A housing for retaining an integrated-lighting-module within the housing may have a main-housing-member that is an elongate hollow member, that is capped at both a top-end and at a bottom-end, by a top-cap and by a bottom-cap, respectively. The integrated-lighting-module may have one or more LEDs (light emitting diodes). The main-housing-member may have internal structural member(s), such as, at least one internal-rib. The main-housing-member may have teeth attachment structures for removable attachment to the bottom-cap. The bottom-cap may have its own teeth attachment structure for removable attachment to a bottom of the integrated-lighting-module. The bottom-cap may have a seat annular shelf structure for supporting and preventing downward movement of the integrated-lighting-module located within the housing. The housing may be implemented as a ceiling-mounted downlight, a track-lighting mounted light, a pendant downlight, or a sconce.

A lighting fixture includes a housing, a first light source, a light guide plate, and a second light source. The housing has an inner cavity and a mounting hole, the mounting hole communicates the inner cavity with an external environment of the housing, the light guide plate is installed in the mounting hole. A side of the light guide plate faces the inner cavity, the other side of the light guide plate faces an outside of the housing. The second light source projects second light to the light guide plate, the second light is capable of being projected to the outside of the housing through the light guide plate. The first light source projects first light, and is configured such that the first light is projected to the outside of the housing through the light guide plate, and the housing is a non-light-transmitting housing.

A recessed light fixture has a heat sink and a removable light engine assembly. A thermally conductive base of the light engine assembly has an LED and has a thermal interface adapted for thermal coupling to a thermal interface of the heat sink. A mechanical connector in the enclosure can connect the base of the light engine assembly to the heat sink and couple the thermal interfaces of the light engine assembly and heat sink. The base of the light engine assembly is insertable through an opening in the ceiling aligned and can be urged into connected and disconnected states, from within the room, with a minimal clearance between the opening in the ceiling and the base, whereby the light engine assembly can be replaced or serviced from within the room without disturbing the ceiling and without the use of a large diameter trim.

A luminaire includes a light source positioned at a first level within a luminaire housing. The luminaire also includes a trim component positioned at a second level of the luminaire housing different from the first level. The trim component extends into a room from a ceiling surface and includes an aperture antenna that receives wireless signals and transmits wireless signals. Further, the luminaire includes a communication module that communicates wirelessly with one or more devices remote from the luminaire by controlling excitation of the aperture antenna.

A lighting device (1) is provided. The lighting device (1) comprises a cavity (10). The cavity (10) is extending along a longitudinal axis (L) of the lighting device (1). Further, the cavity (10) is defined by an interior surface (11) configured to reflect light impinging upon the interior surface (11) of the cavity (10). The cavity (10) has an opening (12) permitting light inside the cavity (10) to exit the cavity (10). The lighting device (1) further comprises an optical module (20). The optical module (20) is arranged in or at the opening (12) of the cavity (10), and is configured to transmit light impinging upon a surface (21) of the optical module (20) through the optical module (20). The light transmitted through the optical module (20) is emitted from the lighting device (1). The lighting device (1) further comprises a plurality of light emitting elements (31). The light emitting elements (31) are arranged in a succession along the longitudinal axis (L) of the lighting device (1) and arranged in the cavity (10), and are configured to emit first light (41). The first light (41) is impinging on the surface (21) of the optical module (20) without having first impinged on the interior surface (11) of the cavity (10). The light emitting elements (31) are further configured to emit second light (42). The second light (42) is impinging on the interior surface (11) of the cavity (10). The optical module (20) is configured to collimate the first light (41) in a transverse plane. The transverse plane is perpendicular to the longitudinal axis (L) of the lighting device (1). The optical module (20) is further configured to produce collimated light so as to increase the degree of collimation of light, in the transverse plane, transmitted from the optical module (20) as compared to the first light (41) prior to transmission through the optical module. At least one of the interior surface (11) of the cavity (10), the plurality of light-emitting elements (31) and the optical module (20) is or are configured such that the second light (42), reflected by the interior surface (11) of the cavity (10) and subsequently having impinged upon the surface (21) of the optical module (20) and transmitted from the optical module (20), is light for which at least 3% of the total luminous flux is in th

An integrated ceiling device includes integrated ceiling device including an electronic device housing, a heat dissipating structure, a light source, and a reflection/refraction assembly. An air gap is defined between the electronics housing and other components allowing ambient air to flow therethrough for cooling.

A lighting device or lamp having two or more operating modes are provided. The lighting device or lamp comprises a housing having one or more light emitting diode (LED) packages mounted therein. The lighting device or lamp further comprises at least one secondary optic disc comprising a plurality of secondary optical elements. The secondary optical elements comprise two or more types of secondary optical elements. An operating mode of the two or more operating modes corresponds to each of the one or more LED packages being aligned with a secondary optical element of a predetermined type. The secondary optic disc is mounted to the housing so that the secondary optic disc is selectively rotatable with respect to the housing.

A fixture is sized to be inserted into an electrical junction box having a socket. The fixture has a plug with conductive terminals that are mateable with the socket to connect the fixture to an electrical signal connected to the socket. An end of the fixture with the plug is inserted into the junction box to mate with the socket. A release latch extends from the plug so that an end of the latch is not recessed within the junction box, and can be pushed to release the plug and fixture for removal. The socket is attached to extension arms that are attachable to the junction box, so that the socket can be positioned at the correct height within the box to properly mate with the plug of the fixture after insertion.

A flipping installation device for LED strip lighting includes an installation frame, a house, at least one link mechanism, and at least one clamping mechanism. Each of the at least one link mechanism includes a first link mounted on the installation frame, a second link disposed on the house, and a third link rotatably connected between the first and second links. The first and second and third links is perpendicular to each other in the cross section perpendicular to the axial direction of the house when the house has been installed into the installation frame. Each of the at least one clamping mechanism includes a catch head disposed on the installation frame, and a resilient lock disposed on the house and coupled to the catch head. The link mechanism and the clamping mechanism are located on the opposite side of the house.

An assembling mechanism for LED downlight includes a cylindrical body, at least one spring fixed on the cylindrical body, and a cover assembled on the at least one spring. Each of the at least one spring includes a fixing portion, a reed extending from the fixing portion along a rotation direction of the cylindrical body, and a catching portion disposed on the reed. The catching portion extends along the radial direction of the cylindrical body. The cover includes at least one clamping gap. Each of the at least one clamping gap includes an open provided along the rotation direction of the cylindrical body. The catching portion is inserted into the clamping gap from the opening by rotating the cover.