• 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:
    Method and installation for framing a solar panel with a plurality of sides, where a frame is attached to the solar panel. The frame comprises a frame segment for each side of the solar panel, each of said frame segments being attached to the corresponding side. To frame a solar panel, in a framing cycle the method comprises a panel feeding step in which the solar panel to be framed is fed to a connection station (101) of an installation (1000) configured to frame solar panels, a frame feeding stage in which the frame segments for said solar panel are fed to the junction station (101), and a framing stage in which said frame segments are attached to said solar panel. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2754874A1
    申请号:ES201930855
    申请日:2019-10-03
    公开日:2020-04-20
    发明作者:Echevarria Gorka Garcia;Ocaranza Alaitz Errasti;Ugarte Aitzol Velasco;Rebollo Jose Maria Aragones
    申请人:Mondragon Assembly S Coop;
    IPC主号:
    专利说明:

    [0001]
    [0002] Method and installation to frame a solar panel
    [0003]
    [0004] TECHNICAL SECTOR
    [0005]
    [0006] The present invention relates to methods and installations for framing solar panels.
    [0007]
    [0008] PREVIOUS STATE OF THE TECHNIQUE
    [0009]
    [0010] Today, renewable energy is gaining weight against fossil energy, and one of the increasing renewable energies is solar energy. Solar energy is based on transforming solar radiation into other forms of energy, such as electrical energy. For this, solar panels are used that are exposed to solar radiation and transform said radiation into electrical energy.
    [0011]
    [0012] US9935222B1 discloses a rectangular solar panel. To manufacture the solar panel, a plurality of rows of cells are generated, each row comprising a plurality of cells connected together in series. Subsequently, a plurality of rows are arranged next to each other and are joined together, forming a solar panel. To protect the solar panel, in a framing process the solar panel is framed with four frame segments, with a respective frame segment adhering or joining to each side of the solar panel. To adhere the frame segments, for example, silicone can be used.
    [0013]
    [0014] CN106493544A discloses an installation and method for framing a solar panel comprising a plurality of sides, in which a frame is attached or adhered to the solar panel. The frames to be attached to a plurality of solar panels are stored in the installation before the framing begins, and once said storage has been carried out, each frame is moved to a specific position to adhere to the corresponding solar panel. The frames are stored one on top of the other, and move actuated by cylinders on the that are supported. Once all the frames are used, the installation stops to reload a plurality of frames on the cylinders, to frame new solar panels.
    [0015]
    [0016] STATEMENT OF THE INVENTION
    [0017]
    [0018] The object of the invention is to provide a method and installation for framing solar panels, as defined in the claims.
    [0019]
    [0020] A first aspect of the invention relates to a method of framing solar panels, in which a frame is attached or adhered to the solar panel. The frame comprises as many frame segments as there are sides of the solar panel to be framed, comprising a frame segment for each of said sides, and in the method each of said frame segments is attached or adhered to a respective side of the solar panel .
    [0021]
    [0022] To frame a solar panel, in a framing cycle, the method comprises:
    [0023] - a panel feeding stage in which the solar panel to be framed is fed to a joining station,
    [0024] - a charging stage in which the corresponding frame segments for said solar panel are loaded into a charging tool configured to support said frame segments and arranged in a charging station,
    [0025] - a frame feeding stage in which the displacement of the loading tool with said frame segments is caused in a determined displacement direction that, preferably, is linear, from the loading station where the loading stage is implemented to the joining station, and
    [0026] - a framing step that is executed in the connection station, in which, with a solar panel and the corresponding frame segments arranged in the connection station, said frame segments are attached or adhered to said solar panel.
    [0027]
    [0028] With the proposed method, thanks to the possibility of moving the loading tool with respect to the joining station, once the loading tool is inserted into the joining station with some frame segments and before the framing of the a solar panel with these charging segments, the charging tool can be removed from the joining station to prepare the frame segments for the next solar panel to be framed. In addition, the fact of being able to move the loading tool to arrange it inside or outside the joining station, where the framing step is carried out, allows, for example, when the loading tool is in the joining station, the space that it occupies when it is extracted can be used for other tasks, or simply to facilitate tasks for operators.
    [0029]
    [0030] A second aspect of the invention relates to a solar panel framing installation, which is configured to adhere or bond a frame to a solar panel. Each solar panel comprises a plurality of sides, and the corresponding frame comprises a frame segment for each side of the solar panel to be framed.
    [0031]
    [0032] The installation includes:
    [0033] - a joining station where the frame segments are attached or joined to the corresponding solar panel,
    [0034] - a loading tool configured to support said frame segments and movable between a loading station and the joining station, in a determined direction of travel that is preferably linear, and
    [0035] - at least one actuation device arranged in the connection station and configured to move the frame segments towards the corresponding side of the solar panel to be framed arranged in the connection station.
    [0036]
    [0037] The advantages mentioned for the first aspect of the invention are thus also obtained with the installation of the invention.
    [0038]
    [0039] These and other advantages and characteristics of the invention will become apparent in view of the figures and the detailed description of the invention.
    [0040]
    [0041] DESCRIPTION OF THE DRAWINGS
    [0042]
    [0043] Figure 1 shows a rectangular solar panel with a frame, framed according to an embodiment of the method of the invention.
    [0044] Figure 2 shows an exploded view of the solar panel of figure 1.
    [0045]
    [0046] Figure 3 shows an embodiment of a solar panel framing installation according to the invention, configured to frame rectangular solar panels and with a charging tool arranged in the charging station of said installation.
    [0047]
    [0048] Figure 4 shows the embodiment of Figure 3, with the loading tool loaded with frame segments.
    [0049]
    [0050] Figure 5 shows a joining station of the installation of figure 3, without the release device.
    [0051]
    [0052] Figure 6 shows the joining station of figure 5, with the frame segments and a solar panel.
    [0053]
    [0054] Figure 7 shows the joining station of figure 5, with the frame segments displaced to the solar panel.
    [0055]
    [0056] Figure 8 shows the loading tool of the installation of figure 3, without a gripping element.
    [0057]
    [0058] Figure 9 shows a module of the joining station of figure 5, with a release device.
    [0059]
    [0060] DETAILED STATEMENT OF THE INVENTION
    [0061]
    [0062] A first aspect of the invention relates to a method for framing a PV solar panel comprising a plurality of sides, with a corresponding frame 1, as shown by way of example in Figure 1. Frame 1 comprises as many frame segments 1.1 as sides has the PV solar panel to be framed, as represented in figure 2, and each of said frame segments 1.1 adheres or joins a respective side of the PV solar panel. The PV solar panel is framed in a 1000 panel framing installation solar, as shown by way of example in Figures 3 and 4.
    [0063]
    [0064] Frame 1 comprises a plurality of frame segments 1.1, depending on the shape of the PV solar panel (number of sides), thus comprising, for example, four frame segments 1.1 if it is a rectangular PV solar panel, and three if it is a triangular PV solar panel. Logically any shape would be possible for a PV solar panel, although preferably it is a four-sided (rectangular) PV solar panel as shown by way of example in the embodiment of the figures.
    [0065]
    [0066] Each of the frame segments 1.1 is attached or adhered to a respective side of the PV solar panel in any of the method embodiments. The different frame segments 1.1 can furthermore be joined together by corner joint blocks (additional elements to the frame segments 1.1), by the shape of the frame segments 1.1 themselves, or in any other known way.
    [0067]
    [0068] To frame a PV solar panel, the method implements a framing cycle. A framing cycle of the method, in any of its embodiments, comprises at least the following steps:
    [0069] - a panel feeding stage in which the PV solar panel to be framed is fed to a connection station 101 of installation 1000, as shown by way of example in Figures 5 to 7,
    [0070] - a charging step that runs outside the joining station 101 (in a charging station 102 of the installation 1000, preferably arranged on one side with respect to the joining station 101), in which the segments of the loading are loaded corresponding frame 1.1 for said solar PV panel in a charging tool 2 configured to support said frame segments 1.1 and arranged in the charging station 102, as shown by way of example in figure 8,
    [0071] - a frame feeding stage in which the corresponding frame segments 1.1 for framing said solar PV panel are fed to the junction station 101, for this purpose the displacement of the load tool 2 with said frame segments 1.1 being caused in a displacement direction X determined that is preferably linear and horizontal, from the loading station 102 where the loading step is implemented to the joining station 101, and
    [0072] - a framing step that is executed in the connection station 101, in which, with a PV solar panel and the corresponding frame segments 1.1 arranged in said connection station 101, said frame segments 1.1 are attached or adhered to said PV solar panel.
    [0073]
    [0074] The order in which the stages of a framing cycle have been exposed does not have to coincide with the order of execution of these stages, since, for example, the panel feeding stage does not have to be prior to the stages charging and frame feeding, for example. However, the frame feeding stage has to be after the loading stage and the framing stage has to be after the panel feeding stage and the frame feeding stage.
    [0075]
    [0076] In a preferred embodiment, the method further comprises a release step which is subsequent to the frame feeding step and prior to the framing step, and which is executed at the bonding station 101 (with charging tool 2 in said connection station 101), in which the frame segments 1.1 of the loading tool 2 are released. In this way, after the release step it is already possible to move the loading tool 2 from the connection station 101 to the transfer station Charge 102 after the release step has been carried out, to load new frame segments 1.1 on charging tool 2, regardless of whether or not a PV solar panel to be framed has been supplied, for example, since once the frame segments have been released 1.1 of load tool 2, said load tool 2 no longer participates in the same framing cycle. This aspect enables the framing cycle to be accelerated compared to the method without the release step, by not having to wait, for example, for a ready-made PV solar panel at the junction station 102 to be framed. Furthermore, there is no need to interrupt the framing cycle since new frame segments 1.1 can be loaded on charging tool 2 at charging station 102, while a PV solar panel is being framed with the previously released frame segments 1.1.
    [0077]
    [0078] In the preferred embodiment, to release the frame segments 1.1 from the loading tool 2, a respective action is performed on each of said frame segments 1.1 that separates the frame segment 1.1 from said loading tool 2, subsequently carrying out at least one additional action on each of said frame segments 1.1 to join or adhere them to the solar PV panel (the framing stage). In other embodiments, with a single action releases all the frame segments 1.1 of the load tool 2, and with an additional action on each one of said frame segments 1.1 (or a single action on all the load segments 1.1), the step of framed.
    [0079]
    [0080] Preferably, the loading tool 2 comprises two longitudinal profiles 2.1 and 2.2 facing and separated from each other, preferably extending in the direction of movement X, and configured to support the frame segments 1.1, causing the longitudinal and joint movement of both profiles longitudinal 2.1 and 2.2 in the direction of movement X when said loading tool 2 is caused to move (from the loading station 102 to the joining station 101 and vice versa). Preferably, the loading tool 2 comprises a connecting element 2.3 that joins both longitudinal profiles 2.1 and 2.2 to each other, so that both longitudinal profiles 2.1 and 2.2 can move together. Preferably, said connecting element 2.3 is a rigid bar that extends transversely between both longitudinal profiles 2.1 and 2.2.
    [0081]
    [0082] In the case of rectangular PV solar panels being framed, and as shown in figure 4, two frame segments 1.1 are arranged on the loading tool 2 longitudinally with respect to the longitudinal profiles 2.1 and 2.2, in such a way that each one of said two frame segments 1.1 is supported on, or joined to, a corresponding longitudinal profile 2.1 and 2.2. The other two frame segments 1.1 are arranged on the loading tool 2 transversely with respect to the longitudinal profiles 2.1 and 2.2, in such a way that each of said two frame segments 1.1 is supported on, or joined to, both longitudinal profiles 2.1 and 2.2. Preferably, the two frame segments 1.1 that are arranged longitudinally with respect to longitudinal profiles 2.1 and 2.2 are arranged supported by, or joined to, said longitudinal profiles 2.1 and 2.2 with a separation between them equal to or greater than the length of the solar panel PV to be framed in the direction transverse to the direction of displacement X determined, and the other two frame segments 1.1 are arranged supported by, or joined to, the longitudinal profiles 2.1 and 2.2 with a separation between them equal to or greater than the length of said solar panel PV in the determined X displacement direction.
    [0083]
    [0084] Preferably, the frame segments 1.1 that are arranged longitudinally are arranged outside the space between the two longitudinal profiles 2.1 and 2.2 of the tool of load 2, in such a way that all the space between both longitudinal profiles 2.1 and 2.2 is left free, and the frame segments 1.1 that are arranged transversely, which are arranged in said space (between both longitudinal profiles 2.1 and 2.2). This arrangement allows all the frame segments 1.1 to be easily arranged on the loading tool 2, manually, without an already arranged frame segment 1.1 disturbing the provision of another of the frame segments 1.1.
    [0085]
    [0086] In the preferred embodiment, the loading tool 2 is moved manually. For this purpose, the loading tool 2 may comprise a grip element 2.5 fixed at one end of at least one of the longitudinal profiles 2.1 and 2.2, and a user grasps said grip element 2.5 and exerts a force in the corresponding direction to move said charging tool 2.
    [0087]
    [0088] A second aspect of the invention relates to a PV solar panel framing installation 1000, which is configured to adhere or bond a frame 1 to a PV solar panel. Frame 1 comprises a plurality of frame segments 1.1, depending on the shape of the PV solar panel (number of sides), thus comprising, for example, four frame segments 1.1 if it is a rectangular PV solar panel and three if it is a triangular PV solar panel. Logically any shape would be possible for a PV solar panel, although preferably it is a four-sided (rectangular) PV solar panel as shown by way of example in the embodiment of the figures.
    [0089]
    [0090] In any embodiment of installation 1000, each of the frame segments 1.1 is attached or adhered to a respective side of the PV solar panel. The different frame segments 1.1 can furthermore be joined together by corner joint blocks (additional elements to the frame segments 1.1), by the shape of the frame segments 1.1 themselves, or in any other known way.
    [0091]
    [0092] Installation 1000 includes at least, in any of its embodiments:
    [0093] - a joining station 101 where the frame segments 1.1 are attached or joined to the corresponding PV solar panel,
    [0094] - a charging tool 2 configured to support said frame segments 1.1, and movable between a charging station 102 and the joining station 101, in a determined direction of movement X that is preferably linear, and - at least one actuation device 4 arranged in the connection station 101 and configured to move the frame segments 1.1 towards the corresponding side of the solar panel PV to be framed arranged in the connection station 101.
    [0095]
    [0096] The frame segments 1.1 are loaded or arranged on the loading tool 2, at the loading station 102 of the installation 100, and with said frame segments 1.1 arranged on the said loading tool 2, the loading tool 2 moves to junction station 101 in the X direction of travel.
    [0097]
    [0098] In a preferred embodiment, the junction station 101 will be formed by a plurality of modules 101.0, one for each frame segment 1.1. Each module 101.0 further comprises at least one actuation device 4.
    [0099]
    [0100] In the preferred embodiment, the installation 1000 comprises a release device 5, shown by way of example in Figure 9, which is arranged in the joining station 101. In said preferred embodiment, each module 101.0 of the joining station 101 comprises at least one release device 5, such that each frame segment 1.1 comprises at least one release device 5. In this case, preferably, said actuators can be synchronized to cause simultaneous actuation thereof. Simultaneous actuation can minimize the total time required to release all 1.1 frame segments so that the time required for one framing cycle can be reduced.
    [0101]
    [0102] The release device 5 is configured to cause a movement of said frame segments 1.1 with respect to the loading tool 2 to a corresponding release position, releasing said frame segments 1.1 from said loading tool 2 for their subsequent adhesion or attachment to the PV solar panel. In this way, as described for the method, the charging tool 2 is free to be able to move to the charging station 102 to support new frame segments 1.1, which speeds up the framing of PV solar panels in installation 1000. In particular, the release device 5 can be configured to carry out two types of displacements: a displacement in a horizontal direction X1 and a displacement in a vertical direction Y1. With the horizontal displacement X1 separates the corresponding frame segment 1.1 from the load tool 2, and with the
    [0103]
    [0104]
    [0105] vertical displacement Y1 positions said frame segment 1.1 in the actuation zone of actuation device 4.
    [0106]
    [0107] In the preferred embodiment, the actuation device 4 is configured to move the corresponding frame segment 1.1 from the corresponding release position (figure 6) to the corresponding side of the solar panel PV to be framed arranged in the connection station 101 (figure 7 ). In the embodiments in which there is no release device 5, it would be the actuation device 4 itself that releases the frame segments 1.1 of the loading tool 2.
    [0108]
    [0109] Before the actuation device 4 moves the frame segments 1.1 to the PV solar panel, another actuator (not shown in the figures) can apply a glue, resin or similar adhesive on the sides of the PV solar panels, to ensure a correct adhesion or union of the frame segments 1.1 to said PV solar panel.
    [0110]
    [0111] Actuation device 4 may comprise at least one actuator for each frame segment 1.1, as is the case with the embodiment of the figures (where three actuators are shown per frame segment 1.1), or a single actuator for all segments of framework 1.1. In the first case, the actuators associated with the different frame segments 1.1 can be synchronized to cause simultaneous actuation of the same. Simultaneous actuation can minimize the total time required to bond all 1.1 frame segments to the PV solar panel so that the time required for one framing cycle can be reduced.
    [0112]
    [0113] In the preferred embodiment, the loading tool 2 comprises two longitudinal profiles 2.1 and 2.2 facing each other and transversely separated from each other by a determined separation distance, and which are configured to support the frame segments 1.1 corresponding to the PV solar panel to be framed. Said longitudinal profiles 2.1 and 2.2 are attached to a structure 101.0 of the joining station 101 of the installation 1000 with freedom of movement in the determined direction of movement X.
    [0114]
    [0115] In the preferred embodiment, the installation 1000 comprises a connecting element not shown in the figures, which preferably joins both longitudinal profiles 2.1 and 2.2 each other, and it can be like the one described for the method.
    [0116]
    [0117] Each longitudinal profile 2.1 and 2.2 can comprise at least one support 2.4 to support the frame segments 1.1. Preferably, each longitudinal profile 2.1 and 2.2 comprises two supports 2.4 that are distributed in the direction of movement X and that protrude from the corresponding longitudinal profile 2.1 and 2.2, preferably outside the space delimited between both longitudinal profiles 2.1 and 2.2, said two supports 2.4 being of a longitudinal profile 2.1 and 2.2 thus arranged to support on them a respective frame segment 1.1.
    [0118]
    [0119] Preferably, each longitudinal profile 2.1 and 2.2 comprises two additional supports 2.4 which are distributed in the direction of movement X and which protrude from the corresponding longitudinal profile 2.1 and 2.2, into the space delimited between both longitudinal profiles 2.1 and 2.2, each additional support being 2.4 of a longitudinal profile 2.1 and 2.2 facing another additional support 2.4 of the other longitudinal profile 2.1 and 2.2 and said two additional supports 2.4 forming a pair of additional supports 2.4. Each pair of additional supports 2.4 is thus arranged to support a respective frame segment 1.1.
    [0120]
    [0121] Installation 1000 is adapted to support a method according to the first aspect of the invention, in any of its embodiments and / or configurations, thus comprising one or the other configuration depending on the method that is implemented (or vice versa). Thus, the comments for the method are also valid for installation 1000 and vice versa.
    权利要求:
    Claims (19)
    [1]
    1. Method for framing a solar panel comprising a plurality of sides, in which a frame (1) is attached or adhered to the solar panel (PV), the frame (1) comprising a plurality of frame segments (1.1) and each of said frame segments (1.1) being attached or adhered to a respective side of the solar panel (PV), where, to frame a solar panel (PV), in a framing cycle the method comprises a panel feeding step in which the solar panel (PV) to be framed is fed to a junction station (101), characterized in that , in the framing cycle, the method further comprises a charging step in which the frame segments (1.1) are loaded. ) corresponding for said solar panel (PV) in a charging tool (2) configured to support said frame segments (1.1) and arranged in a charging station (102), a frame feeding stage in which the displacement of the loading tool (2) with said frame segments (1.1) in a displacement direction (X) determined that is preferably linear, from the loading station (102) where the loading stage is implemented to the joining station (101), and a framing stage that is executed in the station of connection (101), in which, with a solar panel (PV) and the corresponding frame segments (1.1) arranged in the connection station (101), said frame segments (1.1) are attached or adhered to said solar panel (PV).
    [2]
    The method according to claim 1, comprising a release step that is performed at the bonding station (101) and that is subsequent to the frame feeding step and prior to the framing step, in which the frame segments (1.1) of the loading tool (2).
    [3]
    3. Method according to claim 2, wherein to release the frame segments (1.1) from the loading tool (2), a respective action is performed on each of said frame segments (1.1) that separates the frame segment ( 1.1) of said charging tool (2), at least one additional action being carried out on each of said frame segments (1.1) to join them or adhere them to the solar panel (PV).
    [4]
    4. Method according to any of claims 1 to 3, wherein the loading tool (2) it comprises two longitudinal profiles (2.1, 2.2) facing and transversely separated from each other, and configured to support the corresponding frame segments (1.1), causing a longitudinal displacement and the assembly of both longitudinal profiles (2.1,2.2) in the direction of movement ( X) when the displacement of said loading tool (2) is caused.
    [5]
    The method according to claim 4, which is adapted to frame rectangular solar panels (PV), two frame segments (1.1) being arranged longitudinally with respect to the longitudinal profiles (2.1, 2.2), such that each of said two frame segments (1.1) are supported on, or attached to, a corresponding longitudinal profile (2.1, 2.2), and two frame segments (1.1) are arranged transversely with respect to the longitudinal profiles (2.1, 2.2), such that each of said two frame segments (1.1) is supported on, or joined to, both longitudinal profiles (2,1,2.2).
    [6]
    The method according to claim 5, wherein the two frame segments (1.1) that are arranged longitudinally with respect to the longitudinal profiles (2.1, 2.2) are arranged supported by, or joined to, said longitudinal profiles (2.1,2.2) with a separation between them equal to or greater than the length of the solar panel (PV) to be framed in the transverse direction to the determined displacement direction (X), and the two frame segments (1.1) that are arranged transversely with respect to the longitudinal profiles (2.1, 2.2) are arranged supported by, or attached to, the longitudinal profiles (2.1, 2.2) with a separation between them equal to or greater than the length of said solar panel (PV) in the direction of travel (X) determined.
    [7]
    Method according to claim 5 or 6, wherein the longitudinally arranged frame segments (1.1) are arranged outside the space between the two longitudinal profiles (2.1, 2.2) of the loading tool (2), one at a time. side of a respective longitudinal profile (2.1,2.2), the frame segments (1.1) being arranged transversely in said space, being arranged between both longitudinal profiles (2.1, 2.2).
    [8]
    8. Method according to any of claims 1 to 7, wherein the loading tool (2) scrolls manually.
    [9]
    9. Method according to any of claims 1 to 8, wherein the direction of movement (X) is horizontal.
    [10]
    10. Solar panel framing installation, configured to adhere or join a frame (1) to a solar panel (PV), each solar panel (PV) comprising a plurality of sides and the corresponding frame (1) comprising a frame segment (1.1) for each side of the solar panel (PV) to be framed, and the installation (1000) comprising a joining station (101) where the frame segments (1.1) are adhered or attached to the corresponding solar panel (PV), and a charging tool (2) configured to support said frame segments (1.1), characterized in that the charging tool (2) is movable between a charging station (102) and the joining station (101), in a direction of displacement (X) determined that is preferably linear, the installation (1000) further comprising at least one actuation device (4) arranged in the joining station (101) and configured to displace the frame segments (1.1) towards the corresponding side of the solar panel (PV) to be framed arranged at the joining station (101).
    [11]
    11. Installation according to claim 10, comprising at least one release device (5) arranged in the joining station (101), the release device (5) being configured to cause a displacement of said frame segments (1.1) with respect to the charging tool (2) to release the frame segments (1.1) of said charging tool (2), to a corresponding release position, for subsequent adhesion or attachment to the solar panel (PV).
    [12]
    12. Installation according to claim 11, wherein the actuation device (4) is configured to move the frame segments (1.1) from the corresponding release position to the corresponding side of the solar panel (PV) to be framed arranged in the station connecting (101).
    [13]
    13. Installation according to any of claims 10 to 12, wherein the loading tool (2) comprises two longitudinal profiles (2.1, 2.2) facing each other and separated
    one
    transversely to each other by a determined separation distance, and which are configured to support the frame segments (1.1) corresponding to the solar panel (PV) to be framed, said longitudinal profiles (2.1, 2.2) being attached to a structure (101.0) of the joining station (101) with freedom of longitudinal movement in the determined direction of movement (X).
    [14]
    14. Installation according to claim 13, wherein the loading tool (2) comprises a connecting element (2.3) that joins both longitudinal profiles (2.1, 2.2) with each other, such that the longitudinal profiles (2.1, 2.2) they are adapted to move simultaneously and together in the direction of movement (X), said connecting element (2.3) preferably being a bar that extends transversely between both longitudinal profiles (2.1, 2.2).
    [15]
    15. Installation according to claim 13 or 14, wherein each longitudinal profile (2.1, 2.2) comprises at least one support (2.4) to support at least one frame segment (1.1).
    [16]
    16. Installation according to claim 15, which is adapted to frame rectangular solar panels (PV), each longitudinal profile (2.1, 2.2) comprising two supports (2.4) to support a frame segment (1.1) longitudinally, such that each one of said two frame segments (1.1) is supported on, or joined to, a corresponding longitudinal profile (2.1, 2.2), and each longitudinal profile (2.1, 2.2) comprising an additional support (2.4) facing another additional support ( 2.4) of the other longitudinal profile (2.1, 2.2) to support between both longitudinal profiles (2.1, 2.2) two frame segments (1.1) transversely, such that each of said two frame segments (1.1) is supported on, or joined to, both longitudinal profiles (2,1,2.2).
    [17]
    17. Installation according to claim 15 or 16, wherein each longitudinal profile (2.1, 2.2) comprises two supports (2.4) that are distributed in the direction of movement (X) and projecting from the corresponding longitudinal profile (2.1, 2.2) outside of the space delimited between both longitudinal profiles (2.1, 2.2), the two supports (2.4) of a longitudinal profile (2.1, 2.2) configured to support
    one
    a respective frame segment (1.1), and two additional supports (2.4) that are distributed in the displacement direction (X) and that protrude from the corresponding longitudinal profile (2.1, 2.2) within the space delimited between both longitudinal profiles (2.1, 2.2), each additional support (2.4) of a longitudinal profile (2.1, 2.2) facing another additional support (2.4) of the other longitudinal profile (2.1, 2.2) and said two additional supports (2.4) forming a pair of supports (2.4), each pair of additional supports (2.4) configured to support a respective frame segment (1.1).
    [18]
    18. Installation according to any of claims 10 to 17, wherein the direction of movement (X) is horizontal.
    [19]
    19. Installation according to any of claims 10 to 18, wherein the charging station (102) is arranged on one side with respect to the joining station (101).
    类似技术:
    公开号 | 公开日 | 专利标题
    ES2668687T3|2018-05-21|Utility accessory to create a distributed utility network
    RU2018127768A|2020-02-04|CAPTURE DEVICE AND METHOD FOR MANUFACTURING AN INSULATING GLASS PACKAGE
    ES2548551T3|2015-10-19|Procedure and device for industrial manufacturing of photovoltaic concentrator modules
    ES2754874A1|2020-04-20|Method and installation to frame a solar panel |
    TW201526271A|2015-07-01|Solar panel mechanical connector and frame
    JP2014238402A5|2015-02-05|
    WO2017083993A1|2017-05-26|Elasto-mechanical chamber
    RU2018124864A|2020-01-20|ADJUSTABLE LENGTH SCREEN CONTAINING ITS SYSTEM AND METHOD FOR ITS MANUFACTURE
    KR20140122493A|2014-10-20|Parallel manipulator with transportation devices
    ES2358936A1|2011-05-17|Modular energy dissipation system
    TW201533409A|2015-09-01|Mounting structure of a solar panel
    CN109229539A|2019-01-18|A kind of more box vanning gripper robots
    JP2017136931A5|2019-03-07|
    TWI515162B|2016-01-01|Active steady state clamping release system
    TWM498861U|2015-04-11|Solar panel frame module
    RU2008129833A|2010-01-27|DEVICE FOR SEALING INPUT CABLES, PIPELINES OR PIPES
    CN205834033U|2016-12-28|A kind of three moulds roll up discharging material-receiving device of breasting the tape
    ES2529622T3|2015-02-23|Fixing device for solar cells as well as procedure for fixing solar cells
    JP6574597B2|2019-09-11|Solar cell module installation base and solar cell module mounting method
    CN107735217B|2019-09-06|Working piece positioning device
    CN105252479A|2016-01-20|Keyboard assembling device
    CN212496072U|2021-02-09|Weld and take draw gear and stringer
    BR112019005207A2|2019-06-11|system for switching high voltages, and method for switching a system
    CN105345584A|2016-02-24|Board fixing and adjusting clamping jaw with guiding function
    TR201605867A2|2016-09-21|VACUUM HOLDER WITH MECHANICAL SUPPORT
    同族专利:
    公开号 | 公开日
    CN111063762A|2020-04-24|
    ES2754874B2|2020-12-03|
    EP3640166A1|2020-04-22|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20100024190A1|2007-03-16|2010-02-04|Albert Vontz|Connection process and framing device|
    DE102010053161A1|2010-09-08|2012-03-08|Schiller Automation Gmbh & Co. Kg|Device for framing photovoltaic module that is utilized on building roof, has press pressing frame to exposed edges of photovoltaic-module in assembly position, which is adjustable relative to frame|
    CN103646996A|2013-12-06|2014-03-19|保定天威英利新能源有限公司|Automatic framing apparatus of photovoltaic assembly and using method thereof|
    CN105097996A|2015-08-18|2015-11-25|蠡县英利新能源有限公司|Solar cell assembly packaging system and packaging process|
    CN107123704A|2017-06-21|2017-09-01|苏州宏瑞达新能源装备有限公司|PV glass panel longitudinally puts template machine|
    CN108447927A|2018-03-12|2018-08-24|吴竹兰|A kind of solar photovoltaic assembly package system|
    US20050241130A1|2004-04-28|2005-11-03|Vinode Ramnauth|Apparatus for cleaning and processing two frameworks|
    CN103128485B|2013-03-14|2015-06-03|济南天辰铝机制造有限公司|Four-head numerical control corner assembling production line|
    CN106493544A|2016-12-10|2017-03-15|钱理|A kind of photovoltaic module is framed up equipment automatically|
    CN110277458A|2017-03-09|2019-09-24|伟创力有限公司|Stacked tile type array solar cells and manufacture include the method for the solar components of stacked tile type array solar cells|
    法律状态:
    2020-04-20| BA2A| Patent application published|Ref document number: 2754874 Country of ref document: ES Kind code of ref document: A1 Effective date: 20200420 |
    2020-12-03| FG2A| Definitive protection|Ref document number: 2754874 Country of ref document: ES Kind code of ref document: B2 Effective date: 20201203 |
    优先权:
    申请号 | 申请日 | 专利标题
    EP18200570.2A|EP3640166A1|2018-10-16|2018-10-16|Method and installation for framing a solar panel|
    [返回顶部]