An illuminated landscaping assembly for illuminating landscaping includes a plurality of lighting modules, each comprising a housing that defines an interior space. A first connector and a second connector are attached to a first edge and a second edge of the housing, respectively. The second connector is complementary to the first connector so that the lighting modules are physically and electrically interconnectable via selective connection of the first connectors and the second connectors. A plurality of bulbs is attached to an upper face of the housing and is operationally engaged to the first connector and the second connector. A shell, which is substantially transparent, is attached to the housing and encapsulates the plurality of bulbs. A respective one of the first connectors and the second connectors is engaged a power cord extending from a power module. With the lighting modules positioned in a landscape, the bulbs selectively illuminate the landscape.

A light fixture and wireway assembly is provided in a low-profile configuration wherein at least a portion of a plurality of wireways are disposed in a stacked configuration with a low-profile, edge-lit LED light engine. In one configuration, at least portions of two to four individual wireways are disposed in a stacked configuration with a low-profile, edge-lit LED light engine powered by an LED power supply also disposed within the outer perimeter of the overall assembly. Each wireway can be accessed through a single wireway wall without requiring conduit outside of the outer perimeter of the assembly.

An illumination chain includes a first illumination element and a multitude of further illumination elements, wherein each further illumination element is connected via a joint each to the preceding illumination element.

An origami lamp includes a lamp stand having a standing portion and a connecting portion, a light emitter provided with a light source, and a lampshade, which are connected integrally. By bending and fastening a planar bendable sheet, a bottom section, a lower part and an upper part of a middle section and a top section of the planar bendable sheet are respectively formed into the standing portion as a tube, the connecting portion as a cone, the light emitter as another cone and the lampshade as a cloak at the same time. As a result, the origami lamp is easily formed from the planar bendable sheet, so the planar bendable sheet can serve as the product for sale for the convenience in storage and transportation.

A light string, comprising a first illumination device configured to emit a first color light; a second illumination device adjacent the first illumination device, and configured to emit a second color light, the second color being different from the first; a first wire including a first conductor and a first insulating layer, the first conductor partially exposed to form a first conductor soldering section; and a second wire, including a second conductor and a second insulating layer, the second conductor partially exposed to form a second conductor soldering section. The first conductor soldering section and the second conductor soldering section are attached to a pair of electrical contacts on each of the first and second illumination devices, and the first and second illumination devices are electrically biased such that either the first illumination device emits light or the second illumination device emits light, but not both at the same time.

A light string, comprising a first illumination device configured to emit a first color light; a second illumination device adjacent the first illumination device, and configured to emit a second color light, the second color being different from the first; a first wire including a first conductor and a first insulating layer, the first conductor partially exposed to form a first conductor soldering section; and a second wire, including a second conductor and a second insulating layer, the second conductor partially exposed to form a second conductor soldering section. The first conductor soldering section and the second conductor soldering section are attached to a pair of electrical contacts on each of the first and second illumination devices, and the first and second illumination devices are electrically biased such that either the first illumination device emits light or the second illumination device emits light, but not both at the same time.

An LED strip includes a plurality of LED components and a wire set, the LED component comprising: an insulated main body, conductive terminals fixed on the insulated main body and connected to the wire set, and lighting an LED chip and a control unit configured on the insulated main body. The insulated main body has recessed notches. The wire set at least includes a first wire running through the notch, and the first wire is formed with a cut portion. When producing the LED strip in series connection, the LED components and the corresponding continuous wire can be soldered together directly by the means of SMT technique. Then, using a cutter and the preset notch, the wire can be cut at the position of the notch. In this way, the operation of SMT soldering for the LED strip can be completed quickly.

The disclosure includes a convertible light device comprising a housing, a battery pack coupled to the housing, and an elongate flexible light source detachably coupled to the housing and electrically coupled to the battery pack, where the elongate flexible light source comprises a plurality of LEDs. In some embodiments, the convertible light device is configured to convert between a rope mode and a lantern mode. In the rope mode, the elongate flexible light source may be configured to extend from the housing and couple to an external anchor. In the lantern mode, the elongate flexible light source may be configured to wrap around the housing.

An ultraviolet lamp. There is a lamp housing; a plurality of rows of ultraviolet (UV) light emitters, coupled to the housing and disposed linearly and longitudinally along a single face of the lamp housing; wherein each row includes an array of clusters of UV light emitters, each cluster including a diverse set of UV light emitters, wherein the light emitters are diverse in the frequency spectrum of light emission between at least two of the emitters in the cluster; wherein the clusters of each row have consistent light emitter placement configuration with respect to clusters within the same row; and wherein the clusters of a first row have a different configuration than the clusters of a second row; and a power source coupled to the lamp housing opposite the single face and in functional communication with the UV light emitters.

An ultraviolet lamp. There is a lamp housing; a plurality of rows of ultraviolet (UV) light emitters, coupled to the housing and disposed linearly and longitudinally along a single face of the lamp housing; wherein each row includes an array of clusters of UV light emitters, each cluster including a diverse set of UV light emitters, wherein the light emitters are diverse in the frequency spectrum of light emission between at least two of the emitters in the cluster; wherein the clusters of each row have consistent light emitter placement configuration with respect to clusters within the same row; and wherein the clusters of a first row have a different configuration than the clusters of a second row; and a power source coupled to the lamp housing opposite the single face and in functional communication with the UV light emitters.