An intelligent shading charging system, comprises a housing having a rechargeable battery installed therein, a lower support assembly connected to the housing and an upper support assembly, the upper support assembly comprising one or more arm support assemblies. The intelligent shading charging system further comprises a hinging assembly connecting a lower support assembly to an upper support assembly to allow an upper support assembly to rotate with respect to the lower support assembly, one or more arms connected to the one or more are support assemblies, a shading fabric; and one or more solar cell arrays mounted on or integrated within the shading fabric.

A lighting system has a power source formed by a solar panel and a battery assembly, a lighting assembly having a plurality of lighting devices arranged into a plurality of lighting groups, the light assembly having a predetermined maximum power, and a multiple-input power converter electrically coupled to the power source and the lighting assembly for powering the lighting assembly using the power source, and for charging the battery assembly using the solar panel. The multiple-input power converter is configured for calculating a power upper-bound based on the level of stored energy in the battery assembly and the length of a night time, and selecting at least a subset of the lighting groups and powering the selected lighting groups for illumination using the battery assembly for preventing exhausting the stored energy of the battery assembly before the battery assembly can be charged by the solar panel.

An intelligent umbrella includes an array of solar panels/cells for capturing sunlight and converting into electrical energy, a solar panel charging assembly to receive power from one or more solar assemblies, a rechargeable battery to receive power generated from the solar panel charging assembly, and a processor and a memory, the processor and the memory to receive power from the rechargeable battery; and a wireless transceiver to receive power from the rechargeable battery, the wireless transceiver to communicate messages and/or signals when no external power source is connected to and/or available for the intelligent umbrella. The intelligent umbrella may further comprise a cellular transceiver to receive power from the rechargeable battery, the cellular transceiver to communicate messages and/or signals when no external power source is connected to and/or available to supply power for the intelligent umbrella.

An intelligent umbrella includes an array of solar panels/cells for capturing sunlight and converting into electrical energy, a solar panel charging assembly to receive power from one or more solar assemblies, a rechargeable battery to receive power generated from the solar panel charging assembly, and a processor and a memory, the processor and the memory to receive power from the rechargeable battery; and a wireless transceiver to receive power from the rechargeable battery, the wireless transceiver to communicate messages and/or signals when no external power source is connected to and/or available for the intelligent umbrella. The intelligent umbrella may further comprise a cellular transceiver to receive power from the rechargeable battery, the cellular transceiver to communicate messages and/or signals when no external power source is connected to and/or available to supply power for the intelligent umbrella.

A decorative lawn ornament including a rotatable carrier having a plurality of blades. At least one light-emitting device is arranged on each of the plurality of blades to emit light from the blades. A solar panel is provided to receive and collect sunlight, and a photoswitch is automatically operable between an activated state during instances of insufficient sunlight to thereby activate the light-emitting device, and a deactivated state during instances of sunlight to thereby deactivate the light-emitting device. The decorative lawn ornament is operable such that when a flow of air strikes it, the blades rotate and a decorative member rotates to control an orientation of the blades and the light emitted by the light-emitting devices.

A decorative lawn ornament including a rotatable carrier having a plurality of blades. At least one light-emitting device is arranged on each of the plurality of blades to emit light from the blades. A solar panel is provided to receive and collect sunlight, and a photoswitch is automatically operable between an activated state during instances of insufficient sunlight to thereby activate the light-emitting device, and a deactivated state during instances of sunlight to thereby deactivate the light-emitting device. The decorative lawn ornament is operable such that when a flow of air strikes it, the blades rotate and a decorative member rotates to control an orientation of the blades and the light emitted by the light-emitting devices.

Aspects of the present disclosure relate to a bird bath. In one configuration, a frame as a plurality lighting elements therein. A stand is provided for supporting the frame. The bath may include a control component for controlling the lighting elements and a photovoltaic cell for providing power to the lighting elements. In another aspect, the frame may include a plurality of spiral frame members. In yet another aspect, the spiral members have a channel pathway and the lighting elements are disposed in the channel pathway. In yet another aspect, the frame may includes a plurality of radial members. In yet another aspect, the radial members have a channel pathway and the lighting elements are disposed in the channel pathway.

Aspects of the present disclosure relate to a bird bath. In one configuration, a frame as a plurality lighting elements therein. A stand is provided for supporting the frame. The bath may include a control component for controlling the lighting elements and a photovoltaic cell for providing power to the lighting elements. In another aspect, the frame may include a plurality of spiral frame members. In yet another aspect, the spiral members have a channel pathway and the lighting elements are disposed in the channel pathway. In yet another aspect, the frame may includes a plurality of radial members. In yet another aspect, the radial members have a channel pathway and the lighting elements are disposed in the channel pathway.

A beacon device to be installed on a tower, the device including: an electric energy generating unit comprising: at least one photovoltaic module able to be wound over at least part of the circumference of the tower, and a light energy generating unit configured to be fastened on the tower the light energy generating unit comprising: a housing having a periphery, a storage member storing the electric energy generated by the electric energy generating unit, a regulating member regulating the charge of the storage member, and a light-emitting member supplied by the storage member, the light-emitting member extending over the periphery of the housing.

An inflatable solar-powered light is provided. The solar-powered light includes a bladder and a solar-powered light assembly disposed entirely within the bladder. The solar-powered light assembly includes a solar panel, a rechargeable battery in electrical communication with the solar panel, and at least one light-emitting diode in electrical communication with the rechargeable battery. The bladder is substantially transparent, flexible, inflatable, and collapsible.