The present invention relates to pharmaceutical dosage forms, for example to a tamper resistant dosage form including an opioid analgesic, and processes of manufacture, uses, and methods of treatment thereof.

The present invention relates to pharmaceutical dosage forms, for example to a tamper resistant dosage form including an opioid analgesic, and processes of manufacture, uses, and methods of treatment thereof.

The present invention relates to pharmaceutical dosage forms, for example to a tamper resistant dosage form including an opioid analgesic, and processes of manufacture, uses, and methods of treatment thereof.

A three-dimensional modeling apparatus for fabricating a three-dimensional object includes a plasticizing section that plasticizes a thermoplastic material to transform into a molten material; an ejection section for ejecting the molten material; a first air blowing section that blows air from a circumference of the nozzle toward the molten material ejected from the nozzle; a platform on which the molten material ejected from the nozzle is deposited; and a control unit that changes a relative positional relationship between the ejection section and the platform.

An electrical wire includes a conductor and an insulating layer that covers the conductor and that is cross-linked. The insulating layer is a cross-linked product of a resin composition including (a) a base polymer containing polyolefin and a compatibilizer, (b) a photoradical generator of 0.5 parts by mass or more and 3 parts by mass or less relative to the 100 parts by mass of the base polymer, and (c) a reactive monomer of 1 part by mass or more and 5 parts by mass or less relative to the 100 parts by mass of the base polymer. A relative dielectric constant of the insulating layer is less than 2.5.

The present application relates, in particular, a fibre application head for producing composite material parts, comprising a compacting system comprising a compacting roller (2) for applying one or more fibres onto an application surface, and a heating system (9) capable of emitting thermal radiation towards the fibre or fibres. Said head further comprises a blowing system (8) comprising an air blowing nozzle (81), said nozzle being arranged upstream from the roller, with respect to the movement direction, and being capable of forming an air knife, parallel to the axis of the roller, towards the nip zone between the compacting roller and the layup surface.

Systems and methods are provided for fabricating composite parts. One embodiment is a method that includes heating a female die having a receptacle and a complementary male die, heating an extruder above a melting point of a thermoplastic within chopped prepreg fiber, in order to melt chopped prepreg fiber disposed within the extruder, extruding the chopped prepreg fiber from the extruder into the receptacle of the female die while the chopped prepreg fiber remains molten, pressing the male die into the female die, causing the molten chopped prepreg fiber to fully enter receptacle, and cooling the chopped prepreg fiber in the receptacle of the female die to form a composite part.

Examples of the present disclosure relate to a method of cooling objects produced by an additive manufacturing process. The method comprises obtaining a volume of build material output from the additive manufacturing process. The volume of build material comprises unsolidified build material. The volume of build material comprises a plurality of objects and a separating element between the plurality of objects, the objects and the separating element having been produced by sequentially depositing layers of build material and the separating element having been produced based on at least one of the plurality of objects. The method comprises applying gas to the volume of build material to cool the plurality of objects, wherein the separating element provides a barrier between the plurality of objects during the applying of the gas to the volume of build material.

A container (140) for receiving a manufactured object (160) from a 3D printer is disclosed. A method for cooling and unpacking 3D printed objects using that container. (140) is also disclosed. The container has a wall forming the sides of the container, a top extending to the sides of the container, a connector (142) for connection to a vacuum source and a guillotine member (150). The lower portion of the container has support members to slidably receive the guillotine member (150) to form a base of the container. The guillotine member is selectively configurable between an apertured configuration having a plurality of through holes (152) to allow passage of air and/or build material, and a closed configuration in which the through holes are closed so as to prevent build material from falling out of the container.

A soap reforming assembly includes a housing and a soap collection unit that is coupled to the housing for collecting and transporting pieces of soap when the pieces of soap are dropped into the housing. A heating element is coupled to the housing and the heating element heats the soap collection unit to melt the soap pieces into a fluid soap. A forming unit is positioned within the housing for receiving the fluid soap from the soap collection unit when the heating element produces the fluid soap. The forming unit cools and forms the fluid soap into a bar for bathing. A drawer is slidably positioned in the housing and the drawer receives the bar of soap from the forming unit. The drawer is positionable in an open position having the drawer extending outwardly from the housing to dispense the bar of soap.