The purpose of this study is to produce the auxiliary fuel additives that will improve the heat value and reduce the odor of dried sewage sludge, an auxiliary fuel for power plants using process by-products. Through an odor analysis prior to the production of auxiliary fuel additives, it was confirmed that the main odor materials are Methylmercaptan, Acetaldehyde and Trimethylamine. Based on this, we measured the heating value on various processes by-products such as by-products of thermal power generation and by-products of refinery. In addition, the adsorption performance in the major odor material was evaluated. However, for Trimethylamine, it is very difficult to secure the reproducibility of the concentration of the standard materials as the standard material is liquid. Therefore, it was used Ammonia, which has basic property, to replace Trimethyamine. In the evaluation of various process by-products, the highest heating value in heavy oil fly ash was 5,575 kcal/kg, while in the adsorption performance evaluation, FCC was shown as having the best performance in adsorption, as it could adsorb 100% of Methylmercaptan, 47% of Acetaldehyde and 76% of Ammonia. We conducted an adsorption experiment after supporting a transition metal on the FCC in order to improve the adsorption capacity. As a result, it was confirmed the best efficiency when supporting the copper nitrate 0.5% on the FCC. Based on this result, the experiment was conducted to determine the optimal mixing ratio with a high heating value and odor reducing function using Heavy oil fly ash and FCC. The optimal mixing ratio was 90% of Heavy oil fly ash and 10% of FCC. Furthermore, it was found that the most economical performance and highest odor reducing efficiency was achieved when the mixing ratio was 90% of dried sewage sludge and 10% of auxiliary fuel additives.

TRIGA 연구로의 해체 시 발생하는 금속성 폐기물의 용융기술을 확립하기 위한 기초연구로 전기로 내에서 방사성 핵종(Co, Cs, Sr)을 포함한 알루미늄의 용융 시 용융온도, 용융시간 및 플럭스(flux)의 종류가 핵종의 분배 거동에 미치는 영향을 조사하였다. 플럭스의 종류에 따라 다소 차이는 있으나, 플럭스의 첨가로 알루미늄 용융체의 유동성이 증가됨을 확인할 수 있었다 용융 후주괴(ingot) 및 슬래그(slag) 시료의 XRD분석을 통해 핵종이 주괴에서 슬래그 상으로 이동하고 슬래그를 구성하고 있는 산화알루미늄과 결합하여 안정한 화합물을 형성함을 알 수 있었다. 슬래그의 발생량은 용융온도와 용융시간이 증가할수록 증가하는 경향을 보였으며, 증가속도는 플럭스의 종류에 따라 차이를 보였다. 핵종 중 Co는 용융온도가 증가함에 따라 주괴 내 에서는 감소하였으나 슬래그 상에서는 증가하는 경향을 보였으며, 실험조건에 따라 최대 90까지 주괴에서 슬래그로 이동하였다. 휘발성이 강한 Cs과 Sr은 대부분이 슬래그와 분진으로 이동하여 매우 높은 제염계수를 얻을 수 있었다.