METHODOLOGICAL APPROACHES OF DETERMINING PERFORMANCE PARAMETERS OF WHEELED MILITARY AUTOMOTIVE EQUIPMENT WHILE MOVING ON SNOWY BEARING SURFACES

M. Gruble

ABSTRACT

The comparative analysis of the known researches and approaches to the assessment of all-wheel drive vehicles terrain crossing capacity in the conditions of moving on snow-covered bearing surfaces (BS) is carried out. The analysis shows that domestic approaches are based on traditional USSR principles that are different from those adopted in NATO countries in terms of indicators and evaluation criteria. In addition, an analysis of the geographical conditions and road and climatic zones of Ukraine regarding application of wheeled military automotive equipment (MAE) allows to confirm that much of the territory of Ukraine in winter is absolutely snow-covered. Under such conditions, when considering the perspective parameters of wheeled MAE for assessing terrain crossing capacity under snow covered traffic conditions, it is necessary to take into account this factor. Snow is a special kind of BS for military automotive equipment with two-order physical-mechanical variations and corresponding transitions from running to cohesive type of BS. Therefore, mobility and performance of wheeled MAE has some unique characteristics and terminology. Wheeled MAE movement on snow-covered surfaces is related to the thickness of the snow cover and depends on the depth of the formed track, which is a function of snow compaction and shear strength in response to vehicle loads. Besides, the basic empirical dependences of the motor resistance forces and tire coupling with the BS are significantly different from those applied for soil and sand BSs. The comparative analysis provided may be the basis for the formation of a national regulatory framework for assessing terrain crossing capacity of wheeled MAE, taking into account the requirements for compatibility of domestic approaches with those adopted in NATO countries.

KEYWORDS

Snow-covered bearing surface, snow cover thickness, snow compaction, MAE pneumatic tire.

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REFERENCES

Richter G. (1945). Snow cover, its formation and properties. G.D. Richter; [open ed. A.A. Grigoriev]. M .; L .: Publishers of the USSR Academy of Sciences. P. 120.

Snow: Translated from English. Ed. V.M. Kotlyarova. Leningrad, Gidrometeoizdat, 1986. P. 751.

Barakhtanov LV Increasing the patency of tracked vehicles in the snow: Dis. doc. tech. Sciences: 05.05.03. Gorky, 1988. P. 352.

Belyakov VV All-terrain transport technology vehicles: basics of motion theory. V.V. Belyakov, IA Beskin, V.S. Kozlov [and others] under the common. ed. V.V. Belyakova, A.P. Kuleshov. Nizhny Novgorod: Talam, 2004. P.960.

Malygin V.A, Rukavishnikov S.V (1969) Processes occurring in the snow when compressed by its stamp. Snowmobiles: GPI them. A.A. Zhdanov. T. XXV. Issue 16. pp. 88–96.

Harrison W.I. Vehicle Performance Over Snow / US Army Gold Regions Research and Engineering Laboratory. Technical Report 268, Der1975. 81p.

Barakhtanov LV, Blokhin AN, Manyanin SE, Tropin SL Characteristics of snow as a lane [Text]: monograph. N. Novgorod: RUSHIG Research Institute, 2016. P. 250.

Makarov VS A statistical model of snow as a lane of a path for vehicles: A monograph. V.S. Makarov, DV Zezulin, V.V. Belyakov. (2016.) Nizhny Novgorod: Scientific Foundations. Palmarium Academic Publishing, 197 p.

Anikin AA, Barakhtanov LV, Donato IO Physico-mechanical properties of snow as a lane of a path for movement of cars. Electronic journal Science and Education №10, 2010. 8p. Access mode: www: cyberleninka.ru/article/v/fiziko-mehanicheskie-svoystva-snega-kak-polotna-puti-dlya-dvizheniya-mashin.

Makarov V.S., Zezulin D.V., Belyakov V.V. (2014) Snow as a canvas of the road for vehicles // International Journal of Applied and Fundamental Research. № 4. P. 21–24;

Access mode: www: applied-research.com/article/view?id=5062 (accessed 29/07/2019)11. Skripnikov, A.V., Kozlov, V.G., Kondrashova, E.V., Harutyunyan, A.Yu. Passability of complex skidding-transport systems on skidding trains. Forest Gazette. Forestry Bulletin, No. 2, 2016. P. 152–158. Access mode: www.cyberleninka.ru / article / v / prohodimost-kompleksnykh-trelevochno-transportnykh-sistem-na-trelevochnyh-volokah
Donato I
.O. (2006)Passability of wheeled vehicles in the snow. M .: Publishing house of the Moscow State Technical University. N.E. Bauman, 321 p.

Belyakov V.V. (1999) Interaction with the snow cover of elastic motors of special transport vehicles. The dissertation of Dr. Tech. Sciences: 05.05.03 NSTU, Nizhny Novgorod. 485 p.
Makarov V
.S. (2017) Development of scientifically-based technical decisions on creation of mobile complexes of monitoring of coastal zones / Dissertation of Dr. tehn. Sciences: 05.05.03 NSTU, Nizhny Novgorod. 428 p.

Donato I.O. (2007) Theoretical and experimental substantiation of increase of passability of wheeled cars on snow. The dissertation of Dr. Tech. Sciences: 05.05.03 NSTU, Nizhny Novgorod. 306 p.

Petrov S.E. (2012) Aspects of identification of snow cover parameters for mathematical description of the movement of transport-technological machines in the snow. Proceedings of the International Scientific and Technical Conference of the Automobile and Tractor Engineering in Russia: Priorities for Development and Training, dedicated to the 145th anniversary of MAMI Moscow State Technical University. pp. 258–260.

Access mode: www: mospolitech.rf / science / mami145 / scientific / article / s01 / s01_45.pdf

Lutz J. (2003) Mobility of ground vehicles. US military view a review example and reference source quide / Quent systems Inc., June 101 p.

U. S. Army Scaled Vehicle Mobility Factors (Scale Model Tires in Snow). Transportation research command. Fort Eustis, Virginia, October 1961. 61 p.: Www: //apps.dtic.mil/dtic/tr/ fulltext / u2 / 265980.pdf.

DOI: https://doi.org/10.21236/ad0265980

Donato I.O. (2007) Calculation of resistance to the movement of wheeled cars in the snow. Higher education news. Mechanical Engineering, №2, P. 42-46.

Anikin A.A., Belyakov V.V., Donato I.O. (2006) The theory of the movement of wheeled cars in the snow. M .: Publishing house of the Moscow State Technical University. NE Bauman,. 240 p.

Larin V.V. (2013) Analysis of the deformability of the support surface. Vertical deformations / Bulletin of the Moscow State Technical University. NE Bauman: electronic edition.. 11 pp.: Www: engjournal.ru/articles/404/404.pdf

Larin V.V. (2010.) The theory of motion of all-wheel drive cars. Moscow, Publishing House. NE Bauman, 391 p.

Wong J. (1982) The theory of land vehicles. Moscow. Mechanical Engineering, 284 p.

Becker M.G. Introduction to the theory of terrain-machine systems: trans. with English .; ed. V.V. Guskova. M .: Mechanical Engineering, 1973. 520 p.

Wong Y.C. Irvin C.J. (1992) Measurement and characterization of tire pressure syn age for snow obtained using a Rammsonde / Journal of Terramechanics. pp. 265-280. Access mode: www: doi.org/10.1016/1022-4893(92),90031-E.

DOI: https://doi.org/10.1016/0022-4898(92)90031-e

Anikin A.A., Barakhtanov L.V., Zhuk V.A., and Manyanin S.E. (2010) Calculation of the patency of all-terrain vehicles in the snow. Journal of the Association of Automotive Engineers, №2. pp. 28–31.

Anikin A.A., Barakhtanov L.V., Donato I.O. (2006) On the question of determining the resistance to the movement of cars in the snow / AA. Anikin, LV Barakhtanov, IO Donato. Higher education news. Mechanical Engineering, No. 10, P.53–57.

Goncharov K.O. (2010) Estimation of the influence of escalation-bulldozer effects of the patency of multi-axle wheeled vehicles in curvilinear motion in the snow. Dis. Cand. tech. Sciences, 05.05.03 NSTU, Nizhny Novgorod, 232 p.

Barakhtanov L.V., Belyakov V.V., Kravets V.N. (1996) Passability of the car. Nizhny Novgorod, Ed. NSTU,. 200 p.

Makarov V.S., Zezulin D.V., Belyakov V.V. (2013.) Multilevel model of snow as a lane of a path for transport-technological machines on an example of territory of the Russian Federation. Basic research. № 10-2. Pp. 270–276;

Access mode: www.fundamental-research.ru/art/article/view?id=32267 (accessed August 24, 2019).

Larminie J.C. (1988). Standard for the mobility requirements of military vehicles / Journal of terramechnics, vol. 25, No. 3. R. 171–189

Wong Y.J. (2010). Terramechanics and Off-Road Vehicle Engineering: Terrain Behavior, Off-Road Vehicle Performance and Design. 2nd Edition-2010. Access Mode: www // books.google.com / books? Id = s1W9kozKg18C & pg = PA454 & lpg = PA454 & dq = Wong + YJ + terramachanics + and + off-road + vehicle + engineering & source = bl & ots = oILQFlaadV & sig = ACfU3U1LEXyjwYxJwJxYvjYwJyJvxYwjjwYwjjwYyjwYwjywjjxYwjywjwYjjjxYwjjYwjjYjjYxjjxYwjjyYwjjxYvjYwjyjjYwjywjjYjjYxjjYjjxYvw = 2ahUKEwiXkt3w6o7kAhXmsIsKHXzXD7AQ6AEwEHoECAkQAQ # v = onepage & q = Wong% 20Y.J.% 20terramachanics% 20and% 20off-road% 20vehicle% 20engineering & f = false.

DOI: https://doi.org/10.1016/b978-0-7506-8561-0.00006-3

ISO 22476-1: 2012 Geotechnical investigation and testing. - Field testing. - Part 1: Electrical cone and piezocone test. 28 p.

DOI: https://doi.org/10.3403/30255332u

Shadrin S.S. (2014) Mathematical modeling of the process of interaction of a pneumatic tire with a support surface. Car. Road. Infrastructure. Electronic Scientific Journal №2 (2), , Moscow. 12 sec. Access mode: https://www.adi-madi.ru/madi/article/view/89/pdf_
Burkhardt M. (1993). Fahrwerktechnik: Radschlupf - Regelsystemen / Vogel Verlag. Wuerzburg.
P. 273.

Maclaurin B. (2018). High Speed ​​Off-Road Vehicles: Suspensions, Tracks, Wheels and Dynamics / Wiley, London. 249 p. Access Mode: www.wiley.com/en-us/High+Speed+Off+Road+Vehicles:+ Suspensions, + Tracks, + Wheels + and + Dynamics-p-9781119258810.

         DOI: https://doi.org/10.1002/9781119258827

Rowland D., Peel, J.W. (1975) Soft ground performance prediction and assessment for wheeled and tracked vehicles. Institute of Mechanical Engineering, 205, P.81–92.

Shoop S. (2001). The fine element of tire-terrain interaction modeling. PhD thesis, Michigan State University, Ann Arbor, MI. Tsihlas D.

E. Seta, T. Kamegawa, and Y. Nakajima (2003) Prediction of Snow / Tire Interaction Using Explicit FEM and FVM. Tire Science and Technology: July 2003, Vol. 31, No. 1 3, R. 173–188.

DOI: https://doi.org/10.2346/1.2135267

Lee J.H. (2011). Finite element modeling of interfacial forces and contact stresses of pneumatic tire on fresh snow for combined longitudinal and lateral slips / Journal of Terramechanics // June 2011, vol 48, No 3, p 171-191. Access Mode: www.researchgate.net/publication/232371978_ Finite_element_modeling_of_ interfacial_forces_and_contact_stresses_of_pneumatic_tire_on_fresh_snow_for_combined_longitudinal_and_lateral_slips.

DOI: https://doi.org/10.1016/j.jterra.2010.12.003

Sainlo P. (2001) Snow surface model for tyre performance simulation/ 2 International colloquium on vehicle tyre road interaction “Friction potential and safety: Prediction of handling behavior” Florence, February, 17 p. Режим доступу: www.roads.dicea.unifi.it/proceedings-colloquium/P07.pdf

Ferwers W. (2010) Phaenomene von Luftreifen und Gelandeboden – Untersuchungen mit FEM/ Dissertation Dr. – Ing., Universitaet der Bundeswehr Hamburg. 1999. 212 p.

Giessler M., Gauterin C., Wies K., Influence of friction heat on tire traction on ice and snow/ Tire Science and Technology, 38(1), Р. 423.

DOI: https://doi.org/10.2346/1.3298679

Carsten Harnisch, Bjoern Lach, Roland Jakobs, Markos Troulis & Oliver Nehls (2005) A new tyre–soil interaction model for vehicle simulation on deformable ground, Vehicle System Dynamics, 43: sup1, Р. 384-394. Режим доступу: www.tandfonline.com/doi/abs/10.1080/ 00423110500139981.

DOI: https://doi.org/10.1080/00423110500139981

Navin F., Macnabb M., Nicoletti, C. (2014).Vehicle traction experiments on snow and ice. Society of Automotive Engineers Inc., SAE Paper 960652. 26 p.

DOI: https://doi.org/10.4271/960652

Lee, J., Liu, Q., and Zhang, T.,(2005). "Predictive Semi-Analytical Model for Tire-Snow Interaction," SAE Technical Paper 2005-01-0932. https://doi.org/10.4271/2005-01-0932.

DOI: https://doi.org/10.4271/2005-01-0932

Li L., Sandu C., Lee J., Liu B. Stochastic modeling of tire-snow interaction using a polynomial chaos approach/ Journal of Terramechanics. No. 46 (4), 2009. Р. 165188.

DOI: https://doi.org/10.1016/j.jterra.2009.06.006

Lacombe J Tire model for simulation of vehicle motion on high and low friction road suafaces / US Army ERDC. Procedings of the 2000 winter simulation conference. Р. 10251034.

DOI: https://doi.org/10.1109/wsc.2000.899907

Zhang, Y.C., Gao, J.W. and Li, Q. (2018) Experimental Study on Friction Coefficients between Tiretread Rubber and Ice. AIP Advances, 8, Р. 1-9.

DOI: https://doi.org/10.1063/1.5041049

Wu Yeun-Chung. Hadling of multiaxle all wheel drive off-toad vehicles / Dissert. PhD on Mechanical Engineering, Carleton University, Ottawa, Ontario, Canada, 2000. 248 p.

Wong J.Y., Huang Wei. (2006). Wheels vs. track – A fundamental evalution from the traction perspective/ Journal of Terramechanics. Vol. 43. Р. 2742.

DOI: https://doi.org/10.1016/j.jterra.2004.08.003

Crolla D.A. (1991). Off-road vehicle dynamics/ Dr. tech. Thesis, Lough- borough University of technolodgy, UK.1991. 38 p.

El-Gawwad K.A., Crolla D.A., Soliman A.M., El-Saed F.M. (1999). Off-road tire modelling: I The multi-spoke tire model modified to include the effect of straight hugs/ Journal of Terramechanics. Vol. 36 No 1. p. 3-24. II/ Effect of comber on tire performance. p 25-39; III. Effect of angles lugs on tire performance. – Р. 63-76; IV. Extended treatment of tire-terrain interaction for the multi-spouke model. Р. 7790.

DOI: https://doi.org/10.1016/s0022-4898(98)00031-7

Ruff K. Fahrzeugbewegung im Gelaende mit dem Simulationssystem ORIS/ Diss. Dr.-Ing., Universitaet der Bundeswehr. Hamburg, 1997. 191 p.

Harnisch C. Dynamische Echtzeitsimulation der Gelaendefahr mehrachsiger Radfahrzeuge/ Diss. Dr.-Ing., Universitaet der Bundeswehr. Hamburg, 2001. 273 p.

Reid A.A., Shoop S., ones R., Hunez P. (2007). Hight-fidelity ground platform and terrain mechanics modelling for military applications involving vehicle dynamics and mobility analysis/ISTVS conference, Fairbanka, Alaska.

Aubel Th. Interaction between the rolling tires and the soft soil FEM simulationby VENUS and validation/ 6th European Conference of the ISTVS, Vienna, 1994. P. 169189

Lee J. H. (2009). A new indentation model for snow. /Journal of Terramechanics. No. 46. P. 113.

 

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