An embodiment of an apparatus includes a raw material deposition head in communication with a working surface, an energy beam generator, a wire feed, and an ultrasonic head. The energy beam generator is directed toward the working surface for consolidating raw material disposed on the working surface by the raw material deposition head. The wire feed dispenses pre-formed wire to the raw material consolidated on the working surface by an energy beam from the energy beam generator. The ultrasonic head is directed to embed the dispensed pre-formed wire into the consolidated raw material.

A diesel exhaust fluid (DEF) storage system may include a reservoir body having a magnet integrally formed about an inlet opening of the reservoir body. For example, the magnet may be molding about a perimeter of the inlet opening during a molding process in which the reservoir body is formed. In some examples, the inlet opening defines a lumen extending into an interior of the reservoir body with the magnet being positioned at a location along the lumen opposite an external end face. The position of the magnet may be effective to engage a corresponding magnet on a DEF fill nozzle, allowing DEF to be introduced into the reservoir body. By integrating the magnet into the reservoir body, protection features that prevent erroneous filling of the reservoir body cannot be removed or bypassed.

A golf club head with center of gravity proximate to the club head's sweet spot is disclosed. The golf head is composed of a strike face component made from a high-density material and a club body component made from a lightweight material. This combination improves the golfer's chances to strike the golf ball with the club head sweet spot and to land the ball closer to the hole on the green.

A system of securing a connection of a decorative feature to a magnetic surface is provided. The system includes (a) a decorative feature attached to a substrate; (b) a magnet configured to be positioned within the substrate; and (c) two or more attachment arms extending away from the substrate and overmolding the magnet. The magnet is configured to magnetically secure the decorative feature to a magnetic attachment surface. In an example the substrate is a panoramic ring of a vehicle and the decorative feature is a headliner. The magnet is provided in a magnet bowl that includes an engagement feature to assist in overmolding. An attachment clip is also provided having two or more attachment arms with a magnet assembly overmolded to the clip. A pressure fit clip is provided having two or more attachment arms with a magnet assembly overmolded to the clip.

Methods of embedding a heating circuit in an article fabricated by additive manufacturing. The methods describe techniques such as co-extruding a wire, capable of being heated, along with print material in additive manufacturing of the article, and placing a pre-shaped wire capable of being heated between adjacent layers of the article. A third method includes dispensing a wire, capable of being heated, during the additive manufacturing of the article, and compacting the wire into the printed material. An apparatus for embedding a heating circuit in an article fabricated by additive manufacturing. The apparatus contains a wire dispenser, a cutter to control the length of the wire dispensed, and a compactor capable of embedding the wire capable of being heated into the printed material. An article made by additive manufacturing is disclosed. The article contains at least one heating element embedded in the article during the additive manufacturing process.

A method and apparatus for forming a radius filler. A lattice is formed of connecting elongate members having a three-dimensional shape of the radius filler. A resin is placed within the lattice.

Various embodiments of the present invention relate to plastic-metal junctions and methods of making the same. In various embodiments, the present invention provides a method of forming a junction between a metal form and a solid plastic. The method can include contacting a metal including a plurality of pores and a flowable resin composition including a polybutylene terephthalate and a polyethylene terephthalate. The method can also include curing the flowable composition to form the solid plastic, to provide the junction between the metal and the solid plastic.

An exemplary process includes determining a desired pore size, selecting an initial pore size greater than the target pore size, manufacturing a porous structure with the initial pore size, forging the porous structure to form a forged part having the desired pore size, and forming an orthopedic device from the forged part.

In an implementation, a rotor blade (alternatively referred to herein as blade) for a helicopter or other aircraft may include an outer layer. The outer layer may define a cavity. The outer layer may at least partially correspond to an airfoil, e.g., a wing. One or more inserts may be included within the cavity and be encompassed thereby. The first insert may have a density of at least 0.6 pounds per cubic inch.

Methods of embedding a heating circuit in an article fabricated by additive manufacturing. The methods describe techniques such as co-extruding a wire, capable of being heated, along with print material in additive manufacturing of the article, and placing a pre-shaped wire capable of being heated between adjacent layers of the article. A third method includes dispensing a wire, capable of being heated, during the additive manufacturing of the article, and compacting the wire into the printed material. An apparatus for embedding a heating circuit in an article fabricated by additive manufacturing. The apparatus contains a wire dispenser, a cutter to control the length of the wire dispensed, and a compactor capable of embedding the wire capable of being heated into the printed material. An article made by additive manufacturing is disclosed. The article contains at least one heating element embedded in the article during the additive manufacturing process.