The present disclosure discloses a system for preparing new energy NiCoMn raw material from laterite nickel Ore. The system includes a raw auxiliary material supply module, a leaching reaction module, a neutralization and purification module, a neutralization and purification module, a NiCoMn mixed hydroxide synthesis module, a valuable metal recovery module, a crystal manufacturing module, a ternary precursor manufacturing module, and a ternary positive material manufacturing module. The present disclosure overcomes the defects of prior art and process, and is a green technology and process for simultaneous extraction of nickel, cobalt and manganese from low-grade laterite nickel ore, which not only realizes simultaneous and efficient extraction of nickel, cobalt and manganese, but also adopts energy-saving and emission reduction green technology and clean production technology to effectively recycle and safely dispose of waste water, waste residue and waste gas.

The present disclosure relates to an apparatus and method for selectively recovering target metals or minerals from a metal or mineral containing mixture/solution.

Provided is a method and apparatus for extracting a copper/tin source material from an oxalate of copper and/or tin. The method includes the following steps: (1) approach 1: allowing cupric oxalate and/or stannous oxalate to undergo a chemical reaction with a hypochlorite in a hypochlorite-containing aqueous solution to produce a copper compound-containing and/or tin compound-containing precipitate, which is accompanied by release of carbon dioxide; and/or approach 2: allowing the cupric oxalate and/or the stannous oxalate to undergo a chemical reaction in a solution including an alkaline substance to produce a copper compound-containing and/or tin compound-containing precipitate, where the alkaline substance includes a potassium-containing alkaline substance; and (2) solid-liquid separating to produce a filter residue A and a filtrate B, where the filter residue A is the copper compound-containing and/or tin compound-containing precipitate.

A method provides for separating nickel from an aqueous solution using an organicaqueous extraction by performing one or more liquid-liquid extraction stages performed using an input aqueous solution comprising lithium ions, nickel ions, and cobalt ions and/or manganese ions, wherein each extraction stage comprises mixing an aqueous phase with dissolved metal sulfate with an organic solvent having dissolved di-(2,4,4-trimethylpentyl) phosphinic acid from 30% to 70% hydroxyl saponified with alkali, NH.sub.4.sup.+ or nickel counter ions. A collected purified aqueous phase comprising at least 90% of the nickel from the input aqueous solution and no more than about 5% of the each of the cobalt and manganese. The input aqueous solution is prepared from recovered lithium ion battery material.

The present invention generally relates to a method of treating PCB wastewater. More specifically, the present invention relates to a method of ammonical copper etching of PCB wastewater and a process for treating the wastewater. The present invention also relates to the method of purifying the wastewater to reuse the same.