In order to relieve the stress on the substrates in a 3D stacked electronic assembly, a substrate frame may be divided into a plurality of frame sections that are separated by spaces between the frame sections. These separations allow the substrates to expand/contract in response to temperature variations and other environmental conditions, and generally allow the substrates to move in one or more axial directions. The separations between the substrate portions may be design-specific for each substrate design. The placement of IC packages on either side of the substrate may be analyzed to identify areas of maximal warpage through physical measurements, physical model simulations, or using a trained neural network. The spaces in the substrate frame may then be placed next to or aligned with the areas of maximal warpage to reduce the stress on the substrate.

A device for fixing a camera module, includes a base part; and a fixing unit including a first fixing part for supporting one side of each of a plurality of boards, and a second fixing part for supporting the other side facing one side of each of the plurality of boards, wherein a plurality of first fixing parts extends in a first direction from the base part, and includes a plurality of protruding parts protruding in the direction perpendicular to the first direction in order to support one side of each of the plurality of boards, and a plurality of second fixing parts extends in the first direction from the base part, and includes a plurality of protruding parts for supporting the other side of each of the plurality of boards.

A display apparatus comprises a display panel; a heat sink plate coupled to a bottom surface of the display panel and having a coupling member that extends in a semicircular shape at one end and protrudes in a direction toward the bottom surface of the display panel; and a guide panel having a connection member at one end that is coupled to the coupling member in a rotation or sliding manner and connected to a bottom surface a printed circuit board (PCB) connected to the display panel, wherein the printed circuit board is detachably coupled to a bottom surface of the heat sink plate.

A method includes attaching an integrated circuit chip module substrate to a printed circuit board (PCB). First region(s) of a bottom surface of the module include electrical contacts to the board, and second region(s) of the bottom surface of the module lack such contacts. Mechanical structures are assembled into the second regions. These structures allow lateral motion of the module relative to the board, and are sized and placed to inhibit bending of the second regions of the module towards the board under application of a vertical force on a top surface of the module. A package for an integrated circuit may be assembled using the method.

A printed circuit board enclosure employs a box having an open base and opposing side plates. Securing tabs extend laterally from the side plates. The securing tabs have bottom surfaces that are coplanar extensions of a bottom surface of the box and are configured to be attached to the main circuit board. A cover is received on the box. The cover is configured to close the open top of the box. The cover has side flanges extending downwardly from a top plate with mating tabs extending laterally from the side flanges aligned with the securing tabs.

An electronic device is provided. The electronic device includes a first substrate on which a first electrical element and a first conductive structure, which is configured to surround the first electrical element, are disposed, a second substrate on which a second electrical element and a second conductive structure, which is separably connected to the first conductive structure, are disposed, and a connector which is disposed between the first substrate and the second substrate and electrically connects the first electrical element to the second electrical element.

According to an embodiment, an interposer structure comprises a top surface, a bottom surface facing away from the top surface; an inner sidewall extending from the top surface to the bottom surface, and forming an inner space accommodating one or more electronic components mounted on a circuit board of an electronic device; and an outer sidewall extending from the top surface to the bottom surface, and facing away from the inner sidewall, wherein the outer sidewall includes: a first area having a conductive member formed from the top surface to the bottom surface; and a second area having a conductive member formed from the top surface to a first position and a non-conductive member formed from the first position to the bottom surface.

An electronic component and a mounting substrate thereof provide metal frames that reduce stress transmission while occupying only a limited mounting area. The electronic component includes a body, and first and second external electrodes respectively disposed on opposite ends of the body. A first metal frame includes a first support portion bonded to the first external electrode and a first mounting portion extending from a lower end of the first support portion toward the second external electrode. A second metal frame includes a second support portion bonded to the second external electrode and a second mounting portion extending form a lower end of the second support portion away from the first external electrode.

A cooling structure for large electronic boards with closely-spaced heterogeneous die and packages is disclosed. The assembly includes a frame having a plurality of openings. The assembly further includes a cold plate mounted to the frame. The cold plate includes at least one inlet and at least one outlet and fluid channels in communication with the at least one inlet and the at least one outlet. The assembly further includes a heat sink mounted within each of the plurality of openings which in combination with sidewalls of the openings of the frame and the cold plate form individual compartments each of which are in fluid communication with the fluid channels.

In a wiring base body of a printed wiring board, a conductive post including a wiring portion and a wiring are embedded in an insulating resin film. Therefore, even in a region in which a wiring portion is formed, the wiring base body is not increased in thickness. In addition, even in a region in which a wiring is formed, the wiring base body is not increased in thickness. Therefore, it is possible to obtain a printed wiring board having high flatness by stacking a plurality of wiring base bodies and constituting a printed wiring board.