Systems, methods, and devices are provided for the creation of predictable and accurate defects in a fiber tow of an Automated Fiber Placement (AFP) process, with such artificial defects being useful to support calibration of an in situ inspection system used in the AFP process. Various embodiments include methods for creating such artificial defects that support calibration of an in situ inspection system of an AFP system or process. Various embodiments may also include a defect stencils for an AFP system or process.

There is provided a method that includes directing one or more infrared cameras at a compaction roller of a composite laying head of a composite layup machine. The one or more infrared cameras are mounted aft of the compaction roller. The method includes applying heat to a substrate by a heater. The heater is mounted forward of the compaction roller. The method further includes using the one or more infrared cameras, to obtain one or more infrared images of the compaction roller, during laying down of one or more composite tows of a composite layup onto the substrate by the compaction roller. The method further includes identifying, based on the one or more infrared images, one or more temperature profiles of the compaction roller, and analyzing identified temperature profiles, to determine one or more of, a layup quality of the composite layup, and a heat history of the composite layup.

A system is disclosed for additively manufacturing a composite structure. The system may include a support, and a print head operatively connected to and moveable by the support. The print head may include an outlet configured to discharge a material in a trajectory along a central axis of the outlet, and a compactor disposed downstream of the outlet relative to the trajectory and configured to press the material transversely against an adjacent surface. The outlet may be configured to translate relative to the compacting module.

A system is disclosed for additive manufacturing of a composite structure. The system may include a support, and a print head connected to and moveable by the support. The print head may include an outlet configured to discharge a continuous reinforcement at least partially coated in a matrix. The outlet may be moveable relative to the support. The print head may also include at least one actuator configured to cause movement of the outlet relative to the support.

A composite filament for use in additive manufacturing such as fused filament fabrication is described along with methods of its construction and use. The composite filament includes a single continuous filament (e.g., a continuous carbon roving) and a polymer (e.g., a high glass transition polymer) in intimate contact. The composite filament is formed through immersion of the continuous filament in a solution of the polymer. The composite filament can be combined with an additional formation material in an additive manufacturing process.

The invention relates to a process for determining the susceptibility to nosocomical infections in a patient, comprising the measurement of the expression of sCD127 in a biological sample.

The object of the invention is the device for automatic reinforcement of structures, especially concrete structures, which has: —a manipulator (1) with the means for precisely moving it in space, —a printhead located on the endpiece of the manipulator (1), —a reinforcement fibre storage unit (2) in the form of a reel, located preferably on the printhead, characterized in that the reinforcement fibre storage unit (2) is connected to the means for laying the fibre on the surface of the structure being reinforced, where said means have drive rollers (4) and a cutting knife (5). The object of the invention is also the method for automatic reinforcement of structures, where said method uses a remote-controlled device.

An end effector for laying down fibers on a laying mold, the end effector having at least one bobbin arrangement of a system type, the system type being defined by virtue of the fact that the bobbin arrangement has a first bobbin for providing a first fiber strand and a second bobbin for providing a second fiber strand, the rotational axes of the first and the second bobbin being arranged at an angle with respect to one another, the first fiber strand and the second fiber strand being merged over a deflection unit and being guided from a corner region of the end effector jointly into a center region of the end effector and further to a pressure roller.

A sheet metal member forming method comprises placing a fiber bundle of a predetermined length, via a thermosetting resin, in a predetermined position on a surface of a sheet metal member, forming a coating film on at least a part of the sheet metal member after the placing of the fiber bundle, and while heating and drying the coating film, heat-curing the thermosetting resin to bond the fiber bundle to the sheet metal member.

A fiber placement head for applying a plurality of composite tape segments on a mold including one or more powered wheels that are configured to engage and move composite tape; and one or more elongated fingers that closely conform to or abut an outer surface of the powered wheel(s) such that a portion of the elongated finger(s) forms at least a portion of a lane path.