Abstract: A method of preparing an inorganic binder for medical use according to an embodiment of the present disclosure includes preparing a starting material using a-TCP powder and phosphate powder each of which has a predetermined particle size, producing a paste having a predetermined viscosity that is suitable for formation of a molded article having a predetermined shape by homogeneously mixing the starting material, adding water or saline to the homogeneously mixed starting material, and kneading the resulting mixture, subjecting the molded article to hydration reaction, and washing and drying the molded article having undergone the hydration reaction to obtain an inorganic binder containing OCP and HA crystal phases.

Abstract: The invention relates to a method for connecting a connection piece to a U-shaped ring anchor for a head module for rail vehicles, the head module consisting predominantly of fiber-reinforced plastic material and having an outer shell and the ring anchor consisting of fiber-reinforced plastic material and being arranged in the roof region of the outer shell as a stiffening means. According to the method, connecting elements are fed through the dry or matrix-material-impregnated, unconsolidated fiber reinforcement structure of the ring anchor.

Abstract: The disclosed and claimed concept provides for an overmold that is applied to substantially all of the exposed portions of a wood handle for a tool.

Abstract: A method of manufacturing an interface for a body part using an additive manufacturing process is described. The method obtaining a digital model of the body part and modifying the digital model to create a plurality of compression areas. The compression areas are spaced circumferentially around a long axis of the digital model to create a compression pattern. The compression pattern is sized and dimensioned to compress soft tissue of the body part against the skeletal structure such that motion of the skeletal structure towards a wall of the interface is reduced.

Abstract: A polymer composition capable of being additively manufactured includes a polymer matrix and a magnetically receptive additive. The polymer composition may be additively manufactured or extruded to form a tool which may be used to form a composite part.

Abstract: A method for manufacturing a polymer-based fibrous scaffold is disclosed. The method includes the following step: providing an electrospinning device comprising a collector; and injecting a polymer solution into the electrospinning device to produce a single jet fiber, wherein the single jet fiber is piled on the collector to form a fibrous scaffold.

Abstract: The present invention provides an imprinting method, which includes the steps of: adding a soluble material to a master mold; solidifying the soluble material to form a soluble mold having a mold pattern; adhering a taking device to the soluble mold to separate the soluble mold from the master mold; placing the soluble mold on a polymer layer of a workpiece for imprint; applying a high temperature and a pressure to the soluble mold to allow the polymer layer having an imprint pattern corresponding to the mold pattern and being solidified, and to remove the taking device from the soluble mold; and providing a solvent to dissolve the soluble mold to obtain an imprint workpiece having the imprint pattern.

Abstract: Embodiments herein relate to hollow profiles and methods of preparing the same for joining operations. A method herein can include placing a dam within a channel defined by the hollow profile, fitting a die block over an end of the channel, and injecting a flowable composition through an injection port into the channel. Another method can include defining a volume within a first member using at least one flow control device, filling the defined volume with a flowable polymeric composition, allowing the flowable polymeric composition to solidify to form a solid portion in the first member, and mechanically modifying the solid portion to define a joining surface suitable for joining to the second member. Other embodiments are also included herein.

Abstract: The invention relates to a method for manufacturing a three-dimensional component 14 by means of an additive construction method in which the component 14 is constructed by solidifying construction material 9 that can be solidified using radiation 18, especially a selective laser melting method or a selective laser sintering method, in which the component 14 is produced by successively solidifying construction material 9 that can be solidified using the impact of radiation 18 by melting or sintering, comprising the following features: providing an additive construction apparatus 1, especially an SLM apparatus or an SLS apparatus, comprising a process chamber 3, a construction platform 7 for carrying the construction material 9, and a radiation source arranged above the construction platform 7 for generating a point-type or linear energy input for creating a melting or sintering section in the construction material 9, providing a sensor apparatus 31 for selective detection of created melting or sintering secti

Abstract: A method of post manufacture processing of 3D printed parts involves a step of forming at least one treatment aperture through an exterior shell of a 3D printed part to provide access to a lattice of multiple layers of extruded thermo-plastic filaments within a hollow cavity of the part. The method involves a step of inserting a stabilizing substance that flows before it is set and then hardens when set through the at least one treatment aperture into the hollow cavity of the part. The method involves a step of coating the lattice with the stabilizing substance to fill spaces between the multiple layers and between individual thermo-plastic filaments, such that, when set, the stabilizing substance fixes the multiple layers of extruded thermo-plastic filaments of the lattice in position. The method reinforces and stabilizes the internal lattice structure of the part, without significantly adding material or increasing manufacturing cost.

Abstract: A process for manufacturing a multi-layered sole directly on the upper, of the type that employs the technique known as “direct injection on the upper”, by which soles are made of a plastic material and consist of a plurality of layers with different colour, density, softness and physical-mechanical properties. Said layers form at least an external sole, called “outsole”, an internal sole, called “insole” that adheres and extends only partially or totally on the surface of the upper, and an intermediate sole, called “midsole”, that is intended to hold the other two above-said soles. Said process provides for the use of a single mould which is brought, when suitably equipped, in a well-defined sequence, in front of at least three distinct injectors (I1, I2, I3) in order to obtain, also in sequence, by at least a first moulding operation (P1) the lower portion of the sole, i.e. the “outsole”, by at least a second moulding operation (P2) the upper part of the sole, i.e.

Abstract: An additive manufacturing system, and associated methods, comprise an image projection system comprising a plurality of image projectors that project a composite image onto a build area within a resin pool. The composite image comprises a plurality of sub-images arranged in an array. The properties of each sub-image and the alignment of the position of each sub image within the composite image can be adjusted using a set of filters comprising: 1) an irradiance mask that normalizes irradiance, 2) a gamma adjustment mask that adjusts sub-image energy based on a reactivity of the resin, and 3) a warp correction filter that provides geometric correction.

Abstract: Systems and methods for controlling additive manufacturing processes are disclosed. The systems can include multiple laser directors, soot-removal devices, magnetic chucks, replenishable powder distribution blades, automated powder level detectors, and/or overall process automation techniques.

Abstract: Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

Abstract: Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

Abstract: Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

Abstract: A template (100) for controlling application of material (620) around a protuberance (610) is disclosed. The protuberance (610) extends from a workpiece (600) and has a base (612). The template (100) comprises a first portion (110) and a second portion (130), removably attached to the first portion (110). The first portion (110) comprises a first inner peripheral edge (111) that at least partially defines a positioning opening (115) and that is geometrically complementary to at least a portion of the base (612) of the protuberance (610). The first portion (110) also comprises a first-portion environment-facing surface (114). The second portion (130) comprises a second-portion environment-facing surface (136), which partially overlaps with and is removably attached to the first-portion workpiece-facing surface (114), forming an interface (120) between the first-portion workpiece-facing surface (114) and the second-portion environment-facing surface (136).

Abstract: Manufacturing a pre-molded stack of one or more lenses to be installable on a curved substrate such as a vehicle windshield includes placing a moldable stack of one or more lenses and adhesive layer(s) on a mold, applying heat and pressure to the moldable stack to produce a pre-molded stack of one or more lenses from the moldable stack, and removing the pre-molded stack from the mold. The pre-molded stack may have a compound curvature, which may match a curvature of the curved substrate. The mold may be formed using three-dimensional shape data derived from the curved substrate, such as by optically scanning the curved substrate.

Abstract: Apparatuses, systems and methods of providing heat to enable an FDM additive manufacturing nozzle having refined print control and enhanced printing speed. The heating element may include at least one sheath sized to fittedly engage around an outer circumference of the FDM printer nozzle; at least one wire coil at least partially contacting an inner diameter of the sheath; and at least one energy receiver associated with the at least one wire coil.

Abstract: A method of over-molding materials includes: providing a first material in a groove in a first portion of a mold such that only a single surface of the first material is exposed to a vacant portion of the mold; providing, via an injection molding process, a second material in a liquid form in the vacant portion of the mold adjacent to, and in engagement with, the first material; and allowing the second material to solidify and become directly coupled to the first material, thus forming a single component. During the method, the entire single surface of the first material is flush with a plane defined by outer surface of the first portion of the mold. The second material has one or both of a greater hardness when solidified than the first material and/or a higher melting temperature than the first material.