Due to the necessity of isolating spent nuclear fuel (SNF) from the human life zone for a minimum of 106 years, deep geological disposal (DGD) has emerged as a prominent solution for SNF management in numerous countries. Consequently, the resilience of disposal canisters to corrosion over such an extended storage period becomes paramount. While copper exhibits a relatively low corrosion rate, typically measured in millimeters per million years, in geological environment, special attention must be directed towards verifying the corrosion resistance of copper canister welds. This validation becomes inevitable during the sealing of the disposal canister once SNFs are loaded, primarily because the weld zone presents a discontinuous microstructure, which can accelerate both uniform and localized corrosion processes. In this research, we conducted an in-depth analysis of the microstructural characteristics of copper welds manufactured by TIG-based wire are additive manufacturing, which is ideal for welding relatively large structures such as a disposal canister. To simulate the welds of copper canister, a 12 mm thick oxygen-free plate was prepared and Y and V grooves were applied to perform overlay welding. Both copper welding zones were very uniform, with negligible defects (i.e., void and cracks), and contained relatively large grains with columnar structure regardless of groove types. For improving microstructures at welds with better corrosion resistance, the effect of preheat temperature also investigated up to 600°C.

Since spent nuclear fuel (SNF) should be isolated from the human life zone for at least 106 years, deep geological disposal (DGD) is considered a strong candidate for SNF management in many countries. Therefore, a disposal canister should be nearly immune to corrosion in such a long-term storage environment. Even though copper has a low corrosion rate of a few millimeters per million years in geological environments, the corrosion resistance of the copper welds must be preferentially validated, which inevitably occurs during the sealing of the disposal canister after the SNF is loaded. This is because the weld zone is a discontinuous area of microstructure, which can accelerate uniform and localized corrosion. In this study, the microstructural characteristics of copper welds in different welding conditions such as friction stir welding, electron beam welding, cold spray, were analyzed, focusing on the formation of microstructure, which affects resistance to corrosion. In addition, the microstructure and corrosion properties of the copper weld zone manufactured by recent wire-based additive manufacturing (AM) technology were experimentally evaluated. From this preliminary test result, it was found that the corrosion characteristics of the welds produced by the AM process using wire are comparable to those of the conventional forged copper plate.

우리나라에서 발생하는 사용후핵연료를 CANDU형과 PWR형 2종류로 구분한다. PWR형 사용후핵연료의 경우 적절한 공정을 거쳐 원료물질로 다시 사용할 수 있는 물질을 많이 포함하고 있어 재활용 공정을 고려할 수 있다. CANDU형 사용후핵연료는 천연 우라늄을 원료물질로 사용하고 있어 재활용 가능성이 거의 없으므로 직접 처분을 고려하고 있다. 본 논문에서는 PWR형과 CANDU형 사용후핵연료 모두를 직접 처분하는 개념 으로 개발한 한국형 사용후핵연료 처분시스템을 바탕으로 CANDU형 사용후핵연료 처분 시스템을 향상시키 는 방안을 도출하고자 하였다. 이를 위하여, 현재 원자력발전소에서 사용하고 있는 사용후핵연료 60 다발 (Bundle) 용량의 저장바스켓을 포장·활용하는 방안으로 처분용기 개념을 개선하였다. 이들 개선한 처분용 기를 기반으로 하여 사용후핵연료의 심지층 처분시스템에 있어서 주요한 제한요건인 폐기물로부터 발생된 열로 인하여 완충재의 온도가 100 ℃를 넘지 않도록 하는 요건을 만족시키면서 효율을 향상시킨 처분시스템 개념을 제시하였다. 제시한 처분 시스템 개념들은 장기저장 및 회수성이 용이한 방안을 도입한 개념과 개선 한 처분용기를 1개 처분공에 2단으로 처분하는 것으로서 이들 개념을 기존 한국형 처분시스템과 효율성 측면 에서 비교?분석하였다. 본 연구를 통하여 얻은 CANDU 사용후핵연료 처분개념은 단위면적당 열효율, Udensity, 처분면적, 굴착량, 완충재 및 폐쇄 물질량을 30∼40 % 까지 효율을 향상시킬 수 있었다.