A system for overmolding an encapsulation at a perimeter region of a glass window panel includes a mold having a fixed part and a first movable part, and a second movable part. Each of the fixed part and the second movable part has a seal disposed thereat. The fixed part and the first and second movable parts cooperate to receive and support a glass window panel and to define a seal cavity. The second movable part includes an elastomeric or rubber or VITON strip that engages a surface of the glass window panel during overmolding of an encapsulation at the perimeter region of the glass window panel.

A system for overmolding an encapsulation at a perimeter region of a glass window panel includes a mold having a fixed part and a first movable part, and a second movable part. Each of the fixed part and the second movable part has a seal disposed thereat. The fixed part and the first and second movable parts cooperate to receive and support a glass window panel and to define a seal cavity. The second movable part includes an elastomeric or rubber or VITON strip that engages a surface of the glass window panel during overmolding of an encapsulation at the perimeter region of the glass window panel.

Provided are methods for heat curing of various materials, such as heat curable materials or more specifically potting compounds, which are disposed within cavities with limited access to these materials. Also provided are curing for executing such methods. In some embodiments, a heat curable material disposed within a cavity may be heated by a heating rod protruding into the cavity or through the cavity. The heating rod is thermally coupled to the heat curable material and is used to transfer heat to the heat curable material. For example, the heating rod may include a resistive heating element. The heating element may be positioned in such a way that the heat curable material is selectively heated within the cavity without significant heating of surrounding components. In some embodiments, the heating rod may be also used to compress the part containing the cavity or a stack including this part.

Provided are methods for heat curing of various materials, such as heat curable materials or more specifically potting compounds, which are disposed within cavities with limited access to these materials. Also provided are curing for executing such methods. In some embodiments, a heat curable material disposed within a cavity may be heated by a heating rod protruding into the cavity or through the cavity. The heating rod is thermally coupled to the heat curable material and is used to transfer heat to the heat curable material. For example, the heating rod may include a resistive heating element. The heating element may be positioned in such a way that the heat curable material is selectively heated within the cavity without significant heating of surrounding components. In some embodiments, the heating rod may be also used to compress the part containing the cavity or a stack including this part.

What is described is a method of manufacturing a lens (2) for spectacles, comprising the steps of providing a lens blank (1) made from plastic material, obtaining, by cutting the blank (1), a corresponding lens having a final shape and profile suitable for mounting in a mounting frame, removing material from the lens (2) in predetermined areas of the lens to produce a first lens portion (3), inserting the first lens portion (3) into a mould (4) for overmoulding, injecting material into the mould (4) to produce at least a second lens portion (5) overmoulded on the first lens portion (3), and removing the lens (2), in which the first and second lens portions (3, 5) are integrated with one another, from the mould (4).

What is described is a method of manufacturing a lens (2) for spectacles, comprising the steps of providing a lens blank (1) made from plastic material, obtaining, by cutting the blank (1), a corresponding lens having a final shape and profile suitable for mounting in a mounting frame, removing material from the lens (2) in predetermined areas of the lens to produce a first lens portion (3), inserting the first lens portion (3) into a mould (4) for overmoulding, injecting material into the mould (4) to produce at least a second lens portion (5) overmoulded on the first lens portion (3), and removing the lens (2), in which the first and second lens portions (3, 5) are integrated with one another, from the mould (4).

An additive manufacturing method produces a 3D part utilizes electrophotography-based additive manufacturing and molding processes. A layered structure having a cavity is printed on a build platform using at least one electrophotographic (EP) engine to develop imaged layers of powder material, and a transfusion assembly to stack and fuse the imaged layers on the build platform. Molding material is deposited into the cavity as the layered structure is printed, using a deposition unit. The molding material solidifies to form at least a portion of the 3D part, which may also include portions formed from imaged powder material.

A dispenser apparatus for a curable liquid material is disclosed. The apparatus comprises a flexible bag defining a first compartment for accommodating a first component of a curable liquid material, and a second compartment for accommodating a second component of the curable liquid material and adapted to communicate with the first chamber to enable mixing of the first and second components to initiate curing of the curable liquid material. A first clamp temporarily prevents mixing of the first and second components, and an elongate nozzle communicates with the second compartment to dispense the mixed curable liquid material therefrom. A second clamp temporarily prevents passage of the curable liquid material from the second compartment to the nozzle.

A sheet metal member forming method comprises placing a fiber bundle of a predetermined length, via a thermosetting resin, in a predetermined position on a surface of a sheet metal member, forming a coating film on at least a part of the sheet metal member after the placing of the fiber bundle, and while heating and drying the coating film, heat-curing the thermosetting resin to bond the fiber bundle to the sheet metal member.

Provided is a bushing for manufacturing a three-dimensional composite preform using a tow made of a fiber reinforced polymer. The bushing includes a base plate in which one or more through-holes are formed, and a plurality of spools spaced apart from each other on the base plate. A flat top is formed at an end portion of the spools, and grooves are formed on outer surfaces of the plurality of spools in a circumferential direction thereof.