Method for producing acetic acid

The invention claimed is: 1. A method for producing acetic acid, the method comprising the steps of: (A) carbonylating methanol with carbon monoxide in a reactor in the presence of a catalytic system, acetic acid, methyl acetate, and water, to form acetic acid in a reaction mixture, the catalytic system including a metal catalyst and methyl iodide; (B) separating the reaction mixture, using at least one selected from evaporators and distillation columns, into: a stream including the metal catalyst; an acetic acid stream rich in acetic acid; and a stream richer in light ends than the acetic acid stream; (C) liquid-liquid separating a process stream including water, acetic acid, methyl iodide, and acetaldehyde into: an aqueous phase; and an organic phase; (D) removing acetaldehyde derived from the process stream by a treatment of an object, the object being selected from at least a part of at least one of the aqueous phase and the organic phase based on a factor or factors selected from the group consisting of: a liquid temperature in the liquid-liquid separation in the liquid-liquid separation step (C); an acetaldehyde concentration in at least one of the aqueous phase and the organic phase; an acetaldehyde partition coefficient; a methyl acetate concentration in at least one of the aqueous phase and the organic phase; and a methyl acetate partition coefficient; (E) recycling at least a part of at least one of the aqueous phase and the organic phase to the reactor; and (F) removing crotonaldehyde from at least another part of at least one of the aqueous phase and the organic phase by a distillation treatment in a distillation column, wherein the separation step (B) comprises the substep of (B′) yielding, by separation using a first distillation column: a first acetic acid stream rich in acetic acid; and an overhead stream richer in light ends than the first acetic acid stream, wherein, in the substep (B′), a crotonaldehyde concentration in the first acetic acid stream is controlled to 2.2 ppm by mass or less, wherein a reflux ratio at the first distillation column in the separation step (B) is controlled so that: the reflux ratio for the aqueous phase is 2 or more when the aqueous phase alone is refluxed to the first distillation column; the reflux ratio for the organic phase is 1 or more when the organic phase alone is refluxed to the first distillation column; and the total reflux ratio for the aqueous phase and the organic phase is 1.5 or more when both the aqueous phase and the organic phase are refluxed to the first distillation column, and wherein the distillation column in the crotonaldehyde-removing step (F) is operated so as to meet at least one of conditions (a-i), (a-ii), and (a-iii) as follows: (a-i) a reflux ratio at the distillation column is 0.01 or more; (a-ii) at the distillation column, a ratio of a crotonaldehyde concentration (ppm by mass) in a distillate to a crotonaldehyde concentration (ppm by mass) in a charge liquid is less than 1; (a-iii) at the distillation column, a ratio of a crotonaldehyde concentration (ppm by mass) in bottoms to a crotonaldehyde concentration (ppm by mass) in the charge liquid is greater than 1, and wherein the liquid-liquid separation step (C) meets at least one of conditions (b-i), (b-ii), (b-iii), (b-iv), and (b-v), and at least a part of the aqueous phase is subjected to the treatment in the acetaldehyde-removing step (D), where the conditions (b-i), (b-ii), (b-iii), (b-iv), and (b-v) are expressed as follows: (b-i) the aqueous phase has an acetaldehyde concentration of 28.1 mass percent or less, and/or the organic phase has an acetaldehyde concentration of 24.8 mass percent or less; (b-ii) the liquid-liquid separation is performed at a temperature of 70° C. or lower; (b-iii) the aqueous phase has a methyl acetate concentration of 12.0 mass percent or less, and/or the organic phase has a methyl acetate concentration of 47.6 mass percent or less, and/or the totality of the methyl acetate concentration in the aqueous phase and the methyl acetate concentration in the organic phase is 59.6 mass percent or less; (b-iv) an acetaldehyde partition coefficient is 1.1 or more, where the acetaldehyde partition coefficient is a ratio of the acetaldehyde concentration (mass percent) in the aqueous phase to the acetaldehyde concentration (mass percent) in the organic phase; and (b-v) a methyl acetate partition coefficient is 0.25 or more, where the methyl acetate partition coefficient is a ratio of the methyl acetate concentration (mass percent) in the aqueous phase to the methyl acetate concentration (mass percent) in the organic phase, or wherein the liquid-liquid separation step (C) meets at least one of conditions (b′-i), (b′-ii), (b′-iii), (b′-iv), and (b′-v), and at least a part of the organic phase is subjected to the treatment in the acetaldehyde-removing step (D), where the conditions (b′-i), (b′-ii), (b′-iii), (b′-iv), and (b′-v) are expressed as follows: (b′-i) the aqueous phase has an acetaldehyde concentration of 0.045 mass percent or more, and/or the organic phase has an acetaldehyde concentration of 0.013 mass percent or more; (b′-ii) the liquid-liquid separation is performed at a temperature of −5° C. or higher; (b′-iii) the aqueous phase has a methyl acetate concentration of 1.2 mass percent or more, and/or the organic phase has a methyl acetate concentration of 2.2 mass percent or more, and/or the totality of the methyl acetate concentration in the aqueous phase and the methyl acetate concentration in the organic phase is 3.4 mass percent or more; (b′-iv) an acetaldehyde partition coefficient is 4.1 or less, where the acetaldehyde partition coefficient is a ratio of the acetaldehyde concentration (mass percent) in the aqueous phase to the acetaldehyde concentration (mass percent) in the organic phase; and (b′-v) a methyl acetate partition coefficient is 0.8 or less, where the methyl acetate partition coefficient is a ratio of the methyl acetate concentration (mass percent) in the aqueous phase to the methyl acetate concentration (mass percent) in the organic phase. 2. A method for producing acetic acid, the method comprising the steps of: (A) carbonylating methanol with carbon monoxide in a reactor in the presence of a catalytic system, acetic acid, methyl acetate, and water, to form acetic acid in a reaction mixture, the catalytic system including a metal catalyst and methyl iodide; (B) separating the reaction mixture, using at least one selected from evaporators and distillation columns, into: a stream including the metal catalyst; an acetic acid stream rich in acetic acid; and a stream richer in light ends than the acetic acid stream; (C) liquid-liquid separating a process stream including water, acetic acid, methyl iodide, and acetaldehyde into: an aqueous phase; and an organic phase; (D) removing acetaldehyde derived from the process stream by a treatment of an object, the object being selected from at least a part of at least one of the aqueous phase and the organic phase based on a factor or factors selected from the group consisting of: a liquid temperature in the liquid-liquid separation in the liquid-liquid separation step (C); an acetaldehyde concentration in at least one of the aqueous phase and the organic phase; an acetaldehyde partition coefficient; a methyl acetate concentration in at least one of the aqueous phase and the organic phase; and a methyl acetate partition coefficient; (E) recycling at least a part of at least one of the aqueous phase and the organic phase to the reactor; and (F) removing crotonaldehyde from at least another part of at least one of the aqueous phase and the organic phase by a distillation treatment in a distillation column, wherein the separation step (B) comprises the steps of: (B″) yielding, by s