저항성 황화광물 정광으로부터 최적의 gold를 용출시키기 위하여 염소-차아염소산 용액과 다양한 온도와 농도를 소금소성정광에 적용하였다. 정광은 황철석, 황동석, 방연석으로 구성되었으며, 공기 중에서 750℃ 소성처리하자 적철석으로 변환되었고, 소금으로 소성처리하자 적철석과 난토카이트(nantokite, CuCl)으로 변환되었다. 다양한 변수로 용출실험을 수행한 결과, 염소-차아염소산 나트륨 혼합 비율 1 : 2에서, FeCl3 첨가량 1.0 M에서, 광액농도 1.0%에서, 그리고 용출온도 60℃에서 최대의 금 용출율을 얻었다. 금 용출율은 정광에서보다 소성정광에서 더 높게 용출되었고, 소성정광에서보다 소금소성정광에서 더 높게 용출되었다. XRD 분석 결과, 소금소성정광에서, 그리고 60℃의 염소-차아염소산 용출용액 고체 잔유물에서 석영이 관찰되었다.
In order to optimize the gold leaching process from refractory sulfide concentrate, a chlorine-hypochlorite solution with varying concentrations and temperatures were applied to salt-roasted concentrate. The concentrate consisted of pyrite, chalcopyrite, and galena, which were turned into hematite through air-roasting at 750℃. Also these concentrates were changed into hematite and nantokite (CuCl)) through salt (NaCl)-roasting at 750℃. The results of the gold leaching experiments showed that the best gold leaching parameters were obtained when the hydrochloric acid-sodium hypochlorite mix was at a ratio of 1 : 2, the added concentration was 1.0 M concentration, the pulp density was 1.0%, and the leaching was done at a 60℃ leaching temperature. The leaching rate for gold was much greater in the roasted concentrate than in the raw concentrate. The leaching rate was greater in the salt-roasted concentrate than in the plain roasted concentrate too. From XRD analysis, quartz was found in the salt-roasted concentrate and in the solid residue from the chlorine-hypochlorite leaching solution at 60℃.