A method for controlling a power system that powers a load is provided. The power system includes a prime mover, an electrical machine coupled to the prime mover, a battery source, an inverter coupled to the battery source, and a power system controller configured to control operation of the power system. The method includes monitoring a power demand on the power system from the load. The method also includes comparing the monitored power demand with a load threshold value. Also, the method includes determining that the monitored power demand is less than the load threshold value. Further, the method includes upon determining that the monitored power demand is less than the load threshold value: inactivating the prime mover, and instructing the battery source with the inverter to supply power to the load.

A device for transport of air in the tire P or close to it consisting of a chamber K in the shape of a hollow compressible channel, placed along at least a part of the tire perimeter, characterized by the fact that a ring OK is placed at the inner side of the chamber K with the distance of its outer side from the tire axis of rotation equal to 1 to 1.1 multiple of the distance of the bottom side of the chamber K from the axis of rotation of the tire P.

Provided herein is a system and method for heat exchange of a vehicle. The system comprises an enclosure disposed on the vehicle. The enclosure comprises a vent at a base of the enclosure. The enclosure houses one or more sensors. The enclosure comprises a fan disposed at a base of the enclosure. The heat exchange system comprises an deflector disposed on the vehicle outside the enclosure and configured to direct an airflow into the vent of the enclosure. The heat exchange system comprises a motor configured to: generate electricity from the airflow and selectively supply electricity to operate the fan. The heat exchange system comprises a controller configured to adjust the deflector and regulate an amount of electricity supplied from the motor to the fan.

An external car heater system includes a panel section located on an external surface of an automobile. The panel section is regulated through a control unit to turn on/off heat. The system may be regulated via manual user input or through automated processes. A sensor is used to monitor external conditions of the environment around the vehicle and can detect at least temperature. Sensor data is transmitted to the control unit to regulate the heating elements. The heat generated through the heating elements are used to melt ice and snow beneath the vehicles to move.

Provided herein is a system and method for heat exchange of a vehicle. The system comprises an enclosure disposed on the vehicle. The enclosure comprises a vent at a base of the enclosure. The enclosure houses one or more sensors. The enclosure comprises a fan disposed at a base of the enclosure. The heat exchange system comprises an deflector disposed on the vehicle outside the enclosure and configured to direct an airflow into the vent of the enclosure. The heat exchange system comprises a motor configured to: generate electricity from the airflow and selectively supply electricity to operate the fan. The heat exchange system comprises a controller configured to adjust the deflector and regulate an amount of electricity supplied from the motor to the fan.

A system describing Unlimited Range Drive capabilities of electric vehicles using machine learning techniques, assisted by intelligent battery modules and high voltage continuous variable power plant, the intelligent battery and power plant modules work in harmony and continuously provide feedback to each other, causing a battery to recharge while the other is in use to drive, this charging/recharging process and dynamically switching battery in use is continued until physical life of batteries is exhausted approximately 10 to 15 years, dynamic coordination of modules with dynamic switching of batteries, achieves unlimited range drive capabilities which may exceed 1 million mile drive on a single high voltage battery charge, the system provides clean environment and cost effective solution, this platform can be implemented in larger chassis including, but not limited to light duty trucks and vans up to heavy duty cargo tractor trailer and commercial public transportation buses.

An electric power system for a vehicle includes an exhaust heat recovery apparatus, a low-voltage system, a high-voltage system, a first wiring line, a second wiring line, and a DC/DC converter. The exhaust heat recovery apparatus includes a power generator that generates electric power on the basis of heat exhausted from a heating element. The low-voltage system includes a low-voltage secondary battery. The high-voltage system includes a high-voltage secondary battery that outputs a voltage higher than the low-voltage secondary battery. The first wiring line couples the power generator and the low-voltage system. The second wiring line couples the first wiring line and the high-voltage system. The DC/DC converter is disposed on the second wiring line and increases and decreases a voltage supplied to the DC/DC converter.

Systems and methods for an energy harvester proximate to a rotatable component of a vehicle's wheel are disclosed. In some embodiments, an energy harvester system includes: a substrate having a first surface configured to contact and interface with a surface of a wheel, and a second surface opposite the first surface; a piezoelectric component configured to produce energy in response to mechanical strain imparted on the piezoelectric component, wherein the piezoelectric component is configured to deform while experiencing the mechanical strain so as to contact at least a portion of the second surface.

Our system describes Unlimited Range Drive (URD) capabilities of an electrical automotive vehicle using machine learning technique, assisted by newly designed intelligent battery modules (IBM-R, IBM-D/R) and newly invented high voltage continuous variable power plant (CVPP), our intelligent battery and power plant modules work in harmony and continuously provide feedback to each other, causing a high voltage battery to recharge while other high voltage battery is in use to drive a vehicle, this charging/recharging process and dynamically switching high voltage battery in use is continued until physical life of batteries is exhausted which may be 10 to 15 years, dynamic coordination of the modules with dynamic switching of battery in use archives Unlimited Range Drive (URD) capabilities which may exceed more than 1 million miles drive on a single high voltage battery charge, our URD system provides clean environment and cost effective more than 1 million miles drive solution.

Provided herein is a system and method for heat exchange of a vehicle. The system comprises an enclosure disposed on the vehicle. The enclosure comprises a vent at a base of the enclosure. The enclosure houses one or more sensors. The enclosure comprises a fan disposed at a base of the enclosure. The heat exchange system comprises an deflector disposed on the vehicle outside the enclosure and configured to direct an airflow into the vent of the enclosure. The heat exchange system comprises a motor configured to: generate electricity from the airflow and selectively supply electricity to operate the fan. The heat exchange system comprises a controller configured to adjust the deflector and regulate an amount of electricity supplied from the motor to the fan.