A control method for an integrated cooling system may include determining whether an air conditioner is operated or not, and controlling operations of a water pump for electric devices and a cooling fan by the controller according to a predetermined first map when the air conditioner is not operated, detecting an air conditioner refrigerant pressure when the air conditioner is operated, determining whether the air conditioner refrigerant pressure is within a predetermined range or not, and controlling operations of the water pump for electric devices and the cooling fan according to a predetermined second map when the air conditioner refrigerant pressure is not within the predetermined range, and determining of cooling requirement of the condensers and controlling operations of the water pump for electric devices and the cooling fan according to the cooling requirement of the condensers when the air conditioner refrigerant pressure is within the predetermined range.

Methods and systems for controlling a transport refrigeration system are provided. In one instance, the method includes identifying an operational mode change request for a heat exchanger unit of the transport refrigeration system. The method also includes preparing the transport refrigeration system for the operational mode change of the heat exchanger unit, wherein preparing the transport refrigeration system for the operational mode change of the heat exchanger unit includes performing a load control action, the load control action preventing a power source of the transport refrigeration system from at least one of operating outside of a predefined revolutions per minute (RPM) bandwidth and exceeding a predefined power limit of the power source. Also, the method includes changing the operational mode of the heat exchanger unit; and removing the load control action.

Methods and systems for assessing operation of a cooling system of an electric vehicle are described. In one example, a super heating temperature at an inlet of a compressor may be generated solely via a temperature sensor and a pressure sensor. The super heating temperature may be compared against a threshold super heating temperature to judge whether or not an amount of refrigerant in the cooling system is as expected.

Systems and method relate to a fuel efficient automatic temperature control system. The system includes a climate control system configured to heat or cool air. The climate control system includes a condenser and a variable-speed fan. A first sensor provides vent-air information indicative of a condition of the air. An automatic temperature controller receives an indication of a desired temperature, receives the vent-air information, determines whether the variable-speed fan should operate at a maximum fan speed based on at least the desired temperature and the vent-air information and determines whether a dehumidifying operation is requested. If the variable-speed fan is required to operate at the maximum fan speed or a dehumidifying operation is requested, the fan operates at the maximum speed. If the variable-speed fan is not required to operate at the maximum fan speed and a dehumidifying operation is not requested, the fan operates below the maximum fan speed.

Methods and systems are provided for controlling an air conditioning compressor clutch. In one example, a method includes monitoring a clutch of an air conditioning system in a vehicle when the air conditioning system is activated, and responsive to determining that the clutch is not engaged, increasing a current flow to the clutch. In this way, engagement of the compressor clutch may be dynamically maintained with a reduced usage of electrical power.

Methods and systems are provided for adjusting operation of an automotive air conditioning system including a pressure sensor positioned within a compression chamber. In one example, a method may include adjusting operation of the air conditioning system based on one or more parameters of a compressor operation including a compressor inlet pressure, a compressor outlet pressure, and a compressor speed, that are determined based on output from the pressure sensor positioned within the compression chamber.

A vehicle heating, ventilation, and air conditioning (HVAC) system includes: a compressor; an interior condenser located on the downstream side of the compressor and disposed in an HVAC case; a heating-side expansion valve located on the downstream side of the interior condenser; a water-cooled heat exchanger located on the downstream side of the heating-side expansion valve; and a controller. The controller is configured to adjust an opening degree of the heating-side expansion valve based on a temperature difference between air flowing from the interior condenser to front seats of a vehicle cabin and air flowing from the interior condenser to rear seats of the cabin. The controller is also configured to adjust the opening degree based on an amount of heat (heat release amount) transferred from the interior condenser to the air.

This disclosure relates to a vehicle configured to detect a low refrigerant charge and a corresponding method. In some aspects, the techniques described herein relate to a vehicle, including: a thermal conditioning system including a compressor and a suction pressure sensor upstream of the compressor; and a controller in communication with the compressor and the suction pressure sensor, wherein the controller is configured to perform a technique to monitor for a low charge condition, and the controller is configured to inhibit a low pressure cutoff when the controller is performing technique.

A refrigerant circulation system which circulates CO.sub.2-containing refrigerant therethrough includes a compressor which compresses the refrigerant, a motor, a motor speed sensor which detects a rotational speed of the motor, and a control device which controls at least the motor. The motor includes a rotor, a stator, a rotation shaft coupled to the rotor, and slide bearings supporting the rotation shaft and being lubricated using the refrigerant compressed by the compressor, and is configured so that the refrigerant passing through the motor expands after flowing out of the slide bearings and is used for cooling one of the rotor and the stator. The motor further includes a flow rate adjustment mechanism which adjusts a flow rate of the refrigerant. The control device controls the flow rate adjustment mechanism to adjust the flow rate of the refrigerant according to the rotational speed detected by the motor speed sensor.

One embodiment relates to an automotive thermal management fluid module using a circulating fluid, such as a refrigerant or coolant, the module comprising: a manifold plate having a plurality of fluid passages formed therein; and a thermal interference avoidance unit that is coupled to the manifold plate, wherein fluid passages having a relatively high or low temperature from among the fluid passages are formed separately other fluid passages.