A continuous forming apparatus for molding foam material into foam products that includes a first endless belt and a second endless belt that cooperates with the first endless belt to mold the foam material. The continuous forming apparatus may also include a first plurality of cleats and a second plurality of cleats opposed to the first plurality of cleats that support the first endless belt and the second endless belt respectively. The first plurality of cleats may include a three-dimensional abutment surface that provides transverse and lateral support to the first endless belt. Additionally, the continuous forming apparatus may include a first frame disposed to support the first plurality of cleats, a second frame disposed to support the second plurality of cleats, and a drive mechanism for imparting motion to the first endless belt, the second endless belt, the first plurality of cleats, and the second plurality of cleats.

A plant and method for making continuous yarns made of silicone material comprises at least an extrusion station, into which the material is introduced in an amorphous condition, and extrusion means which cause the material to exit from the extrusion station along an extrusion axis. The plant also comprises a vulcanization station, located downstream of the extrusion station, at a determinate distance therefrom, in which the continuous yarn is vulcanized in a direction of treatment. The plant also comprises a drawing unit, disposed downstream of the vulcanization station.

There is provided a system and method for manufacturing continuous strand fiberglass of progressive density with varying skins. Glass media is melted into molten glass within a temperature controlled melter, the molten glass exits the melter through orifices of a bushing plate, which is oriented 6 degrees relative to the axis of a rotating drum. A rotating drum receives the molten glass exiting the bushing plate, and resin and water are applied. The fiberglass media is fed through rollers before it enters a curing oven.

A curing apparatus (100) includes a housing (102) having a loading portion (108) open to ambient atmosphere, a curing portion (110) having a curing chamber (124) with a controlled atmosphere, and a transition portion (112) extending between the loading portion (108) and the curing portion (110). A carrier (128) is movable between the loading portion (108) and the curing chamber (124) via the transition portion (112). The curing apparatus (100) further includes at least one ultraviolet radiation source (150) operative for transmitting ultraviolet radiation into the curing chamber (124). The transition portion (112) includes a plurality of baffles (158) protruding from a sidewall (120) of the transition portion (112) and configured for minimizing mixing between the ambient atmosphere and the controlled atmosphere during movement of the carrier (128) between the loading portion (108) and the curing chamber (124).

A shaping apparatus that fabricates a three-dimensional object by stacking a material layer formed of a shaping material, comprising: a conveyance belt that supports and conveys the material layer; a heating roller that is one of rollers supporting the conveyance belt and heats the material layer supported by the conveyance belt via the conveyance belt; and a shaping section that stacks the material layer on a downstream side of the heating roller in a conveyance direction, wherein a size of a contact area as an area in which the heating roller and the conveyance belt are in contact with each other in the conveyance direction is larger than a maximum possible size of the material layer in the conveyance direction.

The invention relates to a method for producing a fiber-reinforced, polymeric continuous profiled element (1), wherein the continuous profiled element (1), having preferably at least one hollow chamber (2, 2), comprises a core profile (10) which can be produced by means of a pultrusion process, and wherein during the pultrusion process at least one continuous strand having reinforcement fibers (5) is integrated into the polymer matrix (4) of the core profile (10). According to the invention, the curing of the core profile (10) is carried out by means of a dual-cure method.

A super absorbent polymer drying apparatus is disclosed. The super absorbent polymer drying apparatus is a drying apparatus equipped with a conveyor for drying the super absorbent polymer, and may include: a conveyor for transferring the super absorbent polymer; and a hot air supply part for supplying dry hot air to the conveyor, wherein the conveyor may include a plurality of conveyor beds connected to each other in a bent state, a link connecting part for connecting between the plurality of conveyor beds, and a driving part for driving the conveyor beds.