Stabilized flow rate of high-paraffin asphalt cement in cylindrical pipe

The paper studies the flow rate of asphalt cement described by Herschel–Bulkley fluid in a cylindrical pipe. The dependence is suggested for the fluid flow rate and the pressure drop. It is found that with increasing content of paraffins and resins, the yield stress and consistency of the medium increase, thereby leading to a decrease in the flow rate parameters at a given pressure drop.

rheology, asphalt cement, viscoplastic media, viscosity, non-Newtonian fluid, Herschel–Bulkley fluid

1. Metodicheskie rekomendacii po proektirovaniju zhestkih dorozhnyh odezhd [Design recommendations on rigid pavements]. Moscow: Informavtodor. 2004 (rus)

2. Technical Recommendations 134-03 Tehnicheskie rekomendacii po ustrojstvu i priemkev jekspluataciju dorozhnyh pokrytij s uchetom trebovanij mezhdunarodnyh standartov po rovnosti [Technical recommendations for device and acceptance of operation of pavements with respect to international standards of planeness]. Moscow. 2003. (rus)

3. Matvienko O.V., Bazuyev V.P., Venik V.N., Bazarov R.B., Arutyunyan E.R. Matematicheskoye modelirovaniye sdvigoustoychivosti asfal'tobetonnykh pokrytiy avtomobil'nykh dorog [Mathematical modelling of road pavement shear-resistance]. Vestnik of Tomsk State University of Architecture and Building. 2017. No. 4 (63). Pp. 158–170. (rus)

4. Babak O.G., Starkov G.B. Primeneniye modifitsirovannykh vyazhushchikh v dorozhnom stroitel'stve [Application of modified binders in road construction]. Dorozhnaya tekhnika i tekhnologii. 2001. No. 5. Pp. 72–75. (rus)

5. Gun R.Р. Neftyanyye bitumy [Petroleum asphalt]. Moscow: Khimia, 1973. 432 p. (rus)

6. Grudnikov I.B. Proizvodstvo neftyanykh bitumov [Production of petroleum asphalt]. Moscow: Khimia, 1983. 192 p. (rus)

7. Galdina V.D. Modifitsirovannyye bitumy [Modified asphalt]. Omsk: SibADI. 2009. 228p. (rus)

8. Matvienko O.V., Unger F.G., Bazuev V.P. Matematicheskiye modeli proizvodstvennykh protsessov dlya prigotovleniya bitumnykh dispersnykh sistem [Mathematical models of manufacturing processes of dispersed bitumen systems]. Tomsk: TSUAB, 2015. (rus)

9. Sybilski D. Non-Newtonian viscosity of polymer-modified bitumen. Materials and Structures. 1993. V. 26, Pp. 15–23. DOI: 10.1007/BF02472233. (rus)

10. Zolotarev V.A. Dorozhnyye bitumnyye vyazhushchiye i asfal'tobetony [Road bituminous binders and asphalt concretes]. Kharkiv, 2014. 180 p. (rus)

11. Matvienko O.V., Bazuev V.P., Dulzon N.K., Smirnova N.G., Agafonova M.V. Chislennoye issledovaniye struktury techeniya i teploobmena pri zakruchennom techenii bitumno-dispersnykh sistem v tsilindricheskikh kanalakh. [Numerical simulation of swirling flow structure and heat transfer of bitumen dispersed systems in cylindrical channels]. Vestnik of Tomsk State University of Architecture and Building. 2014. No. 2 (43). Pp. 80–93. (rus)

12. Malkin A.Y., Isaev A.I. Reologiya: kontseptsii, metody, prilozheniya [Rheology: Concepts, methods, applications]. Saint-Petersburg: Professia, 2007. 560 p. (rus)

13. Wilkinson W.L. Nen'yutonovskie zhidkosti [Non-Newtonian fluids]. Moscow: Mir, 1964. (transl. from Engl.)

14. Kutepov A.M., Polyanin L.D., Zapryanov Z.D. Vyaz'min A.V., Kazenin D.A. Khimicheskaya gidrodinamnka: spravochnoye posobiye [Chemical hydrodynamics. Handbook]. Moscow: Byuro Kvantum, 1996. (rus)

15. Klimov D.M., Petrov A.G., Georgievsky D.V. Vyazkoplasticheskiye techeniya: dinamicheskiy khaos, ustoychivost' i peremeshivaniye [Viscoplastic flows: Dynamic chaos, stability and mixing]. Moscow: Nauka, 2005. (rus)

16. Matvienko O.V. Chislennoye issledovaniye techeniya nen'yutonovskikh zhidkostey v tsilindricheskom kanale [Numerical simulation of non-Newtonian fluids in cylindrical channel]. Izvestiya vysshikh uchebnykh zavedeniy. Fizika. 2014. V. 57. No. 8-2. Pp. 183–189. (rus)

17. Matvienko O.V., Evtyushkin E.V. Matematicheskoye issledovaniye separatsii dispersnoy fazy v gidrotsiklone pri ochistke vyazkoplasticheskikh burovykh rastvorov [Mathematical simulation of dispersed phase separation in hydrocyclone during cleaning of viscoplastic mud]. Inzhenernofizicheskiy zhurnal. 2011. V. 84. No. 2. Pp. 243–252. (rus)

18. Matvienko O.V., Bazuev V.P., Venik V.N., Smirnova N.G. Numerical investigation of HerschelBulkley fluid mixing. In: IOP Conference Series: Materials Science and Engineering Advanced Materials in Construction and Engineering; Proc. Int. Sci. Conf. of Young Scientists ‘Advanced Materials in Construction and Engineering’. TSUAB, 2015. 012034. (rus)

19. Matvienko O.V., Bazuev V.P., Dulzon N.K. Matematicheskoye modelirovaniye techeniya zakruchennogo potoka vyazkoplasticheskoy zhidkosti v tsilindricheskom kanale [Mathematical modeling of swirling flow of pseudoplastic fluid in cylindrical channel]. Inzhenerno-fizicheskiy zhurnal. 2014. V. 87. No. 5. Pp. 1129–1137. (rus)

20. Matvienko O.V., Bazuev V.P., Sabylina N.R., Aseeva A.E., Surtaeva A.A. Issledovanie ustanovivshegosya techeniya vyazkoplasticheskogo bitumnogo vyazhushchego, opisyvaemogo model''yu Shvedova – Bingama, v tsilindricheskoi trube [Shvedov-Bingham model of steady flow of visco-plastic bitumen binder in cylindrical tube]. Vestnik Tomskogo gosudarstvennogo arkhitekturnostroitel'nogo universiteta – Journal of Construction and Architecture. 2019. V. 20. No. 3. Pp. 158–177. DOI: 10.31675/1607-1859-2019-21-3-158-177. (rus)

21. Matvienko O.V., Bazuev V.P., Aseeva A.E. Matematicheskoye modelirovaniye techeniya zakruchennogo potoka psevdoplasticheskoy zhidkosti Balkli–Gershelya v tsilindricheskom kanale [Mathematical modeling of swirling flow of pseudoplastic Bulkley–Herschel fluid in cylindrical channel]. Inzhenerno-fizicheskiy zhurnal. 2019. V. 92. No. 1. Pp. 215–226. (rus)

22. Matvienko O.V., Bazuyev V.P., Aseeva A.E. Matematicheskoye modelirovaniye techeniya zakruchennogo potoka dilatantnoy zhidkosti Balkli–Gershelya v tsilindricheskom kanale [Mathematical simulation of swirling flow of dilatant Bulkley-Herschel fluid in cylindrical channel]. Inzhenerno-fizicheskiy zhurnal. 2019. V. 92. No. 6. Pp. 2641–2651. (rus)

23. Matvienko O.V., Bazuev V.P., Yuzhanova N.K., Yuzhanova N.K. Matematicheskoye modelirovaniye techeniya zakruchennogo potoka psevdoplasticheskoy zhidkosti v tsilindricheskom kanale [Mathematical modeling of swirling flow of pseudoplastic fluid in cylindrical channel]. Inzhenerno-fizicheskiy zhurnal. 2011. V. 84. No. 3. Pp. 544–547. (rus)

24. Matvienko O.V., Bazuev V.P., Yuzhanova N.K. Matematicheskoye modelirovaniye techeniya zakruchennogo potoka dilatantnoy zhidkosti v tsilindricheskom kanale [Mathematical modeling of swirling flow of dilatant fluid in cylindrical channel]. Inzhenerno-fizicheskiy zhurnal. 2014. V. 87. No. 1. Pp. 192–199. (rus)

25. Matvienko O.V., Bazuev V.P., Cherkasov I.S., Litvinova A.E. Techenie bitumnogo vyazhushchego, opisyvaemogo model''yu Ostval''da – de Veilya, v tsilindricheskoi trube [Liquid asphalt binders in cylindrical tube in terms of the Ostwald–de Waele model]. Vestnik Tomskogo gosudarstvennogo arkhitekturno-stroitel'nogo universiteta – Journal of Construction and Architecture. 2020. V. 22. No. 1. Pp. 129–144. (rus)

26. Matvienko O.V., Bazuev V.P., I Cherkasov.S., Aseeva A.E. Issledovanie gidravlicheskikh kharakteristik potoka vodno-peschanoi suspenzii v trube [Hydraulic properties of sand slurry flow in a pipe]. Vestnik Tomskogo gosudarstvennogo arkhitekturno-stroitel'nogo universiteta – Journal of Construction and Architecture. 2020. V. 22. No. 2. Pp. 171–192. (rus)

27. Matvienko O.V. Issledovaniye ustanovivshegosya techeniya psevdoplasticheskoy zhidkosti, opisyvayemoy model'yu Sisko, v tsilindricheskoy trube [Steady-state flow of pseudoplastic fluid in cylindrical tube described by the Cisco model]. Vestnik Tomskogo gosudarstvennogo universiteta. Matematika i mekhanika. 2018. No. 55. Pp. 99–112. (rus)

28. Loitsyansky L.G. Mekhanika zhidkosti i gaza [Mechanics of fluids and gas]. Moscow: Nauka, 1974. (rus)

29. Bazuev V.P., Matvienko O.V., Voronenko V.L. Modelirovaniye protsessa modifitsirovaniya bituma v kavitatsionno-smesitel'nom dispergatore [Modeling of modifying bitumen in a cavitation mixing disperser]. Vestnik of Tomsk State University of Architecture and Building. 2010. No. 4. P. 121–128. (rus)

30. Matvienko O.V., Bazuev V.P., Turkasova N.G., Baygulova A.I. Issledovaniye protsessa modifikatsii bituma v inzhektornom smesitele [Bitumen modification in injector mixer]. Vestnik of Tomsk State University of Architecture and Building. 2013. No. 3. Pp. 202–213. (rus)

31. Matvienko O.V., Agafontseva M.V., Bazuev V.P. Issledovaniye dinamiki puzyr'ka v zakruchennom potoke nelineyno-vyazkoy zhidkosti [Bubble dynamics in swirling flow of nonlinear viscous fluid]. Vestnik of Tomsk State University of Architecture and Building. 2012. No. 4, Pp. 144–156. (rus)

32. Matvienko O.V., Bazuev V.P., Venik V.N., Smirnova N.G. Chislennoye issledovaniye protsessa obrazovaniya kavitatsionnykh puzyr'kov v smesitel'nom ustroystve [Numerical simulation of cavitation bubbles in a mixing device]. Vestnik of Tomsk State University of Architecture and Building. 2014. No. 4 (45). Pp. 231–245. (rus)

33. Matvienko O.V., Bazuev V.P., Venik V.N., Smirnova N.G. Eksperimental'noye issledovaniye protsessa kavitatsii v tekhnologicheskikh ustroystvakh [Cavitation process provided by technological devices]. Vestnik of Tomsk State University of Architecture and Building. 2015. No. 6. Pp. 165–176. (rus)

34. Matvienko O.V., Efa A.K., Bazuev V.P., Evtyushkin E.V. Chislennoye modelirovaniye raspada turbulentnoy strui v sputnom zakruchennom potoke. [Numerical simulation of turbulent jet decay in swirling flow]. Izvestiya vysshikh uchebnykh zavedeniy. Fizika. 2006. V. 49, No. 6. Pp. 96–107. (rus)

35. Matvienko O.V., Bazuev V.P., Yuzhanova N.K. Chislennoye issledovaniye perekhoda k turbulentnomu rezhimu techeniya vnutrennikh zakruchennykh potokov bitumnykh vyazhushchikh. [Numerical simulation of transition to the turbulent mode of internal swirl flows of bitumen binders]. Vestnik of Tomsk State University of Architecture and Building. 2013. No. 2. Pp. 132–143. (rus)

36. Matvienko O.V., Bazuev V.P., Smirnova N.G., Pushkareva G.V., Dulzon N.K. Issledovaniye smesheniya koaksial'nykh zakruchennykh potokov dlya prigotovleniya bitumnykh dispersnykh sistem [Mixing coaxial swirl flows for preparation of dispersed bitumen systems]. Vestnik of Tomsk State University of Architecture and Building. 2014. No. 3 (44). Pp. 123–134. (rus)

37. Matvienko O.V., Litvinova A.E. Issledovanie ustanovivshegosya techeniya vysokoparafinistogo bitumnogo vyazhushchego, opisyvaemogo model''yu Balkli – Gershelya, v tsilindricheskoi trube [Steady flow of high-paraffin bituminous binder in cylindrical tube in terms of HerschelBulkley fluid]. Vestnik Tomskogo gosudarstvennogo arkhitekturno-stroitel'nogo universiteta – Journal of Construction and Architecture. 2021. V. 23. No. 4. Pp. 79–99. (rus)

38. Matvienko O.V. Issledovaniye teploobmena i formirovaniya turbulentnosti vo vnutrennem zakruchennom potoke zhidkosti pri nizkikh chislakh Reynol'dsa [Heat transfer and turbulence formation in internal swirling fluid flow at low Reynolds numbers]. Inzhenerno-fizicheskiy zhurnal. 2014. V. 87. No. 4. Pp. 908–918. (rus)

39. Matvienko O.V., Aseeva A.E. Matematicheskoye modelirovaniye zakruchennogo potoka termovyazkoy psevdoplasticheskoy zhidkosti Sisko v tsilindricheskom kanale. [Mathematical simulation of swirling flow of thermal viscous, pseudoplastic Cisco fluid in cylindrical channel]. Inzhenerno-fizicheskiy zhurnal. 2020. Т. 93. No. 4. Pp. 827–838. (rus)

40. Kolbanovskaya A.S., Mikhaylov V.V. Dorozhnyye bitumy [Road bitumen]. Moscow: Transport, 1973. 246 p. (rus)

41. Shirkunov A.S., Ryabov V.G., Kudinov A.V., Nechayev A.N., Degtyannikov A.S. Vzaimosvyaz' adgezionnykh svoystv neftyanykh dorozhnykh bitumov i soderzhaniya v nikh vysokoplavkikh parafinov [Relationship between adhesive properties of oil road bitumen and high-melting paraffin content]. Khimiya i tekhnologiya topliv i masel. 2011. No. 1. Pp. 36–39. (rus)