Glass fiber (GF) insulation is a non-combustible material, light, easy to transport/store, and has excellent thermal insulation performance, so it has been widely used in the piping of nuclear power plants. However, if the GF insulation is exposed to a high-temperature environment for a long period of time, there is a possibility that it may be crushed even with a small impact due to deterioration phenomenon and take the form of small particles. In fact, GF dust was generated in some of the insulation waste generated during the maintenance process. In the previous study, the disposal safety assessment of GF waste was performed under the abnormal condition of the disposal facility to calculate the radiation exposure dose of the public residing/ residents nearby facilities, and then the disposal safety of GF waste was verified by confirming that the exposure dose was less than the limit. However, the revised guidelines for safety assessment require the addition of exposure dose assessment of workers. Therefore, in this study, accident scenarios at disposal facilities were derived and the exposure dose to the workers during the accident was evaluated. The evaluation was carried out in the following order: (1) selection of accident scenario, (2) calculation of exposure dose, (3) comparison of evaluation results with dose limits, and confirmation of satisfaction. The representative accident scenarios with the highest risk among the facility accident were selected as; (a) the fire in the treatment facility, (b) the fire in the storage facility, and (c) fire after a collision of transport vehicles. The internal and external exposure doses of the worker by radioactive plume were calculated at 10m away from the accident point. In evaluation, the dose conversion factors ICRP-72 and FGR12 were used. As a result of the calculation, the exposure dose to workers was derived as about 0.08 mSv, 0.20 mSv, and 0.10 mSv, due to fire accidents (vehicle collision, storage facilities, treatment facilities). These were 0.2%, 0.4%, and 0.2% of the limit, and the radiation risk to workers was evaluated to be very low. The results of this study will be used as basic data to prove the safety of the disposal of GF waste. The sensitivity analysis will be performed by changing the radiation source and emission rate in the future.

Several countries, including Korea, are considering the direct disposal of spent nuclear fuels. The radiological safety assessment results published after a geological repository closure indicate that the instant release is the main radiation source rather than the congruent release. Three Safety Case reports recently published were reviewed and the IRF values of seven long-lived radionuclides, including relevant experimental results, were compared. According to the literature review, the IRF values of both the CANDU and low burnup PWR spent fuel have been experimentally measured and used reasonably. In particular, the IRF values of volatile long-lived nuclides, such as 129I and 135Cs, were estimated from the FGR value. Because experimental leaching data regarding high burnup spent nuclear fuels are extremely scarce, a mathematical modelling approach proposed by Johnson and McGinnes was successfully applied to the domestic high burnup PWR spent nuclear fuel to derive the IRF values of iodine and cesium. The best estimate of the IRF was 5.5% at a discharge burnup of 55 GWd tHM−1.

한국형처분시스템에 이용될 가압경수로형 사용후핵연료를 위한 KDC-1 처분용기를 개발하였다. 처분용기 안전성 평가의 일환으로서 처분용기에 대한 구조적 안전성을 평가하였다. 처분용기의 구조적 안전성은 처분조건과 취급조건 2가지로 구분하여 평가하였다. 처분조건에서는 3가지 하중 조건, 정상하중 조건, 비정상 하중 조건, 암반의 움직임을 고려하였다. 처분조건에서 평가 결과 3가지 조건에 대해 모두 안전계수가 설계기준보다 컸다. 취급조건에서는 처분용기 취급 중 구조해석과 처분용기 낙하 사고시 구조해석을 수행하였다. 취급장비 고장 시나리오 평가결과 1개 혹은 2개의 취급 장치가 고장을 일으켰을 때도 취급장비를 계속 운전하는 것이 가능하였다. 처분용기 낙하 시나리오에서는 계산결과 최대 응력은 0.762 MPa 이었으며, 이 값은 주철의 항복응력과 비교하면 거의 무시할 수 있는 값이었다. 본 논문에서 제안한 KDC-1 처분용기에 대한 처분조건 및 취급조건에서의 구조해석 결과, 한국형처분시스템에서 고려하고 있는 조건에서 그 구조적 안전성을 확인하였다.