The present disclosure provides a power transmission device in which stress is reduced and a vehicle air-conditioning device. An air-conditioning device has an inside/outside air door. A power transmission device drives the inside/outside air door. The power transmission device has a motor, a gear train, and a cam mechanism. A first gear of the gear train provides a rotatable member. A plurality of lock mechanisms is provided, which stops a rotation of the first gear at one end and/or the other end in a rotation direction of the first gear. The plurality of lock mechanisms provide a plurality of contacts between the first gear and a stationary link cover.

There is provided a vehicle comprising a thermal conditioning system and a cabin. The thermal conditioning system comprises a fan (102), a first heat exchanger (104), an outside air duct (112), a cabin air duct (114), a sensor, and a control unit (122). The fan is configured to generate a flow of air. The first heat exchanger is arranged to transfer heat to the flow of air. The thermal conditioning system is configured to be operated in a first mode and a second mode. In the first mode, the fan rotates in a first direction to direct the flow of air along a first flow path. In the second mode, the fan rotates in a second direction opposite to the first direction to direct the flow of air along a second flow path. The sensor is arranged to provide a signal representative of a temperature of a part of the vehicle. The control unit is configured to switch the thermal conditioning system between the first mode and the second mode based on the signal.

A vehicle has a storage bin positioned between the seat and the rear wall of an interior compartment. The storage bin includes a receiving portion and louvered portion. The receiving portion is defined by a peripheral wall and a bottom. The louvered portion is coupled with the receiving portion. The louvered portion includes at least one window. An air flow path is defined by the storage bin. The air flow path enables air to pass into and through the at least one window under the receiving portion bottom and out through an exhaust vent in the rear wall.

A motor-vehicle includes one or more electrically-operated valves, arranged on the structure of the motor-vehicle in a lower position with respect to the windows, for providing a communication between a passenger compartment and the external environment, and one or more electronic control units programmed to activate a ventilation mode of the passenger compartment when the motor-vehicle is parked with the engine off, even with the driver outside the vehicle. The ventilation mode includes controlling at least partial opening of one or more windows and the opening of one or more of the valves to generate a flow of natural air from the bottom upwards through the passenger compartment of the motor-vehicle.

System, methods, and other embodiments described herein relate to assisting in closing a trunk door of a vehicle by leveraging a Heating, Ventilation and Air-conditioning (HVAC) system in the vehicle. In one embodiment, a method includes detecting a position of the trunk door, and when the position of the trunk door is an open position, determining whether to activate the HVAC system to reduce air pressure in a trunk of the vehicle, where the trunk and the HVAC system are fluidly connected by an air duct. The method includes, in response to determining to activate the HVAC system to reduce air pressure in the trunk, pumping air out of the trunk through the air duct such that at least some of any increased air pressure caused by a trunk door closure is removed from the trunk. The method includes, when the position of the trunk door has changed from the open position to a closed position, deactivating the HVAC system to stop pumping air out from the trunk.

There is disclosed an environmental control system for thermally conditioning air within an enclosed space comprising: a refrigerant circuit having a compressor, an indoor heat exchanger, an expansion device, and an outdoor heat exchanger. The system further comprises an intake flowpath for directing an intake flow of fresh air to the enclosed space, wherein a heat-transfer section of the indoor heat exchanger is located within the intake flowpath to thermally condition the intake flow of fresh air before entering the enclosed space. The system further comprises an exhaust flowpath for directing an exhaust flow of thermally conditioned air to an external environment. A recovery heat exchanger is provided to transfer thermal energy between the exhaust flow and the intake flow at a location within the intake flowpath that is upstream of the heat-transfer section of the indoor heat exchanger.

A climate control system for a vehicle includes a front-end or first heat exchanger configured to thermally condition airflow from an environment external to a vehicle cabin, a rear-end or second heat exchanger configured to thermally condition airflow from the vehicle cabin, a recirculation path configured to return airflow from the second heat exchanger to the vehicle cabin, and an extraction path configured to vent airflow from the second heat exchanger to the environment external to the vehicle cabin. Various operational modes of the climate control system direct airflow to either the recirculation path or the extraction path.

A vehicle air purging system includes a vehicle body that defines an interior. A support member is coupled to the vehicle body. The support member defines a receiving cavity. The support member defines an aperture proximate the receiving cavity. A one-way valve is coupled to the support member and is disposed within the aperture. A fan is coupled to the support member. The fan includes an outlet aligned with the aperture. A controller is operably coupled to the fan. The controller is configured to activate the fan to blow air from the interior to an area external to the vehicle body through the one-way valve.

A passenger transport vehicle, such as a rail vehicle, has at least one sanitary module and at least one fan for conveying waste air from the sanitary module. A control unit controls the volumetric flow of waste air from the sanitary module. The control unit is formed for at least two volumetric flows of waste air, which differ from one another and differ from zero. The volumetric flows are conveyed by the at least one fan, at least on the basis of a state of the sanitary module.

An air intake system for a vehicle comprises an exterior air inlet disposed on the vehicle that receives air from an exterior of the vehicle. An air outlet is disposed on the vehicle that supplies air to an engine of the vehicle. A conduit network connects the exterior air inlet and the air outlet. An interior air device disposed on the vehicle is connected to the conduit network allowing air from an interior of the vehicle into the engine. A base plate with an opening is attached to the conduit network. A hatch connected the base plate allows air from the interior of the vehicle through the opening.