Abstract: A printer is configured with an actuator to rotate a platen about an axis perpendicular to the surface of the platen and an encoder that generates angular data corresponding to the rotation of the platen. A controller operates the actuator to rotate the platen while monitoring the angular data generated by the encoder to ensure accurate rotation of the platen after each layer of an object is printed. By forming successive layers at different angles to one another, the structural integrity of the object is improved over previously known printed objects and the effects of defective ejectors are mitigated without having to substitute operational ejectors for the defective ejectors.

Abstract: A system (100) and method for monitoring a recoating mechanism (415A, 415B) in an additive manufacturing environment is provided. Various embodiments involve the use of a control computer (102a-102d) to receive data based on a thermal image of a recoating mechanism (415A, 415B) from an imaging device (436) configured to capture thermal image. The control computer (102a-102d) further determines a value of a property of the thermal image, wherein the property is related to an amount of powder in the recoating mechanism. The control computer (102a-102d) further determines at least one of if the value indicates an error related to the amount of powder in the recoating mechanism (415A, 415B), and an action to take with respect to the recoating mechanism (415A, 415B) that is based on the value.

Abstract: Disclosed is a hydraulic system for a molding system, the molding system having a clamp actuator and an injection actuator, the hydraulic system comprising a clamp accumulator for storing hydraulic fluid for use in actuating the clamp actuator; an injection accumulator for storing hydraulic fluid for use in actuating the injection actuator; a pump for conveying hydraulic fluid to the clamp accumulator and the injection accumulator; and a selector valve for selectively fluidly connecting the pump to one of the clamp accumulator and the injection accumulator.

Abstract: Disclosed are a new silicone cold-extrusion lamp belt and its manufacturing method. The manufacturing method includes the following steps. S10: Select a PCB and use the PCB as a substrate. S20: Set LED lamp bead spot-welding units arranged in an array formed on the substrate to obtain a target board. S30: Extrude a slurry which is formed by a food-grade silicone and coat the slurry on an outer surface of the target board to form a lamp skin. S40: Cut the target board into at least one lamp belt substrate. S50: Heat and bake the lamp belt substrate to obtain a lamp belt. This disclosure has the advantages of feasible design, low manufacturing cost, high resistance on cracking, wearing, yellowing, high/low temperature, good fire resistance, environmental friendly and harmless to human safety, high transparency, high light emitting efficiency of the lamp, and applicable for indoor/outdoor lamp belts.

Abstract: A method of making a glass mat includes providing an assembly of glass fibers, applying a binder composition to the assembly of glass fibers, wherein the binder includes an organic resin, and curing the binder composition while dimensionally constraining the assembly of glass fibers. Dimensional constraining includes directly contacting a first major surface and a second major surface of the assembly of glass fibers between two substantially parallel surfaces. Further provided is a glass mat that includes an assembly of glass fibers, wherein the assembly of glass fibers are substantially randomly oriented with a tensile anisotropy of less than about 6 in any two directions. The glass mat has a decreased surface roughness and a decreased caliper compared to an equivalent glass mat having an assembly of naturally packed glass fibers with an equivalent fiber diameter size.

Abstract: An injection-molding method for manufacturing a sleeve (1) comprising a cylindroconical body comprising at least one deformable bellows portion (2) arranged in line with a base (3), by means of tooling comprising a mold (8) formed of at least two portions (81, 82) defining a mold cavity and a core that can be inserted into the mold cavity, and comprising a first cylindroconical portion (11) provided externally with a helical thread that is complementary to a helical thread of the mold (8) and a second portion (15) that is complementary to a recessed portion of the mold (8), said method comprises a step of filling the mold spaces left free between the core and the inside of the mold cavity (9), a step of opening the mold (8) during which, or at the end of which, the second portion (15) of the core is moved axially in a direction parallel to the winding axis (XX?) of the threads of the helical thread going away from the first portion (11) of the core, and a step of driving relative turning movement of the sleev

Abstract: A method of producing a molded product includes preparing a mold for insert molding, setting an insert member, forming a cavity in a condition in which the insert member is disposed by closing the mold and injecting a molten resin into the cavity. The mold for insert molding includes first and second molds, and the first mold has a guide surface provided at a part corresponding to a trunk portion of the molded product within a wall surface defining a groove portion which constitutes a part of the cavity. The insert member is set at the groove portion of the first mold while the projecting portion being guided by the guide surface.

Abstract: A method for manufacturing a hyper-elastic three-dimensional (3D) sandwich panel is disclosed, the method comprising printing a plurality of layers, the plurality of layers comprising a central composite core and upper and lower sandwich face layers; and regulating a temperature of each printed layer to match melting point temperature of a consecutive layer being subsequently printed on top of a previously printed layer, wherein the plurality of layers are printed one layer at a time. The multi-layered and multi-material hyper-elastic three-dimensional (3D) sandwich panel is a central composite rubber core stacked between upper and lower sandwich face layers made of reinforced glass-fiber, wherein the central composite rubber core further comprises a core lower face layer, a central core layer and a core upper face layer.

Abstract: A method for wrapping a stream of material or stream of layers of materials includes feeding a stream of material or stream of layers of materials into a die containing a wrapping deflector which acts to wrap the stream into a tubular or profile shape.

Abstract: An additive manufacturing method for fabricating a component having a surface substantially free of imperfections may include providing a mold having a configuration corresponding to the component, and depositing a material on at least one surface of the mold to fabricate the component having the surface substantially free of imperfections.

Abstract: A thin-form mouthguard can be formed from a U-shape planar sheet. The sheet can be made of expanded-polytetrafluoroethylene and have a thickness between 0.02 inches and 0.25 inches. The sheet can also include instructions for modification of the mouthguard printed thereon. A method for preparing a mouthguard is also provided.

Abstract: Methods of creating and heat-treating 3D-printed objects may involve creating an object utilizing a 3D printer. The object may be moved from the 3D printer to a heat-treatment apparatus. The object may be exposed to an elevated temperature and pressure may be applied to the object utilizing a pressure-transmission medium of the heat-treatment apparatus. The 3D printer and heat-treatment apparatus may in a unified process flow volume.

Abstract: A unitary deflection member and a method for making a unitary deflection member is disclosed. The method can include the steps of: providing an additive manufacturing making apparatus; providing a material for the unitary deflection member, the material being compatible for use with the additive manufacturing making apparatus; generating a 3-D digital image of objects in a repeat element of the unitary deflection member, the objects including at least a reinforcing member and at least one protuberance of the unitary deflection member; assembling the objects into a digitized file including the at least one protuberance being on said reinforcing member; importing the digitized file to make numerical control file; and depositing the material using the additive manufacturing making apparatus to make the unitary deflection member.

Abstract: A method of producing a molded product includes preparing a mold for insert molding, setting an insert member, forming a cavity in a condition in which the insert member is disposed by closing the mold and injecting a molten resin into the cavity. The mold for insert molding includes first and second molds, and the first mold has a guide surface provided at a part corresponding to a trunk portion of the molded product within a wall surface defining a groove portion which constitutes a part of the cavity. The insert member is set at the groove portion of the first mold while the projecting portion being guided by the guide surface.

Abstract: A method for inspection of additive manufactured parts and monitoring operational performance of an additive manufacturing apparatus is provided. The method includes a step of obtaining, in real-time during an additively manufactured build process, a backscatter x-ray scan of an area of a build platform. The build platform is configured for supporting at least one part during the build process. An evaluating step evaluates, by a processor, the backscatter x-ray scan. A determining step determines, based on the evaluating, whether an operational flaw with the additive manufacturing apparatus has occurred or a defect in the at least one part has occurred. A backscatter x-ray system has an emitter that emits x-rays and a detector that receives backscattered x-rays. The emitter and detector are located on a movable support located above the build platform, and the movable support raises and lowers the emitter and detector with respect to the build platform.

Abstract: A carbon paste that includes at least a carbon filler, and a thermosetting resin including a phenoxy resin. The phenoxy ratio X in the thermosetting resin is within a range of 20 Wt %?X?70 Wt %, and the carbon filler content ratio Y with respect to a total of the carbon filler and the thermosetting resin is within a range of 30 Wt %?Y?70 Wt %.

Abstract: The present invention relates to a method and a device for producing three-dimensional models, wherein binding/bonding material is applied in layers to a building platform and media are selectively applied which delay or completely prevent the binding of the applied material.

Abstract: A method and/or system for forming a micro-truss structure in an essentially arbitrary shape. A mold that has a transparent portion, and having an interior volume in the desired shape, is filled with photomonomer resin. The material for the transparent portion of the mold is selected to be a material that is index-matched to the photomonomer resin. The filled mold, placed into a bath of transparent fluid index-matched to the transparent portion of the mold, and illuminated, from outside the fluid, through a photomask, with collimated light. The collimated light travels through the photomask forming beams of light that enter the transparent fluid, propagate into the mold, and form a micro-truss structure in the shape of the interior volume of the mold. The micro-truss structure may then be removed from the mold, or part or all of the mold may be left adhered to the micro-truss structure, forming covering face sheets.

Abstract: A high-moisture-permeability, microporous plastic film randomly having a lot of recesses having different opening diameters and depths, with clefts formed in the recesses, is produced by pressing a first pattern roll randomly having a lot of high-hardness, fine particles having sharp edges on a roll body surface to a flat-surface metal roll, to produce an anvil roll randomly having a lot of recesses on a metal roll surface; arranging a second pattern roll randomly having a lot of high-hardness, fine particles having sharp edges on a roll body surface oppositely to the anvil roll; and passing a plastic film through a gap between the second pattern roll and the anvil roll.

Abstract: An imprint apparatus that forms a pattern on a substrate by using a mold, the apparatus comprises a supply unit configured to supply an imprint material to the substrate; a contact unit configured to contact the imprint material that has been supplied to the substrate with a mold; a substrate stage configured to move the substrate; a gas supply unit that is provided between the supply unit and the contact unit, and supply gas toward the substrate; and a flow volume adjustment unit configured to adjust a flow volume of the gas that is supplied from the gas supply unit, while the substrate stage moves the substrate from a supply position at which the imprint material is supplied by the supply unit to a contact position at which the imprint material is contacted with the mold by the contact unit.