A processing unit and method for separating hydrocarbons from feedstock material. The processing unit includes at least one rotating conveyor in communication with a material inlet and a material outlet; a vacuum pump providing a vacuum atmosphere within the rotating conveyor; at least one material transfer device positioned at the material inlet and at least one material transfer device positioned at the material outlet, each material transfer device configured to allow transfer of feedstock material into or out of the rotating conveyor whilst maintaining the vacuum atmosphere within the rotating conveyor; and an electrostatic generator connected to the rotating conveyor providing a static charge to the vacuum atmosphere within the rotating conveyor. The method includes rotating the feedstock material in at least one rotating conveyor in communication with a material inlet and a material outlet; providing a vacuum atmosphere within the rotating conveyor; providing a static charge to the vacuum atmosphere within the rotating conveyor; transferring the feedstock material into and out of the rotating conveyor through at least one material transfer device positioned at the material inlet and at least one material transfer device positioned at the material outlet, each material transfer device allowing transfer of feedstock material into or out of the rotating conveyor whilst maintaining the vacuum atmosphere within the rotating conveyor.

A processing unit and method for separating hydrocarbons from feedstock material. The processing unit includes at least one rotating conveyor in communication with a material inlet and a material outlet; a vacuum pump providing a vacuum atmosphere within the rotating conveyor; at least one material transfer device positioned at the material inlet and at least one material transfer device positioned at the material outlet, each material transfer device configured to allow transfer of feedstock material into or out of the rotating conveyor whilst maintaining the vacuum atmosphere within the rotating conveyor; and an electrostatic generator connected to the rotating conveyor providing a static charge to the vacuum atmosphere within the rotating conveyor. The method includes rotating the feedstock material in at least one rotating conveyor in communication with a material inlet and a material outlet; providing a vacuum atmosphere within the rotating conveyor; providing a static charge to the vacuum atmosphere within the rotating conveyor; transferring the feedstock material into and out of the rotating conveyor through at least one material transfer device positioned at the material inlet and at least one material transfer device positioned at the material outlet, each material transfer device allowing transfer of feedstock material into or out of the rotating conveyor whilst maintaining the vacuum atmosphere within the rotating conveyor.

A bracket for a luminaire is described. The bracket can include a first portion having at least one first lamp socket connection system coupling feature disposed within a first body of the first portion, where the at least one first lamp socket connection system coupling feature is non-planar with the first body. The bracket can also include a second portion coupled to a proximal end of the body of the first portion, where the second portion includes at least one first housing coupling feature disposed within a second body of the second portion. The at least one first lamp socket connection system coupling feature can be configured to couple to at least one first bracket coupling feature of a socket of the luminaire. The at least one first housing coupling feature can be configured to couple to at least one second bracket coupling feature of a housing of the luminaire.

The invention relates to a printed circuit board (9) for a lamp (1), having a plurality of circuit paths having a multiplicity of light-emitting diodes (8, 12), wherein the light-emitting diodes in a circuit path are each connected up in series with one another and the circuit paths are connected in parallel with one another, wherein a first number of light-emitting diodes (LD11, LD15, LD21, LD25, LD31 LD35, LD41, LD45, LD51, LD55, LD61, LD65) in a circuit path are fitted on a front of the printed circuit board and a second number of light-emitting diodes (LDi11, LDi31, LDi52) in the same circuit path are fitted on a back of the printed circuit board.

The invention relates to a printed circuit board (9) for a lamp (1), having a plurality of circuit paths having a multiplicity of light-emitting diodes (8, 12), wherein the light-emitting diodes in a circuit path are each connected up in series with one another and the circuit paths are connected in parallel with one another, wherein a first number of light-emitting diodes (LD11, LD15, LD21, LD25, LD31 LD35, LD41, LD45, LD51, LD55, LD61, LD65) in a circuit path are fitted on a front of the printed circuit board and a second number of light-emitting diodes (LDi11, LDi31, LDi52) in the same circuit path are fitted on a back of the printed circuit board.

A light-emitting device including a substrate with a top surface and a bottom surface opposite to the top surface and a plurality of LED chips disposed on the top surface and configured to generate a top light visible above the top surface and a bottom light visible beneath the bottom surface, each LED chip comprising a plurality of light-emitting surfaces. The substrate has a thickness greater than 200 μm and comprises aluminum oxide, sapphire, glass, plastic, or rubber. The plurality of LED chips has an incident light with a wavelength of 420-470 nm. The top light and the bottom light have a color temperature difference of not greater than 1500K.

A light-emitting device including a substrate with a top surface and a bottom surface opposite to the top surface and a plurality of LED chips disposed on the top surface and configured to generate a top light visible above the top surface and a bottom light visible beneath the bottom surface, each LED chip comprising a plurality of light-emitting surfaces. The substrate has a thickness greater than 200 μm and comprises aluminum oxide, sapphire, glass, plastic, or rubber. The plurality of LED chips has an incident light with a wavelength of 420-470 nm. The top light and the bottom light have a color temperature difference of not greater than 1500K.

A linear lighting module includes a first string of series-connected LED dies and a second string of series-connected LED dies. The first string of LED dies is coupled in parallel with the second string of LED dies. All of the LED dies of the first and second strings are aligned with respect to one another. The LED dies of the first string and the second string form a combined string of interleaved LED dies such that an LED die of the second string is disposed between every successive pair of LED dies of the first string. The LED dies of the combined string are mounted on a flexible substrate. Each LED die of the combined string is electrically connected to two conductors. Except for the two end LED dies of the combined string, each successive LED die must be accessed by both conductors from alternating sides of the combined string.

Disclosed are illumination tent poles, tent frames and tents having one or more illumination tent poles. An illumination tent pole includes a tent pole, an elongated casing, a strip light source and a cover. The elongated casing is coupled to the tent pole or integrally formed with the tent pole. The elongated casing has an opening along a longitudinal direction of the elongated casing and facing away from the tent pole. The strip light source is disposed in the elongated casing along the longitudinal direction of the elongated casing. The strip light source emits a light when electrically connected to an electrical power source. The cover is coupled to the elongated casing and covers the opening of the elongated casing. The cover is made of a material that is at least partially transparent to the light emitted by the strip light source.

A light mount for mounting a light to a steering arm on an axle may include a bracket designed to attach to the steering arm; and a bracket orifice extending through a portion of the bracket, the bracket orifice sized to accommodate a light pod fastener extending from a light pod, wherein the bracket and, thus, the light pod rotate with rotation of the steering arm. The bracket may have various forms and may be a Z-shaped bracket, a mounting perch integrated into the structure of a steering arm, or a mounting plate designed to be attached to an existing steering arm.