Base material for artificial leather and process for producing the same

What is claimed is: 1. A substrate, comprising a nonwoven fabric comprising bundles of microfine filaments, wherein the nonwoven fabric is obtained by removing a sea component from sea-island filaments to convert the sea-island filaments to the bundles of the microfine filaments, such that: (1) each bundle of microfine filaments comprises 8 to 70 microfine filaments having a nearly circular cross-sectional shape; (2) each bundle of microfine filaments has a cross-sectional area of 170 to 700 μm 2 and a flatness of less than 3.0; (3) on a cross section parallel to a thickness direction of the nonwoven fabric, the number of bundles per area is 1500 to 3000/mm 2 ; (4) on a cross section parallel to a thickness direction of the nonwoven fabric, gaps between the bundles of microfine filaments have a size of 70 μm or less. 2. The substrate of claim 1 , wherein on a cross section parallel to a thickness direction of the nonwoven fabric body, an average size of gaps between the bundles of microfine filaments in a region from a surface to a depth of 200 μm is 10 to 40 μm. 3. The substrate of claim 2 , further comprising an elastic polymer. 4. A nap-finished artificial leather obtained by napping a surface of the substrate of claim 3 . 5. A nap-finished artificial leather obtained by napping a surface of the substrate of claim 2 . 6. The substrate of claim 1 , further comprising an elastic polymer. 7. A nap-finished artificial leather obtained by napping a surface of the substrate of claim 6 . 8. A nap-finished artificial leather obtained by napping a surface of the substrate of claim 1 . 9. The substrate of claim 1 , wherein the microfine filaments comprise a heat-shrinkable polymer. 10. A method of producing the substrate of claim 1 , the method comprising, sequentially (a) to (d): (a) melt-spinning sea-island filaments having an island number of 8 to 70, a sea/island cross-sectional area ratio of 5:95 to 60:40 and a cross-sectional area of 70 to 350 μm 2 with a heat-shrinkable polymer as an island component and a water-soluble polymer as a sea component, and collecting the sea-island filaments, which have been spun, on a collecting surface in random orientations without cutting, thereby producing a sheet-form web of filaments; (b) after optionally superposing the web of filaments in layers, needle-punching the web of filaments from both sides thereof with at least needles with six barbs while allowing at least one barb to penetrate through the web of filaments, thereby three-dimensionally entangling the sea-island filaments to produce a nonwoven fabric body; (c) moist heat-treating the nonwoven fabric body to plasticize the sea component polymer and allow the heat-shrinkable polymer to shrink and then optionally pressing the nonwoven fabric under dry heating, thereby densifying the nonwoven fabric such that cross sections of the sea-island filaments exist 1000 to 3500/mm 2 on a cross section parallel to a thickness direction of the nonwoven fabric body; and (d) removing the sea component from the sea-island filaments with water or an aqueous solution, thereby converting the sea-island filaments to bundles of microfine filaments. 11. The method of claim 10 , further comprising, sequentially, (e) to (h) after (d): (e) applying a solution, aqueous dispersion, or melt, of an easily extractable polymer on at least one surface of the nonwoven fabric body and then coagulating the easily extractable polymer; (f) applying an aqueous dispersion of an elastic polymer on the same surface as the at least one surface of the nonwoven fabric body and then coagulating the elastic polymer; (g) removing the easily extractable polymer from the nonwoven fabric body; and (h) grinding the at least one surface applied with the elastic polymer under pressure to densify the nonwoven fabric body such that gaps between the bundles of microfine filaments in a region from the ground surface to a depth of 200 μm on a cross section of the nonwoven fabric body parallel to its thickness direction have a size of 10 to 40 μm in average. 12. The method of claim 11 , further comprising (i) before or after (d): impregnating a solution or aqueous dispersion of an elastic polymer into the nonwoven fabric and then coagulating the elastic polymer. 13. The method of claim 10 , further comprising (i) before or after (d); (i) impregnating a solution or aqueous dispersion of an elastic polymer into the nonwoven fabric and then coagulating the elastic polymer.