WO2016034737A1 - Solar collector - Google Patents

Abstract

The invention relates to a solar collector, thus a device with which sunlight can be converted into a different form of energy, preferably electric energy. In particular, the invention relates to a solar collector (20) which comprises a plurality of solar panels (10, 12, 14, 16) that extend substantially on a panel surface, each solar panel comprising at least one solar cell. The solar collector comprises at least one panel assembly (18) which comprises at least one first solar panel (10) and at least one second solar panel (12). The first solar panel (10) has a first surface perpendicular (S₁) on the panel surface (E₁), and the second solar panel (12) has a second surface perpendicular (S₂) on the panel surface (E₂). The first solar panel (10) and the second solar panel (12) do not run on one plane, and the panel assembly has a main axis (H) which runs substantially parallel to the panel surface of the first solar panel (10) and the panel surface of the second solar panel (12) and which intersects the intersection point between the first surface perpendicular (S₁) and the second surface perpendicular (S₂). The invention is characterized in that the main axis (H) does not intersect a solar panel of the panel assembly, and solar panels are arranged in an angular range of at least 180 degrees about the main axis (H).

Description

 solar collector

Field of the invention

The present invention relates to a solar collector, so a device with the sunlight can be converted into another form of energy, preferably electrical energy. In this case, solar cells can be used on a semiconductor basis. Background of the invention

 US patent application US 2010/0252085 A1 relates to a solar collector in which a parabolic dish is used to focus light onto a solar cell arranged in the focal point of the dish. The parabolic bowl stands on a tripod so that the bowl can be rotated according to the position of the sun. For this purpose, a complex mechanical adjusting device is required.

US patent application US 201/0272368 A1 is representative of another known approach in which a stand is provided on which solar panels can be arranged in a long oblique surface.

The German patent application DE 199 22 795 A1 relates to a further development of this concept. Again, solar modules are arranged in an extended oblique surface. In the stand presented in this publication, however, one can adjust the inclination of this inclined surface.

The German utility model DE 20 2006 003 476 U1 relates to an even more extensive approach. In this case, not only the inclination angle of the inclined surface can be varied, but also can the solar modules are tilted within the inclined surface. For all this hydraulic drives are provided.

European patent EP 3 47 443 B1 discloses a solar module in which trough-shaped mirrors are used. These mirrors are combined with sandwich solar cells, which can capture light on their top and bottom surfaces. This happens directly on the upper side, on the lower side only after reflection by the channel-shaped mirrors. For this purpose, the width of the solar modules should correspond to the diameter of the semicircle which the channel has in cross section.

European patent EP 4 64 738 B1 gives an example of the use of solar modules on ships. Several solar cells will be connected to form a frameless solar cell laminate. These can also be positioned on a walk-on deck surface.

The US patent application US 201 1/0146752 A1 shows a solar cell arrangement in which also a mechanical adjustment of the panels with the solar cells is provided. For cooling, a liquid circuit should serve, as a rule, water should flow through copper pipes to dissipate heat from the solar cells. In addition, a cleaning system is provided, can be passed through the water to spray outlets. This will then be used to clean the solar panels. The ability to cool and clean here requires a complicated structure.

The present invention seeks to improve this prior art. In particular, a solar collector is to be offered, which brings a good energy yield with low mechanical complexity and thus high reliability. He should be used in different places, especially on ships. Description of the invention

 This object is achieved by a solar collector according to claim 1.

The solar collector may include a variety of solar panels. It will comprise at least two panels, but may also comprise several hundred solar panels.

The solar panels are units that can convert sunlight into another form of energy. This can be done in various ways, for example by heating a medium. The solar panels should have solar cells. Typically, solar cells turn sunlight into electricity. For this purpose, semiconductors are used in so-called wafers in a known manner. However, a solar cell is understood to mean any cell that converts sunlight into another form of energy.

Each solar panel may include one or more solar cells. Several solar cells can be arranged side by side in the main plane of extension of the panel.

The solar collector comprises at least one panel dressing. It can also include many more panel assemblies, for example several dozen panel assemblies. A panel structure comprises at least two solar panels, namely a first solar panel and a second solar panel. The first and the second solar panels of the panel assembly do not run in one plane. The first solar panel has a vertical surface and the second solar panel has a vertical surface. These intersect at a certain point, since the first solar panel and the second solar panel do not run in one plane. The verticals are expediently erected in each case above the centroid of the respective panels. Incidentally, the surface perpendiculars are to be paid in each case on the side on which sunlight is to fall, in which Usually, this can also be referred to as a photovoltaic side or, as follows, briefly as a PV side. Such a vertical above the centroid is understood herein to mean a "central surface perpendicular".

The panel structure has a major axis which is substantially parallel to the panel surface of the first solar panel and the panel surface of the second solar panel. This main axis also passes through the described intersection of the first surface perpendicular with the second surface perpendicular. The major axis is one of the major axes of inertia of the panel assembly (and should generally be preferred).

The solar collector should be designed so that this major axis cuts at most one solar panel of the panel assembly. Often it is useful to make the panel structure so that the main axis does not cut any solar panel of Paneelverbandes.

The solar collector may have a bearing configuration and a payload configuration. For example, if the panels of a solar collector are arranged to be movable, it is possible to convert the solar collector into a compact storage position. This can also be considered if the solar collector is designed like a blind, as will be explained in more detail below. In the storage configuration, the solar collector regularly takes up less space than in the utility configuration. Furthermore, in the storage configuration, the solar panels are usually together at an acute angle. In this case, a storage configuration means any configuration in which adjacent solar panels enclose an angle of 30 degrees or less. Other configurations of the solar collector, which naturally allow more sunlight to shine on the collector, should be understood as a useful configuration. Furthermore, solar panels are to be arranged in an angular range of at least 180 degrees around the main axis. This geometric arrangement of the solar collector allows a much higher light output than previously usual. This applies in particular to cases in which the solar collector is not moved. Because the main axis intersects at most one solar panel of the panel assembly, the panel assembly provides at least one open area into which sunlight may be incident. In this case, a steep incidence of sunlight is possible, approximately parallel to the main axis, typical and expedient is usually an incident of sunlight at an angle of 10 to 80, usually 30 to 60 degrees to the main axis. As the position of the sun changes during the day, different areas of the solar panel are illuminated more intensely. However, as sunlight is usually incident at an angle to the major axis, the area that is most heavily lit is traveling around a circle around the major axis. Because solar panels are arranged on such a circle around the main axis in an angular range of at least 180 degrees, it is possible at different positions of the sun to use the solar collector effectively. The use of the solar collector is particularly effective if solar panels are arranged in an angular range of more than 270 degrees around the main axis. It is also possible and may be convenient to arrange solar panels around the major axis in an angular range of 360 degrees. In addition to the solar panels, which are arranged in such an angular range, it may be expedient to provide an additional solar panel which intersects the main axis. This can be understood as the bottom of an open-topped box, the remaining walls of which are formed by the remaining solar panels, and in whose open "cover" side sunlight can shine in. The above considerations on the geometry, in particular for covering an angular range of more than 180 degrees, more than 280 degrees or even 360 degrees about the main axis, shall each apply to a useful configuration of the solar collector.

It is expedient to provide a panel assembly of three to five solar panels. A panel of three solar panels can have a triangular shape in a cross section perpendicular to the main axis. A panel structure of four panels may have a rectangular shape, diamond shape or a square shape in such a cross-sectional view. The use of four panels has proven to be particularly useful.

It is also useful if the panels are arranged on the side surfaces of a cuboid or specifically cube. It is again expedient if the sides of the panels to be certified by the sun, also referred to herein as their PV sides, point towards the inside of the cuboid. Of course, for the sun to reach this inside, at least one side of the box must be at least partially open.

An interesting embodiment of the invention also results from the fact that a solar collector is made available from a plurality of modules, which each have two or more solar investors themselves. The panels of such a module are expediently arranged in each case at a right angle to each other. In other words, each module consists of a cuboid shape in which between two and five side surfaces are filled by panels. While it is desirable that the panels of such a module form a fixed angle with each other, so it may also be appropriate if the angle of adjacent modules is mutually variable. In this case, the angle can be freely variable, so that a variety of modules to a kind of blind is connected. The angle can also be changed fixable. Such fixation may result, for example, by locking screws. When releasing such screws or fixing certain angles are freely variable, in their fixation, however, these angles are no longer variable. Such a fixation of individual angles can also result from a fixation of the solar collector as a whole, for example the end position of modules. For this purpose, the solar collector can be used in a suitable frame. The solar panels themselves can also have a rectangular shape in the panel plane. You can also have the typical round waver shape.

A particularly useful solar collector results when the angle between the first solar panel and the adjacent second solar panel is variable. On the one hand, then the position of the solar panels can be optimized for the sun. On the other hand, the panel can be transferred from a use position in a transport position. It is also expedient to arrange panels in a solar collector so that their panel surfaces are parallel to one another and orient the solar cells in opposite directions. Such Solarpaneelpaare that are sort of arranged back to back, may be parts of adjacent panel associations. In this way, a larger solar collector can be built very compact.

It is also expedient to provide a solar collector with a plurality of panel assemblies in which the panel assemblies have parallel main axes. The panel dressings may extend over a first surface in a plane EA which is perpendicular to the major axes H. It is useful if this surface is variable in size. It is expedient to provide a solar collector which can be held by a first holder and by a second holder. It is particularly useful if these holders can be moved in the plane EA, preferably they can be moved in the plane along a first direction towards and away from each other.

Particularly useful is the solar collector according to the invention, especially if it is built to be movable, in particular for use on a ship. In this case, the plane E _A can be aligned both horizontally and vertically.

The invention therefore also relates to a ship, preferably a sailing ship, which has a solar collector of the type described.

Other features, but also advantages of the invention will become apparent from the following drawings and the accompanying description. In the figures and in the accompanying descriptions, features of the invention are described in combination. However, these features may also be included in other combinations of an article of the invention. Each disclosed feature is thus also to be regarded as disclosed in technically meaningful combinations with other features. The illustrations are partly slightly simplified and schematic.

Fig. 1 shows a schematic view of the arrangement of

Solar panels in a panel structure. shows a schematic view of the arrangement of panel assemblies in a larger solar collector. shows a schematic plan view of an embodiment of a solar collector. shows a schematic plan view of another embodiment of a solar collector. shows in a schematic view a plan view of an embodiment of an adjustable solar collector that covers a large area. shows a schematic view of a corresponding view in which the adjustable solar collector covers a smaller area. shows in a similar view the coverage of an even smaller area. shows a schematic view of the attachment of a solar collector according to the invention on a boat, wherein the solar collector covers a large area. shows in a corresponding view a position of the solar collector in which it covers a small area. shows a schematic view of an alternative attachment of a solar collector to a boat, the solar collector covers a large area.

Fig. 7B shows in a corresponding view a position in which the

Solar collector covers a small area. Fig. 8 shows another solar collector according to the invention comprising various panel assemblies.

Fig. 1 shows a schematic perspective view of a panel structure, which may be part of a solar collector. Visible is the course of the first solar panel 10, which is substantially along a plane, the plane E | runs. At right angles, the second solar panel 12 connects, which runs in the plane E ₂ . This in turn is followed by the third solar panel 14, which in turn is at right angles to the second solar panel 12. The three solar panels thus define a cube shape and form three side surfaces of this cube. Opposite the second solar panel 12, a fourth solar panel (hereinafter referred to as a solar panel 16) could be provided, but the panel panel 18 shown is only three solar panels.

The first solar panel 10 and the second solar panel 12 define the course of the main axis H, which runs parallel to both extension planes of the solar panels. The main axis H of the panel intersects two perpendiculars constructed in the same way on the plane Ei and on the plane E ₂ . The vertical Si was erected on the centroid of the first solar panel 10. The vertical S ₂ was erected on the centroid of the second solar panel 12. The main axis H is therefore defined by verticals on the respective centroids.

The major axis H passes through the top and bottom surfaces of the cube. Both surfaces are free of panels. Accordingly, light can be incident through these open areas. In a plane perpendicular to the main axis H, light hits the provided panels. In this plane, an angle range α (alpha) of 270 degrees is covered by panels. According to the panel dressing should be designed so that this angle is not less than 180 degrees.

Fig. 2 shows a perspective, schematically slightly simplified representation of a solar collector of a plurality of panel assemblies. Marked are the panel assemblies 18a, 18b and 18c. While the panel assembly 18a consists of only two solar panels and therefore covers an angle range α alpha of only about 180 degrees, the adjacent panel assemblies 18b and 18c each consist of four solar panels, accordingly, in the panel assemblies 18b and 18c, an angular range α (alpha) of Covered 360 degrees.

For the panel assembly 18b, the corresponding solar panels are marked, there are a first solar panel 10, a second solar panel 12, a third solar panel 14 and a fourth solar panel 1 6 are provided. The four solar panels define a cube shape. They form four adjacent sides of this cube, the ceiling and bottom of the cube remain open. Accordingly, sunlight can radiate well from these directions.

For panel assembly 18c, the direction of the main axis is indicated. The other panels have parallel main axes. It can also be seen that in adjacent panel assemblies, the corresponding solar panels are aligned back to back to each other, so touching each other in parallel.

The solar collector can easily absorb sunlight from different directions. It works optimally when the sun moves on a conical surface around the axis H. The conical surface expediently forms an angle of 10 to 80, usually also 30 to 60 degrees to the main axis. Fig. 3 shows a schematic view of the top view of a solar collector, which substantially corresponds to the construction of Fig. 2, but has a slightly larger number of Paneelverbänden. Again, panel panels 18a, 18b and 18c are indicated. It can be seen that it is not necessary for the purposes of the invention that all panel assemblies have the same number of solar panels. Accordingly, the panels of all panel assemblies need not describe an equal angular range α about the major axis. FIG. 4 also shows a schematically simplified view of an alternative embodiment of a solar collector according to the invention. Here, the panel dressings are arranged so that all panels form a square in cross-section. Panel panels with four solar panels are also provided on the edge of the solar collector. Accordingly, solar panels are provided in an angular range α (alpha) of 360 degrees around the major axis.

In particular, when an angle range of 360 degrees around the main axis is covered by panels in a panel structure, the main axis is to be selected as the symmetry axis of the panel assembly.

FIG. 5A, together with FIGS. 5B and 5C, shows a further embodiment of a solar collector. In these three figures, the embodiment is shown in a schematic plan view from the direction of the main axis H. The plane you look at, the level of supervision, is called level EA. This plane EA is always a plane perpendicular to the main axis or axes. For orientation, three panel panels are again shown, the panel panels 18a, 18b and 18c.

Between adjacent panels an opening angle β (beta) is provided, which is representative of a panel association. Fig. 5B shows that the panel assembly shown can be transferred to another position. In this position, the angle β (beta), which was 90 degrees in Fig. 5A, is sharper. Accordingly, the expansion of the solar collector 20 in the plane EA is smaller. Its extent along a first extension direction R _A has been greatly reduced. However, its extension along a second extension direction R _β , which is perpendicular to the direction R _A , has increased slightly.

Fig. 5C shows the same solar collector 20 in another position. The angle ß beta is even sharper. Accordingly, the expansion of the solar collector in the direction RA is greatly reduced. In the direction of R _ß the extent is slightly increased. Overall, however, a significantly reduced area is occupied in the plane E _A. In the configuration shown in Fig. 5C, the solar collector thus occupies little space. Accordingly, it gives also incident impact or incident rain little impact surface. On the other hand, the solar panels are covered to a good extent by other solar panels, so that provides little Einstrahlfläche for sunlight. The position of the solar collector shown in FIG. 5C can therefore also be referred to as a transport configuration. Accordingly, the position shown in FIG. 5A may be referred to as a payload configuration.

FIG. 6A shows the use of a solar collector 20 on a boat 30. The illustration is again schematic. The solar collector 20 is clamped between a first holder 22 and a second holder 24. The first bracket 22 is connected to the rail 32 of the boat. In this position, good sunlight can be captured. Fig. 6B shows that the solar collector 20 can be transferred from its transport position into a use position. For this purpose, the first holder and the second holder moves towards each other. The brackets move in the plane E _A. In the transport position shown, the solar collector offers a significantly lower wind resistance. Depending on the use of the boat and wind and weather conditions, this can be very desirable.

FIG. 7A again shows the solar collector in its useful configuration. In turn, it is spanned between a holder 22 and a second holder 24. With the first holder 22, it is mounted on the rail 32 of a boat 30. The plane E _A extends this time in the horizontal. The solar collector can also be sensibly mounted on a boat in this orientation. Depending on the construction of the holder 22, it may also be possible to convert the solar collector from a vertical to the horizontal orientation. It may also be possible to freely set the plane EA relative to the boat 30. In this case, in particular, the angle of the plane EA can be adjusted to the vertical - free or selected in stages.

FIG. 7B shows that the transfer from a useful configuration to a transport configuration is also possible with horizontal mounting. For this purpose, the second holder 24 is moved toward the first holder 22.

Solar collectors can be used very advantageously for mobile power. Such use is particularly advantageous on non-motorized or not exclusively powered vehicles. This may include pedal-driven vehicles, such as bicycles, but also boats. Important is a permanent power supply on sailboats. Sailboats are usually equipped with an auxiliary engine at most, but have a certain power consumption for lighting equipment, navigation devices, etc. Producing this power safely presents a challenge. Power generation with solar cells is quite interesting. Keep in mind, however, that the boat is in an almost random position to the sun, and not it seems appropriate to align the boat course with the position of the sun. Also, it often comes for reasons of space out of the question, for example, by motorized adjustment, the solar cells always optimally align the sun.

Solar panels according to the present invention, which work well in different positions of the sun, are therefore ideal for such use on a boat. However, since the solar collector itself also provides some attack surface for wind and he could eventually act as an unwanted additional sail, it is very advantageous if the solar collector can be transferred to a transport position in which he offers the wind and other weather little attack surface.

In addition to the possibility of the transfer of a transport configuration in the Nutzkonfiguration and also because of the ability to use the solar collector in different intermediate positions, the use of such a solar collector as a kind of blinds or shading device is possible. In this way, such solar panels could be used behind board windows or used for shadowing deck areas. Appropriate use is also well outside of boats in both general horizontal as well as in generally vertical orientation.

8 shows, in a schematic cross-sectional view, a solar collector according to the invention which comprises two panel assemblies. The first panel assembly 18 includes a first solar panel 10 and a second solar panel 12. The panel assembly may also include other solar panels, for example, could be compared to the solar panel 12, a third solar panel disposed parallel to the solar panel 12 and also a right angle to the first Solar panel 10 forms. The solar collector 20 further includes the further solar panels 34 and 36. These are collectively solar panels of a second panel assembly 38. In this association, the first panel 34 is in a plane with the first solar panel 10 of the other panel association. The second solar panel 36 extends parallel to the second solar panel 12 of the panel assembly 18. The two panels 12 and 36 are oriented back to back. The PV side of the second solar panel 12 thus points in the direction of the center of the panel assembly 18, while the PV side of the second solar panel 36 points to the center of the second panel assembly 38. Also, the panel assembly 38 may include other solar panels, such as a third solar panel, which is perpendicular to the panel 34 and parallel to the panel 36. Thus, according to the manner already described, both panel assemblies may generally be in the shape of a cuboid or cube in which two or more walls form panel surfaces oriented respectively with their PV side toward the center of the dressing.

The corresponding panel assemblies are each constructed geometrically stable. That is, the solar panels of a bandage each take a fixed angle to each other, usually at right angles. However, the two panel assemblies may be mutually movable or immovable. It is advantageous if two panel dressings are movable relative to one another along an axis. The mobility can also be fixed. Such fixability results, for example, by a lockable and releasable locking screw. It is expedient to use for this purpose between two panel associations each a connecting means.

The connecting means may for example be provided at the upper ends of the panels 12 and 36 and connect them together. (The upper end of the panel 12 is understood to mean the end opposite the panel 10, while the lower end of the panel 12 is adjacent to the panel 10.) This connector may be for example, to act a hinge about the manner of a piano hinge. Because in itself solid panel federations are connected to each other movable to a larger solar collector, you can address the individual panel associations in this context as modules. A large number of modules thus results in a kit for a solar collector. Consequently, it is possible to easily adapt this solar collector in size to various tasks.

Due to the mobility of the modules with each other, it is also possible to construct a kind of blind, as shown in Figures 6A, 6B, 7A and 7B. Such a blind can be used for shading purposes and in particular for the solar power supply of boats. For both applications, the modular design is advantageous. It is also advantageous that a limited base or outer surface can be used intensively, that is, the area covered by photovoltaic elements may be larger than the available base or outer surface.

Overall, it shows how a very expedient solar collector can be built, which can be used well in different positions and is particularly suitable for mounting on a ship.

LIST OF REFERENCE NUMBERS

10 first solar panel

 12 second solar panel

14 third solar panel

 1 6 fourth solar panel

 18 panel dressing

 20 solar collector

 22 first bracket

24 second bracket

 30 boat

 32 reeling

 34 first solar panel of the second panel association

36 second solar panel of the second panel assembly 38 second panel

 H main axis

 E | Extension level of 1 0

 E2 extension plane of 1 2

 S | Vertical to E |

S2 perpendicular to E2

 Ej supervisory level

 P »A first extension direction at supervisory level

P »B Second extension direction in plan view plane α Angular range around H

ß panel angle

Claims

claims

1 . A solar collector (20) comprising a plurality of solar panels (10, 12, 14, 16) extending substantially in a panel surface, each solar panel comprising at least one solar cell, the solar collector comprising at least one panel structure (18) at least one first solar panel (10) and at least one second solar panel (12), wherein the first

Solar panel (10) has a first central surface perpendicular (Si) on the panel surface (Ei), and wherein the second solar panel (12) has a second central surface perpendicular (S2) on the panel surface (E ₂ ), and wherein the first solar panel (10 ) and the second solar panel (12) do not extend in a plane, and the

 Panel Association has a major axis (H), which in

Substantially parallel to the panel surface of the first solar panel (10) and the panel surface of the second solar panel (12), and which intersects the crossing point of the first surface perpendicular (Si) with the second surface perpendicular (S ₂ ), characterized

 characterized in that the major axis (H) does not intersect a panel panel solar panel, and solar panels in the panel

 Useful configuration in an angular range of at least 180 degrees about the major axis (H) are arranged.

2. Solar collector (20) according to claim 1, wherein the solar panels are arranged in an angular range of more than 270 degrees about the main axis (H).

3. Solar collector (20) according to any one of the preceding claims, wherein the solar panels are arranged in an angular range of 360 degrees about the main axis (H).

4. Solar collector (20) according to one of the preceding claims, wherein the first solar panel (10) and the second solar panel (12) are arranged at a fixed right angle to each other.

5. Solar collector (20) according to any one of the preceding claims, wherein the incidence of sunlight from directions in one

 Angle range of 10 degrees to 80 degrees to the main axis (H) is possible.

6. Solar collector (20) according to any one of the preceding claims, wherein the solar panels are arranged on the surfaces of a cuboid and their PV sides are aligned towards the inside of the cuboid.

7. Solar collector (20) according to one of the preceding claims, which consists of a plurality of mutually movable modules, each module comprising at least a first solar panel (10) and a second solar panel (12), which are arranged at a fixed angle to each other.

8. Solar collector (20) according to one of the preceding claims, wherein at least one panel assembly 3 to 5 solar panels,

 preferably has 4 solar panels.

9. Solar collector (20) according to the preceding claim, wherein the solar panels from the direction of the main axis (H) a

 describe square or diamond-shaped cross-section.

10. Solar collector (20) according to one of the preceding claims, wherein the solar panels have round or rectangular solar cells.

1 1 .Solar collector (20) according to any one of the preceding claims, wherein the angle between the first solar panel (10) and the second solar panel (12) is fixable variable.

12. Solar collector (20) with a plurality of panel formations (18) which extends in a plane perpendicular to the main axis (H) plane (E _A ), and there covers a surface of variable size.

13. Solar collector (20) according to one of the preceding claims, which is held by a first holder (22) and a second holder (24) and in which preferably the first holder and the second holder parallel to each other in the plane (E _A ) and can be moved away from each other.

14. Solar collector (20) for mounting on a ship, wherein the plane (E _A ) extends horizontally or vertically.

15. Ship, preferably sailing ship, with a solar collector (20) according to one of the preceding claims.