An HVAC module for a vehicle includes a cooling unit to cool air that passes through the cooling unit and a heating unit to warm air that passes through the heating unit. The HVAC module has a housing having a plurality of airflow paths to guide the air that passes through the cooling unit or the heating unit. An upper discharge outlet temperature is indeterminate based on a temperature detected by a single temperature sensor in one of the plurality of airflow paths and a blend setting. The HVAC module includes a temperature sensor to determine a reference temperature of the air at a sensor location. The reference temperature is offset from a floor outlet temperature by a floor offset function of the blend setting. The reference temperature is offset from the upper discharge outlet temperature by an upper offset function of the blend setting.

A closed loop feedback control and diagnostics system for a transport climate control system is provided. The closed loop feedback control and diagnostics system includes a plurality of source current sensors configured to monitor current received from a high voltage three-phase AC power source. The closed loop feedback control and diagnostics system also includes a plurality of compressor current sensors configured to monitor current drawn by an electrically powered compressor of the transport climate control system. The closed loop feedback control and diagnostics system also includes a controller configured to receive source current signals from each of the plurality of source current sensors, configured to receive compressor current signals from each of the plurality of compressor current sensors, and configured to control operation of the transport climate control system based on the received source current signals and the received compressor current signals.

A vehicular compartment temperature control system includes an insulated compartment disposed within a vehicle. The system includes at least one cooling element at the insulated compartment and operable to cool an interior cavity of the insulated compartment. A temperature sensor senses temperature within the insulated compartment. An output of the temperature sensor is provided to a control to determine temperature of the interior cavity. The control, responsive to receiving a signal indicative of a user selected temperature that is selected by a user via operating a user input of the vehicular compartment temperature control system, and responsive to determination that the determined temperature of the interior cavity of the insulated compartment is greater than the user selected temperature by at least a threshold amount, controls the at least one cooling element to adjust temperature of the interior cavity of the insulated compartment toward the user selected temperature.

In an example embodiment, a controller controls the HVAC system, dampers, fans, and heater/coolers in seats to heat or cool the interior and the seats to a desired temperature. The controller may control the temperature and/or the flow of air through a plurality of ducts and the heater/coolers in the seats to heat or cool regions of the interior and the seats to a desired temperature.

Provided is an air conditioning apparatus that is capable of suppressing increases in volume and cost of the apparatus and performing more suitable overheating protection. An electric compressor is an inverter-integrated electric compressor integrally including a compressor, an electric motor that drives the compressor, and an inverter including a temperature sensor that detects the temperature in the vicinity of a semiconductor switching device, wherein a controller estimates a discharge temperature of the compressor on the basis of a correlation of respective pressure loading characteristics for the detected temperature of the inverter, for the rotational speed of the compressor, and for the motive force of the compressor in a refrigerating cycle.

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.

A system includes an external temperature sensor, an internal temperature sensor and an internal moisture sensor, along with an HVAC for blowing air into the vehicle. The system also includes an electronic control unit (ECU) coupled to the sensors and the HVAC. The ECU determines a difference between the inside air temperature and the ambient air temperature and sets a condensation indicator when the ambient air temperature is less than a first temperature threshold, the difference between the inside air temperature and the ambient air temperature is greater than a second temperature threshold, and the inside moisture level is greater than a moisture threshold. The ECU determines a condensation temperature at which additional condensation will accumulate on the window, determines the desired temperature for the air blown by the HVAC and controls the HVAC to blow air at the desired temperature when the condensation indicator is set.

An air-conditioning system comprises a channel system, a system conveying device positioned in the channel system and configured to convey air in the channel system, a sensor device comprising at least one analysis channel and configured to measure a characteristic of air flowing through the at least one analysis channel, and a suction jet pump comprising a motive-fluid inlet, a suction inlet, and a pump outlet. The system conveying device separates a suction area of the channel system arranged upstream of the system conveying device from a pressure area of the channel system arranged downstream from the system conveying device, and the sensor device further comprises a sensor outlet configured to release air from the sensor device. The motive-fluid inlet is fluidically connected to the pressure area via a suction jet branch-off point within the channel system, and the suction inlet is fluidically connected to the sensor outlet.

Methods and apparatus relating to optimization of vehicular systems for occupant presence and condition are described. In one embodiment, logic circuitry detects presence and/or condition of one or more occupants of a vehicle based on sensor data. Memory (e.g., non-volatile memory) stores information corresponding to one or more functions of the vehicle. The logic circuitry transmits a request to the vehicle to cause an adjustment to the one or more functions of the vehicle. Other embodiments are also disclosed and claimed.

A refrigerated storage unit 1 includes: a refrigeration chamber S2, a refrigeration part 3 for cooling air inside the refrigeration chamber S2, a fan 4 for sending cold air cooled by the refrigeration part 3 into the refrigeration chamber S2, a temperature sensor 5 for detecting a temperature inside the refrigeration chamber S2, an infrared sensor 8 for detecting a temperature of a content provided inside the refrigeration chamber S2, and a control part 7 for controlling driving of the fan based on a result detected by at least one of the temperature sensor 5 and the infrared sensor 8.