Method for forming polymer materials utilizing modular die units

Abstract

The present invention is directed to a modular die unit comprising a plurality of individually shaped plates wherein the shaped plates are stacked in face to face juxtaposition, and when placed into such a juxtaposition exhibit useful polymer forming attributes heretofore unattainable by prior art practices. Single die plates are formed such that the plates exhibit a finite geometric relationship, which in turn provides resistance to flexural deformation of the individually shaped die plates and conversely, improved resistance to variability of the modular die unit and enhanced and predictable formation characteristics of the polymer material formed therewith. Each of said single die plates within the stack forming the modular die unit exhibit an x-direction, a y-direction, and a z-direction, wherein any one of said single die plates exhibit in said x-direction and y-direction to have at least a 50% planar continuity of the total planar continuity.

Description

TECHNICAL FIELD [0001] The present invention is directed to the method of forming polymer materials, and specifically, the method of forming polymer materials by means of a stacked-plate modular die unit exhibiting resistance to flexural deformation and enhanced polymer formation capabilities. BACKGROUND OF THE INVENTION [0002] Formation of polymeric compounds into a variety of geometries is well known in the art. For example, heretofore formation practices have exhibited particular importance in the fabrication of continuous filaments, fragmentary filaments and films from a variety of precursor polymer compositions. These practices have typically employed the use of a monolithic forming block, or die, to which the polymer composition or compositions are introduced. The polymer composition(s) are then expressed from the monolithic die under the influence of force, most typically such force being presented in the form of mechanical, hydraulic, or electrostatic attraction. Due to the ...

AI Technical Summary

Benefits of technology

[0007] The present invention is directed to a modular die unit comprising a plurality of individually shaped plates wherein the shaped plates are stacked in face to face juxtaposition, and when placed into such a juxtaposition exhibit useful polymer forming attributes heretofore unattainable by prior art practices. Single die plates are formed such that the plates exhibit a finite geometric relationship, which in turn provides resistance to flexural deformation of the individually shaped die plates and conversely, improved resistance to variability of the modular die unit and enhanced and predictable formation characteristics of the polymer material formed therewith. Each of said single die plates within the stack forming the modular die unit exhibit an x-direction, a y-direction, and a z-direction, wherein any one of said single die plates exhibit in said x-direction and y-direction to have at least a 50% planar continuity of the total planar continuity.

[0009] The flexural deformation attributes of the individually shaped die plates are, optionally, further combined with finite control of the fluidic passage-ways defined in the component geometry of the die plate to further enhance the performance of the corresponding modular die unit when forming polymer materials. So as to obtain effective interfacing of two or more fluidic passageways, said fluid passage ways should interface at coinciding incident angles of between 3 and 87 degrees.

[0011] It is within the purview of the present invention that individually shaped die plates can comprise surface asperities, projections, voids and other deviations in planar geometry which allow for the shaped plates to adjust into specific relative orientation when one or more of such plates are placed into face to face juxtaposition.

Problems solved by technology

Due to the nature of formation and use of monolithic dies themselves, such dies can pose a number of technical limitations.

The uniform introduction of polymer composition into the monolithic die, combined with the maintenance of the polymer composition in an ideal expression state, has proved to be an extremely burdensome task as the dies used to obtain optimum commercial efficiencies must either be quite large in size and / or exhibit enhanced process robustness.

Further, over the course of continuous use, monolithic dies are subject to wear, which in turn alters the physical parameters of the die and likewise, alters the resulting polymer materials formed thereof.

It has been found that such use of specially shaped plates combined into a modular die unit exhibit multiple deficiencies that compromise the ability of the modular die unit to perform in the manufacture of formed-polymer constructs.

This deformation results in variability in the polymer material formed not only across the width of a corresponding modular die unit comprising such shaped plates, but also variability over the course of time as the modular die unit is subjected to continuous stresses.

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