A method is provided for embedding an integrated circuit (IC) into a 3D-printed object. The method includes providing a filament having a material for 3D-printing an object, and an integrated circuit embedded within the filament material. The filament is used to form at least part of the 3D-printed object. A 3D-printing system is provided for implementing the method. The 3D-printing system includes a filament dispenser for storing and dispensing the 3D-printing filament. A platform provides a work surface for supporting the object as the object is being printed. A processor is provided for controlling a printing operation of the 3D-printer, and for 3D-printing the object with the filament having the ICs embedded therein. A configuration circuit is provided for configuring the IC as the IC is embedded in the 3D-printed object.

A method for producing a fiber composite component is disclosed. A sensor device having a flexible circuit carrier and/or a sensor module is integrated in the fiber composite component. The method comprises: loading a tool configured to produce the fiber composite component with textile layers and the sensor device; closing the loaded tool and compressing the textile layers and the sensor device; introducing a liquid matrix into the closed tool and impregnating the textile layers to produce the fiber composite component; detecting an acceleration in relation to the closing of the tool and/or the introducing of the liquid matrix, using at least one of the sensor device and the sensor module of the sensor device; and determining a process state and/or a process parameter based on a spectral analysis of the detected acceleration in a frequency domain.

A device for making a molded stair tread is described. The device can have: a base; a pivoting assembly; a molding template connected to the pivoting assembly; a holding device connected to the molding template, the holding device having a clamp jaw and a pivot configured to rotate the holding device relative to the molding template; and a locking mechanism configured to hold the molding template and the holding device in an open configuration such that the holding device can accept a first part of the plastic sheet and configured to release the molding template and the holding device such that the holding device is in a securing configuration that secures, via the clamp jaw, the first part of the plastic sheet to the first side of the molding template at the first longitudinal edge of the molding template. Methods for making the stair tread are described as well as the molded stair tread.

A method for producing a component made of fiber-reinforced plastic includes comprises the steps of providing at least one insert part, placing the insert part in a mold and embedding the insert part using a matrix material and at least one fiber mat in the mold. The insert part is provided as a closed capsule.

A composite core material and methods for making same are disclosed herein. The composite core material comprises mineral filler discontinuous portions disposed in a continuous encapsulating resin. Further, the method for forming a composite core material comprises the steps of forming a mixture comprising mineral filler, an encapsulating prepolymer, and a polymerization catalyst; disposing the mixture onto a moving belt; and polymerizing said encapsulating prepolymer to form a composite core material comprising mineral filler discontinuous portions disposed in a continuous encapsulating resin.

A friction disk may comprise a first wear surface formed from a carbon fiber-carbon matrix composite material. A wear plug may be located in an opening defined by the carbon fiber-carbon matrix composite material. The wear plug may extend axially from the wear surface. The wear plug may comprise a rod or a particulate.

A friction disk may comprise a first wear surface formed from a carbon fiber-carbon matrix composite material. A wear plug may be located in an opening defined by the carbon fiber-carbon matrix composite material. The wear plug may extend axially from the wear surface. The wear plug may comprise a rod or a particulate.

Provided is a technology for imparting a design having a higher degree of freedom than in the related art to a composite material product including a woven fabric, which is formed of a thread made of a specific fiber (carbon fiber, glass fiber, aramid fiber), and a resin. As a first step, a specific fiber cloth (100), which is the woven fabric formed of the thread made of a specific fiber, and a backing sheet (200) formed of a thermoplastic resin are stacked. Subsequently, embroidery is performed with an embroidery thread (300) to form a design on a front surface of the specific fiber cloth (100). The embroidery thread (300) is made of the specific fiber, and penetrates through the specific fiber cloth (100) and the backing sheet (200). Then, the specific fiber cloth (100) and the backing sheet (200) are sandwiched between resin sheets (400) each formed of a thermoplastic resin, and the whole is cured by an RFI method.

A method for producing a product (200, 300, 400) comprising a composite fiber part (202, 402) and a second part (201, 401), wherein the second part (201, 401) comprises a carrier part (203, 403), wherein the carrier part (203, 403) is a replica of a press tool (301a, 301b) configured to be heated and to apply a pressure, comprising the steps of: applying (101), in a non-cured state, the composite fiber part (202, 402) on the carrier part (203, 403); arranging (103) the carrier part (203, 403) comprising the composite fiber part (202, 402) on the press tool (301a, 301b); curing (104a) the composite fiber part (202, 402) on the carrier part (203, 403); and removing (105) the product (200, 300, 400) from the press tool (301a, 301b), wherein after removal from the press tool (301a, 301b) the composite fiber part (202, 402) and the carrier part (203, 403) constitutes together at least a part of the finished product (200, 300, 400). Also disclosed is a composite fiber product comprising a composite fiber part and a second part.

A method for producing a product (200, 300, 400) comprising a composite fiber part (202, 402) and a second part (201, 401), wherein the second part (201, 401) comprises a carrier part (203, 403), wherein the carrier part (203, 403) is a replica of a press tool (301a, 301b) configured to be heated and to apply a pressure, comprising the steps of: applying (101), in a non-cured state, the composite fiber part (202, 402) on the carrier part (203, 403); arranging (103) the carrier part (203, 403) comprising the composite fiber part (202, 402) on the press tool (301a, 301b); curing (104a) the composite fiber part (202, 402) on the carrier part (203, 403); and removing (105) the product (200, 300, 400) from the press tool (301a, 301b), wherein after removal from the press tool (301a, 301b) the composite fiber part (202, 402) and the carrier part (203, 403) constitutes together at least a part of the finished product (200, 300, 400). Also disclosed is a composite fiber product comprising a composite fiber part and a second part.