CPC Class B33Y

A branch is produced by means of an additive 3D production process for producing a metal part, which comprises at least two parts, namely a support section and a functional section. The metal part is a single-pieced part, in which the support section and the functional section are seamlessly interconnected by means of corresponding connecting webs. After the material is applied, the connecting webs are removed.

A filter element for the filtration of fluids can be manufactured from powdered metal using a laser manufacturing process. The powdered metal is deposited in a layer on fabrication platform and a laser beam is directed toward the layer of material so that the powdered metal granules fuse together to form a first component of the filter element. Successive layers of powdered metal can be deposited over the first component and also fused with the laser beam to form additional components. During the manufacturing process, the power or scan rate of the laser beam many be changed so that the formed layers of the filter element may have different porosity characteristics, for example, with certain portions being fluid permeable and other portions being fluid impermeable.

A system and method for modifying features in designs of objects to make them physically capable of being manufactured using additive manufacturing techniques and machines is provided, carrying out the following steps: Determine if one or more surfaces of the object have a surface angle below a threshold angle; designate one or more edges including a first edge, the first edge being between a first surface of the one or more surfaces and a second surface of the one or more surfaces, wherein the first surface has a surface angle below the threshold angle and the second surface has a surface angle equal to or above the threshold angle; and generate one or more additional surfaces along the one or more edges in the design file.

A manifold structure has at least one flow passage and a center manifold section that has at least one machined cavity. The manifold structure includes a plurality of ultrasonically additively manufactured (UAM) finstock layers arranged in the flow passage. After the finstock is formed by UAM, the finstock is permanently joined to the center manifold section via a brazing or welding process. Using UAM and a permanent joining process enables joining of the UAM finstock having enhanced thermal features to a vacuum brazement structure. UAM enables the finstock to be formed of dissimilar metal materials or multi-material laminate materials. UAM also enables bond joints of the finstock to be arranged at angles greater than ten degrees relative to a horizontal axis by using the same aluminum material in the UAM process and in the vacuum brazing process.

Disclosed herein is a device (100) for making an object. The device (100) comprises a vessel (44) for receiving a radiation hardenable material (42). The device (100) comprises a fabrication platform assembly (7) comprising a fabrication platform (8) and having a first mode in which an orientation of the fabrication platform (8) is adjustable and a second mode in which the orientation of the fabrication platform (8) is fixed, and configured for positioning at the vessel (44) in the second mode to form a layer of the radiation hardenable material when so received between the fabrication platform (8) and a wall (46) of the vessel (44). The device (100) comprises a radiation source (48) arranged to illuminate the layer of radiation hardenable material when so formed to form one of a plurality of layers of the object. The device (100) comprises a guide (28) configured to receive the fabrication platform assembly (7) in the first mode and orientate the fabrication platform (8) when so received with respect to the guide (28). Also disclosed herein is a method for making an object.

A method comprises receiving object model data in an original coordinate system to print within a predefined usable build volume of a three dimensional printer. The method comprises receiving at least one compensation factor for the object model data to compensate for any shrinking of an object. The method comprises scaling the object model data by the at least one compensation factor to provide printable object model data. The scaling is performed with reference to an origin at a centre of the usable build volume.