A method for replacing one or more components of a lip adjustment assembly mounted to a die body of an extrusion die is disclosed. Initially, a translating unit of the lip adjustment assembly is accessed through an exposed end of the lip adjustment assembly. Then, an adjustment actuator is removed from a translator of the translating unit. The translator is decoupled from a rod of the translating unit so that the translator is removable from the lip adjustment assembly and with respect to the rod. Next, the translator is removed from the lip adjustment assembly and a first component of the translating unit is replaced with a second component of the translating unit.

Disclosed herein is a die assembly comprising a first attachment block having a passage, an inlet port and an exit port; where the passage is operative to transport a molten material from the inlet port to the outlet port; a die; and a conduit; where the conduit comprises a passage that is operative to transport the molten material from the first attachment block to an entry port of the die; where the die comprises a first outer tube; and an extrusion pin that comprises a post and fins; where the extrusion pin is located in the first outer tube using the fins and where the post extends from the fins in a direction away from the entry port of the die; and where the post comprises one or more passages; where at least of these passages open to the atmosphere to provide for pressure equalization; and a travelling template; the template being operative to contact an extrudate that emanates from the die and to transfer a texture to a surface of the extrudate by virtue of pressure applied by a guide tube to the extrudate via the travelling template.

An extruder assembly for forming a multi-layered composite is described, the extruder assembly includes an extruder head having a first and second flow passage, a first and second extruder in fluid communication with the respective first and second flow passage, and a splice bar having a first and second passageway extending from a rear side to an outlet side, and communicating flow from the first and second passageway to an outlet die. The splice bar further includes a groove located on the rear side of the splice bar and being positioned between the first and second passageway.

A material deposition system for additive manufacturing including an extruder that defines a first input passage for supplying a first material, a second input passage for supplying a second material, a chamber for combining the first and second materials to form a combined deposition material, and an extrusion port for extruding the combined deposition material. The system further includes an adjustable sleeve that is movable between a first position and a second position to vary the interaction between the first material and the second material in the chamber. For example, the adjustable sleeve may be configured to separate the first and second materials in the chamber, and can vary the point at which the materials interface with each other prior to deposition based on the sleeve position. Such a system may enable a varying degree of infiltration, encapsulation, or other interaction between the first and second materials prior to deposition.

An extrusion head for pipes includes a first female body provided with a first through cavity and a male element inserted and supported in the first cavity, and defining with it a hollow space. A second female body is attached to the first female body and provided with a second through cavity. An interchangeable male body is attached cantilevered on the male element and positioned in the second cavity. The second female body and the interchangeable male body define a passage gap in fluidic communication with the hollow space. In the second cavity, a housing seating is made in which an adjustment ring is positioned, through which the interchangeable male body is positioned through, and adjustment members configured to adjust the position of the adjustment ring.

Disclosed is an extrusion machine including a head body and a die seat arranged on a front surface of the head body. A die is attached in a removable manner to the die seat. The die includes an extrusion outlet that is in communication with an opening through which plastic material is discharged out of the head body. A holding member is in contact with a front surface of the die. A pressing mechanism presses the holding member against the front surface of the die.

An extrusion die includes a first die body having a first lip, and a second die body having a second lip. A lip adjustment assembly is mounted to the first die body and configured to adjust the position of the first lip relative to the second lip to thereby adjust a thickness of the extrudate that exits the gap. The lip adjustment has translating unit that includes translator, a mounting member coupled to the translator, and a rod coupled to the mounting member so that the translator is fixed with respect to the rod. The mounting member is configured to be accessible from the exposed end to decouple the translator from the rod so as to remove the translator from the lip adjustment assembly.

A multi-lane die is provided. The multi-lane slot die comprises an upper body member, a lower body member, an upper shim, a separator shim, and a lower shim. The upper shim is positioned between the upper body member and the separator shim. The upper shim, the upper body member, and the separator shim define a first at least one dispensing channel that extends to a first at least one dispense opening of the multi-lane die. The lower shim is positioned between the separator shim and the lower body member. The lower shim, the separator shim, and the lower body member define a second at least one dispensing channel that extends to a second at least one dispense opening of the multi-lane die.

An adjustment system coupled to a die, and a die including an adjustment system, includes first and second adjustment modules. The first adjustment module includes a first body, a first plurality of studs, and a first actuator. Each of the first plurality of studs is slidably positioned within the first body. The first actuator is coupled to the first plurality of studs and is configured to move each of the first plurality of studs. The second adjustment module includes a second body, a second plurality of studs, and a second actuator. Each of the second plurality of studs is slidably positioned within the second body. The second actuator is coupled to the second plurality of studs and is configured to move each of the second plurality of studs. The number of studs composing the first plurality of studs is different from a number of studs composing the second plurality of studs.

A skinned panel for stably molding a thin skin material and a molding method thereof. An extruding device is configured to extrude a pair of multilayered resin sheets, each of which has a lamination structure of an inner layer made of a foamed resin and an outer layer made of a non-foamed resin that is changed into a skin material of a sandwich panel as a skinned panel. The pair of the resin sheets is abutted to the circumferential part of the pair of the split molds for producing sealed spaces. The sealed spaces are sucked for pressing the pair of the resin sheets onto cavities of the pair of the split molds. Accordingly, the pair of the resin sheets is formed in a shape substantially identical to the outline of the sandwich panel.