Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor

This study proposes a method of optimizing the dry storage design for nuclear-spent fuel from the G.A. Siwabessy research reactor at National Nuclear Energy Agency of Indonesia (BATAN). After several years in a spent fuel pool storage (wet storage), nuclear spent fuel is often moved to dry storage....

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Main Authors: Ratiko R., Samudera S.A., Hindami R., Siahaan A.T., Naldi L., Hapsari D., Mahlia T.M.I., Nasruddin N.
Other Authors: 57200398376
Format: Article
Published: Faculty of Engineering, Universitas Indonesia 2023
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spelling my.uniten.dspace-242232023-05-29T14:57:08Z Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor Ratiko R. Samudera S.A. Hindami R. Siahaan A.T. Naldi L. Hapsari D. Mahlia T.M.I. Nasruddin N. 57200398376 57200389886 57200396294 57205696701 57200394513 57200389600 56997615100 57211141063 This study proposes a method of optimizing the dry storage design for nuclear-spent fuel from the G.A. Siwabessy research reactor at National Nuclear Energy Agency of Indonesia (BATAN). After several years in a spent fuel pool storage (wet storage), nuclear spent fuel is often moved to dry storage. Some advantages of dry storage compared with wet storage are that there is no generation of liquid waste, no need for a complex and expensive purification system, less corrosion concerns and that dry storage is easier to transport if in the future the storage needs to be sent to the another repository or to the final disposal. In both wet and dry storage, the decay heat of spent fuel must be cooled to a safe temperature to prevent cracking of the spent fuel cladding from where hazardous radioactive nuclides could be released and harm humans and the environment. Three optimization scenarios including the thermal safety single-objective, the economic single-objective and the multi-objective optimizations are obtained. The optimum values of temperature and cost for three optimization scenarios are 317.8K (44.7�C) and 11638.1 US$ for the optimized single-objective thermal safety method, 337.1K (64.0�C) and 6345.2 US$ for the optimized single-objective cost method and 325.1K (52.0�C) and 8037.4 US$ for the optimized multi-objective method, respectively. � IJTech 2018. Final 2023-05-29T06:57:08Z 2023-05-29T06:57:08Z 2018 Article 10.14716/ijtech.v9i1.775 2-s2.0-85041104913 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85041104913&doi=10.14716%2fijtech.v9i1.775&partnerID=40&md5=578125c0b4294a0dd9c9ba9545307947 https://irepository.uniten.edu.my/handle/123456789/24223 9 1 55 67 All Open Access, Gold, Green Faculty of Engineering, Universitas Indonesia Scopus
institution Universiti Tenaga Nasional
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description This study proposes a method of optimizing the dry storage design for nuclear-spent fuel from the G.A. Siwabessy research reactor at National Nuclear Energy Agency of Indonesia (BATAN). After several years in a spent fuel pool storage (wet storage), nuclear spent fuel is often moved to dry storage. Some advantages of dry storage compared with wet storage are that there is no generation of liquid waste, no need for a complex and expensive purification system, less corrosion concerns and that dry storage is easier to transport if in the future the storage needs to be sent to the another repository or to the final disposal. In both wet and dry storage, the decay heat of spent fuel must be cooled to a safe temperature to prevent cracking of the spent fuel cladding from where hazardous radioactive nuclides could be released and harm humans and the environment. Three optimization scenarios including the thermal safety single-objective, the economic single-objective and the multi-objective optimizations are obtained. The optimum values of temperature and cost for three optimization scenarios are 317.8K (44.7�C) and 11638.1 US$ for the optimized single-objective thermal safety method, 337.1K (64.0�C) and 6345.2 US$ for the optimized single-objective cost method and 325.1K (52.0�C) and 8037.4 US$ for the optimized multi-objective method, respectively. � IJTech 2018.
author2 57200398376
author_facet 57200398376
Ratiko R.
Samudera S.A.
Hindami R.
Siahaan A.T.
Naldi L.
Hapsari D.
Mahlia T.M.I.
Nasruddin N.
format Article
author Ratiko R.
Samudera S.A.
Hindami R.
Siahaan A.T.
Naldi L.
Hapsari D.
Mahlia T.M.I.
Nasruddin N.
spellingShingle Ratiko R.
Samudera S.A.
Hindami R.
Siahaan A.T.
Naldi L.
Hapsari D.
Mahlia T.M.I.
Nasruddin N.
Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor
author_sort Ratiko R.
title Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor
title_short Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor
title_full Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor
title_fullStr Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor
title_full_unstemmed Optimization of dry storage for spent fuel from G.A. Siwabessy nuclear research reactor
title_sort optimization of dry storage for spent fuel from g.a. siwabessy nuclear research reactor
publisher Faculty of Engineering, Universitas Indonesia
publishDate 2023
_version_ 1806423522518499328