A pillar for a vehicle including at least two different localized areas of different tensile strengths. The pillar includes a body defining a width that merges into sidewalls at a transition. The body having a first tensile strength and the transition has a second tensile strength, wherein the first tensile strength is smaller than the second tensile strength. The variety in tensile strength resulting from at least one of varying the material treatment and varying the gauge. The pillar is press-hardened until it reaches a tensile strength of 1500 MPa to 2000 Mpa.

A part includes a sheet metal component having a predefined shape and at least one additively manufactured reinforcement deposited on, metallurgically bonded to, and extending along a surface of the sheet metal component. The at least one additively manufactured reinforcement can be a directed energy deposition (DED) reinforcement rib. Also, the at least one additively manufactured reinforcement can be deposited on the piece of sheet metal before the piece of sheet metal is formed into the predefined shape, or in the alternative, the at least one additively manufactured reinforcement can be deposited on the piece of sheet metal after the piece of sheet metal is formed into the predefined shape.

A part includes a sheet metal component having a predefined shape and at least one additively manufactured reinforcement deposited on, metallurgically bonded to, and extending along a surface of the sheet metal component. The at least one additively manufactured reinforcement can be a directed energy deposition (DED) reinforcement rib. Also, the at least one additively manufactured reinforcement can be deposited on the piece of sheet metal before the piece of sheet metal is formed into the predefined shape, or in the alternative, the at least one additively manufactured reinforcement can be deposited on the piece of sheet metal after the piece of sheet metal is formed into the predefined shape.

A method is shown for manufacturing a hardened gripping element for a sealing and restraint system used for forming a pipe joint in a fluid pipeline. Instead of machining the gripping elements used in the system from a metal stock, a special series of metal injection molding steps are utilized. A metal polymer composite mix is first formed having a metal particulate phase and a polymer phase. A green metal composite article is formed by either extruding the composite mix or molding the composite mix into a metal polymer composite article having at least one gripping surface having a plurality of gripping teeth. The composite article is subjected to thermal debinding and sintering to produce a finished or near finished hardened gripping element.

Systems and methods of additively manufacturing passive electronic components are provided. An additive manufacturing device may deposit a material to create a passive electronic component. A sensor may continuously measure an electrical property of the passive electronic component across two electrical contacts as the material is deposited during manufacturing. The sensor may transmit the measured electrical property to a processor whereby the processor may adjust a material deposition rate of the additive manufacturing device. The continuous measurement of the electrical property and adjustment of the material deposition rate as the passive electronic component is produced allows for passive electronic components to be manufactured to a high degree of accuracy of the electrical property.

A gas turbine engine assembly according to an example of the present disclosure includes, among other things, an endwall having a first material composition, an airfoil extending in a radial direction from the endwall, and a cupped contour of a second material composition that is formed on the endwall to define a cooling chamber, the first material composition different than the second material composition. A method of forming an endwall is also disclosed.

This silver paste is used to form a silver paste layer by applying the silver paste directly on the surface of a copper or copper alloy member, and the silver paste includes a silver powder, a fatty acid silver salt, an aliphatic amine, a high-dielectric-constant alcohol having a dielectric constant of 30 or more, and a solvent having a dielectric constant of less than 30. The content of the high-dielectric-constant alcohol is preferably 0.01% by mass to 5% by mass when an amount of the silver paste is taken as 100% by mass.

This silver paste is used to form a silver paste layer by applying the silver paste directly on the surface of a copper or copper alloy member, and the silver paste includes a silver powder, a fatty acid silver salt, an aliphatic amine, a high-dielectric-constant alcohol having a dielectric constant of 30 or more, and a solvent having a dielectric constant of less than 30. The content of the high-dielectric-constant alcohol is preferably 0.01% by mass to 5% by mass when an amount of the silver paste is taken as 100% by mass.

A method for manufacturing a thin sheet-like bonding member, including applying a paste including first particles including a first metal, second particles including a second metal having a lower melting point than the first metal, and a solvent to a surface of a base material made of a substance that does not react with the second metal; heating the paste at a temperature lower than a melting point of the first metal and higher than the melting point of the second metal to form a thin sheet-like bonding member on the surface of the base material; and peeling the thin sheet-like bonding member from the base material to obtain the thin sheet-like bonding member.

A method for manufacturing a thin sheet-like bonding member, including applying a paste including first particles including a first metal, second particles including a second metal having a lower melting point than the first metal, and a solvent to a surface of a base material made of a substance that does not react with the second metal; heating the paste at a temperature lower than a melting point of the first metal and higher than the melting point of the second metal to form a thin sheet-like bonding member on the surface of the base material; and peeling the thin sheet-like bonding member from the base material to obtain the thin sheet-like bonding member.