Compact light devices are described herein that are advantageously configured to be secured to a surface in order to provide inexpensive lighting forwardly therefrom. The compact light devices can include on and off configurations in order to preserve battery life and allow a user to selectively energize the light source.

A large plurality of artificial, battery-operated, electronic candles are arranged to be simultaneously recharged upon placement on a series of interconnected charging trays that include a transformer primary winding at defined locations thereon. The primary windings are driven by an AC signal whose duty cycle is controlled by a pulse width modulator 1C to induce a voltage across secondary windings contained within the candle housing. This induced signal is rectified to produce the battery charging current and the delivery of the charging current to the rechargeable batteries is controlled by a microprocessor 1C.

According to an embodiment of the present invention, a recharging device includes a recharging port that receives a flameless candle and recharges a battery in the candle. The recharging device includes a first stacking structure that has a top portion and a bottom portion. There is a top stacking contact on the top portion. An electrical power bus is connected with the top stacking contact. The electrical power bus is also configured to provide electrical power to the flameless candle through the recharging port. The top portion of the first stacking structure is configured to mate with a bottom portion of a first stacking structure of another recharging device.

An electronic candle includes a housing, an LED light source, a battery, and one or more sensors to detect a blow of air or a tilt of the electronic candle. The electronic candle further includes a microprocessor that is coupled to the LED light source, to the blow sensor and to the tilt sensor. The microprocessor is programmed to control illumination produced by the LED light source, to receive signals indicative of the detection of a blow, and to detect a tilt of the electronic candle.

An electronic candle includes a housing, an LED light source, a battery, and one or more sensors to detect a blow of air or a tilt of the electronic candle. The electronic candle further includes a microprocessor that is coupled to the LED light source, to the blow sensor and to the tilt sensor. The microprocessor is programmed to control illumination produced by the LED light source, to receive signals indicative of the detection of a blow, and to detect a tilt of the electronic candle.

Compact light devices are described herein that are advantageously configured to be secured to a surface in order to provide inexpensive lighting forwardly therefrom. The compact light devices can include on and off configurations in order to preserve battery life and allow a user to selectively energize the light source.

A large plurality of artificial, battery-operated, electronic candles are arranged to be simultaneously recharged upon placement on a series of interconnected charging trays that include a transformer primary winding at defined locations thereon. The primary windings are driven by an AC signal whose duty cycle is controlled by a pulse width modulator IC to induce a voltage across secondary windings contained within the candle housing. This induced signal is rectified to produce the battery charging current and the delivery of the charging current to the rechargeable batteries is controlled by a microprocessor IC.

A large plurality of artificial, battery-operated, electronic candles are arranged to be simultaneously recharged upon placement on a series of interconnected charging trays that include a transformer primary winding at defined locations thereon. The primary windings are driven by an AC signal whose duty cycle is controlled by a pulse width modulator IC to induce a voltage across secondary windings contained within the candle housing. This induced signal is rectified to produce the battery charging current and the delivery of the charging current to the rechargeable batteries is controlled by a microprocessor IC.

According to an embodiment of the present invention, a recharging device includes a recharging port that receives a flameless candle and recharges a battery in the candle. The recharging device includes a first stacking structure that has a top portion and a bottom portion. There is a top stacking contact on the top portion. An electrical power bus is connected with the top stacking contact. The electrical power bus is also configured to provide electrical power to the flameless candle through the recharging port. The top portion of the first stacking structure is configured to mate with a bottom portion of a first stacking structure of another recharging device.

According to an embodiment of the present invention, a recharging device includes a recharging port that receives a flameless candle and recharges a battery in the candle. The recharging device includes a first stacking structure that has a top portion and a bottom portion. There is a top stacking contact on the top portion. An electrical power bus is connected with the top stacking contact. The electrical power bus is also configured to provide electrical power to the flameless candle through the recharging port. The top portion of the first stacking structure is configured to mate with a bottom portion of a first stacking structure of another recharging device.