A transport refrigeration unit includes at least one airfoil (88) and an energy conversion device (90) attached to the at least one airfoil. The at least one airfoil is adapted to mechanically drive the energy conversion device upon exposure to wind (105). The energy conversion device is constructed to convert mechanical energy to electrical energy, and the electrical energy is used, at least in-part, to charge the battery (52). An isolation relay (108) is controlled by the controller (82). A capacitor bank (110) and a rectifier (112) are provided.

A method of operating a multiple energy source of a transport refrigeration unit determines if the transport refrigeration unit is at idle. The method may then electrically switch a condenser fan motor from an electrical power source to a battery charging circuit. The condenser fan motor may be back-driven via wind blowing through a condenser fan. Electrical power is thereby generated and applied to charge a battery via a battery charging circuit.

An on-board vehicle battery charging system and method. The system includes a vehicle with a wind turbine operably attached thereto and configured to charge a battery of the vehicle. The wind turbine is configured to rotate with a wind or an airflow, for example, when the vehicle is in motion. A shaft of the wind turbine is operably connected to an electric generator configured to generate an electrical charge upon a rotation of the shaft, thereby charging the battery of the vehicle and extending an operating range of the vehicle.

A device includes a microprocessor and a computer readable medium coupled to the microprocessor. The computer readable medium includes instructions stored thereon that cause the microprocessor to receive output from at least one sensor monitoring an interior space of a vehicle and determine, based on the received output, a condition of an occupant in the interior space of the vehicle. The instructions cause the microprocessor to determine, based on the determined condition of the occupant, to alter a first presentation of information displayed to a display device of the vehicle to a second presentation of the information displayed to the display device. The instructions case the microprocessor to render the second presentation of the information to the display device of the vehicle to replace the first presentation of the information displayed to the display device of the vehicle.

The present invention relates to a self-power generation-type electric bike, and particularly, to a self-power generation-type electric bike which can be applied to an electric bike (an electric bicycle, an electric motorcycle, an electric kick scooter, etc.) to generate air during travel, and use the air to produce electricity and travel for long periods of time without being charged.

A wind-powered electric vehicle power regeneration system for increasing the range of electric vehicles. The system includes a twin turbine system with at least one fan on each turbine, and may include a vacuum-assisted turbine and gearbox. The twin turbine system preferably has three fans on each turbine. The fans may be of various sizes. The first and largest fan may be directly powered via the electric vehicle motor, which may create a vacuum. The second fan may partially be powered by the EV motor, while also being moved by the vacuums suction and the air that enters the compartment. The third fan may rotate via force of air entering the compartment. All of the fans may be connected to a central gearbox located beneath them. The gearbox may be connected to a generator that may be connected to a capacitor that charges an electric vehicle's battery.

A vehicle is provided that detects a first presence of a driver in a vehicle, based upon detecting the first presence, provides a user interface for the driver to enter first user information, information, and communicates the first sensitive information to a vendor to authenticate the combines the first user information and the vehicle information to generate the first sensitive driver to enable the vendor to perform a financial transaction with the driver using the first sensitive information while the vehicle is in motion. The processor is programmed to initiate automatically, on behalf of the driver, the financial transaction with the vendor in response to a sensed state or location of the vehicle.

A vehicle, based on user preferences and while the vehicle is in motion: in response to identification of a first event (e.g., a third party resident being in a vehicle location and/or on the route of the vehicle) and based on the user preferences, determines that the user desires to perform a transaction with the third party, automatically sends a first communication to the third party for the user (the first communication being part of a secure session and enabling authentication of the user by the third party), at a second later time and while the vehicle is in motion, and in response to identification of a second event, automatically sends a different second communication to the third party. The second communication is part of the secure session and enables the third party to complete the transaction with the user.

A vehicle is provided that determines a need for communication with a third party vendor, retrieves the user rule from the memory (the user rule defining to which third party vendor the vehicle can send a first communication to address the need and defining a geographic location of the third party vendor relative to a current location of the vehicle, a monetary amount the vehicle can pay to a third party vendor for a product or service to address the need, and a time limit for the third party vendor to provide the product or service to address the need), based on the user rule, selects a third party vendor from among multiple possible third party vendors, and when determined by the user rule, automatically sends the first communication to the selected third party vendor to order the product or service and provides an authorization to the selected third party vendor to complete the order. The vehicle uses different communication protocols to provide the first communication and authorization to the selected third party vendor.

An aero wind power generation apparatus includes: a drone unit including drone wings configured to make the aero wind power generation apparatus move and hover and a sensor unit configured to detect information for controlling the aero wind power generation apparatus; a buoyancy generation unit connected to the drone unit and including a side cover configured to open or close and a balloon provided inside the side cover, wherein the buoyancy generation unit is configured to enable injection of gas into or release of the gas from the balloon; and a power generation unit connected to the buoyancy generation unit and including a rotating unit with a plurality of blades, a blade control unit of adjusting the state of the blades, and a motor unit of converting kinetic energy transferred from the rotating unit into electrical energy.