DE4424801A1 - Solar generator mfr. for hybrid solar photoelectrical and thermal generator - Google Patents

Abstract

The method involves selectively depositing solar modules (2) on a resin layer (1) in a mould which completely surrounds it. After embedding into the paving a glass fibre reinforced plastics laminate (3) is used for the assembly completion. In the laminate is formed a cavity (5). The cavity shape is obtained by a cup-shaped support inlay (7) with an access branch (6) for a liq. Then an insulation plate (8) and a reflective foil (9) are resin coupled. The glass fibre reinforced laminate is fitted with an outside seal (4), and the formed hybrid collector is removed from the mould, with the laminate forming its rear side.

Description

The main application according to DE-PS 43 01 404 relates to a Process for the production of solar generators in the form of regular or irregular surfaces of mobile or stationary objects, in a row and / or parallel scarf device connected, arranged in resin embedded solar cell modules a backing layer made of glass fiber reinforced synthetic resin laminate. In addition is the use of this method to make So Lar generators in hybrid collectors for coupled light Heat utilization content of this invention.

After the main registration, a transparent, curable Res resin in a mold with a smooth surface brought, which then cured the solar cell modules there laid out and wired as covering resin. After that then resin is applied, which the solar cells embeds modules and connects to each other after curing det. Then another layer of this resin applied which with its underside the covering resin with the cast-in solar cell modules and one still opened glass fiber reinforced synthetic resin laminate binds. The glass fiber-reinforced synthetic resin laminate is finally on the Au Finished on the outside with a seal. The solar genes Rators are then removed from the mold in a known manner.

The proposed solution uses daylight insufficient supply of solar energy in that they do not ver the heat radiation effective during the day can evaluate. In addition, the efficiency compared to un cooled solar generators can be improved.

The object of the invention is a method for the production of solar generators in a frameless design for -especially not regular or irregular surfaces chen to create mobile or stationary objects that äs allow aesthetic, arbitrarily designed forms, self- the optimal and stable surface Utilization of the daylight offer including its allow thermal component, a light object surface surface (outer skin) as well as a light object execution of the objects carrying solar generators, the elimination of the previous frame construction, necessary border and special Supporting and massive supporting structures despite use too the thermal component of daylight and the uses The procedure for training in hybrid solar allow collectors.

The task is accomplished with the means according to the characteristics of Pa claims resolved. Accordingly, a transparent one hardens resin into a mold with a smooth surface brought. This hardened resin covers the on it placed and wired solar cell modules as covering resin. The resin applied to it embeds the solar cell modules then one and connects them together after curing at the. A layer of this resin applied afterwards binds the resin layer with the cast-in solar cell modules part of the glass fiber reinforced synthetic resin laminate. After a first variant for the use of thermal Component of daylight is in the glass fiber reinforced Resin laminate a cavity with at least two or more shaped access port. The cavity is z. B. formed with a nub-like insert supporting it. On in the end another part becomes glass fiber reinforced art resin laminate. The glass fiber reinforced synthetic resin la minat is sealed on the outside with a seal closed and the solar generators are then on a be known way of the form.  

After, analogous to the first variant described above, the photovoltaic part of the solar generator is created in this second variant using this method, the hybrid Collector manufacture proceeded so that the heat transfer medium register in the glass fiber reinforced synthetic resin laminate as one Cavity with at least two or more access ports is formed. It becomes the cavity at a distance from the edge creative, pimpled support and in the Randla ge opposite and penetrating each one access spigot from the other part applied glass fiber reinforced art Resin laminate over the surface by means of selective puncture and edge connected created. There is an insulating plate and on finally a reflective film is applied by resin and finally another part of glass fiber reinforced art resin laminate applied. The glass fiber reinforced synthetic resin lamination nat is sealed on the outside with a seal and the solar generators are then operated in a known manner Taken form.

The use is according to patent 43 01 404 or one of the before standing process in such a way that the hybrid collector is in nem heat-absorbing part in the glass fiber reinforced synthetic resin lamination nat is formed by a hollow at a distance from an edge space through resin with an inlay supporting it like a knob ge is formed, the cavity in the peripheral position opposite and penetrating each with an access port from the other part applied glass fiber reinforced synthetic resin Laminate across the surface by resin-bonding at certain points and edges which is completed, an insulating plate on top and then a reflective film is applied by resin and on finally another part of glass fiber reinforced synthetic resin laminate nats is resinated. The glass fiber reinforced synthetic resin laminate is sealed on the outside with a seal (Final order). Finally, the solar generators taken from the mold in a known manner.

The associated drawings show in

Fig. 1 shows a section through the layer structure of a Solargenera tors for the power-heat utilization with the created in the glass fiber-reinforced resin laminate cavity of predominantly a material,

Fig. 2 shows the layer structure of a solar generator for the use of electricity and heat in which the nat created in the glass fiber reinforced synthetic resin laminate additionally has an insulation and sits

Fig. 3 shows the structure of a hybrid collector produced using the method according to the main patent or claims 1 or 2 for the use of electricity and heat, designed for use as a roof panel or as a surface covering.

An embodiment of the invention is described below with reference to the layer structure of FIG. 1, which shows the sequence of the work steps on the cut.

While the main filing is the manufacturing process for the Extraction of electrical energy from solar daylight offer includes, this invention is intended with its further ent Development according to this procedure for the full use of the of the solar energy also contain thermal energy.

In the process for producing the solar generators after the main application, transparent resin 1 is applied in a form of predetermined choice to form the future outer skin. After Anharzen of the hardened resin 1, the Solarzellenmodu be le 2, directed after the expected in the application case Sonnenein designed angle of incidence and wired. Subsequently, transparent resin 1 is again entered until the commercial solar cell modules 2 contained in housing units are completely covered. The next step is a laminate structure made of glass fiber layers with synthetic resin that is dependent on the static specifications. In this first part glasfaserver reinforced synthetic resin laminate 3 , a cavity 5 with at least two access ports 6 by resin, z. B. a knob-like from supporting insert 7 , formed.

According to FIG. 1, the rest part is directly Liche of glass fiber-reinforced resin laminate 3 be applied to the cavity 5. This synthetic resin laminate then represents the load-bearing component in connection with the heat transfer medium designed from the cavity. The glass fiber reinforced synthetic resin laminate ( 3 ) is provided with a seal 4 on the outside and the solar generators are then removed from the mold in a known manner.

The drawing figures 2 and 3 show a solar generator cutout produced by the method and a cut double collector, which is suitable as an insulated hybrid collector for both photovoltaic and thermal solar energy use. The photovoltaic upper part consists of the transparent resin 1 , the above, between and below in seäu housed solar cell modules 2 envelops them alone in the covering resin. The solar cell modules 2 are networked with one another in series or parallel connection and with the transparent resin 1 to the underlying synthetic resin laminate 3 connected. The glass fiber reinforced synthetic resin laminate 3 forms the carrier layer in which a cavity 5 is formed. This cavity 5 has at least two access ports 6 , which results in a heat transfer medium register for the circulating liquid. The subsequent applied further glass fiber reinforced te resin laminate 3 envelops the cavity and the synthetic resin laminate 3 is in turn provided on the underside with the seal 4 . These access ports 6 are interconnected with access ports of the adjoining heat transfer medium register.

The drawings show the weather-resistant, light outer skin of the objects carrying the hybrid collector, which is built up by resin-bonding to the hybrid collector. The cavity 5 of FIG. 2 is formed in the glass fiber reinforced synthetic resin laminate 3 using a nub-like supporting insert 7 . In addition, the underside of the cavity 5 is resin-coated with an insulating plate 8 and a heat-reflecting film 9 and encased by the glass fiber-reinforced synthetic resin laminate 3 which follows. The glass fiber reinforced synthetic resin laminate ( 3 ) is provided with a seal 4 on the outside and the solar generators are then removed from the mold in a known manner. The shape is only used to achieve the integration of the solar cell modules in the outer skin of the objects, when encapsulated solely in the covering resin that forms the object surface of the solar generator, and the creation of the hybrid collector.

Different resins 1 can be used in the different layers depending on the load requirement. The objects of the solar generators produced according to this method can be mobile or immobile. The most obvious applications are roof surfaces and outer walls of motorhomes, outer and top surfaces of boat hulls.

The utilization of the thermal energy content takes place with the means the state of the art. The collector for the thermal part of the Solar energy is the weatherproof hybrid collector for direct Roof covering or surface cladding. For the use of heat as a circulating liquid, a mixture of water and antifreeze or an oil is provided as a heat transfer medium. The registers will be On the pipeline side, horizontally or vertically in series with one another and tightly connected parallel to a pipe system and the zir temperature-controlled liquid under pump pressure fed to a collecting container. There takes over from a heat transfer a heat pump carries the heat energy to temperature increase in a single or multi-stage, second with water driven storage system, thereby ent appropriately tempered service water from a boiler is available. The heat pump is from the now in battery mulators stored electrical energy from the solar cells is produced, fed. The heat reduced by its heat content Carrier is again circulated by the circulation pump Liquid fed to the hybrid collectors. That way it stands Pre-warmed is sufficient for the extraction of warm service water Hot water available. A Glysan can be used as the heat transfer medium tin-water mixture are used. The hybrid collectors can can be elastically connected to one another by silicone resins. A hybrid collector is understood to mean a double collector that for both photovoltaic and thermal suns energy generation and use is suitable.  

Advantages of the invention are that the solar cell modules in the thin ne outer skin of the objects, integrated only in the covering resin. The solar generator forms the outer skin of the objects. With the For Manufacturing processes could improve the incidence of light, a Improvement of the power consumption and the carrying function of the solar generator and for the objects in which the solar cell module inte is achieved. With this procedure you can as well Flat parts with an irregular course with solar cell modules designed and thus in a freely selectable variety of forms for education high performance capacities can be used efficiently.

Also the prefabrication of the solar generators in segments and that Subsequent casting with resin to a monolith offers itself at. Optimal use of the changing ver different angles of incidence and even the use of scattered light is possible. With this method, the production is faster and cheaper to realize, the products have op technical advantages, are sufficient in terms of design and aesthetics say and there are considerable weight reductions. With this hybrid collector, the photovoltaic Part of the solar generator while pumping around the circulating Liquid cooled, resulting in an increase in its efficiency leads. The hybrid collectors have a high strength, are of high efficiency, long life, have low heat losses and are reliable and require little maintenance.

Other advantages of the method and its use are that of it set the usual roof coverings and save roof underlay pave the way. They also form a roof insulation and save the usual roof insulation panels. You make the facades yourself cladding. The hybrid collectors can be regenerated. she use renewable energies and are therefore environmentally friendly.

Reference list

1 transparent resin
2 solar cell modules
3 glass fiber reinforced synthetic resin laminate
4 sealing
5 cavity
6 access ports
7 Knob-like supporting insert
8 insulating plate
9 reflective film

Claims (3)

1. A process for the production of solar generators in the form of regular or irregular surfaces of mobile or stationary objects, wherein in series and / or parallel connection interconnected, directionally arranged, resin-embedded solar cell modules have a backing layer of glass fiber reinforced synthetic resin laminate, characterized ,

• - That a transparent, curable resin ( 1 ) is introduced into a mold with a smoothed surface, which then cures the solar cell modules ( 2 ), then laid out and wired, thinly covering as a covering resin,
• - that subsequently resin ( 1 ) is applied, which then already embeds the solar cell modules ( 2 ) in the covering resin and connects them to one another after curing,
• - That a further layer of this resin ( 1 ) is applied, which binds with its underside the covering resin with the cast-in solar cell modules ( 2 ) and part of a glass fiber-reinforced synthetic resin laminate ( 3 ) which is still applied, as a result of which the encapsulation takes place,
• - That in glass fiber reinforced synthetic resin laminate ( 3 ) a hollow space ( 5 ) with at least two access ports ( 6 ) is formed by resin-forming a knob-like supporting insert ( 7 ), and then another part of glass fiber reinforced synthetic resin laminate ( 3 ) is resin-coated,
• - That the glass fiber reinforced synthetic resin laminate ( 3 ) on the outside with a seal ( 4 ) is completed and
• - That the solar generators are then removed from the mold in a known manner.

2. A method for the production of solar generators in the form of regular or irregular surfaces of mobile or stationary objects, wherein in series and / or parallel connection interconnected, directed arranged, embedded in resin solar cell modules have a backing layer of glass fiber reinforced synthetic resin laminate, characterized in that

• - That a transparent, curable resin ( 1 ) is introduced into a mold with a smoothed surface, which then cures the solar cell modules ( 2 ), then laid out and wired, as a covering resin,
• - that subsequently resin ( 1 ) is applied, which embeds the solar cell modules ( 2 ) and connects them to one another after curing,
• - That a further layer of this resin ( 1 ) is applied, which binds with its underside the cover resin with the cast-in solar cell modules ( 2 ) and part of a further applied glass fiber reinforced synthetic resin laminate ( 3 ),
• - In that a cavity ( 5 ) creating a gap ( 5 ) creating a nub-like supporting insert ( 7 ) and in the edge position opposite and penetrating each one access piece ( 6 ) from the further part applied glass fiber reinforced synthetic resin laminate ( 3 ) punctually over the surface and finished with resin on the edge,
• - an insulating plate ( 8 ) and then a reflecting film ( 9 ) is applied thereon by means of resin and then a further part of glass fiber reinforced synthetic resin laminate ( 3 ) is applied,
• - That the glass fiber reinforced synthetic resin laminate ( 3 ) on the outside with a seal ( 4 ) is completed and
• - That the solar generators are then removed from the mold in a known manner.

3. Use of the method for producing solar generators in a hybrid collector for coupled use of light / heat in the form of regular or irregular surfaces of mobile or stationary objects, being connected in series and / or parallel connection, directed to ordered, in resin embedded solar cell modules have a backing layer made of glass fiber-reinforced synthetic resin laminate, in which a transparent, curable resin is introduced into a mold with a smoothed surface, which then cures, covers and covers the solar cell modules, laid out and wired, as covering resin, where resin is subsequently applied, which embeds the solar cell modules and connects them to each other after curing, the subsequent further layer of this resin ( 1 ) is applied, which has the underside of the cover resin with the cast-in solar cell modules and a further applied glass fiber reinforced plastic resin laminate binds, then the glass fiber-reinforced synthetic resin laminate is then sealed on the outside with a seal and the solar generators are then removed from the mold in a known manner, according to patent 43 01 404 (file number P 43 01 404.6-33) or claim 1, characterized in that that the hybrid collector is formed in its heat-absorbing part in the glass fiber reinforced synthetic resin laminate ( 3 ) by spacing a cavity ( 5 ) by resin at a distance with resin with a knob-like support insert, the cavity ( 5 ) in the peripheral position opposite and these penetrating each with an access piece ( 6 ) verse hen from the other part applied glass fiber reinforced synthetic resin laminate ( 3 ) over the surface by resin and punctual and edge-connected, then an insulating plate ( 8 ) and then a reflective film ( 9 ) through Resin is applied and then another part glass fiber-reinforced resin laminate (3) is prospective physician, and that the glass fiber-reinforced resin laminate (3) is completed on the outer side with a seal (4).