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A method for making freeform-fabricated core composite articles using freeform-fabricated machine. The articles are capable of being utilized as end products rather than prototype models by creating a core having an interior structure to provide strength to the core and to enhance the strength to we

A method for making freeform-fabricated core composite articles using freeform-fabricated machine. The articles are capable of being utilized as end products rather than prototype models by creating a core having an interior structure to provide strength to the core and to enhance the strength to weight ratio of the article.

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A method for making freeform-fabricated core composite articles using freeform-fabricated machine. The articles are capable of being utilized as end products rather than prototype models by creating a core having an interior structure to provide strength to the core and to enhance the strength to we

A method for making freeform-fabricated core composite articles using freeform-fabricated machine. The articles are capable of being utilized as end products rather than prototype models by creating a core having an interior structure to provide strength to the core and to enhance the strength to weight ratio of the article. cross-sectional area proximate the first surface. 6. A forming receptacle as in claim 1 wherein said apertures comprise aperture walls extending generally perpendicular to the first surface, from loci adjacent the first surface, to interior loci between the first surface and the second surface, and tapering generally outwardly from the interior loci to the second major surface, whereby open areas defined by the respective apertures at the second major surface are greater than open areas defined by respective ones of such apertures at the first major surface. 7. A forming receptacle as in claim 1 wherein said aperture walls taper inwardly from the first major surface and toward the second major surface, to a throat zone, and taper outwardly from the throat zone to the second major surface, such that the throat zone defines an opening smaller in cross-sectional area than corresponding openings defined by the respective aperture at either of the first or second major surfaces. 8. A forming receptacle as in claim 2 wherein a respective aperture defines an opening at the first major surface, the opening having an open area corresponding to the area of a circle having a diameter of at least about 0.009 inch, up to about 0.040 inch. 9. A forming receptacle as in claim 2 wherein a respective aperture defines an opening at the first major surface, the opening having an open area corresponding to the area of a circle having a diameter of at least about 0.010 inch, up to about 0.025 inch. 10. A forming receptacle as in claim 2 wherein a respective aperture defines an opening at the first major surface, the opening having an open area corresponding to the area of a circle having a diameter of at least about 0.011 inch, up to about 0.015 inch. 11. A forming receptacle as in claim 2 wherein said matrix of sheet material at the first major surface generally has a minimum projected width between respective ones of the apertures of about 0.003 inch to about 0.015 inch. 12. A forming receptacle as in claim 8 wherein aperture walls of adjacent ones of the apertures intersect the second major surface without intersecting each other and wherein such aperture walls of adjacent first and second ones of the apertures define nominal distances therebetween without intersecting each other. 13. A forming receptacle as in claim 12 wherein said matrix of sheet material at the second major surface generally has a minimum width between respective ones of the apertures of about 0.0007 inch up to about 0.004 inch. 14. A forming receptacle as in claim 1 wherein the array of apertures is arranged in a series of parallel rows of apertures, wherein spacing between apertures in a given row is substantially constant from row to row. and wherein the rows are displaced laterally with respect to each other such that adjacent apertures in adjacent rows define angles of about 50 degrees to about 70 degrees with respect to an imaginary line parallel to the rows. 15. A forming receptacle as in claim 1 wherein the array of apertures is arranged in a series of parallel rows of apertures, wherein spacing between apertures in a given row is constant from row to row, and wherein the rows are displaced laterally with respect to each other such that adjacent apertures in adjacent rows define angles of about 80 degrees to about 90 degrees with respect to an imaginary line parallel to the rows. 16. A forming receptacle as in claim 1 wherein the array of apertures is arranged sporadically, wherein spacing and orientation between apertures in a given row is substantially variable. 17. A forming receptacle as in claim 2 wherein said sheet material defines a bottom wall of said receptacle and a side wall of said receptacle extending upwardly from said bottom wall, wherein said apertures, measured at a smallest cross-section of opening defined by each such aperture, in combination define a composite open area representing at least about 35 percent of the combined areas of said bottom w all and said side wall. 18. A forming receptacle as in claim 17 wherein said bottom wall and said side wall, in conjunction, comprise a particulate receiving cavity having a depth of at least about 0.001 inch to about 2.00 inches. 19. A forming receptacle as in claim 17 wherein said bottom wall and said side wall, in conjunction, comprise a particulate receiving cavity having a depth of about 0.00 inch. 20. A forming receptacle as in claim 1 wherein thickness of said sheet material is about 0.003 inch to about 0.030 inch. 21. A forming receptacle as in claim 1 wherein structures of the apertures reflect photochemical machining. 22. A forming receptacle as in claim 1 wherein the length of said receptacle is about 10 inches to about 30 inches. 23. A forming drum designed and configured to form, in a continuous process, particulate congregates for use as absorbent cores in personal care absorbent articles, said forming drum comprising mounting structure for mounting said forming drum about an axis of rotation, and forming receptacle repositories extending about at least a portion of a circumference of said forming drum and supported from said mounting structure, the forming receptacle repositories including ones of forming receptacles of claim 1 mounted about the circumference of said drum, said forming receptacles being effective to receive and accumulate thereon elongate fibers, and particles of super-absorbent material, thereby to form such congregates. 24. A forming drum designed and configured to form, in a continuous process, particulate congregates for use as absorbent cores in personal care absorbent articles, said forming drum comprising mounting structure for mounting said forming drum about an axis of rotation, and forming receptacle repositories extending about at least a portion of a circumference of said forming drum and supported from said mounting structure, the forming receptacle repositories including ones of forming receptacles of claim 2 mounted about the circumference of said drum, said forming receptacles being effective to receive and accumulate thereon elongate fibers, and particles of super-absorbent material, thereby to form such congregates. 25. A forming drum designed and configured to form, in a continuous process, particulate congregates for use as absorbent cores in personal care absorbent articles, said forming drum comprising mounting structure for mounting said forming drum about an axis of rotation, and a forming receptacle as in claim 1, said forming receptacle being uniform and continuous, and extending about substantially an entire circumference of said forming drum and supported from said mounting structure, said forming receptacle being effective to receive and accumulate thereon elongate fibers, and particles of super-absorbent material, thereby to form such congregates. 26. A forming receptacle adapted and configured to receive particulate material thereon, including super-absorbent particles, for thereby fabricating particulate congregates for use as absorbent cores in personal care absorbent articles, said forming receptacle comprising a substrate which defines a particulate-receiving cavity in said receptacle, said substrate comprising elements defining a first major side disposed toward the cavity, an opposing second major side disposed away from the cavity, and a thickness between the first and second major sides, and an array of apertures extending through at least a portion of said substrate, and connecting said first and second major sides, aperture walls defining cross-sectional areas of such apertures along the thickness of said substrate, including a locus defining a smallest cross-sectional area, and a locus defining a relatively larger cross-sectional area displaced from the smallest cross-sectional area and disposed toward the second major side of said substrate. 27. A forming receptacle as in claim 26 wherein the aperture walls extend from the first major side to the second major side, and wherein respective said aperture walls taper generally outwardly between the first major side and the second major side. 28. A forming receptacle as in claim 26, the aperture walls defining cross-sectional areas of such apertures along the thickness of said substrate, including a first locus defining a smallest cross-sectional area, and a second locus defining a relatively larger cross-sectional area displaced from the smallest cross-sectional area and disposed, from the first locus, toward the second major side of said substrate. 29. A forming receptacle as in claim 28 wherein the smallest cross-sectional area is displaced from and between both of the first and second sides. 30. A forming receptacle as in claim 26, said aperture walls defining cross-sectional areas proximate the first and second sides, the cross-sectional area of a given aperture, proximate the second side, being greater than the cross-sectional area proximate the first side. 31. A forming receptacle as in claim 26 wherein said aperture walls extend generally perpendicular to the first side, from loci adjacent the first side, to interior loci between the first side and the second side, and taper generally outwardly from the interior loci to the second major side, whereby open areas defined by the respective apertures at the second major side are greater than open areas defined by respective ones of such apertures at the first major side. 32. A forming receptacle as in claim 26 wherein said aperture walls taper inwardly from the first major side and toward the second major side, to a throat zone, and taper outwardly from the throat zone to the second major side, such that the throat zone defines an opening smaller in cross-sectional area than corresponding openings defined by the respective aperture at either of the first or second major sides. 33. A forming receptacle as in claim 27 wherein a respective aperture defines an open area at the first major side corresponding to the area of a circle having a diameter of at least about 0.009 inch, up to about 0.040 inch. 34. A forming receptacle as in claim 27 further comprising a matrix of said substrate between respective ones of the apertures and defining outer perimeters of respective ones of the apertures, wherein matrix of substrate at the first major side generally has a minimum projected width between respective ones of the apertures of about 0.003 inch to about 0.015 inch. 35. A forming receptacle as in claim 33 wherein aperture walls of adjacent ones of the apertures intersect the second major side without intersecting each other and wherein such aperture walls of adjacent first and second ones of the apertures define a nominal distance therebetween without intersecting each other. 36. A forming receptacle as in claim 35 further comprising a matrix of said substrate between respective ones of the apertures and defining outer perimeters of respective ones of the apertures, wherein said matrix of substrate at the second major side generally has a minimum width between respective ones of the apertures of about 0.0007 inch, up to about 0.004 inch. 37. A forming receptacle as in claim 26 wherein the array of apertures is arranged in a series of parallel rows of apertures, wherein spacing between apertures in a given row is substantially constant from row to row, and wherein the rows are displaced laterally with respect to each other such that adjacent apertures in adjacent rows define angles of about 50 degrees to about 90 degrees with respect to an imaginary line parallel to the rows. 38. A forming receptacle as in claim 27 wherein said substrate defines a bottom wall of said receptacle and a side wall of said receptacle extending upwardly from said bottom wall, wherein said apertures, measured at a smallest cross-section of opening defined by each such aperture, in combination define a composite open area representing at least about 35 percent of the combined areas of said bottom wall and sai d side wall. 39. A forming receptacle as in claim 27 wherein thickness of said substrate is about 0.003 inch to about 0.030 inch. 40. A forming receptacle as in claim 26 wherein structures of the apertures reflect photochemical machining. 41. A forming drum designed and configured to form, in a continuous process, particulate congregates for use as absorbent cores in personal care absorbent articles, said forming drum comprising mounting structure for mounting said forming drum about an axis of rotation, and forming receptacle repositories extending about a circumference of said forming drum and supported from said mounting structure, the forming receptacle repositories including ones of forming receptacles of claim 26 mounted about the circumference of said drum, said forming receptacles being effective to receive and accumulate thereon elongate fibers, and particles of super-absorbent material, thereby to form such congregates. 42. A method for forming a congregate of particulate material for use as an absorbent core in an absorbent article, wherein the particulate material comprises particles of super-absorbent material, the method comprising: (a) conveying the particulate material in a gaseous carrier toward a forming receptacle, the forming receptacle comprising sheet material defining a particulate-receiving cavity in the receptacle, the sheet material having a first major surface disposed toward the cavity, an opposing second major surface disposed away from the cavity, a thickness between the first and second major surfaces, and an array of apertures extending through at least a portion of the sheet material and defining passage ways between the first and second major surfaces, the passage ways being defined by aperture walls which taper generally outwardly from central axes of the respective passage ways, and from proximate the first major surface toward the second major surface, whereby the passage ways tend to generally progressively expand in cross-sectional area as one progresses toward the second major surface, and wherein projected areas of the particles of the super-absorbent material are generally larger than projected areas of the apertures; and (b) receiving and collecting particles of the particulate material in the cavity and thereby forming the congregate while generally not conveying particles of the super-absorbent material into the passage ways, and whereby undersize particles of super-absorbent material which do enter respective ones of the passage ways tend to pass entirely through the passage ways and not become lodged in such passage ways because of being released to pass through such passage ways, by the generally progressively expanding cross-sections of such passage ways along the direction of travel of such particles. 43. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein the projected area of a respective such aperture is defined by a relatively more constrictive throat zone of the respective passage way, the throat zone being disposed closer to the first major surface than to the second major surface. 44. A method as in claim 43, the method comprising receiving and collecting the particles on a such forming receptacle wherein a projection of the throat zone is no more than 25 percent smaller in cross-sectional area than a projection of the respective aperture at the first surface. 45. A method as in claim 43, the method comprising receiving and collecting the particles on a such forming receptacle wherein a projection of the throat zone is no more than 15 percent smaller in cross-sectional area than a projection of the respective aperture at the first surface. 46. A method as in claim 43, the method comprising receiving and collecting the particles on a such forming receptacle wherein a projection of the throat zone is substantially the same size in cross-sectional area as a projection of the respective aperture at the first surface. 47. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein a respective aperture defines an opening at the first major surface, the opening having an open area corresponding to the area of a circle having a diameter of at least about 0.009 inch and 0.040 inch. 48. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein the matrix of sheet material generally defines a minimum projected width between respective ones of the apertures of about 0.003 inch to about 0.015 inch. 49. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein aperture walls of adjacent ones of the apertures intersect the second major surface without intersecting each other and wherein such aperture walls of adjacent first and second ones of the apertures define a nominal distance therebetween without intersecting each other. 50. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein the array of apertures is arranged in a series of parallel rows of apertures, wherein spacing between apertures in a given row is substantially constant from row to row, and wherein the rows are displaced laterally with respect to each other such that adjacent apertures in adjacent rows define angles of about 50 degrees to about 90 degrees with respect to an imaginary line parallel to the rows. 51. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein the apertures, measured at a smallest cross-section of opening defined by each such aperture, in combination define a composite open area representing at least about 35 percent of the combined areas of the bottom wall and the side wall. 52. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein the super-absorbent material is generally spherically-shaped. 53. A method as in claim 42, the method comprising receiving and collecting the particles on a such forming receptacle wherein the particles of super-absorbent material are generally oblong-shaped, having a length-to-width ratio of no more than 4/1. rding to claim 22, which includes the loading port comprising a cassette and/or an inspection unit. 24. The semiconductor processing apparatus according to claim 22, wherein the atmospheric transport unit comprises: a slot and an arm shaft for collectively transferring multiple substrates; an elevating/descending shaft; and a rotating shaft for transferring substrates between the loading port and the