The present invention relates to a string lamp. The string lamp includes a bulb, a lamp holder, a hollow connecting base and a capacitor embedded in the connecting base in a separable mode. A lower part of the bulb is contained in the lamp holder. At least two lamp pins extend out from wire holes formed in the lower part of the lamp holder. The inner side wall of the connecting base is provided with at least two separately arranged conductive pieces, and the conductive pieces are electrically contacted with the corresponding lamp pins. The capacitor is arranged below the lamp holder, and connecting pins of the capacitor are electrically contacted with the corresponding conductive pieces as well. The string lamp of the present invention is compact in structure, and the capacitor and the lamp holder are convenient to maintain and replace.

Embodiments relate to a lighting device that includes or retains a plurality of solid-state light emitters and is capable of providing one or more of omni-directional lighting and task lighting. Other embodiments relate to modular lighting systems for providing the same.

The invention provides an interconnected string of three LED modules, having internal and external connections such that each LED in the string is fully individually addressable. LED biases and interconnects are oriented and configured such that individual addressability is achieved without the need for direct external signal connections to each LED in the string. Consequently embodiments are provided comprising pluralities of strings, arranged so as to form an array of LED modules, wherein wiring tracks running beneath, or along the intermediary spaces between, rows of LEDs are not required. Hence are provided LED devices comprising an array of individually addressable LED modules, having reduced spacing between rows and columns, and having optimal thermal path perpendicularly across the substrate layer. Provided devices have improved heat dissipation and greater achievable LED array density. Also provided are embodiments comprising one or more lens arrangements, suitable, for example, for adaptive beam-shaping applications.

Apparatus and associated methods relate to a water-resistant capture device for enclosing wired electro-magnetic components, the capture device having a base module and a connecting cap module, wherein when the base module and cap module enclose an electro-magnetic component and the base module is connected to the cap module, one or more electric wires are compressed within deformable wire apertures formed by the combined base module and cap module. In some embodiments, the base module is deformable and deforms when affixed to the cap module so as to form a compressive water-resistant seal to an interior of the capture device. In an exemplary embodiment, an LED may be captured within the capture device. The cap module may provide a compressing aperture to provide a water resistant seal around the lens of a LED projecting therethrough.

A guide for a strand of electric lights having a plurality of light elements spaced along an electric conductor. The guide includes a tubular body having an inlet end, an outlet end, and an oblong shaped passage extending through the tubular body from the inlet end to the outlet end. The passage dimensioned to slidably receive the light elements in a way that causes the light elements to be generally oriented along a major width of the passage as the light elements pass through the tubular body.

A circuit substrate for carrying at least one light-emitting diode and a light-emitting structure for providing illumination are disclosed. The circuit substrate includes an insulation base layer, a conductive heat-dissipating layer, an insulation covering layer, a conductive circuit structure and a conductive through structure. The conductive heat-dissipating layer is disposed on the insulation base layer. The insulation covering layer is disposed on the conductive heat-dissipating layer. The conductive circuit structure includes a first electrode conductive layer and a second electrode conductive layer that are disposed on the insulation covering layer. The conductive through structure passes through the insulation covering layer and is connected between the conductive heat-dissipating layer and one of the first electrode conductive layer and the second electrode conductive layer. One of the first electrode conductive layer and the second electrode conductive layer is electrically connected to the conductive heat-dissipating layer through the conductive body.

The present disclosure provides a multi-directional light fixture having a single orientation light source. The multi-directional light fixture includes a light source orientated towards a semi-reflective lens. The semi-reflective lens allows a portion of the light it receives from the light source to be reflected upwards, providing uplight from the light fixture. The lens also allows a portion of the light it receives from the light source to be transmitted therethrough, providing downlight from the light fixture. Thus, the light fixture provides both uplight and downlight while the light source is oriented downwards.

The illuminated headset is a headphone that is adapted for listening to audio sources, which provide electrical signals, which are converted to audible sound by the speakers in the headphone. The headphone is enhanced with an illumination system. The illumination system comprises a plurality of LEDs and a phosphorescent material. The plurality of LEDs is used to illuminate the cable, the left speaker, and the right speaker. The phosphorescent material is used to form the headband, the left speaker housing, and the right speaker housing. The illuminated headset comprises a headset, a master cable, a jack, a clasp, a left cable, and a right cable.

The present disclosure relates generally to a light emitting diode (LED) luminaire. In one embodiment, the LED luminaire includes an enclosure having an interior volume and a flat side along a length of the enclosure, wherein the flat side comprises an inside surface and an outside surface, wherein the enclosure comprises an extruded optically clear plastic and one or more LEDs coupled to one or more circuit boards, wherein the one or more circuit boards are mounted on the inside surface of the flat side of the enclosure.

There is a provided a lighting system comprising a first cable and a second cable for receiving a voltage difference. The first cable extends between a first pair of installation locations and the second cable extends between a second pair of installation locations. The lighting system also comprises a plurality of light emitting diode (LED) strips, each LED strip electrically connected to and extending between the first cable and second cable. The lighting system also comprises a cable tensioner system coupled to the first cable and second cable for adjusting the tension of the first cable and second cable.