An air-conditioning control system for a vehicle includes an acquisitor configured to acquire an exposure temperature of an exposed body surface of an occupant and a clothing surface temperature of the occupant, a non-exposure temperature estimator configured to estimate a non-exposure temperature of a non-exposed body surface of the occupant on the basis of the exposure temperature and a clothing amount, a clothing amount estimator configured to estimate the clothing amount on the basis of the non-exposure temperature and the clothing surface temperature, and a control unit configured to control an air conditioner of a vehicle into which the occupant gets on the basis of an estimation result of the clothing amount estimator.

A method for setting a thermal comfort state of at least one user of a vehicle, wherein, at a starting time, at least one actual state variable of the user is detected by at least one device for detecting the at least one state variable and a starting comfort state of the user is determined depending on the at least one actual state variable, wherein a target comfort state is determined, wherein at least one target state variable is determined depending on the target comfort state, wherein at least one vehicle-end device for changing the state variable is controlled so that a deviation in the actual state variable from the target state variable is minimized when the target comfort state deviates from the starting comfort state, wherein the at least one state variable is detected by a device carried by the user for detecting the at least one state variable.

An air-conditioning control system includes a memory, a processor coupled to the memory, and an air-conditioner for a space, wherein the processor is configured to acquire user information that includes any future increase or decrease in a number of users inside the space as a result of input by a user, and to control the air-conditioner for the space based on the user information before there is a change in the number of users inside the space.

A computer-implemented method includes receiving, with a vehicle computing system, global position system (GPS) data associated with a vehicle, determining a solar position relative to the vehicle, receiving trip information associated with the vehicle, and executing one or more vehicle actuators based at least in part on the GPS data, the trip information and the solar position relative to the vehicle. Determining the solar position can include determining a sun glare period during a future time period based at least in part on the trip information associated with the vehicle. The vehicle computing system may display a warning indicative of the sun glare period, generate a window tint command that causes the window to tint and/or generate a vent control command that causes the vent to change one or more of an airflow temperature, and an airflow velocity.

Embodiments of the invention provide air conditioning system for use in a motor vehicle, the air conditioning system comprising a controller, at least one primary vent and an air delivery apparatus for location in a dashboard of a motor vehicle, the apparatus comprising: at least one secondary vent; and means for moving the at least one secondary vent between a retracted position in which the at least one secondary vent lies rearward of an A surface of the dashboard and a deployed position in which the at least one secondary vent is exposed for delivery of air to a zone of the vehicle, the controller being operable to: control the air conditioning system to provide a flow of air from the at least one primary vent while the air delivery apparatus is in a retracted position; and control the at least one vent to assume the deployed position responsive to a demand for a flow of air from the at least one secondary vent.

The invention concerns a ventilator for a motor vehicle passenger compartment, intended to deliver an air flow towards a space to be conditioned, which comprises: an opening through which an air flow flows during operation, a flared guiding surface (S), extending from the opening, a needle valve (25) comprising a needle valve head (27) with: a tip (29) situated at the end of the needle valve (25), a maximum width portion corresponding in shape to the opening (O), with dimensions of between 80% and 100% of those of the opening (O), a base (33) flared in the direction of flow linking the head (29) to an elongate body (31), the needle valve (25) being able to move in translation between two end positions including: a deployed end position in which the widest portion of the needle valve head (27) is downstream from the opening (O) in the direction of the space to be conditioned, the air flow then being laminar and guided by the guiding surface (S) in a divergent flow, a retracted end position in which the widest portion of the needle valve head (27) is upstream from the opening (O), the air flow then being laminar and guided by the tip (29) of the needle valve (25) in a convergent flow.

The quietness requirement level of a charging point is determined based on the position information on the charging point where an in-vehicle battery is fast charged by an external power supply. For an air conditioner that cools the in-vehicle battery through a drive power of an electric compressor when the in-vehicle battery is charged, an upper limit of a rotation speed of the electric compressor is set in such a way that the upper limit of the rotation speed of the electric compressor is set lower when the in-vehicle battery is charged by the external power supply at a charging point where the quietness requirement level is equal to or higher than a predetermined value than when the in-vehicle battery is charged by the external power supply at a charging point where the quietness requirement level is lower than the predetermined value.

A heat control method for a heat control device, particularly for a vehicle interior, is disclosed. The method involves detecting, delimiting and positioning various parts of the body of an occupant (U), measuring thermal or physiological parameters regarding various parts of the body of the occupant (U) and/or the vehicle interior around the occupant (U), establishing a plurality of thermal comfort indices (I.sub.n), each thermal comfort index (I.sub.n) corresponding to one of the parts of the body of the occupant (U) taking into account a feeling of warmth or of cold in the associated body part, and of which the absolute value is at a minimum in a comfortable situation, and regulating the operation of a heat control device (3) to minimize a sum of the absolute values of the comfort indices (Σ|I.sub.n|) in order to create a regulated thermal environment around the occupant (U).

A vehicle air vent system includes a dashboard defining an air vent opening. An air register assembly is disposed within the air vent opening of the dashboard. The air register assembly includes a frame and a vane rotatably coupled to the frame. An imager is coupled to the dashboard. The imager captures data within a field of view. A controller is communicatively coupled to the imager and the air register assembly. The controller receives the data from the imager. The controller determines a position of an object within the field of view in response to the data.

An air conditioning unit and a control method. The control method includes the following: S1. detecting the operation status of an air conditioner; S2. acquiring, by photosensitive sensors, the sunlight conditions of a recreational vehicle in parking; and S3. adjusting, by a control module, air outlet areas of the air conditioning unit for the recreational vehicle according to the acquired sunlight conditions and the sunlight exposure side of the recreational vehicle in parking. The control method can adjust the air outlet areas of the air conditioner by checking the operation status of the air conditioner and acquiring the sunlight conditions of the recreational vehicle in parking through the photosensitive sensors, thereby improving the user's sense of comfort.