A production method of a joint material includes a tab installation step of installing an end tab on a pair of workpieces to be joined at a joining line therebetween by friction stir welding, a tool installation step of installing a probe of a tool for friction stir welding at a cutout portion; an approach step of moving the tool while rotating itself from an opening into the cutout portion; a waiting step of causing the tool for friction stir welding to standby in the cutout portion at an extension line; and a joining step of starting movement of the tool along the joining line at a time at which a temperature of the workpieces at a joining portion in front of the tool in an advancing direction of the tool in the waiting step is a predetermined temperature or more and joining the workpieces with each other.

A friction stir processing (FSP) tool includes a pin having a pin body and a rotational axis. The pin is configured to rotate about the rotational axis in a rotational direction. The pin has a radial protrusion protruding radially from the pin body, and the radial protrusion has a working surface oriented in the rotational direction with a depth in a radial direction relative to the rotational axis.

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.

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.

Disclosed are rotating tools for double-sided friction stir welding that are applied to double-sided friction stir welding, which is a technique for welding two metal plates by rotating a pair of rotating tools, which oppose each other, in opposite directions, a double-sided friction stir welding apparatus that uses the rotating tools, and a double-sided friction stir welding method. A pair of rotating tools for double-sided friction stir welding that are used in double-sided friction stir welding, which is a technique for welding metal plates by using a pair of rotating tools that are each disposed on one of first and second surfaces of an unwelded portion of the metal plates such that the rotating tools rotate in opposite directions, include end portions each of which is formed in a circular and planar shape. The end portions are each made of a material harder than the metal plates.

A friction stir welding tool comprises a cylindrical shank, a shoulder portion disposed at a distal end of the shank, a pin extending from the shoulder, a cutting insert mounted within a concave portion at the distal end of the shank, and a scribe cutter mounted at a distal end of the cutting insert. The cutting insert extends distally through a channel in the pine, and the scribe cutter extends from a distal end surface of the pin in an offset position. The distal end surface of the pin is perpendicular to a longitudinal axis of the shank.

A bottle cap may include a threaded mounting section configured to be screwed to an outlet port of the squeeze bottle from a first end of the threaded mounting section, a spring-loaded nozzle attached to a second opposing end of the threaded mounting section, where the spring-loaded nozzle includes a nozzle and a first resilient spiral spring connecting the second end of the threaded mounting section to an outer surface of the nozzle. The bottle cap may further include a first spring-loaded plug mounted within the threaded mounting section between the opening of the squeeze bottle and the inlet port of the nozzle. The first spring-loaded plug may include a first plug attached to an inner surface of the threaded mounting section utilizing a second resilient spiral spring. The first plug is configured to sit on a peripheral ledge of the inlet port of the nozzle.

A double-pin friction stir device may include an annular friction surface with a central hole, where the annular friction surface is rotatable about a normal axis of the annular friction surface in a first direction. The device may further include a first pin extending through the central hole along a normal axis of the annular friction surface. A distal end of the first pin may protrude from the annular friction surface and the first pin may rotate about a longitudinal axis of the first pin in the first direction. The device may further include a second pin extending through the central hole along and parallel with the first pin, where a distal end of the second pin protrudes from the annular friction surface. The second pin rotates about a longitudinal axis of the second pin in a second direction opposite the first direction.

A rotary tool includes: a main body, and a rotary shaft for transmitting a rotary force; a stirring pin that is arranged on the main body so as to be rotatable by receiving the rotary force and to be movable relative to an axial direction of the rotary shaft, and that is inserted into a joint member to perform friction stirring on the joint member; a shoulder that is formed separately from the stirring pin, that is arranged on the main body so as not to receive the rotary force from the main body but to be movable separately from the stirring pin relative to the axial direction of the rotary shaft, and that presses the joint member while in contact with the joint member; and a first elastic member that biases the stirring pin toward a distal-end side relative to the axial direction of the rotary shaft.

Described are enclosures that include a friction stir weld, including electronic device enclosures, and precursors thereof, that contain a base and a cover that in an assembled condition form a joint at which a friction stir weld can be produced, as well as methods for producing a friction stir weld at a joint of such an assembly.