NL1039535C2 - MOUNTING SYSTEM FOR SOLAR PANELS OR SOLAR THERMAL ELEMENTS ON BUILDINGS FACADES. - Google Patents

Description

Mounting system for solar panels or solar thermal elements on facades of buildings

Description 5 The invention relates to a mounting system for solar panels or solar thermal elements 5 as part of facade cladding on buildings 6. This mounting system consists of a solar panel or solar thermal element 5, at least a decorative facade panel 4 and a supporting structure for attaching the solar panel and the facade panel to the facade assemble. The solar panels or solar thermal elements 5 are mounted on the supporting structure such that a high yield of solar energy results from this element. In general, this means that the solar panels or solar thermal elements 5 are mounted at an angle of less than 45 degrees with a vertical plane. For optimization that is related to the facade orientation relative to the south, it can be opted to mount the solar panels or solar thermal elements 5 diagonally on the facade at an angle to the horizontal plane. The solar panels or solar thermal elements 5 are mounted such that the different elements only cast a minimal amount of shadow on the underlying elements. The spaces between the solar panels or the solar thermal elements are filled in by decorative panels 4 which are mounted on the structure between the different solar panels or solar thermal elements and which can reflect sunlight to the solar panels or the solar thermal elements. the solar panels or solar thermal elements 5 are increased.

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Issue

Solar panels are used to directly convert the incident radiation from the sun into electricity. Solar thermal elements are used to use incident radiation from the sun for heating or evaporating a medium. Solar panels or solar thermal elements are rarely used on facades because the energy efficiency of these precious elements is low if they are mounted vertically. Examples are known of solar panels or solar thermal elements that are mounted to the façade at a more favorable angle via a special support structure without thereby filling the spaces between these panels with inclined façade elements. These solar panels or solar thermal elements thus indeed obtain a higher solar yield, but have the disadvantage that the facade usually produces a little aesthetic facade image and that the yields are still relatively low because the solar panels or solar thermal elements must be mounted at a relatively large distance from each other in order to prevent energy losses by shading the solar panels above or solar thermal elements.

It is known that the energy content of sunlight increases as the sun rises higher in the sky. The higher the sun height, the more important the light for the yield of solar panels or solar thermal elements. In Europe, the sun never rises higher than a sun height of around 70 degrees in southern Europe or 50-15 degrees in northern Europe. In the Netherlands, the highest solar height is reached at midday in June. The solar height is then approximately 61 degrees.

The object of this invention is to develop a facade system with integrated solar panels or solar thermal elements in which the energy efficiency of the expensive solar panels or solar thermal elements is high, wherein the facade offers an aesthetically attractive solution and wherein the facade provides all facade functions such as, for example, waterproofing, rainproofness , impact resistance and thermal insulation.

Solution according to the invention The solution is found in a façade system in which solar panels or solar thermal elements 5 are mounted in an inclined angle range with the vertical axis on the façade, whereby the solar radiation on these elements is increased compared to a vertical mounting on the facade. By mounting decorative panels 4 between the solar panels or the solar thermal elements 5, which complete a closed facade shape, the facade can be completed so that it can fulfill the normal facade functions. By choosing decorative 3 panels 4 with a high reflection of sunlight, it can be achieved that the sunlight received by these decorative panels is at least partially reflected to the solar panels or the solar thermal elements 5. In this way, the yield of these solar panels or solar thermal elements is 5 and 5 sunlight that falls on the façade from unfavorable angles, but also the solar panels or solar thermal elements 5 is achieved. This offers advantages at times when the sun's height is relatively low, such as in the morning, in the afternoon, in the autumn, in spring or winter. By providing the decorative panels with a texture or a hint, the reflection angle of the decorative panels can be directed to angles that deviate from the rule that angle of incidence = angle of reflection. In this way, the decorative panels can reflect more energy-rich light to the solar panels or solar thermal elements. The texture can be a saw-tooth shape 3. Reflective pigments with a high aspect ratio (length / width versus thickness of the pigments) such as, for example, aluminum pigments, mica pigments and film-shredding pigments can be introduced with an orientation into a lacquer layer or plastic element so that they receive the sunlight with a preferred direction 8. It is also possible to place reflective panels with different angles 11 in the space between the solar panels or solar thermal elements or to place curved reflective panels 12. In this way it is possible to reflect sunlight from different directions to the solar panels or solar thermal elements.

It is possible to choose partially light-transmitting solar panels or solar thermal elements or to combine these with light-transmitting elements so that part of the sunlight can reach the interior of the building.

It is possible to select a light-transmitting element for a part of the decorative panels, such as for instance a window glass. This makes it possible to allow sunlight into the interior of the building or to get a good view from the inside of the building.

Description of the drawings

Figure 1 shows how a glossy decorative panel reflects sunlight.

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Figure 2 shows how a matted decorative panel reflects sunlight.

Figure 3 and Figure 5 show how a texture in a decorative panel can influence the reflection angle of the incident sunlight.

Figure 4 shows how the façade system is mounted on the substructure of a façade wall. A solar panel or solar thermal element 5 is attached to the substructure of facade wall 6 or directly to facade wall 6 at an angle range. The decorative panels 4 are attached to the substructure or directly to the wall 6 at an angle alpha. By allowing an overhang and ventilation option 7, the building physical benefits of a ventilated facade 10 can be utilized and the solar panel can be cooled by the ventilation air. Cables, water supplies and other technical facilities can be installed in the triangular space.

Figure 5 shows a textured decorative panel in the same angle of inclination as panel 4 of Figure 4. Figure 5 shows that such a textured decorative panel is capable of transferring energy-rich sunlight from higher solar height to the solar panel or the solar thermal element. to reflect. The dimensions of the texture can vary from very small to large. A texture depth of a micrometer to a few millimeters is possible.

Figure 6 shows how a decorative panel 8 with oriented reflective pigments are able to reflect light to an angle that deviates from the angle of incidence of the light. These reflective pigments may, for example, consist of aluminum pigments, mica pigments and film chips. These pigments can be used in a lacquer layer or a plastic element.

Figure 7 shows a decorative panel 9 in which a texture is covered with a transparent flat layer. The decorative panel is thus given a surface texture that differs from the texture of the functionality that determines the direction of the reflected light.

Figure 8 shows a transparent decorative panel 10 which is provided with a texture at the rear and optionally with a reflective layer. This decorative panel hereby acquires a surface that deviates from the functionality that determines the direction of the reflected light.

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Figure 9 shows a façade with the same functionality as the façade in Figure 4. In this façade, between the repeating unit of Figure 4, a surface is added which is provided with a steeply inclined decorative panel 11. In this way, sunlight from several different radiation directions effectively reflected to the solar panel or the solar thermal element.

Figure 10 shows a facade with the same functionality as the facade in Figure 4. In this facade, the decorative panel has been replaced by a curved panel 12. In this way, sunlight from different radiation directions can be effectively reflected to the solar panel or solar thermal element.

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Example

A south-facing inner shell 6 of a facade in the Netherlands is provided with a grid of vertical aluminum profiles. Thermal insulation material and moisture-inhibiting film are mounted between these profiles. Triangular aluminum profiles are mounted on the 15 vertical aluminum profiles on which solar panels 5 are mounted on the top and glossy white decorative sheet materials 1 are mounted on the bottom.

The solar panels are mounted such that there is a small overhang 7 of the solar panels 5 over the end face of the decorative panels 4. Hereby ventilation is possible in this space while raining in is prevented. The ventilation via the space under the overhang 7 is advantageous because it allows the building physical advantages of a ventilated facade to be utilized and because the solar panels can be cooled by the ventilation air. A solar panel has a lower yield the higher the temperature.

In this example, the triangles are designed in such a way that they enable a high return in the Netherlands. The solar panels 5 are 20 cm wide and are mounted horizontally on the profiles in the east-west axis and in the north-south axis at an angle range of 55 degrees with the vertical axis. The decorative panels 1 are mounted horizontally in the east-west axis and in the north-south axis at an angle alpha of 30 degrees to the north-south axis. In this way the solar panels receive a large amount of direct sunlight. In particular, the sunlight that reaches the earth in 6 an angle near 55 degrees will fall perpendicular to the solar panels and thus yield a maximum energy efficiency. In the Netherlands, the highest intensity of solar energy is measured at angles near 55 degrees. This sun height is only reached around noon in the summer months.

5 Sunlight reaching the earth at an angle of about 90 - 2 * 25 = 40 degrees will be reflected vertically downwards by the decorative panels and thereby make a positive contribution to the yield of the solar panels.

Sunlight that reaches the decorative panel diffusely or at a different angle will also be able to contribute to the energy efficiency of the solar panel or the solar thermal element because light is diffused diffusely through the surface of the decorative panel or because the sunlight strikes the solar panel or the solar thermal element reached in a shifted location.

If a matted white decorative panel 2 is chosen, then approximately 90% of the light will be reflected. Because the reflection of a matte white panel 15 is diffuse, sunlight will reflect on the solar panels or thermal elements 5 from almost all directions. However, a disadvantage is that a lot of sunlight is lost because the sunlight is reflected in all directions, including unfavorable directions, from the matte white panel.

If a glossy high-reflecting mirror 1 is chosen, a large part of the sunlight will reflect from the decorative panels to the solar panels or solar thermal elements, but only at those times that the corners are attractive.

If panels with less defined degree of gloss are chosen, the result will be less predictable but will lie between the glossy and matte results.

If panels with a lower degree of reflection are chosen, such as panels with a dark color or print, then the reflection towards the solar panels or solar thermal elements will be lower.

By providing the decorative panels with a texture 3 or effect pigments with a wing 8 that matches the desired angles for an optimum yield of solar energy, it will then be possible to optimize it.

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Claims (11)

1 Mounting system in which solar panels or solar thermal elements (5) and decorative panels (4) are mounted in a zigzag configuration in a façade construction wherein after mounting the solar panels or solar thermal elements (5) 5 in an inclined orientation in the direction of are mounted in the sun and wherein one or more decorative panels (4) are mounted in an orientation inclined away from the sun, characterized in that sunlight received by the decorative panels (4) is at least partially directed to the solar panels or the solar thermal elements (5) is reflected and the decorative panels are matt (2), glossy (1), or textured (3) and the decorative panels (4) are made of glass, aluminum-plastic laminates, fiber cement, HPL-compact, fiber - reinforced concrete, ceramic materials or wood exist. 2 Mounting system as in 1, wherein the decorative panels contain a surface texturing (3), characterized in that these panels reflect the sunlight that falls in at an angle of failure that deviates from the angle of incidence. Mounting system as in 1, characterized in that the decorative panels contain pigments (8) which ensure that the incident light is reflected at an angle that deviates from the angle of incidence. 4 Decorative panels as in 4, characterized in that the length or width dimension of the reflective pigments (8) is at least three times larger than the thickness dimension of these pigments. Mounting system as in 3, characterized in that the texturing of the decorative panels (9) is embedded in a transparent matrix. 6 Mounting system as in 3, wherein the decorative panel has a transparent top layer or mainly consists of transparent materials, characterized in that this transparent layer is provided on the back with a texture and a reflective layer (10). 7 Mounting system as in 1 where this system is mounted in combination with other parts and materials, characterized in that the total of 30 assembled parts fulfills different façade functions such as aesthetics, rain resistance, impact resistance and thermal insulation. 1039535 9 Mounting system as in 1, characterized in that the solar thermal elements (5) contain vaccuum elements. Mounting system as in 1, characterized in that the decorative panels between the solar panels or the solar thermal elements consist of several panels (11) that are mounted in different angles. 11 Mounting system as in 1, characterized in that the decorative panels are curved (12). 22 Mounting system as in 1, characterized in that the decorative panels at least partly consist of windows. 10 1039535