A method according to an exemplary aspect of the present disclosure includes, among other things, controlling a climate control system of an electrified vehicle by shutting off refrigerant flow to a rear portion of a heat pump subsystem in response to a defrost request.

A control device for a vehicle heater includes: a camera; a heater configured to heat a portion of the window glass located in front of the camera; a temperature sensor configured to acquire a camera temperature; an illuminance acquisition unit configured to acquire an illuminance outside the vehicle; and a control unit configured to determine that a control prohibition condition to prohibit execution of the heater energization control is satisfied when the camera temperature is equal to or larger than a prohibition threshold temperature, execute the heater energization control when execution of the heater energization control is requested, prevent execution of the heater energization control when the control prohibition condition is satisfied, and when the illuminance is lower than a threshold illuminance, set the prohibition threshold temperature to be lower than when the illuminance is equal to or larger than the threshold illuminance.

A surface heating system of an external surface of a vehicle system includes a heater and a heater controller. The heater is configured to provide heat to the external surface. The heater controller is configured to control a heater power of the heater based upon an air temperature of air external to the vehicle, a liquid water content of the air, and a speed of the vehicle.

An electronics systems cluster includes a plurality of brackets, a plurality of electronic devices held in the plurality of brackets and an interlocking feature securing the plurality of brackets directly together into a small footprint configuration less likely to interfere with driver sight lines. A related method of reducing a footprint of an electronics systems cluster is also disclosed.

An arrangement of air outlets on a motor vehicle air conditioning unit, wherein side window outlets, side occupant air outlets, and center occupant or additional vent air outlets are configured as pairs and the side occupant air outlets and the center occupant or additional vent air outlets are arranged in one tier, wherein from outside to inside are, first, the center occupant or additional vent air outlets and then the side occupant air outlets.

An optical device includes a printed circuit board comprising an electronic image-capturing circuit, a lens holder comprising at least one optical lens, the lens holder being mounted on the printed circuit board so as to align, along the optical axis of the device, the electronic image-capturing circuit and the optical lens; a heating element positioned on the lens holder; the heating element being linked electrically to the printed circuit board by at least one electrically conductive trace positioned on the lens holder.

A method for producing a heatable luminaire cover is described. The heatable luminaire cover has: a polymeric main body, a first busbar, a second busbar and at least two conductor tracks on the inside of the polymeric main body.

A heated light enclosure having an adaptable heating system is provided with a controlled heating system to deliver enough heat to a lens on a lamp assembly to remove snow, frost, and/or condensation without overheating the lens. By heating the lens using a combination of one or more of PTC heaters, heat sinks and heat pipes, accumulation of snow, ice, or vapor is mitigated or eliminated from a surface of the lens, thereby enabling light to transmit through the lens. Applications include lamps and bulbs on conveyance devices, including vehicles, boats, planes, and trains, as well as sedentary structures, such as lamp posts, street lights, railroad crossing markers and lights, and airport ground and runway lighting systems.

An individual air conditioning apparatus for a vehicle includes: a driver's seat air conditioning module and a passenger seat air conditioning module sequentially provided with an evaporation core and a heater core; a first channel that passes through the evaporation core and is connected to an indoor outlet; a second channel that passes through the evaporation core and the heater core and is connected to the indoor outlet; and a temperature control door that opens and closes the first channel and the second channel.

A blowout portion of an air discharge device includes a blowout port and a blowout passage that guides air toward the blowout port. Further, an air flow manipulation member of the air discharge device is disposed in the blowout passage and includes a guide wall. The air flow manipulation member switches between a first operation state that throttles an air flow flowing in one side passage which is part of the blowout passage to cause the air flow to flow along a passage guide surface of the blowout portion, and a second operation state that reduces the throttling of that air flow. The guide wall is arranged to regulate air flow when the air flow manipulation member is in the second operation state, and to substantially not regulate air flow when the air flow manipulation member is in the first operation state.