A control device includes: an acquiring part that acquires a temperature of a battery cell of the battery; an identifying part that identifies a charge amount of the battery; and a cooling control part that determines a cooling-onset battery cell temperature on the basis of the charge amount identified by the identifying part, and operates an electric compressor to begin cooling the cooling water with the secondary refrigerant on condition that the temperature acquired by the acquiring part is higher than the determined, cooling-onset battery cell temperature. When the identifying part identifies a first charge amount, the cooling control part determines a higher cooling-onset battery cell temperature than in a case where the identifying part identifies a second charge amount that is higher than the first charge amount.

A vehicle has a front grille, engine, engine compartment, power storage device, temperature sensor, shutter, heater and controller. The device can be electrically charged from an external power supply. The temperature sensor detects engine coolant temperature. The shutter is disposed in a transfer pathway of air drawn into the engine compartment via the front grille, and is switched between closed and open states. The heater is able to generate heat when receiving the electric power, raising the coolant temperature. The controller starts the engine when the coolant temperature is lower than a startup threshold value, drives the heater when the coolant temperature is lower than a first threshold value equal to or higher than the startup threshold value, until the coolant temperature becomes equal to or higher than the first threshold value, and drives the shutter to place the shutter in the closed state while the heater is driven.

An AWD-vehicle control device includes a transfer clutch that adjusts a driving force, a detector that detects a steering angle of a steering wheel, a detector that detects an accelerator pedal opening, a detector that detects a vehicle speed, a detector that detects an engine revolution speed, a detector that detects a turbine revolution speed of a torque converter, and a transfer clutch controller that adjusts hydraulic pressure supplied to the transfer clutch and controls a coupling force of the transfer clutch. If a predetermined period has passed from the accelerator pedal opening becoming less than a predetermined opening, the vehicle speed is within a predetermined range, a deviation between the engine and turbine revolution speeds is less than a predetermined speed, and the steering angle is equal to a first predetermined angle or greater, the transfer clutch controller controls the hydraulic pressure to reduce the coupling force.

A system is disclosed included but not limited to a wheel having a wheel pressure chamber; a tire having a tire pressure chamber, wherein the tire is mounted on the wheel; a tire pressure sensor inside of the tire pressure chamber for measuring a tire air pressure inside of the tire pressure chamber; a wheel outlet valve between the wheel pressure chamber and the tire pressure chamber; a processor that reads a measure of the pressure inside of the tire pressure chamber from the tire pressure sensor and controls the wheel outlet valve to allow gas from the wheel pressure chamber to flow into the tire pressure chamber to increase the pressure in the tire pressure chamber when the tire pressure is less than a reference tire pressure. A method is provided for using the system.

A hydraulic park brake system for an aircraft may include a hydraulic park brake controller having a processor and a tangible, non-transitory memory configured to communicate with the processor. The tangible, non-transitory memory may have instructions stored thereon that, in response to execution by the processor, cause the hydraulic park brake system to perform various operations. Such operations may include receiving, by the processor, a hydraulic park brake condition, comparing, by the processor, the hydraulic park brake condition with a predetermined condition to yield comparison data, and determining, by the processor and based on the comparison data, a hydraulic park brake adjustment status. Such operations may further include generating, by the processor and based on the hydraulic park brake adjustment status, an adjustment command and transmitting, by the processor, the adjustment command to a hydraulic park brake of the aircraft.

Systems of an electrical vehicle and the operations thereof are provided. In particular, a towing cable and methods for utilizing the same in a towing scenario are described. The towing cable is described to facilitate the transfer of power between vehicles as well as data between vehicles. The data transferred between the vehicles involved in the towing include sensor information of the towed vehicle as well as control signals.

A system for monitoring at least one physical characteristic of an endless track includes a sensor removably received within the endless track and at least one probe received within the endless track. The sensor is adapted for wireless communication with a receiver. The at least one probe is adapted for operative communication with the sensor, and for detecting the at least one physical characteristic of the endless track and conveying the at least one physical characteristic to be sensed by the sensor. An endless track having a housing embedded in one inner lug is also provided. The housing includes a receptacle received in the inner lug and a lid removably connected to the receptacle for selectively providing access to an interior of the receptacle. The sensor is receivable in the housing. A method for assessing a secondary physical characteristic of an endless track is also provided.

A capless refueling mechanism attached to a vehicle fuel tank is disclosed. In one example, the capless refueling mechanism includes a guide plate, main opening, misfueling inhibitor mechanism with a first and second pendulum arm mounted within the main opening, and a sealing door pivotably coupled to the refueling mechanism. The first and second pendulum arm of the misfueling inhibitor may be adjusted to move from a first position to a second position, allowing a fuel nozzle sized to fit the main opening to open the sealing door and dispense fuel into the fuel tank.

A vehicle gas fuel management system includes an ambient temperature sensor that detects a first ambient temperature at a first time and a second ambient temperature at a second time, a pressure sensor that detects a pressure for a volume of gas at the first time, and a controller. The controller is programmed to determine a first enthalpy and density for the volume of gas based upon the detected first ambient temperature and detected pressure, and estimate a second enthalpy for the volume of gas based upon the second ambient temperature and the first energy state.

A vehicle safety system and method is provided for preventing heat related injuries in hot cars. The system includes a sensor, to sensing the presence of a child or animal in a stationary vehicle; and a controller, configured to issue an alert in response to the detection of the presence of the child or animal in the vehicle. The controller may also be for controlling a change in temperature in the vehicle in response to detection of the presence of the child or animal in the vehicle.