Provided is a thermal management system. A compressor comprises a first flow channel for circulating a refrigerant and a second flow channel for circulating a cooling liquid, the first flow channel of the compressor being not in communication with the second flow channel of the compressor. The thermal management system can simultaneously execute a first refrigerating mechanism and a cooling mechanism, and can realize thermal management of both a vehicle compartment and a compressor; in the cooling mechanism, the cooling liquid flows through the second flow channel of the compressor, then waste heat of the compressor is brought to a third heat exchanger (14) by means of circulation flow of the cooling liquid, and heat is released into an atmospheric environment by means of the third heat exchanger (14), thereby reducing the temperature of the cooling liquid, and the compressor is cooled by means of circulation flow of the cooling liquid, such that the temperature of the refrigerant at an inlet of a compression assembly of the compressor is low, the concentration of the compressed refrigerant is high, such that the compression efficiency of the compressor can be increased, thereby increasing the working efficiency of the compressor.

A method for operating a refrigeration system for a vehicle, the refrigeration system including a refrigerant circuit with a heat pump function. The refrigerant circuit has an exterior heat exchanger, which is operated as a condenser or gas cooler to perform a refrigeration system mode or which is operated as a heat pump evaporator to carry out a heat pump mode. The refrigerant circuit further has an interior heating condenser or heating gas cooler for carrying out a heating mode. The interior heating condenser or heating gas cooler is fluidically connected downstream of the exterior heat exchanger with a reheating expansion device therebetween to carry out a reheating mode. The opening cross-section of the reheating expansion device is controlled in accordance with a refrigeration system parameter indicating the required reheating power.

An air conditioning system for a motor vehicle. The air conditioning system includes a refrigerant circuit divided into a high-pressure region and a low-pressure region, first and second internal heat exchangers arranged in the high-pressure and low-pressure regions, an external heat exchanger arranged in the refrigerant circuit, a condenser arranged in the high-pressure region, and an evaporator that, in a first operating mode, thermally couples the low-pressure region to the air conditioning air and, in a second operating mode, is arranged outside the refrigerant circuit.

A modular cooling system for a vehicle including a base module having a refrigerant compressor, a high-pressure section having a direct or indirect condenser or gas cooler, and a low-pressure section having an evaporator and a chiller having chiller expansion elements connected upstream. The low-pressure section is connected via a heat pump expansion element to the high-pressure section. A first supplementary module has a heating branch having a heat pump heat exchanger, which is connectable via a first reheating branch having a valve element to the direct or indirect condenser or gas cooler, and a heat pump recirculation branch having a blockable valve element for connecting the direct or indirect condenser or gas cooler to the low-pressure section.

The invention relates to a vehicle thermal management system (1) comprising at least a refrigerant circuit (2), a loop (3) for heat-transfer liquid, and a first heat exchanger (5) which thermally couples the loop (3) for heat-transfer liquid with the refrigerant circuit (2), the loop (3) for heat-transfer liquid comprising at least one heat exchanger (12, 35) configured to dissipate heat energy into a flow (18, 19) of air, the refrigerant circuit (2) comprising at least a compression device (4), the first heat exchanger (5), a refrigerant accumulation device (6), a first expansion device (16) and a second heat exchanger (17) designed to have passing through it a flow (18) of interior air sent into the interior of the vehicle, characterized in that the refrigerant circuit (2) comprises a leg (20) arranged in parallel with the first expansion device (16) and with the second heat exchanger (17), said leg (20) comprising a second expansion device (21) and a third heat exchanger (22) able to be thermally coupled to at least a component of an electric powertrain of the vehicle.

An air conditioning system for a motor vehicle is disclosed. The air conditioning system includes a refrigerant circuit divided into a high-pressure region and a low-pressure region, first and second internal heat exchangers arranged in the high-pressure and low-pressure regions, an external heat exchanger arranged in the refrigerant circuit, a condenser arranged in the high-pressure region, and an evaporator that, in a first operating mode, thermally couples the low-pressure region to the air conditioning air and, in a second operating mode, is arranged outside the refrigerant circuit.

Systems and methods are described herein for controlling heat flow between systems of an electric automotive vehicle. An automotive electric vehicle system includes a high voltage battery system including an enclosure, an electric powertrain system, a radiator, coolant lines that permit coolant flow between the high voltage battery system, the power train system and the radiator, one or more valves for routing coolant along the coolant lines, and a controller. The controller is configured to control the one or more valves to control the flow of coolant among a plurality of different, selectable coolant flow states involving the high voltage battery system, the powertrain system and the radiator.

A vehicle HVAC system includes a compressor, a first heat exchanger for exchanging heat between the refrigerant outside air, a first check valve set, a first expansion device for decompressing a first portion of the refrigerant, a second heat exchanger for exchanging heat between the first portion of the refrigerant and a second portion of the refrigerant, a second expansion device for decompressing the second portion of the refrigerant, a second check valve set, a third heat exchanger for exchanging heat between the refrigerant and inside air, and a selector valve for switching between a heating mode and a cooling mode. The first check valve set and the second check valve set together maintain a constant flow direction through the first expansion device, the second heat exchanger, and the second expansion device in the heating mode and the cooling mode.

A vehicle air conditioning system is provided that performs air conditioning for a front row and a rear row by using a heat pump to optimize cooling and heating efficiency, thereby preventing cooling and heating energy from being wasted.

Systems and methods are described herein for controlling heat flow between systems of an electric automotive vehicle. An automotive electric vehicle system includes a high voltage battery system including an enclosure, an electric powertrain system, a radiator, coolant lines that permit coolant flow between the high voltage battery system, the power train system and the radiator, one or more valves for routing coolant along the coolant lines, and a controller. The controller is configured to control the one or more valves to control the flow of coolant among a plurality of different, selectable coolant flow states involving the high voltage battery system, the powertrain system and the radiator.