A method of making an integrated depth sensor window lens, such as for an augmented reality (AR) head set, the depth sensor window lens comprising a sensor lens and an illuminator lens separated by an opaque dam. The method uses a two-shot injection molding process, a first shot comprising an optically clear polymeric material to form the sensor lens and the illuminator lens and the second shot comprising an opaque polymeric material to form the separator of the two.

A process can be used for the surface treatment of three-dimensional objects which have been produced in additive manufacturing processes from at least one polymer. The process involves a) immersing the three-dimensional object in a substance mixture A, b) leaving the three-dimensional object in the substance mixture A for a time, and c) removing the three-dimensional object from the substance mixture A. The process then involves d) immersing the three-dimensional object in a substance mixture B, e) leaving the three-dimensional object in the substance mixture B for a time, and f) removing the three-dimensional object from the substance mixture B. The substance mixture A has a temperature (process temperature A) which is above the melting point of the polymer, and the substance mixture B has a temperature (process temperature B) which is below the melting point of the polymer.

A method for creating a transition from an edge of an add-on part mounted on the outer surface of a rotor blade, including the steps: delimiting an application area on the rotor blade surface and the add-on part to be covered by a sealant compound with a thin and smooth masking tape; dispensing of the sealant on the application area; distribution of the sealant; removing the masking tape; and smoothening of a sealant transition step with a flexible tool, is provided.

A wind turbine rotor blade is also provided.

A preform is provided for blow-molding to form a container. The preform includes a finish portion for rotatably engaging a closure to seal pressurized contents within an interior of the container. The finish portion comprises a cylindrical body that begins at an opening to the interior and extends to and includes a tamper evidence ledge. A bevel at a beginning of the opening receives a plug seal of the closure. Multiple mirror polished surfaces beyond the bevel are configured to cooperate with the plug seal to seal the container. Mirror polished transition surfaces are disposed between diameter changes within the finish portion. In some embodiments, wherein the plug seal includes a sidewall profile that mates with the transition surfaces, an interior surface of the preform has a diameter that tightly compresses an end of the plug seal to contain pressurized contents within the container.

The invention provides method for producing a 3D item (1) by means of fused deposition modelling, the method comprising: —a 3D printing stage comprising layer-wise depositing an extrudate (321) comprising 3D printable material (201), wherein during at least part of the 3D printing stage the extrudate (321) comprises a core-shell extrudate (1321) comprising a core (2321) comprising a core material (2011), and a shell (2322) comprising a shell material (2012), to provide the 3D item (1) comprising 3D printed material (202), wherein the 3D item (1) comprises a plurality of layers (322) of 3D printed material (202), wherein one or more of layers (322) comprises one or more core-shell layer parts (3322), wherein each of the core-shell layer parts (3322) comprises a layer core (3321) comprising the core material (2011), and a layer shell (3322) comprising the shell material (2012), wherein the 3D item (1) has an item surface (252) defined by at least part of the 3D printed material (202); —an exposure stage comprising exposing at least part of the item surface (252) to a liquid (402), wherein the core material (2011) has core material solubility SC1 for the liquid (402) and wherein the shell material (2012) has a shell material solubility SS1 for the liquid (402), wherein SC1<SS2.

A method for treatment of polymer elements obtained by an additive manufacturing process comprises applying to the polymer element a treating liquid in liquid form.

The invention relates to a powder application unit (8) for a PBLS system (1), wherein the powder application unit (8) comprises an application medium which is movably mounted parallel to a working plane of the PBLS system (1) in order to be able to move powder along the working plane, wherein a distance of the application medium to the working plane can be modified in that the application medium is mounted about a swivel axis (S) in a swiveling manner in order to be able to swivel the application medium away from the working plane. In order to provide an improved powder application unit, according to the invention the powder application unit (8) has a means for swiveling the application medium which is designed and which interacts with the application medium such that the application medium is first unswiveled in a work position during outward travel and then, during the continued travel along a predetermined route, is swiveled against the work position and, during an opposite return travel along the predetermined route, is unswiveled in the work position. The invention further relates to a method for applying two successive powder layers in a PBLS method.

A method for manufacturing a composite material includes placing a netlike sheet material, through which a resin composition permeates, on reinforcing fiber substrates disposed on a forming die. The method includes covering the reinforcing fiber substrates disposed on the forming die and the bag surface-smoothing sheet with a bag film to form a sealed forming space between the bag film and the forming die. The method includes infusing a resin composition into the forming space to impregnate the reinforcing fiber substrates. The method includes curing the resin composition impregnated in the reinforcing fiber substrates. Warp yarns and weft yarns are disposed in a lattice pattern and, after placing the bag surface-smoothing sheet on the reinforcing fiber substrates so that the warp yarns and the weft yarns form acute angles with respect to corners of the reinforcing fiber substrates, the bag surface-smoothing sheet projecting from the reinforcing fiber substrates is bent.

A structural reinforcement and biocompatible pump head for a pump includes a reinforcement structure having a plurality of ports and fluid pathways therein. The fluid pathways in the reinforcement may be coated or lined with a biocompatible material to form a biocompatible pump head useful for liquid chromatography and other analytical instrument systems. The biocompatible material may be injection molded into the fluid pathways of the reinforcement structure and may be machined after core pins are removed to obtain a desired surface finish and/or size of the biocompatible fluid pathways of the pump head.

The invention provides method for producing a 3D item (1) by means of fused deposition modelling, the method comprising:—a 3D printing stage comprising layer-wise depositing an extrudate (321) comprising 3D printable material (201), wherein during at least part of the 3D printing stage the extrudate (321) comprises a core-shell extrudate (1321) comprising a core (2321) comprising a core material (2011), and a shell (2322) comprising a shell material (2012), to provide the 3D item (1) comprising 3D printed material (202), wherein the 3D item (1) comprises a plurality of layers (322) of 3D printed material (202), wherein one or more of layers (322) comprises one or more core-shell layer parts (3322), wherein each of the core-shell layer parts (3322) comprises a layer core (3321) comprising the core material (2011), and a layer shell (3322) comprising the shell material (2012), wherein the 3D item (1) has an item surface (252) defined by at least part of the 3D printed material (202);—an exposure stage comprising exposing at least part of the item surface (252) to a liquid (402), wherein the core material (2011) has core material solubility SC1 for the liquid (402) and wherein the shell material (2012) has a shell material solubility SS1 for the liquid (402), wherein SC1<SS2.