An in-vehicle ventilation system includes a host ECU configured to acquire vehicle outside information using wireless communication, an air conditioner ECU configured to control an air conditioner installed in a vehicle compartment, a zone ECU configured to control a device in the vehicle compartment and to communicate with the host ECU and the air conditioner ECU and a power window unit configured to open and close a window of a vehicle. The zone ECU or the host ECU is configured to perform, based on information acquired inside the vehicle compartment and the vehicle outside information to be acquired by the host ECU, interlocked ventilation control interlockingly controls the power window unit and the air conditioner ECU.

An air conditioning control apparatus for a vehicle according to the present disclosure includes a sensor that senses a number of vehicle occupants, a vehicle speed, and an indoor temperature and an outdoor temperature of the vehicle, an air conditioner that adjusts an amount of air introduced from an outside or exhausted to the outside, and a controller that controls the air conditioner based on the number of vehicle occupants, the vehicle speed, and the indoor temperature and the outdoor temperature of the vehicle. According to the present embodiment, the comfort inside the vehicle may be improved by adjusting the ventilation amount depending on the number of vehicle occupants, the vehicle speed, and the indoor temperature and the outdoor temperature of the vehicle.

An air-conditioning control system acquires settlement information on an electronic settlement performed by an occupant D of a vehicle using a mobile terminal via a car-navigation system from the mobile terminal having an electronic settlement function, and controls an air conditioner on the basis of the acquired settlement information. The settlement information includes a commodity purchased by the electronic settlement or a service having a value paid by the electronic settlement, as a settlement target.

System, methods, and other embodiments described herein relate to assisting in closing a trunk door of a vehicle by leveraging a Heating, Ventilation and Air-conditioning (HVAC) system in the vehicle. In one embodiment, a method includes detecting a position of the trunk door, and when the position of the trunk door is an open position, determining whether to activate the HVAC system to reduce air pressure in a trunk of the vehicle, where the trunk and the HVAC system are fluidly connected by an air duct. The method includes, in response to determining to activate the HVAC system to reduce air pressure in the trunk, pumping air out of the trunk through the air duct such that at least some of any increased air pressure caused by a trunk door closure is removed from the trunk. The method includes, when the position of the trunk door has changed from the open position to a closed position, deactivating the HVAC system to stop pumping air out from the trunk.

In a situation where a temperature in a motor compartment is higher than a temperature of outside air, an inside air introduction rate increasing control is performed in which an inside air introduction rate is changed to be increased on a condition that there is no request for warming an inside of the vehicle cabin, the air conditioner is off, and air is being blown in an outside air introduction mode, and on the other hand, the inside air introduction rate increasing control is prohibited on a condition that there is a request for warming the inside of the vehicle cabin, the vehicular air conditioner is off, and air is being blown in the outside air introduction mode. In this way, heating efficiency can be improved by effectively utilizing the heat in the motor compartment to contribute to warming the inside of the vehicle cabin.

An air-conditioning apparatus for a vehicle and a control method of the same are provided to inhibit a closing degree of a door in closing the door from being insufficient, secure high quietness in a vehicle cabin immediately after the door is closed, and lower energy consumption of the vehicle. An air-conditioning apparatus for a vehicle includes an inside-outside air switching damper including a damper switching actuator, an air-conditioning control switch, a control unit, and door opening-and-closing sensors. The control unit includes two timers and a memory. When an IG switch is in an OFF state, the control unit sets the inside-outside air switching damper to an intermediate mode when the door becomes an open state, thereafter sequentially starts the timers when the door becomes a closed state, and returns the inside-outside air switching damper to a previous state to opening of the door after waiting until the timers expire.

An in-car air pollution prevention system is disclosed and includes plural gas detection modules and a gas conditioning device. The in-car gas detection modules and the out-car gas detection modules are provided for detecting the external gas and the air pollution source and transmitting the gas detection data respectively. A plurality of filtering and purification components are disposed within the gas conditioning device for filtering the external gas and the air pollution source. After the control drive unit compares the gas detection data, the gas conditioning device intelligently select and control the introduction or not introduction of the external gas. The plurality of in-car gas detection modules control the enablement of the gas guider of the gas conditioning device under a monitoring mechanism state. Whereby the gas pollution source in the interior space of the car is filtered through the filtering and purification component, and the gas pollution source is filtered and/or exchanged to generate clean air.

Disclosed are climate systems and methods for control the climate systems. A climate system includes a plurality of compressors, a first heat exchanger disposed downstream of the compressors and a second heat exchanger disposed downstream of the first heat exchanger. The compressors and heat exchangers are fluidly connected by refrigerant lines to form a refrigerant circuit. The climate system also includes a controller that controls the operation of the compressors to draw back lubricant to the compressors without use of an oil equalization system.

There is disclosed an environmental control system for thermally conditioning air within an enclosed space comprising: a refrigerant circuit having a compressor, an indoor heat exchanger, an expansion device, and an outdoor heat exchanger. The system further comprises an intake flowpath for directing an intake flow of fresh air to the enclosed space, wherein a heat-transfer section of the indoor heat exchanger is located within the intake flowpath to thermally condition the intake flow of fresh air before entering the enclosed space. The system further comprises an exhaust flowpath for directing an exhaust flow of thermally conditioned air to an external environment. A recovery heat exchanger is provided to transfer thermal energy between the exhaust flow and the intake flow at a location within the intake flowpath that is upstream of the heat-transfer section of the indoor heat exchanger.

The vehicle air conditioning apparatus comprises at least one physical condition information sensor which detects information on physical conditions of passengers in a vehicle as physical condition information. The vehicle air conditioning apparatus selectively executes an outside-air circulation control for discharging air from an interior of the vehicle to outside of the vehicle and introducing outside air to the interior of the vehicle from the outside of the vehicle and an interior-air circulation control for taking the air from the interior of the vehicle and returning the taken air to the interior of the vehicle. The vehicle air conditioning apparatus executes the outside-air circulation control when the electronic control unit determines that at least one of the passengers has an infection, based on the physical condition information.