Abstract: A counter flow radiator includes multiple layered cooling cores configured in series along a first direction that is the same as the direction of airflow used to cool fluid flowing through the counter flow radiator. Heated fluid inputs the counter flow radiator at a first end and flows through each cooling core in a serpentine-like path to the second end of the counter flow radiator, effectively progressing in a direction opposite that of the airflow.

Abstract: An structure and method of manufacturing a microstructure for use in a heat exchanger is disclosed. The heat exchanger comprises a manifold layer and an microstructured region. The manifold layer comprises a structure to deliver fluid to the microstructured region. The microstructured region is formed from multiple windowed layers formed from heat conductive layers through which a plurality of microscaled apertures have been formed by a wet etching process. The plurality of windowed layers are then coupled together to form a composite microstructure.

Abstract: A payment card manufacturing process glues a thin battery and an autonomously reprogrammable magnetic device to the inside surface of one of two outer front and rear laminate sheets. The magnetic device is pressed through a precisely cut rectangular hole provided for it in the rear laminate sheet, and is sealed with a gasket bead. Such magnetic device is critically placed flush in a magnetic stripe area, and the end gaps are such that they will minimize adverse magnetic transitions seen by a reader between the magnetic stripe field and the autonomously reprogrammable magnetic device. The surfaces of the battery, electronics, and laminate sheets, are plasma treated to promote adhesion. These are then all sandwiched together inside a heated mold that is tilted or vibrated just before a two-part polyurethane is injected. Each of the two polyurethane parts is temperature adjusted to match viscosities and thus improve mixing.

Abstract: A heat collection apparatus is mounted to the heat source using a gimbal plate, which includes a gimbal joint. The gimbal joint enables application of a retaining force to the heat collection apparatus as a single-point load. The retaining force is applied along a vector that is collinear to the face-centered normal vector of the thermal interface of the heat source. This results in a balanced and centered application of the retaining force over the thermal interface area. The gimbal plate is mounted directly to a circuit board using spring means. The spring means regulate the amount of mating force directed through the gimbal joint to the heat collection device. Because the gimbal joint is rotation-compliant, the two mating faces making up the thermal interface are forced into a parallel mate. In this manner, a high performance TIM interface is generated.

Abstract: A cooling system includes a cooling unit configured to fit within a single drive bay of a personal computer. The cooling unit includes a fluid-to-air heat exchanger, an air mover, a pump, fluid lines, and control circuitry. The cooling system also includes a cooling loop configured to be coupled to one or more heat generating devices. The cooling loop includes the pump and the fluid-to-air heat exchanger from the cooling unit, and at least one heat exchanger coupled together via flexible fluid lines. The heat exchanger is thermally coupled to the heat generating device. The cooling unit is configured to maintain noise below a specified acoustical specification. To meet this acoustical specification, the size, position, and type of the components within the cooling unit are specifically configured.

Abstract: An integrated pumping assembly includes a pump coupled to a heat exchanging device via a mounting plate. The mounting plate is sealed to the heat exchanging device. The heat exchanging device is any fluid-based heat exchanging device, such as a fluid radiator configured to operate as a heat rejector or a heat exchanger configured to remove heat from a heat generating device. The pump is mounted directly to the mounting plate. A mounting mechanism compresses the pump housing and the mounting plate. One or more sealing washers, such as o-rings, are positioned between the pump housing and the mounting plate. The pump, mounting plate, and the heat exchanging device are aligned such that an opening in the pump housing, an opening in the mounting plate, and an opening in the housing of the heat exchanging device are aligned to form a sealed fluid path through which fluid is exchanged between the pump and the heat exchanging device.

Abstract: An integrated cooling system for cooling systems such as laptops or subsystems such as a graphics card is disclosed. An integrated cooling system includes a first layer having a contact area configured for coupling to a heat source, wherein the first layer has a fluid path passes adjacent to the contact area where the heat source is in thermal contact with first layer. Coupled to the first layer is a second layer to which a number of air fins are attached. The invention includes a pump that is connected to the fluid path forming a closed path for circulating a fluid through the first layer. Within the first layer, the fluid path will contain a plurality of fluid fins which control the flow of a fluid within the fluid path. Within the fluid path, a structure providing a double-counter flow adjacent to one or more electronic devices. Additionally the fluid path can include a microchannel plate structure.

Abstract: Liquid-based cooling solutions used to transfer heat produced by one or more heat generating devices from one or more electronics servers to the ambient. Each electronics server includes one or more heat generating devices. Integrated onto each electronics server is a liquid based cooling system. Each liquid based cooling system includes a server pump and one or more microchannel cold plates (MCP) coupled together via fluid lines. The liquid based cooling system for each electronics server includes a rejector plate configured with micro-channels. The MCPs, the server pump and the rejector plate form a first closed loop. The rejector plate is coupled to a chassis cold plate via a thermal interface material. In a multiple electronics server configuration, the rejector plates for each of the electronics servers are coupled to the chassis cold plate configured with fluid channels which are coupled via fluid lines to a liquid-to-air heat exchanging system to form a second closed loop.

Abstract: A mounting system provides mechanisms and form factors for bringing a heat exchanger from a server rack into thermal contact with a heat exchanger from a electronics server. To ensure good thermal contact, pressure is applied between the two heat exchangers, the rejector plate and the chassis cold plate. The mounting mechanism used to engage and disengage the heat exchangers is configured to isolate the force applied to the two heat exchangers. The mounting mechanism includes an interlocking mechanism that prevents transfer of the applied force to the rest of the electronics server. Without isolating this force, the force is applied to the electronics server and/or the rack chassis, possibly disconnecting the electrical connections between the electronics server and the rack, as well as providing mechanical stress to the electronics server and the rack chassis.

Abstract: A heat exchanger includes features for alleviating high pressure drops and controlling the expansion of fluid during freezing. The heat exchanger includes an interface layer in which heat is transferred from a heat source to a fluid. A manifold layer couples to the interface layer. The manifold layer includes a first set of substantially vertical fluid paths for directing the fluid to the interface layer. The manifold layer further includes a second set of substantially horizontal fluid paths, perpendicular to the first set of fluid paths, for removing the fluid from the interface layer. Preferably, the heat exchanger includes an upper layer for circulating the fluid to and from the manifold layer. The upper layer can include at least one of a plurality of protruding features and a porous structure. Preferably, a porous structure is disposed along the interface layer.

Abstract: A heat collection apparatus is mounted to the heat source using a gimbal plate, which includes a gimbal joint. The gimbal joint enables application of a retaining force to the heat collection apparatus as a single-point load. The retaining force is applied along a vector that is collinear to the face-centered normal vector of the thermal interface of the heat source. This results in a balanced and centered application of the retaining force over the thermal interface area. The gimbal plate is mounted directly to a circuit board using spring means. The spring means regulate the amount of mating force directed through the gimbal joint to the heat collection device. Because the gimbal joint is rotation-compliant, the two mating faces making up the thermal interface are forced into a parallel mate. In this manner, a high performance TIM interface is generated.

Abstract: A heat exchanger includes features for alleviating high pressure drops and controlling the expansion of fluid during freezing. The heat exchanger includes an interface layer in which heat is transferred from a heat source to a fluid. A manifold layer couples to the interface layer. The manifold layer includes a first set of substantially vertical fluid paths for directing the fluid to the interface layer. The manifold layer further includes a second set of substantially horizontal fluid paths, perpendicular to the first set of fluid paths, for removing the fluid from the interface layer. Preferably, the heat exchanger includes an upper layer for circulating the fluid to and from the manifold layer. The upper layer can include at least one of a plurality of protruding features and a porous structure. Preferably, a porous structure is disposed along the interface layer.