Methods, systems, and apparatus, for hybrid additive manufacturing of parts. In one aspect, a method includes providing a workpiece and manufacturing multiple additive layers on a surface of the workpiece. Manufacturing each of the multiple additive layers includes forming one or more formed layers on a surface of the workpiece by depositing a quantity of powder material on a growth surface, the growth surface inclusive of at least one of a first surface of the workpiece and a second surface of a previously formed layer, and applying a first amount of energy to the quantity of powder material to fuse the particles of the powder material into a formed layer fused to the growth surface, where the formed layer includes a formed surface, and further applying a secondary process to a particular area of the formed surface of the one or more formed layers on the workpiece.

Embodiments of a golf club head with a textured strikeface and methods to form said club head through laser shock treatment are generally described herein. The golf club head can comprise a body and a strikeface. The strikeface has a textured front surface, with an array of indentions. Each indention can have a footprint area of between 0.01 μm.sup.2 (1×10.sup.−8 mm.sup.2) to 250,000 μm.sup.2 (0.25 mm.sup.2). The textured front surface can affect the spin imparted to a golf ball upon impact. Other embodiments may be described and claimed.

Embodiments of a golf club head with a textured strikeface and methods to form said club head through laser shock treatment are generally described herein. The golf club head can comprise a body and a strikeface. The strikeface has a textured front surface, with an array of indentions. Each indention can have a footprint area of between 0.01 μm.sup.2 (1×10.sup.−8 mm.sup.2) to 250,000 μm.sup.2 (0.25 mm.sup.2). The textured front surface can affect the spin imparted to a golf ball upon impact. Other embodiments may be described and claimed.

Laser shock peening is applied to a harvester component for an agricultural wear application that for example may be any of the following components: a knifeback, a knifehead, a knifeback connecting strap, a straw chopper, a sickle section, stalk chopper, a bedknife, a sod cutter knife, a net wrap knife or a combine concave component. The laser shock peening may be selectively applied. For example, laser shock peening can be applied in regions of drive ends of harvester components, and/or in regions proximate fastener holes of such harvester components.

Laser shock peening is applied to a harvester component for an agricultural wear application that for example may be any of the following components: a knifeback, a knifehead, a knifeback connecting strap, a straw chopper, a sickle section, stalk chopper, a bedknife, a sod cutter knife, a net wrap knife or a combine concave component. The laser shock peening may be selectively applied. For example, laser shock peening can be applied in regions of drive ends of harvester components, and/or in regions proximate fastener holes of such harvester components.

A method for manufacturing a cutting tool includes: the cutting tool comprising a tool body made of a sintered alloy, a hard coating which is disposed on an outer surface of the tool body and has at least a layer formed of any of a carbide, a nitride, and a carbonitride, or a composite compound thereof, and a cutting edge which is formed at a ridge portion of the tool body and includes a portion of the hard coating located at the ridge portion, a laser peening step of directly irradiating the hard coating with a pulsed laser having a pulse width of 100 ps or less to apply compressive residual stress to the hard coating and a surface region of the tool body.

A method for separating a thin glass, in which method the thin glass is progressively heated along a path which forms a parting line, wherein the heating of the glass is realized by way of the energy of at least one energy source within an area of action of the energy source on the thin glass, and, by way of a temperature gradient of the glass heated by way of the at least one energy source in relation to the surrounding glass, a mechanical stress is generated in the glass, by way of which mechanical stress, a crack propagates, following the mechanical stress, along the parting line.

A method of cutting thin flexible glass substrates utilizing a feedback loop configured to monitor a position of a crack tip relative to an irradiated zone on the glass substrate. A process controller including the feedback loop controls at least one of a laser beam power, a laser speed or a cooling fluid speed based on the distance between the crack tip and the irradiated zone.

A method of cutting thin flexible glass substrates utilizing a feedback loop configured to monitor a position of a crack tip relative to an irradiated zone on the glass substrate. A process controller including the feedback loop controls at least one of a laser beam power, a laser speed or a cooling fluid speed based on the distance between the crack tip and the irradiated zone.

A tool bit includes a drive portion configured to be engaged by a tool, the drive portion including a first maximum outer dimension, a shank extending from the drive portion and including a reduced outer diameter, and a tip coupled to an end of the shank opposite from the drive portion. The tip includes a compressive residual stress layer formed by blasting to increase a wear resistance of the tip relative to the shank. The tip additionally includes a second maximum outer dimension. The reduced outer diameter of the shank is smaller than the first maximum outer dimension of the drive portion and the second maximum outer dimension of the tip.