Apparatus for electrospinning liquid polymer into nanoscale or submicron scale fibers

That which is claimed is: 1. An apparatus for continuous needleless electrospinning of a liquid polymer source into a nanoscale or submicron scale polymer fiber web, the apparatus comprising: a. an electrospinning enclosure comprising: one or more liquid polymer coating devices; an electrospinning zone comprising an electrically conductive ground plate; and a wire cleaning assembly; b. a wire drive system located external to the electrospinning enclosure; c. a plurality of continuous electrode wires, the plurality of continuous electrode wires being parallel to each other, engaged with the wire drive system, and extending through the electrospinning enclosure and the one or more liquid polymer coating devices located therein, wherein the one or more liquid polymer coating devices comprise at least one liquid polymer coating manifold, wherein the at least one liquid polymer coating manifold feeds the liquid polymer to the plurality of continuous electrode wires; d. a substrate conveyor system located external to the electrospinning enclosure; and e. one or more high voltage power supply units, wherein the one or more liquid polymer coating devices coat a layer of liquid polymer onto a surface of the plurality of continuous electrode wires, the one or more high voltage power supply units apply high voltage to the plurality of continuous electrode wires and generate an electrical field between the plurality of continuous electrode wires and the electrically conductive ground plate in the electrospinning zone, forming nanoscale or submicron scale polymer fibers from the liquid polymer coated onto the surface of the plurality of continuous electrode wires, the wire cleaning assembly comprises a solvent for cleaning residual liquid polymer from the plurality of continuous electrode wires, and the substrate conveyor system drives a substrate through the electrospinning enclosure and collects the nanoscale or submicron scale polymer fibers on the substrate as a polymer fiber web. 2. The apparatus according to claim 1 , further comprising a liquid polymer recycle and feed system, wherein the liquid polymer recycle and feed system receives overflow liquid polymer from and provides fresh liquid polymer to the one or more liquid polymer coating devices; and at least one liquid polymer overflow reservoir, wherein the at least one liquid polymer overflow reservoir receives overflow liquid polymer from the one or more liquid polymer coating devices and returns the overflow liquid polymer to the liquid polymer recycle and feed system. 3. The apparatus according to claim 1 , further comprising a draft gas supply system comprising a draft gas source and a draft gas distribution manifold, wherein the draft gas distribution manifold receives draft gas from the draft gas source and blows the draft gas onto the plurality of continuous electrode wires in the electrospinning zone to facilitate collection of the nanoscale or submicron scale polymer fibers on the substrate. 4. The apparatus according to claim 1 , further comprising a primary drying region comprising a primary distribution manifold, wherein the primary distribution manifold distributes primary drying gas to the substrate and polymer fiber web formed thereon to facilitate drying thereof. 5. The apparatus according to claim 4 , further comprising a secondary drying region comprising a secondary distribution manifold, wherein the secondary distribution manifold distributes secondary drying gas to the substrate and polymer fiber web formed thereon to facilitate drying thereof. 6. The apparatus according to claim 1 , further comprising at least one emission control box located proximate the electrospinning enclosure, the at least one emission control box comprising openings for one or more of the plurality of continuous electrode wires and the substrate to enter or exit the electrospinning enclosure. 7. The apparatus according to claim 1 , wherein the at least one liquid polymer coating manifold for coating a layer of liquid polymer on the surface of the plurality of continuous electrode wires comprises a plurality of wire inlet apertures and a plurality of wire outlet apertures; and wherein the one or more liquid polymer coating devices ( 400 ) further comprise: a liquid polymer overflow reservoir to receive liquid polymer overflow from the at least one liquid polymer coating manifold; and at least one set of wire positioning pulleys that guide the plurality of continuous electrode wires through the plurality of wire inlet apertures and the plurality of wire outlet apertures. 8. The apparatus according to claim 7 , wherein each of the plurality of wire inlet apertures aligns with one of the plurality of wire outlet apertures so as to allow one of the plurality of continuous electrode wires to pass therethrough. 9. The apparatus according to claim 7 , wherein each of the plurality of wire inlet apertures and the plurality of wire outlet apertures comprises a capillary tube, wherein the capillary tube guides one of the plurality of continuous electrode wires through the at least one liquid polymer coating manifold so as to allow the liquid polymer to coat the one continuous electrode wire within the at least one liquid polymer coating manifold and minimize leakage of liquid polymer out of the at least one liquid polymer coating manifold. 10. The apparatus according to claim 7 , wherein the at least one liquid polymer coating manifold comprises a liquid polymer supply port and a liquid polymer overflow port. 11. The apparatus according to claim 10 , wherein the one or more liquid polymer coating devices comprises a liquid polymer recirculation port and the liquid polymer overflow reservoir receives liquid polymer from the liquid polymer overflow port. 12. The apparatus according to claim 1 , wherein the one or more high voltage power supply units comprises: a negative voltage source connected to the electrically conductive ground plate; and a positive voltage source connected to at least one electrically conductive freely rotating axle, wherein the at least one electrically conductive freely rotating axle is in rotating contact with the plurality of continuous electrode wires; and wherein the at least one electrically conductive freely rotating axle comprises a plurality of grooves corresponding to the number of the plurality of continuous electrode wires ( 1000 ), and each of the grooves receives one of the plurality of continuous electrode wires ( 1000 ) and maintains contact therewith so that high voltage from the one or more high voltage power supply units ( 820 ) is passed to the one continuous electrode wires. 13. The apparatus according to claim 1 , wherein the substrate conveyor system comprises: a combination roller for winding the substrate and the electrospun polymer fiber web thereon; or a fiber web roller for winding the electrospun polymer fiber web thereon and a substrate finishing roller for winding the substrate thereon. 14. The apparatus according to claim 1 , wherein the apparatus further comprises a resistance measuring system comprising, in a driving direction of the plurality of continuous electrode wires by the wire drive system, an upstream contact point located upstream of the one or more liquid polymer coating devices and a downstream contact point located downstream of the wire cleaning assembly, wherein the resistance measuring system measures electrical resistance of one or more of the plurality of continuous electrode wires between the upstream contact point and the downstream contact point, and the measured electrical resistance provides an indica