Abstract: Systems and methods for manufacturing eyelash prostheses are described.

Abstract: In an embodiment, a system includes a three-dimensional (3D) printer, a neutral feedstock, a p-doped feedstock, an n-doped feedstock, and a laser. The 3D printer includes a platen and an enclosure. The platen includes an inert metal. The enclosure includes an inert atmosphere. The neutral feedstock is configured to be deposited onto the platen. The neutral feedstock includes a halogenated solution and a nanoparticle having a negative electron affinity. The p-doped feedstock is configured to be deposited onto the platen. The p-doped feedstock includes a boronated compound introduced to the neutral feedstock. The n-doped feedstock is configured to be deposited onto the platen. The n-doped feedstock includes a phosphorous compound introduced to the neutral feedstock. The laser is configured to induce the nanoparticle to emit solvated electrons into the halogenated solution to form, by reduction, layers of a ceramic comprising a neutral layer, a p-doped layer, and an n-doped layer.

Abstract: A method for printing uses at least one bio-ink. The method also uses at least one laser print head to deposit at least one droplet of at least one bio-ink onto a depositing surface of a receiving substrate. The printing method uses at least one nozzle print head to deposit at least one droplet of at least one bio-ink onto a depositing surface of the same receiving substrate as the laser print head.

Abstract: A method of forming a three-dimensional object is carried out by: (a) providing a cyanate ester dual cure resin; (b) forming a three-dimensional intermediate from said resin, where said intermediate has the shape of, or a shape to be imparted to, said three-dimensional object, and where said resin is solidified by exposure to light; (c) optionally washing the three-dimensional intermediate, and then (d) heating and/or microwave irradiating said three-dimensional intermediate sufficiently to further cure said resin and form said three-dimensional object. Compositions useful for carrying out the method, and products made from the method, are also described.

Abstract: A caul plate assembly for applying compaction pressure to a composite structure includes caul plates arranged side-by-side on the surface of the composite structure. The caul plates include overlapping edges of compliant material which form a continuous face applying even pressure and shear across gaps between the caul plates.

Abstract: An apparatus for continuously making a spunbond web of filaments comprises a spinneret, a cooling chamber into which process air for can be introduced for the purpose of cooling the filaments, a monomer suction device between a spinneret and cooling chamber, a stretcher and a deposition device for depositing the filaments of the spunbond web. The cooling chamber is divided into two cooling compartments, and process air can be suctioned out from a first upper cooling compartment at a volumetric flow rate (VM) to a monomer suction device. Process air exits from the first upper cooling compartment at a volumetric flow rate (V1) into a second lower cooling compartment and from the first upper cooling compartment at a volumetric flow rate (V1) into a second lower cooling compartment. A ratio (VM/V1) is 0.1 to 0.35.

Abstract: In order to attain an object to achieve a graphite sheet processed product which is made of high quality graphite and which has a smooth cut surface even after being subjected to a cut process, a graphite sheet processed product of the present invention has a thickness of not less than 10 nm and not more than 20 ?m, has a cross-sectional area 90% or more of which is occupied by graphite layers each extending continuously or discontinuously in a horizontal direction, the cross-sectional area being observed with use of a scanning electron microscope (SEM), includes therein graphite crystal having an average crystal grain size of not less than 0.35 ?m and not more than 25 ?m, and has, on a cut surface thereof, a burr having a size that is not more than 15% of a line width thereof, the line width being less than 400 ?m.

Abstract: A mold clamp control method for an injection molding machine having a toggle-type mold clamping mechanism. The mold clamp control method includes: a low-pressure mold clamping step that performs position hold control by which a crosshead is held in a set holding position in a state where a toggle link has been bent, when injection-filling is started; and a compression-press step that performs speed and position control by which the crosshead is advanced toward a set advancement position from the set holding position in a state where a first output upper limit value has been provided to a driving section. Advancement of the crosshead is continued in at least part of the compression-press step in a state where a generated output of the driving section is maintained at the first output upper limit value.

Abstract: Systems and methods for imprinting formable material on a substrate with a template. Illuminate the formable material with a gelling radiation distribution pattern. The gelling radiation distribution pattern has a gelling dosage that that varies from a minimum gelling dosage at each of a plurality of corners of a boundary edge to a peak gelling dosage at a center of each of the boundary edges.

Abstract: In an embodiment, a system includes a three-dimensional (3D) printer, a feedstock, and a laser. The three-dimensional printer includes a platen including an inert metal, and an enclosure including an inert atmosphere. The feedstock is configured to be deposited onto the platen. The feedstock includes a halogenated solution and a nanoparticle having negative electron affinity. The laser is configured to induce the nanoparticle to emit solvated electrons into the halogenated solution to form, by reduction, a ceramic and a diatomic halogen.

Abstract: A facility for the production of containers from blanks, which facility includes: a forming unit equipped with a rotating carrousel driven by a motor; a unit for heating blanks, equipped with infrared emitters and a power feed for each emitter; a control unit having in the memory a nominal speed setpoint ?N of the rotation of the carrousel and a nominal electrical power setpoint PN. The control unit is programmed for: controlling the rotation of the carrousel according to the nominal speed setpoint ?N.

Abstract: This invention relates to a process of making a fiber-reinforced composite. Glass fibers may be provided. These glass fibers may be treated with a sizing composition that has a coupling-activator compound with the formula: S—X-(A)n, where S represents a silicon-containing coupling moiety capable of bonding to the surface of glass fibers, X represents a linking moiety, and (A)n, represents one or more polymerization activator moieties. The treated glass fibers may be combined with a resin to make a fiber-resin mixture. The resin may have a monomer, a catalyst, and an activator compound capable of initiating a polymerization of the monomer. The monomer may be a lactam or lactone having 3-12 carbon atoms in the main ring. The fiber-resin mixture may then be cured so that the monomer polymerizes to form a thermoplastic polymer matrix of the fiber-reinforced composite. The thermoplastic polymer matrix may be formed by in situ polymerization initiated from both the surface of the glass fibers and the resin.

Abstract: A method for producing a part includes the steps of: positioning an insert in a mold via a gripping element, able to be actuated between an inactive configuration and an active configuration, of a gripping device comprising a shaping wall; shaping the insert in a reinforcing element against a surface; during positioning, maintaining a separation between the surface and the insert, and moving the shaping wall to apply the insert against the surface; and during the shaping, applying the shaping wall and the gripping element against the insert and the surface, the element being actuated in its inactive configuration before the application of the shaping wall.

Abstract: Techniques are described for controlling widths of nanofiber sheets drawn from a nanofiber forest. Nanofiber sheet width can be controlled by dividing or sectioning the nanofiber sheet in its as-drawn state into sub-sheets as the sheet is being drawn. A width of a sub-sheet can be controlled or selected so as to contain regions of uniform nanofiber density within a sub-sheet (thereby improving nanofiber yarn consistency) or to isolate an inhomogeneity (whether a discontinuity is the sheet (e.g., a tear) or a variation in density) within a sub-sheet. Techniques for dividing a nanofiber sheet into sub-sheets includes mechanical, corona, and electrical arc techniques.

Abstract: Provided are a method for producing an FRP precursor and a device for producing an FRP precursor, wherein the method and the device have a good productivity, and under a normal pressure, enable filling of a resin into a bulk gap of an aggregate as well as prevent the resin from spouting out from an edge portion thereof. The method for producing the FRP precursor is to produce the FRP precursor by melt-adhering each of a pair of thermosetting resin films 54 to each of both surfaces 40a and 40b of an aggregate 40 that is in a form of a sheet, the method comprising: an aggregate's surface heating process to heat aggregate's both surfaces, i.e.

Abstract: The invention described herein provides a method and material for creating tools surfaces from a granulated material comprised of a particulate and binding material in compositions and ratios described below. The granulated material may be formed using a number of methods and provides for the efficient repair of worn or damaged areas. Additionally, the granulated material may be used by placing it on the surface of a tooling encasement, or may be used by itself without any further structural support. The granulated material may also be used for both forming and trimming/machining of the part to desired tolerances.

Abstract: In an additive 3D printing method for production of shaped articles from silicone elastomers, an elastomeric shaped body is built up step by step, by repeatedly precisely positioning portions of the crosslinkable silicone material and crosslinking by means of electromagnetic radiation. Charges that occur on the surface of the print material or on the article are neutralized by means of an ionization system.

Abstract: Provided are a production method of a mold having a recessed pedestal pattern for preventing a liquid flow and a manufacturing method of a pattern sheet. A production method of a mold having a recessed pedestal pattern, has: a step of preparing an insert mold having a protruding needle pattern group; a step of preparing a mold having a first mold provided with a protruding pedestal shape and a second mold; a holding step of holding the protruding pedestal shape of the first mold and the protruding needle pattern group of the insert mold in an overlapping manner; a clamping step of performing clamping with the first mold and the second mold to form a cavity; and an injection step of filling the cavity with a resin.

Abstract: A scanning approach used in the feedback procedure is able to distinguish between different materials, for example, based on spectral properties (e.g., color) of reflectance from a partially fabricated object. Because material layers can be quite thin, and in general the materials are not completely opaque, properties of subsurface layers can greatly affect the reflectance of a thin layer of one material over a thicker section of another material. Detection of locations of thin layers after a material change takes into account the reflectance characteristics of the object before the thin layer was deposited.

Abstract: An example system for processing composite material includes a cure tool, a source of pressurized gas, and a vacuum bag forming an enclosed volume between the cure tool and the vacuum bag. The system further includes composite material positioned on the cure tool within the enclosed volume. The source of pressurized gas is configured to inflate the vacuum bag, thereby moving a portion of the vacuum bag away from the cure tool and the composite material. An example method includes placing composite material onto a cure tool, placing a vacuum bag over the composite material and the cure tool to form an enclosed volume between the cure tool and the vacuum bag, processing the composite material while the composite material is within the enclosed volume, and inflating the vacuum bag to move a portion of the vacuum bag away from the cure tool and the composite material.