Systems and methods are provided for laser heating in a fluid environment (30). Such a system may include a laser generator (12) and a laser output sub (16) separate from one another via an optical fiber (18). The laser generator may generate a heating laser pulse over the optical fiber. The laser output sub may emit the heating laser pulse to heat a substrate (22) in the fluid environment (30). To enable the heating laser pulse to pass between the laser output sub (16) and the substrate (22), the laser output sub may dispense a laser-transmissive optical grease or a laser-transmissive magnetic fluid, or may generate a vacuum cavitation bubble in the fluid between the laser output sub (16) and the substrate (22).

A method of manufacturing a shaft of a surgical instrument including forming a proximal segment of the shaft to include one or more features for operably engaging the shaft to a first component of the surgical instrument, forming a distal segment of the shaft to include one or more features for operably engaging the shaft to a second component of the surgical instrument and forming an intermediate segment of the shaft. The proximal segment is welded to a proximal end of the intermediate segment; and the distal segment is welded to a distal end of the intermediate segment. The proximal and distal segments are welded to the intermediate segment such that the one or more features thereof are aligned in a pre-determined orientation relative to one another.

A number of variations may include a product that may include a substrate that may include an aluminum-nickel alloy and at least one surface and a coating that may include a metallic material deposited over the at least one surface via laser cladding.

A number of variations may include a product that may include a substrate that may include an aluminum-nickel alloy and at least one surface and a coating that may include a metallic material deposited over the at least one surface via laser cladding.

A rotating machine component, particularly a gas turbine combustion component, having at least one part built from a porous material with a plurality of pores, wherein at least a subset of the plurality of pores is at least partly filled with a gas with a composition different from air and/or with a powder, wherein the porous material is a laser sintered or laser melted material in which void local regions form the plurality of pores. The component counter-acts vibrations. A rotating machine or gas turbine engine may have such a component.

A processing system for forming a cross-section of an object. The processing system comprises a focused ion beam system for forming the cross-section from a pre-prepared surface region of the object and a laser and a light optical system for forming the pre-prepared surface region by laser ablation of a processing region of the object with a first and a second laser beam. The light optical system is configured to direct the first and the second laser beams onto common impingement locations of a common scanning line in the processing region for scanning the first laser beam and for scanning the second laser beam. For each of the impingement locations, an angle between a first incidence direction along an axis of the first laser beam and a second incidence direction along an axis of the second laser beam is greater than 10 degrees, measured in a stationary coordinate system.

An additive manufacturing system including a two-dimensional energy patterning system for imaging a powder bed is disclosed. Improved structure formation, part creation and manipulation, use of multiple additive manufacturing systems, and high throughput manufacturing methods suitable for automated or semi-automated factories are also disclosed.

To provide a protection barrier, which includes an inlet from which laser light emitted from a laser device enters; an outlet from which the laser light is output towards an irradiation target; and a unit configured to prevent a leakage, where the unit is configured to reduce an intensity of the laser light leaked from the protection barrier, wherein the protection barrier is configured to surround a light path of the laser light emitted from the laser device.

A laser welding system is provided including a laser source configured to produce at least one laser beam, beam modifying means configured to split the at least one laser beam, directing means, and controlling means configured to control the directing means. The controlling is configured to control the directing means to cause the split laser beam to form at least two heat source points on the target, the heat source points maintaining a linear profile, and move the at least two heat source points in a travel direction along the target, wherein the linear profile forms a predetermined, oblique angle relative to the travel direction.

Three-dimensional manufacturing method and apparatus which easily adjust individually a heating amount per unit area for each of solidified and unsolidified regions is provided. Light source and scanning unit heat with a laser beam a layer formed by a layer forming unit. In a layer forming step, a controlling unit causes the layer forming unit to form a layer of material powder. In a laser heating step, the controlling unit controls the light source and the scanning unit to alternately heat with the laser beam the solidified region obtained by fusing and solidifying the layer and the unsolidified region adjacent to the solidified region, thereby integrally fusing and solidifying the solidified region and the unsolidified region.