A user interface arrangement may include a printed circuit board having a first surface and a second surface, and a light emitting unit. The printed circuit board may include a first non-conductive layer provided with at least one aperture. The light emitting unit may be arranged to emit light through the at least one aperture of the first non-conductive layer in a direction from the second surface to the first surface of the printed circuit board to thereby define an image visible at the first surface of the printed circuit board. Embodiments of an electric apparatus comprising a user interface arrangement, a use of a printed circuit board to provide a user interface arrangement, and a method for visualizing an image on a user interface arrangement are also provided.

In one embodiment, provided is a connector comprising: a body; a first protrusion formed on a first surface of the body; a first groove formed on the first surface of the body to be adjacent to the first protrusion, and of which the shape includes the inverse of the first protrusion; a first terminal of which at least a portion is arranged to correspond to the first protrusion; and a second terminal of which at least a portion is arranged to correspond to the first groove.

Various embodiments relate to a circuit support for an electronic circuit. The circuit support may include at least one conductor track, and an insulating matrix that is injection-molded over the at least one conductor path in such a way as to leave open at least a first region for connecting at least one electronic component of the electronic circuit. The circuit support may include at least one fastening aid that is formed from the material for the insulating matrix and/or from the material of the at least one conductor.

The present application discloses a light-emitting device including a first support structure having a first surface, a plurality of light-emitting elements arranged on the first surface, and a first adhesive layer arranged on the first support structure. Each light-emitting element has a side wall, a bottom surface, a first electrode pad, and a second electrode pad arranged on the bottom surface. The first adhesive layer surrounds the side wall and does not directly contact the bottom surface. The first support structure includes a plurality of through holes located on positions corresponding to the first electrode pad and the second electrode pad.

A circuit support for an electronic circuit may include at least one conductor track, a first insulation material with which the at least one conductor track is encapsulated by injection molding so as to form an insulating matrix and so as to leave open at least one first region for the connection of at least one electronic component of the electronic circuit, and a heat sink. The conductor track is encapsulated by injection molding with the first insulation material in such a way that the insulating matrix furthermore leaves open at least one second region which is arranged between the conductor track and the heat sink. The circuit support may further include a large number of spacers which are designed and arranged in order to set a height of the second region. The circuit support may further include a second insulation material with which the second region is filled.

The present invention relates to an electrical connection structure for a PCB and an electroplating frame, and a modular lamp. The modular lamp comprises a plurality of light-emitting modules. Each light-emitting module comprises a housing and a lamp plate arranged within the housing, a light source and conductive connectors electrically connected to the light source being arranged on the lamp plate, an outer side wall of the housing being provided with two sets of conductive strips surrounding the outer side wall and protruding from the outer side wall, the two sets of conductive strips being respectively electrically connected to two electrodes of the lamp plate via the conductive connectors. After the plurality of light-emitting modules have been assembled and joined together, adjacent light-emitting modules are in contact and electrically connected via the conductive strips. The modular lamp is provided with the plurality of light-emitting modules, the shapes of the light-emitting modules are flexible and variable, each module is designed independently, and after the light-emitting modules have been joined together, adjacent light-emitting modules are electrically connected via the conductive strips on the outer side walls and may be combined to form a variety of shapes. The present invention is simple in operation, and strong in combination operability.

The present disclosure provides a frisbee, which includes a housing, and a base assembled to the housing, the frisbee further includes a speaker component assembled to the housing, and at least one light emitting component, the housing and the base cooperatively form a receiving space, the speaker component and the light emitting component are both received in the receiving space. When tossing, the frisbee of the present disclosure can deliver sound and light, which improves the fun of tossing.

A flexible copper-clad laminate for a vehicle LED lamp is provided and includes a copper-clad layer and a composite layer that are laminated. The composite layer includes a polyimide layer and thermoplastic polyimide layers. An outermost layer of the composite layer is formed as a thermoplastic polyimide layer. A total thickness of the thermoplastic polyimide layers and an entire thickness of the polyimide layer with respect to a total thickness of the composite layer is about 10 to 50% and 50 to 90%, respectively. The total thickness of the thermoplastic polyimide layers and the entire thickness of the polyimide layer with respect to the thickness of the composite layer is about 20 to 40% and 60 to 80%, respectively. A thickness of the copper-clad layer is about 30 to 80 m, and the total thickness of the composite layer is about 10 to 15 m.

The present application discloses a light-emitting device including a first support structure having a first surface, a plurality of light-emitting elements arranged on the first surface, and a first adhesive layer arranged on the first support structure. Each light-emitting element has a side wall, a bottom surface, a first electrode pad, and a second electrode pad arranged on the bottom surface. The first adhesive layer surrounds the side wall and does not directly contact the bottom surface. The first support structure includes a plurality of through holes located on positions corresponding to the first electrode pad and the second electrode pad.

A flexible circuit board assembly for an LED lamp of the present disclosure comprises: a resin layer having a strip shape; a conductive signal line layer formed from a predetermined pattern provided on the upper part of the resin layer; and a radiation layer provided on the lower part of the resin layer, having a thickness relatively thicker than that of the conductive signal line layer, and radiating the heat generated from an LED mounted on the signal line layer, wherein the signal line layer and the radiation layer are made from one material from among copper, aluminum, copper alloy and an aluminum alloy.