A transport refrigeration system includes a transport refrigeration unit configured to provide conditioned air to a refrigerated cargo space of a container; a low voltage DC power source including a fuel cell configured to provide electricity to the transport refrigeration unit; a power converter configured to condition DC power from the low voltage DC power source prior to supply to a transport refrigeration unit load; and a power management module configured to manage power provided to the transport refrigeration unit.

A transport refrigeration unit (TRU) system is provided and includes a TRU and an energy storage device (ESD). The TRU includes components which are configured to control an environment and a TRU controller configured to control the components in accordance with component operating settings. The ESD includes an ESD controller receptive of identification data identifying the components, current condition data reflective of current conditions and control data reflective of a temperature profile. The ESD controller is configured to determine the component operating settings in accordance with the identification, current condition and control data and to issue the component operating settings to the TRU controller.

A vehicle, a refrigerator for a vehicle, and a method for controlling a refrigerator for a vehicle are provided. The method for controlling the refrigerator for the vehicle includes turning on a switch of the refrigerator for the vehicle, measuring a temperature of an interior of the refrigerator for the vehicle a first time, measuring a temperature of the interior of the refrigerator for the vehicle again a second time after a predetermined time has elapsed from the first time, determining a temperature change of the interior of the refrigerator from the first time to the second time, and operating the refrigerator for the vehicle in a quench mode in which the temperature in the interior of the refrigerator is rapidly lowered, unlike a normal mode, if the temperature change in the interior of the refrigerator is in a positive direction.

An air distribution system for use in a cargo delivery vehicle. The air distribution system includes a compressor, a condenser, a plurality of tubes, an air distribution unit, and a mounting system for mounting the air distribution unit to the roof of the cargo delivery vehicle. The air distribution unit includes a unit body, a vent hood, and a vent plate. The unit body includes a fan and a plurality of tubes. The vent plate includes at least one vent opening.

Disclosed is a vehicle air conditioner, wherein an integrated air conditioning module using a heat pump system enables, in order to secure interior space, the optimizing of the arrangement thereof and the arrangements among the elements thereof, and the increasing of a coupling force between an air conditioning module and a distribution duct.

A cooling system control method for an autonomous driving controller may include detecting the temperature of the autonomous driving controller by the controller when a vehicle is driving; determining whether a current temperature of the autonomous driving controller is lower than a target temperature by the controller; and terminating the controlling of the cooling system if the condition is satisfied in determining whether the current temperature of the autonomous driving controller is lower than the target temperature.

A refrigerant system includes a compressor, multiple pressure sensors, multiple refrigerant flow valves, and a processor. The compressor is configured to present a refrigerant at a first pressure. A first pressure sensor is configured to measure the first pressure of the refrigerant. A second pressure sensor is configured to measure a second pressure of the refrigerant. The refrigerant flow valves have a plurality of flow valve positions. The processor is configured to calculate a delta value as a difference between the first pressure and the second pressure, calculate an expected delta value between the first pressure and the second pressure based on a ratio of a low-side density of the refrigerant at the compressor to the flow valve positions, and perform a remedial action where the delta value deviates from the expected delta value by greater than a threshold value.

A temperature control system includes a heater core utilizing heat of a heat medium; an engine heat exchanger utilizing exhaust heat of an engine to heat the heat medium; a condenser utilizing heat other than the exhaust heat to heat the heat medium; a heat circuit having the heater core and condenser; a communication flow path making the engine heat exchanger communicate with the heat circuit; and a connection state switching mechanism switching a flow state of the heat medium, between a first state and a second state. In the first state, the heat medium flows through the heat circuit, while flowing through the heater core, and in the second state, the heat medium flows through the heat circuit without flowing through the heater core. The heat circuit is arranged at a front of a passenger compartment, and the engine heat exchanger is arranged at a rear of the compartment.

A method for controlling air conditioning of a vehicle includes: determining whether an air conditioning control entry condition for battery cooling wind backseat backflow compensation is satisfied from environment information collected from the vehicle; starting air conditioning control for the battery cooling wind backseat backflow compensation if it is determined that the entry condition is satisfied; determining a compensation value corresponding to a current operating level of a battery cooling fan when the air conditioning control for the battery cooling wind backseat backflow compensation is started; compensating for a current control variable value of an air conditioning device component using the determined compensation value; and performing an air conditioning operation for compensation in accordance with a backflow of a battery cooling wind having cooled a battery toward a backseat by controlling a state of the air conditioning device component in accordance with the compensated control variable value.

A system and method for protecting against low refrigerant charge of a refrigerant subsystem in a vehicle includes a controller configured to control a component of the vehicle in response to detecting a low refrigerant charge based on an ambient temperature of the refrigerant subsystem, a suction pressure of refrigerant entering a compressor of the refrigerant subsystem, and a speed of the compressor.