A substrate for a solid state lighting module has a plurality of serrated finger sections extending from an interconnecting base. The substrate may be formed from a single rectangular sheet by cutting away material between adjacent finger sections of a symmetrical second substrate to form the finger sections of the substrate. Parallel linear rows of solid state light sources may be disposed along the length of each finger section. For example, the solid state light sources may be disposed proximate to points of sawteeth at the edges of the finger sections.

A lamp assembly for a vehicle includes a housing that defines a space; an outer lens that covers the space defined by the housing; and a bezel disposed on the space defined by the housing. The lamp assembly also includes a plurality of OLED modules mounted on the bezel that is disposed on the space defined by the housing, the plurality of OLED modules mounted to be separated from each other. The lamp assembly further includes a drive module configured to control the plurality of OLED modules; and a connecting flexible circuit board disposed on at least one of the housing or the bezel, to which each of the plurality of OLED modules is connected and which is connected to the drive module.

An electronic device is described that is designed to be more easily recycled at its end of life while maintaining usability during its lifetime. The electronic device includes a first substrate, an encapsulation layer, and a set of electronics disposed there between. One or more delamination layers cover at least one side, preferably both sides, of the set of electronics to separate the set of electronics from at least one, preferably both, of the first substrate and the encapsulation layer. The set of electronics, covered by the one or more delamination layers, is encapsulated between the encapsulation layer and the first substrate. At least one of the delamination layers includes a set of passages filled with material of the encapsulation layer forming a set of interconnections between the encapsulation layer and the first substrate.

An illumination device comprises a holder, a plurality of light emitting elements, a translucent cover and a lamp cap structure. The holder comprises a heat dissipating base body and a carrying unit. The carrying unit is connected to a top portion of the heat dissipating base body and comprises a carrying base body, a circuit pattern and a heat dissipating pattern, the circuit pattern and the heat dissipating pattern are directly formed to a surface of the carrying base body, the circuit pattern has a plurality of mounting positions, the heat dissipating pattern at least extends from a region close to the mounting position to a region where the heat dissipating pattern can contact the heat dissipating base body. The plurality of light emitting elements are respectively provided at the plurality of the mounting positions and establish an electrical connection with the circuit pattern.

Disclosed herein is a circuit-and-heat-dissipation assembly which includes: a heat sink including a heat absorbing base and a heat dissipating element, the heat absorbing base having a circuit-forming surface and an element-forming surface, the heat dissipating element protruding from the element-forming surface for dissipating heat conducted from the heat absorbing base into an ambient environment; an insulator layer formed on the circuit-forming surface; and a patterned circuit formed on the insulator layer and having an electroless plating layer which has a patterned catalyst seed layer comprising an active metal and formed on the insulator layer, and a reduced metal layer formed on the catalyst seed layer. Also disclosed herein is a method of making the circuit-and-heat-dissipation assembly.

A shading device for a greenhouse includes a shading element and at least one lighting element, wherein the shading element comprises an outer side and an inner side. The shading element is formed from interwoven electrically conductive first thread elements and electrically insulating second thread elements. The first and/or second thread elements each may be adapted for reflecting an ambient light. The lighting element(s) may be arranged at the inner side of the shading element and connected with the first thread elements, and the lighting element(s) may be driven by an electrical current, conducted by the first thread elements, resulting in the emission of an artificial light, which may illuminate a plant growing in the greenhouse.

A novel light-emitting device that is highly convenient or reliable is provided. The light-emitting device includes a framework, a flexible first light-emitting panel supported by the framework so as to form a first developable surface, and a flexible second light-emitting panel supported by the framework so as to form a second developable surface.

The invention relates to a shading device (10) for a greenhouse (15), with a shading element (20) and at least one lighting element (50,50), wherein the shading element (20) comprises an outer side (21) and an inner side (22), the shading element (20) is formed from interwoven electrically conductive first thread elements (30,30) and electrically insulating second thread elements (40), the first thread element (30,30) comprises a reflective mean (33), reflecting an ambient light (60), the lighting element (50,50) is arranged at the inner side (22) of the shading element (20) and connected with the first thread element (30,30), and the lighting element (50,50) is driven by an electrical current, conducted by the first thread element (30,30), resulting in the emission of an artificial light (51), illuminating a plant (80) growing in the greenhouse (15).

A circuit-and-heat-dissipation assembly includes: a heat sink including a heat absorbing base and a heat dissipating element, the heat absorbing base having a circuit-forming surface and an element-forming surface, the heat dissipating element protruding from the element-forming surface for dissipating heat conducted from the heat absorbing base into an ambient environment; an insulator layer formed on the circuit-forming surface; and a patterned circuit formed on the insulator layer.

An origami enabled manufacturing system. The system uses origami design principles to create functional materials, structures, devices and/or systems having an adjustable size and/or shape. An operational device can be coupled to a planar substrate shaped and sized to correspond to a desired origami shape of an origami pattern. A plurality of planar substrates can be coupled together by a plurality of connection members that corresponds to one or more crease of the origami pattern. An array of planar substrates can be formed that convert into a three dimensional structure with origami shape. The resulting three-dimensional structure provides smaller projection area, higher portability and deformability.