Title of the article THE POSSIBILITIES OF THE ENTERPRISE. ISSUE OF MOTOR VECHICLES FOR MILITARYTECHNICAL PURPOSES
Authors

NIKOLAEV Yu.I., Chief Designer, Minsk Wheel Tractor Plant (MWTP), Minsk, Republic of Belarus

In the section TECHNICAL INFORMATION
Year 2015 Issue 2 Pages 97-102
Type of article RAR Index UDK 629.114 Index BBK  
Abstract The report presents the technical capabilities of JSC "Minsk Wheel Tractor Plant" and the overview of produced motor vehicles for military-technical purposes.
Keywords technological capacity of the enterprise, special wheeled chassis and wheel tractor, multi-purpose vehicles, technical requirements, hydromechanical transmissions, independent wheel suspension
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Title of the article ABOUT DEVELOPMENT OF REPRESENTATIONS ABOUT FATIGUE OF METALS AT VOLUME AND SURFACE (CONTACT) DEFORMATION
Authors

SOSNOVSKIY Leonid A., Dr. Techn. Sc., Professor, Professor of the Department "Dynamics, Strength and Durability of Vehicles", Belarusian State University of Transport, Gomel, Republic of Belarus

In the section MECHANICS OF TRIBO-FATIGUE SYSTEMS
Year 2015 Issue 2 Pages 85-96
Type of article RAR Index UDK 620.178.16; 620.178.3 Index BBK  
Abstract Concept development about fatigue of metals in communication of its integrated characteristic-curve of fatigue is described at volume deformation (and destruction), surface damage (and wear) at contact loading and complex wear-fatigue damage and destruction to a case when one of elements of pair a friction perceives and transfers repeatedly-variable (volume) loading. It is shown that concept fatigue - fundamental and beyond all bounds wide; it is successfully used for terminology construction in the mechanic of fatigue destruction, tribology, tribo-fatigue.
Keywords fatigue, volume deformation, surface deformation, mechanical fatigue, rolling fatigue, friction fatigue, fatigue curve, diagram of limiting states, wear-fatigue damage
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Bibliography
  • Wohler A. Versuche zur Ermittlung der auf die Eisenbahnwagensachsen einwirkenden Krafte und die Widerstandsfahigkeit der Wagen-Achsen. Zeitschrift fur Bauwessen, 1860, vol. X, pp. 583-616.
  • Poncelet J.V. Introduction a la Mecanique Industrielle, Physique ou Experimentale. Zweite Ausgabe. Paris, Imprimerie de Gauthier-villars, 1839.
  • Sosnovskiy L.A., Makhutov N.A., Troshchenko V.T. Evolution of ideas on fatigue of metals by volume loading and friction. Trudy 6 Mezhdunarodnogo simpoziuma po tribofatike [Proc. of VI International Symposium on Tribo-Fatigue (ISTF 2010)]. Minsk, 2010, vol. 1, pp. 77-84.
  • Schutz W. A History of Fatigue. Engineering Fracture Mechanics, 1996, pp. 263-300.
  • Duncan Dowson. History of Tribology. Professional Engineering Publishing, 1997.
  • Andronov P.V. [et al.], Sosnovskiy L.A. ed. Tribofatika [Tribo-fatigue]. Minsk-Gomel, 1996. 138 p.
  • GOST 30638-99. Tribofatika. Terminy i opredelenija: mezhgos. standart [State Standard 30638-99. Tribo-Fatigue. Terms and definitions (Interstate Standard)]. Minsk, 1999. 17 p.
  • Sosnovskiy L.A. O principah razrabotki standarta Belarusi STB "Tribofatika. Terminy i opredelenija" [On the principles of development of the standard of Belarus STB "Tribo-Fatigue. Terms and definitions"]. Tribofatika-95: Ezhegodnik [Tribo-Fatigue-95: Annual]. Gomel, 1996, pp. 8-26.
  • Gough H.J. The fatigue of metal. London, 1926. 304 p.
  • Fairbrain W. Experiments to determine the effect of impact, vibratory action and long continued changes of load of wrought iron girders. Phil. Trans. R. Soc., 1864, 311-325.
  • Hele-Show H.S. Human endurance curves. Proc. Inst. Mech. Eng., vols. III-IV, 1911.
  • Sosnovskiy L.A. Tribofatika: o dialekte zhizni [Tribo-Fatigue: about the dialectics of life]. Gomel, 1999. 116 p.
  • Sosnovskiy L.A., Makhutov N.A. O polnoj krivoj ustalosti [About full fatigue curve]. Zavodskaja laboratorija [Industrial Laboratory], 1995, no. 5, pp. 33-34.
  • Sosnovskiy L.A. Mehanika ustalostnogo razrushenija [The mechanics of fatigue fracture]. Gomel, 1994, vol. 1. 328 p., vol. 2. 340 p.
  • Troshenko V.T., ed. Ustalost' metallov. Vlijanie sostojanija poverhnosti i kontaktnogo vzaimodejstvija [Metal fatigue. Influence of surface condition and contact interaction]. Prochnost' materialov i konstrukcij: serija monogr. [Strength of Materials and Structures: Monograph Series]. Kiev, vol. 2, 2009. 664 p.
  • Kragelsky I.V., Dobychin M.N., Kombalov V.S. Osnovy raschetov na trenie i iznos [The basis of calculation for friction and wear]. Мoscow, 1977. 526 p.
  • Chichinadze A.V., ed. Osnovy tribologii [Fundamentals of tribology]. Moscow, 2001. 663 p.
  • Sysoev P.V., Bogdanovich P.N., Lizarev A.D. Deformacija i iznos polimerov pri trenii [Deformation and wear of the friction polymers]. Minsk, 1985. 239 p.
  • Preece K., ed. Jerozija [Erosion]. Moscow, 1982. 464 p.
  • Sosnovskiy L.A. Radiacionnoe povrezhdenie [Radiation damage]. Soprotivlenie materialov deformirovaniju i razrusheniju [Resistance materials deformation and destruction]. Kiev, 1994, vol. 2, pp. 302-327.
  • Zharin A.L. Metod kontaktnoj raznosti potencialov i ego primenenie v tribologii [Contact potential difference method and its application in tribology]. Minsk, 1996. 235 p.
  • Sosnovskiy L.A., Makhutov N.A., Marchenko A.V. O postroenii krivoj frikcionnoj ustalosti [On the construction of the curve friction fatigue]. Zavodskaja laboratorija [Factory Laboratory], 1998, no. 12, pp. 36-39.
  • Sosnovskiy L.A., Marchenko A.V. Frikcionnaja ustalost' polimera pri trenii po stali [Friction fatigue polymer in friction against steel]. Problemy prochnosti [Strength of Materials], 2001, no. 1, pp. 48-61.
  • Sosnovskiy L.A. Osnovy tribofatiki [Fundamentals of Tribo-Fatigue]. Gomel, 2003, vol. 1. 246 p., vol. 2. 234 p.
  • Sosnovskiy L.A., ed. Iznosoustalostnye povrezhdenija i ih prognozirovanie (tribofatika) [Wear-fatigue damage and forecasting (Tribo-Fatigue)]. Gomel, Kiev, Moscow, Uhan, 2001. 170 p.
  • Sosnovskiy L.A. Tribo-Fatigue. Wear-fatigue damage and its prediction (Foundations of engineering mechanics). Springer, 2005. 424 p.
  • Frolov K.V., Sosnovskiy L.A., Makhutov N.A., Drozdov Yu.N. Tribofatika: novye idei v perspektivnom napravlenii [Tribo-Fatigue: new ideas in promising direction]. Gomel, 1990. 7 p.
  • Sosnovskiy L.A. Mehanika iznosoustalostnogo povrezhdenija [Mechanics of wear-fatigue damage]. Gomel, 2007. 434 p.
  • Waterhouse R.B. Fretting Corrosion. New-York, Pergamon Press, 1972.
  • Hills D.A., Nowell D. Mechanics of Fretting Fatigue. Springer, 2010.
  • SI-series machines for wear-fatigue tests. Minsk, 2009. 62 p.

Title of the article DEFINITION OF BIOMATERIALS' PROPERTIES ON BASE OF THE NANOINDENTATION TECHNOLOGIES. PART 3. CLINICAL TRIAL RESULTS
Authors

ZHURAVKOV M.A., Dr. Phys.-Math. Sc., Professor, Minister of Education of the Republic of Belarus, Ministry of Education of the Republic of Belarus, Minsk, Republic of Belarus
MITKOVSKAY N.P., Dr. Med. Sc., Professor, Head of the 3rd Department of Internal Diseases, Belarusian state Medical University, Minsk, Republic of Belarus
LASKINA O.V., Assistant of the 3rd Department of Internal Diseases, Belarusian State Medical University, Minsk, Republic of Belarus
ROMANOVA N.S., Research Associate of the Theoretical and Applied Mechanics Department, Belarusian State University, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.
PROHOROV N.A., Master's Student of the Mechanics and Mathematical Faculty, Belarusian State University, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.

In the section BIOMECHANICS
Year 2015 Issue 2 Pages 74-79
Type of article RAR Index UDK 539.2/.6+612.76+519.68: [5/6+3] Index BBK  
Abstract This paper is a part of the series of works which are devoted to development of analytical and experimental methods to estimate the physical and mechanical properties of biomaterials and biostructures. Proposed methods are designed on the basis of nanoindentation and atomic force microscopy (AFM). Results of hemorheological modifications study due to changes in the physico-mechanical properties of erythrocytes under the influence of coronary heart disease, acute coronary syndrome are presented this paper. The effectiveness of ultraviolet modifications and extracorporeal blood autogemomagnitoterapii for real patients is shown.
Keywords physical and mechanical properties of red blood cells (erythrocytes), hemorheological modifications, viscoelasticity model of fractional order modified algorithm Creek, UV modification of blood and extracorporeal autogemomagnitoterapiya, acute coronary syndrome
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Bibliography
  • World Health Statistics - Geneva (CH): World Health Organization, 2013. 172 p.
  • Laskina O.V., Zalesskay G.A., Mitkovskay N.P. Electrophoreticheskay podvignost u pacientov s ostrim koronarnim sindromom v prothesse provedeniya ultrafioletovoi modifikatsii krovi i ekstrakorporalnoi autogemomagnitoterapii [Electrophoretic mobility of erythrocytes in patients with acute coronary syndrome in the course of UV modification and extracorporeal blood autogemomagnitoterapii]. Antikoagulyantnya terapia na sovremennom urovne [Anticoagulation therapy at the present level], 2010, pp. 42-46.
  • Zhuravkov M., Romanova N. Fractional viscoelastic models in biomechanics. The First Workshop on fractional calculus and its applications. Al-Ain, United Arab Emirates, 2013.
  • Lyusov V.A., Parphenov A.S. Gemostaz i reologiya krovi pri razlichnix formax ishemicheskoi bolezni serdtsa [Hemostasis and blood rheology in various forms of ischemic heart disease]. Actualnie problemi gemostaziologii [Actual problems of Hemostasis]. Minsk, 1979. 140 p.
  • Roytman E.V. Klinicheskaya gemoreologiya [Clinical hemorheology]. Tromboz, gemostaz i reology [Thrombosis, hemostasis and rheology], 2003, no. 3(15), pp. 14-15.
  • Petrochenko E.P., Tixomirova I.A., Petrochenko A.S. Vliyanie aspirina na reologicheskie svoystva [Effect of aspirin on blood rheology in patients with coronary heart disease]. Matematicheskaya morfologia [Mathematical morphology], 2008, vol. 7(1).
  • Zhuravkov M., Drozd L., Romanova N., Krupoderov A. Mechanical-mathematical modelling of biological tissue behaviour. Analytic Methods in Interdisciplinary Applications. Springer Proccedings in Mathematics & Statistics, 2015, vol. 116, pp. 153-181.
  • Zhuravkov M., Romanova N., Prokhorov N. Ob opredelenii svoystv biomaterialov na osnove tekhnologii nanoindentirovania. Chast 1. Modifikatsia modeley kontaktnoy mekhaniki pri modelirovanii protsesov nanoindentirovanya [Definition of biomaterials' properties on base of the nanoindentation technologies. Part 1. Modification of classical contact mechanics models for the using in the modeling of nanoindentation processes]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and materials], 2015, vol. 1, pp. 47-57.
  • Zhuravkov M., Romanova N., Prokhorov N. Ob opredelenii svoystv biomaterialov na osnove tekhnologii nanoindentirovania. Chast 2. Metodiki opredeleniya tochki kontakta v metode silovoy spektroskopii [Definition of biomaterials' properties on base of the nanoindentation technologies. Part 2. Techniques for determining the point of contact in the method of force spectroscopy ]. Mekhanika mashin, mekhanizmov i materialov [Mechanics of machines, mechanisms and
    materials], 2015, vol. 1, pp. 58-65.
  • Laskina O.V., Mitkovskaya N.P., Zalesskaya G.A., Ulaschik V.S. Primenenie ultrafioletovoy modifikatsii krovi dlya lechenia bolnikh s ostrim koronarnim sindromom [Application of UV modification of blood for the treatment of patients with acute coronary syndrome]. Aktualnie voprosi kardiologii [Cardiology Update]. Minsk, 2010, pp. 167-175.
  • Zalesskay G.A., Akulich A.V., Marochkov A.V., Laskina O.V., Mitkovskaya N.P. Opticheskie metody korrektsii kislorodtransportnykh kharakteristik krovi i ikh biomeditsinskie primeneniya [Optical methods for correcting blood oxygen
    transport characteristics and their biomedical applications]. Zhurnal prikladnoy spektr. [Journal of Applied Spectroscopy], 2010, vol. 77(3), pp.451-459.

Title of the article METHODOLOGICAL ASPECTS OF THE MODULUS OF ELASTOMERIC MATERIALS AND BIOLOGICAL CELLS BY FORCE SPECTROSCOPY MEASUREMENT
Authors

MOHAMMED S.A.A., Postgraduate Student, Belarusian National Technical University, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.
MELNIKOVA G.D., Junior Researcher, A.V. Luikov Heat and Mass Transfer Institute of the National Academy of Sciences of Belarus, Minsk, Republic of Belarus
MAKHANIOK A.A., Cand. Phys.-Math. Sc., Senior Researcher, A.V. Luikov Heat and Mass Transfer Institute of the National Academy of Sciences of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.
CHIZHIK S.A., Academician of the NAS of Belarus, Dr. Techn. Sc., Professor, First Deputy Chairman of the Presidium of the NAS of Belarus, Presidium of the NAS of Belarus, Minsk, Republic of Belarus

In the section BIOMECHANICS
Year 2015 Issue 2 Pages 80-84
Type of article RAR Index UDK 53.088.3 Index BBK  
Abstract In this article some methodological questions probe force spectroscopy at nanoindentation elastomeric materials discuss. They associated with the choice of the contact point and sliding the probe over the surface of the test material. An alternative method for choice of the contact point, in which the depth of probe's penetration into the sample becomes zero when using the model of Johnson-Kendall-Roberts proposes. It has been established that this point is located to the point of maximum adhesion force. According to nanoindentation data of erythrocyte by silicon probe with a radius of curvature of 60 nm and stiffness console 3 N/m is shown that the proposed version of the choice of the contact point provides a smaller variance the modulus of elasticity and access to a constant value of modulus of elasticity in the depth of penetration of 5-15 nm.
Keywords nanoindentation, young's modulus, contact point, Hertzian model, Johnson-Kendall-Roberts model, force spectroscopy
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Bibliography
  • Gupta S., Carrillo F., Li Ch., Pruitt L., Puttlitz Ch. Adhesive forces significantly affect elastic modulus determination of soft polymeric materials in nanoindentation. Materials Letters, 2002, vol. 61, no. 2, pp. 448-451.
  • Huang Y., Zhang F., Hwang K.C., Nix W.D., Pharr G.M., Feng G. A model of size effects in nanoindentation. J. Mech. Phys. Solids, 2006, vol. 54, pp. 1668-1686.
  • Doerner M.F., Nix W.D. A method for interpreting the data from depth-sensing indentation instruments. J. Mater. Res., 1986, vol. 1, no. 4. pp. 601-609.
  • Field J., Swain M.V. A simple predictive model for spherical indentation. J. Mater. Res., 1993, vol. 8, no. 2, pp. 297-306.
  • Gao H., Chiu C.H., Lee J. Elastic contact versus indentation modelling of multilayered materials. Int. J Solids Structures, 1992, vol. 29, pp. 2471-2492.
  • Golovin Yu.I. Nanoindentirovanie i mehanicheskie svojstva tverdyh tel v submikroob'emah, tonkih pripoverhnostnyh slojah i plenkah (Obzor) [Nanoindentation and mechanical properties of hard bodies in submicrovolumes, thin subsurface layers and films (Scope)]. Fizika tverdogo tela [Physics of hard bodies], 2008, vol. 50, no. 12, pp. 2113-2142.
  • Makushkin A.P. Naprjazhenno-deformirovannoe sostojanie uprugogo sloja pri vnedrenii v nego sfericheskogo indentora. 1. Opredelenie kontaktnogo davlenija [Stress-strain state of the elastic layer at the implementation by a spherical indenter. 1. Determination of the contact pressure]. Trenie i iznos [Friction and wear], 1990, vol. 11, no. 3, pp. 423-434.
  • Torskaya E.V., Goryacheva I.G., Chizhik S.A., Syroezhkin S.V. Opredelenie tolshhiny uprugogo sloja na tverdoj podlozhke metodom staticheskoj silovoj spektroskopii. [Determination of the thickness of the elastic layer on a solid substrate by static force spectroscopy]. Trudy VII Mezhdunarodnogo seminara "Metodologicheskie aspekty skanirujushhej zondovoj mikroskopii" 1-3 nojabrja 2006 Minsk" [Proc. of the VII International Seminar "Methodological aspects of scanning probe microscopy"]. Minsk, 2006, pp. 241-245.
  • Gerberich W.W., Tymiak N.I., Grunian J.C., Horstemeyer M.F., Baskes M.I. Interpretations of indentation size effects. J. Appl. Mech., 2002, vol. 69. pp. 433-442.
  • Rashid K., AlRub A. Prediction of micro and nanoindentation size effect from conical or pyramidal indentation. Mechanics of Materials, 2007, vol. 39, pp. 787-802.
  • Mencik J. Uncertainties and Errors in Nanoindentation, Nanoindentation in Materials Science, ISBN: 978-953-51-0802-3, InTech, DOI: 10.5772/50002. 2012. Available at: http:// www.intechopen.com/books/nanoindentation-in-materials-science/uncertainties-and-errors-in-nanoindentation.
  • Johnson K.L., Kendall K., Roberts A.D. Surface energy and the contact of elastic solids. Proc. Roy. Soc. London A., 1971, vol. 324, pp. 301-313.
  • Mohammed Salem A.A., Melnikova G.B., Makhaniok A.A., Chizhik S.A. Novye sposoby obrabotki rezul'tatov nanoindentirovanija metodom atomno-silovoj mikroskopii. [New ways of processing the results nanoindentation by atomic force microscopy]. Nauka i tehnika [Science and Technology], 2015, no. 1, pp. 53-60.

Title of the article COMPUTER SIMULATION OF IMPACT INTERACTION WITH SOLID BODIES FOR VEHICLE SECURITY BARRIERS DEVELOPMENT PURPOSE
Authors

SHMELIEV A.V., Cand. Techn. Sc., Director of the Republican Computer Center of MechanicalEngineering, Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.
IVCHENKO V.I., Head of the Automobile Departament Republican Computer Center of Mechanical Engineering, Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.
LISOVSKIY E.V., Junior Researcher Republican Computer Center of Mechanical Engineering, Joint Institute of Mechanical Engineering of the National Academy of Sciences of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.

In the section COMPUTER MECHANICS
Year 2015 Issue 2 Pages 66-73
Type of article RAR Index UDK 624.042 Index BBK  
Abstract The research tasks in the field of perspective vehicle security barriers development, their design process optimization and finding of new effective solutions with the use of LS-DYNA software is under consideration. Discussed the computer simulation results of solid deformable body’s impact interaction with vehicle security barrier using final elemental models. Demonstrated the efficiency of complex vehicle finite element dynamic model replacement by rigid body model for the virtual testing in the early stages of vehicle security barriers designing.
Keywords computer modeling, finite element model, dynamic model, crash test, virtual test, deformable solid body, vehicle security barrier, penetration rating, kinetic energy, designing
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Bibliography
  • Kraynov G. Obzor rossiyskogo rynka protivotarannykh ustroystv [Review of Russian vehicle security barrier market]. Sistemy bezopasnosti [Security systems], 2012, no. 4, pp. 68-72.
  • ASTM F265607. Standard Test Method for Vehicle Crash Testing of Perimeter Barriers.
  • SD-STD-02.01. Test Method for Vehicle Crash Testing of Perimeter Barriers and Gates. Certification standard. U.S. Department of State. Revision A, 2003.
  • British Standards Institution. Impact test specifications for vehicle security barriers. Publicly Available Specification PAS 68: 2013. BSI. London, 2013.
  • UFC 4-022-02 (S June 2009). Unified Facilities Criteria (UFC): Selection and Application of Vehicle Barriers.
  • CWA 16221:2010 Vehicle security barriers. Performance requirements, test methods and guidance on application. CEN. 2010.
  • ISO/IWA 14-1:2013(en) Vehicle security barriers - Part 1: Performance requirement, vehicle impact test method and performance rating.
  • NCAC. The National Crash Analysis Center. Finite Element Model Archive. Available at: http://www.ncac.gwu.edu/vml/ models.html.
  • Mohanand P., Marzougui D., Kan C. D. S. Validation of a Single Unit Truck Model for Roadside Hardware Impact. International Journal of Vehicle Systems Modelling and Testing, 2007, vol. 2, no. 1, pp. 1-15.
  • FEM Models for Semitrailer Trucks. Available at: http:// thyme.ornl.gov/FHWA/TractorTrailer index.cgi? model= 1&navv=0.
  • UNECE UTPWV Regulation no. 29. Vehicles with regard to the protection of the occupants of the cab of a commercial vehicle. UN, 2012. 26 p.
  • Aleshkevich E.L., Djuzhev A.A., Ivchenko V.I., Kritsky M.A., Levitsky V.A., Petko V.I., Skok A.N., Kharitonchok S.V., Shmelev A.V. Zagraditel'noe ustrojstvo [The barrier device]. Patent BY, no. 20140006, 2014.