An arrangement for de-icing a heat exchanger includes an air guiding housing and at least one fan. The air guiding housing is configured to take in an air from an outside of a motor vehicle through an inlet opening and to discharge the air from an outlet opening. The fan is positioned between the inlet opening and the outlet opening inside the air guiding housing and is configured to circulate the air in the air guiding housing. The heat exchanger is positioned between the inlet opening and the outlet opening inside the air guiding housing and allows the air to pass therethrough, thereby being configured to cool the air. The inlet opening and the outlet opening each are configured to be closed. The air guiding housing is configured to cause a circulation flow therein when the fan is operated while the inlet opening and the outlet opening are closed.

An air conditioner for a vehicle includes a heating line having a condenser at an inlet thereof and having an outlet communicating with an interior of the vehicle. A cooling line has an inlet communicating with the inlet of the heating line, an outlet communicating with the interior of the vehicle, and an evaporator connected to the condenser inside of the cooling line. One or more doors are provided to control a flow stream of each line and to control a temperature of air introduced into the interior of the vehicle.

A humidity detector a humidity sensor detecting a relative humidity of an air inside a sensor case housing the humidity sensor. The humidity detector has an air volume obtaining section, a flow direction obtaining section, a setting section, and a correction section. The air volume obtaining section obtains air volume information correlated with an air volume of the air flowing around the humidity sensor. The flow direction obtaining section obtains flow direction information correlated with a flow direction of the air flowing around the humidity sensor. The setting section sets correction factors configuring a dynamic compensator based on the air volume information and the flow direction information. The dynamic compensator compensates for a response delay of the humidity sensor. The correction section corrects a detection value, which is detected by the humidity sensor, by using the dynamic compensator to obtain the relative humidity of the air.

An air conditioning system for motor vehicles includes an air conditioner case having a left path, a right path and a rear seat path. A temperature door is configured to adjust a volume of a cold air or a hot air. A main blower is configured to blow the cold air or the hot air and an air volume distribution door is configured to control opening degrees of the left path and the right path. A rear seat auxiliary blower is configured to increase a volume and a pressure of the cold air or the hot air flowing through the rear seat path. A control unit is configured to, when an air volume distribution ratio of the main blower is changed, correct an opening position of the air volume distribution door and compensate a change in an air volume distribution ratio of the left path and the right path.

In an air conditioner system for a mobility device, some inside air communicates with an outdoor heat exchanger when outside air for indoor ventilation is introduced, thereby improving heat pump performance. That is, by allowing indoor cold air to communicate with the outdoor heat exchanger upon mixing the inside and outside air during indoor cooling and allowing indoor warm air to communicate with the outdoor heat exchanger upon mixing the inside and outside air during indoor heating, it is possible to increase the heat pump efficiency as the outdoor heat exchanger recovers the heat of the indoor air during indoor cooling and heating. In addition, introduced is an air conditioner system for a mobility device in which a structure is simplified as inside air may be selectively transmitted to an outdoor heat exchanger side only by applying a flow path structure and a valve.

A vehicle system includes a plurality of temperature sensors positioned in the vehicle and a control module in communication with the plurality of temperature sensors. The plurality of temperature sensors are configured to measure surface temperatures of objects in the vehicle. The control module is configured to receive the measured surface temperatures from the plurality of temperature sensors, determine whether any of the measured surface temperatures is greater than a defined threshold, and in response to any of the measured surface temperatures being greater than the defined threshold, transmit an alert signal to a user communication device indicative of the objects in the vehicle having the measured surface temperatures greater than the defined threshold. Other examples vehicle systems and methods for selectively controlling airflow in a vehicle and/or warning users of objects of a vehicle having potentially dangerous surface temperatures are also disclosed.

A climate control system for a vehicle for combustible coolants and is a device for installation on a vehicle roof. A directly evaporating system includes an electrical switch box inside a climate control device for the vehicle and is partitioned so that, in the event of relevant leakages of assemblies containing coolant, the assembly cannot come into contact with the combustible coolant and no ignitable mixture can occur in these areas. The electrical box is a closed assembly and is operatively connected to an assembly by which air from areas outside the segments containing coolant is guided into the electrical box.

An air supply system for a whole vehicle, which is intended to solve the technical problem that it is hard to provide a multi-position and controllable air supply solution for an electric vehicle. A first air source device, a control valve and a pipeline constitute a first-type air supply system, the first-type air supply system has multiple air passages, each air passage is respectively provided with an air supply port, and a controller can switch operating states of the control valve, control the opening or closing of the multiple air passages, and achieve controllable air supply effects in multiple positions. A second air source device and several pipelines constitute a second type of air supply system, the second type of air supply system has multiple air passages, each air passage is respectively provided with an air supply port, and a controller can switch operating states of the second air source device, control the opening or closing of the multiple air passages, and achieve controllable air supply effects. The first type of air supply system and the second type of air supply system are rationally configured on the electric vehicle, so as to achieve multi-position and controllable air supply effects.

According to one aspect, a thermal system of a vehicle which provides cooling to within the vehicle, e.g., within a driver and passenger carrying cabin or compartment, is effectively leveraged to provide cooling capabilities to autonomous vehicle systems. Some coolant flowing through a coolant loop included in the thermal system of a vehicle may be diverted to an offshoot loop which provides cooling to coolant included in a coolant loop configured to cool autonomous vehicle systems, e.g., a compute system that is part of an autonomous vehicle. The coolant from the thermal system of the vehicle may flow past coolant from the coolant loop configured to cool autonomous vehicle systems, and the cooled coolant from the coolant loop configured to cool the autonomous vehicle systems may flow near the autonomous vehicle systems to cool the autonomous vehicle systems.

The present disclosure relates to a vehicle control apparatus for safety of a vehicle occupant, a vehicle system including the same, and a method thereof. An exemplary embodiment of the present disclosure provides a vehicle control apparatus, including: a processor configured to recognize information related to occupants in a vehicle using a radar and to generate information for air conditioning control and airbag control depending on the occupant information; and a communication device configured to transmit the information for the air conditioning control and the airbag control depending on the occupant information to an air conditioning control device and an airbag control device.