A light bulb or fixture design is presented with dual types of light spectra (visible and invisible UV), having economic benefits stemming from the use of a single bulb, single bulb socket, and single fixture capable of providing selection of different spectra type illumination states and other types of adjustability with a minimum of additional bulbs, additional wiring, additional fixtures and additional instruction in use.

The disclosure relates to a life prediction system for a fan of a lamp. The system comprises a fan signal detecting module to detect at least one working parameter of the fan; and a micro control unit to receive the working current signal, the environment temperature signal and the working rotation speed signal of the fan. The detecting module comprises a current detecting unit to detect a working current of the fan and output a working current signal; a temperature detecting unit to detect a working environment temperature of the fan and output an environment temperature signal; and a rotation speed detecting unit to detect and output a working rotation speed signal of the fan. The micro control unit calculates a predicted residual life of the fan based on the received working current signal, the environment temperature signal, the working rotation speed signal, through the life model of the fan.

A light emitting device configured to emit light with a total color temperature (CT.sub.tot), said light emitting device comprising at least one first light emitting diode (LED) filament, and at least one second LED filament, wherein each of the at least one first LED filament and the at least one second LED filament comprises an elongated carrier, and an array of light emitting diodes mounted on said substrate; and a controller for individually controlling said at least first LED filament and said at least one second LED filament, wherein said at least one first LED filament is arranged to emit light of a first color temperature (CT.sub.1), said first color temperature being controllable in a first color temperature range, from CT.sub.1.sup.low to CT.sub.1.sup.high, wherein said at least one second LED filament is arranged to emit light of a second color temperature (CT.sub.2), said second color temperature being controllable in a second color temperature range, from CT.sub.2.sup.low to CT.sub.2.sup.high, and wherein said controller is configured to control said total color temperature (CTtot) from a first total color temperature (CT.sub.tot,1) to a second total color temperature (CT.sub.tot,2) by controlling the first color temperature, and the second color temperature according to a preselected control scheme, such that the difference between the first color temperature and the second color temperature (ΔCT) is not constant during the change of CT.sub.tot.

A light emitting device configured to emit light with a total color temperature (CT.sub.tot), said light emitting device comprising at least one first light emitting diode (LED) filament, and at least one second LED filament, wherein each of the at least one first LED filament and the at least one second LED filament comprises an elongated carrier, and an array of light emitting diodes mounted on said substrate; and a controller for individually controlling said at least first LED filament and said at least one second LED filament, wherein said at least one first LED filament is arranged to emit light of a first color temperature (CT.sub.1), said first color temperature being controllable in a first color temperature range, from CT.sub.1.sup.low to CT.sub.1.sup.high, wherein said at least one second LED filament is arranged to emit light of a second color temperature (CT.sub.2), said second color temperature being controllable in a second color temperature range, from CT.sub.2.sup.low to CT.sub.2.sup.high, and wherein said controller is configured to control said total color temperature (CTtot) from a first total color temperature (CT.sub.tot,1) to a second total color temperature (CT.sub.tot,2) by controlling the first color temperature, and the second color temperature according to a preselected control scheme, such that the difference between the first color temperature and the second color temperature (ΔCT) is not constant during the change of CT.sub.tot.

A waterproof light-emitting diode (LED) lamp bulb, including a lamp base and a shell connected with the lamp base, and further including a stem assembly; the stem assembly is connected to an opening portion of the shell; the stem assembly includes a rubber seat, and a first metal wire, a printed circuit board (PCB) light source panel and a second metal wire which are electrically connected with each other in sequence; the rubber seat is matched with the opening portion of the shell; a filling recess is formed by the rubber seat and the opening portion of the shell; the rubber seat is further provided with at least two accommodating holes that the metal wires pass through; and a sealant layer for sealing and waterproofing is arranged at the filling recess.

A fence apparatus for handling a workpiece and resting on a support surface includes a rigid rectanguloid base, a top side of which includes a plurality of parallel guide slots. A bottom side includes at least three height-adjustable feet. A fence assembly includes an adjustable fence bracket and a fence. In some embodiments a top edge of the fence includes one of the guide slots, and the flip stop includes one of the guides for cooperating therewith to allow the flip stop to slide along the top edge of the fence. The flip stop may further include a removable pusher bar extending parallel to the fence for pushing the workpiece close to the tool. Two side L-brackets are each adapted for fixing with sides of the base and for fixing with the support surface. The fence apparatus is fully reversible from left to right.

A light-emitting device, including a shell assembly and a heat dissipation assembly. The heat dissipation assembly includes a first heat dissipation portion and a second heat dissipation portion. The first heat dissipation portion is connected with the second heat dissipation portion. The first heat dissipation portion is used to load a light source assembly, and a cavity space is formed when the second heat dissipation portion is covered by and communicated with the shell assembly. The second heat dissipation portion is provided with a first through-hole portion, and the shell assembly is provided with a second through-hole portion, the first through-hole portion and the second through-hole portion circulate a cooling medium to remove heat from the cavity space. Whether the light-emitting device is installed vertically, horizontally or at a certain inclination, a good heat dissipation effect can be achieved and the applicable scope can be greatly expanded.

Provided is an illumination device comprising a support structure and a light-emitting component being provided on one side of the support structure. The support structure also has an opening on one of its sides and an optical component cooperating with the opening to form an accommodating space. The illumination device also comprises an integrally formed light transmission portion provided above a light-emitting side of the light-emitting component. The light transmission portion is configured to transmit light from the light-emitting component. The illumination device additionally comprises a plurality of sealing portions being integrally formed.

Provided is an illumination device comprising a support structure and a light-emitting component being provided on one side of the support structure. The support structure also has an opening on one of its sides and an optical component cooperating with the opening to form an accommodating space. The illumination device also comprises an integrally formed light transmission portion provided above a light-emitting side of the light-emitting component. The light transmission portion is configured to transmit light from the light-emitting component. The illumination device additionally comprises a plurality of sealing portions being integrally formed.

The present invention discloses a highly waterproof and highly insulative simple plastic lamp bulb without a conventional lamp cap, including a lampshade, a waterproof insulation plastic lamp cap, a conductive connection piece, and a lamp core body, wherein an insertion portion is provided at the bottom of the lampshade, the lamp core body is inserted into the insertion portion, the conductive connection piece is in electrical connection with the lamp core body, the conductive connection piece is disposed on the insertion portion and then integrally injection-molded into the waterproof insulation plastic lamp cap by an injection molding machine. The production process is simplified, those conventional lamp bulbs with lamp caps of various sizes are replaced, the production costs are reduced, and the daily production volume is increased.