HU226546B1 - Heat stream channeled roof tile and the made from these for utilization of solar energy - Google Patents

Abstract

The roofing tile has a heat channel made of clay mixed with leaning and coloring agents, formed by upper and lower mirroring profiles. Two heating channels are formed on one tile, if the dimension of the tile is increased. Several flexible collector pipes made of silicone rubber are led into heat channel, to receive heat receiving medium containing mixture of ethylene glycol water, ammonia or aqueous solution.

Description

Scope of the description is 10 pages (including 4 pages)

EN 226 546 Β1

Field of the Invention The present invention relates to a new structurally constructed roof tile and as a solar collector utilizing a solar system built from it.

Roof tiles are well-known flat roofing building blocks, which are pressed into a press press or pressed and burned out by the press, which are among the most important products of the ceramic industry. The most well-known classic roof tiles are described in Volume 3 of Engineering Structures, Balot Palotás: Beton - Habarcs - Ceramics - Plastic (Akadémia Kiadó, Bp. 1980). (Fig. 483 XI. 10). Roof tiles of many manufacturers are well known in the market, the raw material of which is mainly clay and adobe, which is mixed with iron oxides mixed with them to yellow, brown or red on burning. It is well known that the vast majority of our buildings, especially our residential buildings, are covered with clay and lacquers at a temperature of about 800-1200 ° C with a once-burned roof tile. When burning, they get a porous tile. The shades of color varying from blue to slate gray are achieved by switching on a flame-reducing flame for a short time after incineration, and during that time, dilute tar oil is fed to the furnace. If the roughly shaped pieces are coated with clay or clay, they will receive deep red or brown roof tiles after burning. Glazed tiles are filled with colored earth or lead and burned once more. (RÖMPP: Chemical Lexicon, Technical Book Publisher, Bp. 1984) Various building protection products, such as 0.05-0.1 mm of quartz flour mixed with low melting glass forming materials, are used to enhance weather resistance, which is energy efficient because it melts at 800 ° C gives enamel-like coating. (Green: Brick, Tile Production, Bp. Technical Book Publisher 1958). They are also made of glass, plastic, asbestos, concrete, roof tiles, and board plates, bituminous sheets and metal sheets. We list these as necessary because these building elements are only designed to protect buildings against rain, cold, wind and high-intensity sunlight and to meet the aesthetic requirements of monument protection.

Nowadays, however, solar energy recovery is becoming increasingly urgent. Efforts to achieve this, in the construction and application of various solar collectors, have produced significant results by storing the thermal energy of the sun by technical means.

Various, mainly experimental, homes and greenhouses for solar heating and household constructions, many of which are not used in industrial applications.

It is known that geographical - climatic conditions have a decisive influence on the technical use of solar energy. Central European (44 degrees to 49 degrees latitude, 14 degrees to 24 degrees long), for example, in Hungary 1800-2200 hours of sunshine per year and 42% of the sun's rays.

Since our invention is basically a tile roofing element that has been developed specifically for solar energy use, we consider it necessary to separate our solution from roofing elements, tiles and shingles that are closest to the same task at the technical level.

The patent application disclosed in EP 0020798A1 discloses a roofing element made of concrete, in which a tubular radiator is embedded during manufacture, pressed.

The main feature of this solution is that a heat exchanger in a concrete shingle is cast into concrete and, referring to the drawings, describes that the pipes of the tube radiator can be arranged horizontally or vertically in the concrete.

The description describes that each of the tubular radiators embedded in the concrete is provided with an inlet and an outlet, by means of which the tiles above or adjacent to one another can be connected in series or columns, and in this system, an antifreeze liquid is circulating with a pump minus 30 ° C. The description refers to the possibility of condensation on the contact surface of the concrete and the metal pipe radiator, which must be taken into account during manufacture. However, this problem is not solved in the description, presumably because if you place an insulation between the concrete and the pipe radiator, it becomes almost inappropriate to use the solar energy, and without the insulation it can freeze under the freezing point of the concrete tile.

U.S. Pat. No. 4,445,2020 discloses a planar roofing tile having a circular nest receiving a tube in a tile-like position in the overlapping portion of a roof, which is a circular nest in the top tile on its lower surface, in the lower tile on its upper surface. It consists of a semicircular groove that is closed together. In the closed circular seat, a fluid conduit is provided, where the pipe wall receives heat from the tile and passes it to the circulating fluid. Here, the pipe system is well suited to the classical roof structure, but with this solution the heat transfer between the roof tile and the pipe is very local, with thermal conductivity, so it utilizes only a small fraction of the heat absorbed by the tile because the tile is a bad thermal conductor. This roof tile construction is a well-designed solution for fixing and holding the connected pipeline, but does not provide more in the design of a heat accumulation system than laying the pipes over the rafters (horizontally) over the tiles.

FR 2415 178A discloses a solution where a trough-like recess is provided on the roof side of the roof tile or simply a window. A metal lid enclosed with a top-transparent lid is placed in this trough or window, which is connected to a similar metal rod placed in a roof tile placed above it. The sun2

EN 226 546 Β1 is designed to deliver fluid to the top of the roof by pumping and draining free-flowing through the bottom plate of the metal flap coupled to each other, while the leaking liquid takes over the heat difference of the sun-heated metal flap, collecting the drain fluid at the bottom of the roof. to a heat exchanger.

This roof tile is designed as a support structure for placing a metal vessel and the roof tile has no appreciable effect on the efficiency of the solar energy system thus installed. The disadvantage of such a tile structure is that the basic function of the roof becomes doubtful due to the fitting and insulation problems of the two structures. There could be a problem with the metal dish on the outside of the traditional roof.

It can be stated that the closest solutions known at the technical level can be applied to the utilization of solar energy with a lot of disadvantages and little results.

It is an object of the present invention to provide a completely new roof tile structure, which by its application is significantly more solar energy, by eliminating the defects and defects of roof tile solutions known in the art, by eliminating roof tile (protection against precipitation, shielding, wind, snow and ice loading). to create a new system that can be deployed with simple tools in an existing building environment and run without risks.

We have discovered that a greater part of the solar radiation energy can be collected and utilized in enclosed spaces on the entire surface of the roof tile and in closed spaces with high heat potential on the opposite side, such as in a tunnel furnace between very small but very different thermal conductivity (tile and metal) surfaces. with local heat transfer.

We discovered that the heat-absorbing capacity of the roof tile can be significantly increased if a roof-like structure is formed under the roof tiles, from the tile material. It is well known that the heat capacity of bodies increases in proportion to their heat and weight. A multi-layered cabinet-like roof tile in which the layers are joined by ribs of their own material, where the ribs are spaced apart and form closed channels together with the layers, constitute a heat trap with increased heat capacity, such as the heat passages of the tiled stoves. The upper visible part of the roof tile remains unchanged, the cabinet-like part is located in the lower part of the tile, and the roof tile can be positioned in the same layout as the standard roof tile, which in itself makes its use attractive. From the clay it is possible to form a cupboard roof tile so that its mass does not overload the support structure.

The object of the present invention is therefore to provide a roof tile, namely a roof tile with a material of clay or loam, which has been made into a soft paste by means of lapping and / or coloring agents, molded into a single, once-burned porous tile that fits onto a roof tile and has a structural feature that the top tile profile of the roof tile has a structural feature. at the lower part of the roof tile a mirror-like profile is connected and the two facing profiles form a closed channel where the closed channel is located at the bottom of the roof tile and, when installed in the lower edge of the roof tile, the closed channel is up to the upper edge of the roof tile - a steam-cone-like, prismatic heat channel forming a pipe profile with a pipe profile, which is preferably formed in parallel with two roof tiles by increasing the width of the roof tile in a roof tile, and the width of the roof tile and the length of the roof tile. according to the size of the tile, the lower part of the heat channels is removed. With this design, the roof roof tiles can be installed in place of the roof tiles used so far, or can be built in the same way as in the case of new buildings, even if they do not want to be connected to a solar system at the time of construction.

Preferably, the base material of the roof tile clay is approx. 5% black coloration transmitter (CoO, FeO, Cr ₂ O 3) is mixed with a dye and is the surface treated before sintering at 800 ° C, melt coating using a coating of 0.05 to 0.1 mm is particularly preferred silica flour with a particle size . In a preferred embodiment, the absorption of sunlight is achieved by 98% when a pigment blend of about 10 to 15% (dye) is blended with the lacquered clay material, so the roof tile treated thus absorbs infrared rays.

The heat-shrinking tile according to the invention is specifically designed to create a solar energy system. At the technical level, we presented the closest solar collector systems related to roof shingles.

Our aim was to eliminate disabilities that limit the effectiveness and operational reliability of the known solutions.

In line with our goal, we have created a flawless solar collector system that is fully in line with the built environment. The simple, additional effect of the system is ensured by the synergy of the factors involved. As the solar energy transmitted to the roof tiles, apart from absorption in the atmosphere, is approx. 2 cal / cm ² min, ie approx. 1.38 kw / m ² , therefore, it is necessary to provide a large irradiated surface to absorb irradiated energy. (RÖMPP: Chemical Lexicon, Technical Publisher Bp. 1984). This is why we use the entire roof surface so that it is covered with the heat channel roof tiles according to the invention. Due to our geographic and climatic conditions, special attention was paid to the heat transfer medium. The water is used as a 1: 1 ethylene glycol-water mixture, which is an antifreeze liquid up to -40 ° C, with thermal properties of 50% more favorable than water alone. Preferred conditions are ammonia or an aqueous solution of ammonia known as straw straw, a high evaporative heat of ammonia (1460 KJ / kg) commonly known as heat transfer medium. In this

EN 226 546 Β1 In case of re-liquefaction, a separate device or compressor is required, however, the heat of this can be utilized with the heat storage.

We examined the material to be used for the circulation of the heat transfer medium. In contrast to the most preferred material, the previously used non-ferrous metal, heat and frost resistant rubber, especially hot vulcanized silicone rubber, was found to have a rubber elasticity in the range of -100 ° C to +250 ° C. Species weight is small 1.6-2.2 g / cm ³ , 1 meter 3/4 inch tube weight, less than 0.2 kg. Excellent heat of heat (0.28-0.35 KJ / K degree kg) and thermal conductivity (0.33-0.55 W / mK degrees). Such chemicals are known as SlLASTIC, RHODOSIL, SILOPREN, SILASTOMER. The heat transfer ethylene glycol-water mixture or aqueous ammonia solution or ammonia is thus circulated between the roof and the heat exchanger in a circulation tube made of silicone rubber.

Thus, our solar energy recovery system with a heat pipe roof tiles is a flexible collector pipe, which is led under the roof tiles of buildings, filled with heat transfer medium, liquid, unsaturated steam, or gas, to which the heat transfer medium is led by a manifold located in the lower part of the floor space, the flexible collector tubes connected to the heat collecting pipe in the upper part of the floor space. the heat collecting tube itself is connected to a known heat exchanger apparatus, the system being characterized in that the flexible collector tube material of the manifold and the heat collecting tube is silicone rubber, preferably hot vulcanized silicone rubber, and the flexible collector tube is provided in the prismatic heat ducts or pipe profiles of the heat channel roof tiles, preferably in pairs, and the roof rafters are secured to the sides of the roof rafters, which are completely insulated by the insulation between the rafters. panels are provided, wherein the side of the insulating panel facing at least the roof tile is laminated with 0.1-0.3 mm thick aluminum foil, and wherein the heat transfer medium is preferably a 1: 1 ethylene glycol-water mixture, or ammonia (NH ₃ ), or an aqueous solution thereof, which is fully sealed by heat transfer media, indirectly, preferably with a heating spiral or a dual-wall heat exchanger vessel.

Preferably, the flexible collector tube is a 1/2 or 3/4 inch nominal size silicone rubber with a wall thickness of 1.5 to 2 mm.

Preferably, the flexible collector tube is connected to the manifold from the riser, the descent, and again to a rising, endless wave, thereby increasing its absorption path.

It is connected to the manifold and to the heat collector pipe by hose connectors and hose clamps that are stuck to the flexible collector tube, gas, vapor and liquid loss completely sealed.

Preferably, the heat collecting tube has a thermostatic valve on the side of the heat exchanger which opens at a specified temperature.

It is preferred that in the flexible collector tubes, a capillary constrictor is provided in the riser and descending wave to slow down the flow.

The thermal channel roof tiles according to the invention and the solar energy system implemented with it are illustrated in the figures below.

Figure 1, roof tile with a prismatic heat channel in perspective view;

Fig. 2, roof tiles with two prismatic heat channels, increased tile surface, perspective view;

Figure 3, two prismatic two-side roof tiles in a perspective view;

Figure 4, four two-row, two prismatic heat channel roof tiles for displaying the heat pipe connections;

Fig. 5, roof tile with a pipe profile heat pipe in perspective view;

Figure 6 is a cross-sectional view of a pipe profile of a pipe profile with a pipe profile along the M-M plane of Figure 5, depicted in a mounting position;

Figure 7 is a schematic illustration of a solar energy system in a solar thermal roof.

Figure 1 shows a perspective view of the prismatic design of a roof tile of a heat channel 2. In the bottom view, the profile at the bottom of the roof tile, which together with the trapezoidal profile above the usual, forms a through-hole, so-called prismatic heat channel 1, is clearly visible. Here, it can be seen that in the lattice-fitting strip C, the section of the roof tile at the bottom of the roof tile according to the invention is removed, thereby providing a flat grip on the roof rack C to the top edge of the roof tile F and showing the two cams on the roof tile C. The upper trapezoidal profile is substantially different from the conventional extrusion, because it does not penetrate into the upper, pleated plane of the tile, but protrudes over it, covering the upper portion of the prismatic heat channel. At the lower edge of the roof tile, the upper trapezoidal profile extends to a wider extent to accommodate the trapezoidal profile, which is tapering at the upper edge of the roof tile. Here, the overlay B is depicted where the lower section of the prismatic heat channel 1 is removed. The prismatic heat exchanger 1 closes as shown in Fig. 4 for the overlapping tile lines, so that the upper plane of the roof rack C replaces the portion of the bottom section removed at the top edge of the roof tile F. In the fitting part, a few millimeters of gaps are formed (also due to manufacturing tolerances), but these provide an advantageous flow draft for the inner roof.

Figure 2 shows a perspective view of the prismatic two heat channel roof tiles 3. The fact that two heat chambers are formed in a single pot has an additional effect designed in our invention because it is capable of collecting and storing more heat energy than two prismatic two-channel roof tile without temporary resistance. This roof tile is made of clay, its weight does not reach the rude, concrete roofing elements made of concrete, so it does not require a stronger support structure. This figure shows the protrusion of the upper trapezoidal profile, the lower edge of the roof tile A and its size4 at the top edge of the roof tile.

EN 226 546 Β1. Here D denotes the bending direction of the roof. Of course, the valuable features of the pressed roof tiles are preserved so that not only on the long sides but also on the short sides with grooves and cams, the associated grooves on the top edge of the roof tiles F, the cams that fit into them are visible on the lower edge of the roof tiles, and here denote the prismatic 1 heat channels.

Figure 3 illustrates the connection of two three prismatic two tile roof tiles 1 adjacent to each other;

Fig. 4 shows the overlapping of two overlapping tile lines as the top edge of the roof tile A overlaps the upper edge B of the roof tile F with the overlap overlay.

Fig. 5 shows a roof profile 5 having a pipe profile 5, in which the heat channel is perpendicular to the cross section. Note that heat channels 1, 5 are exemplary! its profiles are best suited for the purpose of the invention because the size of their covering surfaces is the largest. We also consider our protection requirements to be different for roof tiles with different profiles, but other designs of the basic design of our invention.

Fig. 6 is a sectional view taken along the M-M section of Fig. 5 with a 5-pipe roof tile with a roof profile built on the roof structure. The figure shows schematically the hanging of the pipe profile 4 on the roof rack section C on the roof raft C by the cams, the removed part of the lower section of the pipe profile 5 on the roof rack C, the overlap B on the roof tile L, here V1 and V2. marked the upper and lower wall thicknesses of the heat channel, which can be selected to differ in size. We do not disclose the description of production-related know-how in our submission, and for the professional (tool designers) skilled in the art, the design of the required pressing tool is a normal design task.

Figure 7 shows the part of a solar energy system in a roof tile 1.5 that is connected to a roof structure. One or more flexible collector tubes 9 are provided in the prismatic heat pipe 1 or in the pipe section 5 in which the heat transfer medium is flowed from the distribution tube E located underneath the loft into the heat collecting tube H located above the roof. Preferably, the placement of two flexible collector tubes 9 in a heat channel row is expedient and it is advisable to connect the flexible collector tubes 9 to the heat collecting tube H after a riser, landing, and a second riser. This provides heat absorption for a length of 10-15 meters. On the opposing sides of the rafters SZ, a retaining strip 8 is attached, on which heat insulating panels 7 are laid and on the side of the insulating panels 7 facing the roof tiles 2, 3, 4 they are covered with aluminum foil with a thickness of 0.1-0.3 mm. The schematic arrangement is connected to a heat storage or heat exchanger.

The solar energy system associated with FIG. 7 is exhaustively described in the relevant part of the description. Here you will find brief information on how to operate the system. In our flexible collector tubes 9, it is preferred to circulate a mixture of ethylene glycol water or ammonia or an aqueous solution thereof as a heat transfer medium. The ammonia can be used more efficiently, but it should be noted that the ultraviolet rays of the sun also break down into nitrogen and hydrogen, while a large amount of thermal energy is released, which leads to cooling and returns to liquid ammonia reversibly. In aqueous solution this conversion occurs only by evaporation, preferably the solution contains 15-25% ammonia (density: 09-08 g / cm ³ ). The flexible collector tube should be closed and well sealed, which should be vented before filling to avoid undesirable concentrations of air and ammonia.

Our system can be connected to different heat storage devices, and users can choose the best solution for their design proposal. Expert briefing is required on how to deal with storing excess heat in the summer and how to heat the heating system in winter, how to heat it, and how to produce hot water.

The heat channel roof tiles of the present invention can absorb, store, heat, transfer, and pass through the solar collector tubes under controlled solar air from the solar energy, such as the well-known roof tiles, the heat content of the receiving medium, the material of the collector tube and the arrangement of the invention. can be utilized to a very large extent, not yet described. The roof of the heat channel is a new product for the construction industry and the tile industry.

Claims (9)

1. A heat-ducted roof tile, which is formed from clay or adobe to leachable pulp by reducing and / or coloring agents, is molded once into a porous tile, which overlaps the roof tile by a profile on the top of the tile profile. , the two profiles facing each other form a closed channel, where the closed channel is located at the bottom of the roof tile (2, 3, 4) and the closed channel of the roof tile (2, 3) at the lower edge (A) of the roof tile (2, 3, 4) 4) forming a heat-channel (1) or a tube-shaped heat channel (5) extending extensively to the base or conical surface, which is preferably formed in parallel in the roof tile (3) and the width of the roof strip (C) size and the size of the installation overlap (B) before, the lower part of the heat channels (1, 5) is removed. 2. The heat-tile roof tile according to claim 1, characterized in that the clay base material has a size of ca. It is mixed with 5% by weight of a black coloring agent (CoO, FeO, Cr ₂ O ₃ ) and, after molding, with a coating melting at 800 ° C before firing, preferably HU 226 546 Β1 It is coated with quartz flour with a particle size of 0.05-0.1 mm. The heat channel roof tile according to claim 1, characterized in that the clay base material is mixed with 15-20% by weight of pigment carbon black in addition to the leaning material. 4. Solar energy recovery system with a heat channel roof tile, a flexible manifold filled with heat transfer fluid, liquid, unsaturated vapor or gas, under roof roofs of buildings, to which the heat transfer medium is fed through a heat sink in the lower part of the attic, (H) are connected flexible manifolds connected to a known heat exchanger tube (H) by means of a known heat exchanger, characterized in that the flexible manifold tube (9) is made of silicone rubber, preferably hot-vulcanized silicone rubber, and the flexible collector tube (9) is guided in the prismatic heat channels (5) of the heat channel roof tiles (2, 3), preferably in pairs, and retaining strips (8) are fixed to the sides of the roof rafters (Sz) to completely fill the space there are insulation boards (7) laying where the side of the heat-insulating panels (7) facing the roof tile (3, 3) is laminated with aluminum foil (6) 0.1-0.3 mm thick, and wherein the heat transfer medium is preferably a 1: 1 mixture of ethylene glycol and water, or ammonia (NH ₃ ) or an aqueous solution thereof, the heat transfer media being connected to the heat exchanger by means of a fully sealed, preferably heating coil, or via a double walled heat exchanger. Solar energy recovery system according to claim 4, characterized in that the flexible collector tube (9) has a nominal size of 1/2 inch or 3/4 inch and a wall thickness of 1.5-2.0 mm. Solar energy recovery system according to Claim 4 or 5, characterized in that the flexible collector tube (9) is connected in a continuous wave from a manifold (E) to a heat collector (H) in an ascending, descending and again ascending wave. 7. Solar energy recovery system according to any one of claims 1 to 3, characterized in that the flexible collector tube (9) is connected to a manifold (E) and to the heat collector tube (H) by sealed hose connections, completely sealed against gas, moisture and liquid loss. 8. Solar energy recovery system according to any one of claims 1 to 3, characterized in that a thermostatic valve is disposed on the side of the heat-collecting pipe (H) connected to the heat-exchange device. 9. Solar energy recovery system according to any one of claims 1 to 3, characterized in that at least one reducing capillary is formed in the ascending and descending wave of the flexible collector tubes (9).