A system for cooling computer hardware includes a heat exchanger having a computer hardware contact surface configured to be in thermal contact with the computer hardware on a first side and to be in thermal contact with a cooling liquid on a second side, the second side being opposite to the first side. The system also includes a bracket configured to removably clamp the heat exchangerto the computer hardware.

A semiconductor device includes semiconductor modules disposed on a support member via a cooling plate; and a metal plate which supports a control board for controlling the semiconductor modules, wherein the metal plate, being supported by the support member, covers the semiconductor modules, and also fixes the control board opposite the installation surfaces of the semiconductor modules.

Methods, systems, apparatus, and articles of manufacture to control load distribution of integrated circuit packages are disclosed. An example apparatus includes a heatsink, a base of the heatsink to be thermally coupled to a semiconductor device, and a rigid plate to be coupled to the semiconductor device and the base of the heatsink, the rigid plate stiffer than the base, the rigid plate distinct from a bolster plate to which the heatsink is to be coupled.

A container assembly and system for dispensing a stack of electronic device components includes an elongated tube having a cavity configured to contain a stack of said components. The tube has a dispensing end opposite an access end and a dispenser opening sized to dispense the electronic device components. The access end has an access opening sized to allow entry of a press to push the stack upwardly. A retainer is positioned proximate the access end to engage a last component in the stack and prevent it from exiting the tube through the access opening. The retainer may include a plurality of retainers. The retainer(s) can be a pair of retainers, four retainers, a chamfer formed in the tube, a perimeter insert, and/or a slidable panel. A method of making and a method of dispensing are provided.

A placement base (100) of a semiconductor device (90) comprises a body (10) on which the semiconductor device (90) is disposed, and a fixing unit (40) for fixing the semiconductor device (90) to the body (10). The body (10) has a supporting unit (12) and a bottom surface (11) placed in an inner periphery of the supporting unit (12) and placed lower than the supporting unit (12). A difference in height ΔH between the supporting unit (12) and the bottom surface (11) is larger than a sum (H1+H2) of a calculated or measured maximum upward warp H1 of the bottom surface (11) and a calculated or measured maximum downward warp H2 of a base of the semiconductor device (90).

A semiconductor guide pin is disclosed. Specific implementations may include a heatsink, one or more substrates coupled together, one or more pressfit pins coupled to the one or more substrates, and two or more guide pins coupled to the one or more substrates, where the two or more guide pins may have a height greater than the one or more pressfit pins.

Methods, systems, apparatus, and articles of manufacture to control load distribution of integrated circuit packages are disclosed. An example apparatus includes a carrier plate including a first surface to face a heatsink; a second surface opposite the first surface, and an aperture extending between the first and second surfaces, the aperture dimensioned to surround a semiconductor device, and a spring carried by the carrier plate, the spring to contact a surface of the semiconductor device proximate an outer edge of the semiconductor device.

In one general aspect, an apparatus can include a first module including a first semiconductor die, and a first heatsink coupled to the first module where the first heatsink includes a substrate and a first plurality of protrusions. The apparatus can also include a second module including a second semiconductor die, and a second heatsink coupled to the second module and including a second plurality of protrusions. The apparatus can also include a cover defining a channel where the first plurality of protrusions of the first heatsink and the second plurality of protrusions of the second heatsink are disposed within the channel.

In one example, an electronic device comprises a base substrate comprising a base substrate conductive structure, a first electronic component over a first side of the base substrate, an encapsulant over the first side of the base substrate, wherein the encapsulant contacts a lateral side of the electronic component, an interposer substrate over a first side of the encapsulant and comprising an interposer substrate conductive structure, and a vertical interconnect in the encapsulant and coupled with the base substrate conductive structure and the interposer substrate conductive structure. A first one of the base substrate or the interposer substrate comprises a redistribution layer (RDL) substrate, and a second one of the base substrate or the interposer substrate comprises a laminate substrate. Other examples and related methods are also disclosed herein.

A method of forming a semiconductor structure includes: attaching a semiconductor device to a first surface of a substrate; placing a thermal interface material (TIM) film over a first side of the semiconductor device distal from the substrate, where the TIM film is pre-formed before the placing, where after the placing, a peripheral portion of the TIM film extends laterally beyond sidewalls of the semiconductor device; and attaching a lid to the first surface of the substrate to form an enclosed space between the lid and the substrate, where after attaching the lid, the semiconductor device and the TIM film are disposed in the enclosed space, where a first side of the TIM film distal from the substrate contacts the lid.