Abstract: A method of making a photovoltaic panel includes previously preparing one or more pre-formed substrates with a first temperature and pressure to be non-planar, textured, embossed, colored, or combinations thereof. A manufacturer can then prepare a laminate assembly comprising one or more organic photovoltaic components one or more pre-formed substrates, and a barrier layer with one or more thermally-activated thermoplastic tie layers there between. The manufacturer can then finish the photovoltaic panel lamination by subjecting the assembly to a second set of temperatures and pressures sufficient to activate and bond the pre-formed substrate, barrier layer, and photovoltaic components without significantly softening the pre-formed substrates or otherwise degrading/damaging the organic photovoltaic components. A non-planar panel made by this method can be used in both exterior and interior decorative and/or structural applications where electrical generation is desired.

Abstract: A roller door system includes a roller assembly configured to mount directly to a panel and move along a complementary upper guide. In particular, the roller assembly can be coupled to a coupling member embedded in the panel. The roller assembly, when coupled with the panel, can provide a smooth gliding motion for the panel.

Abstract: A variable angle panel mounting system can include at least one variable-angle panel mounting member, which in turn includes an elongate support member and an angularly-adjustable mounting plate adapted to secure an end of the elongate support member to a plurality of mounting surface angles. In some embodiments, the variable angle panel mounting system may also include a pressure-fit mounting system. These components can provide the ability to angularly and vertically adjust the variable-angle panel mounting member between opposing support surfaces.

Abstract: Implementations of the present invention relate to systems, methods, and apparatus for applying heat and pressure to a laminate assembly and to form a unitary product therefrom with increased processing efficiency. One implementation includes an apparatus that can decrease processing time by directly heating and cooling platens that press the laminate assembly. Additionally, the lamination press can allow the platens to flex about the laminate assembly, thereby applying substantially uniform pressure to the laminate assembly.

Abstract: An efficient lamination presses can rapidly provide both heating and cooling, as well as pressure to resin sheets to create a laminate end-product. Specifically, an efficient lamination press can comprise one or more components and apparatus that can apply uniform fluid pressure across one or more platens. The one or more platens, in turn, can flex about one or more contours in a layup assembly. For example, an exemplary platen can comprise a plurality of coupled platen extensions, which can flex or otherwise adjust about each other to help create flexibility in the platen, and thus, uniform pressure across a laminate assembly.

Abstract: An efficient lamination presses can rapidly heat and precisely control the temperature of a laminate assembly to create final products with excellent structural and aesthetic properties. Specifically, an efficient lamination press can include a radiant heating assembly. The radiant heating assemblies can uniformly heat one or more platens using radiation. The platens in turn can comprise material having a high thermal conductivity, which can allow them to quickly transfer heat to a laminate assembly. The platens can further comprise one or more fluid channels that enable rapid cooling. The rapid heating and cooling capability can enable fast processing times for laminate panels at much lower energy levels than with conventional presses.

Abstract: Implementations of the present invention relate to systems, methods, and apparatus for manufacturing aesthetically pleasing architectural resin panels having a thick three-dimensional interlayer. In particular, at least one implementation includes a layup assembly that includes a decorative interlayer, positioned between resin sheets, that decorative interlayer comprising one or more three-dimensional decorative objects and one or more resin blocks. At least one implementation also includes a single-step lamination or pressing process that uses a combination of heat and pressure to melt the resin sheets and the resin blocks together, forming a decorative resin panel which includes the three-dimensional objects.

Abstract: Implementations of the present invention relate generally to methods, systems, and apparatus for manufacturing aesthetically pleasing, resin-based sheets including color and/or multi-decorated images. In particular, at least one implementation includes subjecting at least one surface of a polymer sheet to uniform heat and pressure in order to sublimate a dye into the surface, and ensure that that polymer sheet is not warped or otherwise damaged during processing. Additional implementations include decorative architectural resin panels including a resin sheet having a dye sublimated into one or more surfaces in order to create an effect of depth or other aesthetic.

Abstract: Implementations of the present invention relate to a translucent and/or transparent polymer-based panel system that incorporates multi-colored insert layers that enable manipulation of color, transparency or light transmission of the finished panel system. Implementations of the present invention also relate to the construction of such panels to avoid the capture and retention of air within the panels through the use of textured surfaces at the lamination interfaces. In addition, implementations of the present invention provide a method of quantifying the optical response achieved in a given panel system and describes types of construction that enable the multiplicity of color and optic manipulation. Furthermore, implementations of the present invention provide methods for applying texture in an efficient, uniform manner.