A server includes a printed circuit board (PCB), an electronic component connected to the printed circuit board, and a chassis connected to the PCB. The chassis includes a first end with a first aperture configured to allow airflow into the server, a second end with a second aperture configured to allow the airflow out of the server after having passed across the electronic component, and a temporary bulkhead that is movable between a deployed position and a stowed position, wherein in the deployed position, the temporary bulkhead is connected to the PCB and extends across the server in a path of the airflow, and wherein in the stowed position, the temporary bulkhead is disconnected from the PCB and is positioned to open the path of the airflow.

A server includes a printed circuit board (PCB), an electronic component connected to the PCB, and a chassis connected to the PCB. The chassis includes a first end with a first aperture configured to allow airflow into the server, a second end with a second aperture configured to allow the airflow out of the server after having passed across the electronic component, and a movable bulkhead comprising a first set of louvers, the movable bulkhead being movable between a closed position and an opened position, wherein each of the louvers includes a leading edge contact feature configured to interface with a trailing edge of a respective adjacent louver. In the closed position, the first set of louvers forms a wall in a primary path of the airflow, and, in the opened position, the first set of louvers are oriented in a direction of the primary path of the airflow.

In a housing of a vehicle control device are formed a suction port for taking outdoor air and a discharge port for discharging air taken in through the suction port. A flow passage that connects the suction port and the discharge port is formed inside the housing. A blocking member, a radiator, and a blower are provided in the flow passage. The blocking member is provided at a position where the blocking member faces at least a portion of an opening face of the suction port in the flow passage and a distance between the blocking member and the suction port is in a predetermined range.

An information handling system includes a computing device, a computing component of the computing device that is housed in a chassis, and a chilled air filter that reduces a humidity level of a portion of an airflow when the chilled air filter is in an active state. The portion of the airflow thermally manages the computing component. The airflow is received by the chassis via an air receiving exchange and exhausted by the chassis via an air expelling exchange.

A fan arrangement has a plurality of fans arranged in parallel to each other and configured to generate airflow along a common main flow direction. A flow channel is assigned to each fan, and a respective flow channel has a flap that can be swiveled between an open position and a closed position. The flap is constructed and positioned within the flow channel in such a way that it is supported by the airflow in the open position and brought into the closed position by a reverse flow opposing the airflow. This arrangement reliably prevents a fluidic short circuit in the event of failure of individual fans, and ensures natural draft convection in the event of failure of all fans. The flap is constructed in such a way that it is brought into the open position when no air is flowing due to its intrinsic weight.

A noise reduction assembly includes an outer frame and a partition plate. An accommodating cavity is arranged in the outer frame; the partition plate is arranged in the accommodating cavity, and the partition plate and the outer frame form a noise reduction channel, the noise reduction channel includes a first noise reduction section, a second noise reduction section and a third noise reduction section that are communicated in sequence, and the channel cross-sectional areas of the first noise reduction section and the third noise reduction section are both smaller than the channel cross-sectional area of the second noise reduction section. The technical solution of the present application may reduce the noise of a new energy equipment having the noise reduction assembly during operation.

A power conversion device includes a housing, a power conversion unit, a fan, and a flexible shutter. The shutter is in a sheet shape. The shutter includes an end portion and a movable portion, the end portion being fixed to at least one of the housing and a frame body, the movable portion being movable with respect to the housing. The shutter is configured to be deformed by wind from the fan in a case where the fan is driven and to form a gap through which the wind passes between the shutter and at least one of the housing and the frame body.

Disclosed is an electrical cabinet with associated air flow direction and heat separation control system. The cabinet has a front, rear, a first side and a second side. The front side has openings to accept flow of cool air into the cabinet and the rear side has openings for exit of warm air from the rear side of the cabinet. The front, rear, first side and second side define an interior space are configured to house heat generating electrical equipment. A frame is adjacent the rear side of the cabinet. The frame has a first frame side and a second frame side. Louvers are located adjacent the rear of the cabinet. The louvers extend between the first frame side and the second frame side. Each louver has a face positioned at an angle to direct the warm air exiting the cabinet other than perpendicular to the rear of the cabinet. A first compartment for storing heat generating equipment is positioned above or below a thermally separated second compartment for storing heat sensitive equipment.

In some examples, a system uses ambient air from outside a controlled airflow environment to cool equipment within the controlled airflow environment. The system can include ductwork that seals the ambient air from air outside of the ductwork within the controlled airflow environment. The system can further include a passive heat exchanger connected to the equipment and extending into an interior of the ductwork to allow heat exchange between the equipment and the ambient air. The system can further include a fan to flow the ambient air through the ductwork, the fan being connectable to the equipment to allow the equipment to control the operation of the fan.

A dust collector includes a housing, a passage structure and a dust collecting region. The passage structure is disposed in the housing, and configured to accelerate an airflow containing dust particles and separate the dust particles from the airflow. The dust collecting region is connected to the passage structure, and is configured to collect at least part of the dust particles of the airflow.