Patent application number | Description | Published |
20090256255 | COMPOSITE INTERCONNECT - A composite interconnect system includes a plurality of carbon nanotubes, a plurality of solder balls and standoff balls disposed on a first device to provide a connection to a second device. A die-attached substrate includes a substrate and one or more die disposed on the substrate by a die-attach composite interconnect. The die-attach composite interconnect includes a plurality of carbon nanotubes, solder bumps, and standoff balls disposed on the die to provide one or more connections to the substrate. A PCB-attached substrate package includes a substrate package and one or more die disposed on the substrate package. The substrate package is disposed on a PCB by a PCB-attach composite interconnect. The PCB-attach composite interconnect includes a plurality of carbon nanotubes, solder balls, and standoff balls disposed on the substrate package to provide one or more connections to the PCB. | 10-15-2009 |
20090273077 | MULTI-LID SEMICONDUCTOR PACKAGE - A multi-lid semiconductor package includes one or more die disposed on a substrate, an interconnect disposed on the substrate, one or more die lids, a die thermal interface between the one or more die and the corresponding die lid or lids, one or more substrate lids, and a substrate interface between the substrate and the corresponding substrate lid or lids. The multi-lid semiconductor package may include one or more discrete surface mount components disposed on the substrate. The multi-lid semiconductor package may include a sealant between the one or more die lids and the one or more substrate lids and the substrate. The one or more die lids and the one or more substrate lids may differ in construction, design, placement, and/or thermal performance. | 11-05-2009 |
20090286359 | OPTIMIZED LID ATTACH PROCESS FOR THERMAL MANAGEMENT AND MULTI-SURFACE COMPLIANT HEAT REMOVAL - A multi-surface compliant heat removal process includes: identifying one or more components to share a heat rejecting device; applying non-adhesive film to the one or more components; identifying a primary component of the one or more components; and applying phase change material on each of the one or more components other than the primary component. The phase change material is placed on top of the non-adhesive film. The process further includes placing the heat rejecting device on the corresponding one or more components; and removing the heat rejecting device from the corresponding one or more components. The phase change material and the non-adhesive film remain with the heat rejecting device. The process also includes reflowing the phase change material on the heat rejecting device; removing the non-adhesive film from the heat rejecting device; placing a heatsink-attach thermal interface material on the one or more components; and placing the heat rejecting device on the corresponding one or more components. | 11-19-2009 |
20100243298 | CARBON NANOTUBE BASED INTERPOSER - In at least one embodiment, an interposer for a board interconnect system is provided. The interposer comprises a frame and at least one interconnect. The frame receives a substrate. The substrate includes a top side, a bottom side, and a conductive interface. The conductive interface extends through the top side and the bottom side for delivering an electrical signal from an electrical device positioned on the top side therethrough. The at least one interconnect includes a plurality of carbon nanotubes (CNTs) positioned within the frame for contacting the conductive interface of the substrate to deliver the electrical signal to a conductive arrangement of a circuit board. | 09-30-2010 |
20110177656 | OPTIMIZED LID ATTACH PROCESS FOR THERMAL MANAGEMENT AND MULTI-SURFACE COMPLIANT HEAT REMOVAL - A multi-surface compliant heat removal process includes: identifying one or more components to share a heat rejecting device; applying non-adhesive film to the one or more components; identifying a primary component of the one or more components; and applying phase change material on each of the one or more components other than the primary component. The phase change material is placed on top of the non-adhesive film. The process further includes placing the heat rejecting device on the corresponding one or more components; and removing the heat rejecting device from the corresponding one or more components. The phase change material and the non-adhesive film remain with the heat rejecting device. The process also includes reflowing the phase change material on the heat rejecting device; removing the non-adhesive film from the heat rejecting device; placing a heatsink-attach thermal interface material on the one or more components; and placing the heat rejecting device on the corresponding one or more components. | 07-21-2011 |
20120188708 | THERMAL AND POWER BUS STACKED PACKAGE ARCHITECTURE - A stacked microprocessor package architecture includes one or more microprocessor packages, the microprocessor packages including one or more microprocessor die disposed on a substrate, a satellite die, a thermal bus thermally coupled to the microprocessor die and thermally connected to system cooling, and a power bus providing power to the microprocessor die and coupled to system power. The microprocessor packages may include a module cap providing mechanical protection and/or thermal isolation or a thermal cooling path for stacked modules. Variable height standoffs provide signal connection from substrates of the stacked microprocessor packages to a system board. | 07-26-2012 |
20140055951 | Chassis with Adjustable Baffle for Cooling - A chassis including a slot configured to receive a printed circuit board having a baffle position pin and electronic components mounted thereon, a guide mechanism mounted within the slot, and a carriage moveably mounted within the slot and biased toward a slot opening by the guide mechanism, the carriage including a baffle suitable to manipulate a flow of air through the slot, the carriage configured to be driven away from the slot opening and to be oriented relative to the electronic components on the printed circuit board by the baffle position pin when the printed circuit board is loaded into the slot such that the baffle directs the flow of air over the electronic components. | 02-27-2014 |
20140262449 | Apparatus and Method for a Back Plate for Heat Sink Mounting - Apparatus and method embodiments are provided for a heat sink mounted on a printed circuit board using a back plate with preload. An apparatus comprises a circuit component, a heat sink on a first side of the circuit component a, a back plate having an initial curvature and positioned at a second side of the circuit component opposite to the heat sink, and one or more screws through the back plate and the circuit component and partially through the heat sink. A method further includes placing and flattening a curved back plate on a second side of a circuit board opposite to the first side, and fastening the back plate, the circuit board, and the heat sink together by inserting a plurality of screws through the back plate, the circuit board, and a partial depth on a single side of the heat sink. | 09-18-2014 |
20140332948 | THERMAL MANAGEMENT IN 2.5 D SEMICONDUCTOR PACKAGING - Lower semiconductor dies in 2.5 D semiconductor packaging configurations can be cooled by thermally coupling the lower semiconductor dies to a heat sink positioned above the interposer, to an upper semiconductor die, to a heat sink affixed beneath a substrate, or to free-flowing air circulating above the interposer or beneath the substrate. The thermal coupling can be achieved using heat pipes, thermal vias, or other conductive passage ways. | 11-13-2014 |
20150036280 | Centralized Chassis Architecture for Half-Width Boards - The thermal efficiency of dual-column chassis can be improved by re-locating line card to connection plane (LC-to-CP) interfaces to the center of the connection plane, as this allows inter line card channels (inter-LC channels) to be routed in a manner that avoids bisecting the thermal throughways over which convection cooling air is circulated to the line cards. One technique for centrally locating the LC-to-CP interfaces on the connection plane is to invert one column of line cards. Another technique for centrally locating the LC-to-CP interfaces on the connection plane is to use non-uniform line cards. An additional benefit of centrally locating the LC-to-CP interfaces on the connection plane is that the inter-LC channels extending between perpendicularly adjacent line cards are shortened, which increases server performance by virtue of reducing switching latency. | 02-05-2015 |