SUBSTANTIATION A NEW CAUSAL INTERPRETATION OF THE DEVELOPMENT AND TRANSFORMATION OF EMERGENCY SITUATIONS ON THE EXAMPLE OF THE ACCIDENT AT THE FUKUSHIMA-1 NUCLEAR POWER PLANT-Reference-Cited by-同舟云学术

SUBSTANTIATION A NEW CAUSAL INTERPRETATION OF THE DEVELOPMENT AND TRANSFORMATION OF EMERGENCY SITUATIONS ON THE EXAMPLE OF THE ACCIDENT AT THE FUKUSHIMA-1 NUCLEAR POWER PLANT

Published:2024-04-26 Issue:1 Volume:2024 Page:25-36
ISSN:1998-8990
Container-title:Problems of risk management in the technosphere
language:en
Short-container-title:

Author:

Ivakhnyuk Sergey¹^ORCID,Koroleva Lyudmila¹^ORCID,Lugavtsov Oleg²

Affiliation:

1. Saint-Petersburg university of State fire service of EMERCOM of Russia

2. Saint-Petersburg state technological institute (technical university)

Abstract

Using the example of the radiation accident at the Fukushima-1 nuclear power plant and subsequent measures to discharge tritium-containing aqueous coolant into the ocean, the adequacy of a new causal interpretation – the «triangle of emergencies», justifying and explaining scenarios of mutual transition of one type of emergency into another, as well as its graphical interpretation is considered. The issues of existing and possible consequences related both directly to the accident and to the discharge of the coolant are investigated. The results of calculating the change in the radioactivity of tritium in the volume of water planned for discharge for a period equal to ten of its half-life are presented. The prospects of applying the concept of an «emergency triangle» are considered, which are seen in the construction of an «emergency space», which is an array of emergency data collected for the purpose of analyzing, interpreting information, establishing cause-effect relationships and forecasting, as well as the principles of its formation.

Publisher

St. Petersburg University of the State Fire Service of EMERCOM of Russia

Reference17 articles.

1. Кондратьев Н.Д. Избранные сочинения. М.: Экономика, 1993., Kondrat'ev N.D. Izbrannye sochineniya. M.: Ekonomika, 1993.

2. Ивахнюк С.Г. Каскадность взаимных возникновения и развития чрезвычайных ситуаций – результат научно-технического прогресса // Проблемы управления рисками в техносфере. 2022. № 1 (61). С. 67–77., Ivahnyuk S.G. Kaskadnost' vzaimnyh vozniknoveniya i razvitiya chrezvychajnyh situacij – rezul'tat nauchno-tekhnicheskogo progressa // Problemy upravleniya riskami v tekhnosfere. 2022. № 1 (61). S. 67–77.

3. Khazai B., Daniell J., Wenzel F. The March 2011 Japan earthquake: analysis of losses, impacts, and implications for the understanding of risks posed by extreme events // TATuP-Zeitschrift für Technikfolgenabschätzung in Theorie und Praxis. 2011. Т. 20. № 3. С. 22–33., Khazai B., Daniell J., Wenzel F. The March 2011 Japan earthquake: analysis of losses, impacts, and implications for the understanding of risks posed by extreme events // TATuP-Zeitschrift für Technikfolgenabschätzung in Theorie und Praxis. 2011. T. 20. № 3. S. 22–33.

4. The Fukushima Daiichi accident. Vienna: IAEA, 2015. 262 p., The Fukushima Daiichi accident. Vienna: IAEA, 2015. 262 p.

5. Steinhauser G., Brandl A., Johnson T.E. Comparison of the Chernobyl and Fukushima nuclear accidents: a review of the environmental impacts // Science of the total environment. 2014. Т. 470. С. 800–817., Steinhauser G., Brandl A., Johnson T.E. Comparison of the Chernobyl and Fukushima nuclear accidents: a review of the environmental impacts // Science of the total environment. 2014. T. 470. S. 800–817.