DE102017105710A1 - solar system - Google Patents

Abstract

The invention relates to a solar system. To provide a solar system that can make the sunlight particularly efficient and usable in previously unusable positions, is particularly cost-effective and easy to retrofit, while the visual impression of the object to which the solar system is fixed does not deteriorate permanently, the solar cells particularly efficient against a Damage is protected, it is provided that the solar system has a plurality of slidable on a guide device and / or bevelable slats, wherein at least one solar cell is arranged on each slat

Description

The invention relates to a solar system and the use of such a solar system on a ship, a building or a land vehicle, in particular a train.

From the prior art, it is already known to fix solar systems fixed to a surface, such as a vehicle, a ship or a building. In addition, it is known, a single solar module or a plurality of independent, juxtaposed solar modules pivotable and / or set up rotatable.

However, such an arrangement of solar modules in a solar system has the disadvantage that the solar cells are poorly protected against damage, permanently deteriorate the visual impression of a vehicle, ship or building, are difficult to replace and in a fixed arrangement often an unfavorable angle to the impinging Have light. Finally, the known solar systems can not be retrofitted easily or only at great expense on an existing vehicle, ship or building.

The invention is therefore an object of the invention to provide a solar system that can make the sunlight particularly efficient and usable in previously unusable positions, is particularly cost-effective and easy to retrofit, while the visual impression of the object to which the solar system is set not permanently deteriorated, the solar cells are particularly efficiently protected against damage.

The object is achieved by an apparatus according to claim 1. Dependent claims relate to advantageous embodiments of the invention.

The solar system according to the invention has a plurality of slidable on a guide device and / or bevelable slats, wherein at least one solar cell is arranged on each slat.

The invention further relates to the use of a solar system according to the invention to a ship, in particular a container ship, a tanker, a cargo ship or a cruise ship, the arrangement of the solar system preferably on the outer sides of the ship, more preferably at least partially on the hull and / or the outside the construction and / or stored on the ship containers, in particular ISO containers, and very particularly preferably takes place on both sides of the ship and / or at the rear.

Moreover, the invention relates to the use of a solar system according to the invention on a building, wherein the arrangement preferably takes place on a wall of the building and / or on or in front of a window of the building.

Finally, the invention also relates to a use of a solar system according to the invention on a land vehicle, in particular on a train or on a railroad car.

Preferably, at least one, particularly preferably exactly one solar panel made up of several solar cells is arranged on each lamella. Also preferably, an entire surface of each blade is substantially covered with at least one, preferably with a plurality of solar cells.

The solar system and / or the individual fins and / or the solar cells and / or the bearing housing can initially have any size. Preferably, the sizes of the individual components of the solar system are coordinated.

In a preferred embodiment of the solar system according to the invention, the bearing housing and / or the guide device, in particular at least one side of the guide device and / or one of the guide sections, in particular on a side facing the bearing housing, pivotally fixed to a holding device, whereby the entire solar system or a part thereof opposite the holding device, for example from a wall on which the solar system is fixed by means of the holding device, can be pivoted away or in relation to a surface of the wall is beveled. In particular, pivoting in one direction substantially at right angles to the direction of movability of the lamellae into or out of the bearing housing and / or at right angles to the direction of the guide device is possible.

In a further preferred embodiment of the solar system, the slats are each formed of a solar panel with at least one solar cell, preferably a plurality of identical solar cells.

According to an advantageous embodiment of the solar system according to the invention all the slats are identical to each other and / or formed from a metal.

This solar system is preferably extendable and extendable extendable and / or on can be mounted on both sides of the ship and / or on the stern as well as on the deck.

The system varies in size and layout depending on the size of the vessel and the type of construction.

It is preferable to extend the solar system electrically or hydraulically or mechanically and to pivot the lamellae into the respective position in order to obtain a maximum solar or energy yield.

The advantage of a fin system is that it can be turned into the sun for maximum yield.

A solar system on a sail can also be adapted to the sun by extending the supports.

The extension and retraction of the solar system, for example, in a closable bearing housing, the ship should not interfere with the deletion and can protect the solar system even in severe weather.

It can also be offered a cheaper variant in which the solar system, in particular the guide device of the solar system, is hooked into the container corner points and you need no masts, guide rails or the like for stabilization. Instead, the guide device may then be formed of cables, which are particularly preferably clamped between a bearing housing and the containers at the edge of a ship.

The solar system should provide the ship with electricity and preferably also charge lithium batteries, thereby making the ship, for example, independent of the auxiliary engines and save raw material. Finally, the recovered power can be used to intervene in the drive and thus contribute to the propulsion of the ship.

For example, the solar system may be extendable upwardly and / or downwardly and / or sideways, and the fins may twist about the longitudinal axis. A rotation may also be possible about the vertical axis, in that the bearing housing or a box module in which the slats can be retracted by asynchronous extension or pivoting relative to a holding device for arrangement, for example on a ship's wall allows rotation about the vertical axis.

The trip of the ship could adjust the itinerary so that the fins can keep the maximum efficiency. Furthermore, the fins are cooled by the air flowing around to keep the efficiency high.

• 1 eine schematische Seitenansicht eines Schiffes mit daran angeordneter Solaranlage,
• 2 eine schematische Schnittzeichnung eines Querschnitts des in 1 dargestellten Schiffes mit der Solaranlage,
• 3 ein schematischer Teilausschnitt des in 4 dargestellten Schiffes mit der Solaranlage,
• 4 zwei schematische Darstellungen eines weiteren Ausführungsbeispiels einer Solaranlage mit Solarlamellen in unterschiedlichen Ausrichtungen und
• 5 eine schematische Teilansicht eines Schiffes mit einer Solaranlage in einer eingefahrenen Position.

Embodiments of the solar system according to the invention will be explained below with reference to the drawings. In the figures show:

• 1 a schematic side view of a ship with solar system arranged thereon,
• 2 a schematic sectional view of a cross section of the in 1 represented ship with the solar system,
• 3 a schematic partial section of the in 4 represented ship with the solar system,
• 4 two schematic representations of another embodiment of a solar system with solar fins in different orientations and
• 5 a schematic partial view of a ship with a solar system in a retracted position.

An in 1 illustrated solar system 1 has numerous, each on both sides of a guide portion 5 of a guide device 2 moveable and pivotable slats 3 on. On a surface of the fins are each solar cells 4 arranged for power generation. The solar system is on both sides of a ship S both on a side wall B as well as on containers stored on the ship C set (see 2 ).

The guiding device 2 this embodiment of the solar system 1 consists of guide sections formed as a fixed frame 5 , At it are the individual lamellas 3 hung and guided, with the slats 3 over the full length of the guide portions 5 of a bearing housing 7 pulled out and can be driven back into it. The guide device 2 extends over the full height of the on the ship S stored containers C , Furthermore, on the ship's side B directed downward each have another solar panel 9, which is also at least opposite the hull B is pivotable.

The individual slats 3 are opposite the guide device 2 swiveling (see 3 ).

In the 4 and 5 is another embodiment of a solar system 1 shown in which the guide device 2 , in particular the guide sections 5 through ropes 6a . b are formed at a container corner of the top container C on the edge of a ship S by means of a locking device 8th can be set and braced, reducing the guiding device 2 especially can be formed easily and very flexible and a ship particularly inexpensive with a solar array 1 can be retrofitted.

Like in the 4a and 4b shown, the slats 3 can be pivoted in this embodiment, too.

For example, the louvers can be extended so that a 40 foot container is covered by two modules a about 6 m and a 20 foot container is covered by a box.

Each bearing housing has 4 × 148 cm × 46 cm wide solar cells which are each adapted to the height. With eyelets you get exactly on the 6.1 m of the width of a 20 foot container.

If a ship's length of 360 m a six meter bins 60 bins per side are needed. With a staggering of 6 containers, this corresponds to a height of about 15.5 m and if the solar system continues to extend by 10 m down to the side wall, this corresponds to 25 m total height, resulting in total to about 9000 sqm solar area.

Since some overseas vessels are on routes that are further south, the ships also have a better inclination to the sun and can reach the peak efficiencies better than comparable systems in higher latitudes.

A ship operating on the latitudes from Equator to 45 degrees north / south would be able to use a very high yield.

In the following example, solar cells with an efficiency of 19% are taken into account, which have the dimensions 148 × 46 × 0.3 cm and a dead weight of 1.5 kg. The solar cells are flexible, weatherproof and maritime suitable.

At higher efficiencies, 2.5 times more and more would be possible. With increasing efficiencies in the coming years, profitability will increase more and more.

One unit thus has 200 solar blades, which have a dead weight of 300kg. With brackets and bearing housings 600kg are achieved, which is the case with 60 boxes per side and at the rear 8th Boxes totaled 128 units total with a weight of 38.4 tons.

In addition, the weight of the lithium-ion batteries, which can still be adjusted, of about 40 tons. In addition to cables and accessories, the weight is expected to be about 13.6 tons.

This results in a net weight of the solar equipment on a ship of 92 tons. In addition, if necessary, the brackets and extendable supports of ca.16 tons.

The solar system in the example achieves a total area of 9000 + 9000 + 1125 (rear) = 19125 square meters.

When using 10,000 to 15,000 square meters with direct and indirect light and charged batteries, a generator of 10000kW can be supplied and thus the power supply on board ensured and the rest of the energy to drive or optionally the drive can be used supportive and at slow speeds, the drive can be fully electric, for example near cities or at the harbor entrance.

In severe weather, the solar system or at least the fins would have to be retracted with the solar cells to protect the system. In this case, one would need to access the accumulators or access the original energy source, such as the diesel power generators. The system must be wind resistant.

In addition, two electric motors of up to 10000 kW of power could be installed instead of two or three of the four existing auxiliary motors to drive the ship and / or to supply power.

As a result, one uses the most environmentally friendly energy source that would greatly contribute to the image of the shipping company and would also protect the environment. The CO2 requirements would be guaranteed years in advance. And if the ship is not traveling at full speed, but at 34-36% power, and you install solar cells with a higher efficiency, you would be CO2-emission-free to maintain the ride or speed.

Since a diesel engine has a maximum efficiency of 30% and the efficiency of the electric motor is very high, 100 kW electric power corresponds to about 350 kW diesel power or 475.87 hp. This results in an output of the solar system of 10000W an available electric power to drive according to about 35000W diesel power.

LIST OF REFERENCE NUMBERS

1

solar system

2

guiding device

3

slats

4

solar cell

5

guide section

6a, b

ropes

7

bearing housing

8th

locking device

9

solar panel

e

End of the guide device

S

ship

A

Outside of the construction

B

tailboard

C

Container

Claims (10)

Solar system (1), with a plurality on a guide device (2) displaceable and / or bevelable lamellae (3), wherein on each lamella (3) at least one solar cell (4) is arranged. Solar system after Claim 1 , characterized in that each lamella (3), preferably at opposite ends, is displaceably arranged on a respective guide section (5) of the guide device (2) and / or pivotable relative to the guide section (5). Solar system after Claim 1 or 2 , characterized in that each guide section (5) comprises a guide rail. Solar installation according to one of the preceding claims, characterized in that each guide section (5) at least one, preferably two cables (6 a, b), in particular steel cables, which particularly preferably parallel to one another or at one end (E) of the guide device (2 ) are arranged converging to each other. Solar installation according to one of the preceding claims, characterized in that the guide device (2) comprises an adjusting mechanism by means of which all the slats (3) can be bent at the same time, wherein particularly preferably the angle of all slats (3) with respect to each other and / or the guide device (2) is the same. Solar installation according to one of the preceding claims, characterized in that at least one solar cell (4), preferably all the solar cells (4) of the solar system (1) arranged on a flexible film or formed as a flexible film. Solar installation according to one of the preceding claims, characterized in that all lamellae (3) or all solar cells (4) are connected to an electrical control system and / or to a storage unit, which preferably comprises lithium-ion batteries. Solar installation according to one of the preceding claims, characterized in that all the slats (3) are arranged displaceably on, in particular along the guide device (2) that all slats (3) by means of the guide device (2) and preferably at the same time by means of a drive in a bearing housing (7) can be retracted. Solar installation according to one of the preceding claims, characterized in that the bearing housing (7) and / or the guide device (2), in particular at least one side of the guide device (2) and / or one of the guide sections (5), in particular on a bearing housing ( 7) facing side, are pivotally fixed to a holding device. Solar installation according to one of the preceding claims, characterized in that an upper, in particular one of the bearing housing (7) facing away from end (E) of the guide device (2), in particular each of the guide sections (5) a locking device (8) for fixing to a standardized Holder, in particular on a holder or container corner of an ISO container having.

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