The disclosure relates to inducing compressive stress with shot peen elements in an internal opening of an additively manufactured component. Methods according to the disclosure include: receiving a component made by a metal powder additive manufacturing process, the component including a body having an external surface and an internal opening passing at least partially through the body, the internal opening including an additively manufactured shot peen element detached from a surface of the internal opening, wherein the additively manufactured shot peen element is shaped to induce a residual compressive stress upon contact with the surface of the internal opening; and vibrating the component at a selected frequency, wherein the additively manufactured shot peen element induces the compressive stress against the surface of the internal opening during the vibrating.

A process for producing a glass melting component composed of refractory metal. A surface zone of the glass melting component is densified at least in sections by application of local compressive stress. As a result the surface zone has its porosity reduced compared to a volume section which is located underneath the surface zone and which has residual porosity.

A process for producing a glass melting component composed of refractory metal. A surface zone of the glass melting component is densified at least in sections by application of local compressive stress. As a result the surface zone has its porosity reduced compared to a volume section which is located underneath the surface zone and which has residual porosity.

A method, apparatus, and program for build surface mapping and recovery for additive manufacturing. The method may include fabricating an object by additive manufacturing wherein the topology of a build surface is determined. An additive manufacturing process may be modified based on the topology determination. The topology of the surface may be determined by marking the surface with a first mark using a converging energy source; determining a dimension of the mark using a camera; and determining a height of the first mark based on the dimension of the mark.

A method is for treating at least one part of a metal component that is at least partly produced by additive manufacturing. The method comprises the steps of heating the at least one part of the metal component to form at least one softened region, and applying a mechanical load to the at least one softened region to plastically deform the metal in the at least one softened region.

A method is for treating at least one part of a metal component that is at least partly produced by additive manufacturing. The method comprises the steps of heating the at least one part of the metal component to form at least one softened region, and applying a mechanical load to the at least one softened region to plastically deform the metal in the at least one softened region.

The present disclosure relates to powder-bed-based additive manufacturing methods, in which a component is produced layer by layer in a build-up process by local melting of particles in a powder bed. For example, a powder-bed-based additive manufacturing method may include: producing a component layer by layer in a build-up process by local melting of particles in a powder bed; interrupting the build-up process after a layer has been completed; post-treating a surface of the component by laser peening, wherein compressive stresses are generated at the surface of the layer that has been completed; and restarting the build-up process for producing a next layer. An installation for the powder-bed-based additive manufacturing method may include an application apparatus for an ablation medium.

The present disclosure relates to powder-bed-based additive manufacturing methods, in which a component is produced layer by layer in a build-up process by local melting of particles in a powder bed. For example, a powder-bed-based additive manufacturing method may include: producing a component layer by layer in a build-up process by local melting of particles in a powder bed; interrupting the build-up process after a layer has been completed; post-treating a surface of the component by laser peening, wherein compressive stresses are generated at the surface of the layer that has been completed; and restarting the build-up process for producing a next layer. An installation for the powder-bed-based additive manufacturing method may include an application apparatus for an ablation medium.

A method for fixing an attachment object to a side of a patterned object comprising a plurality of protrusions with tip portions, by pressure-sintering. A deformation uptake means made of a material having a lower yield strength and/or a lower hardness than the tip portions, is arranged between the patterned object and at least a fraction of the tip portions.

A method for attaching a contact element to the end of an electrical conductor is specified, by which electrically conductive material which is present at the end of the conductor and is fixedly connected to the conductor is shaped to form a contact element with a variable shape. The end of the bare conductor is firstly moved into an at least approximately vertical position. Particles of an electrically conductive material are then applied at such a high speed to the upwardly projecting front-side end of the conductor in the axial direction thereof that the material of the conductor connects to the electrically conductive material to form a compact structure which is connected to the material of the conductor in a mechanically fixed and electrically conductive fashion. In order to form a metal body without interrupting the method, further particles of the electrically conductive material are subsequently applied to the compact structure, and the metal body is finally shaped mechanically to form the contact element.