A method is provided for manufacturing an article. The method comprises depositing by additive friction stir deposition a wear-resistant material on a surface of a preform to provide an intermediate article. The preform comprises a first composition and the wear-resistant material comprises a second composition. The second composition is substantially different from the first composition. The method also comprises machining the intermediate article to remove therefrom at least a portion of the wear-resistant material.

A method of joining a first component and a second component that are made of dissimilar metals. In some embodiments, the method comprises applying friction between the first component and the second component sufficient to generate a layer of quasi-liquid metal and produce shear localization within the quasi-liquid metal at a dissimilar metal interface between the first component and the second component and terminating the application of friction at a predetermined time after generation of the quasi-liquid metal. In some embodiments, the method comprises applying amorphous metal between at least a portion of the first component and the second component at a dissimilar metal interface, heating the amorphous metal to a temperature between its glass transition temperature (T.sub.g) and the lowest melting temperature of the components involved, and applying compression pressure to generate thermoplastic deformation of the amorphous metal.

The invention relates to a rotatable, plungeable and free path travelable non-consumable tool (5) for production of a channel (2) and a weld joint (1). The tool (5) comprises a shoulder and a probe, the shoulder having a surface facing the material(s) of components (3) to be processed. The shoulder and the probe are arranged to have a simultaneous and synchronized action in the materials of at least two components (3) to be processed. The shoulder facing the at least two components (3) to be processed has a system of scrolls shaped to have an inward action and an outward action on the at least two components (3) to be processed. The probe has a cylindrical or conical surface having a top zone, provided with a profile having a push-up action on the components (3) to be processed in a direction towards the shoulder. The top zone ends at or in the vicinity of a bottom zone provided with a profile having a push-down action on the components (3) to be processed in a direction towards the tip. The tool (5) enables the production of a channel (2) and a weld (1), between said at least two components (3), in one single action.

A friction welding apparatus is provided, which includes a tool, a rotary driver, a linear driver, and a control device. The control device controls the linear driver and the rotary driver so that the tool is rotated while a tip-end part thereof is pressed against a to-be-joined part of a to-be-joined object to increase a temperature of the to-be-joined part at or above an A1 transformation point, the tip-end part of the tool reaches a given first position so that a softened second member sticks into a softened first member, and the tool is drawn out from the to-be-joined part while the tool is rotated.

A friction stir welding method using a resin composition including: a monomer (A) having an ethylenically unsaturated bond; a thermosetting resin (B); a radical polymerization initiator (C); and a fiber reinforcing material (D), wherein the thermosetting resin (B) is an unsaturated polyester resin or a vinyl ester resin.

A method for manufacturing a composite slab to manufacture a plural layer clad material composed of different kinds of metals, the method including: a preparation process to prepare a bottom portion, a metallic box body having a peripheral wall portion standing on a peripheral edge of the bottom portion, and a metallic sealing body to seal an opening of the box body; a butting process to butt a side face of the sealing body against an inner wall face of the peripheral wall portion to form a butted portion with intermediate members being inserted in a recessed portion of the box body and a closing process to join and close the butted portion. At least one of the intermediate members is made of a material different from at least one of the box body and the sealing body.

A manufacturing system includes a tension-wound system having a feedstock system and a shape fixture. The tension-wound system is configured to feed a feedstock from the feedstock system and to wind the feedstock under tension in successive layers around the shape fixture to allow the feedstock to form a component having a shape represented by the shape fixture. The manufacturing system includes a solid-state joining tool configured to additively join the successive layers of the feedstock. In a spiral tension-winding process, with a continuously-fed strip of aluminum feedstock around a piece of tooling, the feedstock can be friction stir welded and additively joined in successive layers to produce a large, near-net structure.

There is provided a manufacturing method of a terminal plate including a conductive plate and a terminal that is welded to the conductive plate and that is made of a different material from a material of the conductive plate. This manufacturing method comprises an overlapping process of laying an end portion of the terminal on the conductive plate; a pressing process of pressing part of overlapping surfaces of the conductive plate and the terminal, after the overlapping process; and a welding process of welding at least part of a remaining region excluding the pressed part of the overlapping surfaces, by friction stir welding.

A technique for creating a weld along a joint. A method begins by positioning a first edge of a first member proximate to a second edge of a second member to form the joint, wherein the joint is to be welded along the length from a first position on the joint to a second position on the joint. A clamping ring of a refill spot welding apparatus is placed to surround an unwelded portion of the length. The clamping ring contacts a top surface of the first member and a top surface of the second member. A first refill spot weld process is performed with the refill spot welding apparatus to join the first member and the second member at a first spot weld on the joint.

A video coder is configured to form, in a symmetric motion vector difference mode, a List 0 (L0) base vector using a L0 Advanced Motion Vector Prediction (AMVP) candidate list and a List 1 (L1) base vector using a L1 AMVP candidate list; determine a refined L0 motion vector and a refined L1 motion vector by performing a decoder-side motion vector refinement process that refines the L0 base vector and the L1 base vector; and use the refined L0 motion vector and the refined L1 motion vector to determine a prediction block for a current block of a current picture of the video data.