A method of making an annular component includes forming sheet feedstock into an annular shape disposed about a central axis; and bonding one portion of the feedstock to another portion of the feedstock using ultrasonic welding, so as to fix the annular shape.

A method of making an annular component includes forming sheet feedstock into an annular shape disposed about a central axis; and bonding one portion of the feedstock to another portion of the feedstock using ultrasonic welding, so as to fix the annular shape.

A method for joining hot slabs, which can be fed in succession to at least one roll stand. Joining sides of the hot slabs facing each other are, by pendular friction welding and/or vibration friction welding, simultaneously integrally bonded to a single metal intermediate piece arranged between the joining sides, by oscillatingly moving the intermediate piece at least largely parallel to the joining sides, while the joining sides are pressed against the intermediate piece and are held stationary; or simultaneously integrally bonded to at least one separate metal intermediate piece each, the intermediate pieces being arranged between the joining sides, by pressing the intermediate pieces arranged in series between the joining sides and oscillatingly moving the intermediate pieces at least largely parallel to the joining sides and oppositely to each other, while the joining sides are pressed against the intermediate pieces and held stationary.

The present disclosure relates to a process for integrally joining an electrical line to an electric contact part by means of a material bond. An exposed end of the line is inserted into a receiving sleeve of the contact part. Then a friction welding tool is rotated on an open end face of the receiving sleeve for the cohesive connection of the line end with the receiving sleeve. According to the disclosure, a powdery metal filler material is introduced into the receiving sleeve before rotation in such a way that the metal filler material is at least partially arranged between the line end and/or the receiving sleeve and the friction welding tool. Furthermore, the disclosure also concerns an electrical line arrangement which is manufactured with the aid of the metal filler material.

A molding method according to the present invention is a method of molding a composite material including a first member, a second member, and a reinforcement member interposed between the first member and the second member, the method including a first step of disposing the reinforcement member between the first member and the second member, and a second step of causing the first member to collide with the second member by a predetermined urging force after the reinforcement member is disposed, thus joining the first member and the second member with the reinforcement member interposed between the first member and the second member. The composite material has a thickness of 0.01 mm or more and 1 mm or less.

An interlayered structure for joining of dissimilar materials includes: a first material substrate; a second material substrate having a composition dissimilar from a composition of the first material substrate; and a plurality of interlayers disposed between the first material substrate and the second material substrate, including a first interlayer nearest to the first material substrate and a last interlayer nearest to the second material substrate. The first interlayer has a composition selected to have a maximum solid solubility within the composition of the first material substrate that is greater than or equal to the other interlayers within the composition of the first material substrate, and the last interlayer has a composition selected to have a maximum solid solubility within the composition of the second material substrate that is greater than or equal to the other interlayers within the composition of the second material substrate.

An interlayered structure for joining of dissimilar materials includes: a first material substrate; a second material substrate having a composition dissimilar from a composition of the first material substrate; and a plurality of interlayers disposed between the first material substrate and the second material substrate, including a first interlayer nearest to the first material substrate and a last interlayer nearest to the second material substrate. The first interlayer has a composition selected to have a maximum solid solubility within the composition of the first material substrate that is greater than or equal to the other interlayers within the composition of the first material substrate, and the last interlayer has a composition selected to have a maximum solid solubility within the composition of the second material substrate that is greater than or equal to the other interlayers within the composition of the second material substrate.

A bonded body of copper and ceramic includes: a copper member made of copper or a copper alloy and a ceramic member made of an aluminum oxide, the copper member and the ceramic member being bonded to each other; a magnesium oxide layer which is formed on a ceramic member side between the copper member and the ceramic member; and a Mg solid solution layer which is formed between the magnesium oxide layer and the copper member and contains Mg in a state of a solid solution in a Cu primary phase, in which one or more active metals selected from Ti, Zr, Nb, and Hf are present in the Mg solid solution layer.

A bonded body of copper and ceramic includes: a copper member made of copper or a copper alloy and a ceramic member made of an aluminum oxide, the copper member and the ceramic member being bonded to each other; a magnesium oxide layer which is formed on a ceramic member side between the copper member and the ceramic member; and a Mg solid solution layer which is formed between the magnesium oxide layer and the copper member and contains Mg in a state of a solid solution in a Cu primary phase, in which one or more active metals selected from Ti, Zr, Nb, and Hf are present in the Mg solid solution layer.

This disclosure describes various configurations and components for bimetallic and trimetallic claddings for use as a wall element separating nuclear material from an external environment. The cladding materials are suitable for use as cladding for nuclear fuel elements, particularly for fuel elements that will be exposed to sodium or other coolants or environments with a propensity to react with the nuclear fuel.