A head is disclosed for an additive manufacturing system. The head may include a reservoir configured to hold a matrix, and a nozzle configured to discharge a continuous fiber received via the reservoir. The head may also include a plurality of supplies of different matrixes in fluid communication with the reservoir.

A part holder is disclosed for use with an additive manufacturing system. The part holder may include a first ring configured to provide mounting for a part during additive manufacturing. The part holder may also include a second ring configured to internally receive the first ring. The first ring may be moveable relative to the second ring.

A connector and a method of retaining a contact in a housing. The method includes: inserting the contact into a contact receiving cavity of the housing; applying extruded material in layers into the contact receiving cavity with a precision controlled nozzle; filling voids in the contact receiving cavity layer by layer until the contact receiving cavity is filled; and cooling or curing the extruded material, allowing the extruded material to bond with a wall of the contact receiving cavity. The contact is securely maintained in the contact receiving cavity of the housing by the extruded material. The connector having a contact positioned in a contact receiving cavity of a housing. Extruded material is positioned in the contact receiving cavity. The extruded material is bond to walls of the contact receiving cavity, wherein the extruded material securely maintains the contact in the contact receiving cavity of the housing.

A dispenser includes a high-pressure liquid feeder that feeds a high-pressure liquid higher in pressure than atmospheric pressure, a discharger that discharges the high-pressure liquid fed from the high-pressure liquid feeder, and a drive source that drives the discharger to operate. The discharger includes at least a container in which the high-pressure liquid is containable, a rotor rotatable by the drive source, a casing in which the rotor is housed in a rotatable manner, and a controller configured to control rotation of the drive source and a position of the container in a direction of the rotation. The container is formed on an outer peripheral surface of the discharger. The casing has a liquid supply channel formed to intercommunicate the container and the high-pressure liquid feeder, and further has a discharge nozzle formed to intercommunicate the container and outside of the discharger.

A method for dispensing a material into a mold for forming contact lenses, comprises the steps of: (1) providing a contact lens mold, (2) providing a dispensing needle, wherein the dispensing needle is made from a material having a surface energy less than 32 dynes/cm, (3) arranging the contact lens mold underneath the dispensing needle, (4) dispersing a fluid composition into a mold for making a contact lens, wherein the fluid composition comprises a lens-forming material, and the lens-forming material containing a solvent and is crosslinkable and/or polymerizable by thermal curing or actinic radiation.

The present invention provides an apparatus for use in mixing and dispensing a curable fluid stream (stream) into an open mold to fill the mold to make polishing pads for chemical mechanical planarization of substrates. The apparatus comprises an actuator frame on which is mounted (i) a set of two plates releasably attached to the actuator frame and adapted to cut the stream when the mold is full and to release from the actuator frame after cutting the stream, and (ii) a dispenser unit for continuous pouring of the stream into an open mold, the apparatus adapted to enable removal of the released plates from the actuator during the continuous pouring after the mold is full, e.g. by raising the actuator frame and the (ii) dispenser unit, whereby one can place a container above the mold to catch the plates.

A dosage device for extruding a monocomponent or a bicomponent polymeric product, particularly for an automatic machine for forming a spacer frame, includes a first dosage assembly and a separate second dosage assembly for the dosage and feeding of the product, which can be activated, in a first feeding step and in a third feeding step, alternately so that one of them provides continuity of flow to an extrusion nozzle while the other one is in the reloading step. The first and second dosage assemblies are activated, in a second swapping step that is intermediate with respect to the first and third feeding steps, simultaneously and jointly, one of them having a flow-rate ramp that passes from the steady-state value to zero and the other one complementarily having a flow-rate ramp that passes from zero to the steady-state value.

Methods of and devices for manufacturing a multi-layered microfluidic filter are disclosed. In one embodiment, method of manufacturing a multi-layered filter comprises providing a first molding plate that includes a plurality of apertures and is coupled to a flow stream source, applying from the flow stream source a first flow stream to pass through the plurality of apertures of the first molding plate, forming a first membrane layer comprising a first set of pores using the first molding plate and the first flow stream, controlling the first flow stream to generate a second flow stream from the first set of pores of the first membrane layer, and forming a second membrane layer comprising a second set of pores using the second flow stream and the first membrane layer.

According to at least one aspect, embodiments of the invention provide a method comprising supplying a reinforced axial fiber filament including a matrix material, a plurality of axial fiber strands extending continuously within the matrix material, and a multiplicity of fiber rods between 0.2-10 mm long dispersed throughout the matrix material, at least some of the dispersed fiber rods being oriented transversely to the fiber strands, supplying a composite fill separately from the filament, including a multiplicity of fiber rods between 0.2-10 mm long dispersed throughout the fill, the fiber rods having hardness at least twice that of a matrix of the fill, and depositing the filament within a first region of an outward portion of a part, through a nozzle throat having a thermal conductivity of at least 35 w/M-K adjacent a nozzle tip having a Rockwell C hardness of at least C40.

A pendulum device includes a base. A rotating plate is pivoted on the base. A movable member is eccentrically pivoted on the rotating plate by one of two ends thereof, and the other end of the movable member is for connecting to an article to be operated. A driving unit is at one side of the base. The driving unit is for driving the rotating plate of the base to perform a uniform circular motion. Because of the movable member eccentrically pivoted on the rotating plate, when the operating end is connected to the article, the operating end is dragged by the transmission of the rotating plate to perform a simple harmonic motion that is a variable accelerating linear motion relative to the rotating plate.