Abstract: An apparatus is described. The apparatus includes a cover to enclose a junction between respective ends of first and second fluidic conduits. The first and second fluidic conduits transport a coolant fluid within an electronic system. The apparatus also includes a leak detection device to be located within a region that is enclosed by the cover when the junction is enclosed by the cover. The leak detection device is to detect a leak of the coolant fluid at the junction when the junction is enclosed by the cover. The first and second fluidic conduits extend outside the cover when the junction is enclosed by the cover. Another apparatus is also described. The other apparatus includes a leak detection device to detect a leak of coolant fluid from a specific component or junction in a liquid cooling system of an electronic system.

Abstract: An apparatus is described. The apparatus includes a back plate, where, an electronic circuit board is to be placed between the back plate and a thermal cooling mass for a semiconductor chip package. The back plate includes a first material and a second material. The first material has greater stiffness than the second material. The back plate further includes at least one of: a third material having greater stiffness than the second material; re-enforcement wires composed of the first material; a plug composed of the second material that is inserted into a first cavity in the first material, a stud inserted into a second cavity in the plug. An improved bolster plate having inner support arms has also been described.

Abstract: Reinforced nuts comprise a polymer nut body and a metal casing fitted to an outer surface of the nut body. In some embodiments, the metal casing can cover the top of the polymer nut body and comprise a drive opening so that the casing carries a portion of an applied torque when the nut is being tightened. In other embodiments, the metal case can cover a portion of the bottom surface of the polymer nut body. Reinforced nuts can also comprise a cylindrical metal sleeve that is embedded in a polymer nut body. The metal sleeve can be solid, porous, comprise holes, or be a mesh. The reinforced nuts have an increased strength relative to nuts that are not reinforced and can thus handle a greater load when they nuts are being tightened.

Abstract: Techniques for processor loading mechanisms are disclosed. In the illustrative embodiment, a heat sink is in contact with a top surface of a processor, applying a downward force on the processor. A load plate is also in contact with the processor, applying a downward force to the processor as well. The combination of the downward force from the load plate and the heat sink keep the processor in good physical contact with pins of the processor socket. The heat sink has enough force applied to the processor to be in good thermal contact with the processor without applying higher stress to the heat sink. The load plate can apply force to the processor without regard to the thermal characteristics of the load plate. Other embodiments are envisioned and described.

Abstract: An apparatus is described. The apparatus includes a back plate, where, an electronic circuit board is to be placed between the back plate and a thermal cooling mass for a semiconductor chip package. The back plate includes a first material and a second material. The first material has greater stiffness than the second material. The back plate further includes at least one of: a third material having greater stiffness than the second material; re-enforcement wires composed of the first material; a plug composed of the second material that is inserted into a first cavity in the first material, a stud inserted into a second cavity in the plug. An improved bolster plate having inner support arms has also been described.

Abstract: Protrusions of socket bodies having metal are disclosed. An example apparatus comprises a socket body, the socket body including a plastic material, an array of contacts distributed across a surface of the socket body, and a protrusion extending away from the surface of the socket body, the protrusion to facilitate alignment of an IC package with the array of contacts, the protrusion including metal.

Abstract: Embodiments disclosed herein include sockets and electronic packages with socket architectures. In an embodiment, a socket comprises a housing with a first surface and a second surface. In an embodiment, a plurality of interconnect pins pass through the housing. In an embodiment, an alignment hole is provided through the housing. In an embodiment, an alignment post extending out from the first surface of the housing is also provided.

Abstract: A semiconductor chip package is described. The semiconductor chip package has a substrate. The substrate has side I/Os on the additional surface area of the substrate. The side I/Os are coupled to I/Os of a semiconductor chip within the semiconductor chip package. A cooling assembly has also been described. The cooling assembly has a passageway to guide a cable to connect to a semiconductor chip's side I/Os that are located between a base of a cooling mass and an electronic circuit board that is between a bolster plate and a back plate and that is coupled to second I/Os of the semiconductor chip through a socket that the semiconductor chip's package is plugged into.

Abstract: Covers for integrated circuit package sockets are disclosed herein. An example cover for a socket for an integrated circuit package includes a base including a cutout, the cutout to engage a pin associated with the socket, engagement of the cutout and the pin to maintain a position of the cover relative to the socket; and a handle to facilitate positioning of the cover to move the cutout into engagement with the pin.

Abstract: Systems, apparatus, articles of manufacture, and methods are disclosed for supports for internal hardware of electronic devices. An example support includes an integrated circuit (IC) carrier that includes a plurality of walls, supports carried by the walls to support an IC from below the IC, and a retention clip to secure the IC.

Abstract: Embodiments disclosed herein include assemblies. In an embodiment, an assembly comprises a socket and a bolster plate on a board, where the bolster plate has load studs and an opening that surrounds the socket; a shim having first and second ends; and a carrier on the bolster plate, where the carrier has an opening and cutouts. The shim may have an opening through the first end as the second end is affixed to the carrier. The opening of the shim entirely over one cutout from a corner region of the carrier. In an embodiment, the assembly comprises an electronic package in the opening of the carrier, where the electronic package is affixed to the carrier, and a heatsink over the electronic package and carrier, where the first end is directly coupled to a surface of the heatsink and a surface of one load stud of the bolster plate.

Abstract: A microprocessor heat sink fastener assembly, comprising a base to couple to a heat sink a retention nut to be received by a cavity of the base, and a retention clip to be attached to the base and to be cantilevered therefrom. The retention clip is to engage with a latching structure extending from a latching structure of a retention plate.

Abstract: A microprocessor loading mechanism, comprising a bolster plate surrounding an aperture, wherein the opening is to receive a microprocessor socket, one or more torsion bars coupled to the bolster plate, and a stud coupled to each of the one or more torsion bars, wherein each stud is to receive a nut to secure a microprocessor package to the microprocessor socket within the aperture and wherein each stud is secured to the bolster plate by each corresponding torsion bar.

Abstract: A microprocessor heat sink fastener, comprising a nut comprising a thermoplastic material and fibrous fill particles and a bore extending along an axis of the nut. The bore has internal threads. The internal threads comprise a surface. At least one of the fibrous fill particles has first and second ends extending from the surface into a sub-surface region.

Abstract: An apparatus is described. The apparatus includes a cover to enclose a junction between respective ends of first and second fluidic conduits. The first and second fluidic conduits transport a coolant fluid within an electronic system. The apparatus also includes a leak detection device to be located within a region that is enclosed by the cover when the junction is enclosed by the cover. The leak detection device is to detect a leak of the coolant fluid at the junction when the junction is enclosed by the cover. The first and second fluidic conduits extend outside the cover when the junction is enclosed by the cover. Another apparatus is also described. The other apparatus includes a leak detection device to detect a leak of coolant fluid from a specific component or junction in a liquid cooling system of an electronic system.

Abstract: Embodiments disclosed herein include sockets and electronic packages with socket architectures. In an embodiment, a socket comprises a housing with a first surface and a second surface. In an embodiment, a plurality of interconnect pins pass through the housing. In an embodiment, an alignment hole is provided through the housing. In an embodiment, an alignment post extending out from the first surface of the housing is also provided.

Abstract: A microprocessor carrier, comprising a frame comprising a metal. The first frame surrounds an aperture for receiving a microprocessor package. At least one hinge assembly is on a first frame edge, and at least one latch assembly is on a second frame edge. One or more alignment tabs coupled to the frame. The one or more alignment tabs extend orthogonally from at least one frame edge. The alignment tabs are to align the microprocessor package with a microprocessor socket. The hinge assembly and the latch assembly are to engage with a microprocessor loading mechanism coupled to a printed circuit board.

Abstract: An apparatus is described. The apparatus includes a back plate, where, an electronic circuit board is to be placed between the back plate and a thermal cooling mass for a semiconductor chip package. The back plate includes a first material and a second material. The first material has greater stiffness than the second material. The back plate further includes at least one of: a third material having greater stiffness than the second material; re-enforcement wires composed of the first material; a plug composed of the second material that is inserted into a first cavity in the first material, a stud inserted into a second cavity in the plug. An improved bolster plate having inner support arms has also been described.

Abstract: Embodiments disclosed herein include assemblies. In an embodiment, an assembly comprises a socket and a bolster plate on a board, where the bolster plate has load studs and an opening that surrounds the socket; a shim having first and second ends; and a carrier on the bolster plate, where the carrier has an opening and cutouts. The shim may have an opening through the first end as the second end is affixed to the carrier. The opening of the shim entirely over one cutout from a corner region of the carrier. In an embodiment, the assembly comprises an electronic package in the opening of the carrier, where the electronic package is affixed to the carrier, and a heatsink over the electronic package and carrier, where the first end is directly coupled to a surface of the heatsink and a surface of one load stud of the bolster plate.

Abstract: Techniques for processor loading mechanisms are disclosed. In the illustrative embodiment, a heat sink is in contact with a top surface of a processor, applying a downward force on the processor. A load plate is also in contact with the processor, applying a downward force to the processor as well. The combination of the downward force from the load plate and the heat sink keep the processor in good physical contact with pins of the processor socket. The heat sink has enough force applied to the processor to be in good thermal contact with the processor without applying higher stress to the heat sink. The load plate can apply force to the processor without regard to the thermal characteristics of the load plate. Other embodiments are envisioned and described.