Method for producing V-ribbed belt

What is claimed is: 1. A method for producing a V-ribbed belt including a compressed rubber layer which forms an inner peripheral portion of the V-ribbed belt in a thickness direction of the V-ribbed belt, and which has a plurality of V-shaped ribs extending in a longitudinal direction of the V-ribbed belt and arranged in a width direction of the V-ribbed belt, the plurality of V-shaped ribs having a friction drive surface covered with a surface rubber layer, the method comprising: preparing a surface rubber sheet which is to constitute the surface rubber layer; setting a shaped structure and the surface rubber sheet in a belt mold such that the shaped structure and the surface rubber sheet are respectively positioned inside and outside with respect to each other, the shaped structure having a cylindrical shape, being made of an uncrosslinked rubber composition, and including, on an outer peripheral surface thereof, a plurality of ridges which have been formed in advance, extend in a circumferential direction, and are arranged adjacent to one another in an axial direction of the shaped structure, the belt mold including a plurality of compressed rubber layer-shaping grooves arranged in a groove width direction; molding a cylindrical belt slab by crosslinking the shaped structure set in the belt mold through heating and pressing the shaped structure toward the belt mold, while each of compressed rubber layer-forming portions is fitted in an associated one of the compressed rubber layer-shaping grooves of the belt mold, the compressed rubber layer-forming portions being comprised of the plurality of ridges, of the shaped structure, each covered with the surface rubber sheet and together forming the compressed rubber layer, the crosslinking involving integration of the shaped structure with the surface rubber sheet; and cutting the belt slab into ring-shaped pieces each including two or more of the plurality of compressed rubber layer-forming portions that are to constitute the plurality of V-shaped ribs. 2. The method of claim 1 , wherein the belt mold has a cylindrical shape having, on an inner peripheral surface thereof, the plurality of compressed rubber layer-shaping grooves extending in a circumferential direction and arranged adjacent to one another in an axial direction of the belt mold, and the shaped structure is placed in the belt mold. 3. The method of claim 1 , wherein prior to the setting the shaped structure and the surface rubber sheet in the belt mold, the ridges are covered with the surface rubber sheet, thereby forming the compressed rubber layer-forming portions. 4. The method of claim 3 , wherein before the ridges are covered with the surface rubber sheet, the surface rubber sheet is shaped to have a corrugated cross section having same pitches as those of the ridges, and then, disposed such that portions of the surface rubber sheet protruding toward the ridges are positioned at grooves between the ridges. 5. The method of claim 4 , wherein the surface rubber sheet which originally has a flat shape is continuously passed between a pair of plate-shaped or rolled members configured to pleat the surface rubber sheet, so that pitches of the surface rubber sheet pleated gradually decrease in a length direction. 6. The method of claim 3 , wherein before the ridges are covered with the surface rubber sheet, the surface rubber sheet is shaped to fit surfaces of the ridges. 7. The method of claim 1 , wherein the setting the shaped structure and the surface rubber sheet in the belt mold is carried out such that the compressed rubber layer-forming portions are fitted in the compressed rubber layer-shaping grooves. 8. The method of claim 2 , wherein the shaped structure is pressed toward the belt mold by expanding an expansion sleeve disposed inward of the shaped structure and by causing the expansion sleeve to press the shaped structure from inside. 9. The method of claim 8 , wherein a tensile member is provided between the shaped structure and the expansion sleeve, the tensile member being comprised of an uncrosslinked rubber composition formed into a cylindrical shape and having a cord embedded therein and forming a helical pattern with pitches in an axial direction of the tensile member. 10. The method of claim 9 , wherein the tensile member is provided on the expansion sleeve before the expansion sleeve is expanded. 11. The method of claim 9 , wherein a gap is provided between the tensile member and the expansion sleeve before the expansion sleeve is expanded. 12. The method of claim 10 , wherein the shaped structure and the tensile member are brought into contact with each other before the expansion sleeve is expanded. 13. The method of claim 10 , wherein a gap is provided between the shaped structure and the tensile member before the expansion sleeve is expanded. 14. A method for producing a V-ribbed belt including a compressed rubber layer which forms an inner peripheral portion of the V-ribbed belt in a thickness direction of the V-ribbed belt, and which has a plurality of V-shaped ribs extending in a longitudinal direction of the V-ribbed belt and arranged in a width direction of the V-ribbed belt, the plurality of V-shaped ribs having a friction drive surface covered with a surface rubber layer, the method comprising: setting a shaped structure and a surface rubber sheet which is to constitute the surface rubber layer in a belt mold such that the shaped structure and the surface rubber sheet are respectively positioned inside and outside with respect to each other, the shaped structure having a cylindrical shape, being made of an uncrosslinked rubber composition, including, on an outer peripheral surface thereof, a plurality of ridges extending in a circumferential direction and arranged adjacent to each other in an axial direction of the shaped structure, the belt mold including a plurality of compressed rubber layer-shaping grooves arranged in a groove width direction; molding a cylindrical belt slab by crosslinking the shaped structure set in the belt mold through heating and pressing the shaped structure toward the belt mold, while each of compressed rubber layer-forming portions is fitted in an associated one of the compressed rubber layer-shaping grooves of the belt mold, the compressed rubber layer-forming portions being comprised of the plurality of ridges, of the shaped structure, each covered with the surface rubber sheet and together forming the compressed rubber layer, the crosslinking involving integration of the shaped structure with the surface rubber sheet; and cutting the belt slab into ring-shaped pieces each including two or more of the plurality of compressed rubber layer-forming portions that are to constitute the plurality of V-shaped ribs, wherein prior to setting the shaped structure and the surface rubber sheet in the belt mold, the ridges are covered with the surface rubber sheet, thereby forming the compressed rubber layer-forming portions, before the ridges are covered with the surface rubber sheet, the surface rubber sheet is shaped to have a corrugated cross section having same pitches as those of the ridges, and then, disposed such that portions of the surface rubber sheet protruding toward the ridges are positioned at grooves between the ridges, and the surface rubber sheet which originally has a flat shape is continuously passed between a pair of plate-shaped or rolled members configured to pleat the surface rubber sheet, so that pitches of the surface rubber sheet pleated gradually decrease in a length direction. 15. The method of claim 2