Provided are systems and methods for enclosing an energy source of a material handling vehicle. The systems and methods include an enclosure having a front wall, a rear wall, and an interior compartment, an inlet channel integrally formed with the front wall and in fluid communication with the interior compartment, the air inlet channel defined by an inlet louver and an inlet flange, an outlet channel integrally formed with the rear wall and in fluid communication with the interior compartment, the air outlet channel defined by an outlet louver and an outlet flange, one or more energy source cells positioned within the interior compartment; and a cooling fan in fluid communication with the inlet channel and the interior compartment. The cooling fan operates to draw air through the inlet channel to the interior compartment such that air within the interior compartment is expelled out of the outlet channel.

An in-vehicle computer includes a computer casing, an electronic component, a fan, and an air duct. The electronic component and the fan are disposed inside the computer casing. An air inlet of the air duct is located outside the computer casing, and an air outlet thereof is toward or connected to the fan. The fan can generate an airflow for dissipating heat from the electronic component. Therein, the computer casing, the fan, and the air duct therefore form a heat dissipating system. A vehicle includes a vehicle cage and the in-vehicle computer. The in-vehicle computer is disposed inside the vehicle cage. The air inlet of the air duct communicates with the interior space of the vehicle cage, so that when the air conditioner of the vehicle is turned on, the fan can draw the cold air from the cockpit space for enhancing the heat dissipation efficiency.

A sensor assembly for a vehicle includes a base, a sensor body mounted to the base and rotatable relative to the base around an axis in a direction of rotation, and a cover. The sensor body includes a sensor window and a wall having heat fins elongated circumferentially relative to the axis. The cover is positioned to cover the heat fins. The cover includes an inlet open in the direction of rotation. The cover defines an airflow path from the inlet through the heat fins. The cover includes an outlet positioned to direction air across the sensor window.

An apparatus to cool electronics in an autonomous vehicle, where the autonomous vehicle includes significant computing power to receive data from on-board sensor, cellular data and user interactions and to navigate an environment to a predetermined location. The cooling system includes a radiator, fan, pump and cold plate. The cold plate is formed from two plates with extended surfaces that are mated together so that the cavities around the extended surfaces form a flow passage. The electronics processing the data and navigating are mounted on the outside surface of the cold plate.

A temperature conditioning unit includes a first temperature conditioning unit part, a second temperature conditioning unit part, and a blower (centrifugal blower). The first temperature conditioning unit part includes a first housing, a first air hole part, a first air chamber, a first object to be temperature-conditioned, and a second air chamber. The second temperature conditioning unit part includes a second housing, a second object to be temperature-conditioned, a second air hole part, and a third air chamber.

A cooling system for an eco-friendly vehicle is provided. The system includes an electronic component cooling device that cools an electronic component of an eco-friendly vehicle and a battery cooling device that cools a battery installed within the eco-friendly vehicle. A connector connects the electronic component cooling device and the battery cooling device with each other.

A propulsion control device of the present disclosure includes: a housing; a gate controller disposed at one end side of an interior space of the housing in a longitudinal axis direction X, the gate controller being configured to control a power converter; a fan disposed under the gate controller, the fan being configured to feed air to the gate controller; and an airflow guide member disposed at the side opposite to the fan relative to the gate controller, having, on an interior face of a ceiling of the housing, an airflow guide face having a predetermined angle with respect to the vertical direction, the airflow guide member being configured to guide air passed through the gate controller to flow toward the other end side of the interior space of the housing in the longitudinal axis direction X.

This application discloses a vehicle-mounted device comprising: a first temperature equalization board and a PCB are fastened inside a housing. The first temperature equalization board is close to a first inner wall of the housing. The PCB is close to a second inner wall of the housing. The first inner wall is opposite to the second inner wall. A first protrusion is disposed on a side that is of the first temperature equalization board and that is close to the PCB. A first heat pipe is disposed on a side that is of the first temperature equalization board and that is close to the first inner wall. A first heat emission component is disposed on a side that is of the PCB and that is close to the first temperature equalization board. A position of the first protrusion corresponds to a position of the first heat emission component.

Provided herein is a system and method for heat exchange of a vehicle. The system comprises an enclosure disposed on the vehicle. The enclosure comprises a vent at a base of the enclosure. The enclosure houses one or more sensors. The enclosure comprises a fan disposed at a base of the enclosure. The heat exchange system comprises an deflector disposed on the vehicle outside the enclosure and configured to direct an airflow into the vent of the enclosure. The heat exchange system comprises a motor configured to: generate electricity from the airflow and selectively supply electricity to operate the fan. The heat exchange system comprises a controller configured to adjust the deflector and regulate an amount of electricity supplied from the motor to the fan.

Provided herein is a system and method for heat exchange of a vehicle. The system comprises an enclosure disposed on the vehicle. The enclosure comprises a fan disposed at a base of the enclosure, one or more sensors within the enclosure, and a cover on an exterior of the enclosure. The cover comprises a hole pattern to selectively permit an airflow to enter the enclosure. A deflector is disposed on the vehicle outside the enclosure and configured to direct an airflow through the hole pattern.