A refrigeration cycle device including a first pressure reducing valve, a first evaporator that exchanges heat between the refrigerant decompressed in the first pressure reducing valve and air, a second pressure reducing valve that is disposed in parallel with the first pressure reducing valve; a second evaporator in which the refrigerant decompressed in the second pressure reducing valve to absorbs heat from a battery; a third pressure reducing valve that reduces the pressure of the refrigerant evaporated in the second evaporator; and a controller configured to control opening degrees of the second pressure reducing valve and the third pressure reducing valve. The controller performs a limit control for controlling the opening degree of the second pressure reducing valve to an opening degree of smaller one of a battery cooling opening degree and an air cooling opening degree.

A vehicle climate control assembly for modulating a temperature of a passenger compartment includes a solar panel, a battery, a heating and cooling unit, a temperature sensor, and a controller, all of which are mountable to a vehicle. The battery is operationally engaged to the solar panel, which is mountable to an exterior surface of the vehicle. The heating and cooling unit is in fluidic communication with the passenger compartment of the vehicle and is operationally engaged to the battery. The temperature sensor and the controller are mountable within the passenger compartment. The controller is operationally engaged to the solar panel, the battery, the heating and cooling unit, and the temperature sensor. The temperature sensor measures a temperature of the air in the passenger compartment, positioning the controller to selectively actuate the heating and cooling unit to modulate the temperature within the passenger compartment.

A cooling apparatus for an autonomous driving controller may include, a chiller fluidically connected to an air-conditioning system through a refrigerant connection line so that a refrigerant circulating in the air-conditioning system provided in the vehicle is introduced into the chiller; a reservoir tank storing a coolant, and fluidically connected to the chiller; and a water pump mounted between the reservoir tank and the autonomous driving controller;, wherein coolant pipes connected to the water pump and the chiller may be connected to the autonomous driving controller respectively.

An conditioning device for a fuel cell vehicle includes a heater core configured to heat air in a vehicle cabin with a coolant to be discharged from a FC stack cooled by the coolant as a heat source, a coolant heating heater configured to heat the coolant, an air heating heater configured to further heat air warmed by the heater core, and a vehicle ECU configured to, in a case where a heater core outlet coolant temperature based on a target blowing temperature is equal to or higher than an FC stack inlet target temperature, perform control such that the air heating heater is operated with an output set based on the heater core outlet coolant temperature, and the coolant heating heater is operated with an output set based on a heater core inlet target coolant temperature calculated according to the set output of the air heating heater.

A method of power demand management is provided. The method includes an electrically powered climate control unit (CCU) detecting one or more additional electrically powered CCUs in a vicinity of the electrically powered CCU and the CCU establishing a communication link with the one or more additional electrically powered CCUs. The method includes generating and transmitting a pending power request to demand power from the power source to the CCU. The CCU monitors for one or more additional pending power requests from the one or more additional CCUs and monitors its position within a power request queue for obtaining power from the power source amongst the CCU and the one or more additional CCUs. Also, the method includes the electrically powered CCU demanding power from the power source when its position within the power request queue is high enough to demand power from the power source.

The present disclosure relates to a method for controlling a thermal effector in a vehicle. The method comprises calculating a heat transfer rate relative to a conditioned medium and calculating a target temperature of the thermal effector required to effectuate the heat transfer rate relative to the conditioned medium. The heat transfer rate is required to arrive at the setpoint temperature of the conditioned medium. The heat transfer rate is based on a setpoint temperature and a dynamically estimated temperature of the conditioned medium. The thermal effector is controlled to arrive at the target temperature.

When a temperature of a coolant is a first predetermined temperature or higher, an air conditioner ECU executes a first control that sets a target evaporation temperature higher by a predetermined temperature and the air conditioner ECU executes a second control that changes the target evaporation temperature in accordance with a cooling load inside the vehicle cabin. When the second control is executed after the first control is executed, the air conditioner ECU sets a first target evaporation temperature set by the first control as the target evaporation temperature, and calculates a second target evaporation temperature that is changed by the second control based on the target evaporation temperature immediately before the first control is executed. When the second target evaporation temperature becomes larger than the first target evaporation temperature, the air conditioner ECU sets the second target evaporation temperature as the target evaporation temperature.

Disclosed are a vehicle air conditioning control system and method, the vehicle air conditioning control system including a controller configured to receive a target temperature and a sensor value and determine an optimal control variable on the basis of a cost function that reflects energy consumption and following-up performance in following up the target temperature received by using a control model, and a plant configured to receive the control variable determined by the controller and operate to cool or heat a vehicle interior on the basis of the received control variable.

Methods and systems are provided for heat sanitizing a vehicle. In one example, a method may include, responsive to receiving a request for sanitization of a vehicle interior, operating a heating, ventilation, and air-conditioning (HVAC) system to heat the vehicle interior above an upper threshold temperature for a threshold duration. In this way, the HVAC system may be advantageously used to expose the vehicle interior to temperatures that kill or inactive microbes.

A refrigeration system for cooling a refrigeration compartment. The refrigeration system comprises a cooling reservoir for cooling refrigerant in a first loop using energy recovered from an engine exhaust stream and a refrigeration circuit comprising a compressor drivable by an internal combustion motor, the compressor circulating refrigerant in a second loop. The refrigeration system comprises at least one heat exchanger in communication with the first and second loops to receive cooled refrigerant, and at least one blower for forcing air over the at least one heat exchanger. A controller selectively activates the internal combustion motor based on a temperature of the cooling reservoir.