A vehicle-mounted solar power generation device includes a solar panel, a solar battery that is a battery temporarily storing electric power, and a controller configured to perform control by switching between an electric power generation mode in which the solar battery is charged with a generated electric power of the solar panel and an electric power saving mode in which at least the charging of the solar battery is stopped such that power consumption is suppressed in comparison with the electric power generation mode. The controller determines to switch between modes based on the output voltage of the solar panel. In the electric power saving mode, the controller restricts a switch to the electric power generation mode based on any of the frequency of switching between modes, the amount of electric power stored in the solar battery, and the state of stoppage of a vehicle.

A vehicle-mounted solar power generation device includes a solar panel, a solar battery that is a battery temporarily storing electric power, and a controller configured to perform control by switching between an electric power generation mode in which the solar battery is charged with a generated electric power of the solar panel and an electric power saving mode in which at least the charging of the solar battery is stopped such that power consumption is suppressed in comparison with the electric power generation mode. The controller determines to switch between modes based on the output voltage of the solar panel. In the electric power saving mode, the controller restricts a switch to the electric power generation mode based on any of the frequency of switching between modes, the amount of electric power stored in the solar battery, and the state of stoppage of a vehicle.

An ecological system for use in land or marine vehicles is provided, which uses wasted airmass making it to pass through two subsystems which allow lighten the load of the moving vehicle and generates electrical energy. Therefore, showing an economy in fuel, tires, and general maintenance savings, as well as a decrease of contaminants thrown to the environment.

An ecological system for use in land or marine vehicles is provided, which uses wasted airmass making it to pass through two subsystems which allow lighten the load of the moving vehicle and generates electrical energy. Therefore, showing an economy in fuel, tires, and general maintenance savings, as well as a decrease of contaminants thrown to the environment.

The inventive vehicle provides all the benefits discussed above with a frame defining an operator compartment, the operator compartment having a back section and having open sides and an open bottom. A first movable chair is attached to a motorized chair movement device which allows the chair to be moved vertically and horizontally on the back section of the operator compartment within the operator compartment. A pair of rear wheels is connected to the frame, each being driven by an electric motor. The frame has an upper section defining the top of the operator compartment and being constructed and arranged to support a solar panel. The solar panel is electrically connected to at least one battery which is connected to the frame and which provides power to the vehicle. A front caster wheel is rotatable connected to a caster wheel arm which is rotatably connected to the upper frame section. A control computer is connected to the rear wheel motors, motorized chair movement device, caster wheel arm and foot/leg rest. A plurality of operator controls are connected to the first movable chair and operably connected to the control computer for operating the vehicle.

The inventive vehicle provides all the benefits discussed above with a frame defining an operator compartment, the operator compartment having a back section and having open sides and an open bottom. A first movable chair is attached to a motorized chair movement device which allows the chair to be moved vertically and horizontally on the back section of the operator compartment within the operator compartment. A pair of rear wheels is connected to the frame, each being driven by an electric motor. The frame has an upper section defining the top of the operator compartment and being constructed and arranged to support a solar panel. The solar panel is electrically connected to at least one battery which is connected to the frame and which provides power to the vehicle. A front caster wheel is rotatable connected to a caster wheel arm which is rotatably connected to the upper frame section. A control computer is connected to the rear wheel motors, motorized chair movement device, caster wheel arm and foot/leg rest. A plurality of operator controls are connected to the first movable chair and operably connected to the control computer for operating the vehicle.

Systems, methods, and a device which produces and stores electrical energy from primarily the forward movement of a vehicle is disclosed. This device has a variety of potential applications, such as use with a semitrailer and various types of electric vehicles. It also includes a number of features, such as functioning as a cryptocurrency mining rig that uses excess electricity generated, that add to its usefulness.

A method of controlling a vehicle includes: determining whether a condition for entry into a refresh mode of a battery in the vehicle is satisfied; when the condition is satisfied, predicting an amount of power generated by a solar generator; determining whether to perform the refresh mode based on the predicted amount of power; when the refresh mode is determined to perform, charging the battery using the power generated by the solar generator; identifying a charge amount of the battery; when the identified charge amount is greater than or equal to a first reference charge amount, terminating charging the battery; when an ignition-on command is received, determining whether the charge amount of the battery is greater than or equal to the first reference charge amount; when the charge amount of the battery is less than the first reference charge amount, charging the battery using power generated by an alternator.

A method of controlling a vehicle includes: determining whether a condition for entry into a refresh mode of a battery in the vehicle is satisfied; when the condition is satisfied, predicting an amount of power generated by a solar generator; determining whether to perform the refresh mode based on the predicted amount of power; when the refresh mode is determined to perform, charging the battery using the power generated by the solar generator; identifying a charge amount of the battery; when the identified charge amount is greater than or equal to a first reference charge amount, terminating charging the battery; when an ignition-on command is received, determining whether the charge amount of the battery is greater than or equal to the first reference charge amount; when the charge amount of the battery is less than the first reference charge amount, charging the battery using power generated by an alternator.

Systems and methods for reducing a current speed of a vehicle that can operate on solar energy to increase solar energy collection. The system may include a photovoltaic (PV) panel configured to receive sunlight to drive an electric motor, a solar loading sensor configured to detect solar load, a global position system (GPS) sensor configured to detect vehicle location data, a speed sensor configured to detect vehicle speed, and an electronic control unit (ECU) connected to the electric motor, the solar loading sensor, the speed sensor, and the GPS sensor. The ECU may determine whether the vehicle is exposed to solar load greater than a predetermined threshold value and, if so, present a driver of the vehicle a minimum acceptable speed to select based on sensor data and a difference of solar energy collection between the minimum acceptable speed and the current speed.