Aspects relate to a charging station configured to transfer power between an electric aircraft and a power grid via a charging connection. In one or more embodiments, charging station may communicate with the power grid and/or electric aircraft via a communication network. For example, the charging station may be configured to receive a supply request from a power grid or a demand request from an electric aircraft and subsequently generate a control signal that transfers electrical power between the power grid and the electric aircraft via the charging connection.

A control system and apparatus for managing charging of electric vehicles in a transportation infrastructure and controlling at least the flight paths for drone-assisted vehicles requiring periodic charge comprises a transportation system control node connected in a first wide area network (WAN), a plurality of vehicle charging facilities distributed within the geographic region covered by the first wide area network and a charge controller connected to each of the plurality of charging facilities for brokering electric power from a power source to at least one structurally supported charge transfer apparatus maintained at each of the charging facilities.

A control system and apparatus for managing charging of electric vehicles in a transportation infrastructure and controlling at least the flight paths for drone-assisted vehicles requiring periodic charge comprises a transportation system control node connected in a first wide area network (WAN), a plurality of vehicle charging facilities distributed within the geographic region covered by the first wide area network and a charge controller connected to each of the plurality of charging facilities for brokering electric power from a power source to at least one structurally supported charge transfer apparatus maintained at each of the charging facilities.

The invention includes a Microprocessor Control Center for controlling an Electric Vehicle Charging Station, and methods thereof, which include a load center for aggregating a charging load from a renewable energy source, a battery stored energy source, and electricity taken directly from the transmission grid when the battery storage depleted. The objective of the system is to maximize the use of the renewable energy source which is used directly and at first priority. The use of an energy storage system prevents local brown-outs which can occur when large amounts of electricity is quickly removed from the grid. The energy storage system is recharged from the grid off-peak when rates and house-hold usage are lowest. In a preferred embodiment, the renewable source is solar power, in other embodiments the renewable source can be wind, tidal and biomass. The solar panels are located on the weather canopy roof at petroleum retail fueling sites.

The invention includes a Microprocessor Control Center for controlling an Electric Vehicle Charging Station, and methods thereof, which include a load center for aggregating a charging load from a renewable energy source, a battery stored energy source, and electricity taken directly from the transmission grid when the battery storage depleted. The objective of the system is to maximize the use of the renewable energy source which is used directly and at first priority. The use of an energy storage system prevents local brown-outs which can occur when large amounts of electricity is quickly removed from the grid. The energy storage system is recharged from the grid off-peak when rates and house-hold usage are lowest. In a preferred embodiment, the renewable source is solar power, in other embodiments the renewable source can be wind, tidal and biomass. The solar panels are located on the weather canopy roof at petroleum retail fueling sites.

An energy storage system for a military vehicle includes a lower support, a battery supported on the lower support, a bracket coupled to the battery, and an upper isolator mount coupled between the bracket and a wall. The upper isolator mount is configured to provide front-to-back vibration isolation of the battery relative to the wall.

An energy storage system for a military vehicle includes a lower support, a battery supported on the lower support, a bracket coupled to the battery, and an upper isolator mount coupled between the bracket and a wall. The upper isolator mount is configured to provide front-to-back vibration isolation of the battery relative to the wall.

The present invention relates to a method for reporting an electric car charging space in a parking lot, the method comprising: identifying whether a charger of each of charging spaces in a parking lot is being used; identifying whether a car exists in each of the charging spaces; and selecting a chargeable space and reporting the selected chargeable space.

The present invention relates to a method for reporting an electric car charging space in a parking lot, the method comprising: identifying whether a charger of each of charging spaces in a parking lot is being used; identifying whether a car exists in each of the charging spaces; and selecting a chargeable space and reporting the selected chargeable space.

A distributed charging system (1) comprising a plurality of charging stations (2) transportable by charging station transport trucks (3), wherein each charging station transport truck (3) of the distributed charging system (1) has at least one lifting mechanism (4) adapted to lift at least one charging station (2) deployed on a ground floor onto a transport platform (3A) of the charging station transport unit (3) for transport to another location, wherein each transportable charging station (2) has at least one battery pack (2D) with rechargeable battery cells adapted to store electrical energy which is used to charge batteries of electrically powered vehicles (6) connected to charging stations (2) deployed on the ground floor, wherein the housing (2A) of the portable charging station (2) comprises a ground locking interface unit (2C) adapted to lock the charging station (2) mechanically and/or electrically to a base frame (5) of the distributed charging system (1) installed on the ground floor.