A luminaire element (10) for a luminaire (1), which luminaire element (10) comprises a first light-emitting device (11); a second light-emitting device (12); a frame (2) realized to accommodate the first light-emitting device (11) and the second light-emitting device (12), which frame (2) comprises a connecting interface (22, 23) realized to physically and electrically connect to a further luminaire element (10) of the luminaire (1); and wherein the first light-emitting device (11) and the second light-emitting device (12) are arranged within the frame (2) such that the first light-emitting device (11) emits to a first side of the luminaire element (10), and the second light-emitting device (12) emits to a second side of the luminaire element (10).

Disclosed is a lighting fixture (10) that illuminates a presentation object or surface. The lighting fixture includes a first member (18) that at least partially surrounds or encompasses the presentation object and has a plurality of LED-based light sources (12) which can create a variety of lighting effects based on one or more characteristics of the presentation object. The lighting fixture further has a sensor (34) that detects a characteristic of the presentation object, and a controller (26) connected to the sensor such that, as a result of the individual addressability of the LED-based light sources, create or modify a directional lighting effect based on the detected characteristic.

A lamp is disclosed with a circuit board that is manufactured from a flexible material. The lamp may find particular use in a surgical or diagnostic environment. The flexible material allows the orientation of lamp elements to allow for a custom light beam. The flexible circuit board allows for interconnection between multiple lamp elements at different angles and rotation without having individual rigid circuit boards. Furthermore, the flexible circuit board may be mounted to a back panel, wherein the back panel is configured to act as a heat sink to dissipate heat generated, in operation, by the lamp element.

The illuminated bottle rack is an accessory adapted for use with a beverage display. The accessory includes an LED strip that is adapted to attach itself onto a beverage display shelf. Moreover, the LED strip is secured onto the beverage display shelf via at least one bracket. The LED strip is adapted to be presented underneath the beverage display shelf so as to illuminate at least one bottle positioned on the beverage display shelf. The LED strip is wired to a first controller, which in turn includes a wire that is adapted to be inserted into a standard electrical outlet. A remote controller may be included to remotely control the output of the LED strip.

A lamp has an optically transmissive enclosure and a base. A tower extends from the base into the enclosure and supports an LED assembly in the enclosure. The LED assembly comprises a plurality of LEDs operable to emit light when energized through an electrical path from the base. The tower and the LED assembly are arranged such that the plurality of LEDs are disposed about the periphery of the tower in a band and face outwardly toward the enclosure to create a source of the light that appears as a glowing filament. The tower forms part of a heat sink that transmits heat from the LED assembly to the ambient environment. The LED assembly has a three-dimensional shape. An electrical interconnect connects a conductor to the heat sink where the conductor is in the electrical path between the LED assembly and the base.

A lamp has an optically transmissive enclosure and a base. A tower extends from the base into the enclosure and supports an LED assembly in the enclosure. The LED assembly comprises a plurality of LEDs operable to emit light when energized through an electrical path from the base. The tower and the LED assembly are arranged such that the plurality of LEDs are disposed about the periphery of the tower in a band and face outwardly toward the enclosure to create a source of the light that appears as a glowing filament. The tower forms part of a heat sink that transmits heat from the LED assembly to the ambient environment. The LED assembly has a three-dimensional shape. An electrical interconnect connects a conductor to the heat sink where the conductor is in the electrical path between the LED assembly and the base.

An LED light fixture assembly includes an elongated first support member, an elongated second support member spaced from and substantially parallel to the first support member, and a plurality of elongated LED lighting fixtures coupled to and extending between the first support member and the second support member. Each LED lighting fixture includes an elongated structural frame member having a substantially channel shaped support portion, and a mounting portion opposite the support portion. Each LED lighting fixture also includes a plurality of LED light modules secured to and positioned along the mounting portion, and a cover extending along and supported by the mounting portion. The cover is positioned so light emitted from the plurality of LED light modules passes through the cover and away from the mounting portion.

The present invention discloses a method for constructing a universal LED bulb, a flange snap ring type LED bulb and a lamp. A heat conductive bracket (3) with a flange is used as a structure supporting main body of the bulb to establish an optical engine core member of the LED bulb. An inner snap ring (81) fixed to the heat conductive bracket (3) is used to support the optical engine core member in an auxiliary manner. The optical engine core member is composed of the heat conductive bracket (3), an optical engine module (4), the inner snap ring (81), an inner cover (6), an electric connector (11) and a light distribution optical lens (7). The optical engine module (4) is made up of an optical engine die plate, an LED chip and a relevant wiring by bonding and packaging, or is further integrated with a power supply drive chip.

The present invention discloses a method for constructing a universal LED bulb, a flange snap ring type LED bulb and a lamp. A heat conductive bracket (3) with a flange is used as a structure supporting main body of the bulb to establish an optical engine core member of the LED bulb. An inner snap ring (81) fixed to the heat conductive bracket (3) is used to support the optical engine core member in an auxiliary manner. The optical engine core member is composed of the heat conductive bracket (3), an optical engine module (4), the inner snap ring (81), an inner cover (6), an electric connector (11) and a light distribution optical lens (7). The optical engine module (4) is made up of an optical engine die plate, an LED chip and a relevant wiring by bonding and packaging, or is further integrated with a power supply drive chip.

A housing includes a mount projection defining a first notch, a second notch, and a recessed wall. At least a portion of the recessed wall defines a substantially conical cross-sectional shape between a maximum width and a length from a leading portion to a line associated with the maximum width. The mount projection is configured to complimentarily mate to a bracket defining a recessed wall with a maximum width, corresponding to the maximum width of the mount projection, and a length, corresponding to the length of the mount projection, from a leading portion to a line associated with the maximum width. The mount projection is releasably retained within an opening of the bracket when a first projection and a second projection of the bracket are disposed within the first notch and the second notch, respectively, of the mount projection.