A waterproof power plug includes a mounting frame, first and second conductive terminals, a fuse, and a fuse cover which are mounted inside the mounting frame. The fuse is electrically connected to the second conductive terminal. The mounting frame is provided with a mounting groove for exposing the fuse, and the fuse cover is mounted in the mounting groove to cover or expose the fuse. The power plug further includes a housing opened with a window for slidably operating the fuse cover, and a waterproof cover is mounted in the window. Therefore, the fuse cover is arranged on the mounting groove and the waterproof cover is further covered on the fuse cover, which provides multiple waterproof protections. The power plug has a good sealing performance and waterproof performance, which also helps to improve the overall waterproof performance and work safety of the string light with the power plug.

A lighted accessory and/or corresponding method of installation seamlessly replace an original equipment manufacturer (OEM) lighting apparatus and/or accessory. The accessory includes a front side and back side with a circuit board positioned therebetween. One side of the accessory includes translucent portion(s). The circuit board includes a plurality of light emitting diodes (LEDs) which are aligned with the translucent portion of the front side of the accessory such that when the LEDs are illuminated, light is emitted from the accessory. The circuit board also includes at least one microcontroller and a radio-frequency interference filter circuit wherein the microcontroller controls the LEDs and the radio-frequency interference filter circuit mitigates RF emissions.

A lighted accessory and/or corresponding method of installation seamlessly replace an original equipment manufacturer (OEM) lighting apparatus and/or accessory. The accessory includes a front side and back side with a circuit board positioned therebetween. One side of the accessory includes translucent portion(s). The circuit board includes a plurality of light emitting diodes (LEDs) which are aligned with the translucent portion of the front side of the accessory such that when the LEDs are illuminated, light is emitted from the accessory. The circuit board also includes at least one microcontroller and a radio-frequency interference filter circuit wherein the microcontroller controls the LEDs and the radio-frequency interference filter circuit mitigates RF emissions.

A lighting apparatus includes a wireless circuit board, a driver circuit board, a light source plate, a metal cover and a metal housing. The wireless circuit board is mounted with a wireless circuit. The wireless circuit has a first reference ground terminal. The driver circuit board is mounted with a driver circuit. The driver circuit has a second reference ground terminal. The light source plate is mounted with a LED module. The light source plate is placed on a top side of the metal cover. The first reference ground terminal and the second reference ground terminal are connected to the metal cover as a reference ground. The metal housing and a bottom side of the metal cover forms a container space for holding the driver circuit board and a first portion of the wireless circuit board.

A lighting apparatus includes a wireless circuit board, a driver circuit board, a light source plate, a metal cover and a metal housing. The wireless circuit board is mounted with a wireless circuit. The wireless circuit has a first reference ground terminal. The driver circuit board is mounted with a driver circuit. The driver circuit has a second reference ground terminal. The light source plate is mounted with a LED module. The light source plate is placed on a top side of the metal cover. The first reference ground terminal and the second reference ground terminal are connected to the metal cover as a reference ground. The metal housing and a bottom side of the metal cover forms a container space for holding the driver circuit board and a first portion of the wireless circuit board.

A luminaire (10) is disclosed with built-in surge protection. The luminaire comprises an electrically conductive structure including a carrier (11) carrying at least one active circuit component (15, 16) and a shielding element (13) at least partially covering the carrier inside a housing, a set of active conductors (17, 19) connected to the active circuit component for connecting the active circuit component to a mains supply including a neutral (N) and live (L) terminal, wherein one of said terminals is further connected to the shielding element by a connection (19′) bypassing the at least one active circuit. The housing comprises a cover (21) over the electrically conductive structure, wherein the shielding element defines a clearance (25) between the electrically conductive structure and the cover, said clearance comprising a pinch point (27) between the shielding element and the cover.

A luminaire (10) is disclosed with built-in surge protection. The luminaire comprises an electrically conductive structure including a carrier (11) carrying at least one active circuit component (15, 16) and a shielding element (13) at least partially covering the carrier inside a housing, a set of active conductors (17, 19) connected to the active circuit component for connecting the active circuit component to a mains supply including a neutral (N) and live (L) terminal, wherein one of said terminals is further connected to the shielding element by a connection (19′) bypassing the at least one active circuit. The housing comprises a cover (21) over the electrically conductive structure, wherein the shielding element defines a clearance (25) between the electrically conductive structure and the cover, said clearance comprising a pinch point (27) between the shielding element and the cover.

A submersible light fixture including an outer casing with a window and a housing, the outer casing being sealed for operation underwater, an LED array within the outer casing behind the window including a plurality of light-emitting diodes, and a driver within the outer casing including a microprocessor, at least one capacitor, a charging circuit, and discharging circuit. The charging circuit charges the at least one capacitor to a voltage of at least two times a forward voltage of the LED array. The discharging circuit delivers power from the at least one capacitor to the LED array in discrete pulses at a voltage of at least two times the forward voltage of the LED array.

A submersible light fixture including an outer casing with a window and a housing, the outer casing being sealed for operation underwater, an LED array within the outer casing behind the window including a plurality of light-emitting diodes, and a driver within the outer casing including a microprocessor, at least one capacitor, a charging circuit, and discharging circuit. The charging circuit charges the at least one capacitor to a voltage of at least two times a forward voltage of the LED array. The discharging circuit delivers power from the at least one capacitor to the LED array in discrete pulses at a voltage of at least two times the forward voltage of the LED array.

A lighting system includes an LED downlight mountable to a ceiling, a driver, and an insulation displacement connector (IDC). Light from the downlight can be faced downward to project light or upward to reflect light off of the ceiling. The driver has an input with a first voltage and an output with a second voltage, the second voltage being lower than the first and being provided through a wire system extending from the LED driver. The IDC connects the downlight to the wire system. The lighting system can be changed from a first to a second configuration by at least one of adding an additional downlight using a corresponding MC or removing an existing downlight using a corresponding IDC. The second configuration does not significantly affect a desired output range of light from any downlight or any LED circuit of any downlight that remains or preexists from the first configuration.