Shim-stack foaming die

What is claimed is: 1 . A foaming die for extruding a molten foamable composition, comprising: a plurality of shims that are layered together under pressure to form a shim stack, the shims combining to collectively define a plurality of die orifices in a working face of the foaming die and to collectively define at least one die cavity that is configured to receive a molten foamable composition from an extrusion apparatus and that is fluidly connected to the die orifices. 2 . The foaming die of claim 1 wherein the shim stack is comprised of at least about twenty shims 3 . The foaming die of claim 1 wherein the shim stack is comprised of at least about two hundred shims. 4 . The foaming die of claim 1 wherein the die orifices of the plurality of die orifices are spaced in a single row along a lateral axis of the foaming die. 5 . The foaming die of claim 1 wherein the die orifices each exhibit an elongated shape with a long axis that is oriented at least substantially orthogonal to a lateral axis of the foaming die and that is at least substantially aligned with a height axis of the foaming die, and wherein the die orifices each exhibit an orifice height to orifice width aspect ratio of at least about 4:1. 6 . The foaming die of claim 1 wherein each shim of the plurality of shims exhibits a major plane that is at least substantially parallel to a thickness axis of the foaming die. 7 . The foaming die of claim 1 wherein the plurality of shims includes a first shim set of orifice shims, each orifice shim comprising at least one open-ended cutout that defines a height of a die orifice and that defines a lateral slice of the at least one die cavity; and, wherein the plurality of shims includes a second shim set of spacer shims, each of which spacer shims does not comprise an open-ended cutout that defines a height of a die orifice but does comprise at least one closed-ended cutout that defines a lateral slice of the at least one die cavity. 8 . The foaming die of claim 7 wherein at least selected orifice shims are each present as a single orifice shim between a pair of nearest-neighbor spacer shims, and wherein each selected orifice shim comprises a thickness that defines an orifice width of at least one die orifice. 9 . The foaming die of claim 7 wherein at least selected orifice shims are each present as a bundle of multiple orifice shims without a spacer shim being present between any of the orifice shims of the bundle of multiple orifice shims, and wherein a combined thickness of the orifice shims of the bundle of orifice shims defines an orifice width of at least one die orifice. 10 . The foaming die of claim 7 wherein at least selected spacer shims are each present as a single spacer shim between a pair of nearest-neighbor orifice shims, and wherein each selected spacer shim comprises a thickness that defines a lateral edge-to-edge distance between nearest lateral edges of a pair of nearest-neighbor die orifices. 11 . The foaming die of claim 7 wherein at least selected spacer shims are each present as a bundle of multiple spacer shims without an orifice shim being present between any of the spacer shims of the bundle of multiple spacer shims, and wherein a combined thickness of the spacer shims of the bundle of spacer shims defines a lateral edge-to-edge distance between nearest lateral edges of a pair of nearest-neighbor die orifices. 12 . The foaming die of claim 1 wherein the shims combine to collectively define a first set of die orifices in the working face of the foaming die and to collectively define a first die cavity that is configured to receive a first molten foamable composition from an extruder that is fluidly connected to the first set of die orifices; and, wherein the shims combine to collectively define a second set of die orifices in the working face of the foaming die and to collectively define a second die cavity that is configured to receive a second molten composition from an extruder that is fluidly connected to the second set of foaming die orifices. 13 . The foaming die of claim 12 wherein the second die cavity is configured to receive a second molten composition from a second extruder that is a different extruder than the extruder from which the first die cavity is configured to receive a first molten foamable composition; and, wherein the second molten composition is a densified molten composition. 14 . The foaming die of claim 12 wherein at least selected die orifices of the second set of die orifices are each laterally sandwiched in between a pair of die orifices of the first set of die orifices. 15 . The foaming die of claim 1 wherein the die orifices are laterally-aligned die orifices. 16 . The foaming die of claim 1 wherein the foaming die is fluidly coupled to an extrusion apparatus that comprises at least one extruder and that is configured to continuously supply a molten foamable flowstream to at least one die cavity of the foaming die. 17 . The foaming die of claim 1 wherein the plurality of shims includes a first shim set of orifice shims, each orifice shim comprising at least one open-ended cutout that defines a height of a die orifice and that defines a lateral slice of the at least one die cavity; and, wherein the at least one open-ended cutout comprises, at a terminal end of the open-ended cutout that is substantially opposite the open end of the open-ended cutout, a comb structure comprising a linear array of teeth with spaces interspersed therebetween. 18 . A method of making a unitary foam slab, the method comprising: continuously emitting molten foamable extrudate flowstreams through at least selected die orifices of the plurality of die orifices of the foaming die of claim 1 , and, allowing the molten foamable extrudate flowstreams to foam, to coalesce and to solidify as a unitary mass so as to form a unitary foam slab with a slab width and a slab thickness.