LU81567A1 - SOLAR PANEL - Google Patents

Description

-0—1 ~ ε — Λ— | μ GRAND-DUCHÉ DE LUXEMBOURG L 2 ^ 25

Brevet N ° ............................................ ü. W

you ................. 0.1 .- .. 0..8 ..-. 19, .7.9 ....... Monsieur le Ministre de l'Économie Nationale et des Classes Moyennes

Titre délivré: ........................................ Aiâ'frv. . .

Service de la Propriété Industrielle

T ,. 7 LUXEMBOURG

(Kf m ^,% m Demande de Breyet d’invention 11. <Fo I. Requête

Hans Peter Roser, Hinterbackhaus9 / D-5444 Polch / (1) Allemagne FêdéraïeV représenté par Jean Waxweiler / 21-25 Allée Scheffer, Luxembourg, agissant en qualité de ................. ............... (2) mandataire dépose ce premier août mil ..... neuf ..... cent ... soixante ..... dix-huit .. ... (3) à ,, 1 ^ .00 ...... heures, au Ministère de l'Économie Nationale et des Classes Moyennes, à Luxembourg: 1. la présente requête pour l'obtention d'un brevet d 'invention concernant: .............................................. .................................................. .................................................. .................................................. .................................................. ................................. (4)

<SOLAR COLLECTOR

déclare, en assumant la responsabilité de cette déclaration, que l '(es) inventeur (s) est (sont): ......................... .................................................. .................................................. .................................................. .................................................. ................... (5)

Hans Peter Rôser_, Hinterbackhaus 9 f D-5444 Polch_______________________________________________________ ο, a a <- a Poich. 6 juillet 1979 3. la description en langue ............. al lemande .......................... ..... de l'invention en deux exemplaires; 4 ..................... 2 .________ planches de dessin, en deux exemplaires; 5. la quittance des taxes versées au Bureau de l'Enregistrement à Luxembourg, le ..... p.remi © r .-- aoû-t .-- iail -.- neuf --- Gen-t · - ^ -.soixante .... dix "" huit ....................................... ......................................

revendique pour la susdite demande de brevet la priorité d'une (des) demande (s) de (6) ______________________ brevet .......................... ..................... déposée® en (7) .................. Allemagne Fédérale ________________________________, huit août mil neuf cent soixante dix-huit le .............. (Bj .................... sous ..... le .... nQ., ..... P ..... 2.8 ..... 3.4 ...... 6.3..2. ,, .. 9_______________________________________________________________________________________________________________________________________________________

Hans Peter Roser au nom de ............................................ .................................................. ................. (9) élit domicile pour lui (elle) et, si désigné, pour son mandataire, à Luxembourg _______________________________________ ........ Jean .. ... Waxweiler .., 2.1-25 ..... All.ée ..... Schef. £ er.,. L.uxemhour.g ............... ............................... (10) sollicite la délivrance d'un brevet d'invention pour l'objet décrit et représenté dans les annexes susmentionnées, - avec ajournement de cette délivrance à ................... 6 ................. ....— · mois.

Le ____________ mandataire .............................

** ^ Π. Procès-verbal de Dépôt t .La susdite demande de brevet d'invention a été déposée au Ministère de l'Économie Nationale et des Classes Moyennes, Service de la Propriété Industrielle à Luxembourg, en date du: 01-08-1979 3:00 p.m. le Ministre à heures / de l'Économie National ^ et dès Classes Moyennes, /// Mi V \ -, · [Xifnf 31 l / • - U vis s $ l Ç

PRlOBITlTS-BEIWSPFÜCHUMG

the patent application {fl Germany

From August 8, 1978 at h | r, P 28 34 632.9

DESCRIPTION

FOR A PATENT APPLICATION IN

GRAND DUCHY OF LUXEMBOURG

HANS PETER ROESER

SOLAR PANEL

t - 1 -

Solar panel

The invention relates to a solar collector with a housing in which an absorber is arranged in the form of a pipe system through which a flow medium flows and which is provided with a radiation-permeable cover on at least one wall.

Known solar collectors of this type consist of an essentially closed housing which is provided with a glass cover. The glass cover allows the short-wave and high-energy solar radiation to penetrate the housing without major losses 1o, but forms a barrier to the long-wave heat radiation generated in the collector. In this way, the pipe system inside the housing is heated by heat absorption. The principle of the solar collectors is based on the fact that when the solar radiation is absorbed in a black body, it is heated and emits radiation in the form of heat. Special solar glasses are used as covers, which have a transmission of more than 90% in the entire wavelength range of the solar radiation unit and a transmission of less than 2% for the longer-wave worm radiation. In this way, with good thermal insulation from the outside, an idle temperature of 13 ° C is created.

- 2 - «

In the known solar collectors, the absorber consists of a pipe system with a flat profile. These flat tubes have a flat upper side facing the cover and a flat lower side facing a reflector. The highest 5 absorption values for the energy of solar radiation are obtained when the radiation hits the absorbing surface perpendicularly. This condition is only met once a day when the solar collector is in the most favorable orientation, and at noon when the sun is in the south. The flatter “1o the sun's rays fill the absorbing surface, the * less radiation is absorbed and the more radiation is reflected. This means that with a flat angle of incidence, a large part of the solar radiation is reflected out of the collector even before the radiation has been converted into heat. In the case of a flat absorber element, the effective surface is only approximately as large as the (flat) tube surface facing the cover.

The object of the invention is to provide a Sonnenkoll.ector of the type mentioned, in dom with different directions of incidence of the radiation, the absorption capacity is increased compared to the known collectors and which is particularly large in diffuse radiation (cloudy sky) short-wool * radiation is converted into heat.

25 To achieve this object, the invention provides that the pipe system has at least one pipe with an essentially round cross section.

In the case of a round tube, there is more favorable uptime over a longer period of the day when the sun is moving. -: 3 angle of impact for solar radiation than with a flaqh tube. Although the flat tube, when it is oriented towards the sun, i.e. in the ideal state, gives higher absorption values than a tube with a round cross-section, he-5 proves a round tube with diffuse radiation or with radiation hitting the solar collector as cheaper because it is always one Part of the radiation strikes a part of the pipe surface perpendicularly or almost vertically. The absorption capacity of a round tube 10 is therefore to a greater extent independent of the angle of incidence of the radiation compared to the flat tube and enables a more uniform energy yield over time.

To further improve the absorption process, the tubes of the tube system are advantageously arranged next to one another in one plane at a distance of 15.

In an advantageous development of the invention, the pipe system is underlaid with a reflector. The reflector directs the radiation penetrating between the tubes to the undersides of the tubes, where it strikes the tube surface almost perpendicularly and is therefore absorbed to a large extent.

The reflector can consist of a flat reflective layer which lies on the inner surface of the housing rear wall or can be arranged at a distance above this inner surface. The pipe system can be provided at a distance above the reflective layer or physically connected to it. The physical connection of the pipe system to the reflector improves the heat dissipation of the reflector.

* - 4 -

In an advantageous further embodiment of the invention, the reflector is essentially zigzag-shaped in cross section, and it is a pipe string of each

Pipe system attached to an upper ridge of the reflector 5 parallel to this. The zigzag shape increases the surface of the reflector.

The oblique angles of the reflector enable good utilization and heat transfer to the pipe system even in the case of oblique sunlight.

The zigzag-shaped reflector can be formed at an acute angle or rounded or flattened in at least one of its two planes.

The pipe system is preferably made of copper, the 15 good thermal conductivity is known. The pipe system can be designed, for example, as a pipe coil, one end of which is connected to an inlet line for a heat transfer medium and the other end of which is connected to an outlet line.

An exemplary embodiment of the invention is explained in more detail below with reference to the drawings.

1 schematically shows a cross section through the solar collector with a flat reflector layer,

Fig. 2 shows a schematic diagram of the effect of 25 obliquely incident sun rays and the effect of

Scattered radiation,

Fig. 3 is a schematic cross section through a solar collector with a zigzag reflector, and

Fig. 4 shows schematically a cross section of a further embodiment with a flat reflector layer.

- 5 - a

The solar collector shown in FIG. 1 in cross section consists of a housing 10, the frame 11 of which is made of weather-resistant timber with a deep black matt impregnation. The back of the housing 5 is formed by a waterproof chipboard 12, which carries a high temperature resistant insulation made of polyurethane foam i. The entire housing 10 is anodized

Aluminum profile 13 edged.

The top of the housing 10 ses 10 formed as a flat box is covered with a plate 14 made of special solar glass. The metal profile 13, which surrounds the housing frame 11, engages over the edges of the glass plate 14 so that it is firmly connected to the housing frame. The underside of the glass plate 14 lies on sealing strips 15 15 on a projection 16 which runs around the inside of the housing 10.

The base plate 12 is covered with a flat reflector layer 17 made of aluminum. Above the reflector layer 17 is the pipe system 18, which for example consists of a

Pipe coil exists. The serpentine curved tube 19 has a circular cross section in the present case.

It is made of copper and has a thin tube wall. The pipe ends are connected to connectors (not shown) which lead out of the housing 10. As a 25 Ileizmedium a mixture of Kasser and an antifreeze medium can be passed through the pipe.

In Figure 2, the reflection and absorption ratios are 3 _ - 6 - ί.

of the absorber 19 is shown schematically. When the sun is shining * (left in Figure 2), part of the solar radiation always hits the tube walls perpendicularly, regardless of the angle of incidence of the sun. Therefore, the energy yield of this collector is largely independent of the direction of impact in sunshine.

In the case of diffuse radiation (on the right in FIG. 2), rays from different directions strike the tube 19 or between the tube sections. The rays are partly reflected from the tube wall and then hit another tube at some point and some of the radiation is reflected at the reflector 17 and from there reaches the rear of the tube. Overall, the absorber with a round (or at least approximately round) cross section offers a far greater absorption area than a flat absorber with diffuse radiation. This is particularly important for use in temperate climates with frequent cloud cover for the most uniform energy yield possible.

According to FIG. 3, a housing 10 is designed essentially in accordance with the example in FIG. 1. It is only designed to support the edges of the glass plate 14, a circumferential shoulder 21 on the frame 11, which replaces the projection 16. A sealing strip 15 is inserted between the edge of the glass plate 14 and the shoulder 21.

In the interior of the housing, the pipe system 18, which consists, for example, of a pipe coil, is firmly connected to a reflector 20 made of copper profile. This # i - 7 - i e>

The reflector 20 has a substantially zigzag-shaped course in cross-section, and a pipe string 19 of the pipe system 18 is fastened on an upper ridge of the reflector 20 running parallel to it, e.g. soldered on.

5 In the example of FIG. 3, the lower prongs 23 of the reflector 20 are designed at an acute angle, while the upper prongs are flattened, preferably curved somewhat concavely to accommodate the tubes 19.

The lower prongs 23 are attached to the inner surface of the housing rear wall 12. The angles of the reflector 20 u are chosen so that there are free spaces between * the parallel pipe strands 19, so that the

Sunlight strikes the inclined surfaces of the reflector and this transfers the heat to the pipes 15 19 (their.

Another embodiment of the invention is shown in FIG. 4. In this case, a flat reflector layer 22 made of copper is arranged at a distance above the inner surface of the housing rear wall 12, and the 20 tubes 19 of the tube system 18 are also physically connected to the surface of this reflector 22, e.g. soldered. The outer edges 24 of the reflector 22, which are parallel to the pipe strands 19, are bent upwards to match the radius of curvature of the pipe strings 19.

‘25 Through the gaps between the individual tube strands, the sunlight falls on the reflector 22 and the heat absorbed is reflected by it against the tube system 18.

ï

Claims (13)

1. Solar collector with a housing in which an absorber is arranged in the form of a pipe system through which a flow medium flows and which is provided on at least one wall with a radiation-permeable cover, characterized in that the pipe system (18) has at least one pipe (19) has a substantially round cross-section. 2. Solar collector according to claim 1, characterized in that the tubes (19) of the tube system (18) are arranged next to one another in one plane at a distance. 3. Solar collector 'according to claim 1 or 2, characterized in that the pipe system (18) with a reflector (17; 20; 22) is underlaid. & 4. Solar collector according to claim 3, characterized in that the reflector consists of a flat reflective layer (17; 22). 5. Solar collector according to claim 4, characterized in that the flat reflective layer (17) rests on the inner surface of the rear wall (12). ; 1 -2- 6. Solar collector according to claim 4, characterized * in that the plane reflecting layer (22) is arranged at a distance above the inner surface of the housing rear wall (12). 7. Solar collector according to claims 4 to 6, characterized in that the pipe system (18) is arranged at a distance above the reflective layer (17). 8. Solar collector according to claims 4 to 6, characterized in that the pipe system (18) is physically connected to the reflecting layer (22). 9. Solar collector according to claim 3, characterized in that the reflector (20) is designed in cross section substantially zigzag and one pipe string (19) of the pipe system (18) is fastened on an upper ridge of the reflector (20) parallel to this. 10. Solar collector according to claim 9, characterized in that the reflector (20) is formed at an acute angle in at least one of its two planes. 11. Solar collector according to claim 9, characterized in that the reflector (20) is rounded at least in one of its two planes. -3- 12. Solar collector according to claim 9, characterized in that the reflector (20) is flattened for at least one of its two planes. 13. Solar collector according to claims 1 to 12, characterized in that the pipe system (18) consists of copper. 1 u «