A circuit board assembly in an electronic is disclosed. To conserve space in the electronic device, the circuit board assembly includes stacked circuit boards in electrical communication with each other, such as a first circuit board stacked over a second circuit board. Each circuit board may include multiple surfaces that carry operational components. Moreover, the first circuit board may include a first surface and the second circuit board may include a second surface facing the first surface. The first and second surfaces may include operational components in corresponding locations. Also, the operational components may include corresponding shapes such that one component is positioned in another component. The components may electrically connect to each other. Also, the circuit board assembly may include EMI shields around an outer perimeter in order to shield the operational components form EMI and to components in the electronic device from EMI emanating from the operational components.

An assembly (1) is disclosed, comprising at least one electrical device (5) and at least one carrier substrate (2) arranged to support the at least one electrical device (5). The at least one carrier substrate (2) is arranged with at least one tubular structure (6), which is at least in part hollow and arranged so as to permit passage of fluid through the at least one carrier substrate (2), for example between a first side (3) of the carrier substrate (2) and a second side (4) of the carrier substrate (2), and wherein the at least one tubular structure (6) is arranged such that it has an extension so that it protrudes a predefined distance from at least one of the first side (3) and the second side (4). A lighting device comprising the assembly (1) and a method (30) for manufacturing the assembly (1) are also disclosed.

A mounting jig for a semiconductor device includes an insulated circuit board positioning jig having a concave part in which an insulated circuit board is placed, a tubular contact element positioning jig disposed on an upper side of the insulated circuit board and having a plurality of positioning holes at predetermined positions to insert a plurality of tubular contact elements respectively, and a tubular contact element press-down jig having a flat plate and a plurality of projections extending from a lower surface of the flat plate. The plurality of projections includes a first length from the flat plate on a side closer to an outer circumference of the insulated circuit board, and a second length from the flat plate inside the outer circumference of the insulated circuit board. The first length is shorter than the second length.

A display apparatus including a waveguide is provided. The display apparatus includes a display panel; a backlight configured to provide light to the display panel; a heat sink configured to absorb heat generated by the backlight; a bottom chassis configured to support the backlight and the heat sink; a first circuit board mounted on the bottom chassis; a second circuit board mounted on the bottom chassis; and a waveguide formed between the first circuit board and the second circuit board.

A component cooling device (101) comprising: a circuit board (102), the circuit board (102) having an upper side (103) and a lower side (104) facing away from the upper side (103); and at least one electronic component (106) and at least one hollow circuit board opening (107) for a gaseous cooling medium for cooling the component, wherein on the lower side (104) of the circuit board (102) is provided a guide (110) which forms a flow channel (109) that has at least one inlet (113) and at least one outlet, which is formed by the at least one circuit board opening (107), for at least one convection flow (108) of the cooling medium.

One illustrative method embodiment includes: providing a direct bonded copper (DBC) substrate including a plurality of copper traces; providing a guide plate having protrusions on a surface of the guide plate; mounting hollow bush rings onto the protrusions; mounting the bush rings onto the copper traces by aligning the protrusions of the guide plate with solder units on said copper traces; attaching the bush rings and one or more dies to the copper traces by simultaneously reflowing said solder units and other solder units positioned between the dies and the copper traces; and after said simultaneous reflow, removing the protrusions from the bush rings.

A light bulb is disclosed, and includes a screw shell defining a cavity, a screw shell insulator, and a driver board. The screw shell insulator defines a passageway that terminates in an aperture. The driver board includes a positive leg that projects from a proximal edge of the driver board, with a proximal end portion that protrudes outside of the aperture, and a negative leg that projects from the proximal edge of the driver board, with a proximal end portion that is electrically connected to the screw shell. The positive leg is configured to extend through the passageway to make electrical contact with a positive terminal of a light socket. Variants in which a base shell and the legs are configured for bayonet type, multifaceted reflector, and T8-like bases are also disclosed.

A thermal distribution assembly for an electronic device is disclosed. The electronic device includes an enclosure defined by a metal band and a non-metal bottom wall formed by glass, sapphire, or plastic. In this regard, the enclosure may include a relatively low thermal conductivity. However, the thermal distribution assembly provides heat transfer capabilities that offset thermal conductivity losses by using a non-metal bottom wall, and also provides added structural support. The thermal distribution assembly may include a first layer, a second layer, and a third layer. The first and third layers provide structural support, while the second layer provides a relatively high thermally conductive layer. The thermal distribution assembly includes sidewalls engaging and thermally coupling to the metal band, allowing the thermal distribution assembly to draw heat from a heat-generating component, and pass the heat to the metal band while minimizing or preventing temperature increases along the non-metal bottom wall.

A method, in some embodiments, comprises: providing a direct bonded copper (DBC) substrate including a plurality of copper traces; providing a guide plate having protrusions on a surface of the guide plate; mounting hollow bush rings onto the protrusions; mounting the bush rings onto the copper traces by aligning the protrusions of the guide plate with solder units on said copper traces; attaching the bush rings and one or more dies to the copper traces by simultaneously reflowing said solder units and other solder units positioned between the dies and the copper traces; and after said simultaneous reflow, removing the protrusions from the bush rings.

An assembly (1) is disclosed, comprising at least one electrical device (5) and at least one carrier substrate (2) arranged to support the at least one electrical device (5). The at least one carrier substrate (2) is arranged with at least one tubular structure (6), which is at least in part hollow and arranged so as to permit passage of fluid through the at least one carrier substrate (2), for example between a first side (3) of the carrier substrate (2) and a second side (4) of the carrier substrate (2), and wherein the at least one tubular structure (6) is arranged such that it has an extension so that it protrudes a predefined distance from at least one of the first side (3) and the second side (4). A lighting device comprising the assembly (1) and a method (30) for manufacturing the assembly (1) are also disclosed.