Abstract: A method of forming a custom module lid. The method may include placing a multichip module (MCM) between a module base and a temporary lid, target components are exposed through viewing windows in the temporary lid, a top surface of the target components is measured and mapped to create a target profile, the target profile is used to form custom pockets in a custom lid, and the custom pockets correspond to the target components.

Abstract: Coupling assemblies for connecting fluid-carrying components are provided. The coupling assemblies include, for instance: a socket fitting with a first opening and a second opening in fluid communication through the fitting, the first opening being sized to accommodate a first fluid-carrying component, and the second opening being sized to accommodate a second fluid-carrying component; a sleeve, the sleeve encircling the socket fitting and being rotatable relative to the fitting, and the sleeve including a first locking feature; and a second locking feature associated with one of the fluid-carrying components. The second locking feature is positioned and sized to engage the first locking feature of the sleeve when the one fluid-carrying component is inserted into the socket fitting. Once engaged, rotating of the sleeve locks the first and second locking features together to secure the one fluid-carrying component to the socket fitting.

Abstract: Coupling assemblies for connecting fluid-carrying components are provided. The coupling assemblies include, for instance: a socket fitting with a first opening and a second opening in fluid communication through the fitting, the first opening being sized to accommodate a first fluid-carrying component, and the second opening being sized to accommodate a second fluid-carrying component; a sleeve, the sleeve encircling the socket fitting and being rotatable relative to the fitting, and the sleeve including a first locking feature; and a second locking feature associated with one of the fluid-carrying components. The second locking feature is positioned and sized to engage the first locking feature of the sleeve when the one fluid-carrying component is inserted into the socket fitting. Once engaged, rotating of the sleeve locks the first and second locking features together to secure the one fluid-carrying component to the socket fitting.

Abstract: Tapering couplers and coupling methods for connecting fluid flow components are provided. In one embodiment, the tapering coupler includes a housing with a first opening and a second opening in fluid communication through the housing. The first opening is sized for a first fluid flow component to couple to the housing, and the second opening for a second fluid flow component. The first and second fluid flow components include first and second fluid-carrying channels of different diameter, with the first fluid-carrying channel having a first channel diameter that is larger than the second channel diameter of the second fluid-carrying channel. A tapering element is associated with the housing and extends into the first fluid-carrying channel. The tapering element includes a tapering fluid-carrying channel which tapers in a direction back towards the housing, for instance, from about the first channel diameter to about the second channel diameter.

Abstract: Tapering couplers and coupling methods for connecting fluid flow components are provided. In one embodiment, the tapering coupler includes a housing with a first opening and a second opening in fluid communication through the housing. The first opening is sized for a first fluid flow component to couple to the housing, and the second opening for a second fluid flow component. The first and second fluid flow components include first and second fluid-carrying channels of different diameter, with the first fluid-carrying channel having a first channel diameter that is larger than the second channel diameter of the second fluid-carrying channel. A tapering element is associated with the housing and extends into the first fluid-carrying channel. The tapering element includes a tapering fluid-carrying channel which tapers in a direction back towards the housing, for instance, from about the first channel diameter to about the second channel diameter.

Abstract: A method of forming a custom module lid. The method may include placing a multichip module (MCM) between a module base and a temporary lid, target components are exposed through viewing windows in the temporary lid, a top surface of the target components is measured and mapped to create a target profile, the target profile is used to form custom pockets in a custom lid, and the custom pockets correspond to the target components.

Abstract: A method of forming a custom module lid. The method may include placing a multichip module (MCM) between a module base and a temporary lid, target components are exposed through viewing windows in the temporary lid, a top surface of the target components is measured and mapped to create a target profile, the target profile is used to form custom pockets in a custom lid, and the custom pockets correspond to the target components.

Abstract: Coupling assemblies for connecting fluid-carrying components are provided. The coupling assemblies include, for instance: a socket fitting with a first opening and a second opening in fluid communication through the fitting, the first opening being sized to accommodate a first fluid-carrying component, and the second opening being sized to accommodate a second fluid-carrying component; a sleeve, the sleeve encircling the socket fitting and being rotatable relative to the fitting, and the sleeve including a first locking feature; and a second locking feature associated with one of the fluid-carrying components. The second locking feature is positioned and sized to engage the first locking feature of the sleeve when the one fluid-carrying component is inserted into the socket fitting. Once engaged, rotating of the sleeve locks the first and second locking features together to secure the one fluid-carrying component to the socket fitting.

Abstract: Coupling assemblies for connecting fluid-carrying components are provided. The coupling assemblies include, for instance: a socket fitting with a first opening and a second opening in fluid communication through the fitting, the first opening being sized to accommodate a first fluid-carrying component, and the second opening being sized to accommodate a second fluid-carrying component; a sleeve, the sleeve encircling the socket fitting and being rotatable relative to the fitting, and the sleeve including a first locking feature; and a second locking feature associated with one of the fluid-carrying components. The second locking feature is positioned and sized to engage the first locking feature of the sleeve when the one fluid-carrying component is inserted into the socket fitting. Once engaged, rotating of the sleeve locks the first and second locking features together to secure the one fluid-carrying component to the socket fitting.

Abstract: Coupling assemblies for connecting fluid-carrying components are provided. The coupling assemblies include, for instance: a socket fitting with a first opening and a second opening in fluid communication through the fitting, the first opening being sized to accommodate a first fluid-carrying component, and the second opening being sized to accommodate a second fluid-carrying component; a sleeve, the sleeve encircling the socket fitting and being rotatable relative to the fitting, and the sleeve including a first locking feature; and a second locking feature associated with one of the fluid-carrying components. The second locking feature is positioned and sized to engage the first locking feature of the sleeve when the one fluid-carrying component is inserted into the socket fitting. Once engaged, rotating of the sleeve locks the first and second locking features together to secure the one fluid-carrying component to the socket fitting.

Abstract: Coupling assemblies for connecting fluid-carrying components are provided. The coupling assemblies include, for instance: a socket fitting with a first opening and a second opening in fluid communication through the fitting, the first opening being sized to accommodate a first fluid-carrying component, and the second opening being sized to accommodate a second fluid-carrying component; a sleeve, the sleeve encircling the socket fitting and being rotatable relative to the fitting, and the sleeve including a first locking feature; and a second locking feature associated with one of the fluid-carrying components. The second locking feature is positioned and sized to engage the first locking feature of the sleeve when the one fluid-carrying component is inserted into the socket fitting. Once engaged, rotating of the sleeve locks the first and second locking features together to secure the one fluid-carrying component to the socket fitting.

Abstract: Methods of fabricating cooling apparatuses are provided, which include providing a thermal transfer structure configured to couple to and cool one or more electronic components. The thermal transfer structure includes a thermal spreader, and at least one coolant-carrying tube coupled to the thermal spreader. The coolant-carrying tube(s) includes multiple tube lengths disposed substantially in a common plane, and an out-of-plane tube bend. The out-of-plane tube bend is couples in fluid communication first and second tube lengths of the multiple tube lengths, and extends out-of-plane from the multiple tube lengths disposed in the common plane. The first and second tube lengths may be spaced apart, with a third tube length disposed between them, and the coolant-carrying tube(s) further includes an in-plane tube bend which couples in fluid communication the third tube length and a fourth tube length of the multiple tube lengths.

Abstract: A cooling assembly is provided which includes: one or more coolant-cooled heat sinks configured to couple to one or more electronic components to be cooled; one or more flexible coolant conduits; and one or more pivotable coolant manifolds. The flexible coolant conduit(s) couples in fluid communication the pivotable coolant manifold(s) and the coolant-cooled heat sink(s), and accommodates pivoting of the pivotable coolant manifold(s), while maintaining the coolant-cooled heat sink(s) in fluid communication with the pivotable coolant manifold(s). In one or more embodiments, the pivotable coolant manifold(s) pivots between a first position laterally offset from one or more of the coolant-cooled heat sink(s), and a second position above the one or more coolant-cooled heat sinks. First and second pivot arms may be provided at opposite ends of the pivotable coolant manifold(s) to facilitate pivotable movement of the manifold(s) between the first position and the second position.

Abstract: A package for a multi-chip module includes a top cold plate and a bottom plate whose perimeters are in thermal communication so the plates together completely encase the module except for a connector passing through the bottom plate. The cold plate has copper tubing pressed into a groove formed in a serpentine pattern. The perimeter of the cold plate has thermal conduction fins which mate with thermal conduction slots in the perimeter of the bottom plate. Thermal interface material is disposed in gaps between the plates and chips on the module, the gaps having dimensions controlled by support ribs of plates which abut the module substrate. The cold plate is used on the hottest side of the module, e.g., the side having computationally-intensive chips such as ASICs. A densely packed array of these packages can be used in a central electronic complex drawer with a shared coolant circulation system.

Abstract: Aspects of the present invention include an optical fiber connector for connecting optical fibers. The optical fiber connector includes a ferrule coupled to one or more optical fiber ribbons. The optical fiber connector includes a connector housing coupled with a radius controlled ribbon bending housing. The connector housing surrounds the ferrule on at least four sides, and the one or more optical fiber ribbons coupled to the ferrule are within the connector housing. The optical fiber connector includes a strain relief clamp coupled with the radius controlled ribbon bending housing.

Abstract: Aspects of the present invention include an optical fiber connector for connecting optical fibers. The optical fiber connector includes a ferrule coupled to one or more optical fiber ribbons. The optical fiber connector includes a connector housing coupled with a radius controlled ribbon bending housing. The connector housing surrounds the ferrule on at least four sides, and the one or more optical fiber ribbons coupled to the ferrule are within the connector housing. The optical fiber connector includes a strain relief clamp coupled with the radius controlled ribbon bending housing.

Abstract: A coolant-cooled electronic module is provided which includes a multi-component assembly and a module lid with openings aligned over respective electronic components. Thermally conductive elements are disposed within the openings, each including opposite coolant-cooled and conduction surfaces, with the conduction surface being thermally coupled to the respective electronic component. A manifold assembly disposed over the module lid includes inner and outer manifold elements, with the inner element configured to facilitate flow of coolant onto the coolant-cooled surfaces. The outer manifold element is disposed over the inner manifold element and coupled to the module lid, with the inner and outer manifold elements defining a coolant supply manifold, and the outer manifold element and module lid defining a coolant return manifold. The coolant supply openings are in fluid communication with the coolant supply manifold, and the coolant exhaust channels are in fluid communication with the coolant return manifold.

Abstract: Aspects of the present invention include an optical transceiver for providing transmission and reception of optical signals. The optical transceiver includes a carrier having two opposing surfaces and one or more openings extending from a first of the two opposing surfaces to a second of the two opposing surfaces. The optical transceiver includes a laser driver chip coupled to the first surface. The optical transceiver includes a vertical cavity surface emitting laser (VCSEL) array chip coupled to the first surface. The optical transceiver includes a photodetector array chip coupled to the first surface. The optical transceiver includes a receiver amplifier chip coupled to the first surface. The optical transceiver includes an optical coupling element coupled to the second surface. The VCSEL array chip and the photodetector array chip are disposed such that optical signals can pass through the one or more openings in the carrier.

Abstract: Cooling apparatuses and coolant-cooled electronic assemblies are provided which include a thermal transfer structure configured to couple to an electronics card which operatively inserts into an electronic system. The thermal transfer structure includes a clamping structure movable between opened and clamped positions. A coolant-cooled structure, which is associated with the electronic system within which the electronics card is operatively inserted, resides between the electronics card and, at least partially, the clamping structure with insertion of the electronics card into the electronic system.

Abstract: A method and system for installing and removing a row of cables from a cable array is provided. The method includes providing an installation tool having a first body with a plurality of arms extending from one side. The plurality of arms being configured to receive a cable connector body, the plurality of arms including at least one first projection extending from one of the plurality of arms. The installation tool is moved onto a row of cables held coupled together by a bracket, each of the cables in the row of cables having a cable connector body. The connector bodies are engaged into receptacles and the bracket is moved with the at least one first projection.