Fe-based amorphous alloy ribbon manufacturing method, Fe-based amorphous alloy ribbon manufacturing device, and wound body of Fe-based amorphous alloy ribbon

What is claimed is: 1. A method of manufacturing an Fe-based amorphous alloy ribbon, via an Fe-based amorphous alloy ribbon manufacturing device comprising: a chill roll, wherein a coated film of a molten alloy is formed on a peripheral surface of the chill roll and is cooled on the peripheral surface to form an Fe-based amorphous alloy ribbon, wherein the molten alloy is a source material for the Fe-based amorphous alloy ribbon, a molten metal nozzle configured to discharge the molten alloy toward the peripheral surface of the chill roll, a peeling means configured to peel off the Fe-based amorphous alloy ribbon from the peripheral surface of the chill roll, a wind-up roll configured to wind the Fe-based amorphous alloy ribbon that has been peeled off, and a polishing brush roll, comprising a roll axis member and a polishing brush, the polishing brush comprising a plurality of brush bristles having tips, wherein the polishing brush roll (i) is placed around the roll axis member; (ii) is provided between the peeling means and the molten metal nozzle at a periphery of the chill roll; and, (iii) is configured to polish by bringing the polishing brush into contact with the peripheral surface of the chill roll while rotating axially in a reverse direction to the chill roll; wherein a free length of the brush bristles is more than 30 mm but no more than 50 mm, and a density of the brush bristles at the brush bristle tips is more than 0.30 bristles/mm 2 but no more than 0.60 bristles/mm 2 ; the method comprising (a) forming a coated film of the molten alloy on the peripheral surface of the chill roll that has been subjected to polishing using the polishing brush roll; (b) cooling the coated film on the peripheral surface; (c) peeling off the Fe-based amorphous ribbon from the peripheral surface of the chill roll; (d) polishing the peripheral surface of the chill roll by using the polishing brush of the polishing brush roll; and, (e) winding the Fe-based amorphous alloy ribbon on the wind-up roll to obtain a wound body of the Fe-based amorphous alloy ribbon. 2. The method of claim 1 , wherein: 20 sheets of early stage alloy ribbon samples and 20 sheets of end stage alloy ribbon samples are each obtained by continuously cutting every 20 mm along a longitudinal direction to cut out sheets of samples from a range of the Fe-based amorphous alloy ribbon that has been produced continuously; each of the 20 sheets of early stage alloy ribbon sample and 20 sheets of end stage alloy ribbon sample having a strip shape wherein a width direction in the Fe-based amorphous alloy ribbon corresponds to a long side and the longitudinal direction in the Fe-based amorphous alloy ribbon corresponds to a short side; for the early stage alloy ribbon samples: (i) the range of the Fe-based amorphous alloy ribbon is produced within a time period of 5 minutes to 7 minutes after the start of production, (ii) a space factor LF [EARLY] is 87% to 94%, and (iii) WC [EARLY] , which is measured with regard to a layered body prepared by disposing 20 sheets of the early stage alloy ribbon samples one on another in layers, is from 5 μm/20 sheets to 40 μm/20 sheets; for the end stage alloy ribbon samples: (i) the range of the Fe-based amorphous alloy ribbon is 1 m from the last end formed at the time of finishing the production, (ii) a rate of change (LF [END] −LF [EARLY] )/LF [EARLY] ×100 in a space factor LF [END] in the end stage alloy ribbon samples from the space factor LF [EARLY] is 2% or less, and (iii) a rate of change (WC [END] −WC [EARLY] )/WC [EARLY] ×100 in WC [END] , which is measured with regard to a layered body prepared by disposing 20 sheets of the end stage alloy ribbon samples one on another in layers, from the WC [EARLY] is from −12% to +80%; and, to measure a wedge coefficient (WC), with regard to each of one end IB and another end OB in a long side direction in a layered body prepared by disposing, one on another in layers, 20 sheets of alloy ribbon samples each having a strip shape, the thicknesses of three points 0 mm to 16 mm from the end, 10 mm to 26 mm from the end, and 20 mm to 36 mm from the end, are measured using a micrometer employing an anvil having a diameter of 16 mm, a greater one of a difference between a maximum value IB max of one end side and a minimum value OB min of the other end side and a difference between a minimum value IB min of one end side and a maximum value OB max of the other end side is taken as WC, wherein WC measured with regard to the early stage alloy ribbon samples is taken as WC [EARLY] , and WC measured with regard to the end stage alloy ribbon samples is taken as WC [END] . 3. The method of claim 2 , wherein: the Fe-based amorphous alloy ribbon consists of Fe, Si, B, C, and impurities, and a content of Si is 1.8 atom % to 4.2 atom %, a content of B is 13.8 atom % to 16.2 atom %, and a content of C is 0.05 atom % to 0.4 atom %, wherein a total content of Fe, Si, B, C, and impurities is 100 atom %. 4. The method of claim 3 , wherein the content of Si is 2 atom % to 4 atom %, the content of B is 14 atom % to 16 atom %, and the content of C is 0.2 atom % to 0.3 atom %, wherein the total content of Fe, Si, B, C, and impurities is 100 atom %. 5. The method of claim 1 , wherein: the Fe-based amorphous alloy ribbon consists of Fe, Si, B, C, and impurities, and a content of Si is 1.8 atom % to 4.2 atom %, a content of B is 13.8 atom % to 16.2 atom %, and a content of C is 0.05 atom % to 0.4 atom %, wherein a total content of Fe, Si, B, C, and impurities is 100 atom %. 6. The method of claim 5 , wherein the content of Si is 2 atom % to 4 atom %, the content of B is 14 atom % to 16 atom %, and the content of C is 0.2 atom % to 0.3 atom %, wherein the total content of Fe, Si, B, C, and impurities is 100 atom %.