A solar powered charging station uses photovoltaic panels to generate electrical energy for use directly and/or for storage in electrical batteries for use during night operation. The station includes parallel electrical circuits which permit the station to operate during daylight hours in the event of a failure of the battery or the battery charging system. The station is adapted to use stabilizing ballast which can be collected locally at the site of the station. The parallel circuitry is adaptable for use with other forms of electrical power generation having a minimal carbon footprint.

A wireless power transfer pad for wireless charging of a vehicle electrical storage system. The wireless power transfer pad includes an oscillating electromagnetic field generating device configured for transmitting energy to a wireless power receiver associated with the vehicle. The pad further includes a foreign object detection arrangement including a plurality of foreign object detection coils. The solar panel arrangement includes a photovoltaic substrate with a front side and a rear side, a front side electrode arrangement and a rear side electrode arrangement. The foreign object detection coils are configured to function also as the front side electrode arrangement.

A wireless power transfer pad for wireless charging of a vehicle electrical storage system. The wireless power transfer pad includes an oscillating electromagnetic field generating device configured for transmitting energy to a wireless power receiver associated with the vehicle. The pad further includes a foreign object detection arrangement including a plurality of foreign object detection coils. The solar panel arrangement includes a photovoltaic substrate with a front side and a rear side, a front side electrode arrangement and a rear side electrode arrangement. The foreign object detection coils are configured to function also as the front side electrode arrangement.

An automatic system for providing full body shower with round the body cleaning to a user is illustrated. The automatic system includes a solid supporting unit with horizontal and vertical frames. A primary cleaning unit and a secondary cleaning unit are provided for the cleaning of the head portion and the body surface of a user. The first horizontal frame and the secondary cleaning unit are configured with vertical upward and downward movement along the vertical frame using an elevating means. Each of the primary and secondary cleaning units comprises a plurality of nozzles, brushes and ultraviolet (UV) light sources. An air dryer chamber propelling dry air for drying the wet body and head portion of the user is utilized. The automatic shower system can also be used in the horizontal orientation.

Aspects of the present disclosure are presented for a multi-purpose robot. In certain implementations, the robot of the present disclosure can initiate performance of one or more tasks. Aspect(s) of the power consumption of the robot can be monitored. Input(s) originating from sensor(s) of the robot can be received. Based on the aspect(s) of the power consumption of the robot and input(s) originating from the sensor(s), aspect(s) of the performance of the one or more tasks can be adjusted.

Aspects of the present disclosure are presented for a multi-purpose robot. In certain implementations, the robot of the present disclosure can initiate performance of one or more tasks. Aspect(s) of the power consumption of the robot can be monitored. Input(s) originating from sensor(s) of the robot can be received. Based on the aspect(s) of the power consumption of the robot and input(s) originating from the sensor(s), aspect(s) of the performance of the one or more tasks can be adjusted.

An energy harvesting vehicle includes a plurality of vehicular panels, and an energy canopy. The energy canopy is connected to at least two of the plurality of vehicular panels configured for generating electrical energy. The energy canopy includes a predetermined number of surfaces configured for receiving incident light, the incident light being received for a plurality of time durations. At least one of the predetermined number of surfaces includes a solar unit configured for harvesting the incident light. A predetermined number of solar units are positioned on a portion of the predetermined number of surfaces. The predetermined number of surfaces are connected in one of a series connection and a parallel connection with each other. The one of the series connection and the parallel connection between the predetermined number of surfaces are configured for improving an energy conversion efficiency of the energy canopy, through enhanced harvesting of the incident light.

An energy harvesting vehicle includes a plurality of vehicular panels, and an energy canopy. The energy canopy is connected to at least two of the plurality of vehicular panels configured for generating electrical energy. The energy canopy includes a predetermined number of surfaces configured for receiving incident light, the incident light being received for a plurality of time durations. At least one of the predetermined number of surfaces includes a solar unit configured for harvesting the incident light. A predetermined number of solar units are positioned on a portion of the predetermined number of surfaces. The predetermined number of surfaces are connected in one of a series connection and a parallel connection with each other. The one of the series connection and the parallel connection between the predetermined number of surfaces are configured for improving an energy conversion efficiency of the energy canopy, through enhanced harvesting of the incident light.

Method of installation of a PV array with planar PV modules of square/rectangular configuration, each module defining square/rectangular edge and comprising a pair of parallel end and side edges, the modules being connected along adjacent end edges and foldable relative to each other about the connected end edges between a closed condition and an open condition, whereby in the closed condition, the modules are stacked together on a movable carriage on which the modules can be transported, the modules comprising a leading module, a trailing module and two or more intermediate modules, and in the open condition, the modules are laterally displaced from the closed condition about the end edge connections to collect electromagnetic radiation, the method including securing the leading module and moving the carriage relative to the leading module so that the carriage moves away from the leading module, allowing the PV array to unfold from the carriage.

Method of installation of a PV array with planar PV modules of square/rectangular configuration, each module defining square/rectangular edge and comprising a pair of parallel end and side edges, the modules being connected along adjacent end edges and foldable relative to each other about the connected end edges between a closed condition and an open condition, whereby in the closed condition, the modules are stacked together on a movable carriage on which the modules can be transported, the modules comprising a leading module, a trailing module and two or more intermediate modules, and in the open condition, the modules are laterally displaced from the closed condition about the end edge connections to collect electromagnetic radiation, the method including securing the leading module and moving the carriage relative to the leading module so that the carriage moves away from the leading module, allowing the PV array to unfold from the carriage.