An illumination device includes a support section, a heatsink coupled above the support section and including a plurality of flat vertical exterior surfaces, a driver housing coupled above the heat sink, a plurality of light source modules coupled to the exterior surfaces of the heatsink, and a plurality of nano-optical lenses coupled to the light source modules to direct light from the light source modules to sub-fields of illumination disposed horizontally below. The illumination device is mounted above ground and configured for uniformly illuminating the sub-fields of illuminations without direct glare.

A charging station for providing power connections, charging and/or data connections includes one or more wiring devices mounted to a power module that slides in the housing of the main assembly of the charging station such that each wiring device is recessed from the outer surface of the charging station. A back wall of the power module serves as a barrier between different branch circuits for code compliance. The charging station includes a cover assembly with a sloped upper surface and is constructed so that most of the required electrical connections are made on the power module prior to the assembly of the charging station.

A lighting apparatus includes an anchored base comprising a bollard configured to slide onto an anchor plate and a first extrusion configured to mate the bollard with the anchor plate at a bottom end of the bollard, a cap attachment comprising a second extrusion configured to mate with the bollard at a top end of the bollard, a fixture head comprising a third extrusion disposed on an LED optical chamber and a front cap, wherein the third extrusion is configured to mate with the front cap, and a first fixture head attachment disposed on an exterior surface of the bollard at a top end, wherein the first fixture head attachment includes a fourth extrusion configured to mate with the fixture head and operatively connect the fixture head with the anchored base, wherein the first, second, third, and fourth extrusions are configured to respectively mate at four regions of contact to flushly visually obscure one or more screws.

A lighting apparatus includes an anchored base comprising a bollard configured to slide onto an anchor plate and a first extrusion configured to mate the bollard with the anchor plate at a bottom end of the bollard, a cap attachment comprising a second extrusion configured to mate with the bollard at a top end of the bollard, a fixture head comprising a third extrusion disposed on an LED optical chamber and a front cap, wherein the third extrusion is configured to mate with the front cap, and a first fixture head attachment disposed on an exterior surface of the bollard at a top end, wherein the first fixture head attachment includes a fourth extrusion configured to mate with the fixture head and operatively connect the fixture head with the anchored base, wherein the first, second, third, and fourth extrusions are configured to respectively mate at four regions of contact to flushly visually obscure one or more screws.

Described herein is modular luminaire assembly which is readily assembled and installed in the field whilst providing rigidity, structural integrity and water-tightness. The assembly comprises a plurality of luminaire modules mounted on a supporting pole. The plurality of luminaire modules comprises three luminaire modules which are connected to one another by respective module connectors and to the supporting pole by module connector. Each luminaire module has at least one interface for engaging with a complementary interface of an adjacent luminaire module or the supporting pole to provide a water-tight connection, each pair of modules being fixed together by a module connector.

An apparatus includes a classification of shaded area and a light unit being configured for illumination. A solar panel is configured for at least providing an energy output during exposure of shade being classified by the classification of shaded area. A rechargeable storage device is configured for storing at least a portion of the energy output as stored energy. The stored energy recharges the rechargeable storage device. A safety device is configured for at least protecting the rechargeable storage device from substantial overcharging during exposure of direct sunlight. A cutoff threshold is configured for at least preventing a deep discharging of the rechargeable storage device. An illumination mode comprises at least the rechargeable storage device providing the stored energy, the light unit providing the illumination, the illumination lasting for at least 5 hours, and the cutoff threshold preventing the deep discharging of the rechargeable storage device.

A lighting apparatus comprising: a mounting substrate being arranged in the lighting apparatus at an angle below 45 with respect to a vertical direction; a plurality of light sources mounted on a lower or vertical surface of the mounting substrate such that at least two light sources are at a different height; a plurality of lens elements provided to the mounting substrate such that each of the light sources is provided with a corresponding lens element; at least two reflector elements provided to the at least two light sources, such that each of the at least two reflector elements has a reflective surface facing the mounting substrate; wherein each of the at least two reflector elements extends between a first edge, located above a corresponding light source as seen in a vertical direction, and a second edge, located below a corresponding light source as seen in a vertical direction.

Apparatus and methods are disclosed which may keep retractable landscape lamps substantially free from water intrusion in operation for a variety of embodiments. Retractable lamps may have a lower fixed portion which could be buried in the ground and an upper portion which may rise and illuminate. When the upper portion rises it may create a low pressure or vacuum inside. Water may be pulled into the lamp which may lead to failure. The lamp may benefit from a seal between the lower and upper portions. A seal may consist of a flexible rubber material and a grease or other lubricant which may form a watertight seal with low friction. The upper portion may have a cap with provisions for aspiration. While traveling between the retracted and extended positions the lamp may aspirate through the bottom of this cap. The cap may be designed to trap an air reservoir when it retracts. It may then provide air for aspiration the next time the lamp rises to permit such a rise such as above wet conditions or above standing water. The cap may have a protective vent which may allow air to pass while restricting water from passing.

An apparatus includes a light emitting diode for at least illuminating a pathway. A rechargeable storage device provides a discharge current to the light emitting diode. A solar panel supplies a charging current to the rechargeable storage device during exposure of scattered light of at most 900 foot-candles. The ratio of the charging current to the discharge current is greater than 0.5. A safety device protects the rechargeable storage device from substantial overcharging during exposure of direct sunlight. A recharging switch supplies the charging current to the rechargeable storage device during a charging mode. A discharging switch supplies the discharge current to the light emitting diode during an illumination mode. A low light sensor effects a switching between the charging mode and the illumination mode.

Apparatus and methods are disclosed which may keep retractable landscape lamps substantially free from water intrusion in operation for a variety of embodiments. Retractable lamps may have a lower fixed portion which could be buried in the ground and an upper portion which may rise and illuminate. When the upper portion rises it may create a low pressure or vacuum inside. Water may be pulled into the lamp which may lead to failure. The lamp may benefit from a seal between the lower and upper portions. A seal may consist of a flexible rubber material and a grease or other lubricant which may form a watertight seal with low friction. The upper portion may have a cap with provisions for aspiration. While traveling between the retracted and extended positions the lamp may aspirate through the bottom of this cap. The cap may be designed to trap an air reservoir when it retracts. It may then provide air for aspiration the next time the lamp rises to permit such a rise such as above wet conditions or above standing water. The cap may have a protective vent which may allow air to pass while restricting water from passing.