The fuel fabrication facility has been built and is being operated by KAERI since licensing research reactor fuel fabrication in 2004. After almost 20 years of operation, outdated equipment for fabrication or inspection has been replaced by automated, digitalized ones to assure a higher quality of nuclear fuels. However, the generation of a large amount of radioactive waste is another concern for the replacement in terms of its volume and various types of it that should be categorized before disposal. The regulatory body, NSSC (Nuclear Safety and Security Commission) released a notice related to the classification of radioactive wastes, and most accessory equipment can be classified into the clearance levels, called self-disposal waste. In this study, the practice of self-disposal of metal radioactive waste is carried out to reduce its volume and downgrade its radioactivity. For metal radioactive waste, which is expected to occupy the most amount, analysis status and legal limitations were performed as follows: First, the disposal plan was established after an investigation of the use history for equipment. Second, those were classified by types of materials, and their surface radio-contamination was measured for checking self-disposable or not. After collecting data, the plan for the self-disposal was written and submitted to the Korea Institute of Nuclear Safety (KINS) for approval.

In plants, starch is the main carbohydrate reserve and an important ingredient in human nutrition. Nutritionally, starch is classified into rapidly digestible starch (RDS), slowly digestible starch (SDS), and resistant starch (RS) based on the rate and degree of digestion. RS escapes enzymatic digestion in the small intestine, but in the large intestine microbial flora may ferment some RS. Malic acid is C4 carboxylic acid with two carboxyl groups. It is well known to take from 69% up to 92% of all organic acids in grape berries and leaves and is naturally produced by many organisms without showing any nutritional harm. However, properties of malic acid treated starch has not been clearly reported. The objectives of this study were to investigate the influence of pH value on low-digestible malate starch formation and digestibility in relation to structural properties of corn starch. Different pH values (1.5-8.5) of 2 M malic acid solution were reacted with corn starch in a forced-air oven at temperature of 130°C for 12 hr. Using FT-IR, carbonyl groups were detected in malate starch, indicating the formation of cross-linking by esterification. Increasing pH value of malic acid-treated sample from 1.5 to 8.5 showed an increase in degree of substitution (DS) and resulted in increase in the RS content from 18.2 to 74.8%, which was maintained after gelatinization. The granular structure of malate starches was not destroyed, and the starches maintained birefringence. This malate starch could be utilized in heat processed foods such as bread and cookies as well as in the products with reduced calories.

Starch is classified as fast digestible starch (RDS), slowly digestible starch (SDS) and resistant starch (RS) depending on digestibility. RS can avoid enzymatic digestion in the small intestine, but microbes in the large intestine can ferment some RSs. The purpose of this study was to investigate the structural characteristics of low digestible starch by malic acid mutation in rice, corn and potato starch. Rice, corn and potato starch were treated with a 2M malic acid solution in a forced air oven at 130 ° C for 12 hr. Using FT-IR, carbonyl groups were detected in malate starch, indicating the formation of cross-linking by esterification. And, Using X-ray, diffractograms of malic acid-treated starch. In the micrographs, malate treated corn and potato starch granules were marked with elliptical or polygonal shapes and starch retained birefringence. Through microscopic observe in morphology of starch granules, Microscopic observation did not reveal any changes in morphology of starch granules. The modified starches had higher RS than the control and native starch. RS content of maltitized rice, corn and potato starch was 87.6%, 89.8% and 64.8%, respectively. Malic acid treated RS was maintained after the cooking process. The RS of substituted starches increased with increasing degree of substitution. These results suggest that the increase in RS content by malic acid treatment is caused by the change in the structure. And the highest resistant starch content (86.7%) was found at pH 1.5, 2M of malic acid treated corn starch. Malic acid-treated starch can be used as heat-stable and low-digestible starch containing food ingredients.