Method for recycling waste lithium ion battery, method for smart recycling waste lithium ion battery and system for smart recycling waste lithium ion battery comprising partial melt separation process for lithium alloy compound formation and graphite separation

What is claimed is: 1 . A method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation, wherein the partial melt separation process comprises: preparing a mixture of a lithium alloy compound in which lithium compounds, aluminum and copper are partially melted, a copper metal and an aluminum-copper alloy from waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases which comprise lithium compounds, aluminum, copper and graphite; and physically separating the graphite from the mixture of the lithium alloy compound, the copper metal and the aluminum-copper alloy. 2 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the method comprises adding metal powder such as aluminum powder or copper powder to the mixture to partially melt same in the process of preparing the lithium alloy compound. 3 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 2 , wherein the particle size of the metal powder such as aluminum powder or copper powder is 0.1 to 10 mm. 4 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the lithium compound is at least one selected from the group consisting of lithium iron phosphate (LiFePO 4 ), lithium nickel cobalt manganese oxide (Li(Ni,Co,Mn)O 2 ), lithium manganese oxide (LiMn 2 O 4 ), lithium nickel cobalt aluminum oxide (Li(Ni,Co,Al)O 2 ) and lithium cobalt oxide (LiCoO 2 ). 5 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the graphite is artificial graphite or natural graphite. 6 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the lithium alloy compound is at least one selected from the group consisting of aluminum-copper-lithium-iron-phosphorus-oxygen compound, aluminum-copper-lithium-cobalt-nickel-manganese-oxygen compound, aluminum-copper-lithium-cobalt-nickel-oxygen compound, aluminum-copper-manganese-oxygen compound, and aluminum-copper-lithium-cobalt-oxygen compound. 7 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the mixture of the lithium alloy compound, copper metal and aluminum-copper alloy has spherical, needle-shaped or rod-shaped porous particles, and the particle size of the mixture of the lithium alloy compound, copper metal and aluminum-copper alloy is 20 μm to 5 mm. 8 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the partial melt separation process comprises: charging waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases which comprise lithium compounds, aluminum, copper and graphite into a melting furnace to prepare a mixture of a lithium alloy compound in which the lithium compounds, aluminum and copper are partially melted, a copper metal and an aluminum-copper alloy; and separating the graphite from the mixture of the lithium alloy compound, copper metal and aluminum-copper alloy by physical methods such as gravity selection, sieving and air suspension. 9 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the separation rate of lithium is 95 to 99% by weight. 10 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the separation rate of nickel is 95 to 99% by weight. 11 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 1 , wherein the separation rate of graphite is 70 to 95% by weight. 12 . A method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation, wherein the waste lithium ion battery comprises lithium compounds, aluminum, copper and graphite, and wherein the method comprises: (a-1) preparing waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases; (a-2) charging the waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases into a melting furnace under air or an inert gas, followed by heating, to prepare a mixture of a lithium alloy compound in which lithium compounds, aluminum and copper are partially melted, a copper metal and an aluminum-copper alloy; and (a-3) separating the graphite from the mixture of the lithium alloy compound, copper metal and aluminum-copper alloy by physical methods such as gravity selection, sieving and air suspension. 13 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 12 , wherein, in the step of (a-1) preparing waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases, waste lithium ion battery cells are shredded by a jaw crusher, a cone crusher, a rod mill, a pin mill, a ball mill, a tube mill, a pot mill, a roller mill, a turbo mill or a tower mill, under an inert gas to prepare the waste lithium ion battery cell shreds, and waste lithium ion batteries are discharged in water to prepare the discharged waste lithium ion battery cells. 14 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 12 , wherein, in the step of (a-1) preparing waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases, metal powder such as aluminum powder or copper powder are added to the waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases, and the particle size of the metal powder such as aluminum powder or copper powder is 0.1 to 10 mm. 15 . The method for recycling a waste lithium ion battery, comprising a partial melt separation process for lithium alloy compound formation and graphite separation according to claim 12 , wherein, in the step of (a-2) charging the waste lithium ion battery cell shreds, discharged waste lithium ion battery cells or waste lithium ion battery cases into a melting furnace under air or an inert gas, followed by heating, to prepare a mixture of a lithium alloy compound in which lithium compounds, aluminum and copper are partially mel