Vehicle-environment monitoring device is capable of monitoring a situation outside a vehicle. The vehicle-environment monitoring device includes an image capturing module, an image-capturing-device cover, a fan, and an air passage. The image capturing module is disposed near an inner surface of a glass member and includes a heat-generating device and an image sensor configured to capture an image of the situation outside the vehicle. The image-capturing-device cover covers the image capturing module from inside a vehicle cabin. The fan cools the heat-generating device by introducing air into the image-capturing-device cover and blows the air toward the glass member. The air passage is formed inside the image-capturing-device cover, and the air blown by the fan flows toward the glass member through the air passage.

Provided herein is a system and method for cooling a sensor enclosure of a vehicle. The system comprises one or more sensors configured to determine a speed of the vehicle, an internal temperature of an enclosure, and an external temperature. The system comprises an enclosure to house the one or more sensors. The system comprises a fan disposed at a base of the enclosure. The system comprises a controller configured to regulate a rotation speed of the fan based on the speed of the vehicle, the internal temperature of the enclosure, the external temperature, or the difference between the internal temperature of the enclosure and the external temperature. The controller operates the fan at the regulated rotation speed.

Systems and methods for heating and cooling a vehicle using a heat pump are disclosed herein. In one embodiment, a system for heating and cooling the vehicle includes a heat pump having: a compressor located in an engine compartment of the vehicle, and an evaporator located in a sleeper or a cab of the vehicle. The system also includes a controller for selecting a cooling mode or a heating mode for the heat pump. In one embodiment, the system includes a clutch for engaging the compressor with a transmission of the vehicle.

This disclosure relates to controlling temperature inside a receptacle 102 in a vehicle. In an embodiment, a temperature-controlled system for a vehicle is disclosed. The temperature-controlled system may include a receptacle 102 having at least one inlet 104, and a housing 106 fitted to the receptacle 102. The housing 106 may include an opening 108. The opening 108 may be configured to be fluidically coupled to a heating, ventilation, and air conditioning (HVAC) vent of the vehicle. The housing 106 may further include an open front face 110 fluidically coupled to the at least one inlet 104 of the receptacle 102, and a gate assembly mounted on the housing 106. The gate assembly 106 may include a gate configured to engage or disengage with the opening 108 to fluidically couple or fluidically decouple, respectively, the opening 108 to the vent.

A cooling apparatus for an autonomous driving controller may include, a chiller fluidically connected to an air-conditioning system through a refrigerant connection line so that a refrigerant circulating in the air-conditioning system provided in the vehicle is introduced into the chiller; a reservoir tank storing a coolant, and fluidically connected to the chiller; and a water pump mounted between the reservoir tank and the autonomous driving controller;, wherein coolant pipes connected to the water pump and the chiller may be connected to the autonomous driving controller respectively.

An conditioning device for a fuel cell vehicle includes a heater core configured to heat air in a vehicle cabin with a coolant to be discharged from a FC stack cooled by the coolant as a heat source, a coolant heating heater configured to heat the coolant, an air heating heater configured to further heat air warmed by the heater core, and a vehicle ECU configured to, in a case where a heater core outlet coolant temperature based on a target blowing temperature is equal to or higher than an FC stack inlet target temperature, perform control such that the air heating heater is operated with an output set based on the heater core outlet coolant temperature, and the coolant heating heater is operated with an output set based on a heater core inlet target coolant temperature calculated according to the set output of the air heating heater.

Example embodiments relate to an air cooling system for an electronic spinning assembly. An example embodiment includes a plurality of vanes coupled to a static base. A vane cover is rotatably coupled to the static base. The vane cover at least partially encloses the plurality of vanes. Additionally, the vane cover is coupled to an electronic spinning assembly and configured to rotate with the spinning assembly. The vane cover further includes at least one air inlet configured to act as an air intake for an airflow, at least one air duct extending from the vane cover and configured to direct the airflow, and at least one choke point disposed in the cover. The at least one choke point is configured to increase a pressure of the airflow.

A method is described for operating a refrigeration system having a heat pump function for motor vehicle, including the following steps: setting a heat pump operation, in which the refrigerant is routed from the refrigerant compressor into the secondary line; setting an expansion valve assigned to the third heat exchanger such that a total mass flow of refrigerant flows through the third heat exchanger; detecting the temperature of the coolant in the third heat exchanger. The total mass flow of refrigerant is routed through the third heat exchanger when the temperature of the coolant is greater than an upper limiting temperature.

Systems and methods for controlling a temperature of a compartment of a vehicle are provided. The vehicle system includes a compartment, one or more processors, one or more memory modules communicatively coupled to the one or more processors; and machine readable instructions stored in the one or more memory modules that, when executed by the one or more processors, cause the one or more processors to receive information about an item; determine whether the item needs to be temperature controlled based on the information; and instruct a temperature control system to adjust a temperature of the compartment of the vehicle in response to determining the item needs to be temperature controlled.

A cooling structure for an electronic control unit which is mounted in a vehicle, includes: a duct having a flow channel on which the electronic control unit is disposed; and a blower configured to take air in the inside of the vehicle and to emit the air to the flow channel of the duct, wherein the duct is configured to: cool the electronic control unit with the air emitted from the blower; and discharge air which has been used to cool the electronic control unit to the outside of the vehicle.