Identyfikatory
Warianty tytułu
Zwiększanie odporności infrastruktury krytycznej poprzez wykorzystanie wirtualnych symulacji awarii na przykładzie elektrowni
Języki publikacji
Abstrakty
Resilience of Critical Infrastructure (CI) facilities defined as a capacity for further operation even upon changes that may result from natural or human-made disasters is extremely important from the perspective of functioning of society. Resilience of critical infrastructure facilities may be developed by taking such activities as introducing changes to their structure based on results of simulations of functioning of CI facilities. Another solution is to make use of computer simulations for better preparation of persons responsible for the functioning of CI facilities. This article describes a reference CI facility with potential scenarios of development of emergency situations and with a set of optional courses of an emergency situation. The scenarios were used to prepare a training application based on virtual reality techniques with an interface allowing a wide spectrum of interactions with a virtual environment, including commands issued to other employees, to be executed.
Odporność obiektów Infrastruktury Krytycznej (IK) definiowana jako zdolność do dalszego działania nawet po wystąpieniu zmian, których źródłem mogą być katastrofy naturalne lub te spowodowane przez człowieka, jest niezwykle istotna z punktu widzenia funkcjonowania społeczeństwa. Zwiększanie odporności obiektów infrastruktury krytycznej może być realizowane dzięki działaniom takim jak wprowadzanie zmian do ich budowy na podstawie wyników symulacji funkcjonowania obiektów IK. Innym rozwiązaniem jest wykorzystanie symulacji komputerowych do lepszego przygotowania osób odpowiedzialnych za funkcjonowanie obiektów IK. W artykule opisano referencyjny obiekt IK wraz z potencjalnymi scenariuszami rozwoju sytuacji kryzysowych wraz zestawem wariantów przebiegu sytuacji kryzysowej. Scenariusze te zostały wykorzystane do przygotowania aplikacji szkoleniowej bazującej na technikach rzeczywistości wirtualnej z interfejsem umożliwiającym realizację szerokiego spektrum typów interakcji z środowiskiem wirtualnym, w tym wydawanie poleceń innym pracownikom.
Rocznik
Strony
57--66
Opis fizyczny
Bibliogr. 32 poz., fot.
Twórcy
autor
- Central Institute for Labour Protection - National Research Institute, 16 Czerniakowska Str., 00-701 Warsaw, Poland
autor
- Central Institute for Labour Protection - National Research Institute, 16 Czerniakowska Str., 00-701 Warsaw, Poland
Bibliografia
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- [16] Ouyang, Min. 2014. “Review on modeling and simulation of interdependent critical infrastructure systems”. Reliability Engineering & System Safety 121 : 43-60.
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- [23] Ding, Tao, Yanling Lin, Gengfeng Li, Zhaohong Bie. 2017. “A new model for resilient distribution systems by microgrids formation”. IEEE Transactions on Power Systems, 32 (5) : 4145-4147.
- [24] Manshadi, D. Saeed, Mohammad E. Khodayar. 2015. “Resilient operation of multiple energy carrier microgrids”. IEEE Transactions on Smart Grid 6 (5) : 2283-2292.
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- [29] P. Pederson, Donald D. Dudenhoeffer, S. Hartley, May R. Permann. 2006. Critical infrastructure interdependency modeling: a survey of US and international research. Technical Report INL/EXT-06-11464, Idaho National Lab, Idaho Falls, USA.
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- [31] Ji, Chuanyi, Yun Wei, Henry Mei, Jorge Calzada, Robert Wilcox, Steve Church, Timothy Hayes, et al. 2016. “Large-scale data analysis of power grid resilience across multiple US service regions”. Nat Energy 1 (5) : 16052.
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Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-7c7b7bc5-4655-40b3-b0cf-0b3f3cd9019f