An improved light assembly includes aligned directional light sources mounted one behind another. A distal one of the light sources occludes light emitted from a proximal one of the light sources. A reflector is interposed between the light sources, with a convex surface facing the proximal one of the light sources. Thus, the light assembly projects a light field extending at least through an 180 hemisphere, and up to about 270 backwards from the forward orientation of the light field, well-illuminating lateral approaches to the assembly.

A light tower assembly configured to rotate a light section from a first to a second position. In various embodiments, the light tower assembly comprises (a) a primary boom extending vertically from a base, (b) a light array boom supporting a light section on a frame rotatively mounted to the primary boom wherein the light array boom rotates around an axis of rotation, (c) a mounting assembly rotatively mounting the light array boom to the primary boom, and (d) a linear actuator assembly connected to the primary boom and the light array boom being configured to rotate the light array boom in one direction when the linear actuator extends and configured to rotate the light array boom in an opposite direction when the linear actuator assembly retracts.

Disclosed is an illuminated flag including a flag, a first layer of the flag, a second layer of the flag, a light disposed between the first layer of the flag and a second layer of the flag, a flag clamp, and a wire extending from the light and into an interior space of the flagpole.

Disclosed is an illuminated flag including a flag, a first layer of the flag, a second layer of the flag, a light disposed between the first layer of the flag and a second layer of the flag, a flag clamp, and a wire extending from the light and into an interior space of the flagpole.

Lighting strip system (1) which extends along a longitudinal axis direction (L) and has the following: an elongated carrier profile (2) with two elongated side walls (21, 22) that face each other and an elongated base wall (20) connecting the side walls (21, 22), which together delimit a receiving space (A), a first and a second mechanical coupling region (3, 4), wherein the first coupling region (3) is provided between the base wall (20) and the second coupling region (4) as viewed in the longitudinal axis direction (L), an elongated power supply unit (5) which extends in the longitudinal axis direction (L) in the receiving space (A), a lighting strip lamp (6) which extends in the longitudinal axis direction (L), is electrically contacted with the power supply unit (5) and is releasably mechanically coupled to the second coupling region (4), and an electrical or electronic unit (7) with a functional region (73) and an operating region (74), wherein the functional region (73) is arranged adjacent to the lighting strip lamp (6) in the longitudinal axis direction (L), and wherein the operating region (74) extends starting from the functional region (73) at least partially between the lighting strip lamp (6) and the base wall (20), is electrically contacted with the power supply unit (5) and is releasably mechanically coupled to the first coupling region (3). Alternatively, the first coupling region (3) is provided on the side of one of the side walls (21) and the second coupling region (4) is provided on the side of the other of the side walls (22) as viewed in the longitudinal axis direction (L). In this case, the lighting strip lamp (6) and the unit (7) are both releasably mechanically coupled to the coupling regions (3, 4).

Lighting strip system (1) which extends along a longitudinal axis direction (L) and has the following: an elongated carrier profile (2) with two elongated side walls (21, 22) that face each other and an elongated base wall (20) connecting the side walls (21, 22), which together delimit a receiving space (A), a first and a second mechanical coupling region (3, 4), wherein the first coupling region (3) is provided between the base wall (20) and the second coupling region (4) as viewed in the longitudinal axis direction (L), an elongated power supply unit (5) which extends in the longitudinal axis direction (L) in the receiving space (A), a lighting strip lamp (6) which extends in the longitudinal axis direction (L), is electrically contacted with the power supply unit (5) and is releasably mechanically coupled to the second coupling region (4), and an electrical or electronic unit (7) with a functional region (73) and an operating region (74), wherein the functional region (73) is arranged adjacent to the lighting strip lamp (6) in the longitudinal axis direction (L), and wherein the operating region (74) extends starting from the functional region (73) at least partially between the lighting strip lamp (6) and the base wall (20), is electrically contacted with the power supply unit (5) and is releasably mechanically coupled to the first coupling region (3). Alternatively, the first coupling region (3) is provided on the side of one of the side walls (21) and the second coupling region (4) is provided on the side of the other of the side walls (22) as viewed in the longitudinal axis direction (L). In this case, the lighting strip lamp (6) and the unit (7) are both releasably mechanically coupled to the coupling regions (3, 4).

A streetlight device includes a power source portion and a lighting portion. The power source portion includes a driving power source, a power source base provided with a receiving space for receiving the driving power source, and a power source upper cover for closing the power source base. The lighting portion is connected at one end of the power source upper cover. The power source upper cover and the power source base are connected with each other through a hinge assembly. The power source upper cover is provided with a power source mounting assembly, and the driving power source is mounted onto the power source upper cover through the power source mounting assembly.

An aiming device is provided including a body, an optical element joined with the body that has selectively displayed thereon a dot visible to a user along a first line of viewing, and a power indicator distal from the optical element, where the power indicator emits illumination along a second line of viewing, offset from the first line of viewing. The power indicator can alert the user via the illumination that the dot is or is not displayed on the optical element, without the user needing to directly view the dot along the first line of viewing. The illumination emitted by the power indicator can be of a first visible wavelength range, e.g., blue, and the dot can illuminate in a second visible wavelength range different from the first visible wavelength range, e.g., green or red, so the likelihood of confusing the power indicator with the dot can be reduced.

The present invention relates to a marine structure comprising an external surface (50), a load (2, 20, 21, 22, 25) comprising a light source, said load having a first load terminal (2a) and a second load terminal (2b) adapted to be powered by an AC power source (1), said AC power source (1) having a first AC terminal (1a) electrically connectable to the surface (50) and a second AC terminal (1b), a first electrode (3) electrically connected to the first load terminal (2a), and a dielectric layer (4). The first electrode (3) and the dielectric layer (4) are arranged to form, in combination with the surface (50), a capacitor (6) for capacitive transmission of electrical power between the first electrode (3) and the surface (50). The second AC terminal (1b) and the second load terminal (2b) are arranged to be electrically connected to an external electrically conductive element (10, 11) insulated from the surface (50). The first load terminal (2a) is electrically insulated from the second load terminal (2b).

The present invention relates to a marine structure comprising an external surface (50), a load (2, 20, 21, 22, 25) comprising a light source, said load having a first load terminal (2a) and a second load terminal (2b) adapted to be powered by an AC power source (1), said AC power source (1) having a first AC terminal (1a) electrically connectable to the surface (50) and a second AC terminal (1b), a first electrode (3) electrically connected to the first load terminal (2a), and a dielectric layer (4). The first electrode (3) and the dielectric layer (4) are arranged to form, in combination with the surface (50), a capacitor (6) for capacitive transmission of electrical power between the first electrode (3) and the surface (50). The second AC terminal (1b) and the second load terminal (2b) are arranged to be electrically connected to an external electrically conductive element (10, 11) insulated from the surface (50). The first load terminal (2a) is electrically insulated from the second load terminal (2b).