• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A solar module construction (10) comprises at least one pyramidal support unit with a triangular base (2) and triangular side surfaces (3) and at least on one of the side surfaces (3) of the support unit provided photovoltaic units. The carrier unit is designed as a carrier frame (1), which forms the triangular base (2) by means of base struts (2 ') and the side surfaces by means of side struts (3'). At least one of the side surfaces (3) is covered with a flexible material. On at least one side surface (3) photovoltaic units in the form of flexible solar modules are mounted on the membrane. A plurality of such solar module constructions together form a solar module field, preferably with solar module pairs, which are formed from two solar module constructions and together form a parallelogram.
    公开号:CH710397A1
    申请号:CH01791/14
    申请日:2014-11-20
    公开日:2016-05-31
    发明作者:Ott Christoph
    申请人:S E Track Ag;
    IPC主号:
    专利说明:

    The present invention relates to a solar module construction and a solar module array for photovoltaic areas, e.g. on building structures, on or over rail infrastructures, buildings, open spaces in nature, etc. In particular, the invention relates to a three-dimensional, modular solar module construction.
    For the conversion of solar energy into electrical energy increasingly free areas are equipped with solar modules. For example, solar panels are mounted on roof structures, wall surfaces and even on previously used agricultural land and aligned with the sun so that during the day as much solar energy can be detected and implemented. For this purpose, various constructions are known, with which an optimal angle adjustment of the solar panels and a nationwide arrangement of a variety of solar panels can be performed. To further optimize the detection of solar energy, e.g. rotatable structures known which align the solar panels continuously according to the position of the sun. It is also known to use constructions which align adjacent panels in different directions, so that during the day different panels are optimally oriented to the sun, without having to move the panels.
    Such constructions are often complex in construction and expensive to maintain. However, the solar panels are often not completely aligned at an optimal angle. Furthermore, there is the problem that the individual panels shadow each other and reduce the yield of electrical energy. From spaced solar panels or rows of solar panels need a lot of space and leave a gap unused.
    In WO 2012/172 296, for example, a construction is shown in which a support structure for solar units is formed hemispherical. On the hemispherical support a plurality of solar units is placed, which have a four-sided pyramidal shape. The four-sided solar pyramids are arranged in rows and span the entire carrier. To cover larger areas several such hemispherical carrier can be arranged side by side. In this construction, too, there is the problem that, in relation to the area covered by solar units, a large part of the photovoltaically active areas of the solar units is not profitably aligned. Furthermore, the assembly and maintenance of such a support structure is complicated. Also, the dimensions of a provided with this construction, photovoltaic used area can be adapted only very limited to the shape of an available area.
    It is therefore an object of the present invention to provide a structure for solar modules, which allows a high efficiency of the solar modules, is simple in construction and installation and allows efficient use of space. Furthermore, it is an object of the present invention to provide a field of solar modules that can be easily adapted to existing conditions, can be provided on surfaces already used elsewhere, saves space and allows easy maintenance.
    This object is achieved by the invention by a solar module construction according to claim 1 and a solar module array with such solar module structures according to claim 10. Advantageous embodiments and further embodiments are described in the dependent claims.
    A solar module construction according to the present invention comprises at least one pyramidal support unit and photovoltaic units provided on the support unit. The carrier unit has a triangular base and triangular side surfaces. The carrier unit is designed as a carrier frame which spans the triangular base by means of base struts and the side surfaces by means of side struts. The space between the base and side struts is open. Advantageously, the base is designed as an isosceles triangle and preferably as an equilateral triangle. The side surfaces are advantageously provided as isosceles triangles. But they can also have a different triangular geometry, as long as the support frame as a whole forms a pyramid shape. The support frame can thus form a straight or a crooked pyramid. The catheters of the three side surfaces meet at a point which forms the top of the pyramid and thus a head region of the support unit and the solar module construction.
    At least one of the side surfaces is covered with a flexible material. Preferably, all three side surfaces are covered with a flexible material. The gap between the base and side struts is thus covered by the flexible material. The material may be secured to the base by retaining means so that it is fixed relative to the support unit.
    As a flexible material is preferably a flexible membrane, such as a film provided. The membrane may e.g. be pulled over the head portion of the carrier unit along the side surfaces to the base struts and fastened. A membrane as a flexible material has the advantage that it has a low weight and is easily moldable. Also, a stretchable membrane can be used because it can be easily adapted to a shape of the side surfaces.
    But the flexible material can also be given by a thin plate which is so thin that it is flexible and thus flexible. Such a plate is not suitable as a sole carrier because of the flexibility, but requires the carrier unit in order to form a stable base for the photovoltaic units. The advantage of such a plate is its low weight, easy processing and easy mounting on the carrier unit.
    The photovoltaic units are provided at least on one of the side surfaces of the carrier unit. For a good energy yield per area, which is covered with a solar module construction, all side surfaces are advantageously provided with photovoltaic units. The photovoltaic units are mounted in the form of flexible solar modules on the flexible material. As flexible solar modules, e.g. Thin-film solar cells used, which are applied to a flexible film. According to the invention, the flexible material, preferably a membrane, is first attached to the support frame and subsequently the photovoltaic units are applied to the membrane. The membrane can thus be precisely positioned over the side surfaces, bent, if necessary, also stretched and braced without the solar modules are damaged. The solar modules are positioned on the already fixed flexible material relative to the geometry of the support frame and thus can be optimally arranged in a simple manner.
    The flexible membrane may consist of a membrane element which spans the three side surfaces of the pyramidal support frame over the entire surface. Thus, all three side surfaces can be covered simultaneously and it is not required several individual steps for covering individual side surfaces. Preferably, the membrane material is stretchable, so that the membrane element can be deformed when mounting on the support frame and adapted to the geometry of the support frame. In particular, the membrane can be bulged through the head region of the support frame, so that the membrane taut over the side surfaces. As an alternative to a full surface overvoltage of all three side surfaces, the side surfaces of the solar module construction with a membrane element, the side surfaces can be spanned individually.
    The solar module designs can thus be easily and quickly produced in stock. In this case, the solar module structures can be stacked so that they occupy little space during storage and during transportation despite the three-dimensional construction.
    A plurality of such juxtaposed solar module constructions may form a solar module array according to the present invention. The solar module constructions can be installed individually or mounted on common supports. The three-sided pyramidal shape ensures that one side surface is always exposed to sunlight during the day and contributes to the generation of energy. For energy production, it is advantageous to use solar module construction equipped with photovoltaic units on all three sides. However, the solar panel can also have other applications, as shown below, in which it may be advantageous to provide only one or two of the side surface with solar modules.
    In a preferred embodiment of a solar module array according to the invention, the field is composed of a plurality of solar module pairs, wherein a solar module pair is formed by two juxtaposed solar module structures, in which the bases of the solar module constructions abut each other and together form a parallelogram. It follows that the six side surfaces of the solar module pair are aligned in six different directions. The six different directions of the side surfaces can optimize the orientation of the solar modules of the solar module pairs relative to the sun and the energy production can be increased. Furthermore, the solar module pairs can be aligned flush in each case in the same orientation, thereby resulting in a straight line, whereby the structure of the solar module array and its installation and maintenance is simplified.
    In an advantageous geometry of an inventive solar module construction, the base of the pyramidal support frame forms an equilateral triangle and the side surfaces close at a head portion of the support frame an angle between 50 ° and 70 °, preferably of 60 °. The head area is thus only slightly raised from the base surface of the support frame. The side surfaces thus form only a small wind attack surface and have a preferred angle setting for solar radiation.
    The flexible material can be selected specifically for desired properties. For example, the material may be transparent, reflective, structured, sound-absorbing or colored. For large-area solar panel fields, the field can thus take on an additional function, such as shading, sound insulation, roofing, etc.
    In the case of individually covered side surfaces of the solar module construction, the side surfaces may each be covered with different materials. Thus, the side surfaces of the solar module construction may have different properties. The selection of material properties can be selected according to the orientation of the solar module design at a job site. For example, dark membranes may be selected for south facing side surfaces and sound absorbing membranes for side surfaces oriented toward busy roads.
    For a high energy yield per area, which is covered with a solar module construction, the side surfaces are completely occupied as possible with photovoltaic units. However, it is also possible to provide solar module constructions in which a side surface provided with solar modules has an area with flexible solar modules and a free area without solar modules, the free area being at least 10% of the side area, preferably between 20% and 35%. The free area allows e.g. a light passage to the solar module construction covered area, or covered with a solar panel field surface to provide sufficient light entry. This can e.g. be advantageous in the use of solar panels according to the invention, which are provided on or on greenhouses or form a roof of a greenhouse.
    In a further advantageous embodiment of a solar module construction according to the invention, the membrane or the plate may be perforated. At solar module-free areas of the side surfaces, this can result in an exchange between the inside and outside of the solar module construction. For example, an exchange of moisture to the outside and of fresh air to the inside. Also, e.g. Rainwater at least partially pass through the solar module construction.
    Further, the membrane or the plate may have a reinforcement, whereby the stability of the side surfaces is increased. The reinforcement may already be provided on the flexible material prior to being mounted on the support frame, or it may be mounted thereafter. Preferably, a net reinforcement is used, which allows stabilization in two different dimensions.
    The support frame of the solar module construction is preferably modular in construction, the base struts, the side struts and corner connectors being present as unitary modules for assembling the support frame. The corner connectors serve to connect the base struts and the side struts and to fix the flexible material, in particular the membrane, over the side struts at the base. Preferably, also the base struts holding means for holding the material, such as clamping rails or adhesive surfaces. Preferably, a head connector is also provided for connecting the side struts to the head region of the support frame, which is mounted on the side struts at least partially above the membrane in the head region of the solar module construction. As a result, the side struts are held in position and at the same time the membrane is fixed.
    For an advantageous embodiment of a solar module array according to the present invention a plurality of parallel support beams are provided for supporting the solar module structures. In each case, two parallel support beams carry a plurality of solar module constructions, in particular pairs of solar modules, as described above. The solar module construction, or solar module pairs are preferably provided adjacent to each other in series on the support beam. Several such rows are arranged adjacent to each other in parallel, so that the solar module array can form a closed surface. The support beams may also have a mounting rail so that e.g. a cart on the parallel rails of two parallel support beams can drive over the solar module structures. This allows a simple assembly of the support beams with solar module designs and easy maintenance of the solar module structures of a solar module array. The support beams can be adjusted in height to the application of the solar module array. Furthermore, by means of the support beams, the inclination of a solar module field relative to the covered surface, or relative to the solar radiation can be adjusted.
    The invention has been illustrated with reference to several embodiments. The individual technical features of an example may well be used in combination with another example with the advantages set forth. The description of the inventive technical features is therefore not necessarily limited to the respective embodiments.
    Advantageous embodiments of the invention are illustrated below with reference to the drawings, which are merely illustrative and not restrictive interpreted. Features of the invention which will become apparent from the drawings are to be considered individually and in any combination as belonging to the disclosure of the invention. In the drawings show:<Tb> FIG. 1a <SEP> is a top view of a support frame of a solar module construction according to a variant of the present invention,<Tb> FIG. 1b shows a side view of the carrier frame from FIG. 1a without membrane, FIG.<Tb> FIG. 2 <SEP> a side view on another side of the support frame of FIG. 1a with membrane,<Tb> FIG. 3 <SEP> is a schematic representation of a side surface of a solar module construction according to the present invention with solar modules,<Tb> FIG. 4 <SEP> is a top view of a variant of a solar module construction on parallel support beams according to the present invention,<Tb> FIG. 5 <SEP> is a schematic representation of a variant of a solar module pair according to the present invention,<Tb> FIG. 6 is a schematic representation of a variant of a solar module array with solar module pairs according to FIG. 5 according to the present invention, FIG.<Tb> FIG. 7 <SEP> a side view of the solar module array with solar module pairs according to FIG. 6,<Tb> FIG. 8 <SEP> is a schematic representation of a further variant of a solar module array according to the present invention,<Tb> FIG. 8a <SEP> a schematic representation of the orientation of side surfaces of a first solar module construction of a solar module pair of the solar module array from FIG. 8,<Tb> FIG. 8b <SEP> a schematic representation of the orientation of side surfaces of a second solar module construction of a solar module pair of the solar module array from FIG. 8,<Tb> FIG. 9 is a schematic illustration of a first application of a solar module array according to the present invention over railway tracks and<Tb> FIG. Fig. 10 is a schematic illustration of a second application of a solar panel array according to the present invention to a greenhouse.
    Although the invention is explained in more detail below with examples of a flexible membrane as a flexible material. It is emphasized, however, that even a flexible plate can be used as a flexible material, as stated previously.
    1a and 1b, a support unit of a solar module construction according to the present invention is shown, which is designed as a support frame 1. The support frame 1 comprises base struts 2, which span a triangular base 2. In the embodiment shown, the base is formed as an isosceles triangle and the three base struts 2 are thus the same length. From a base strut 2 and two side struts 3 side surfaces 3 are spanned. The side struts 3 are the same length in the embodiment shown, so that the side surfaces are formed as an equilateral triangle. The base struts 2 and the side struts 3 are joined together at the corners by corner connectors 4 and the three side struts 3 are joined by a head connector 5 in a head region 15 of the support frame 1. The support frame 1 forms a three-dimensional pyramidal support unit with three equal side surface. 3
    In principle, the pyramid geometry but also have side surfaces of different sizes and the base or side struts need not have the same length. A base in the form of an at least equilateral triangle is preferred so that when assembling two solar module structures to a pair of solar modules results in a parallelogram, as will be explained in more detail later.
    In Fig. 1b, the support frame 1 is shown from the side. It can be seen that the side struts 3 stand out from the area spanned by the base 2. In the embodiment shown, the side struts 3 are at an angle α of 26 ° from the surface of the base 2 from. However, other angles and different angles for the different side struts can also be selected, depending on the field of application and the orientation of the base area on which the solar module constructions are used.
    In Fig. 2, the support frame 1 is covered with a flexible membrane 6. The membrane 6 is formed in this embodiment as a membrane element that is stretched over the three side surfaces 3 of the pyramidal support frame 1 and is fixed by means of the corner connector 4 on the support frame 1. In addition, the membrane can be pulled over the outsides of the base struts and secured along the base struts. Further, the membrane can be fastened by the head connector to the side struts 3. For this purpose, a first head connector element from above and a second head connector element can be applied from below. First and second header connectors are connected together, e.g. screwed, pinching the membrane between them and fix the side struts 3. On the first header connector element, a hook or eyelet may protrude upwardly, which may serve to grasp and transport the solar module construction.
    In Fig. 3, a side surface 3 of the solar module construction is shown, are mounted on the photovoltaic units in the form of flexible solar modules 7 on the membrane 6. The solar modules 7 are e.g. formed by photovoltaically active Wavern. There are e.g. 60 solar modules 7 arranged in rows next to and parallel to each other and wired in a conventional manner with each other with a wiring 8, so that solar energy can be captured and converted into electrical energy and dissipated. As can be seen in Fig. 3, the side surface 3 has an area covered with solar modules 7, and also a free area 9 without solar modules, which areas need not be contiguous. The free area 9 in the illustrated example corresponds to approximately 20% of the side surface 3. The wafers may be a front foil, e.g. ETFE foil, and a back foil, e.g. as a modified polyamide film, on wise, which together form the film base for the solar modules 7. The wavers, e.g. Silicon wafer, are laminated between the front and the back foil including a wiring for a wiring 8. The solar modules 7 can be combined to form a photovoltaic surface module by means of the film base and applied together by attachment to the membrane. Depending on the material used, different bonding techniques may be used, e.g. Gluing, sewing, laminating, vulcanizing or riveting.
    In Fig. 4, a solar module construction 10 according to the present invention is shown, which is formed as previously described. The solar modules 7 have been omitted in favor of a better overview in the illustration. The solar module construction 10 is mounted on two parallel support beams 11, 11 and attached to the corners of the base 2 on this. In this case, one of the base struts 2 extends parallel to a support beam 11 and the two other base struts 2 protrude from the support beam 11 to the support beam eleventh The corners of the parallel base strut 2 thus lie on the support beam 11. The corner of the base, which is opposite to the parallel base strut 2, thus lies on the other support beam 11. Due to the symmetrical geometry of the solar module construction 10, a further solar module construction 10 (see FIG. 5) can be rotated by 180 ° next to the illustrated solar module construction 10 such that the base struts of the two solar module structures can come to lie parallel to each other. In principle, it is also conceivable that a base strut for both solar module constructions 10 and 10 is used together and the common base strut belongs to the two adjacent bases. Two solar module constructions arranged in such a way form a solar module pair, as will be explained in more detail below. The solar module pair is formed by a kind of double pyramid.
    FIG. 5 shows such a solar module pair 12 with a first solar module construction 10 and a second solar module construction 10 rotated by 180 ° thereto. The solar module pair 12 spans a parallelogram with the side lengths of the base struts 2. The distance between the opposing base struts 2 corresponds advantageously to the distance of the parallel support beams 11 and 11, as shown in Fig. 4. Again, the solar modules 7 were not shown for a better overview. The solar module pair 12 has six side surfaces 3, which are each oriented in different directions. The solar module construction 10 includes the side surfaces 3a, 3b and 3c. The solar module construction 10 includes the side surfaces 3d, 3e and 3f.
    In Fig. 6, a solar module array 13 according to the present invention is shown schematically, which is constructed of pairs of solar modules according to FIG. For this purpose, the solar module constructions 10 are mounted individually or as solar module pairs 12 in series on the support beams 11, 11. Three parallel rows of solar module pairs are shown. Each row is shown as having two pairs of solar panels 12, although more than two panels of solar panels are typically used in solar panel panels that are in actual use, such as those shown in FIG. can be seen from Fig. 8. The solar module pairs 12 of a row abut each other with their bases in such a way that results in a strip of solar module constructions having a common rectilinear axis. The edge of the arrayed solar module pairs forms on both sides of a continuous straight edge, which rests on the support beams. The individual rows can be arranged as desired in relation to each other. An optically pleasing impression arises, for example, if the solar module pairs 12 are arranged with the same orientation in adjacent rows at the same height.
    In Fig. 7, the solar module array 13 is shown in a side view of a number of solar module pairs 12 with a section through a support beam 11. It can be seen from the view that the head region 15 of the solar module construction 10 and the head region 15 of the solar module construction 10 are offset from each other. The solar module construction 10 and 10 solar module pairs 12 lying one behind another are aligned in FIG. 7, so that only one pair of solar modules 12 can be seen in each case.
    In Fig. 8 an example of a solar module array 13 is shown, e.g. Can serve as a roofing of railway tracks. There are shown five parallel rows of solar module pairs 12 mounted on support beams 11, 11. The solar module pairs 12 of a row are as shown in Fig. 6, then strung together. FIG. 8 also shows the solar modules 7, which are arranged on the side surfaces 3 of the solar module constructions 10 and 10 of the solar module pairs 12. A solar module pair 12 includes the six side surfaces 3a, 3b, 3c, 3d, 3e and 3f of the solar module constructions 10 and 10, as can also be seen in FIG. In the example shown, the side surface 3a is oriented to the west, the side surface 3b to the north-east, the side surface 3c to the south-east, the side surface 3d to the south-west, the side surface 3e to north-west and the side surface 3f to the east. Toward the south, therefore, the side surfaces 3c and 3d are provided and in the north, the side surfaces 3b and 3e. This results in a good orientation of the side surfaces for the generation of energy for all directions.
    FIG. 9 shows a first application of a solar module array with solar module constructions according to the present invention as a roofing of railway tracks 20 and associated overhead lines 21. The support beams 11 are supported by piles 16 and placed over the overhead lines. Along the support beams 11 there is shown by way of example a series of solar module constructions 10 belonging to solar module pairs as previously described. Several rows of solar module pairs are provided, which together form a solar module array 13, e.g. in Fig. 8 is shown. The solar module constructions 10 in this application are e.g. covered with a membrane which is impermeable to water and slightly opaque. The solar module constructions 10 can be mounted on the support beam 11 by means of a seal such that no water can penetrate between the support beam and the solar module construction. The solar module array 13 thus protects the area covered by it against precipitation.
    In Fig. 10, a second application of a solar module array 13 is shown with solar module pairs 12 according to the invention that serves as a superstructure of a plant 30. The solar module pairs 12 are in turn mounted on support beams 11, which in turn are mounted on piles 16. In this application it is advantageous to use a perforated and transparent membrane so that e.g. Rainwater for irrigation 31 can pass through the membrane. On the side surfaces, larger solar module-free areas are preferably provided, for example, 25% to 35% of the side surface, to allow a tanning of the plant 30. Also, the rainwater may be collected in a catch basin 32 and supplied from the plant 30. To operate such irrigation, e.g. the electrical energy obtained with the solar module array 13 are used, so that there is an energy-neutral planting plant. In principle, the catch basin 32 can also be filled with groundwater.
    reference numeral
    [0039]<Tb> 1 <September> support frame<Tb> 2 <September> Base<tb> 2 <SEP> Basic Struts<Tb> 3 <September> face<tb> 3 <SEP> Side struts<Tb> 4 <September> corner connector<Tb> 5 <September> header connector<Tb> 6 <September> Membrane<Tb> 7 <September> Solar module<Tb> 8 <September> Cabling<tb> 9 <SEP> free area<tb> 10, 10 <SEP> Solar module construction<tb> 11, 11 <SEP> Beams<Tb> 12 <September> Solar module pair<Tb> 13 <September> solar panel field<Tb> 15 <September> head area<Tb> 16 <September> stake<Tb> 20 <September> Railway Track<Tb> 21 <September> catenary<Tb> 30 <September> planting<Tb> 31 <September> Irrigation<Tb> 32 <September> sump<tb> α <SEP> Angle Base Side Brace
    权利要求:
    Claims (13)
    [1]
    1. Solar module construction comprising at least one pyramidal support unit with a triangular base (2) and triangular side surfaces (3) and at least on one of the side surfaces (3) of the support unit provided photovoltaic units, characterized in that- The support unit is designed as a support frame (1) which by means of base struts (2), the triangular base (2) and by means of side struts (3) spans the side surfaces,- At least one of the side surfaces (3) is covered with a flexible material and- At least one side surface (3) photovoltaic units in the form of flexible solar modules (7) on the membrane (6) are mounted.
    [2]
    2. Solar module construction according to claim 1, characterized in that the flexible material consists of a flexible membrane (6) or a flexible plate.
    [3]
    3. Solar module construction according to claim 1, characterized in that the flexible membrane (6) consists of a membrane element which spans the three side surfaces (3) of the pyramidal support frame (1) over its entire surface.
    [4]
    4. solar module construction according to claim 1, characterized in that at least two of the side surfaces (3) are covered with different flexible material, wherein the different flexible materials each have one of the following properties: transparent, reflective, structured, sound-absorbing, colored.
    [5]
    5. Solar module construction according to one of claims 1 to 3, characterized in that the solar modules (7) provided side surface (3) has an area with flexible solar modules (7) and a free area (9) without solar modules, wherein the free area ( 9) is at least 10% of the side surface, preferably between 20% and 35%.
    [6]
    6. Solar module construction according to one of the preceding claims, characterized in that the flexible material is perforated.
    [7]
    7. Solar module construction according to one of the preceding claims, characterized in that the flexible material has a reinforcement, in particular a net reinforcement.
    [8]
    8. Solar module construction according to one of the preceding claims, characterized in that the base (2) of the support frame (1) forms an equilateral triangle and the side surfaces (3) at a head portion (15) of the pyramidal support frame (1) an angle of 60 ° lock in.
    [9]
    9. Solar module construction according to one of the preceding claims, characterized in that the support frame (1) is modularly constructed from the base struts (2), the side struts (3) and corner connectors (4) for connecting the base struts (2). and the side struts (2) and for fixing the flexible material over the side struts (21) are provided on the base (2).
    [10]
    10. solar module construction according to claim 9, characterized in that the modular support frame (1) has a head connector (5) for connecting the side struts (3) in a head region (15) of the solar module construction at least partially over the membrane (6) the side struts (3) is mounted.
    [11]
    11. solar module array, which is constructed from a plurality of juxtaposed solar module structures (10) according to one of claims 1 to 10.
    [12]
    12. solar module array according to claim 11, characterized in that two juxtaposed solar module constructions (10; 10) form a pair of solar modules (12) in which the bases (2) of the solar module structures (10; 10) adjacent to each other and together a parallelogram form.
    [13]
    13. Solar module array according to claim 11 or 12, characterized in that a plurality of parallel support beams (11; 11) for supporting the solar module constructions (10) are provided, wherein each two parallel support beams (11; 11) a plurality of solar module pairs (12) to each other adjacent to each other in series and several such rows are arranged side by side, so that the solar module array (13) forms a closed surface.
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    同族专利:
    公开号 | 公开日
    ES2715723T3|2019-06-05|
    US20160149537A1|2016-05-26|
    EP3026366A2|2016-06-01|
    EP3026366A3|2016-08-10|
    HRP20190441T1|2019-05-17|
    US10892371B2|2021-01-12|
    EP3026366B1|2018-12-19|
    SI3026366T1|2019-05-31|
    CH710397B1|2018-10-31|
    引用文献:
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    法律状态:
    2020-06-30| PL| Patent ceased|
    优先权:
    申请号 | 申请日 | 专利标题
    CH01791/14A|CH710397B1|2014-11-20|2014-11-20|Solar module construction.|CH01791/14A| CH710397B1|2014-11-20|2014-11-20|Solar module construction.|
    SI201530619T| SI3026366T1|2014-11-20|2015-11-19|Solar module arrangement|
    ES15195275T| ES2715723T3|2014-11-20|2015-11-19|Construction of solar modules|
    EP15195275.1A| EP3026366B1|2014-11-20|2015-11-19|Solar module arrangement|
    US14/947,857| US10892371B2|2014-11-20|2015-11-20|Solar module construction|
    HRP20190441TT| HRP20190441T1|2014-11-20|2019-03-05|Solar module arrangement|
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