The present invention relates to a closure device (1) for a container (2) in which a flowable material (3) is stored, comprising a base element (4), which can be fastened on a container opening (5) of the container (2), a spout (11) with a dispensing opening (7), whereby the spout (11) is positioned inboard of the base element (4), and a lid (8) connected to the base element (4) by a hinge (12), whereby the lid (8) can be moved back and forth between a closed position (9) in which the lid (8) closes the dispensing opening (7) so that the spout (11) is not accessible and an open position (10) in which the spout (11) is accessible, tamper evidence indication means (13) for visually indicating if the lid (8) of the closure device (1) has once been moved out of its closed position (9).

The present invention relates to a closure device (1) for a container (2) in which a flowable material (3) is stored, comprising a base element (4), which can be fastened on a container opening (5) of the container (2), a spout (11) with a dispensing opening (7), whereby the spout (11) is positioned inboard of the base element (4), and a lid (8) connected to the base element (4) by a hinge (12), whereby the lid (8) can be moved back and forth between a closed position (9) so that the spout (11) is not accessible and an open position (10) in which the spout (11) is accessible, tamper evidence indication means (13) for visually indicating if the lid (8) of closure device (1) has once been moved out of its closed position (9).

The present invention relates to a process for manufacturing a closure device (1) for a container (2) in which a flowable material (3) is stored whereby the manufacturing process includes the following steps: moulding of the base element (4), the lid (8) and the hinge (12) with the lid (8) being moulded in its open position; closing of the lid (8) to the base element (4); moulding of the tamper evidence indication means (13), whereby the tamper evidence indication means (13) comprising a first indication ring (14) and a second indication ring (15) being coaxially positioned to each other and which are connected by at least one radially oriented frangible bridge (6); assembly of the tamper evidence indication means (13) into the base element (4) and the lid (8); assembly of the spout (11) into the base element (4).

The present invention relates to a process for manufacturing a closure device (1) for a container (2) in which a flowable material (3) is stored whereby the manufacturing process includes the following steps: moulding of the base element (4), the lid (8) and the hinge (12) with the lid (8) being moulded in its open position; closing of the lid (8) to the base element (4); moulding of the tamper evidence indication means (13), whereby the tamper evidence indication means (13) comprising a first indication ring (14) and a second indication ring (15) being coaxially positioned to each other and which are connected by at least one radially oriented frangible bridge (6); assembly of the tamper evidence indication means (13) into the base element (4) and the lid (8); assembly of the spout (11) into the base element (4).

A method of filling a microcavity with layers of a polymer material includes the following steps: (A) estimating a current vertical position of a bottom of the microcavity (current bottom position); (B) lowering the capillary tube into the microcavity towards the current bottom position; (C) dispensing a polymer composition from a tube outlet of the capillary tube under a dispensing applied pressure until the polymer composition substantially fills the microcavity; (D) curing a work piece including the microcavity and the polymer composition in the microcavity to obtain a current layer of the polymer material; and (E) repeatedly executing steps (A), (B), (C), and (D), until the layers of the polymer material have substantially filled the microcavity.

An apparatus for manufacturing a semiconductor device includes a base portion, a bonding stage arranged on the base portion and having a placement surface for placing a substrate; and one or more connecting members which connect the base portion and the bonding stage, wherein at least one of the one or more connecting members is a connecting plate that deflects following the expansion and contraction of the bonding stage in the plane direction caused by a temperature change.

An injection molding device (1) includes a center part (3) and a rotating device (2) for rotating the center part (3) in the injection molding device (1). The rotating device (2) includes a base (4) supported with respect to an injection molding machine. A thereto attached column (5) extends in an axial direction (z) above the base (4). A sleeve (6) coaxially surrounds the column (5) and is at least partially arranged in the center part (3). The sleeve (6) rotates with the center part (3) around the column (5). The column (5) is arranged removable with respect to the center part (3).

An injection molding apparatus includes a fixed die having a first gate opening and a second gate opening formed therein, a movable die configured to be clampable to the fixed die, a first injection unit that injects a first molding material into a cavity defined by the fixed die and the movable die via the first gate opening, and a second injection unit that injects a second molding material into the cavity via the second gate opening.

An injection molding apparatus includes a fixed die having a first gate opening and a second gate opening formed therein, a movable die configured to be clampable to the fixed die, a first injection unit that injects a first molding material into a cavity defined by the fixed die and the movable die via the first gate opening, and a second injection unit that injects a second molding material into the cavity via the second gate opening.

A golf ball material contains (i) fine particles that have an average particle size of less than 300 μm and are composed of a crosslinked multi-component copolymer having conjugated diene units, non-conjugated olefin units and aromatic vinyl units; and (ii) a thermoplastic resin. The conjugated diene units include butadiene units, the non-conjugated olefin units include units selected from the group consisting of ethylene, propylene and 1-butene units, the aromatic vinyl units include styrene units, and the content of the conjugated diene units in the multi-component copolymer is 5 wt % or more. This golf ball material is soft, has an excellent rebound resilience and also has a good processability.