector that will return incident solar radiation without absorbing it; - the films and components of each Reflective Screen Fabric will be assembled together by an adhesive adapted to the specific use, that is to say with constant and large temperature variations, with my alternative mechanical movements and vibratory forces in all directions because of the flag effect to which a horizontal blind is subjected. For this the only glue that gives satisfaction is a glue obtained by crosslinking a polyester with an isocyanate and implemented in the form of a net. EVA adhesives, polyurethane chemical reaction adhesives that require emptying and complete cleaning at the end of operation, all solvent-based glues that must evaporate, all glues that soften, can not be used. Thus the prescriptions C 1 are respected. This film must also constitute a continuous obstacle completely impervious to any penetration of moisture in the complex, in the multilayer device below. It is known that water is a black body that absorbs all the infrared radiation to transform it into heat, the lesser presence of water reduces the effectiveness of the device. An aluminum film will also constitute a screen that absorbs all the static electricity present. It will be enough to connect one of the ends of this film to the ground to have a remarkable screen Faraday cage and be completely safe from any electromagnetic radiation. The presence of this metal film that provides underneath an extraordinary impression of serenity, physical and psychological comforts not explicable but unanimously felt. In an elaborated version this aluminum film or one and preferably several may be embossed in relief: thus the incident radiation will not meet a perpendicular surface but instead will encounter an oblique surface which will be much more reflective, on which the ricochet of the radiation will be less braked and rebound less absorbed, in the same way that a shield protects better from an arrow that comes obliquely, obliquely than a projectile that arrives perpendicular .. In an elaborate version we can not use outside film with metallized back and slightly color glue. This will have an external appearance that is not aluminum, metallic appearance that the housewives do not appreciate. This will give the insulating complex metal reverberation tone stone, or bluish, or green, or tile without much change the overall efficiency of the device, this because of the succession of thermos bottle effects without vacuum insulation air obtained by the succession of non-emitting reflectors I and of the non-absorber assembly unlike all existing blinds. In this version we will have a web TER1 whose stratum AI will be composed of an outer protective film, a slightly colored layer of glue and a reflective polished and waterproof aluminum film and reflective and opaque to protect the films TER2 and following. To comply with the DI requirements and to ensure that the body of the Screen-Reflector does not transmit electromagnetic energy to the web-screen-reflector TER2 the fabric TER1 will comprise, behind the aluminum film = first reflector, but after a transparent separation consisting of a transparent glue film a second reflector in the form of a film metallized on both sides, for example a polyester film metallized on both sides. The back of this metallized film on both sides will receive another transparent adhesive film, the succession of reflective walls with transparent films increasing the efficiency, probably by a kind of condenser effect. In order to comply with the requirements E 1 and to ensure that the body of the Web-Screen has sufficient mechanical strength, a mechanical reinforcing reinforcement in the form of a grid of glass wires will be introduced at this point. All other fabrics are made of plastic (acrylic, polyester, PVC) that soften to the heat found in a sun-blind in the conservatory context (often 100 ° C in the absence of wind). To avoid this defect, the body of the Web Screen TER1 will include a wire mesh reinforcement grid that is perfectly resistant to the heat encountered in the veranda context, unlike the usual paintings. This frame will have a mesh of about 10 mm. The wires will have a diameter sufficient to create an extra thickness in the following softer films than the IC aluminum film, this allowance in the form of a grid of about 10 mm will reduce the contact of the film TER1 with the film TER2 alone. top of the stitches leaving a gap of air between the threads. A larger mesh allows the flexibility of the film TER2 to have a contact = conduction with the film TER1, a smaller mesh reduces the exchange by radiation.

The reinforcement grid will be installed where the blind is the most heated by the sun, so in the film the first presentation, so in the component TER1. To comply with the requirements F 1 and to ensure that the body of the Screen-Reflector TER1 emits the least possible energy-heat to the film TE2 that follows in the complex of spaced reflectors according to the invention, the bottom of the TER1 canvas will be the least possible emitter. For this it will be composed of a hydrophobic film metallized on one side. The metallized side will be installed towards the inside of the stratum so that the reflector metallization = non emitter is protected from the air and the humidity which causes the corrosion (oxygen and water). The surface of the bottom in the open air being hydrophobic (polypropylene for example) will see the inevitable moisture condense in non-contiguous droplets that emit less infrared than any other material. The fact that the surface will be discharged from static electricity by the aluminum foil will reduce the amount of water retained. To comply with the requirements G let ensure that the top of the TE2 screen fabric, as part of the thermos bottle effect, receives the least thermal energy radiation, the only heat present in the context of the sun protection, the top of the fabric TER2 will be reflective and for that composed of a reflective material film resistant to corrosion. For example a metallized polyester film on its outer face and glued according to the above descriptions on a support will be suitable. The indoor reflective film TER2 is protected from solar radiation, rain and climatic aggressions thanks to the TER1 fabric. It will not take more effort than the TER1 canvas, so it does not need reinforcements. The only qualities that are required of it is to be, and to remain the most and the best reflector = non emitter of the thermal radiation carrying the heat energy.

To respect the H / prescriptions and to ensure that the body of the screen-reflector fabric TER2, in the context of the thermos bottle effect without air vacuum, transmits the least possible radiative energy-heat, it is necessary to give the fabric TER2 a reflective surface of the top possible, for this a polyester-like film metallized to at least 400 Angstroms is required, the metallization being inside and sticking it with a film of the bottom which is the least emitter possible. For this purpose, a metallized polypropylene film will be used. Without being able to explain the phenomenon, it can be seen that the fact of making succeeding films of different support and metallization materials gives better results of reducing contactless heat-energy transport than the succession of support films of the same type. similar material and metallization. In order to comply with the prescriptions I 1 and to ensure that the underside of the screen fabric TER2, in the context of the thermos bottle effect, transmits the least possible amount of radiative energy towards the top of the TER3, the fabric TER3 will be the most reflector = non emitter possible on both sides, with change of the support materials composing the films, while always keeping below a hydrophobic film. To meet the requirements of J 1, K I, L I, M 1, it suffices to repeat the prescriptions of the previous strata. The fact of having five reflective films in a row is not essential, but the veranda experiments in real size have shown us that with 4 times the thermos bottle effect it was found that the underside of the TER4 canvas was always the temperature of the ambient air and emitted no radiative energy. To meet the requirements N / TER5 will have specific characteristics. Indeed it is the bottom of the web TER5 which will be in contact with the users. For this the TER5 canvas can be only a decorative element. Indeed one of the major shortcomings of the existing canvases on the market is that these fabrics are obtained by weaving and weaving does not allow large choice of decorations apart from the multiplication of the eternal stripes or solid colors. In addition the appearance of the decoration concerns all the fabric which is manufactured in large width and in large quantity. While in the context of the present invention it is easy to take any small decorative fabric sold in small widths and to make with a simple sewing machine widths of the desired width and to have a pattern original decoration and personal always appreciated on a store which is usually an industrial product. In a simplified version the bottom of the web TER3 will be able to fulfill the functions of the last web in contact with the users. For this it will be in a material that can be printed by standard techniques so as to present a wide range of decorations and colors. But above all it will be in a hydrophilic material, for example cotton or any other material with high moisture absorption, anti-mold treated. This material will absorb moisture during the night or even the day and will want to evaporate this moisture as soon as the weather or physical conditions will make this possible evaporation. That is to say, as soon as it starts to get a little hot. That is, as soon as the utility of a solar protection awning begins to manifest itself. The hydrophilic fabric will evaporate its moisture as soon as it starts to get hot and therefore delay the impression of heat all the more. On the other hand, the hydrophilic fabric will absorb the ambient humidity without this absorption having the slightest influence on the ambient heat, and in addition with an impression of comfort due to the fact that the relative humidity level of the protected room will be reduced. always extra comfort. In order to facilitate this evaporation, the blind as described above offers the advantage that it necessarily provides the space required for free convection between the top of the roof of the veranda, the underside of the last fabric of the multilayer device TER5 and the bearing wall. This important space will facilitate the circulation of air to cool the underside of the last fabric and especially to promote cooling evaporation as soon as it starts to get hot.

It goes without saying that it will be possible, without departing from the scope of the present invention to reduce or increase, modify the number or the individual characteristics, or to change the order and arrangement of the components constituting the web-reflector-reflectors TER. 10 15 20 25 30 35

Claims (1)

CLAIMS1 / Device in the form of shade cloth to stop the heat-energy darted by any hot surface, such as the sun, transported by radiation, and, among other things, to protect from the excessive heat received, any surface, any transparent volume such as veranda , glass roof, characterized in that: a / this device in the form of multilayer awning fabric superimposed, or juxtaposed, horizontal or vertical, consists of a succession of several, and at least two, continuous surfaces and not woven, superimposed, based on films, said fabrics, treated to be reflectors of energy-heat, on their two faces (TER1, TER2, TER3, TERetc.), to implement the Thermos bottle effect without air vacuum and the shield effect on which, like a projectile, the thermal radiation ricochets, bad conductors of the heat, kept separated and parallel with each other but perpendicular to the sun or the source of chal radiative beam, to constitute a thermal insulation which imposes the transfer of heat-energy by the only exchange of radiative energies, electromagnetic waves between two continuous surfaces without any exchange by contact,> b / this device in the form of multilayer blind fabric is consisting of widths, strips of small widths that will be assembled side by side to form a wide awning fabric, reflective multi-layer fabric whose surfaces which constitute each width, said surfaces are spaced apart from one another by extending between the splines (CN1, CN2, CN3, CNetc.) superimposed web holder profiles without use of any spacer material. 2 / Apparatus according to claim 1 / characterized in that the different webs TER1, TER2, TER3, etc.), reflectors held face to face, are continuous complexes consist of a mechanical support on which are glued, thanks to glues obtained by the crosslinking of Polyesters with isocyanates, reflectors (thus non-emitting on one or both sides of the same fabric), reflectors therefore non-emitting by nature or after treatment, that the reflectors = non-emitting reverberants are protected by a coating hydrophobic and antifouling. 3 / Apparatus according to claims 1 / and 2 / characterized in that at least one of these reverberant reflector-non-emitter canvases comprises a continuous reflective polished solid aluminum foil therefore non-absorber of all the light radiation, totally opaque y included in all ultraviolet, completely waterproof to any form of moisture, conductive of all forms of electricity to reduce static electricity that attracts water and dust, to provide an impression of comfort, serenity, and also includes in addition a second reflective metallized film on both sides, separated from the others by a transparent film and a transparent adhesive film. 4 / Apparatus according to claims 2 /, 3 / characterized in that at least one of these reverberant reflecting screen cloths, and preferably the first TER1, comprises a textile reinforcement son resistant to heat better than plastics such that the glass, the diameter of the son and the maillede of the armature being chosen to constitute specific extra thicknesses avoiding the accidental contact of two successive canvases while imposing the exchange of heat energy by radiation in the zones of the frame does not not touching. 5 / Apparatus according to claim 1 /, characterized in that the last fabric (TER5 for example) visible by the user consists of a decorative fabric independent of the entire blind and other fabrics, easily interchangeable and / or hydrophilic anti-mold treated able to absorb moisture and evaporate to cool the visible wall of the blind visible by users 6 / Device according to claims 1 /, and 2 / characterized in that the first web TER1 comprises at a continuous coating, totally smooth, hydrophobic, non-water-attracting, non-stick, chemical-resistant, non-absorbing light radiation, resistant to all ultraviolet and radiation from the sky, this coating being a film of vinyl fluoride or of the PTFE teflon family or a coating based on poly-methyl methacrylate resins, the back of this outer coating being able to be directly molded tallisé. 7 / Apparatus according to claims 1 /, and 2 / characterized in that the first web TER1 comprises above a standard coating resistant very well to the aggressions to which the blinds are subjected. This first canvas protects the other paintings TER2, TER3 and following and is considered sacrificed. It can be changed without difficulty thanks to the tenon hem device in CN1 splines, without having to change the entire blind as on current systems. The system with multiple flutes also allows to change the canvas TER1 when the hostess wants to change the appearance of her blind. Without changing the entire blind. In the same way the fabric TR5 can be changed especially that it must be hydrophilic and therefore subject to mold. 8 / Apparatus according to claims 1 /, and 2 / characterized in that one uses as reflectors one or embossed surfaces in relief so that the incident rays do not encounter directly perpendicular surfaces but oblique surfaces on which the ricochet of incident radiation will be much less absorbed, so the reverb more effective, in the same way that a shield that receives an angled arrow, oblique, protects better than a shield, a shield that receives a projectile perpendicular. 9 / Apparatus according to claims 1 /, and 2 / characterized in that is used as adhesive to adhere the components of the different fabrics TER crosslinked polyester adhesive with a slightly colored isocyanate, this color to change the metallic appearance of the reflective film of TER1 and give it an appearance more in line with the aesthetic tastes of the users, without much altering the reverb characteristics. 10 / Apparatus according to claims 1 /, and 2 / characterized in that it is arranged after the continuous reflector-non-emitter TER1 fabric several, and at least one, continuous reflective-non-emitting screen fabrics different in their supporting materials and different in their metallizations and gathering the qualities allowing them to be, on each face, reflector and transmitter of energy-heat so as not to transport heat-energy and to have surfaces protected from corrosions and deteriorations as they occur in the use of thermal protection against heat darted by a hot source such as the sun according to the device object of this patent and that the spaces between the imperative volumes between two canvases can be closed, at least one of their ends by a Velcro velvet tape and hook fastened by adhesive or any other means. 11 / Device according to claim 1 / characterized in that the carrier profiles comprise at their apices and at their base a groove, a groove M to the shape of the head of a countersunk head screw. 12 / Apparatus according to claim 1 / characterized in that the support profiles, extruded or obtained by any other means, have on each side a succession of grooves, splines CN1, CN2, CN3, CN4, CN5 parallel superimposed, partially closed leaving an opening whose lips will not let pass the extra thickness created on each side of the webs TER by the constitution of a tenon hem in which is slipped a rod, so that the web-reflector-TER reflectors slipped into these parallel grooves will be kept separated from each other, parallel and spaced apart, juxtaposed or superimposed, and this without any spacing material, the distance separating the parallel openings of the grooves being less than the dimension allowing the natural convection of the air for the conductive temperatures encountered on a blind exposed to the sun in the open air, less than 15 mm. 13 / Apparatus according to claim 1 / and claims 11 and 12 characterized in that the support profiles are divided into two sections: a first PTM master canvas profile having on each side at least two CN flutes and preferably 3, and also having at its top and at its base a mortise groove M in the form of the head of a countersunk screw, and a second profile raises PTR having on each side at least one groove CN, and also having at its top a tenon-shaped bead adapted to the mortise M and also having at its base a mortise groove M which can receive the tenon T of a second profile raises PTR. The profiles of the tenons T and the mortises M being in the shape of the heads of countersunk head screws. In this way, the CN master master PTM master rail profile can be enlarged into a 3 or 4 or 5 NC spline carrier profile by sliding the post T of a PTR riser profile in the groove M that it comprises. at its base and by sliding the tenon T of a second profiled raises PTR in the mortise M of the first extension PTR. 14 / Apparatus according to claim 1 / and claims 11 and 12 characterized in that the device household between the web TER1 and TER2 canvas space sufficient to allow the free flow of air so that the wall no exposed to the sun of the web TER1 and the top of the webTER2 are cooled by natural convection, this to carry the heat that would have been absorbed by the top of the web TER1 especially because of dew whose deposit is inevitable, dew consisting of a thin layer of water that is a black body that absorbs infrared, and also because of the inevitable degradation and dirtiness of the surface of the TER1 fabric exposed to all the attacks of radiation coming from the sky, from the atmosphere and climate. 15 / Device according to claim 1 / and claims 11 and 12 characterized in that the household device between the top of the roof of the veranda, the TER5 fabric and the carrier wall sufficient space to allow free flow of air in order to allow the proper functioning of the TER5 fabric responsible for eliminating completely in the air that bathes it any residual heat which would have crossed the multilayered reverberant shield composed of the addition of the superimposed reflector-non-emissive webs, This to take into account since it is the thermal emissivity of the underside of the last TER5 fabric which alone determines the total result of comfort printing and thermal protection result of all the addition of the components arranged above, the result of protection thermal as it will be judged and appreciated permanently and without appeal by the users. 20 25 30 35