Abstract: Printed circuit boards include conductive metallic paths, such as vias, traces, and pads on the printed circuit board. One or more metal additive structures are additively manufactured onto the printed circuit boards in a manner that forms a continuous weld with at least one of the conductive metallic paths. As a result, the metal additive structures are continuous with the printed circuit board and do not require separate attachment mechanisms (e.g., soldering or mechanical fastening). The metal additive structures may include shield cans, frames, antennas, or heat sinks for the printed circuit board, for example.

Abstract: A lost wax cast vapor chamber device is provided. Once a mesh is produced, a meltable core is formed from a meltable core material with the mesh positioned at least partially inside the core. Over the meltable core a metallic layer is formed, at least partially surrounding the meltable core. A chamber formed by the metallic layer is exposed by melting the meltable core to cause it to be removed from an internal void of the chamber, the internal void encapsulating the mesh. The melted material from the meltable core flows out an opening on at least one surface of the chamber. Subsequently, the internal void is filled at least partially with a working fluid and the opening is closed. The mesh supports the surfaces of the chamber against deformation under the vacuum of the internal void. Movement of working fluid by capillary action is facilitated by the mesh.

Abstract: A three-dimensional printed vapor chamber device is provided. A chamber from a first surface and a second surface at least partially enclosing a volume includes a spanning structure extending from the first surface to the second surface throughout a region within the volume. A defined gap between the first surface and second surface is maintained by the spanning structure, which also defines a plurality of flow passages. Evaporated working fluid flows from an evaporation region proximate a heat source through looped flow passages to a condensation region at a distal end of the chamber before returning as condensate by way of capillary action to the evaporation region.

Abstract: A dissipation or rigid support layer for a display device (such as a touch screen display device) is provided herein. The display device may include a display unit (e.g., a LCD unit and backlight unit), an internal electronics component, and a dissipation layer disposed between the display unit and the internal electronics component. The dissipation layer may be affixed to a surface of the display unit, and the dissipation layer may be configured to at least partially disperse a mechanical force applied by the internal electronics component on the display unit when an input force moves the dissipation layer into contact with the internal electronics component. In some examples, the dissipation layer is affixed to the surface of the display unit via an adhesive layer (e.g., an optically clear adhesive layer).

Abstract: A dissipation or rigid support layer for a display device (such as a touch screen display device) is provided herein. The display device may include a display unit (e.g., a LCD unit and backlight unit), an internal electronics component, and a dissipation layer disposed between the display unit and the internal electronics component. The dissipation layer may be affixed to a surface of the display unit, and the dissipation layer may be configured to at least partially disperse a mechanical force applied by the internal electronics component on the display unit when an input force moves the dissipation layer into contact with the internal electronics component. In some examples, the dissipation layer is affixed to the surface of the display unit via an adhesive layer (e.g., an optically clear adhesive layer).

Abstract: A point of sale coffee pod dispensing device for use with shell less, expandable coffee pods. The compressible pods are arranged in a linear array that allows for pleated or stacked storage in a pod loading means within the device's enclosure, as well as continuous feed capabilities. The pod advancing means moves the pods from a pod loading station to the pod delivery station, there between sequentially passing through stations for pod expanding, coffee filling, and sealing. An operating system allows input of signals for the operation of the device based on tactile input from a control panel on the device's housing that determines the parameters of the coffee pods to be fabricated.

Abstract: A method of fabricating coffee pods at a point of sale location using a coffee pod dispensing device with shell less, expandable coffee pods. The fabrication is initiated by tactile input from a control panel that determines the parameters of the coffee pods to be fabricated and generates the operational signals for the dispensing device. Fabrication there after progresses sequentially through a series of operations that involves the loading of the coffee pods onto a pod advancing means which then takes the coffee pods through the steps of expansion, filling, sealing and delivery. To accomplish this the pods are compressible pods arranged in a linear array that allows for pleated or stacked storage in a pod loading means within the device's enclosure, as well as continuous feed capabilities.

Abstract: A shell less, biodegradable coffee pod for use with a point of sale coffee pod dispensing device. The pod is compressible for pleated or stacked storage and linearly linked to a series of substantially similar pods by a flexible, hingeable separable tab bridging between adjacent pods. The pods have a support structure that is affixed to a fillable well. Each well is expandable with an expanding means (utilizing a burst of air, a vacuum or mechanical pusher) as the series of pods is mechanically advanced along a tractor feed style conveyor belt that passes the pod to a ground coffee bean filling unit, a sealing unit and a pod separating unit.

Abstract: A support component for an apparatus is described. In at least some implementations, a support component is attached to an apparatus (e.g., a computing device) via a hinge mechanism. The support component can serve as a “kickstand” that can be positioned via the hinge mechanism to support the apparatus in a variety of orientations relative to an adjacent surface. In at least some embodiments, a support component includes hinge mounts via which the support component is attached to hinges of an associated apparatus. The support component and associated hinge mounts, for instance, can be manufactured separately and/or via different manufacturing processes, and attached during a production process.

Abstract: A support component for an apparatus is described. In at least some implementations, a support component is attached to an apparatus (e.g., a computing device) via a hinge mechanism. The support component can serve as a “kickstand” that can be positioned via the hinge mechanism to support the apparatus in a variety of orientations relative to an adjacent surface. In at least some embodiments, a support component includes hinge mounts via which the support component is attached to hinges of an associated apparatus. The support component and associated hinge mounts, for instance, can be manufactured separately and/or via different manufacturing processes, and attached during a production process.

Abstract: Embodiments are disclosed herein that are related to input devices with curved multi-touch surfaces. For example, in one disclosed embodiment, a method of making a multi-touch input device having a curved touch-sensitive surface comprises forming on a substrate an array of sensor elements defining a plurality of pixels of the multi-touch sensor, forming the substrate into a shape that conforms to a surface of the curved geometric feature of the body of the input device, and fixing the substrate to the curved geometric feature of the body of the input device.

Abstract: A support component for an apparatus is described. In at least some implementations, a support component is attached to an apparatus (e.g., a computing device) via a hinge mechanism. The support component can serve as a “kickstand” that can be positioned via the hinge mechanism to support the apparatus in a variety of orientations relative to an adjacent surface. In at least some embodiments, a support component includes hinge mounts via which the support component is attached to hinges of an associated apparatus. The support component and associated hinge mounts, for instance, can be manufactured separately and/or via different manufacturing processes, and attached during a production process.

Abstract: A surface contact for a support component is described. The support component, for example, can serve as a “kickstand” that can be positioned to support the apparatus in a variety of orientations relative to an adjacent surface. A surface contact disposed on the support component can serve as an interface (e.g., a “foot”) for the support component on the adjacent surface. For instance, the surface contact can be formed from a slip-resistant material such that slippage of the support component on an adjacent surface is reduced or eliminated. In at least some embodiments, the surface contact is embedded with a material that responds to a magnetic field, e.g., a ferromagnetic material. The surface contact is attracted to magnets on an adjacent edge of the attached apparatus, thus stabilizing the support component in a closed position.

Abstract: In one or more embodiments, wedge light guides are constructed that are monolithic in nature and include integrally-formed optical concentrators. The wedge light guide and its associated optical concentrators are defined by a mold. In at least some embodiments, structure within the mold that defines the optical concentrators can be used as injection ports through which formation material can be injected to form the monolithic wedge light guide.

Abstract: Embodiments are disclosed that relate to casting of an optical part having a non-uniform thickness. For example, one disclosed embodiment provides a method for casting an optical part having a non-uniform thickness, the method including adding a fluid material into a first cavity and into a second cavity separated from the first cavity by a separator. The first and second cavities may each have a non-uniform thickness and the separator may have a configuration complementary to shapes of the first and second cavities such that the first cavity, the second cavity, and the separator form a combined structure having a uniform thickness during a casting process. The method further comprises solidifying the fluid material in the first and second cavities to form the first and second optical parts.

Abstract: Embodiments are disclosed herein that are related to input devices with curved multi-touch surfaces. One disclosed embodiment comprises a touch-sensitive input device having a curved geometric feature comprising a touch sensor, the touch sensor comprising an array of sensor elements integrated into the curved geometric feature and being configured to detect a location of a touch made on a surface of the curved geometric feature.

Abstract: A support component for an apparatus is described. In at least some implementations, a support component is attached to an apparatus (e.g., a computing device) via a hinge mechanism. The support component can serve as a “kickstand” that can be positioned via the hinge mechanism to support the apparatus in a variety of orientations relative to an adjacent surface. In at least some embodiments, a support component includes hinge mounts via which the support component is attached to hinges of an associated apparatus. The support component and associated hinge mounts, for instance, can be manufactured separately and/or via different manufacturing processes, and attached during a production process.

Abstract: A surface contact for a support component is described. The support component, for example, can serve as a “kickstand” that can be positioned to support the apparatus in a variety of orientations relative to an adjacent surface. A surface contact disposed on the support component can serve as an interface (e.g., a “foot”) for the support component on the adjacent surface. For instance, the surface contact can be formed from a slip-resistant material such that slippage of the support component on an adjacent surface is reduced or eliminated. In at least some embodiments, the surface contact is embedded with a material that responds to a magnetic field, e.g., a ferromagnetic material. The surface contact is attracted to magnets on an adjacent edge of the attached apparatus, thus stabilizing the support component in a closed position.

Abstract: Embodiments are disclosed that relate to fabrication of a laminated optical wedge. One embodiment provides a method comprising inserting a wedge blank into a vacuum molding tool, applying a vacuum to the vacuum molding tool, and removing a layer from a top surface of the wedge blank to expose a machined surface of the wedge blank. The method further comprises laminating a finish piece to the machined surface via an adhesive, wherein the finish piece comprises a smoother surface than the machined surface, and curing the adhesive to form a finished optical wedge. The method further comprises removing the finished optical wedge from the vacuum molding tool.

Abstract: Various embodiments are disclosed relating to fabrication of an optical wedge. For example, one embodiment provides a method for manufacturing an optical wedge comprising inserting a wedge blank into a vacuum molding tool and applying a vacuum to the vacuum molding tool to temporarily hold the wedge blank against a molding surface of the vacuum molding tool. The method further comprises removing a layer from a top surface of the wedge blank to expose a machined surface of the wedge blank, and casting a finish layer on the machined surface to form a finish layer of a finished optical wedge.