For one embodiment, an exemplary method of controlling the climate in a vehicle includes the operations of detecting a moving of a touch from a first location to a second location on the touch screen in the vehicle, each of the first location and the second location associated with a pair of values; determining a first value and a second value of the pair of values associated with the second location on the touch screen; and adjusting the speed of at least one fan based on the first value and the temperature of at least one seating area based on the second value.

An air vent apparatus of a vehicle according to one embodiment of the present invention includes a knob electrically interlocked with a display disposed inside a cockpit and laterally moved to selectively operate various functions installed in the display and an air duct disposed on a movement path of the knob and configured to adjust a ventilation direction of air introduced into an interior of a vehicle according to the lateral movement of the knob.

A controller for vehicle air conditioner includes a base defining a mounting cavity; a knob assembly rotatably mounted to the base, wherein at least a portion of the knob assembly is located in the mounting cavity; and at least one bearing element arranged between the base and the knob assembly. Such a design reduces the friction between the base and the knob assembly and thus reduces the noise.

An outlet device for ventilation of a vehicle interior has a housing which extends between an air inlet orifice and an air outlet orifice and a pivot bearing device mounted on the housing, wherein the pivot bearing device provides a rotational axis. The outlet device further comprises a rotatable displacement body, a first vane which extends in a direction across the rotational axis, a second vane which extends in a direction across the rotational axis and contrary to the extension of the first vane, a rudder, and an adjustment device. The adjustment device permits pivoting of the rudder around an axis that is parallel to the direction of extension of the first and second vanes.

A vehicle includes a first seat, a second seat, an HVAC system, and a touch screen configured to detect a user's touch and to display a setting interface of the HVAC system according to a plurality of seats. A controller is configured to convert the touch screen to a synchronization mode based on a first touch, to change the setting interface of the first seat and the setting interface of the second seat equally based on a second touch changing the setting interface of the first seat, and to control the HVAC system based on the changed setting interface.

The present invention relates to a lever (11) having: an engagement part (16) designed to engage in a corresponding housing in a component with which the lever is intended to cooperate, a base (18) to which the engagement part is connected, a connecting zone (20) between the engagement part and the base, this connecting zone having a profile extending from the engagement part to the base, said profile having a gradual curve shape, this connecting zone also comprising at least one stop (21) adjacent to the profile with a gradual curve shape.

A control device that includes a body, a movable element that is movable according to a first degree of freedom relative to the body, an actuator for moving the movable element relative to the body, and a secondary control device. The secondary control device has a switch movable between an open position in which a function is deactivated and a closed position in which the function is activated. The actuator is movable according to a second degree of freedom between a spaced apart position and a control position in which the actuator moves the switch between its open position and its closed position.

An air nozzle of an air outlet in an interior of a motor vehicle. An operating element is adjustable around an axis of rotation. A kinematics adjustment system has a deflection unit where, via an adjustment of the operating element, a shut-off flap inside the air outlet is displaceable around a flap axis by the kinematics adjustment system. The operating element is disposed on an end of an actuator rod where the actuator rod is displaceable in a direction of extension from an actuating position into a locking position. The axis of rotation of the operating element runs transversely to the flap axis, a rotational movement of the actuator rod is deflectable by the deflection unit into a rotational movement of the shut-off flap, and, by displacing the actuator rod into the locking position, the deflection unit is lockable by applying a spring force to the deflection unit.

Disclosed herein is a vehicle air vent that includes a duct having a channel therein through which air flows, and a discharge end through which the air is discharged, a first adjuster installed in the duct so as to be rotatable about a first rotary shaft, an extending direction of a first opening being varied depending on the angle of rotation of the first adjuster, a second adjuster installed in the duct so as to be rotatable about a second rotary shaft, an extending direction of a second opening being varied depending on the angle of rotation of the second adjuster, a third adjuster installed on the discharge end so as to be rotatable about a third rotary shaft, a third opening being defined between the third adjuster and the duct, and an interlocking connector operatively connecting the first adjuster to the third adjuster.

A vehicle-mounted temperature controller used in a vehicle having a motor, a battery, and a PCU is provided with a low temperature circuit and a refrigeration circuit. The low temperature circuit has a battery heat exchanger, a PCU heat exchanger, a radiator, and a chiller, and the cooling water circulates through them. The refrigeration circuit has a condenser and the chiller absorbing heat from the cooling water to the refrigerant, and the refrigerant circulates through them. The low temperature circuit is configured to be able to switch connection states between a first state where the battery heat exchanger and the chiller are connected, the PCU heat exchanger and the radiator are connected, and the battery heat exchanger and the chiller are not connected to the PCU heat exchanger and the radiator, and a second state where the chiller, the PCU heat exchanger, and the radiator are connected.