A vehicle roof assembly includes a roof that defines an aperture. A heating, ventilation, and air conditioning assembly is selectively disposed within the aperture. The heating, ventilation, and air conditioning assembly includes a housing defining an interior. The housing defines an intake and a vent opening. The intake is defined on a first side of the housing. A fan is disposed within the interior on a second side of the housing. The second side opposes the first side. A duct is disposed within the interior. The duct extends between the first side and the second side of the housing. The duct fluidly couples the intake with the vent opening.

A bracket configured to mount a high voltage component to a structure of a vehicle. The bracket includes a body, a plurality of first apertures formed in the body that are each respectively configured for receipt of a fastener that secures the body to the high voltage component, and a plurality of second apertures formed in the body that are respectively configured for receipt of a fastener that secures the body to the structure of the vehicle. Upon application of a sufficient force to the vehicle, a material of the body that forms at least one of the first apertures and the second apertures is configured to fail to permit either the body and the high voltage component to disengage from structure of the vehicle or the high voltage component to disengage from the body.

A vehicle system is described that includes a multi-phase rotary electric motor rotatably coupled via a rotatable member to an air-conditioning compressor, and a remotely located rechargeable energy storage system (RESS). The RESS includes a first power inverter that is electrically coupled to the multi-phase rotary electric motor via a plurality of electric power cables, a second power inverter that is electrically coupled to a second electric machine, a DC power source, and a chiller. A controller is in communication with and controllably coupled to the first power inverter and the second power inverter. The controller is operative to control the first power inverter to operate the multi-phase rotary electric motor in an open-loop control scheme.

A fluid heat exchange assembly includes a fluid control module and a fluid heat exchange module, the fluid control module includes a first connecting lateral portion, the fluid heat exchange module includes a second connecting lateral portion; the first connecting lateral portion and the second connecting lateral portion are oppositely and sealingly arranged; the fluid heat exchange module includes a heat exchange core and a connecting component fixed by welding; the fluid control module includes at least a first flow passage and a second flow passage; the fluid heat exchange module includes a first fluid communication cavity, and the second flow passage is in communication with the first fluid communication cavity; the connecting component includes a connecting channel, the connecting channel penetrates through the connecting component. The fluid heat exchange assembly reduces pipeline arrangement and is of a small and compact integral structure.

An air-conditioning device includes: a compressor; an outdoor heat exchanger; an evaporating unit configured to evaporate refrigerant a heater unit configured to heat the air by using the heat of the refrigerant a liquid receiver arranged at the downstream side of the outdoor heat exchanger and a restrictor mechanism provided between the heater unit and the outdoor heat exchanger, wherein, in an operation state in which the flow of the refrigerant is restricted by the restrictor mechanism and heat is released in the heater unit, a first operation mode and a second operation mode are switched, the first operation mode being set such that the liquid-phase refrigerant is stored in the liquid receiver and the gaseous-phase refrigerant is guided to the compressor and the second operation mode being set such that the liquid-phase refrigerant stored in the liquid receiver is guided to the evaporating unit.

An apparatus and methods are provided for an air conditioning system for an off-road vehicle that includes an enclosed cabin. The air conditioning system includes a compressor that may be driven by an engine of the vehicle or a dedicated motor. A condenser comprising the air conditioning system may be positioned behind a grill at a front of the off-road vehicle or at a location where outside air enters an engine compartment of the off-road vehicle. An evaporator and a blower direct a cooled airstream into the enclosed cabin. One or more adjustable vents are disposed within the enclosed cabin and positioned to advantageously direct the cooled airstream to occupants within the enclosed cabin. Climate control switches are disposed in a dashboard of the off-road vehicle and configured to enable the occupants to operate the air conditioning system.

An internal return pump is disclosed for a heat engine converting energy from a vapor source to an output device. The heat engine comprises a heat engine body having a sealed first and a second heat engine body end with a heat engine piston is located in the heat engine bore. A heat engine piston rod is connected to the heat engine piston and extending from the second heat engine body end. A first valve and a second valve assembly communicating with the heat engine bore for reciprocating the heat engine piston within the heat engine bore. A condensate pump operated by the heat engine piston rod extending from the second heat engine body end for pumping low pressure vapor to the low pressure vapor return of the vapor source. An output section connecting said heat engine piston rod extending from said second heat engine body end to the output device.

An external automotive condenser and light assembly for mounting on a body of a vehicle, the condenser and light assembly includes a condenser housing having a top portion defining at least one top opening and a bottom portion defining at least one bottom opening. The condenser housing includes a front face so as to permit at least one warning light to be affixed thereto. The condenser housing includes a right face extending rearward from the front face. The condenser housing includes a left face extending rearward from the front face. At least one warning light is affixed to an exterior of the front face.

An accumulator (28), optionally in combination with an internal heat exchanger in a shared housing (24), comprising a cyclone (12) for separation of the gas and liquid phase of a refrigerant, and characterised in that the cyclone (12) comprises two separate, curved flow paths (14, 16), one of which (14) leads from an inlet (18) on the cover side whose direction of flow is closer to the axial than the radial direction of the cyclone (12) into the accumulator and radially outwards, and the other of which (16, 52) leads outwards from an end facing away from the cover (20).

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.