Authors:
Eduard V. Kotlyarsky, Naum B. Uriev, Yury E. Vasilev3, Vladimir I. Kochnev,Igor Yu. Sarichev,DOI NO:
https://doi.org/10.26782/jmcms.spl.10/2020.06.00020Keywords:
Bitumen mineral mixes,structuring,contact interactions,physical chemical and structural rheological properties,Abstract
At present, the quality of bitumen-mineral mixtures both,inRussia and abroad, is estimated by a set of empirical methods based on many years of experience in using asphalt concrete in road building. Numerous attempts havebeen made over the years to theoretically substantiate the basic behavior patterns of the material under the influence of various factors. Thus, the creation of optimal conditions for the formation of microstructural contact bonds in a highly concentrated polymineral polydispersion system significantly contributes to the formation of asphalt mixes with necessary processing properties and asphalt concrete with required transport and performance characteristics. The article describes the solution of this problem according to the basic provisions of physical chemical mechanics of highly concentrated dispersion systems, taking into account peculiarities of contact interactions. The studies have allowed finding the quantitative correlations of indicators of physical mechanical and structural rheological properties being formed at compaction of bitumen mineral mixes as well as quantitative connections between formative and destructive factors with structural mechanical and construction technical properties of asphalt in road coverings.It has been established that the structural changes in asphalt concrete in road coverings under the influence of operational factors are physical chemical in nature and reliably described, taking into account the basic provisions of physical chemical mechanics and the theory of contact interactions.Refference:
I. Arrambide J. and Duriez M. Liants Routiers et Enrobés. Matériaux de Protection Platre-Agglomérés-Bois. Paris: Dunod, Édition du Moniteur des Travaux Publiques, 1959.
II. Compaction and Paving. Theory and Practice. SwedenÇ Dynapac AB, 1989.
III. Deryagin B. V. and Landau L. D. Theory of Stability of Strongly Charged Lyophobic Fields and Agglutination of Strongly Charged Particles in Electrolyte Solutions [Teoriya ustoychivosti sil’no zaryazhennykh liofobnykh zoley i slipaniye sil’no zaryazhennykh chastits v rastvorakh elektrolitov]. Zhurnal eksperimental’noy i teoreticheskoy fiziki (Journal of Experimental and Theoretical Physics). 1945. Vol. 15. P. 663.
IV. Dodkhoev I. I. Peculiarities of Using Cold Asphalt Concrete Technology in Tajik Climate [Osobennosti tekhnologii kholodnogo asfal’tobetona v uslo-viyakh klimata Tadzhikistana]. Extended Abstract of thesis for a Candidate of Engineering Sciences. Moscow: MADI, 1998.
V. Gorelyshev N. V., Goglidze V. M., Radovsky B. S., and Suprun A. S. Instructional Guidelines for Determining Non-Standardized Properties of Asphalt Concrete As Part of Course in Road Building Materials [Metodicheskiye ukazaniya po opredeleniyu nestandartizovannykh svoystv asfal’tobetona po kursu «Dorozhno-stroitel’nyye materialy]. 1988.
VI. Gridchin A. M., Vysotskaya M. A., and Korotaev A. P. Peculiarities of Interaction between Porous Mineral Powders and Bitumen [Osobennosti vzaimodeystviya poristykh mineral’nykh poroshkov s bitumom] in Collection of articles and reports of Annual Meeting of Association of Asphalt Concrete Researchers. Moscow: State Technical University-MADI, 2009. Pp. 49-53.
VII. Gridchin A. M., Yadykina V. V., Vysotskaya M. A., and Korotaev A. P. Asphalt Binder Based on Porous Mineral Powder [Asfal’tovyazhushcheye na osnove poristogo mineral’nogo poroshka] in Efficient Materials, Technologies, and Machines in Construction – part 3 of Collection of papers of XIX International Research-to-Practice Conference “Research, Nanosystems, and Resource-Saving Technologies in Construction Materials Industry”. Belgorod: BSTU, 2010. Pp. 82-86.
VIII. Grushko I. M., Korolev I. V., Borshch I. M., and Mishchenko G. M. Road Building Materials [Dorozhno-stroitel’nyye materialy]. Moscow: Transport, 1983.
IX. INSERT YOUR PROPER
X. Ivan’sky M. And Uriev N. B. Asphalt Concrete as Composite with Nanodispersion and Polymeric Components [Asfal’tobeton kak kompozitsionnyy material (s nanodispersnymi i polimernymi komponentami)]. Moscow: Techpolygrafcenter. 2007.
XI. Kalashnikova T. N. And Sokal’skaya M. B. Construction and Repairs of ASphalt Concrete Coverings [Stroitel’stvo i remont asfal’tobetonnykh pokrytiy]. Moscow: Econom-Inform, 2010.
XII. Kiryukhin G. N. and Kazarnovsky V. D. Developing Regulatory Framework of Design Characteristics of Asphalt Concrete [Razvitiye normativnoy bazy raschetnykh kharakteristik asfal’tobetonov] in Collection of articles and reports of Annual Meeting of Association of Asphalt Concrete Researchers. Moscow: State Technical University-MADI, 2010. Pp. 86-92.
XIII. Kotlyarsky E. V. And Finashin V. N. Formative Phases of Asphalt Concrete Mixes at Compaction [Etapy formirovaniya asfal’tobetonnykh smesey pri ikh uplotnenii] in Collection of papers “Methods of Improving Technology of Producing Road Building Materials and Enhancing Their Quality” [Puti sovershenstvovaniya tekhnologii proizvodstva i povysheniya kachestva dorozhno-stroitel’nykh materialov]. Moscow: MADI, 1987.
XIV. Kotlyarsky E. V. Construction and Technology Properties of Road Asphalt Concrete [Stroitel’no-tekhnicheskiye svoystva dorozhnogo asfal’tovogo betona]. Moscow: Academic Methodological Association of the Education Agency of the Ministry of Science and Education of Russia, Techpolygraphcenter, 2004.
XV. Kotlyarsky E. V. Increasing Longevity of Road Coverings by Structural Optimization of Asphalt Concrete [Povysheniye dolgovechnosti pokrytiy avtomobil’nykh dorog za schet optimizatsii struktury asfal’tobetonov]. Thesis for a Dictor of Engineering Sciences. 2013.
XVI. Kotlyarsky E. V. Procedure for Estimating Unit Surface of Mineral Part of Asphalt Concrete Mix [Metodika otsenki udel’noy poverkhnosti mineral’noy chasti asfal’tobetonnoy smesi] in Collection of articles and reports of Annual Meeting of Association of Asphalt Concrete Researchers. Moscow: State Technical University-MADI, 2007. Pp. 33-41
XVII. Kotlyarsky E. V. Structural Mechanical Properties of Asphalt Concrete and Asphalt Concrete Mixes [Strukturno-mekhanicheskiye svoystva asfal’tobetonnykh smesey i asfal’tobetona]. Vestnik Belgorodskogo gosudarstvennogo tekhnologicheskogo universiteta im. V.G. Shukhova (Bulletin of BSTU named after V.G. Shukhov). 2008, No. 4. Pp.4-9.
XVIII. Korolev I. V. Bitumen Saving Methods for Road Building [Puti ekonomii bituma v dorozhnom stroitel’stve]. Moscow: Transport, 1986.
XIX. Korolev I. V. Bitumen Saving Methods for Road Building [Puti ekonomii bituma v dorozhnom stroitel’stve]. Moscow: Transport, 1986.
XX. Korolev I. V. Structural Model of Bitumen Film on Mineral Grains in Asphalt Concrete [Model’ stroyeniya bitumnoy plenki na mineral’nykh zernakh v asfal’tobetone]. Izvestiya vuzov. Stroitel’stvo i arkhitektura (News of Higher Educational Institutions. ArchitectureandConstruction). 1981. No. 8. Pp. 63-67.
XXI. Korolev I. V. Structure and Properties of Hot Road Asphalt Concrete. Thesis for a Doctor of Engineering Sciences. 1982.
XXII. Nikol’sky Yu. Ye., Babak O. G., Starkov G. B., and Gubach L. S. Guidelines for Shear Resistance Evaluation of Asphalt Concrete [Metodicheskiye rekomendatsii po otsenke sdvigoustoychivosti asfal’tobetona]. 2002.
XXIII. Phinashin V. N., Kotlyarsky E. V., Uriev N. B., and Chernomaz V. Ye. Asphalt Concrete Mix Formation Phases at Compaction [Etapy formirovaniya asfal’tobetonnykh smesey pri ikh uplotnenii] in Collection of Research Works “Methods of Improving Technology of Producing Road Building Materials and Enhancing Their Quality” [Puti sovershenstvovaniya tekhnologii proizvodstva i povysheniya kachestva dorozhno-stroitel’nykh materialov]. Moscow: MADI, 1987. Pp. 118-128.
XXIV. Pirotsky V. Z. Dispersion Characteristics and Activity of Cement [Dispersnyye kharakteristiki i aktivnost’ tsementa]. Moscow, 1995.
XXV. Polak A. F. Solidification of Monomineral Binders [Tverdeniye monomineral’nykh vyazhushchikh veshchestv]. Moscow: Stroyizdat, 1966. P. 208.
XXVI. Polak A. F. Solidification of Monomineral Binders [Tverdeniye monomineral’nykh vyazhushchikh veshchestv]. Moscow: Stroyizdat, 1966. P. 208.
XXVII. Rebinder P. A. and Uriev N. B. Main Formation and Destruction Phases of Coagulation Structures and Their Role in Optimizing Technology Processes in Structured Dispersion Systems [Osnovnyye stadii obrazovaniya i razrusheniya koagulyatsionnykh struktur i ikh rol’ v optimizatsii tekhnologicheskikh protsessov v strukturirovannykh dispersnykh sistemakh]. Doklady AN SSSR (Proceedings of the USSR Academy of Sciences). 1972. Vol. 205. 1164 p.
XXVIII. Rebinder P. A., Shchukin Ye. D. Margolis L. Ya. Mechanical Strength of Porous Dispersion Bodies [O mekhanicheskoy prochnosti poristykh dispersnykh tel]. Doklady AN SSSR (Proceedings of the USSR Academy of Sciences). 1964. Vol. 154. P. 696.
XXIX. Rybiev I. A. Construction Material Science [Stroitel’noye materialovedeniye]. Moscow: Vysshaya Shkola, 2003.
XXX. Shalyt S. Ya., Mikhaylov N. V., and Rebinder P. A. Influence of Active Filler and Solvent on Properties of Bitumens [Vliyaniye aktivnogo napolnitelya i rastvoritelya na svoystva bitumov]. Kolloidnyy Zhurnal (Colloid Journal). 1957. Vol. 19. Pp. 244-251.
XXXI. Solomatin V. I. And Selyatin V. P. Elements of the General Theory of Composites [Elementy obshchey teorii kompozitsionnykh materialov]. Stroitel’stvo i arkhitektura (Architecture and Construction). 1980. No. 8. Pp. 61-70.
XXXII. Uriev N. B. and Teleysnik M. A. Physical Chemical Mechanics and Intensified Alimentary Mass Formation [Fiziko-khimicheskaya mekhanika i intensifikatsiya obrazovaniya pishchevykh mass]. Moscow: Pishchevaya promyshlennost’, 1976.
XXXIII. Yakhnin Ye. D. Doklady AN SSSR (Proceedings of the USSR Academy of Sciences). 1965. Vol. 164. P. 1105.
XXXIV. Yakhnin Ye. D. On Relation of Dispersion Structure Strength to Forces of Interaction among Elements. Doklady AN SSSR (Proceedings of the USSR Academy of Sciences). 1968. Vol. 178. P. 152.
XXXV. Zimon A. D. and Andrianov Ye. D. Self-Adhesion of Bulk Materials [Autogeziya sypuchikh materialov]. Moscow: Metallurgiya, 1978. P. 71.