Abstract: Techniques for heat reduction are disclosed. An apparatus may include a heat-generating component, an insulative layer having a first surface in contact with the heat-generating component and a second surface opposite the first surface, and a heat-conducting component disposed on the second surface of the insulative layer.

Abstract: A device that includes an integrated device and a heat dissipating device coupled to the integrated device. The heat dissipating device includes an electro-osmotic (EO) pump. The electro-osmotic (EO) pump includes a casing comprising a first opening and a second opening; a membrane located in the casing; an anode electrode; a cathode electrode; and a catalyst layer formed on a surface of the membrane. The membrane includes a plurality of channels. The electro-osmotic (EO) pump is configured to provide a fluid to flow from the first opening of the casing, through the plurality of channels of the membrane and out of the second opening of the casing. The catalyst layer is configured to recombine gas ions that are produced by the electro-osmotic (EO) pump.

Abstract: A quad-rotor or other unmanned aerial drone having a planar vapor chamber mounted to a processor of the drone to cool the processor. The processor may be enclosed in a protective central housing. The vapor chamber is mounted, in some examples, with a perimeter of the vapor chamber extending from the processor through the housing into an airflow region near the rotors of the drone so that airflow, which may include propeller wash, serves to cool the perimeter of the vapor chamber. The planar vapor chamber cools the enclosed processor using both phase-change cooling/heat spreading (i.e. heat is dissipated from the processor via evaporation and subsequent condensation) and convection (i.e. airflow passing over the perimeter of the vapor chamber carries heat away).

Abstract: Some features pertain to an apparatus that includes a first heat spreader and a second heat spreader, a matrixed heat spreader, the matrixed heat spreader including a first plurality of portions perpendicular to a second plurality of portions, the first plurality of portions intersects the second plurality of portions, and a phase change material (PCM) located in a plurality of reservoirs defined by the matrixed heat spreader.

Abstract: Some novel features pertain to a quad-rotor or other unmanned aerial drone having a planar vapor chamber mounted to a processor of the drone to cool the processor. The processor may be enclosed in a protective central housing. The vapor chamber is mounted, in some examples, with a perimeter of the vapor chamber extending from the processor through the housing into an airflow region near the rotors of the drone so that airflow, which may include propeller wash, serves to cool the perimeter of the vapor chamber. With this design, the planar vapor chamber cools the enclosed processor using both phase-change cooling/heat spreading (i.e. heat is dissipated from the processor via evaporation and subsequent condensation) and convection (i.e. airflow passing over the perimeter of the vapor chamber carries heat away). In some examples, the planar vapor chamber is turtle-shaped with legs aligned with the struts of the drone.

Abstract: Techniques for heat reduction are disclosed. An apparatus may include a heat-generating component, an insulative layer having a first surface in contact with the heat-generating component and a second surface opposite the first surface, and a heat-conducting component disposed on the second surface of the insulative layer.

Abstract: A device that includes a region comprising an integrated device and a heat dissipating device coupled to the region comprising the integrated device. The heat dissipating device is configured to dissipate heat away from the region. The heat dissipating device includes a fluid, an evaporator configured to evaporate the fluid, a first condenser configured to condense the fluid, where the first condenser is located in a first wall of the device, an evaporation portion coupled to the evaporator and the first condenser, and a collection portion coupled to the first condenser and the evaporator. The evaporation portion is configured to channel an evaporated fluid from the evaporator to the first condenser. The collection portion is configured to channel a condensed fluid from the first condenser to the evaporator through the help of gravity.

Abstract: A heat dissipating device that includes a first heat spreader layer, a second heat spreader layer, a first spacer, a second spacer, a first phase change material (PCM), and a second phase change material (PCM). The first heat spreader layer includes a first spreader surface and a second spreader surface. The second heat spreader layer includes a third spreader surface and a fourth spreader surface. The first spacer is coupled to the first heat spreader layer and the second heat spreader layer. The second spacer is coupled to the first heat spreader layer and the second heat spreader layer. The first PCM is located between the first heat spreader layer and the second heat spreader layer. The first PCM is surrounded by the first spacer. The second PCM is between the first heat spreader layer, the second heat spreader layer, the first spacer and the second spacer.

Abstract: A device that includes a region comprising an integrated device and a heat dissipating device coupled to the region comprising the integrated device. The heat dissipating device is configured to dissipate heat away from the region. The heat dissipating device includes a fluid, an evaporator configured to evaporate the fluid, a first condenser configured to condense the fluid, where the first condenser is located in a first wall of the device, an evaporation portion coupled to the evaporator and the first condenser, and a collection portion coupled to the first condenser and the evaporator. The evaporation portion is configured to channel an evaporated fluid from the evaporator to the first condenser. The collection portion is configured to channel a condensed fluid from the first condenser to the evaporator through the help of gravity.

Abstract: A heat dissipating device that includes a first heat spreader layer, a second heat spreader layer, a first spacer, a second spacer, a first phase change material (PCM), and a second phase change material (PCM). The first heat spreader layer includes a first spreader surface and a second spreader surface. The second heat spreader layer includes a third spreader surface and a fourth spreader surface. The first spacer is coupled to the first heat spreader layer and the second heat spreader layer. The second spacer is coupled to the first heat spreader layer and the second heat spreader layer. The first PCM is located between the first heat spreader layer and the second heat spreader layer. The first PCM is surrounded by the first spacer. The second PCM is between the first heat spreader layer, the second heat spreader layer, the first spacer and the second spacer.

Abstract: Electronic devices incorporating a heat dissipation feature include an enclosure, and at least one heat-generating component positioned within the enclosure. The heat dissipation feature is sufficiently coupled to the at least one heat-generating component to facilitate conductive heat transfer from the heat-generating component. The heat dissipation feature includes a plurality of protrusions exposed externally to the enclosure. A thermally insulating material may be disposed on at least a tip portion of at least some of the protrusions. The thermally insulating material is selected to provide a touch temperature that is below a predetermined threshold. In some instances, the thermally insulating material can provide such a touch temperature by selecting the material to include properties for thermal conductivity (k), density (?), and specific heat (Cp) such that the product of k*?*Cp results in a value less than a product of k*?*Cp for human skin.

Abstract: Some implementations provide a folding electronic device that includes a base portion, a cover portion and a coupler. The base portion includes a region configured to generate heat. The cover portion includes a display screen, a heat dissipating component, and a thermally insulating component. The heat dissipating component is coplanar to the display screen. The thermally insulating component is coplanar to the display screen. The thermally insulating component is located between the display screen and the heat dissipating component. The coupler is for thermally coupling the base portion to the cover portion. The coupler includes a first component and a second component. The first component is coupled to the region configured to generate heat. The second component is coupled to the heat dissipating component of the cover portion. The coupler provides a path for transferring heat.

Abstract: An apparatus has external and/or internal capacitive thermal material for enhanced thermal package management. The apparatus includes an integrated circuit (IC) package having a heat generating device. The apparatus also includes a heat spreader having a first side that is attached to the IC package. The apparatus also includes capacitive thermal material reservoirs contacting the first side of the heat spreader. The capacitive thermal material reservoirs may be disposed laterally relative to the heat generating device.

Abstract: Some implementations provide a semiconductor package structure that includes a package substrate, a first package, an interposer coupled to the first package, and a first set of through via insert (TVI). The first set of TVI is coupled to the interposer and the package substrate. The first set of TVI is configured to provide heat dissipation from the first package. In some implementations, the semiconductor package structure further includes a heat spreader coupled to the interposer. The heat spreader is configured to dissipate heat from the first package. In some implementations, the first set of TVI is further configured to provide an electrical path between the first package and the package substrate. In some implementations, the first package is electrically coupled to the package substrate through the interposer and the first set of TVI. In some implementations, the first set of TVI includes a dielectric layer and a metal layer.

Abstract: Some implementations provide a folding electronic device that includes a base portion, a cover portion and a coupler. The base portion includes a region configured to generate heat. The cover portion includes a display screen, a heat dissipating component, and a thermally insulating component. The heat dissipating component is coplanar to the display screen. The thermally insulating component is coplanar to the display screen. The thermally insulating component is located between the display screen and the heat dissipating component. The coupler is for thermally coupling the base portion to the cover portion. The coupler includes a first component and a second component. The first component is coupled to the region configured to generate heat. The second component is coupled to the heat dissipating component of the cover portion. The coupler provides a path for transferring heat.

Abstract: Various embodiments of methods and systems for controlling and/or managing thermal energy generation on a portable computing device are disclosed. Data discarded from one or more processing core registers may be monitored and analyzed to deduce individual workloads that have been processed by each of the cores over a unit of time. From the deduced workloads, the power consumed by each of the cores over the unit of time in order to process the workload can be calculated. Subsequently, a time dependent power density map can be created which reflects a historical and near real time power consumption for each core. Advantageously, because power consumption can be correlated to thermal energy generation, the TDPD map can be leveraged to identify thermal aggressors for targeted, fine grained application of thermal mitigation techniques. In some embodiments, workloads may be reallocated from the identified thermal aggressors to the identified underutilized processing components.

Abstract: A first tier die is provided having a thermal management floorplan with a heat region having an area for thermal coupling to a heat sink, a second tier die is provided, shaped and dimensioned to be stackable into a multi-tier stack with the first tier die and, when stacked in the multi-tier stack, to not substantially overlap the heat region. A heat sink is provided, and a thermal coupling element, the heat sink, a stack having the first tier die and the second tier die, and the heat sink are arranged to form the multi-tier stacked integrated circuit. In the arrangement, the thermal coupling element is located to form a thermal path from the heat region of the first tier die to the heat sink.

Abstract: Electronic devices incorporating a heat dissipation feature include an enclosure, and at least one heat-generating component positioned within the enclosure. The heat dissipation feature is sufficiently coupled to the at least one heat-generating component to facilitate conductive heat transfer from the heat-generating component. The heat dissipation feature includes a plurality of protrusions exposed externally to the enclosure. A thermally insulating material may be disposed on at least a tip portion of at least some of the protrusions. The thermally insulating material is selected to provide a touch temperature that is below a predetermined threshold. In some instances, the thermally insulating material can provide such a touch temperature by selecting the material to include properties for thermal conductivity (k), density (?), and specific heat (Cp) such that the product of k*?*Cp results in a value less than a product of k*?*Cp for human skin.

Abstract: An apparatus has external and/or internal capacitive thermal material for enhanced thermal package management. The apparatus includes an integrated circuit (IC) package having a heat generating device. The apparatus also includes a heat spreader having a first side that is attached to the IC package. The apparatus also includes capacitive thermal material reservoirs contacting the first side of the heat spreader. The capacitive thermal material reservoirs may be disposed laterally relative to the heat generating device.

Abstract: Various embodiments of methods and systems for controlling and/or managing thermal energy generation on a portable computing device are disclosed. Data discarded from one or more processing core registers may be monitored and analyzed to deduce individual workloads that have been processed by each of the cores over a unit of time. From the deduced workloads, the power consumed by each of the cores over the unit of time in order to process the workload can be calculated. Subsequently, a time dependent power density map can be created which reflects a historical and near real time power consumption for each core. Advantageously, because power consumption can be correlated to thermal energy generation, the TDPD map can be leveraged to identify thermal aggressors for targeted, fine grained application of thermal mitigation techniques. In some embodiments, workloads may be reallocated from the identified thermal aggressors to the identified underutilized processing components.