A heat-loss management system for a vehicle and a control method thereof, which are capable of identifying a heat-insulation degree at a specific point in the vehicle so as to maintain or repair the heat-insulation performance of the vehicle.

A sensory stimulation system within an interior of an autonomous vehicle (AV) can obtain maneuver data representing one or more maneuvers to be performed by the AV. For each respective maneuver of the one or more maneuvers, the system can determine one or more visual outputs to provide a passenger of the AV with a sensory indication of the respective maneuver, and then output the one or more visual outputs via the display system.

The invention controls a power cinching function of a motor vehicle door latch in order to improve door seal performance under conditions wherein vibrations could otherwise reduce seal effectiveness. With the door latched closed in a flush condition, the vehicle speed is compared to a slow-speed threshold. When the vehicle speed is greater than the slow-speed threshold, then a vehicle vibration parameter is compared to a vibration threshold. When the vibration parameter is greater than the vibration threshold, then the power cinching function is activated to move the door to to a subflush condition which increases a compression of the seal between the door and a vehicle door frame. When the door is in the subflush condition, the vehicle speed continues to be compared to the slow-speed threshold, and when the vehicle speed is less than the slow-speed threshold then the door is released back to the flush condition.

An air handling system (1) for a land transport vehicle, in particular a railway vehicle (M) is disclosed. The system includes: one or more air handling units (2) distributed within the vehicle (M); a cooling machine (4) that supplies frigories to the air handling units; and a frigories storage unit (8) that is capable of being loaded by the cooling machine and of supplying frigories to the air handling units when the vehicle is travelling in an enclosed or partially enclosed space. When the vehicle (M) is travelling in the open air, the cooling machine (4) supplies frigories to the air handling units (2) and loads the frigories storage unit (8) if a surplus of frigories is produced, by discharging into the exterior of the vehicle (M) the heat extracted from an interior volume of the vehicle.

This disclosure relates to a motor vehicle including a climate control system with an accumulator, and a corresponding method. An example motor vehicle includes a powertrain and a climate control system configured to meet a thermal conditioning demand. The climate control system includes an accumulator and a compressor driven by the powertrain. Further, a controller is in electronic communication with the climate control system, and the controller is configured to selectively command the climate control system to charge the accumulator when an amount of energy available to the compressor from the powertrain is in excess of an amount of energy required to meet the thermal conditioning demand.

An air conditioning system for an electric transport vehicle supplied by an electrical supply network includes at least one actuator for the production of heat or cold, and a regulator configured in order to generate at least one operating command applied to the at least one actuator as a function of values for parameters representing the climatic conditions, the actuator delivering an average power over a predetermined time period. The regulator are configured in order to generate at least one operating command applied to at least one actuator as a function moreover of the value for a parameter relating to at least one electric transport vehicle supplied by the electrical supply network, the value for the parameter indicating that electrical energy is consumed by the at least one electric transport vehicle or that electrical energy is produced by the at least one electric vehicle.

A radiator assembly in a vehicle comprises a first coolant tank; a second coolant tank spaced apart from the first coolant tank; a plurality of moveable blades; a linkage coupled to the plurality of blades; and an actuator coupled to the linkage to adjust positions of the blades. Each of the plurality of blades has a first end pivotally coupled to the first coolant tank, a second end pivotally coupled to the second coolant tank and has a hollow body portion extending between the first end and the second end, and each of the blades is fluidly communicated with the first and second coolant tanks to form a coolant passage.

A method for power management of a transport refrigeration system electrically connected to a utility power source. The method including determining an operating mode for the transport refrigeration system based on one or more of an amount of utility power available from the utility power source to the transport refrigeration system, a current cost of the utility power, and a noise or emission regulation for operating a prime mover. A transport refrigeration system unit that includes a transport refrigeration unit and a controller configured to receive power from a utility power source or a primary energy source. The controller also configured to determine an operating mode for the transport refrigeration system based on one or more of an amount of utility power available from the utility power source to the transport refrigeration system, a current cost of the utility power, and a noise or emission regulation for operating the prime mover.

A vehicle climate system includes a blower and a controller. The controller is configured to, responsive to input of a particular user selected climate setting, operate the blower with an initial power having a predetermined value corresponding to the climate setting provided that cabin temperature is outside a predetermined range. The controller is also configured to operate the blower with an initial power having a value less than the predetermined value provided that the cabin temperature is within the predetermined range.

System and methods are provided for improving fuel economy, and providing optimized operating conditions associated with a vehicle's air-conditioning system when the vehicle is carrying a load, e.g., towing a trailer. Operating conditions including, for example, air-mix setting, coolant temperature, ambient temperature, vehicle speed, and whether or not the vehicle is carrying the aforementioned load, may be considered when determining whether or not to activate or deactivate a vehicle heating element, such as a positive temperature coefficient (PTC) heater, steering wheel heater, etc.