A method of making a light sensor module includes connecting a light sensing circuit to an interconnect on a substrate, and forming a cap. The cap is formed by producing a cap substrate from material opaque to light to have an opening formed therein, placing the cap substrate top-face down, dispensing a light transmissible material into the opening, compressing the light transmissible material using a hot tool to thereby cause the light transmissible material to fully flow into the opening to form at a light transmissible aperture, and placing the cap substrate into a curing environment. A bonding material is dispensed onto the substrate. The cap is picked up and placed onto the substrate positioned such that the light transmissible aperture is aligned with the light sensing circuit, with the bonding material bonding the cap to the substrate to thereby form the light sensor module.

A device (1) for producing a moulding of surface properties comprises a housing (3) having a pressure plunger (4) mounted on or in the housing (3), which can be moved and can be pressed on a surface (2), which pressure plunger has a blank carrier (5) comprising a pressure surface (6) which can be pressed on the surface (2), on which pressure surface a moulding blank (7) comprising a moulding layer (9) made of a curable material can be secured in a detachable manner. The device further comprises a curing device (12) arranged on or in housing (3), with which the curable material of the moulding blank (7) can be cured while being pressed on the surface (2).

A fiber capsule and a method of compression molding a fiber-based packaging capsule, includes the steps: forming a raw capsule of a loosely bonded fiber mat, which capsule has an opening, positioning the raw capsule of the loosely bonded fiber mat on the inside of a substantially rigid mol having inner surfaces defining the molded outer surfaces of the fiber-based packaging capsule, compression molding the loosely bonded fiber mat by the insertion of a pressurizable compression member through the opening, and pressurizing the pressing device at a temperature of 150-250 degrees C.?, preferably 160-200 degrees C., and at a pressure of 100-5000 bar, preferably 300-1200 bar. The compression molding may take place by reshaping the reshaping pressing device and pressing the inside of the capsule against the inner surfaces of the rigid mold so that a cohesive fiber-based packaging capsule is obtained.

A disposable drink-through dome lid for disposable drinking cups used in the sale of hot or cold beverages, the top of the lid elevated above the top of the beverage cup when in place. The lid's outer wall is elevated to form a drink ridge adapted to the user's lips for drinking through a generally oval-shaped drink-through orifice. Ideally, the drink-through orifice includes: a drink-through chamber having a drink flap capable of closing off a drink-through opening, thereby shielding against accidental spillage due to sloshing of the beverage while traveling; and a recessed orifice ridge on the interior side of the drink-through orifice, directs froth exiting the drink opening into a spill reservoir. A vent opening positioned near the lid's center and within a vent slot, collects and directs beverage exiting the vent into the spill reservoir.

The present disclosure relates to a forming apparatus for forming a base of a container filled with a pourable product and closed with a closure element. In one implementation, the apparatus includes a first conveyance device advancing the container along a first path, a second conveyance device arranged below the first path and configured to advance the deformation device along a second path, an upper retainer arranged above the first path and cooperating in use with a top part of the container, and at least one deformation device arranged below the first path, advanced in use to follow the container moving along the first path, and configured to interact with the container to deform its base. The first conveyance device may include two parallel first linear conveyors arranged side by side, defining a gap between the conveyors, and having respective horizontal linear transport branches lying in a common horizontal plane.

Provided is a compression molding die. The die can be used for compression molding an I-shaped part without the need for machining. The molding die comprises: an outer mold with an inner diameter of d; an upper pressing disc, a lower pressing disc and a huff mold with the same outer diameter of d and the same inner diameter of f; an upper mold; a lower mold; and a core mold with a diameter of h. The upper pressing disc, the huff mold and the lower pressing disc, which are movable vertically, are arranged in the outer mold in a vertically spaced manner; the vertically movable upper mold extends into the upper pressing disc, and the vertically movable lower mold extends into the lower pressing disc; the outer mold, the upper mold, the upper pressing disc, the huff mold, the lower pressing disc and the lower mold define a cavity.

A molding apparatus according to an embodiment of the present invention may mold a cup part in a pouch film. The molding apparatus includes: a die on which the pouch film is seated on a top surface thereof and in which a first space recessed from the top surface is defined; a stripper which is disposed above the die to fix the pouch film and in which a second space is defined at a position corresponding to the first space; and a pressing part configured to apply a pneumatic or hydraulic pressure to the pouch film so that a portion of the pouch film is elongated into the first space.

A method for processing a curved plastic panel is to first form a hard coating layer, an optical function layer, and a printing layer on a flat plastic substrate, and then cut it into a predetermined shape, and then use a hot pressing and curving device to perform a hot pressing and curving process to the flat plastic substrate in order to make it becoming a curved plastic substrate. The hot pressing and curving device can simultaneously perform hot pressing during the heating process, and has the functions of real-time monitoring of the local temperature and the local curvature forming state, and then feedback to the local heating and curvature forming mechanism for adjustments. The monitoring of temperature and curvature can be divided into multiple stages, which can be monitored stage by stage and adjusted for heating or curvature forming to improve production yield.

An optical element includes a base having a curved depression formed in a front surface thereof and a formed layer arranged on the base. The formed layer includes a main part in the depression as viewed from a depth direction of the depression and an overhang on the front surface of the base while connecting to the main part. An opposite surface of the main part to a surface thereof on a side of an inner surface of the depression is formed like a concave curve that is concave in a same direction as the inner surface of the depression. A predetermined surface of the main part that is opposed to the inner surface of the depression is provided with an optical function part.

There is provided an apparatus for molding a thermoplastic material into a homogenous sample body having a predetermined shape, the apparatus comprising: (a) a main body (110) comprising a first opening (112), a second opening and a hollow bore (116) connecting the first opening (112) with the second opening, the hollow bore (116) being adapted to receive a separation foil shaped to cover at least a part of the hollow bore surface; (b) a piston (120) adapted to fit moveably into the hollow bore (116) containing the separation foil; (c) a base plate (130) comprising a protrusion, wherein the base plate (130) is adapted to be inserted into the first opening (112) in such a manner that the protrusion extends into a part of the hollow bore (116) containing the separation foil, and wherein the base plate (130) is adapted to transfer heat from a heating unit to a thermoplastic material (150) resting on the protrusion (132); (d) a vacuum connector (142) adapted to be connected to a vacuum source; (e) a lid (140) adapted to fit moveably into the second opening and adapted to apply a force to the piston (120) when the vacuum connector (142) is connected to the vacuum source such that the piston (120) applies a compressing force to the thermoplastic material (150) resting on the protrusion. There are further provided a method and a system for molding a thermoplastic material into a homogenous sample body having a predetermined shape.