A hydrodynamic heater pump may include a housing and a stator fixed relative to the housing. A rotor may be coaxially aligned with and positioned adjacent the stator. The rotor and the stator define an interior region of a hydrodynamic chamber operable for heating a fluid present within the interior region of the hydrodynamic chamber. The rotor may be attached to a drive shaft for concurrent rotation therewith. The rotor may be moved axially along an axis of rotation of the drive shaft between a pumping mode position and a heating mode position. The rotor may be located a first distance from the stator when arranged in the heating mode position and a second distance from the stator when arranged in the pumping mode position. The second distance may be greater than the first distance.

Comfortable vehicle interior air conditioning is realized while giving an appropriate temperature difference to air blown out from outlets. A vehicle air-conditioning device 1 includes an air mix damper 28, a FOOT outlet 29A, and a VENT outlet 29B. A control device has a B/L mode to blow out air from both of the FOOT outlet and the VENT outlet to a vehicle interior. In the B/L mode, the control device sets a target air volume ratio TGSW to be within a predetermined intermediate range of an air volume ratio SW by the air mix damper, and calculates a target heater temperature TCO on the basis of a target outlet temperature TAO and the target air volume ratio TGSW.

A combustion chamber assembly unit for a fuel-operated vehicle heater includes a combustion chamber housing (14), a combustion chamber (18) formed in the combustion chamber housing (14), an evaporator medium (28) for the absorption of liquid fuel and for the discharge of fuel vapor into the combustion chamber (18), and a heating/ignition device (36) for heating the evaporator medium (28) or/and for igniting a mixture of fuel and combustion air formed in the combustion chamber (18). The heating/ignition device (38) includes at least one radiation source (38) for the emission of electromagnetic radiation into the combustion chamber (18) and at least one absorption body (29, 46) for the absorption of electromagnetic radiation emitted into the combustion chamber (18).

A method for digitally controlling a heating arrangement may include receiving a temperature value with a control device, the temperature value reflecting a current outside temperature. The method may also include determining via the control device, based on the received temperature value, a limit output of the heating arrangement that is smaller than a maximum output of the heating arrangement. The method may further include dividing the determined limit output into a plurality of output stages via the control device, a number of the plurality of output stages corresponding to a digital resolution of the control device. The method may additionally include controlling the heating arrangement between a minimum output and the limit output to one of the plurality of output stages.

Systems, methods, and computer-readable media are provided for detecting and responding to a moisture condition of an autonomous vehicle (AV). In some examples, an AV fleet management device may detect a moisture condition within AV based on sensor data received from the AV. In some aspects, in response to detecting the moisture condition, the AV fleet management device may determine, based on the sensor data, that a humidity level within the autonomous vehicle exceeds a threshold humidity level or a wet surface within the autonomous vehicle is present. In some cases, a drying procedure may be determined or selected for reducing the humidity level or drying the wet surface within the autonomous vehicle.

An embodiment is a control method for cooling a battery, the control method including in response to a destination being input to a navigation, determining estimated high-load driving timing of the battery based on estimated driving information of a vehicle, and in response to a determination that a temperature difference between the actual temperature of the battery and a reference temperature before the estimated high-load driving timing is lower than or equal to a precooling operating value, precooling the battery until an actual temperature of the battery reaches a target temperature by controlling an operation of each component of a battery cooling system.

A vehicle control device that controls an air conditioning device and a battery in a vehicle that uses a coolant of the air conditioning device that cools a vehicle cabin for cooling the battery, the vehicle control device including: an air conditioning load determination unit that determines whether the air conditioning device is driven by a predetermined load or more; and a battery input-output control unit that controls at least one of an input power or an output power of the battery. When the air conditioning device is driven by the predetermined load or more, at least one of the input power or the output power is restricted without cooling the battery.

According to the present disclosure, a drunk driving prevention system including: an alcohol detection unit configured to detect a driver's inebriation through the breath test device provided in a vehicle; a computation unit configured, when the driver is detected to be in a drunk state by the alcohol detection unit, to compute a driving-possible time at which the drunk state is resolved in the future so that driving is possible; and a notification unit configured to output the driving-possible time or whether or not driving is possible through an infotainment system of the vehicle or a driver's terminal is disclosed.

An air conditioner is disposed in a vehicle in which a driving device of a traveling power source is housed in an outer space separated from a cabin by a partition wall. The air conditioner includes: a temperature control unit that controls a temperature of air blown into the cabin; and plural air distribution ducts connected to the temperature control unit to guide temperature-controlled air having a temperature controlled by the temperature control unit to predetermined positions in the cabin. The temperature control unit is disposed in the outer space together with the driving device. Intermediate parts of the air distribution ducts located at least between the outer space and the cabin are bundled together and extended through a single insertion hole formed in the partition wall.

An HVAC system including a front blower having a first front blower outlet and a second front blower outlet. The first front blower outlet and the second front blower outlet are arranged vertically relative to one another. A joint duct includes a first body portion and a second body portion. The first body portion includes a first duct inlet, which is connected to the first front blower outlet, and a first duct outlet. The second body portion includes a second duct inlet, which is connected to the second front blower outlet, and a second duct outlet. The first duct outlet and the second duct outlet are arranged horizontally relative to one another. An HVAC case defines a first inlet and a second inlet arranged horizontally relative to one another. The first duct outlet is connected to the first inlet, and the second duct outlet is connected to the second inlet.