The invention relates to a surface temperature-controlling device, in particular for use in vehicles, comprising a first air-distributing layer which has multiple air inlets extending through the first air-distributing layer and multiple air outlets extending through the first air-distributing layer, and a second air-distributing layer which fluidically connects air inlets and air outlets of the first air-distributing layer, wherein the air inlets are designed to introduce pre-heated or pre-cooled air into the second air-distributing layer, and the air outlets are designed to discharge air out of the second air-distributing layer.

A base station is disclosed that is configured for use with a UAV. The base station includes: an enclosure with an outer housing that defines a roof section and an inner housing that is connected to the outer housing; one or more heating elements that are supported by the enclosure and which are configured to heat the roof section; one or more fiducials that are supported by the enclosure; an illumination system that is supported by the enclosure and which is configured to illuminate the one or more fiducials; and a visualization system that is supported by the enclosure.

A temperature modulation assembly for a motor vehicle's passenger compartment includes an assembly panel having a single or a plurality of solar panels which convert sunlight into electricity and an assembly housing which includes an internal thermoelectric Peltier cooler having a heat sink on its cool side and a heat sink on its hot side and an internal fluid distribution module which draws air into the assembly housing, causes some of the air to be cooled by passing through the cool side heat sink and directed back into the passenger compartment and the rest of the air to be heated by passing through the hot side heat sink and directed back into the passenger compartment. The components of the assembly housing utilize electricity that originates at the assembly panel, and the assembly housing is structured to distribute cooled towards near the passenger seating and heated air towards the windshield.

A vehicle occupant air curtain system includes a seat that has a seat cushion and a seat back. The seat back has a region that is configured to be arranged above an occupant shoulder. An air vent is supported on the seat back and is arranged in the region. The air vent is configured to be directed adjacent to a seated occupant's head and neck.

A vehicular air conditioner includes a first outlet that blows a conditioned air frontward to flow past a neck part of an occupant on a seat, and a second outlet that is provided below the first outlet and blows the conditioned air upward to flow past an armpit part of the occupant. The second outlet blows the conditioned air to merge with the conditioned air blown from the first outlet. The second outlet blows the conditioned air with an airflow volume larger than an airflow volume of the conditioned air from the first outlet such that the conditioned air blown from the second outlet guides the conditioned air blown from the first outlet to flow along a face of the occupant.

Methods and systems for providing multi-zone climate control for a vehicle. One system includes a power source, a plurality of switches, a first zone heating/cooling device, a second zone heating/cooling device, and an electronic controller. The electronic controller is configured to operate the plurality of switches to supply current bi-directionally through the first zone heating/cooling device, bi-directionally through the second zone heating/cooling device, or bi-directionally through a series connection of the first zone heating/cooling device and the second zone heating/cooling device.

An apparatus, according to an exemplary aspect of the present disclosure includes, among other things, a vehicle door panel, a removeable structure having a retention member fixed on the vehicle door panel, and a holding element associated with the retention member to provide a pocket that can be configured in different ways to accommodate a plurality of powered devices. A power interface in the vehicle door panel powers at least one of the plurality of powered devices. A method according to an exemplary aspect of the present disclosure includes, among other things, providing the power interface in the vehicle door panel to power at least one of the plurality of powered devices, and providing a communications link between at least one of the plurality of powered devices and a vehicle touchscreen or control.

A temperature modulation assembly for a motor vehicle's passenger compartment includes an assembly panel having a single or a plurality of solar panels which convert sunlight into electricity and an assembly housing which includes an internal thermoelectric Peltier cooler having a heat sink on its cool side and a heat sink on its hot side and an internal fluid distribution module which draws air into the assembly housing, causes some of the air to be cooled by passing through the cool side heat sink and directed back into the passenger compartment and the rest of the air to be heated by passing through the hot side heat sink and directed back into the passenger compartment. The components of the assembly housing utilize electricity that originates at the assembly panel, and the assembly housing is structured to distribute cooled towards near the passenger seating and heated air towards the windshield.

Examples of the present disclosure relate to systems and methods for providing cooling and/or heating in a vehicle. For example, the systems and methods may cool and/or heat a vehicle cabin while the vehicle’s engine is not idling or otherwise in operation, without consuming excessive power stored by a vehicle battery. In example implementations, thermoelectric cooling cells may be used.

A system for controlling an internal temperature of a vehicle when an engine is turned off includes a temperature sensor configured to measure an internal temperature (Ti) of a vehicle; a first blower configured to discharge cooled air when an electric power is supplied to the first blower; a battery; and a control unit electrically connected to the temperature sensor and the first blower and configured to receive the internal temperature (Ti) of the vehicle from the temperature sensor, and to operate the first blower, in which the control unit electrically connected to the battery is configured to control an electric power of the battery to be applied to the first blower when the internal temperature (Ti) of the vehicle is equal to or greater than a predetermined reference temperature (Tr) in a state where an engine of the vehicle is turned off.