A transdermal drug delivery patch according to an exemplary embodiment of the present invention includes: a flexible base layer; and a plurality of microneedle disposed at one surface of the base layer. Each of the plurality of microneedles includes a biodegradable polymer and a drug and has an empty space inside. Each of the plurality of microneedles is formed as a star-shaped pyramid including a plurality of protrusions extending in a radial direction, and a part between two protrusions adjacent along the circumferential direction among the plurality of protrusions is concave.

According to some aspects, a method is provided of casting an object from a mold, the method comprising obtaining a mold comprising a hollow shell of rigid material, the material comprising a thermoset polymer having a plurality of pores formed therein, providing a metal and/or ceramic slurry into an interior of the mold, exposing at least part of the mold to a low pressure environment so that a net flow of gas is produced from the interior of the mold into the low pressure environment. According to some aspects, a method of forming a porous mold is provided. According to some aspects, a photocurable liquid composition is provided, comprising a liquid photopolymer resin, particles of a solid material, in an amount between 30% and 60% by volume of the composition, and a water-soluble liquid.

To provide a moth-eye transfer mold and a method of manufacturing a moth-eye transfer mold that provide a simple and inexpensive manufacturing process. A moth-eye transfer mold 1 is characterized by including a base 10, an underlayer 20 formed on the base 10, and a glassy carbon layer 30 formed on the underlayer 20, the glassy carbon layer 30 has an inverted moth-eye structure RM over a surface 30a, and the inverted moth-eye structure RM is randomly arranged cone-shaped pores.

An apparatus for manufacturing a part, where the apparatus includes a granular media made of a particulate material and a binding material, where at least a portion of the granular media being formed as a surface of a layup tool.

Methods of forming a curvature into a composite stiffener and a forming tool are presented. The composite stiffener is positioned in a forming region created by a base assembly and an upper assembly. A first airflow is applied through the material of the base assembly. A second airflow is applied through the material of the upper assembly. A plurality of brackets of the upper assembly is moved relative to each other to change a curvature of the forming region along a length of the forming region to form the curvature into the composite stiffener.

A mold for encapsulating an electrical component. The mold includes an encapsulation chamber and an air inlet. The encapsulation chamber is defined by a housing, an open top, and a solid bottom. The housing includes a solid outer wall, a permeable inner wall, and an air chamber between the solid outer wall and the inner wall. The air inlet is configured to introduce a gas into the air chamber. The encapsulation chamber is sized and shaped to receive the electrical component while leaving a gap for the introduction of encapsulant around the electrical component. The encapsulant may be silicone rubber. To remove an encapsulated electrical component, pressurized air may be introduced through the air inlet into the air chamber, passing through the permeable inner wall, separating the outer surface of the encapsulant from the housing, and allowing the combination casting to be removed from the mold.

A system that includes a mould drum having one or more product cavities, a first front end, and a second front end; a forming apparatus, which utilizes the mould drum to form food products from a food mass; a cleaning apparatus, which cleans the mould drum after forming the food products, the cleaning apparatus is remote from the forming apparatus; a movable unit that is configured to transport the mould drum from the forming apparatus to the cleaning apparatus, and vice versa; and a support structure and a spindle, which are reversibly attached to the forming apparatus during production and reversibly attached to the movable unit during the transport of the mould drum.

Methods, systems, and apparatus, including medium-encoded computer program products, for designing and manufacturing conformal cooling molds with lattice structures include, in one aspect, a method including: obtaining temperature and pressure data for a 3D model of a conformal cooling mold from computer simulation of injection molding; replacing a volume of the 3D model with a lattice structure to reduce the mass of the mold; adjusting a number of lattice unit cells for the lattice structure in accordance with the temperature data to increase heat conduction from hotter areas of the mold; adjusting thickness(es) of beams forming the lattice structure in accordance with the pressure data to prevent structural failure of the mold; and providing an updated version of the 3D model of the conformal cooling mold that incorporates the lattice structure after adjustment of the number of lattice unit cells and the thickness(es) of beams forming the lattice structure.

The invention described herein provides a method and material for creating tools surfaces from a granulated material comprised of a particulate and binding material in compositions and ratios described below. The granulated material may be formed using a number of methods and provides for the efficient repair of worn or damaged areas. Additionally, the granulated material may be used by placing it on the surface of a tooling encasement, or may be used by itself without any further structural support. The granulated material may also be used for both forming and trimming/machining of the part to desired tolerances.

A method of manufacturing a textured former and a glove made therefrom, wherein the method comprises preparing a hand-shaped ceramic greenware, scanning the hand-shaped ceramic greenware to generate a digital 3D hand-shaped greenware model, modelling a pair of stencil covers with curvy texture line based on the digital 3D hand-shaped greenware model, printing the stencil covers, creating a curvy palm texture on the hand-shaped ceramic greenware with the aid of the stencil covers, firing the hand-shaped ceramic greenware with curvy palm texture in a kiln and dipping the hand-shaped ceramic former with curvy palm texture in an aqueous colloidal dispersion to produce glove with curvy palm texture.