논문 상세보기
pp.101-112
본 연구는 고방사성해수폐액 (HSW)으로부터 Barium (Ba)이 함침된 4A 제올라이트 (BaA)에 의한 고방사성핵종 중에 하나인 Sr의 흡착 제거를 수행하였다. BaA에 의한 Sr의 흡착 (BaA-Sr)은 Ba의 함침농도 20.2wt% 이상에서 Ba의 함침농도가 증가 할수록 감소하며 Ba 함침농도는 20.2wt% 정도가 적당하였다. 그리고 BaA-Sr 흡착은 BaA 내 4A에 의한 Sr 흡착 (4A-Sr)에 BaSO4 침전에 따른 Sr 공침이 첨가되어, Sr의 농도가 0.2 mg/L 이하 (HSW 내 실제 Sr 농도 수준)에서 BaA는 m/V (흡착제 량/용액 부피)=5 g/L, 4A는 m/V >20 g/L에서 99% 이상의 Sr 제거가 가능하였다. 이는 흡착제 단위 g 당 Sr의 처리용량 및 2 차 고체폐기물 (폐흡착제 등) 발생량 저감화 차원에서 BaA-Sr 흡착이 4A-Sr 흡착보다 우수함을 나타낸다. 또한 BaA-Sr 흡 착이 증류수보다 해수폐액에서 Sr의 제거능이 우수하여 HSW로부터 직접 Sr을 제거하는 데 효과적일 것으로 보인다. 반면 에 BaA에 의한 Cs의 흡착 (BaA-Cs)은 주로 BaA 내 4A에 의해서 이루어지고 있어 함침 Ba의 영향은 거의 없는 것 같다. 한 편 BaA-Sr 흡착속도는 유사 2차 속도식으로 표현할 수 있으며, Sr의 초기농도 및 V/m 비 증가에 따라서 속도상수 (k2)는 감 소하지만 평형흡착량 (qe)은 증가하고 있다. 그러나 용액의 온도증가에 따라서는 반대로 k2는 증가하지만 qe는 감소하고 있 다. BaA-Sr 흡착 활성화에너지는 약 38 kJ/mol 로 강력한 결합 형태를 이룬 화학흡착은 아니더라도 물리적 흡착보다 화학적 흡착이 지배적일 것으로 보인다.
This study investigated the removal of Sr, which was one of the high radioactive nuclides, by adsorption with Barium (Ba) impregnated 4A zeolite (BaA) from high-radioactive seawater waste (HSW). Adsorption of Sr by BaA (BaA-Sr), in the impregnated Ba concentration of above 20.2wt%, was decreased by increasing the impregnated Ba concentration, and the impregnated Ba concentration was suitable at 20.2wt%. The BaA-Sr adsorption was added to the co-precipitation of Sr with BaSO4 precipitation in the adsorption of Sr by 4A (4A-Sr) within BaA. Thus, it was possible to remove Sr more than 99% at m/V (adsorbent weight/solution volume)=5 g/L for BaA and m/V >20 g/L for 4A, respectively, in the Sr concentration of less than 0.2 mg/L (actual concentration level of Sr in HSW). It shows that BaA-Sr adsorption is better than 4A-Sr adsorption in for the removal capacity of Sr per unit gram of adsorbent, and the reduction of the secondary solid waste generation (spent adsorbent etc.). Also, BaA-Sr adsorption was more excellent removal capacity of Sr in the seawater waste than distilled water. Therefore, it seems to be effective for the direct removal of Sr from HSW. On the other hand, the adsorption of Cs by BaA (BaA-Cs) was mainly performed by 4A within BaA. Accordingly, it seems to be little effect of impregnated Ba into BaA. Meanwhile, BaA-Sr adsorption kinetics could be expressed the pseudosecond order rate equation. By increasing the initial Sr concentrations and the ratios of V/m, the adsorption rate constants (k2) were decreased, but the equilibrium adsorption capacities (qe) were increasing. However, with increasing the temperature of solution, k2 was conversely increased, and qe was decreased. The activation energy of BaA-Sr adsorption was 38 kJ/mol. Thus, the chemical adsorption seems to be dominant rather than physical adsorption, although it is not a chemisorption with strong bonding form.
