The classification of mechanical models of road pavements

Nagórski, R.

doi:10.2478/ace-2018-0068

Artykuł - szczegóły

Tytuł artykułu

The classification of mechanical models of road pavements

Autorzy

Nagórski R.

Treść / Zawartość

Pełne teksty:

Nagorski_R_The_classification_4.II_2018.pdf

Pobierz

Identyfikatory

DOI

10.2478/ace-2018-0068

Warianty tytułu

Klasyfikacja modeli mechanicznych nawierzchni drogowych

Języki publikacji

Abstrakty

The paper contains a review of mechanical models of road pavements in the form of a proposal of classification of these models. It is assumed an autonomy of the following elements of the pavement model: the models of structural layers, the subgrade model, the interlayer bonding models, including bonding of pavement structure with its subgrade, models of external impacts on pavement layers, including the load of heavy traffic, models of pavement environment impacts on structural layers’ borders (lateral) and subgrade borders (including the lower one) – according to the criteria selected by paper Author - in the frame of assumptions of the classical Newtonian deterministic mechanics. The above elements of pavement modelling can be combined respectively into certain rational (correct, useful) sets, which define the specified models of the whole road pavement.

Praca zawiera przegląd modeli mechanicznych nawierzchni drogowych w formie propozycji klasyfikacji tych modeli. Założono autonomię w tworzeniu następujących elementów modelu nawierzchni: modele warstw konstrukcyjnych, model podłoża, modele połączeń (wiązań) międzywarstwowych, w tym konstrukcji nawierzchni z podłożem, modele oddziaływań zewnętrznych na warstwy nawierzchni, model obciążenia nawierzchni ruchem ciężkich pojazdów, modele oddziaływań otoczenia zewnętrznego nawierzchni na granice warstw konstrukcyjnych i na granice podłoża - zgodnie z kryteriami klasyfikacyjnymi przyjętymi przez Autora - w ramach założeń mechaniki klasycznej i deterministycznej Newtona. Powyższe elementy modelowania nawierzchni mogą być odpowiednio zestawione w całościowe modele nawierzchni drogowej.

Słowa kluczowe

road pavement mechanistic modelling models classification classification criteria

nawierzchnia drogowa modelowanie mechanistyczne klasyfikacja modeli kryteria klasyfikacyjne

Wydawca

Komitet Inżynierii Lądowej i Wodnej PAN
Politechnika Warszawska, Wydział Inżynierii Lądowej

Czasopismo

Archives of Civil Engineering

Rocznik

2018

Tom

Vol. 64, nr 4/II

Strony

155--170

Opis fizyczny

Bibliogr. 54 poz.

Twórcy

autor

Nagórski R.

r.nagorski@il.pw.edu.pl

Warsaw University of Technology, Faculty of Civil Engineering, Warsaw, Poland

Bibliografia

1. R. Nagórski and others, “Mechanics of road pavements in outline” (in Polish), Scientific Publishers PWN (Wydawnictwo Naukowe PWN), Warsaw, 2014.
2. R. Nagorski, W.Szczesniak, “Theoretical mechanics” (in Polish), vol. 2, Publishing House of Warsaw University of Technology (Oficyna Wydawnicza Politechniki Warszawskiej), Warsaw, 1993.
3. Cz. Rymarz, “Continuum mechanics” (in Polish). Scientific Publishers PWN (Wydawnictwo Naukowe PWN), Warsaw 1993.
4. J. Ostrowska-Maciejewska, “Foundations of continuum mechanics” (in Polish), Scientific Publishers PWN (Wydawnictwo Naukowe PWN), Warsaw, 1982.
5. Cz. Eimer, “Theory of multiphase media” (in Polish), Theoretical and Applied Mechanics (Mechanika Teoretyczna i Stosowana) 10 (2) (1972) 243-258.
6. Cz. Woźniak, “Foundations of deformable bodies dynamics” (in Polish), Scientific Publishers PWN (Wydawnictwo Naukowe PWN), Warsaw 1969.
7. L. Wang, “Mechanics of Asphalt. Microstructure and Micromechanics”, McGraw-Hill, New York 2011.
8. J. Fish, K. Shek, “Multiscale analysis of composite materials and structures”, Composite Science and Technology 60 (2000) 2547-2556.
9. A. Carpinteri A., B. Chiaia, P. Cornetti, “A fractal theory for the mechanics of elastic materials”, Materials Science and Engineering A365 (2004) 235-240.
10. S. Jemioło, A. Szwed, “Problems of statics of elastic layered half-space” (in Polish), Civil Engineering Faculty of Warsaw University of Technology, Warsaw, 2013.
11. P. Perzyna, “Termodynamics of non-elastic materials” (in Polish), Scienific-Technical Publishers WNT (Wydawnictwa Naukowo-Techniczne – WNT), Warsaw, 1978.
12. Y.R. Kim, “Modeling of Asphalt Concrete”, ASCE Press – McGrow-Hill, New York, 2009
13. W. Derski, in: I. Kisiel (Ed.), Applied Mechanics, vol. VII, Mechanics of rocks and soils (in Polish), Scientific Publishers PWN (Wydawnictwo Naukowe PWN), Warsaw, 1982.
14. A.E. Green, R.S. Rivlin, “Multipolar continuum mechanics”, Archive for Rational Mechanics and Analysis, 17 (2) (1964) 113-120.
15. A.E. Green, “Micro-materials and multipolar continuum mechanics”, International Journal of Engineering Science, 3 (5) (1965), 533-542.
16. A. Neimitz, “Fracture mechanics” (in Polish), Scientific Publisher PWN (Wydawnictwo Naukowe PWN), Warsaw, 1998.
17. J.R. Williams, G. Hocking, G. Mustoe G, “The theoretical basis of the discrete element method”, Numerical Methods in Engineering. Theory and Applications (1985), 897-906.
18. W. Bulttlar, Y. Zhanping, “Discrete element modeling of asphalt concrete: microfabric approach”, Transportation Research Record. Journal of the Transportation Research Board 1757 (13) (2014).
19. C. O’Sullivan, “Particulate discrete element method. A Geomechanics perspective”, Spon Press, London – New York, 2011.
20. A. Munjiza, “The Combined Finite-Discrete Element Method”, John Wiley & Sons, London, 2004.
21. R. Talreja, “Multi-scale modeling in damage mechanics of composite materials”, Journal of Materials Science 41 (20) (2006), 6800-6812.
22. E. Weinan, B. Engquist, Z.Y. Huang, “Heterogeneous multiscale method: a general methodology for multiscale modeling”, Physical Revue B 67 (092101) (2003).
23. A.Bensoussan, J.L Lions, G. Papanicolau, “Asymptotic analysis for periodic structures”, North-Holland, Amsterdam, 1978.
24. Duvaut G.: “Homogenization et materiaux composites”, in: P. Ciarlet, M. Rouseau (Eds), Theoretical and Applied Mechanics, North-Holland, Amsterdam 1976, pp 194-278.
25. K.J. Falconer, “The Geometry of Fractal Sets”, second ed., Cambridge University Press, Cambridge, 1990.
26. P.D. Panagiotopoulos, O.K. Panagouli, E.S. Mistakidis, “Fractal geometry and fractal material behaviour in solids and structures”, Archive of Applied Mechanics, 63 (1993) 1-24.
27. S. G. Samko, A.A. Kibas, O.I. Marichev, “Fractional integrals and derivatives. Theory and applications”, Gordon & Breach, Amsterdam, 1993.
28. M.A. Biot; “General theory of three-dimensional consolidation”, Journal of Applied Physics, 12 (1941)
29. I.I. Kandaurov, “Mechanics of granular media and its applications in construction” (in Russian), Gosstiechizdat, Moskva-Leningrad, 1977.
30. N. Odemark, “Investigations of the elastic properties of soils and design of pavements according to the theory of elasticity”, Meddelande 77. Statens Vaginstitut, Stockolm, 1949, pp. 3-30.
31. Y.H. Huang, “Pavement Analysis and Design”, Pearson – Prentice Hall, London, 2004
32. G. Martinček, “Dynamics of Pavement Structures”, E & FN SPON, Bratislava, 1994
33. H. M. Westergaard, “Theory of concrete pavement design”, Proceedings of the Highway Research Board, Washington D.C., 1927.
34. G. Jemielita, in: Cz. Woźniak (Ed.), Applied Mechanics, vol. VIII, Mechanics of elastic plates and shells (in Polish), Scientific Publishers PWN (Wydawnictwo Naukowe PWN), Warsaw, 2001.
35. A. Szydlo, “Cement concrete road pavements”, Polish Cement (Polski Cement), Cracow, 2004.
36. R. Nagorski, P. Wisniakowski, M. Nagorska, “One-dimensional consolidation of two-phase elastic layer” (in Polish), in: W. Szcześniak (Ed.), Polish-Ukrainian Transactions „Theoretical Foundation of Civil Engineering”, vol. 20, pp. 101-108, Publishing House of Warsaw University of Technology (Oficyna Wydawnicza Politechniki Warszawskiej), Warsaw, 2012.
37. A. Das, “Analysis of pavement structures”, CRC Press, Taylor & Francis Group, Boca Raton London New York, 2015.
38. J. Judycki, P. Jaskuła, A. Grądzka, “Theoretical modeling of interlayer bonding impact on the behavior of asphalt pavements” (in Polish) Report – stage 1, Cathedral of Road Engineering , Technical University of Gdansk, 2011.
39. G. Jemielita, W. Szczesniak, “Methods of subgrade modeling” (in Polish), Scientific Papers of Warsaw University of Technology (Prace Naukowe Politechniki Warszawskiej), series Construction (Budownictwo), 120 (1992)
40. M.A. Biot, “General theory of three-dimensional consolidation”, Journal of Applied Physics, 12 (2) (1941) 155-164.
41. M. Graczyk, “Load-bearing capacity of multilayer pavements in domestic climatic conditions” (in Polish), series Studies and Reports (seria Studia i Materialy), vol. 63, Road and Bridge Research Institute (IBDiM), Warsaw, 2010.
42. K. Wilmanski, “Foundations of phenomenological thermodynamics” (in Polish), Scientific Publishers PWN (Wydawnictwo Naukowe PWN), Warsaw, 1974.
43. S. Wisniewski, “Heat exchange” (in Polish), Scienific-Technical Publishers – WNT (Wydawnictwa Naukowo-Techniczne – WNT), Warsaw, 2000.
44. D. Cebon, “Handbook of vehicle-road interaction”, Swetz & Zeitlinger Publishers, Lisse,1999.
45. D. Godlewski, “Road Pavements” (in Polish), Publishing House of Warsaw University of Technology (Oficyna Wydawnicza Politechniki Warszawskiej), Warsaw, 2011.
46. K.P. George, A.S. Rajagopal, L.K. Lim, “Models for predicting pavement deterioration”, Transportation Research Record 1215, Transportation Research Board, Washington DC, 1989
47. A. Drescher, J.Y. Kim, D.E. Newcomb, “Permanent Deformation in Asphalt Concrete”, Journal of Materials in Civil Engineering 5 (1) (1993) 112-128.
48. Y. R. Kim, H. J. Lee, D. N. Little, “Fatigue Characterization of Asphalt Concrete Using Viscoelasticity and Continuum Damage Theory”, Journal of the Association of Asphalt Paving Technologists 66 (1997) 520-569.
49. P. Kettil, B. Lenhof, K. Runesson, N.-E. Wiberg, “Simulation of inelastic deformation in road structures due to cyclic mechanical and thermal loads”, Computers and Structures 85 (2007) 59-70.
50. F. M. Burdekin, D. E. W. Stone, “The crack opening displacement approach to fracture mechanics in yielding materials”, Journal of Strain Analysis, 1 (1966) 145-153.
51. J. Piłat, P. Radziszewski, “Asphalt pavements” (in Polish), second ed., Transport and Communication Publishers – WKŁ (Wydawnictwa Komunikacji i Lacznosci – WKL), Warsaw, 2007.
52. AASHTO Guide for the Design of Pavement Structures, American Association of State Highway and Transportation Officials, 1993.
53. P. Radziszewski, “Fatigue durability modelling of modified mineral-asphalt composites” (in Polish), Scientific Transactions (Rozprawy Naukowe). vol. 45, Bialystok Technical University (Politechnika Białostocka), Bialystok 1997.
54. M.I. Darter, W.R. Hudson, “Probabilistic Design Concepts Applied to Flexible Pavement System Design”, Research Report 123-18, Center for Highway Research, The University of Texas, Austin, Texas, 1973

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-b3c3be34-4261-4328-8acb-30e909ed1e30