The present disclosure relates to manufacturing an inflatable structure. There is determined one or more contours of at least a portion of an inflatable structure to be manufactured. There is further provided a drop stitch fabric having a first layer and a second layer tethered by drop stitches. Moreover, there is provided along at least a portion of the drop stitch fabric one or more fixation lines comprising coupling means fixating the first layer to the second layer, the one or more fixation lines corresponding to the one or more contours. Furthermore, the drop stitch fabric is coated, wherein one or more coating layers cover at least the one or more fixation lines. The disclosure also relates to an inflatable structure manufactured according to the foregoing, and a control system for controlling said manufacturing.

An apparatus including an overlay with a top side and a bottom side. The apparatus also can include an adhesive component with a top side and a bottom side. The top side of the adhesive component can be adhered to the bottom side of the overlay. The adhesive component can be configured to adhere the bottom side of the overlay to a screen of an electronic device in a single-use application of the overlay by adhering the bottom side of the adhesive component to the screen of the electronic device. The apparatus can be configured such that, when the overlay is removed from being adhered to the screen of the electronic device after the single-use application of the overlay, at least a portion of the adhesive component is detached from at least a portion of the overlay. Other embodiments are provided.

A system for maintaining alignment of a press plate is provided. The system comprises: a press including a press plate, the press configured for forming a laminate comprising a decorative layer and a substrate; a camera; and a processing device configured to: retrieve a laminate design file comprising a decorative design drawing layer and a texture design drawing layer, the laminate design file illustrating the decorative design drawing layer overlaid with the texture design drawing layer; following manufacture of the laminate with the press, capture an image of the laminate with the camera; compare a portion of the captured image of the laminate to a corresponding portion of the laminate design file to determine a registration quality; based on the determined registration quality, determine a misalignment of the decorative layer with the press plate; and in response to determining the misalignment, trigger an alert.

An optical bonding machine is provided, including a transparent datum located within the optical bonding machine, wherein the transparent datum supports a first substrate, a robotic placement head configured to pick up a second substrate and place the second substrate into contact with the first substrate, on the transparent datum, a camera disposed proximate the transparent datum, the camera capturing a video of a flow of an optically clear adhesive between the first substrate and the second substrate, and a curing source disposed proximate the transparent datum, the curing source emitting UV rays that pass through the transparent datum and the first substrate to cure an optically clear adhesive between a bonded substrate comprising the first substrate, the optically clear adhesive, and the second substrate. An associated method is also provided.

A manufacturing device for manufacturing an electrode assembly by laminating unit electrode assemblies in each of which an electrode is placed on a separator. The device includes a transferring device that includes a sucking plate and transfers, onto the positional adjustment stage, each of the unit electrode assemblies sucked up by the sucking plate. Moreover, an image capturing device captures an image of the electrode of each of the unit electrode assemblies placed on the positional adjustment stage. A positional adjustment device positionally adjusts the positional adjustment stage based on the image of the electrode captured, and a transferring and laminating device picks up each unit electrode assembly and transfers each to a lamination stage and performs a lamination process. At least part of the sucking plate is transparent and the image capturing device captures an image of the electrode from above the transparent portion of the sucking plate.

The disclosure relates to additively manufactured (AM) composite structures such as panels for use in transport structures or other mechanized assemblies. An AM core may be optimized for an intended application of a panel. In various embodiments, one or more values such as strength, stiffness, density, energy absorption, ductility, etc. may be optimized in a single AM core to vary across the AM core in one or more directions for supporting expected load conditions. In an embodiment, the expected load conditions may include forces applied to the AM core or corresponding panel from different directions in up to three dimensions. Where the structure is a panel, face sheets may be affixed to respective sides of the core. The AM core may be a custom honeycomb structure. In other embodiments, the face sheets may have custom 3-D profiles formed traditionally or through additive manufacturing to enable structural panels with complex profiles. The AM core may include a protrusion to provide fixturing features to enable external connections. In other embodiments, inserts, fasteners, or internal channels may be co-printed with the core. In still other embodiments, the AM core may be used in a composite structure such as, for example a rotor blade or a vehicle component.

A machine including a base. The machine also can include a cradle configured to hold an electronic device. The machine further can include an alignment base configured to engage with an alignment mechanism of an overlay applicator. The overlay applicator can include an overlay configured to be applied to a screen of the electronic device. The machine also can include a lid hingedly attached to the base. The machine can be configured such that the lid can be rotated with respect to the base between an open configuration and a closed configuration. The machine can be configured in the closed configuration to facilitate applying the overlay of the overlay applicator to the screen of the electronic device. Other embodiments are described.

The present disclosure relates to a method for teaching a laminating method as well as operating a laminating device, the both being for laminating a film element on a substrate part, in which designated path routes, in particular designated path curves, along which grippers for gripping the film element are subsequently moved to laminate the film element, are determined and taught by way of CAD data of the substrate part as well as the film element.

Systems and methods are provided for acoustic paneling. One embodiment is a method for fabricating an acoustic panel. The method includes receiving a sheet of thermoplastic paper, stamping/conforming the sheet into rows that each comprise a three dimensional shape, and transforming the sheet into a multi-celled core. Transforming the sheet includes identifying fold lines separating the rows, folding the sheet at the fold lines in a pleat fold, thereby uniting upper surfaces of adjacent rows and uniting lower surfaces of adjacent rows; and compressing the rows of the folded sheet together in the presence of heat, causing adjacent rows to fuse together into cells. The method further includes applying a backing sheet to the core, and applying a facesheet to a surface of the core that includes openings which direct a portion of airflow across the facesheet into the cells, resulting in acoustic control.

Provided is a lamination device that laminates an electrolyte film and a porous film. The lamination device includes a support portion configured to support a porous film roll, in which the porous film is wound, such that the porous film roll is able to revolve, an unwinding portion configured to support an electrolyte film roll, in which the electrolyte film is wound, and unwind the electrolyte film from the electrolyte film roll, a conveying portion configured to convey the unwound electrolyte film, and a control portion configured to control the support portion, the unwinding portion, and the conveying portion. The control portion is configured to control the support portion such that the conveyed electrolyte film and the porous film roll are brought closer to one another and an outer peripheral surface of the porous film roll is pressed against one of surfaces of the electrolyte film.