An additive manufacturing apparatus is provided and may include at least one build unit; a build platform; and at least one collector positioned on the apparatus such that the at least one collector contacts an outer surface of a build wall as the build wall is formed during a build. Methods are also provided for manufacturing at least one object.

A resistive soldering system, includes a first electrode; a second electrode; a support cylinder; a resistive soldering joint which is adapted to raise or lower the first electrode, the second electrode and the support cylinder; and a power supply unit which is connected with the first and second electrodes and adapted to supply power and a heating current to the first and second electrodes.

A method of making a light weight component is provided. The method including the steps of: forming a metallic foam core into a desired configuration; and applying an external metallic shell to an exterior surface of the metallic foam core after it has been formed into the desired configuration.

An article including a ceramic material and featuring a machined surface that is characteristic of cold ablation laser machining, wherein the machined surface exhibits no visible oxidation.

A laser machining apparatus and technique based on cold-ablation, but modified or augmented with an inert assist gas, which minimizes the deleterious surface modifications and mitigates the oxide formation associated with laser machining.

The present disclosure is directed to a multi-segment device, such as an intravascular guide wire. The multi-segment device includes an elongate first portion comprising a first metallic material, an elongate second portion comprising a different metallic material, the first and second elongate portions being directly joined together end to end by a solid-state weld, and a heat affected zone surrounding an interface of the weld where the first and second portions are joined together, wherein the heat affected zone has an average thickness of less than about 0.20 mm.

A laser texturing process modifies the surface of a semiconductor wafer-handling device so that flatness is maintained, but controlled roughness is imparted to prevent unwanted wafer sticking. The laser texturing may be from a thermal laser, a cold ablation laser, or either laser modified with an inert cover gas. The laser etches or burns away a portion or fraction of a flat surface, thereby reducing the area of contact to the semiconductor wafer and thereby reducing friction and sticking. The etched or burned-away portion is thus at a reduced, relieved or lower elevation than the unaffected portion. The laser texturing may take the form of a plurality of channels cut into the surface, or a plurality of holes. Laser machining can yield a semiconductor wafer handling device having finer detail than can be produced by other shaping techniques, with feature sizes on the order of 50 microns being achievable.

A copper-based brazing material comprises an alloy having nickel in a proportion of from 20 to 35 percent by weight, zinc in a proportion of from 5 to 20 percent by weight, manganese in a proportion of from 5 to 20 percent by weight, chromium in a proportion of from 1 to 10 percent by weight, silicon in a proportion of from 0.1 to 5 percent by weight and molybdenum in a proportion of from 0 to 7 percent by weight, each based on the total weight of the alloy, and the remainder being copper and unavoidable impurities. The alloy is in particular free from boron, phosphorus and lead. The brazing material can be used for induction brazing of components made of iron materials for exhaust systems in motor vehicles.

Devices and methods are provided for an implantable medical device which is degradable over a clinically relevant period of time. The medical devices may have the form of implants, graft implants, vascular implants, non vascular implants, wound closure implants, sutures, drug delivery implants, biologic delivery implants, urinary tract implants, inter-uterine implants, organ implants, bone implants including bone plates, bone screws, dental implants, spinal disks, or the like. In preferred embodiments, the implantable medical device comprises an implantable luminal prosthesis, such as vascular and non-vascular stents and stents grafts.

A chip card body including a metal plate, a reception region in the metal plate for receiving a chip and configured for inductive coupling of the metal plate to a chip received in the reception region; and at least one through-opening in the metal plate and configured such that at least a part of the metal plate acts as an antenna for delivering an electromagnetic signal to the reception region.

Disclosed are a gear product having an enhance deposition surface and a deposition system for manufacturing the gear product. The gear product having a reinforced deposition surface according to the present disclosure includes: teeth in which valleys and crests are successively famed along an outer or inner circumference of a cylindrical body having a central rotation shaft; and a reinforced deposition layer, which is formed by radiating a laser beam in a coaxial nozzle system to be directed to the teeth and injecting powdered materials to be in contact with a radiation axis of the laser beam around the radiated laser beam such that the powdered materials are melted and integrated with a surface of the teeth. According to the present disclosure, a reinforced corrosion-resistant and wear-resistant deposition layer famed on a gear product is formed through a coaxial nozzle system in which powdered materials, which are injected so as to be in contact with the radiation axis of a laser beam radiated towards teeth around the radiated laser beam, is melted by the laser beam so as to be deposited on the surface of the teeth. Thus, it is possible to freely and finely control the laser beam power, the rotational speed of the gear, and the type and the injection amount of powdered materials according to the shape and size of the crests and valleys (teeth), and the physical properties of the raw material constituting the gear product, so that a deposition layer, optimized to the teeth having various shapes and physical properties, can be uniformly and precisely formed.