Methods and apparatus for manufacturing a microwavable food container include: forming a wire mesh over a mold comprising a mirror image of the microwavable food container; immersing the wire mesh in a fiber-based slurry bath; drawing a vacuum across the wire mesh to cause fiber particles to accumulate at the wire mesh surface; and removing the wire mesh including the accumulated fiber particles from the slurry bath; wherein the slurry comprises a moisture barrier, an oil barrier, and a vapor barrier.

Methods and apparatus for manufacturing a microwavable food container include: forming a wire mesh over a mold comprising a mirror image of the microwavable food container; immersing the wire mesh in a fiber-based slurry bath; drawing a vacuum across the wire mesh to cause fiber particles to accumulate at the wire mesh surface; and removing the wire mesh including the accumulated fiber particles from the slurry bath; wherein the slurry comprises a moisture barrier, an oil barrier, and a vapor barrier.

A method for manufacturing a transparent aligner for dental alignment is disclosed. The method may include: determining a tooth contour model which includes a contour portion surrounding a surface of a tooth requiring rotational correction; determining an axis of rotation for the tooth requiring rotational correction; determining two points touching exterior surfaces of the tooth requiring rotational correction based on the axis of rotation and a direction of rotation required for correcting the tooth requiring rotational correction, the two points being symmetrical with respect to the axis of rotation; determining a rotational correction model for the rotational correction by protruding the contour portion towards a tooth surface and towards a direction of rotation at the two points; and generating the 3D dental alignment model data by applying the rotational correction model.

An apparatus for thermoforming plastic containers comprising a thermoforming device (3) in turn comprising a shaped mould (4) and a closing element (5) movable relative to one another at least between a home position and a forming position, and an extracting device (9) for extracting the thermoformed container (2) from the shaped mould (4), the extracting device comprising at least one gripper element (68) shiftable between a pickup position and a releasing position; in which when the shaped mould (4) and the closing element (5) are in an extracting position, the gripper element (68) in the pickup position can grip a projecting edge (66) of a projecting flange (71) of the container (2) for retaining it, whilst when the gripper element (68) is in the releasing position it can release a thermoformed container (2), retained by it, onto a conveying device (69); and in which the gripper element (68) and the shaped mould (4) are also movable relative to each other, starting from the position in which the gripper element (68) has gripped the edge (66) of the container (2), along an extracting line, for causing the container (2) to come out of the shaped mould (4).

An apparatus for thermoforming plastic containers comprising a thermoforming device (3) in turn comprising a shaped mould (4) and a closing element (5) movable relative to one another at least between a home position and a forming position, and an extracting device (9) for extracting the thermoformed container (2) from the shaped mould (4), the extracting device comprising at least one gripper element (68) shiftable between a pickup position and a releasing position; in which when the shaped mould (4) and the closing element (5) are in an extracting position, the gripper element (68) in the pickup position can grip a projecting edge (66) of a projecting flange (71) of the container (2) for retaining it, whilst when the gripper element (68) is in the releasing position it can release a thermoformed container (2), retained by it, onto a conveying device (69); and in which the gripper element (68) and the shaped mould (4) are also movable relative to each other, starting from the position in which the gripper element (68) has gripped the edge (66) of the container (2), along an extracting line, for causing the container (2) to come out of the shaped mould (4).

A display for a computer system may be created by generating a three-dimensional image using a rotating helicoid. The helicoid may be formed by deforming a catenoid to form a helicoid. The helicoid may be supported by a pair of structures that do not occlude an image projected onto the helicoid nor occlude the user's ability to view the full extent of the image on the helicoid. The helicoid generated image may be transformed to an aerial floating image by a corner cube reflector array plate. Then depth sensing cameras may sense user interaction with the floating aerial image and may modify the image to make it appear that the user is actually modifying a physical object by manual manipulation.

A method of manufacturing a cover for a spa includes the steps of vacuum molding a first shell member and a second shell member, bringing the first and second shell members into registration with one another to define a hollow cavity therebetween, and injecting a foam into the hollow cavity, wherein the foam is configured to bond with the shell members to create a unitary structural part that provides increased strength and rigidity.

A method of manufacturing a cover for a spa includes the steps of vacuum molding a first shell member and a second shell member, bringing the first and second shell members into registration with one another to define a hollow cavity therebetween, and injecting a foam into the hollow cavity, wherein the foam is configured to bond with the shell members to create a unitary structural part that provides increased strength and rigidity.

A gripper is disclosed for a draping frame having a gripper chassis and at least two opposing mutually movable gripper jaw elements for gripping a film element. The gripper jaw elements are provided on a gripper head part of the gripper. The gripper head part of the gripper is movably mounted, at least with one degree of freedom, relative to the gripper chassis.

A protective film 10 of the present invention is used by being attached to a resin substrate 21 at the time of performing heat bending on the resin substrate 21 while heating the resin substrate 21. The protective film 10 includes a base material layer and a pressure sensitive adhesive layer which is positioned between the base material layer and the resin substrate 21 and is adhered to the resin substrate 21. The base material layer is formed of a laminate having a first layer which is positioned on the opposite side of the pressure sensitive adhesive layer, contains a thermoplastic resin, and has a melting point of 150° C. or higher and a second layer which is positioned on the pressure sensitive adhesive layer side, contains a thermoplastic resin, and has a melting point of lower than 120° C.