2019-1(30)

Nuclear, radiation and environmental safety

Article Name10.26583/GNS-2019-01-01
Passive Protection Development of the Mobile Unit of Nuclear and Radiation Hazardous Objects
AuthorsO.A. Gubeladze1, A.R. Gubeladze2
Address

Don State Technical University, Gagarin square 1, Rostov-on-Don, Russia, 344000

1ORCID iD: 0000-0001-6018-4989

WoS Researcher ID: F-6921-2017

e-mail: buba26021966@yandex.ru

2ORCID iD: 0000-0002-6966-6391

WoS Researcher ID: F-7215-2017

e-mail: buba26021966@yandex.ru

AbstractImproving the means of protecting mobile nuclear and radiation hazardous objects (NRHFs) from kinetic impactors should be achieved through the use of new materials, the use of multilayer structures with separated and multi-oriented layers, the use of rebound properties, and the refraction of the impactor's trajectory during the passing through barrier. The article presents some results of experimental studies aimed at making constructive and technical solutions implementing various principles of mobile NRHF protection.
Keywordsconventional weapons, kinetic impactors, protective shield, nuclear and radiation hazardous object.
LanguageRussian
References
  1. Gubeladze O.A., Gubeladze A.R., Burdakov S.M. Vybor kriterija otsenki stoykosti transportno-upakovochnogo komplekta s jaderno- i radiatsionno opasnym ob’ektom [Criterion Choice for Evaluation of Transport and Packing Set Firmness with Nuclear and Radiation Dangerous Object]. Global’naia iadernaia bezopasnost [Global Nuclear Safety]. 2016. № 4. Р. 16-21 (in Russian).
  2. Gubeladze, O.A. Modelirovanie vysokoskorostnogo udara [Modeling of High-Speed Blow]. Globalnaia iadernaia bezopasnost [Global Nuclear Safety]. 2015. №1. Р. 61-69 (in Russian).
  3. Denisov O.V., Gubeladze O.A., Meskhi B.Ch., Bulygin Yu.I. Kompleksnaya bezopasnost' naseleniya i territoriy v chrezvychaynykh situatsiyakh. [Complex Safety of the Population and Territories in Emergency Situations. Problems and Solutions]. Rostov on Don. Don State technical university [Publishing center of Don State technical university]. 2016. 278 p. (in Russian).
  4. Gubeladze O.A., Fedorenko S.V., Gubeladze P.O.  Issledovanie dvigenija vysokoskorostnogo udarnika v mnogofunktsionalnom pokrytii perspektivnoj konstruktsii kontejnera s ustanovkoj, sodergashchej jadernoopasnye deljashchiesja materialy  [Study of High-Speed Traffic Drummer in Multifunctional Coating Prospective Container Design to Installation, Contains the Nuclear-Dangerous Fissile Materials]  Izvestiya vy`sshix uchebny`x zavedenij. Severo-Kavkazskij region. Seriya: Texnicheskie nauki [Scientific Educational and Applied Journal. University news of North-Caucasian Region. Technical Science Series. Application]. 2010. Special Issue. Р. 134-136 (in Russian).
  5. Gubeladze O.A., Gubeladze A.R., Burdakov S.M. Issledovanie effektivnosti sistemy okhrany podvignogo jaderno- i radiatsionno opasnogo ob’ekta [Research of the Protection System Effectiveness for a Mobile Nuclear and Radiation Hazardous Facility] Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2018. №1 (26). Р. 36-46 (in Russian).
  6. Gubeladze O.A. Otsenka rezul'tatov nereglamentirovannykh vozdeystviy na vzryvoopasnyy ob’ekt [Estimating of Unregulated Influence Results on Explosive Object]. Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2011. №1 (1). Р. 61-63 (in Russian).
  7. Gubeladze O.A., Gubeladze A.R. Ekspress-otsenka rezul’tatov nereglamentirovannykh destruktivnykh vozdejstvij na jaderno- i radiatsionno opasnyj ob’ekt [Express Assessment of Results of Independent Destructive Impacts on Nuclear and Radiation-Hazardous Object] Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2018. №4 (29). Р. 24-30 (in Russian).
  8. Sakhabudinov R.V., Gubeladze O.A. Nauchno-metodicheskie osnovy obespecheniya fizicheskoy zashchity yadernoopasnykh ob’ektov. [Scientific and Methodical Bases of Ensuring Physical Protection of Nuclear-Dangerous Objects]. Rostov-on-Don. «LLC Terra» [«Terra» Limited Liability Company]. 2006. 153 p. (in Russian).
  9. Krasnov A.A., Tkachev V.P., Saxabudinov R.V. Zashchitnoe zagragdenie [Protective Boom]. Patent RF, № 2211434, 2003 (in Russian).
  10. Krasnov A.A., Tkachev V.P., Saxabudinov R.V. Mobilnyj razvertyvaemyj zashchitnyj ekran [Mobile Expandable Protective Screen]. Patent RF, № 2229675, 2004 (in Russian).
  11. Krasnov A.A., Saxabudinov R.V., Fedorenko S.V. Bronetransporter s transformiruemym ekranom [Armored Personnel Carrier with Transformable Protective Screen]. Patent RF, № 2399857, 2009 (in Russian).
Papers7 - 15
URL ArticleURL Article
 Open Article
Article Name10.26583/GNS-2019-01-02
Water Quality Assessment on Sanitary-Hygienic Parameters of Neman River at Baltic Power Plant (Under Construction) Region
AuthorsE.V. Luneva*1, E.A. Vereshchagina**2, D.V. Kulakov**3, M.E. Makushenko***4
Address

*JSC «Concern Rosenergoatom», Projected passage № 4062, 6, bldg. 5,  Moscow, Russia 115432

1ORCID iD: 0000-0003-4238-2214

Wos Researher ID: B-1754-2019

e-mail: luneva100@yandex.ru

**Institute of Earth Sciences, St. Peterburg State University, Universitetskaya nab., 7/9. Saint-Petersburg, Russia, 199034

2ORCID iD: 0000-0003-2249-4614

Wos Researher ID: G-8232-2015

e-mail: ea.grigorieva@gmail.com

3 ORCID iD: 0000-0002-1855-4509

Wos Researher ID: G-9980-2018

e-mail: dvkulakov@mmail.ru

***St. Petersburg Division, Sergeev Institute of Environmental Geosciences, the Russian Academy of Sciences, Vasilievskiy island., Middle pr, 41, of. 519, Saint-Petersburg, Russia 199004

4ORCID iD: 0000-0003-0071-8314

Wos Researher ID: B-2512-2019

e-mail: maria@hgepro.ru

AbstractUsing surface water objects for water supply and disposal systems of nuclear power plants (NPP) produces a complex of problems concerned with environmental and health protection. Sanitary-hygienic (including hydrochemical and micro-biological) parameters and natural water toxicity are studied at Neman river, as the river is planned to be a cooling pond of Baltic NPP, which is under construction. Water quality assessment is done based on the observed data during 2011–2016. Observations have shown high variety of river condition during the year (seasonal variations) with not good enough water quality parameters for water supply purposes over the most part of the year. To obtain water with high organoleptic indicators and an acceptable level of risk in terms of chemical and microbiological composition for water supply system, a complex of methods for water purification, post-treatment and disinfection should be applied. Although, it is shown, that natural waters of the Neman river within the Kaliningrad region should be considered not to have a toxic effect on aquatic organisms.
Keywordswater quality assessment, micro-biological parameters, hydrochemical parameters, Neman river, Baltic nuclear power plant
LanguageRussian
References
  1. Beznosov V.N. et al. Osobennosti e`vtrofirovaniya vodoema-oxladitelya AE`S [Features of NPP Cooling Pond Eutrophication]. Aktual`ny`e problemy` e`kologii i prirodopol`zovaniya. Sbornik nauchny`x trudov Rossijskogo universiteta druzhby` narodov [Actual Problems of Ecology and Landuse. Collection of Scientific Papers of RUDN University]. V. 5. P. 2. E`kologicheskie issledovaniya prirodno-texnogenny`x system [Ecological Researches of Environmental-Technogenic Systems]. Moskva: RUDN [Moscow: RUDN]. 2004. Р. 176-186 (in Russian).
  2. MU 2.1.5.1183-03 «Sanitarno-e`pidemiologicheskij nadzor za ispol`zovaniem vody` v sistemax texnicheskogo vodosnabzheniya promy`shlenny`x predpriyatij» [Methodical Recommendations 22.1.5.1183-03. Sanitary-Epidemiological Supervision on Water Usage in Industrial Enterprises Technical Water Supply].  Moskva: Standartinform.  [Moscow: Standardinform]. Introduced 11.01.2003. 8 р. (in Russian).
  3. Kulakov D.V., Vereshchagina E.A., Makushenko M.E., Luneva E.V. Zooplankton i gidroximicheskie usloviya transgranichnoj reki Neman v period stroitel`stva Baltijskoj AE`S [Zooplankton and Hydrochemical Parameters for Transboundary River Neman during the Construction Period of Baltic Nuclear Power Plant]. Voda: ximiya i e`kologiya [Water: Chemistry and Ecology]. 2016. N 6. Р. 46-55 (in Russian).
  4. SP 151.13330.2012 Inzhenerny`e izy`skaniya dlya razmeshheniya, proektirovaniya i stroitel`stva AE`S, chast` 2 Inzhenerny`e izy`skaniya dlya razrabotki proektnoj i rabochej dokumentacii i soprovozhdeniya stroitel`stva [Code of Regulations 151.13330.2012. Engineering Surveys for the Location, Design and Construction of Nuclear Power Plants. Part 2. Engineering Surveys for the Development of Design and Working Documentation and Construction Support]. Moskva: Standartinform.  [Moscow: Standardinform]. Introduced 25.12.2012. 2012. 128 р. (in Russian).
  5. FR.1.39.2007.03222 Metodika opredeleniya toksichnosti vody` i vodny`x vy`tyazhek iz pochv, osadkov stochny`x vod, otxodov po smertnosti i izmeneniyu plodovitosti dafnij FR.1.39.2007.03222 [Methodology for Determining Water and Water Extracts from Soils, Sewage Sludge and Wastes Toxicity by Mortality and the Change in the Fertility of Daphnia]. Moskva: Standartinform.  [Moscow: Standardinform]. 2007. 51 р. (in Russian).
  6. RD 52.24.643-2002 Metod kompleksnoj ocenki stepeni zagryaznennosti poverxnostny`x vod po gidroximicheskim pokazatelyam [Statestandard 17.1.2.04-77. Protection of Nature. Hydrosphere. Indicators of the State and Taxation Rules of Fishery Water Bodies]. Moskva: Standartinform.  [Moscow: Standardinform]. Introduced 07.01.78. 1977. 17 р. (in Russian). 
  7. RD 52.24.643-2002 «Metod kompleksnoj ocenki stepeni zagryaznennosti poverxnostny`x vod po gidroximicheskim pokazatelyam [Ruling Document 52.24.643-2002 Methodical Instructions. The Method of Integrated Assessment of the Contamination Degree of Surface Water by Hydrochemical Indicators]. Moskva: Standartinform.  [Moscow: Standardinform]. Introduced 01.01.2004. 2004.
    49 р. (in Russian).
  8. Vereshchagina E.A., Luneva E.V., Shvartc A.A. Metodicheskie osnovy` kompleksnogo monitoringa vodny`x ob``ektov zony` vliyaniya AE`S dlya e`ffektivnoj ocenki kachestva vody` [Methodological Basics of Water Bodies Integrated Monitoring of NPP Influence Zones for Water Quality Effective Evaluation]. Trudy` vtoroj nauchno-prakticheskoj konferencii s mezhdunarodny`m uchastiem, posvyashhennoj 70-letiyu atomnoj otrasli Rossii «E`kologicheskaya bezopasnost` AE`S». – Kaliningrad, 20-21 oktyabrya 2015 [Proceedings of Second Scientific-Practical Conference with International Participation Dedicated to 70-years of Russian Nuclear Industry. Environmental Safety of Nuclear Power Plants. Kaliningrad. 20-21.10.2015]. Р. 43-49 (in Russian).
  9. Guseva T.V., Molchanova I.P., Zaika E.A., Vinichenko V.N., Averochkin E.M. Gidroximicheskie pokazateli sostoyaniya okruzhayushhej sredy` [Hydrochemical Indicators of the Environment State]. Moskva: Ecoline [Moscow. Ecoline]. 2000. P. 87 (in Russian).
  10. Sxema kompleksnogo ispol`zovaniya i oxrany`  vodny`x ob``ektov bassejnov reki Neman i rek bassejna Baltijskogo morya (rossijskaya chast` v Kaliningradskoj obl.) [Scheme of Integrated Use and Protection of Water Bodies of the Neman River Basins and the Rivers of the Baltic Sea Basin (the Russian part in the Kaliningrad Region)]. Moskva: Standartinform.  [Moscow: Standardinform]. 2012. 105 р. (in Russian).
  11. PND F T 14.1:2:4.12-06 Metodika opredeleniya toksichnosti vodny`x vy`tyazhek iz pochv, osadkov stochny`x vod i otxodov, pit`evoj, stochnoj i prirodnoj vody` po smertnosti test-ob``ekta Daphnia magna Straus [Ruling Document 14.1:2:4.12-06 Methodology of Toxicity of Water Extracts of Soil, Sewage Sludge, Waste, Drinking and Natural Water Determining at the Test Object Dаphnia Magna Straus Mortality]. Moskva: Standartinform.  [Moscow: Standardinform]. 2011. 45 р. (in Russian).
Papers16 - 24
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 Open Article

Design, manufacturing and commissioning of nuclear industry equipment

Article Name10.26583/GNS-2019-01-03
Application of the Expert System for Assessing of the Stress-Strain State of Nuclear Power Plant Containments at the Stage of Construction and Operation
AuthorsV.N. Medvedev1, Aleksandr S. Kiselev2, Aleksei S. Kiselev3, V.F. Strizhov4, A.N. Ul'yanov5, M.I. Skorikova6
Address

Nuclear Safety Institute of the Russian Academy of Sciences (IBRAE RAS), Bol'shaya Tul'skaya St., 52, Moscow, Russia, 115191

1ORCID iD: 0000-0003-2182-9769

Wos Researher ID: U-8092-2018

e-mail: cont@ibrae.ac.ru

2ORCID iD: 0000-0002-1405-4080

Wos Researher ID: U-8140-2018

e-mail: alkis_rrcki@mail.ru

3ORCID iD: 0000-0002-2450-4495

Wos Researher ID: U-8820-2018

e-mail: kis-rncki@rambler.ru

4ORCID iD: 0000-0003-2244-6612

Wos Researher ID: V-5004-2018

e-mail: vfs@ibrae.ac.ru

5ORCID iD: 0000-0003-4850-4825

Wos Researher ID: U-8123-2018

e-mail: cont@ibrae.ac.ru

6ORCID iD: 0000-0002-9090-346X

Wos Researher ID: U-8075-2018

e-mail: skorikova@ibrae.ac.ru

AbstractNuclear Safety Institute of the Russian Academy of Sciences develops an expert system for assessing the stress-strain state of the containments of WWER-1000 NPP units. The expert system consists of the software package CONT, force control sensors in armored channels, sensors of instrumentation equipment. The paper provides a description of the expert system for assessing the stress-strain state of NPP containment and the features of its application.
Keywordscontainment, stress-strain state, expert system.
LanguageRussian
References
  1. Medvedev V.N., Ulyanov A.N., Kiselev Al-Ndr S., Kiselev Alexey S., Strizhov V.F.,
    Bayuklin V.F. Razrabotka e`kspertnoj sistemy` ocenki napryazhennogo sostoyaniya dlya zashhitnoj obolochki 1-go e`nergobloka Volgodonskoj AE`S [Development of Expert System for Assessing the Stress State for the Volgodonsk NPP1st Unit Containment]. Izvestiya vy`sshix uchebny`x zavedenij. Severo-Kavkazskij region. Texnicheskie nauki [News of Higher Educational Institutions. North Caucasus Region. Technical Science]. 2008. Special issue. P. 107-112 (in Russian).
  2. SNiP 52-01-2003. Betonny`e i zhelezobetonny`e konstrukcii. Osnovny`e polozheniya [SNiP 52-01-2003. Concrete and Reinforced Concrete Structures. The Main Provisions]. Moskva [Moscow]. 2004 (in Russian).
  3. RD E`O 1.1.2.99.0624-2011. Monitoring stroitel`ny`x konstrukcij atomny`x stancij [RD EO 1.1.2.99.0624-2011. Monitoring of Building Structures of Nuclear Power Plants]. Moskva [Moscow].  2011 (in Russian).
  4. GOST 31937-2011. Zdaniya i sooruzheniya. Pravila obsledovaniya i monitoringa texnicheskogo sostoyaniya [GOST 31937-2011. Buildings and Constructions. Rules of Inspection and Monitoring of Technical Condition]. Moskva [Moscow].  2011 (in Russian).
  5. NP-010-16. Pravila ustrojstva i e`kspluatacii lokalizuyushhix sistem bezopasnosti atomny`x stancij [NP-010-16. Rules for Design and Operation of Localized Safety Systems of Nuclear Power Plants]. Moskva [Moscow].  2016 (in Russian).
  6. Sposob natyazheniya armaturny`x kanatov. L.A. Bol`shov, V.N. Medvedev, V.F. Strizhov, A.N. Ul`yanov. Patent na izobretenie RUS 2548267. 20.04.2015 [The Method of Tension Reinforcing Ropes. L.A. Bolshov, V.N. Medvedev, V.F. Strizhov, A.N. Ulyanov. Patent for Invention RUS 2548267. 04/20/2015] (in Russian).
  7. Medvedev V.N. Kiselev Alexander S., Kiselev Alexey S., Ulyanov A.N., Strizhov V.F., Potapov E.A. Naturny`e nablyudeniya na e`tape stroitel`stva zashhitnoj obolochki e`nergobloka № 3 Rostovskoj AE`S [Field Observations at the Construction Stage of the Containment of the Power Unit No. 3 of the Rostov NPP]. Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2014. № 3 (12). P. 89-99 (in Russian).
  8. Medvedev V.N. Kiselev Alexander S., Kiselev Alexey S., Ulyanov A.N., Strizhov V.F., Salnikov A.A. Rezul`taty` ispy`tanij zashhitnoj obolochki e`nergobloka № 3 Rostovskoj AE`S [Test Results of the Containments of the Rostov NPP Power Unit No. 3  ]. Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2015 № 2 (15). P. 71-83 (in Russian).
  9. Salnikov A.A. Medvedev V.N., Kiselev Alexander S., Kiselev Alexey S., Ulyanov A.N. Strizhov V.F., Skorikova M.I. Osobennosti NDS zashhitny`x obolochek AE`S na e`tape vozvedeniya, prednapryazheniya, priemo-sdatochny`x ispy`tanij i e`kspluatacii [Features of NPP Containments at the Stage of Construction, Prestressing, Acceptance Tests and Operation].  Bezopasnost`, e`ffektivnost` i e`konomika atomnoj e`nergetiki: materialy` 11-j mezhdunar. nauchno-texnich. konf. Moskva [Safety, Efficiency and Economics of Atomic Energy: materials of the 11th International Scientific and Technical Conference Moscow]. May 23-24, 2018. Moskva [Moscow]: Rosenergoatom Concern. 2018. Р. 24-30 (in Russian).
  10. Pimshin Yu.I., Klyushin E.B., Gubeladze O.A., Medvedev V.N., Burdakov S.M., Zayarov Yu.V. Vliyanie krana krugovogo dejstviya na texnicheskoe sostoyanie stroyashhejsya zashhitnoj germetichnoj obolochki AE`S [The Effect of a Circular Action Valve on the Technical Condition of the Protective Containment of the NPP under Construction]. Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2016. № 2 (19). Р. 33-42 (in Russian).
  11. Pimshin Yu.I., Medvedev V.N., Naumenko G.A., Char V.A., Zabaznov Yu.S. Ocenka napryazhenno-deformirovannogo sostoyaniya zashhitny`x germetichny`x obolochek na primere blokov Rostovskoj AE`S [Assessment of the Stress-Strain State of Containments on the Example of the Rostov NPP Units]. Izvestiya vy`sshix uchebny`x zavedenij. Geodeziya i ae`rofotos``emka [News of Higher Educational Institutions. Surveying and Aerial Photography]. 2017. № 3. P. 36-42 (in Russian).
Papers25 - 38
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 Open Article
Article Name10.26583/GNS-2019-01-04
Assess of Possibility of Eu2O3Using as Burnable Absorber in WWER-1200 Reactor
AuthorsM.A. Abu Sondos1, V.M. Demin2, V.I. Savander3
Address

Institute of Nuclear Physics and Technology (INP&T), National Research Nuclear University «MEPhI»,

Kashirskoye shosse, 31, Moscow, Russia 115409

1ORCID ID: 0000-0003-3954-151X

Wos Researher ID: E-2735-2019

e-mail: MAbusondos@mephi.ru

2ORCID ID: 0000-0003-3894-9396

Wos Researher ID: E-2750-2019

e-mail: VMDemin@mephi.ru

3 ORCID ID: 0000-0001-9309-5616

Wos Researher ID: E-2743-2019

e-mail: VISavander@mephi.ru

AbstractThe paper deals with the problem of using burnable absorbers (BAs) in WWER reactors to reduce the volume of liquid regulation of excess fuel burnup reactivity. It considers natural europium in the form of Eu2O3, placed in an integrated form with uranium fuel in fuel rods. The analysis of nuclear and radiation safety in the use of such fuel in VVER-1200 reactors is carried out.
KeywordsTVEG, SERPENT, FA, WWER-1200, burnable absorbers, Eu2O3, Gd2O3, gamma radiation source spectrum.
LanguageRussian
References
  1. Abdelghafar Galahom A. Issledovanie vozmozhnosti ispol`zovaniya splava evropiya i Pireksa v kachestve szhigaemogo poglotitelya v PWR [Study of Possibility of Europium and Pyrex Alloy Using as Burnable Absorber in PWR]. Annaly` yadernoj e`nergii [Annals of Nuclear Energy]. Volume 110. December 2017. P. 1127-1133 (in Russian).
  2. Stogov Yu.V., Belousov N.I. Savander V.I. et al. Perspektivny`e texnologii ispol`zovaniya oksidnogo uran-gadolinievogo topliva v legkovodny`x reaktorax [Promising Technologies for the Use of Uranium-Gadolinium Oxide Fuel in Light-Water Reactors]. Materialy` XIV seminara po problemam fiziki reaktorov [Proceedings of the XIV Seminar on Reactor Physics]. Moscow: MEPhI. 2006. P. 45-47 (in Russian).
  3. Balestieri D. Issledovanie UO2/Gd2O3 toplivnoj smesi. IAEA-TECDOC-1036. Vienna (Austria). 1998. P. 63-72.
  4. Ermolin V.S., Okunev V.S. O razmeshhenii gadoliniya v central`nom otverstii tve`lov vodo-vodyany`x reaktorov [Placement of Gadolinium in the Central Opening of Water-Water Reactor Fuel Rods].  Fiziko-texnicheskie problemy` yadernoj e`nergeti [Physical and Technical Problems of Nuclear Power Engineering]. Nauchnaya sessiya MIFI [Scientific Session of MEPhI]. 2008. P. 101-102 (in Russian).
  5. Bergelson B., Belonog V., Gerasimov A. et al. Glubina vy`goraniya yadernogo topliva VVE`R s razny`mi poglotitelyami [Depth of Burn-Up of WWER Nuclear Fuel with Different Absorbers]. Atomnaya e`nergiya [Atomic Energy]. V. 109 Vol. 4 October 2010. P. 240-245 (in Russian).
  6. Vygovskii S.B., Ryabov N.Oh, Semenov A.A. et al. Fizicheskie i konstrukcionny`e osobennosti yaderny`x e`nergeticheskix ustanovok s VVE`R [Physical and Structural Features of Nuclear Power Plants with WWER]. Moskva. NIYaU MIFI [Moscow. National Research Nuclear University «MEPhI»]. 2011. 376 p. (in Russian).
  7. Jaehong Lee Jun-ichi Hori, Ken Nakajima, Tadafumi Sano & Samyol Lee. Neutron capture cross section measurements of 151,153Eu using a pair of C6D6 detectors. Pages 1046-1057 | Received 14 Oct 2016, Accepted 23 May 2017, Published online: 17 Jul 2017.
  8. Leppänen J. SERPENT – a Continuous-energy Monte Carlo Reactor Physics Burnup Calculation Code. VTT Technical Research Centre of Finland. (June 18, 2015).
  9. Chadwick M.B. , et al.ENDF/B-VII.1 nuclear data for science and technology: cross sections, covariances, fission product yields and decay data. Nucl. Data Sheets, 112 (2011). Р. 2887-2996, 10.1016/j.nds.2011.11.002.

[10]  Willman, C. 2006. Applications of Gamma Ray Spectroscopy of Spent Nuclear Fuel for Safeguards and Encapsulation. Acta Universitatis Upsaliensis. Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Science and Technology 212. 81 p. Uppsala. ISBN 91-554-6637-0.

Papers39 - 46
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 Open Article
Article Name10.26583/GNS-2019-01-05
Monitoring and Regulation System of Penetration Depth at Argon-Arc Welding of Important Products on Welding Pool Oscillation
AuthorsEh.A. Gladkov*1, N.A. Simakova**2, R.A. Perkovskij*3, T.V. Brodyagina***4
Address

* Bauman Moscow State Technical University (MSTU), 2nd Baumanskaya St., 5, Moscow, Russia, 105005

1 ORCID iD:  0000-0101-6610-8725

WoS Researcher ID: J-6791-2017

e-mail: 123777@bk.ru

3ORCID iD:  0000-0002-7512-4687

WoS Researcher ID: J-7170-2017

e-mail: proman@bmstu.ru

**Volgodonsk Engineering Technical Institute the branch of National Research Nuclear University “MEPhI”,

Lenin St., 73/94, Volgodonsk, Rostov region, Russia, 347360

2ORCID iD:  0000-0002-8599-6008

WoS Researcher ID: Y-3656-2018

e-mail: simnataalex@gmail.com

*** Certification Center of Urban Farming (TSGH), Perevedenovsky lane, 13 building 15, Moscow, Russia, 105082

4ORCID iD: 0000-0002-8609-3687

WoS Researcher ID: P-2357-20

e-mail: ac-mosgaz@yandex.ru

AbstractThe article presents the results of studies carried out to build an automatic system for regulating the depth of penetration during argon-arc welding using signals of welding pool oscillations. Methods of control and algorithms for controlling the process of argon-arc welding of critical structures by welding pool oscillations and extraction of the oscillation spectrum are proposed.
Keywordswelding pool, the amount of penetration, optical sensor, welding quality
LanguageRussian
References

[1]       Gladkov E.А., Guslistov I.A., Sas A.V. Opisanie dinamicheskih processov v svarochnoj vanne pri variacii dejstvuyushchej na gruzki [Description of Dynamic Processes in the Weld Pool with Variations in the Current Load]. Svarochnoe proizvodstvo [Welding production]. 1974. № 4. P. 11-13 (in Russian).

[2]      Ishanin G.G., Pankov Eh.D., Andreev A.L. Istochniki i priemniki izlucheniya [Radiation Sources and Receivers]. SPb Politekhnika [St. Petersburg: Polytechnic]. 1991 (in Russian).

[3]      Guslistov I.A., Gladkov Eh.A, Krichevskij E.M. Ustrojstvo dlya kontrolya velichiny proplavleniya pri svarke nerzhaveyushchih trub na stanah ADS [A Device for Controlling the Magnitude of Penetration in Welding of Stainless Steel Tubes at Mills ADS]. Svarochnoe proizvodstvo [Welding Production]. 1973. №2. P. 46-47 (in Russian).

[4]      Shirkovskij N.A., Gladkov Eh.A., Kiselev O.N. Adaptivnaya ASU processa argonodugovoj svarki trub [Adaptive Automatic Control System of the Process Of Argon-Arc Welding Pipe]. Svarochnoe proizvodstvo [Welding Production]. 1986. №11. P. 1-3 (in Russian).

[5]      Gladkov Eh.A., Shirkovskij, Kiselev O.N. i dr. Kompleks tekhnicheskih sredstv i ocenka ehffektivnosti funkcionirovaniya N.A. ASU processa argonodugovoj svarki trub [Set of Technical Tools and Evaluation of Efficiency of Functioning of Automated Control System of the Process of Argon-Arc Welding Pipe]. Svarochnoe proizvodstvo [Welding Production]. 1989. №11 P. 3-5 (in Russian).

[6]      Gladkov Eh.A., Perkovskij R.A., Kiselev O.N. Datchik velichiny proplavleniya pri svarke trubchatyh izdelij [Sensor of Penetration Value at Welding of Tubular Products]. Perspektivnye puti razvitiya svarki i kontrolya Svarka i control 2001. Tez dokl Vseros nauch-tekhn konf [Perspective Ways of Development of Welding and Control. Welding and Control 2001 : abstracts of All-Russian Science Techical Conference]. Voronezh. 2001. P. 34 (in Russian).

[7]      Smilyanskij G.L., Amlinskij L.Z., Baranov V.Ya. Spravochnik proektirovshchika ASU TP [Handbook of the APCS designer]. Pod red. G. L. Smilyanskogo. M: Mashinostroenie. 1983. P. 527 (in Russian).

[8]      Vinogradov V.A., Romanenkov E.I. Issledovanie opticheskogo izlucheniya svarochnoj dugi v argone [Investigation of Optical Radiation of Welding Arc in Argon]. Voprosy atomnoj nauki i tekhniki. Ser Svarochnoe proizvodstvo [Issues of Nuclear Science And Technology. Welding Production]. 1977. Vol. №3. P. 184-190 (in Russian).

[9]      Vinogradov V.A. Vozmozhnost kontrolya i regulirovaniya ehnergo vlozheniya v izdelie pri svarke koncentrirovannymi istochnikami nagreva s pomoshchyu opticheskih metodov [The Ability to Control and Regulate the Energy Input into the Product When Welding with Concentrated Heating Sources Using Optical Methods]. Voprosy atomnoj nauki i tekhniki. Ser Svarochnoe proizvodstvo [Issues of Nuclear Science And Technology. Welding Production]. 1982. Vol. 3. P. 91-94 (in Russian).

[10]   Poskachej A.A.,  Chubarov E.P. Optiko-ehlektronnye sistemy izmereniya temperatury [Optical-Electronic System for Measuring Temperature]. 2-e izd. Pererab. i dop. Moskva: Energoatomizdat [Moscow: Energoatomizdat]. 1988. P. 248 (in Russian).

[11]   Watkins P.V.C., Collier R., Harvey D. Pulsed arc TIG Welding. Welding Revie International. 1993. Vol. 62. N 2. P. 29-32.

[12]   Chin W., Chin B. Monitoring joint penetration using infrared sensing techniques. Welding Journal. 1990. Vol. 69. N 4. P. 181-185.

[13]   Salter R., Deam R. A practical front face penetration control system for TIG welding. Automated and Robotic Welding. 1987 Vol. 60. N 11. P. 145-156.

Papers47 - 58
URL ArticleURL Article
 Open Article
Article Name10.26583/GNS-2019-01-06
Principle of Accuracy Calculation of Measurements during Deformation Process Monitoring
AuthorsYu.I. Pimshin *1, Yu.V. Zayrov *2, G.A. Naumenko **3
Address

*Volgodonsk Engineering Technical Institute the branch of National Research Nuclear University “MEPhI”,

Lenin St., 73/94, Volgodonsk, Rostov region, Russia 347360

1ORCID iD: 0000-0001-6610-8725

WoS Researcher ID: J-6791-2017

e-mail: YIPimshin@mephi.ru

2ORCID iD: 0000-0003-3353-8037

WoS Researcher ID: G-7342-2019

e-mail: YVZayarov@mephi.ru

** Don State Technical University, Gagarin square 1, Rostov-on-Don, Russia, 344000

3ORCID iD: 0000-0002-7512-4687

WoS Researcher ID: J-7170-2017

e-mail: geodez@aaanet.ru

AbstractThe paper considers the method of determining the accuracy of geodesic measurements in the process of monitoring the technical condition of objects, provided the reliable determination of the deformation characteristics values within the normative permissible values.
Keywordsdeformation, measurement, measurement error, measured parameter, physical and mechanical properties, tolerance.
LanguageRussian
References
  1. Stolbov Yu.V. Dopuski i sredstva proverki kachestva stroitel'no-montazhnyh rabot [Tolerances and Means of Quality Control of Construction Works]. Geodezicheskie metody kontrolya toch-nosti v stroitel'stve [Geophysical Methods of Accuracy Control in Construction]. Kuibyshev: Kuibyshev state UN-T. 1983. P. 63-65 (in Russian).
  2. Spravochnik po geodezicheskim rabotam v stroitel'no-montazhnom proizvodstve [Reference for Geodesic Works in the Construction Trade]. Ed. by Y.V. Polishchuk. Moscow: Nedra. 1990.
    336 p. (in Russian).
  3. Abadzhi K.I., Druzhinin V.I., Isaev V.I. Kontrol' vzaimnogo raspolozheniya poverhnostej detalej mashin [Control of the Mutual Position of Machine Part Surfaces]. – Leningrad: Mashgiz. 1962. 116 p. (in Russian)
  4. GOST 21779-76 Sistema obespecheniya tochnosti geometricheskih parametrov.  Tekhnologicheskie dopuski geometricheskih parametrov [The system of Ensuring the Accuracy of Geometric Parameters. Technological Tolerances of Geometrical Parameters]. 1976. 11 p. URL : http://gostt.ru/Index/22/22039.htm (in Russian).
  5. Golendukhin M.A. Obosnovanie norm tochnosti na geodezicheskie razbivochnye raboty i kontrol'nye izmereniya pri stroitel'stve i ekspluatacii promyshlennyh sooruzhenij [Justification of Accuracy Standards for Geodetic Center Work and Control Measurements in the Construction and Operation of Industrial Facilities. Abstract. on competition of a scientific degree. Academic Step. Ph. D. in engineering. 05.24.01. Novosibirsk, NISI]. 1974. 23 p. (in Russian).
  6. Zhukov V.N. Normirovanie tochnosti geodezicheskih izmerenij pri vozvedenii sooruzhenij, montazhe oborudovaniya i kontrole  za ih sostoyaniem [Regulation of the Accuracy of Geodesic Measurements in the Construction of Facilities, Installation of Equipment and Monitoring of their Condition]. Izv. vuzov. Geodeziya i aerofotosemka. WPI [Higher Educational. Geodesy and Aerial Photography]. Issue.4. 1983. P. 28-35 (in Russian).
  7. Borodko A.B., Makarenko H.L., Demyanov G.V. Razvitie sistemy geodezicheskogo obespecheniya v sovremennyh usloviyah. [Development of the Geodesic Support System in Modern Conditions]. Moskva: Izvestiya vuzov. Geodeziya i aerofotosemka [Moscow: University News. Geodesy and Aerial Photography]. № 10. 2003. P. 7-13  (in Russian)
  8. Klyushin E.B., Kiselev M.I., Mikhalev D.S., Feldman V.D. Mihalev D.Sh. Inzhenernaya geodeziya [Engineering Geodesy]. Moskva: Vysshaya Shkola [Moscow: Higher school]. 2002. 480 р. (in Russian).
  9. Klyushin E.B., Zaki Mohamed Zeidan El-Sheikha, Vlasenko E.P. Sozdanie planovoj razbivochnoj osnovy na montazhnom gorizonte pri stroitel'stve zdanij povyshennoj etazhnosti [Creation of Planned Center Basis on the Installation Horizon in the Construction of High-Rise Buildings]. Izvestiya vuzov. Geodeziya i aerofotosemka [University News. Geodesy and Aerial Photography]. № 6. 2009. P. 48-54 (in Russian).
  10. Yambaev H.K., Ryazantsev G.E. Razrabotka i vnedrenie vysokotochnyh geodezicheskih izmerenij v proektirovanie i ekspluataciyu unikal'nyh inzhenernyh sooruzhenij Rossii [Development and Implementation of High-Precision Geodetic Measurements in the Design and Operation of Unique Engineering Structures of Russia]. Mezhdunarodnaya nauchno-tekhnicheskaya konferenciya, posvyashchennaya 225-letiyu MIIGAiK [International Scientific and Technical Conference Dedicated to the 225th Anniversary of MIIGAiK]. Moscow. 2004. 126 p. (in Russian).
Papers59 - 66
URL ArticleURL Article
 Open Article
Article Name10.26583/GNS-2019-01-07
Elements for Solar Batteries on the GaInAs Nanostructure Basis Obtained by Ion-Beam Deposition Method
AuthorsI.A. Sysoev*1, D.A. Gusev**2, A.E. Dembitsky**3, A.Yu. Smolin**4, V.F. Kataev**5
Address

*Federal State Autonomous Educational Institution of Higher Professional Education "North Caucasian Federal University", Pushkin street, 1, Stavropol, Russia 355009

1ORCID iD: 0000-0001-5415-0782

WoS Researcher ID: Q-1522-2015

e-mail: eianpisia@yandex.ru

**Volgodonsk Engineering-Technical Institute – Branch of NRNU «MEPhI»,

Lenin street, 73/94, Volgodonsk, Russia 347360

2ORCID iD: 0000-0002-4997-9497

WoS Researcher ID: M-9350-2016

e-mail: dmon_@mail.ru

3ORCID iD: 0000-0003-4616-621X

WoS Researcher ID: O-3133-2018

e-mail: demartev@gmail.com

4ORCID iD: 0000-0002-0148-2086

WoS Researcher ID: F-4089-2017

e-mail: smol_vol@mail.ru

5ORCID iD:0000-0001-5217-0991

WoS Researcher ID:Q-1673-2018

e-mail: kataev.v.f.@gmail.com

AbstractThe study experimentally showed the possibility of quantum dots formation based on three-component InGaAs solid solutions of various compositions on the surface of GaAs by the method of ion-beam deposition of quantum dots. The features of the technology of ion – beam deposition are considered. The optimal ratios of the of the GaInAs solid solution components are determined at which the quantum dots are characterized by the smallest dimensions, and the technological conditions are established where their density increases. The results of the study of the photoluminescence spectra and the surface morphology of the obtained nanostructures are presented. The results obtained may be of practical interest as materials for the formation of highly efficient solar cell panels on their basis, which are widely used as alternative environmentally friendly energy sources in the energy sector at present .
Keywordssolar cells, nanoscale structures, multicomponent solid solutions, ion beam deposition, technology, materials for photovoltaic cells.
LanguageRussian
References
  1. Ledentsov N.N. Geterostruktury` s kvantovy`mi tochkami: poluchenie, svojstva, lazery` [Heterostructures with Quantum Dots: Obtaining, Properties, Lasers]. Fizika i texnika poluprovodnikov [Physics and Technology of Semiconductors]. 1998. Vol. 32. Issue. 4. P. 385-410 (in Russian).
  2. Lunin L.S. Novy`e vozmozhnosti ionno-luchevy`x texnologij v zadachax polucheniya optoe`lektronny`x ustrojstv na osnove mnogokomponentny`x soedinenij A3V5 [New Possibilities of Ion-Beam Technologies in the Problems of Obtaining Optoelectronic Devices Based on A3B5Multicomponent Compounds]. Izv. vuzov. Severo-Kavkazskij region. Texn. nauki [North Caucasian Region University Bulletin Technical Science]. 2003. Special. no. P. 53-54 (in Russian).
  3. Lunin L.S. Ionno-luchevoe osazhdenie fotoaktivny`x nanosloev kremnievy`x solnechny`x e`lementov [Ionic-Beam Deposition of Photoactive Nanolayers of Silicon Solar Cells]. Neorgan. materialy`[Inorganic Materials]. 2012. T. 48. № 5. P. 517-522 (in Russian).
  4. Lunin L.S. Issledovanie fotochuvstvitel`ny`x geterostruktur InAs/GaAs s kvantovy`mi tochkami, vy`rashhenny`x metodom ionno-luchevogo osazhdeniya [Study of Photosensitive Heterostructures of InAs / GaAs with Quantum Dots Grown by the Method of Ion-Beam Deposition]. Poverxnost`. Rentgenovskie, sinxrotronny`e i nejtronny`e issledovaniya [Surface. X-ray, Synchrotron and Neutron Studies]. 2011. № 6. P. 58-62 (in Russian).
  5. Bloxin S.A. et al.  Fotoe`lektricheskie preobrazovateli AlGaAs/GaAs s massivom kvantovy`x tochek InGaAs [AlGaAs / GaAs Photoelectric Converters with an InGaAs Quantum Dot Array]. Fizika i texnika poluprovodnikov [Semiconductor Physics and Technology]. 2009. T. 43. V. 4. S. 537-542 (in Russian).
  6. Chebotarev S.N., Pashhenko A.S. Issledovanie fototoka v solnechny`x e`lementax na geterostrukturax s massivom kvantovy`x tochek [Investigation of Photocurrent in Solar Cells on Heterostructures with an Array of Quantum Dots] Izv. vuzov. Severo-Kavkazskij region. Texn. nauki. [North Caucasian Region University Bulletin Technical Science]. 2013. № 2. S. 97-99 (in Russian).
  7. Salij R.A. et al.  Opredelenie texnologicheskix parametrov rosta v sisteme InAs-GaAs dlya sinteza «mnogomodal`ny`x» kvantovy`x tochek InAs metodom gazofaznoj e`pitaksii iz metalloorganicheskix soedinenij [Determination of Technological Parameters of Growth in the InAs-GaAs System for the Synthesis of “Multimodal” InAs Quantum Dots by the Method of Gas Phase Epitaxy from Organometallic Compounds]. Fizika i texnika poluprovodnikov [Semiconductor Physics and Technology]. 2015. T. 49. V. 8 (in Russian).
  8. Blagin A.V. Fiziko-texnologicheskie osobennosti ionno-luchevogo osazhdeniya nanorazmerny`x struktur na osnove tverdy`x rastvorov A3B5 [Physico-Technological Features of Ion-Beam Deposition of Nanosized Structures Based on A3B5 Solid Solutions]. Izv. vuzov. Severo-Kavkazskij region. Texn. nauki. [North Caucasian Region University Bulletin Technical Science]. 2011. № 5. P. 125-128 (in Russian).
  9. Lunin L.S. Formirovanie kvantovy`x tochek InAs na podlozhkax GaAs metodom ionno-luchevogo osazhdeniya [Formation of InAs Quantum Dots on GaAs Substrates by Ion-Beam Deposition]. Vestn. Yuzhnogo nauch. centra RAN [Southern Scientific center of RAS Bulletin]. 2010. T. 6. № 4. P. 46-49 (in Russian).
  10. Sysoev I.A. Formirovanie massivov kvantovy`x tochek GaxIn1-xAsyP1-y/GaAs v processe ionno-luchevogo osazhdeniya [The Relationship between the Sizes of Quantum Dots in InAs-QD / GaAs with the Photoluminescence Spectrum]. Neorganicheskie materialy` [Inorganic Materials]. 2014. T 50. №3. P. 237-244 (in Russian).
Papers67 - 73
URL ArticleURL Article
 Open Article

Operation of nuclear industry facilities

Article Name10.26583/GNS-2019-01-08
The Current Digital Logical Elements and IP-Modules for Problems of Automatic Control and Monitoring of Nuclear Objects
AuthorsN.V. Butyrlagin*1, N.I. Chernov*2, N.N. Prokopenko*,**3, А.V. Bugakova*4
Address

* Don State Technical University, Gagarin sq. 1, Rostov-on-Don, Russia, 3440000

1ORCID iD: 0000-0002-6363-5113

WoS Researcher ID: B-9159-2014

Scopus Author ID: 55975353700

e-mail: nbutyrlagin@mail.ru

2ORCID iD: 0000-0002-2438-4825

WoS Researcher ID: S-3745-2016

Scopus Author ID: 56434029200

e-mail: chernovni@yandex.ru

4ORCID iD: 0000-0001-9255-0015

WoS Researcher ID: E-6820-2014

Scopus Author ID: 56543776600

e-mail: annabugakova.1992@mail.ru

* Don State Technical University, Gagarin sq. 1, Rostov-on-Don, Russia, 3440000 

**Institute for Design Problems in Microelectronics of Russian Academy of Sciences (IPPM RAS)

Sovetskaya st. 3,  Zelenograd, Russia, 124681

3ORCID iD: 0000-0001-8291-1753

WoS Researcher ID: I-6599-2013

Scopus Author ID: 25227786700

e-mail: prokopenko@sssu.ru

AbstractThe paper considers the features of designing a special electronic component base (ECB) for automatic control systems and control of nuclear power plants. Unlike classical potential digital devices, ECB of this class is based on the properties of current logic elements (CLE). A more complete and systematic presentation of the main provisions of the CLE synthesis is given. The synthesis process of functions of the main functionally complete system using sets of logical arithmetic and logical operations is described. Directions for further research in the field of current ECB are formulated. Linear representations of logical functions of Boolean and linear algebra are discussed for two-valued and three-valued logics. The basic components of CLE are considered. The schemes that implement logical operations in various bases - “truncated difference”, “difference modulus”, “comparison” as well as their combinations are presented. The advantages of CLE compared with potential digital logic elements are shown.
Keywordselectronic component base, automatic control systems, digital current structures, logic elements, representations of logical functions, two-digit logic, three-digit logic, reliability
LanguageRussian
References
  1. Dunaev V., Medvedovskij E. Sistemy avtomaticheskogo upravleniya i kontrolya dlya atomnyh ehlektrostancij [Automatic Control and Monitoring Systems For Nuclear Power Plants]. Control Engineering. Vol. 3 (45). 2013. pp. 22-31 (in Russian).
  2. Hohlov C.V., Perspektivy razvitiya otechestvennoj radioehlektronnoj promyshlennosti [Prospects for the Development of the Domestic Electronics Industry]. Radio industry. 2014. Vol. 4, pp. 9-18.
  3. Krasnikov G.Ya., Orlov O.M. Otlichitel'nye osobennosti i problemy KMOP-tekhnologii pri umen'shenii proektnoj normy do urovnya 0,18 mkm i men'she [Distinctive Features and Problems of CMOS Technology with a Decrease in the Design Standard to a Level of 0.18 Microns and Less]. «Russian nanotechnology». 2008. Vol. 3. No. 7-8, pp. 124-128 (in Russian).
  4. Bumagin A., Gulin Yu., Zavodskov S., Krivyakin V., Rutkevich A., Steshenko V., Suhorukov A., Shishkin O. Specializirovannye SBIS dlya kosmicheskih primenenij: problemy razrabotki i proizvodstva [Specialized VLSI for Space Applications: Problems of Development and Production]. ELECTRONICS: Science. Technology. Business. Vol. 1. 2010, pp. 50-56 (in Russian).
  5. Wang Z. Current-Mode CMOS Integrated Circuits for Analog Computation and Signal Processing: A Tutorial. Analog Integrated Circuits for Analog Computation and Signal Processing, 1. 1991. P. 287-295.
  6. Wayne K. Current-Mode Multiple-Valued Logic Circuits. IEEE. Journal of Solid-State. V.29. No 2, Febrary 1994, P. 95-107.
  7. Turgay T., Morgul A. Implementation of Multi-Valued Logic Gates Using Full Current-Mode CMOS Circuits. Analog Integrated Circuits and Signal Processing.  May 2004. Volume 39. Issue 2. P. 191-204.
  8. Chang Y.-H., Butler J. The design of current mode CMOS multiple-valued circuits. Proceedings of 21st International Symposium on 'Multiple-Valued Logic. Victoria. 1991. P. 130-138. DOI: 10.1109/ISMVL.1991.130718.
  9. Dvornikov O.V., Prokopenko N.N., Butyrlagin N.V., Bugakova A.V. Perspektivy primeneniya novyh mikroskhem bazovogo matrichnogo i bazovogo strukturnogo kristallov v datchikovyh sistemah [Prospects for the Application of new Microcircuits of the Basic Matrix and Basic Structural Crystals In Sensor Systems]. SPIIRAN Proceedings. Vol. 2 (45). P. 157-171 (in Russian).
  10. Malashevich D.B., Nedvoichnye sistemy v vychislitel'noj tekhnike [Non-Binary Systems in Computing]. Yubilejnaya Mezhdunarodnaya nauchno-texnicheskaya konferenciya «50 let modulyarnoj arifmetike» [Anniversary International Scientific and Technical Conference «50 Years of Modular Arithmetic»]. Zelenograd. 23-25 November. 2005. P. 599-613 (in Russian).
  11. Chernov N.I., Yugai V.Ya., Prokopenko N.N., Butyrlagin N.V. Вasic Concept of Linear Synthesis of Multi-Valued Digital Structures in Linear Spaces. Proceedings of IEEE East-West Design & Test Simposium (EWDTS’2013). Rostov-on-Don. Russia. September 27-30. 2013. Kharkov National University of Radioelectronics. P. 146-149.
  12. Andreev A.S., Shuka A.A. Vozmozhnosti preodoleniya bar'era mezhsoedinenij v mikroehlektronike [Opportunities to Overcome the Interconnect Barrier in Microelectronics]. Zarubezhnaya radioe`lektronika [Foreign Radio Electronics]. 1986. No.10. P. 3-19 (in Russian).
  13. Adamov Yu.F., Shishina L.Yu. Proektirovanie sistem na kristalle [Design of Systems on a Crystal]. Mosk. gos. in-t e`lektron. texniki (texn. un-t). Moskva : MIE`T [Moscow State Institute of  Electronic Equipment (Technical Institute). Moscow. MIET]. 2005. 163 p. (in Russian).
  14. Nemudrov V., Nemudrov V., Martin G. Sistemy na kristalle [System-on-Chip]. Proektirovanie i razvitie Moskva : Texnosfera [Design and Development. Moscow: Technosphere]. 2004. 216 p. (in Russian).
  15. Buhteev A.V., Buhteev A.V. Metody i sredstva proektirovaniya sistem na kristalle [Methods and Tools for Designing Systems on a Chip]. Chip news. 2003. No. 4. P. 4-14 (in Russian).
  16. Prokopenko N.N., Chernov N.I., Yugai V.Ya., Budyakov P.S. Logic functions representation and synthesis of k-valued digital circuits in linear algebra. 2016. 24nd Telecommunications Forum (TELFOR 2016). Belgrade. Serbia. 22-23 November 2016. P. 1-4. DOI: 10.1109/TELFOR.2016.7818892.
  17. Prokopenko N.N., Chernov N.I., Yugai V.Ya., Butyrlagin N.V. The Element Base of the Multivalued Threshold Logic for the Automation and Control Digital Devices. On International Siberian Conference on Control and Communications. SIBCON-2017. Astana. Kazakhstan. 29-30 June. 2017.  DOI: 10.1109/SIBCON.2017.7998508.
Papers74 - 89
URL ArticleURL Article
 Open Article
Article Name10.26583/GNS-2019-01-09
Compare the Result of Uncertainty Analysis in the Physical Calculations of WWER Cells in the Daily Maneuvering Schedule by GETERA and WIMS Programs
AuthorsRahman S.K. Anisur1, M.A. Uvakin2
Address

National Research Nuclear University (MEPhI), City-Moscow, Kashira Highway, House-31, 115409

1ORCID iD: 0000-0001-7803-8234

Wos Researher ID:  D-3381-2019

e-mail: ranisur01@gmail.com

2ORCID iD: 0000-0002-4917-1770

Wos Researher ID: E-1027-2019

e-mail: uvakin_ma@grpress.podolsk.ru

AbstractThis work is focused on solving real problems of a WWER reactor. The problem of simulating a fuel rod and a fuel rod with gadolinium in WWER is solved, exactly, it is analyzed for how many design layers is necessary in the fuel rod and fuel with gadolinium rod. The work contains the dependence of the deviation of the multiplication factor of neutrons from burnout. To solve these problems, the GETERA-93 and WIMS programs are used. SIMPLE FORTRAN was used for data preparation.
KeywordsFuel rod, burn up, fuel zone, fuel rod with gadolinium. GETERA-93, SIMPLE FORTRAN.
LanguageRussian
References
  1. Shotikov A.V., Savchenko V.E., Vigranenko Yu.M., Khrustalev V.A. Puti sovershenstvovaniya vodno-khimicheskogorezhimavtorogokontura AES s VVER-1000 [Ways to Improve Water-Chemical Mode of the NPP Second Circuit with WWER-1000] [News of  Tomsk Polytechnic University]. 2008. V. 312. № 2. P. 39-43 (in Russian).
  2. Averyanova S.P., Dubov A.A., Kosourov K.B., Filimonov P.E. Temperaturnoye Rregulirovaniye i manevrentnost  VVER-1000 [Temperature Regulation and Maneuverability of WWER-1000] [ Atomic Energy]. 2002. V.109, № 4. Р. 246-251(in Russian).
  3. Yerak D.Yu., Kochkin V.N., Zhurko D.A., Panfyorov P.P. Modernizatsiya program obraztsovsvideteley VVER-1000 [Modernization of Samples Witnesses Programs WWER – 1000] [History of Science and Technology]. 2013. № 8. P. 142-152 (in Russian).
  4. Shkarovsky A.N., Aksenov V.I., Serdun N.P. Analizfizicheskikh sostoyaniy reaktora VVER-1000 iupravleniyeavariynymisituatsiyami [Analysis of Physical States of
    WWER-1000 Reactor and Control of  Emergency Situation] [Proceedings of Higher Educational Institutions]. [Nuclear power]. 2005. № 3. P. 60-68 (in Russian).
  5. Getya S.I., Krapivtsev V.G., Markov P.V., Solonin V.I. [and others] Modelirovaniye temperaturnykh neunifikatorov v elemente toplivno-elementnogo topliva topliva-VVER-1000 [Modeling Temperature Nonuniformities in a Fuel-Element Bundle of  WWER-1000 Fuel Assembly] [Atomic Energy]. 2013. V.114.№ 1. Р. 69-72 (in Russian).
  6. Melikhov V.I., Melikhov O.I., Yakush S.E. [and others] Issledovaniye razresheniya borona v reaktore VVER-1000[A Study of Boron Dilution in WWER-1000 Reactor] [Thermal Engineering]. 2002. V 49. № 5. p. 372-376.
  7. Filimonov P.E., Averyanova S.P., Dubov A.A., Kosourov K.B.,
    Semchenkov Yu.M.  Rabota VVER-1200/1300 v sutochnom grafike nagruzki [WWER-1200/1300 Operation in the Daily Load Schedule] [Atomic Energy]. 2012. V.113. Issue 5. Р. 247- 252 (in Russian).
  8. Filimonov P.E., Averyanova S.P., Dubov A.A., Kosourov K.B., Semchenkov Yu.M. Temperaturnoyeregulirovaniye i manevrennost' VVER-1000 [Temperature Regulation and Maneuverability of the WWER-1000] [Atomic Energy]. 2010.V.109. issue.6.Р.198-202 (in Russian).
  9. Malyshev A.B., Efanov A.D., Kalyakin S.G. Eksperimentalnyye issledovaniya sistemy dlya passivnogo napolneniya reaktora VVER-1000 [Experimental Investigations of the System for Passive Flooding of WWER-1000 Reactor]. [Thermal Engineering]. 2002. V. 49. № 12. Р. 1032-1037 (in Russian).
  10. Vokhmyanina N.S., Zlobin D.A., Kuznetsov V.I., Lagovsky V.B. [and others] Metod offset moshchnost noyfazovoy diagrammy dlya upravleniya energovydeleniyem reaktora [Offset-Power Phase Diagram Method for Control of Reactor Energy Release] [Atomic Energy]. 2016. V.121. Issue 3. Р.123-127 (in Russian).
Papers90 - 100
URL ArticleURL Article
 Open Article
Article Name10.26583/GNS-2019-01-10
Design Version of the Device, Exact Positioning of the Gripper for Lifting the Fallen Cassettes in the WWER Reactor
AuthorsP.D. Kravchenko*1, D.N. Fedorenko**2, Y.P. Kosogova*3
Address

*Volgodonsk Engineering Technical Institute, the Branch of the National Research Nuclear University “MEPhI”, Lenin St., 73/94, Volgodonsk, Rostov region, Russia 347360

1ORCID iD: 0000-0003-3437-9998

WoS Researcher ID: G-5279-2017

e-mail: krapa21@yandex.ru

3ORCID iD: 0000-0003-3952-7814

WoS Researcher ID: Y-4338-2018

e-mail: kosogova-up@yandex.ru

**Atomspetsservis Ltd, Vosmaya Zavodskaya St., 23, Volgodonsk, Rostov region, Russia 347469

2ORCID iD: 0000-0003-2483-7801

WoS Researcher ID: G-5164-2017

e-mail: fdn999@ya.ru

AbstractThe paper presents the variant of the scheme of precise positioning of the suspension device for pointing at the fallen WWER reactor cassette. The scheme is offered instead of the applied load-lifting device with long telescopic links.
Keywordsprecise positioning, lifting device, rope suspension, double polyspast
LanguageRussian
References
  1. Kachur S.A., Shahova N.V., Halina A.A. Model` funkcionirovaniya sistemy` navedeniya peregruzochny`x mashin AE`S na osnove setej Petri [Functioning Model of the Aiming System of Shifting Machines of APP on the Basis of the Petry Nets]. E`nergeticheskie ustanovki i texnologii [Power Plants and Technologies]. 2017. VOL. 3. №2. Р. 35-40 (in Russian).
  2. Avdeev A.A., Kobelev A.M., Silnikov D.V., Efremov S.M., Pinchuk M.E., Marchenko S.A., Korobkin V.V. Mashiny` peregruzki yadernogo topliva novogo pokoleniya dlya e`nergoblokov proekta AE`S-2006 S VVE`R-1200 [Machine Overload of Nuclear Fuel for a New Generation of Power Units of NPP-2006 Project with WWER-1200]. Integral] 2010. №1.
    Р. 28-33 (in Russian).
  3. Patent RF na izobretenie. № 2380206 Rossijskaya Federaciya MPK: B23K1102, B23K1110, B23K3102, G21C310, G21C2100 [Patent of the Russian Federation for Invention № 2380206 Russian Federation B23K1102, B23K1110, B23K3102, G21C310, G21C2100]. Sposob izgotovleniya teplovy`delyayushhego e`lementa yadernogo reaktora [Method for Manufacturing of Nuclear Reactor Fuel Element]. I.G. Chapaev, A.V. Strukov, S.V. Jaichnikov, A.A. Kislitskij, A.N. Petrov, A.M. Luzin, P.M. Jurin. Zayavitel` i patentoobladatel` otkry`toe akcionernoe obshhestvo «Novosibirskij zavod ximkoncentratov» [Applicant and Patentee of the Company «Novosibirsk Plant of Chemical Concentrates»]. № 2007108867/02. Appl. 09.03.2007. Publ. 27.01.2010 (in Russian).
  4. Margolin B.Z., Yurchenko V., Kostylev V.I., Morozov А.М., Varovin A.Y., Rogozkin S.V.,
    Nikitin А.А. Radiation embrittlement of support structure materials for WWER RPVS. Journal of nuclear materials. Elsevier Science Publishing Company. Inc. 2018. VOL. 508. Р. 123-138 (in English).
  5. Yablonovskiy. I.M. Veroyatnostny`j analiz bezopasnosti peregruzochnoj kanatnoj mashiny` dlya reaktorov tipa VVE`R [Probabilistic Analysis of Safety of Shifting Rope Machine for the WWER Reactors]. Tyazheloe mashinostroenie [Heavy Mechanical Engineering]. 2008. № 3. Р. 5-8 (in Russian).
  6. Lapkis A.A., Nikiforov V.N., Pugacheva O.Yu. Osobennosti prodleniya sroka e`kspluatacii peregruzochny`x mashin e`nergoblokov s reaktorami VVE`R-1000 [Operation Extension Features of Overload Machines of WWER -1000 Reactors Power Units]. Globalnaya yadernaya bezopasnost [Global nuclear safety]. 2016. № 1 (18). Р. 95-103 (in Russian).
  7. Zhemchugov G.A., Kazachkov A.N., Portnoy Y.T., Smirnitskii M.A. Novoe pokolenie kompleksa e`lektrooborudovaniya dlya peregruzochny`x mashin AE`S s reaktorami tipa VVE`R-1000 [New Generation of Complex Electrical Equipment for Reloading Machines of NPPs with WWER Reactors]. Voprosy` e`lektromexaniki. Trudy` VNIIE`M [Questions of Electromechanics. Proceedings VNIIEM]. 2004. Vol. 101. P. 200-218 (in Russian).
  8. Lapkis A.A., Nikiforov V.N.,  Pervushin L.A. Vibroakusticheskaya pasportizaciya rezhimov raboty` mashin peregruzochny`x e`nergoblokov VVE`R [Vibroacoustical Certification of Operating Modes of WWER Fuel-Handling Machines]. Globalnaya yadernaya bezopasnost [Global Nuclear Safety]. 2018. № 2 (27). Р. 82-90 (in Russian).
  9. Panasenko N.N., Asadulin R.K. Optimizaciya amplitudno-chastotny`x xarakteristik metallokonstrukcij pod``emno-transportny`x mashin [Optimization of Amplitude-Frequency Characteristics of Metal Structures of Hoisting-and-Transport Machines]. Vestnik Astraxanskogo gosudarstvennogo texnicheskogo universiteta [Bulletin of Astrakhan State Technical University]. 2005. №2 (25). P. 71-80. (in Russian).
  10. Korobkin V.V., Povarov V.P. Informacionno-upravlyayushhaya sistema mashiny` peregruzochnoj novogo pokoleniya [A New-Generation Information Controlling System for the Refueling Machine]. Izvestiya vy`sshix uchebny`x zavedenij. Yadernaya e`nergetika [News of Higher Educational Institutions. Nuclear Power]. 2017. №3. Р. 98-107 (in Russian).
  11. Kravchenko P.D. Innovacionny`e proektny`e resheniya v atomnom mashinostroenii [Innovative Design Solutions in Nuclear Engineering]. Globalnaya yadernaya bezopasnost [Global nuclear safety]. 2012. № 4 (5). P. 60-65 (in Russian).
  12. Kravchenko P.D., Fedorenko D.N. Heuristic Method of Design of the Load Gripping and Manipulating Devices For Work In Special Conditions. International Journal of Applied Engineering Research ISSN 0973-4562 Volume 10, Number 6. 2015. Р. 14537-14542 (in English).
  13. Kravchenko P.D., Malyarenko, A.D. Problema sovershenstvovaniya transportno-texnologicheskogo oborudovaniya v atomnom mashinostroenii na primere peregruzochnoj mashiny` [The Challenge of Improving Transport and Technological Equipment in Nuclear Power Engineering; Handling Machine]. Globalnaya yadernaya bezopasnost [Global Nuclear Safety]. 2016. № 1 (18). Р. 87-94 (in Russian).
  14. Kravchenko P.D., Fedorenko D.N. New Engineering Decisions in Nuclear Engineering. ARPN Journal of Engineering and Applied Sciences ISSN 1819-6608 VOL. 11, № 3, February. 2016. Р. 1951-1955 (in English).
  15. Patent RF na izobretenie № 2332729 Rossijskaya Federaciya S1 MPK G 21 C 3/00 (2006.01). Podvesnoe avtomaticheskoe ustrojstvo povorota i zaxvata probki penala [Patent of the Russian Federation for Invention № 2332729 Russian Federation C1, IPC G 21 C 3/00 (2006.01). Suspended Automatic Device for Turning and Capturing the Plug of Case]. P.D. Kravchenko, I.M. Yablonovskiy, M.S. Mahalasa. Zayavitel` i patentoobladatel` Yuzhno-Ros. gos. un-t e`konomiki i servisa [Applicant and Patentee of the South Russian State University of Economics and Service]. №2007111699/06; Appl. 29.03.2007; Publ. 27.08.2008. Byul. № 24 (in Russian).
Papers101 - 105
URL ArticleURL Article
 Open Article
Article Name10.26583/GNS-2019-01-11
Using Entropy Methods of Processing Video Images to Control NPP Equipment
AuthorsO.E. Draka*1, E.A. Abidova*2, A.V. Chernov*3, O.I. Beysug*4, A.V. Blagin**5
Address

*Volgodonsk Engineering Technical Institute the branch of National Research Nuclear University “MEPhI”,

Lenin St., 73/94, Volgodonsk, Rostov region, Russia 347360

1ORCID iD: 0000-0002-3397-6830

Wos Researher ID: О-2222-2018

e-mail: oed17@mail.ru 

2ORCID iD: 0000-0003-0258-5543

Wos Researher ID: O-1870-2018

e-mail: e-abidova@mail.ru 

3ORCID iD: 0000-0003-2700-0898

Wos Researher ID: G-3742-2017

e-mail: chernov.alexander47@mail.ru 

4ORCID iD: 0000-0001-9218-9354

Wos Researher ID: O-6513-2018

e-mail: beisug@rambler.ru 

**Don State Technical University, Gagarin square, 1, Rostov-on-Don, Russia 344000

5ORCID iD: 0000-0002-1349-8528

Wos Researher ID: B-3843-2016

e-mail: a-blagin@mail.ru

AbstractThe purpose of the study is to study the possibility of Renyi entropy applying to monitor the condition of nuclear power plant equipment and the ability to detect faults in this equipment. In the present work processing of video images obtained with the help of a thermal imaging control system at Rostov NPP is performed. For this purpose a program is developed for the Renyi entropy calculating of the 0th, 1st, and 2nd orders for video images, as well as an analysis of the time variations of the 0-order, 1-order, 2-order Renyi entropy for detecting malfunctions in nuclear power plant equipment. Calculation of entropy indicators allows to obtain important qualitative and quantitative information about the structure of complex physical systems, the features of their dynamic evolution and about the physical processes taking place in such systems.
Keywordsthermal imaging control, digital image recording, Renyi entropy, nuclear power plant
LanguageRussian
References
  1. Klimontovich Yu.L. Vvedenie v fiziku otkry`ty`x sistem [Introduction to the Physics of Open Systems] Mosсow. Janus-K. 2002. 284 р. (in Russian).
  2. Tarynin I.V., Madarov A.V. Izv. Volgograd. Gos. Tekhn. Univ. 2014. V.6. No. 18 (145). P. 98-102 https://elibrary.ru/item.asp?id=22621685 (in Russian).
  3. Vavilov V.P. Infrakrasnaya termografiya i teplovoj kontrol` [Infrared Thermography and Thermal Control]. Mosсow. Id Spectrum, 2009. 544 p. (in Russian).
  4. Chumak, O.V. E`ntropiya i fraktaly` v analize danny`x [Entropy and Fractals in Data Analysis]. Mosсow – Izhevsk. [SRC "Regular and Chaotic Dynamics" Institute for Computer Research]. 2011. 164 p. (in Russian).
  5. Mandelbrot B.B. Samoaffinny`e fraktal`ny`e mnozhestva [Self-Affine Fractal Sets]. Fraktaly` v fizike  [Fractals in Physics]. Moscow. Mir, 1988. 672 p. (in Russian).
  6. Ikhlazov S.Z. Jmsk. Nauch. Vestn. 2012. N. 2 (110). P. 235-239 https://elibrary.ru/item.asp?id=17879234 (in Russian).
  7. Abidova E.A., Hegay L.S., Chernov A.V., Draka O.E., Pugacheva O.Yu. Diagnostirovanie e`lektroprivodnoj apparatury` s ispol`zovaniem e`ntropijny`x pokazatelej [Diagnosis of Electric Drive Equipment Using Entropy Indicators]. Global`naya yadernaya bezopasnost` [Global Nuclear Security]. 2016. N. 4. FROM. 69-77 (in Russian).
  8. Abidova E.A., Soloviev V.I., Draka O.E., Hegay L.S., Chernov A.V., Pugacheva O.Yu. Obrabotka izobrazhenij v sisteme diagnostiki dizel`-generatorov AE`S s ispol`zovaniem e`ntropijny`x podxodov  [Image Processing in the System of Diagnostics of Diesel Generators of Nuclear Power Plants Using Entropy Approaches] Yadernaya fizika i inzhiniring [Nuclear Physics and Engineering]. 2017. N.  2. P. 1-6 (in Russian).
  9. Abidova E.A. Hegay L.S., Chernov A.V., Bulava V.A., Soloviev V.I., Pugacheva O.Yu. Diagnostirovanie dizel`-generatornogo oborudovaniya AE`S s ispol`zovaniem determinirovanny`x i stoxasticheskix metodov [Diagnosis of Diesel-Generator Equipment of Nuclear Power Plants Using Deterministic and Stochastic Methods] Global`naya yadernaya bezopasnost` [Global Nuclear Security]. 2016. N. 3 (20). P. 74-79 (in Russian).
  10. Abidova, E.A., Hegay L.S., Chernov A.V., Pugacheva O.Yu. Diagnostirovanie e`lektroprivodnoj armatury` s ispol`zovaniem e`ntropijny`x pokazatelej [Diagnosis of Electric Drive Armature Using Entropy Indicators]. Global`naya yadernaya bezopasnost` [Global Nuclear Security]. 2016. N. 4 (21). P. 69-77 (in Russian).
Papers106 - 112
URL ArticleURL Article
 Open Article
Article Name10.26583/GNS-2019-01-12
Assessment of Erosion and Corrosion Deterioration Development Using Magnetic Anisotropy Measurement Method
AuthorsA.K. Adamenkov1, I.N. Veselova2, V.Y. Shpitser3
Address

Volgodonsk Engineering Technical Institute the branch of National Research Nuclear University «MEPhI»

Lenin St., 73/94, Volgodonsk, Rostov region, Russia 347360

  1. ORCID iD:  0000-0001-7342-0231

WoS Researcher ID:

e-mail:

2 ORCID iD: 0000-0001-5867-5690

WoS Researcher ID:

e-mail: INVeselova@mail.ru

3ORCID iD: 0000-0002-5051-5091

e-mail: shpitser@mail.ru

AbstractThis article presents information on assessment of erosion and corrosion deterioration development of pipeline components using the magnetic anisotropy measurement method. The purpose of the research is fixing of locally stressed areas which are typical for local wall thinning in zones with probable erosion and corrosion deterioration and determination of magnetic anisotropy parameters as well as formation of measurement results database.
Keywordspipelines, thickness, erosion and corrosion deterioration, magnetic anisotropy
LanguageRussian
References
  1. RD EO 1.1.2.11.0571.2015 Normy dopuskaemyh tolshchin stenok ehlementov truboprovodov iz uglerodistyh stalej pri ehrozionno-korrozionnom iznose [1 RD EO 1.1.2.11.0571-2015 "Standarts of Allowable Wall Thicknesses of Carbon Steel Pipeline Elements during Erosion and Corrosion Wear"]. Moskva [Moscow], VNIIAS. 2015. P. 210 (in Russian).
  2. PNAE G-7-002-86 Normy rascheta na prochnost oborudovaniya i truboprovodov atomnyx energeticheskix ustanovok (s izmeneniyami ot 10.07.87) [PNАE G-7-002-86 Standards for Strength Calculation of Equipment and Pipelines of Nuclear Power Plants (as amended July 10, 1987).] – URL: http://docs.cntd.ru/document/1200037730 (in Russian).
  3. PNAE G-10-012-89 Normy rascheta na prochnost stalnyx zashhitnyx obolochek atomnyx stancij [PNАE G-10-012-89 Standards for Strength Calculation of Steel Protective Shells of Nuclear Power Plants.]. – URL: http://docs.cntd.ru/document/1200059848 (in Russian).
  4. Raschet texnologicheskogo truboprovoda. Internet-resurs [Calculation of the Technological Pipeline. Internet Resource]. – URL: https://proektanti.ru/user/work/34973 (in Russian).
  5. Skaner mexanicheskix napryazhenij «STRESSVISION» Expert versiya 2.013 Pasport FL 413.175.001 PS, TU 4276-007-82237826-13 [STRESSVISION Mechanical Stress Scanner Expert version 2.013. Passport FL413.175.001 PS, TU 4276-007-82237826-13]. URL: https://subscribe.ru/archive/tech.tdndt/201406/16144652.html (in Russian).
  6. Wilson J., Liu J., Karimian N., Davis C.L., Peyton A.J. Assessment of mi-crostructural changes in Grade 91 power station tubes through permeability and magnetic Barkhausen noise measurements. ECNDT 2014. October 6-10. 2014. Prague. Czech Republic.
  7. Gurin S.A., Zhukov V.S., Zhukov S.V., Kopicza N.N. Skanery-defektoskopy serii «Kompleks-2»: novye modeli [Flaw Detector Scanners of the “Complex-2” Series: New Models]. V mire NK [In the World of NK]. – 2004. – № 2(24). – P. 31-33 (in Russian).
  8. Barkovskij S.S. [i dr.].  Mnogomernyj analiz dannyx metodami prikladnoj statistiki [Multivariate Data Analysis Methods of Applied Statistics]. Kazan: Izd. KGTU [Kazan: KSTU Publishing House]. – 2010. – 126 p. (in Russian).
  9. Lin J.M., Lin J.C., Sha H. A new non-destructive testing technique based on magnetic memory effect. Chinesse J. NDT. 2000. Vol. 22. No. 7. P. 297-299.
  10. Zhukov S.V. K voprosu o neobxodimosti izmereniya napryazhenij [On the Need for Measuring Stresses]. Texnicheskaya diagnostika i nerazrushayushhij control [Technical Diagnostics and Non-Destructive Testing]. – URL: http://www.td.ru/content/view/68/20/.-2007  (in Russian).
Papers113 - 119
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Article Name10.26583/GNS-2019-01-13
Responsibility for Stealing or Extortion of Nuclear Materials and Radioactive Substances
AuthorsN.S. Aleksandrova
Address

Dimitrovgrad engineering and technological Institute the branch of the National Research

Nuclear University “MEPhI”, Kuibyshev St., 294, Dimitrovgrad, Ulyanovsk region, Russia 433512

ORCID iD: 0000-0002-0499-2161

WoS Researcher ID: Т-5294-2018

e-mail: nadezhdaleksandrova@yandex.ru

AbstractThe Russian Federation Criminal Code provides for responsibility for stealing or extortion of nuclear materials and radioactive substances in order to ensure nuclear and radioactive safety and protection of especially dangerous objects from potential threats. The article presents an analysis of this crime taking into account the changes made to the current criminal legislation. The author considers the problems associated with the use of the analyzed crime and makes proposals for their legislative solution.
Keywordsradioactive substances, nuclear materials, stealing, extortion, special rule, self-interest, nuclear energy, subject of the crime, subject, method.
LanguageRussian
References
  1. Ukaz Prezidiuma Verhovnogo Soveta RSFSR ot 30 marta 1988 g [The Decree of the of the Supreme Soviet Presidium of the RSFSR, March 30, 1988]. Vedomosti VS RSFSR [Gazette of the Supreme Soviet of the RSFSR]. 1988. № 14. Art. 396 (in Russian).
  2. Konvenciya o fizicheskoj zashchite yadernogo materiala i yadernyh ustanovok, prinyataya OON 26 oktyabrya 1979 g. [Convention on the Physical Protection of Nuclear Material and Facilities adopted by the UN on 26 October 1979]. Dejstvuyushchee mezhdunarodnoe pravo [Existing International Law]. Moskva. Moskovskij nezavisimyj institut mezhdunarodnogo prava [Moscow Independent Institute of International Law]. Vol. 3. 1997. P. 30-38 (in Russian).
  3. Ugolovnyj kodeks Rossijskoj Federacii (s izm. na 29.07.2018) [The Russian Federation Criminal Code (as amended on 29.07 2018.)] Moskva. Prospekt [Moscow. Prospectus] 2018. 186 p. (in Russian).
  4. Federal'nyj zakon ot 09.02.1999 № 26 - FZ "O vnesenii izmenenij i dopolneniya v Ugolovnyj kodeks Rossijskoj Federacii" [The Federal Law of 09.02.1999 № 26 - The Federal law "About Amendments and Additions to the Russian Federation Criminal Code"]. Rossiyskaya Gazeta [The Russian Newspaper]. № 27, 12.02.1999 (in Russian).
  5. Ugolovnyj kodeks respubliki Belarus' [The Republic of Belarus Criminal Code]. URL: http://pravo.kulichki.com/vip/uk/00000024.htm (in Russian).
  6. Ugolovnyj kodeks Kyrgyzskoj Respubliki [Criminal Code of the Kyrgyz Republic]. URL: http://cbd.minjust.gov.kg/act/view/ru ( in Russian).
  7. Federal'nyj zakon ot 21 noyabrya 1995 g. № 170 – FZ "Ob ispol'zovanii atomnoj energii" (s izm. ot 3 avgusta 2018 g.) [The Federal Law of November 21, 1995 № 170 – The Federal law "The Use of Atomic Energy" (as amended from August 3, 2018)]. Rossiyskaya Gazeta [The Russian Newspaper]. № 230. 28.11.1995 (in Russian).
  8. Postanovlenie Pravitel'stva RF ot 19 iyulya 2007 g. № 456 (red. 05.07.2018) Ob utverzhdenii Pravil fizicheskoj zashchity yadernyh materialov, yadernyh ustanovok i punktov hraneniya yadernyh materialov [Resolution of the Russian Federation Government of July 19, 2007 № 456 (ed. 05.07.2018) Approval of the Rules of Physical Protection of Nuclear Materials, Facilities and Nuclear Material Storage Facilities] Sobranie zakonodatel'stva RF [Collection of the Russian Federation Legislation], 30.07.2007. № 31. Art. 4081 (in Russian).
  9. Pis'mo GTK RF ot 27.01.1997g. № 2-12/1441 "O vremennom razmeshchenii Gos-atomnadzora Rossii pri vvoze (vyvoze) yadernyh materialov i radioaktivnyh veshchestv" (oficial'no ne byl opublikovan) [The Letter of the State Customs Committee of the Russian Federation of 27.01.1997 No. 2-12 // 1441 "Temporary Placement of Gosatomnadzor of Russia at Import (Export) of Nuclear Materials and Radioactive Substances"(it wasn't published officially)]. URL: http://base.garant.ru/738046/ (accessed 08.10.2018) (in Russian).
  10. Ugolovnyj kodeks Kazahstana [Criminal Code of Kazakhstan]. Moskva. Yurist [Moscow. Lawyer]. 2015. 228 p. (in Russian).
Papers120 - 123
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Article Name10.26583/GNS-2019-01-14
Effective Training Practices for Rosatom Export-Oriented Strategy Implementation
AuthorsV.A. Rudenko1, M.V. Golovko 2, Y.A. Evdoshkina3, N.P. Vasilenko4
Address

Volgodonsk Engineering Technical Institute the branch of National Research Nuclear University “MEPhI”,

Lenin St., 73/94, Volgodonsk, Rostov region, Russia 347360

1ORCID iD: 0000-0002-6698-5469

WoS Researcher ID: B-7730-2016

e-mail: VARudenko@mephi.ru

 2ORCID iD: 0000-0002-4835-9800

WoS Researcher ID: J-2461-2016

e-mail: MVGolovko@mephi.ru

3ORCID iD: 0000-0002-6704-0643

WoS Researcher ID: G-8379-2017

e-mail: YAEvdoshkina@mephi.ru

4ORCID iD: 0000-0001-7054-1302

WoS Researcher ID: G-4963-2017

e-mail: NPVasilenko@mephi.ru

AbstractThe article is devoted to the substantiation of the leading role of the supporting universities of the Rosatom State Nuclear Energy Corporation (Rosatom State Corporation) and their regional branches in the territories where nuclear power facilities are located in the formation of a high level of safety culture among future nuclear plant staff in Russia and abroad in technical, socio-cultural and economic aspects. The need to analyze effective tools is updated by the development of Rosatom State Corporation export-oriented strategy. Analysis of data from sociological surveys, historical references, materials provided by organizations, and previous researches by a group of authors revealed an effective approach to building a safety culture among foreign students. It is based on the multilateral cooperation of the educational organization with the industrial enterprises of the Rosatom Group of Companies, the machine-building cluster as well as its specialization within the framework of the distributed campus of the state institution high school.
Keywordssafety culture, Rosatom State Corporation, Rosenergoatom Concern JSC, export-oriented strategy, resource center, personnel training.
LanguageRussian
References
  1. Kadry`. Projti ne poskol`znut`sya [Personnel. Go not to Slip]. Rose`nergoatom [Rosenergoatom]. 2017. № 7. P. 27 (in Russian).
  2. Golovko, M.V., Rudenko V.A. Korporativny`e cennosti v sisteme ustojchivogo razvitiya i bezopasnosti e`konomiki promy`shlenny`x predpriyatij (na primere GK «Rosatom») [Corporate Values in the System of Sustainable Development and Economic Security of Industrial Enterprises (on the example of Rosatom)]. Global`naya yadernaya bezopasnost` [Global nuclear safety].  2015. № 4 (17). P. 103-114  (in Russian).
  3. Golovko, M.V. Razvitie kul`tury` e`konomicheskoj bezopasnosti kak instrument bor`by` s rentoorientirovannoj tenevoj e`konomikoj [Development of Economic Security Culture as a Tool to Combat Rent-Oriented Shadow Economy]. Sovremennost`: xozyajstvenny`e algoritmy` i praktiki: monografiya [Modernity: Economic Algorithms and Practices: monograph]. Moskva ; Tambov : Izdatel`skij dom TGU im. G.R. Derzhavina [Moscow ; Tambov : Publishing house of Derzhavin TSU.] 2016. P. 407-411 (in Russian).
  4. The annual report for 1986 (IAEA). International Atomic Energy Agency: официальный сайт. – 1987. URL : http://www.iaea.org/About/Policy/GC/GC31/GC31Documents/English/gc31-800_en.pdf – 11.03.2017.
  5. Razvitie kul`tury` bezopasnosti v yadernoj deyatel`nosti: Prakticheskie sovety` po dostizheniyu progressa [Development of Safety Culture in Nuclear Activities: Practical Advice on Progress]. Seriya «Otchety` po bezopasnosti» [A series of "Safety Reports"]. MAGATE ` [IAEA]. Vena [Vienna], 1998.
  6. Three Mile Island Accident. World Nuclear Association, March 2001.
  7. Walker J. Samuel Three Mile Island: A Nuclear Crisis in Historical Perspective Berkeley: University of California Press, 2004, 231 p.
  8. Abramova V.N. [and others]  Psixologicheskie metody` v rabote s kadrami na AE`S [Psychological Methods in the Work with Personnel at Nuclear Power Plants]. Moskva [Moscow].  E`nergoatomizdat. 1988. 192 p. (in Russian).
  9. Badyaev V.V., Egorov Yu.A., Kazakov S.V. Oxrana okruzhayushhej sredy` pri e`kspluatacii AE`S [Environmental Protection during Operation of Nuclear Power Plants]. Moskva [Moscow].  E`nergoatomizdat. 1990. 224 p. (in Russian).
  10. Lozanovskaya I.N., Orlov D.S., Sadovnikova L.K. E`kologiya i oxrana biosfery` pri ximicheskom zagryaznenii [Ecology and Conservation of the Biosphere under Chemical Pollution]. Moskva [Moscow]. 1998. (in Russian).
  11. L`vov L.V. Fedorov M.P., Shul`man S.G. Nadezhnost` i e`kologicheskaya bezopasnost` gidroe`nergeticheskix ustanovok [Reliability and environmental safety of hydropower plants] Sankt-Peterburg [St. Petersburg]. 1999. 440 p. (in Russian).
  12. Klyuchevy`e voprosy` praktiki povy`sheniya kul`tury` bezopasnosti: INSAG-15 [Key Issues of Safety Culture Improvement Practice]. Doklad Mezhdunarodnoj konsul`tativnoj gruppy` po yadernoj bezopasnosti [Report of the International Advisory Group on Nuclear Safety]. Vena : Mezhdunarodnoe agentstvo po atomnoj e`nerg [Vienna : International Nuclear Energy Agency]. 2002. 24 p.
  13. Zhuk A.V., Golovko M.V., Evdoshkina Yu.A. Otechestvennaya i zarubezhnaya istoriografiya  problem kul`tury` bezopasnosti v atomnoj e`nergetike [Domestic and Foreign Historiography of Safety Culture Problems in Nuclear Power Engineering].  Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2017. № 1 (22). P. 113-121 (in Russian).
  14. Bogdanov A.A. Tektologiya: vseobshhaya organizacionnaya nauka [Tectology: Universal Organizational Science]. Moskva : E`konomika [Moscow : Economy]. 1989. P. 106 (in Russian).
  15. Yanev Ya. Vy`zovy` i vozmozhnosti [Challenges and Opportunities]. 2017. № 9. P. 39 (in Russian).
  16. Shapovalova I. Kar`era nachinaetsya v shkole [Career Starts at School]. Rose`nergoatom. 2018. № 10. P. 41 (in Russian).
  17. Dmitriev N.M.,  Aref`ev P.A. Podgotovka specialistov dlya atomnoj promy`shlennosti zarubezhny`x stran v NIYaU MIFI [Training of Specialists for the Nuclear Industry of Foreign Countries in MEPhI]. Moskva : CzSPiM [Moscow : CSEM] 2018. 264 p. (in Russian).
  18. Rudenko V.A., Vasilenko N.P. Kompetentnostny`j podxod v vospitanii kul`tury` bezopasnosti v vuze [Competence Approach in the Education of Safety Culture at the University]. Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2012. № 2-3(4). P. 136-141 (in Russian).
  19. Rudenko V.A., Vasilenko N.P. Prakticheskie metody` formirovaniya priverzhennosti kul`ture bezopasnosti na individual`nom urovne u studentov vuza [Practical Methods of Formation of Commitment to the Safety  Culture at the Individual Level of University students]. Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2013. № 1 (6). P. 100-103 (in Russian).
  20. Rudenko V.A., Vasilenko N.P. Cennostnaya sostavlyayushhaya kul`tury` bezopasnosti [Value Component of Safety Culture]. Global`naya yadernaya bezopasnost` [Global Nuclear Safety]. 2013. № 4 (9). P. 82-86 (in Russian).
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