Method for recovering valuable metals from waste lithium ion batteries

1 . A method for recovering valuable metals from a waste lithium ion battery, the method comprising: a pre-heating step of heating the waste lithium ion battery at a temperature equal to or greater than 700° C. under presence of an oxidant; a melting step of melting the waste lithium ion battery after being heated so as to obtain a molten material; and a slag separation step of separating slag from the molten material so as to recover an alloy including the valuable metals, wherein in the melting step, a reducing agent including a carbon atom is added, a flux containing a calcium compound is used under presence of the reducing agent, the flux is added to the waste lithium ion battery such that a mass ratio of silicon dioxide to calcium oxide in the slag is equal to or less than 0.50 and that a mass ratio of calcium oxide to aluminum oxide is equal to or greater than 0.30 and equal to or less than 2.00 and the melting is performed. 2 . The method for recovering valuable metals according to claim 1 , wherein the valuable metals are one or more types selected from at least cobalt, nickel, and copper. 3 . The method for recovering valuable metals according to claim 1 , wherein a heating temperature in the melting step is equal to or greater than 1300° C. and equal to or less than 1500° C. 4 . The method for recovering valuable metals according to claim 1 , wherein a phosphorus grade in the alloy recovered in the slag separation step is less than 0.1% by mass. 5 . The method for recovering valuable metals according to claim 1 , wherein calcium carbonate is used as the calcium compound. 6 . The method for recovering valuable metals according to claim 2 , wherein a heating temperature in the melting step is equal to or greater than 1300° C. and equal to or less than 1500° C. 7 . The method for recovering valuable metals according to claim 2 , wherein a phosphorus grade in the alloy recovered in the slag separation step is less than 0.1% by mass. 8 . The method for recovering valuable metals according to claim 3 , wherein a phosphorus grade in the alloy recovered in the slag separation step is less than 0.1% by mass. 9 . The method for recovering valuable metals according to claim 6 , wherein a phosphorus grade in the alloy recovered in the slag separation step is less than 0.1% by mass. 10 . The method for recovering valuable metals according to claim 2 , wherein calcium carbonate is used as the calcium compound. 11 . The method for recovering valuable metals according to claim 3 , wherein calcium carbonate is used as the calcium compound. 12 . The method for recovering valuable metals according to claim 4 , wherein calcium carbonate is used as the calcium compound. 13 . The method for recovering valuable metals according to claim 6 , wherein calcium carbonate is used as the calcium compound. 14 . The method for recovering valuable metals according to claim 7 , wherein calcium carbonate is used as the calcium compound. 15 . The method for recovering valuable metals according to claim 8 , wherein calcium carbonate is used as the calcium compound. 16 . The method for recovering valuable metals according to claim 9 , wherein calcium carbonate is used as the calcium compound.