A cooling device includes an upper flat plate-shaped member and a lower flat plate-shaped member disposed with a predetermined interval therebetween, a heat radiation fin configured to extend from the upper flat plate-shaped member toward the lower flat plate-shaped member and to form a flow path through which air flows between the upper flat plate-shaped member and the lower flat plate-shaped member, and a centrifugal fan having an inlet as an opening and an outlet configured to be open in a direction intersecting an opening direction of the inlet, wherein the centrifugal fan is disposed at a position separated from the upper flat plate-shaped member by a predetermined interval so that the outlet is open toward the flow path, and a protruding part that protrudes toward the centrifugal fan is provided on the upper flat plate-shaped member.

A heat sink comprises a bottom plate and a plurality of fins. The bottom plate is formed in a T-shape of a head portion and a body portion and includes a coupling region in which the body portion is thermally coupled to a heat generation element; and the plurality of fins that are erected at the head portion and the body portion of the bottom plate and extend in a direction from the head portion toward the body portion. With the plurality of fins, a pressure loss of first air which flows through a center portion of the head portion is smaller than a pressure loss of second air which flows through a side portion of the head portion in a case where air flows between the plurality of fins along the direction.

The present application discloses a sound absorbing device to be placed in an airflow that is in a first direction. The sound absorbing device includes a housing; a plurality of sound absorbing units disposed in the housing to be passed by the airflow, the plurality of sound absorbing units being arranged in a direction perpendicular to the first direction, any two adjacent sound absorbing units being separated by a gap; and a plurality of supports fixed in the housing. The plurality of sound absorbing units are fixed to the housing through the plurality of supports.

According to one embodiment, a memory system includes a first plate, an intermediate member, and a substrate. The intermediate member includes a second plate and a pair of side walls. The second plate includes a first opening, and is arranged to have a gap with respect to the first plate. The second plate includes a first face facing the first plate and a second face located on a side opposite to the first face. The pair of side walls is arranged on the second face. The substrate is placed between the pair of side walls. The substrate includes a third face on which a first non-volatile memory package and a controller package are mounted. The third face faces the second plate. The first non-volatile memory package is thermally connected to the second plate. The controller package is thermally connected to the first plate through the first opening.

Apparatus cools electronic circuitry. An enclosure surrounds the circuitry. Air intake holes are only in a portion of a first panel that faces a first direction. Air exhaust holes are only in a portion of a second panel that faces a second direction opposite the first. Air plenum piece is disposed within the enclosure, and a substantially planar portion extends from a first panel inner wall and ends a distance from a second panel inner wall. At least one tab extends from the substantially planar portion to an upper panel inner wall. The air plenum piece divides an enclosure interior into a first volume, enclosed by the first panel inner wall, substantially planar portion, at least one tab, and upper panel inner wall, into which the air intake holes open and a second volume into which the air exhaust holes open. The second volume is a remaining interior volume.

A set of electronic package elements intended to be mounted on an electronic board having a component to be cooled including: a chassis, a heatsink fixed by a retaining piece inside the chassis, a cover configured to be fixed on the chassis so as to retain the electronic board in the package. The heatsink is configured to be fixed on the electronic board while maintaining a predetermined distance between a lower face of the heatsink and the component. The cover is configured to be able to be fixed by a fixing point to the heatsink. The retaining piece is connected to the heatsink so as to allow the heatsink a translational movement relative to the chassis in three orthogonal directions.

A noise suppressing heat exchanger (also referred to as heat sink) includes a plurality of heat dissipating fins formed with baffles. The baffles suppress noise from a fan by slowing air flow and creating internal reflections within the heat exchanger that reflect noise away from the air flow path, absorbing sound energy and potentially setting up standing waves which dissipate noise via destructive interference. Other embodiments may be described and/or claimed.

An electronic control device includes a housing including a first region in which heat dissipation fins are formed on one side and an electronic component generating the largest amount of heat is in thermal contact with the other side, and a second region in which an electronic component is in thermal contact with the one side and the other side.

An electronic device includes a first body including a first part and a second part hinged to each other, a second body, and a hinge structure hinged between an edge of the second body and the second part. The first part has a recess. When the second body is unfolded relative to the first body from a folded state to a first unfolded state, the hinge structure pushes against the first part to rotate the first part relative to the second part. When the second body is continuously unfolded relative to the first body from the first unfolded state to a second unfolded state, the edge of the second body pushes against the first part, so that the first part continues to rotate relative to the second part. When the second body is in the folded state, the hinge structure is at least partially accommodated in the recess.

An EMI attenuation device includes a housing stator, a fan rotor, and an electrical bridge therebetween. The housing stator has an aperture therethrough, and at least a portion of the housing stator is electrically conductive. The fan rotor is adjacent to the aperture and has a rotational axis relative to the housing stator and a proximate surface proximate the housing stator. The fan rotor is electrically conductive, and the proximate surface is continuous around a rotational direction of the fan rotor. The electrical bridge is between the proximate surface of the fan rotor and a contact surface of the housing stator.