Provided is a method for manufacturing a liquid-cooled jacket, to reduce the size of a recessed groove on a surface of a metal member and also to reduce roughness of a jointed surface. The method includes: a placing step of placing a sealing body on a jacket body, a first main joining step of performing friction stirring by moving a main joining rotary tool around to a first overlapped portion, and a second main joining step of performing friction stirring to a second overlapped portion. The main joining rotary tool has a base-end-side pin and a tip-end-side pin. A taper angle of the base-end-side pin is greater than a taper angle of the tip-end-side pin and a stairs-like pin step portion is formed on an outer circumferential surface of the base-end-side pin.

The present invention relates to a joined component used in a semiconductor manufacturing process or a display manufacturing process, in which the joined component is formed by welding parent members by friction stir welding.

Disclosed example weld tracking system include a plurality of tracking anchors, each of the tracking anchors configured to: transmit a triggering signal, and transmit a response signal, or receive a response signal from a tracking tag; a welding device having the tracking tag attached to the welding device, the tracking tag configured to receive the triggering signal and receive the response signal, or receive the triggering signal and transmit the response signal in response to receiving the triggering signal; and a processing system configured to determine a distance between the tracking anchor and the tracking tag based on a time between the response signal being received and the triggering signal being sent or received, and determine a location of the welding device based on predetermined locations of the plurality of tracking anchors, and based on determined distances between the at least one tracking tag on the welding device and corresponding ones of the plurality of tracking anchors.

The present invention includes a preparation step in which a stepped portion including step bottom and step side surfaces is formed along an edge of a jacket body, a placing step in which a sealing body is placed on the jacket body forming first and second butted sections, and a main joining step in which friction stir welding (FSW) is performed by moving a rotary tool along the first butted section with only a stirring pin of the rotary tool in contact with only the sealing body. During FSW, a central axis of rotation of the rotary tool is tilted towards a central or peripheral side of the jacket body so that the angle of tilt relative to a vertical plane equals the angle the stirring pin's outer circumferential surface makes with the central axis of rotation subtracted by the angle the step side surface makes with a vertical plane.

A linear friction welding system in one embodiment includes a welding control system operably connected to a hydraulic press and a ram, the welding control system including a processing circuit operably connected to a memory and configured to execute program instructions stored in the memory to bring a shaped charge portion of a first component to be welded into contact with a second component to be welded, and establish an initial scrub load pressure between the two components based upon a ratio between initial surface area of a contact initiation portion of the shaped charge portion and a final surface area of the first component. The processing circuit increases pressure between the components from the initial scrub load pressure to a target scrub load pressure before terminating oscillation of the ram and establishing or maintaining a weld load pressure.

Provided is a joining method that can prevent a plastic flowing material from flowing out from a butt section and that can reduce the thickness and weight of metal members. The joining method is for joining a first metal member and a second metal member by using a rotary tool comprising a stirring pin, and is characterized in that: the stirring pin comprises a flat surface perpendicular to the rotation axis of the rotary tool and comprises a protruding section protruding from the flat face; and in a friction stirring step, the flat surface is brought into contact with the first metal member and the second metal member, and a front end face of the protruding section is inserted deeper than an upper overlapping section to join an upper front butt section and the upper overlapping section.

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 welding machine and method that injects filler materials into a weld joint and determines the amount of materials to add by monitoring and compensating for insufficient internal weld pressures in the joint. Two workpieces are placed adjacent one another in an abutting relationship with a joint formed between them. A pin tool is inserted in the joint, rotated, and moved along the joint as the pin is rotating so as to mix and heat materials in the joint. Internal weld pressures in the joint adjacent the pin tool are monitored, and filler materials are injection into the joint when an internal weld pressure below a threshold weld pressure is detected.

The friction stir welding head presented herein includes a head housing and an axle. The head housing extends from a top end to an open bottom end and defines a bore extending between the top end and the open bottom end. The axle that is coaxial with and rotatable within the bore. The axle is also laterally secured within the head housing and axially movable with respect to the head housing. Still further, the axle includes an engagement end that extends beyond the open bottom end of the head housing. The engagement end supports a friction stir welding tool that is configured to rotate with the axle to effectuate friction stir welding operations. The friction stir welding head may also include a load cell configured to generate load signals in response to axial movement of the axle.

A counter support for friction stir welding, which makes it possible to also produce very long weld seams by friction stir welding despite a very compact design, is shown. Curved components and nn-straight weld seams may also be produced.