The present disclosure relates to a water sprayer and various features thereof. More particularly, the present disclosure relates to a water sprayer for use in a pool, and to a method for using the same. In various embodiments, the water sprayer may include a water output mechanism and a light source that is powered by flowing water to provide illumination functionality.

A clip and system for providing light to a spa feature, having a clip for holding a light emitting device and a spa feature having a housing connector, the spa feature and the housing connector being manufactured at least in part from a clear material and having a connector allowing the attachment of the clip to the spa feature, the clip having a support structure for containing and/or supporting the light emitting device and a clip connector for attaching the clip to the spa feature.

There is provided an image processing device to enable a user to experience a VR space in a floating state, the image processing device including: a wall configured to form a water storage space; and an image generating unit configured to generate a stereoscopic view image to be displayed on the wall toward an inside of the water storage space.

A method for wirelessly providing power to a LED includes: receiving an AC input voltage having a first frequency via a cable; generating a first rectified voltage at a first node from the AC input voltage, the first node coupled to a first filtering non-electrolytic capacitor; powering a driver with the first rectified voltage; wirelessly transmitting power by driving a first resonant tank with the driver with a driving voltage at a second frequency higher than the first frequency, the driving voltage having a sinusoidal envelope at the first frequency and approximating a square-wave at the second frequency; receiving the wirelessly transmitted power with a second resonant tank; generating a second rectified voltage at second node from a voltage across the second resonant tank, the second node coupled to a second filtering capacitor; generating a DC voltage from the second rectified voltage; and powering the LED with the DC voltage.

A system and method for an accent lighting system is provided. The system includes a plurality of underwater luminaires each having a plurality of light emitting diodes, and a junction box controller housing a plurality of electrical components for generating electrical signals for controlling the plurality of underwater luminaries. The junction box controller can be mounted to an electrical conduit and a plurality of cables can connect the plurality of underwater luminaires with the junction box controller. An underwater luminaire can include a heat sink and a flexible circuit board having a plurality of light emitting diodes mounted on the heat sink. The flexible circuit board transfers heat from the light emitting diodes to the heat sink. The underwater luminaire can also include a wiring harness for connecting the underwater luminaire to a cable. The underwater luminaire can also include a housing having a lens positioned at one end, an end cap mounted to an opposite end of the housing. The housing and the end cap can form a waterproof enclosure for the heatsink, the flexible circuit board, the plurality of light emitting diodes, and the wiring harness.

An ornamental chlorine float assembly for chlorinating a swimming pool includes a chlorine float that is floatable in a swimming pool. The chlorine float is structured to have a variety of pre-determined ornamental features to enhance visual appeal of the chlorine float when the chlorine float is floating in the swimming pool. A plurality of light emitters is each of the light emitters is coupled to the bottom side of the chlorine float to illuminate the water in the swimming pool. A plurality of speakers is each coupled to the top side of the chlorine float to emit sound outwardly therefrom.

An underwater lamp with improved light distribution for underwater applications. The underwater lamp includes a circuit trace having non-coplanar circuit segments, LEDs mounted on the non-coplanar circuit segments so as to emit light in nonparallel directions, and a lens. The lens includes lens portions aligned with the LEDs on the circuit trace circuit segments. The lens may be a thermoplastic material encapsulating the LEDs and the circuit trace.

Nicheless lighting assemblies principally for swimming pools and spa are detailed. The lighting assemblies include features configured to dissipate heat. The assemblies additionally are designed to reduce possibility of water intrusion. Some versions of the assemblies may include thermally-conductive plastic overmolded onto at least one of a lens or a heat spreader. Versions of the assemblies additionally or alternatively may include a generally annular heat sink to which a printed circuit board containing at least one light-emitting diode (LED) is attached. Versions of the assemblies may be divided into subassemblies, one subassembly fitting into another, or include protective covers.

A LED lighting device (80) is installable on a standard wall fitting (10). The LED lighting device (80) includes an inductive power transmitter (84) including a housing (146), a tee top (112) on the housing (146) including a flat inductive power transfer face (120), and an inductive transmitter coil (154) located within the tee top (112). A LED lamp module (86) of the LED lighting device (80) includes a LED lamp body (184) containing one or more LEDs (180), a threaded male portion (131) formed on the LED lamp body (184) and shaped to threadably engage the standard wall fitting (10), an inductive power receiver pad (132) located adjacent a flat surface (120) of the threaded male portion (131), and an inductive power receiver coil (166) located in the LED lamp body (184). When the LED lighting device (80) is installed on the standard wall fitting (10), the LED lamp module (86) is wirelessly powered by the inductive power transmitter (84).

A lighting system includes a light fixture assembly having a lower housing portion enclosing LED light circuitry, a rechargeable battery, a wireless communications module, and a system controller, and an upper housing portion enclosing a wireless charging receiver, a communication antenna, and a first set of magnets. A wireless charging assembly includes a wireless charging transmitter connected to a power source and a second set of magnets configured to releasably adhere to the first set of magnets to hold the charger housing against the fixture housing for charging. A wireless remote control application is used to control the lights within the fixture.