Yarn from polymers having different decomposition temperatures and process for forming same

What is claimed is: 1. A yarn comprising a plurality of filaments, each of the filaments having a distinct, continuous, uniform-density sheath of a first polymer and a distinct, continuous core of a second polymer, with the sheath surrounding the core; wherein the filaments are made by extruding a first polymer solution comprising the first polymer in a solvent with a second polymer solution comprising the second polymer in the same solvent; and additionally, the first polymer solution being salt-free and the second polymer solution including at least 4 percent inorganic salt by weight, based on the amount of the salt, the second polymer and the solvent in the second solution; wherein the first polymer is a polyacrylonitrile polymer and the second polymer is an aramid polymer, the polyacrylonitrile polymer being either a copolymer consisting of acrylonitrile and vinyl chloride, or a copolymer consisting of acrylonitrile and vinylidene chloride; wherein the polyacrylonitrile polymer has a limiting oxygen index of greater than 21, or is provided with additives that increase the limiting oxygen index of the polyacrylonitrile polymer to a value of greater than 21, and the aramid polymer has an LOI of greater than 24, the polyacrylonitrile polymer further having a thermal decomposition temperature at least 50 degrees Celsius lower than the thermal decomposition temperature of the aramid polymer, wherein the inorganic salt is a chloride or bromide of calcium, lithium, magnesium or aluminum, wherein the continuous core has a solid cross section, and wherein the filament contains greater than 50 weight percent to 85 weight percent aramid polymer, based on the weight of the aramid polymer and the polyacrylonitrile polymer in each filament. 2. The yarn of claim 1 wherein the thermal decomposition temperature of the polyacrylonitrile polymer is at least 75 degrees Celsius lower than the thermal decomposition temperature of the second polymer. 3. The yarn of claim 1 wherein the aramid is poly (metaphenylene isophthalamide). 4. The yarn of claim 1 made by dry spinning the filaments. 5. The yarn of claim 1 wherein the first polymer sheath includes a dye or pigment to color the yarn. 6. The yarn of claim 5 wherein the yarn has a change in color (Delta E*) of 10 or less after 20 hours of ultraviolet light exposure. 7. A process for forming a yarn comprising filaments, each of the filaments comprising a distinct, continuous uniform-density sheath of a first polymer and a distinct, continuous core of a second polymer, with the sheath surrounding the core; wherein the first polymer is a polyacrylonitrile polymer and the second polymer is an aramid polymer, the polyacrylonitrile polymer being either a copolymer consisting of acrylonitrile and vinyl chloride, or a copolymer consisting of acrylonitrile and vinylidene chloride; wherein the polyacrylonitrile polymer has a limiting oxygen index of greater than 21, or is provided with additives that increase the limiting oxygen index of the polyacrylonitrile polymer to a value of greater than 21, and the aramid polymer has an LOI of greater than 24, the polyacrylonitrile polymer having a thermal decomposition temperature at least 50 degrees Celsius lower than a thermal decomposition temperature of the aramid polymer, the process comprising the steps of: a) forming a first polymer solution comprising the first polymer in a solvent and a second polymer solution comprising the second polymer in the same solvent; the first polymer solution being salt-free and the second polymer solution including at least 4 percent inorganic salt by weight, based on the amount of the salt, the second polymer and the solvent in the second solution, wherein the inorganic salt is a chloride or bromide of calcium, lithium, magnesium or aluminum; b) providing a spinneret assembly having separate inlets for the first polymer solution and the second polymer solution and a plurality of exit capillaries for spinning dope filaments; c) forming a plurality of dope filaments having a sheath of the first polymer solution and a core of the second polymer solution by extruding through the exit capillaries a plurality of conjoined streams of the first polymer solution and the second polymer solution into a spin cell, d) contacting the dope filaments with heated gas in the spin cell to remove solvent from the dope filaments to form reduced solvent filaments, the heated gas having a temperature such that the dope filaments remain below the thermal decomposition temperature of the first polymer in the spin cell; e) quenching the reduced solvent filaments with an aqueous liquid to cool the filaments, forming a yarn of polymer filaments; and f) further extracting solvent from the yarn of polymer filaments, wherein the continuous core has a solid cross section, and wherein the filament contains greater than 50 weight percent to 85 weight percent aramid polymer, based on the weight of the aramid polymer and the polyacrylonitrile polymer in each filament. 8. The process of claim 7 wherein the thermal decomposition temperature of the polyacrylonitrile polymer is at least 75 degrees Celsius lower than the thermal decomposition temperature of the aramid polymer. 9. The process of claim 7 wherein the first solution and the second solution are combined in the spinneret assembly and then extruded into sheath-core dope filaments through each exit capillary of the plurality of exit capillaries. 10. The process of claim 7 wherein the plurality of exit capillaries in the spinneret includes a plurality of first apertures and a plurality of second apertures; the first solution being spun through the plurality of first apertures and the second solution being spun through the plurality of second apertures to form a plurality of sheath-core dope filaments. 11. The process of claim 7 wherein the aramid is poly (metaphenylene isophthalamide).