PECULIARITIES OF THE DISTRIBUTION OF TECHNOLOGICAL FASTENING SOLUTIONS IN THE POROUS STRUCTURE OF THE CRUSHED STONE BASE OF THE ASPHALT CONCRETE PAVEMENT DURING IMPULSE INJECTION FASTENING

Authors

DOI:

https://doi.org/10.31649/2311-1429-2023-2-62-69

Keywords:

Technological binders, porous structure, gravel base, asphalt concrete pavement, impulse injection, mathematical model, Darcy's equation, Navier-Stokes equation, Shvedov-Bingham equation, solution infiltration, hydrodynamic pressure, gravel material gradation, technology optimization, road construction quality

Abstract

The article is dedicated to the investigation of the peculiarities of spreading technological binding solutions within the porous structure of gravel base in asphalt concrete pavement through impulse injection fixation. The research utilizes a mathematical model based on Darcy's, Navier-Stokes, and Shvedov-Bingham equations to analyze the process of solution penetration into the material pores under the influence of impulse hydrodynamic pressures. The study is conducted on samples of various gravel bases, applying impulse solution injection. The obtained results provide a better understanding of the solution penetration process into the material pores and canals and examine the influence of various factors such as intensity, magnitude, and amplitude of periodic impulse hydrodynamic pressures, properties of technological binding solution, and fractionation of the gravel material. They also serve as a basis for optimizing the technology of asphalt concrete pavement construction on fixed gravel base, which can enhance the quality and durability of the road structure. The obtained results and utilized mathematical models can be beneficial not only for the road construction industry but also for other fields that utilize porous materials with binding solutions, such as technologies for improving the load-bearing capacity of foundation soil bases, landslide mitigation, and other similar cases.

Author Biographies

Ivan V. Kots, Vinnytsia National Technical University

Ph.D. (Eng.), professor of the department of engineering systems in construction, faculty of construction, civil and environmental engineering,  head and scientific leader of the hydrodynamics research laboratory

Oleh O. Horiun, Vinnytsia National Technical University

assistant of the department of engineering systems in construction, faculty of construction, civil and environmental engineering

References

Cambefort, Henri (1964).Injection des sols. Tome 1: Principes et méthodes. Publisher: Paris : Eyrolles.390 p.

Glossop R. The invention and development of injection process. Geotechnique, sept. 1960 –dec. 1961.

Babaskin Y.G., Kolivoska J. Sucasny stav a perspectiva rozvoja medzinarodnych ciest v Bieloruakej republike. Silnicni obzor № 8. Praha, 1997. S. 252-256.

Hameliak I.P., Kots I.V., Badora N.P. Remont dorozhnoho ta aerodromnoho odiahu z vykorystanniam hidroimpulsnoho iniektsiinoho ustatkuvannia. Naukovo-tekhnichnyi zbirnyk «Avtomobilni dorohy ta dorozhnie budivnytstvo», №85. 2012. C.59-65.

Badora N. P., Kots I. V. Doslidzhennia dynamiky robochoho protsesu ustanovky impulsnoi dii dlia nahnitannia sumishei v gruntovyi masyv. Suchasni tekhnolohii, materialy ta konstruktsii v budivnytstvi. 2010. №1. C.58-61.

Badora N.P., Kots I.V., Kolisnyk O.P., Pavliuk O.I. Hidrodynamika rukhu viazko-plastychnykh rozchyniv v porystomu seredovyshchi pry hidroimpulsnomu pidsylenni nesuchykh osnov sporud. Naukovo-tekhnichnyi zbirnyk «Suchasni tekhnolohii, materialy i konstruktsii v budivnytstvi». 2012. № 1. S. 90-94.

Kots I.V., Badora N.P. Doslidzhennia protsesu impulsnoho pidsylennia nesuchykh osnov sporud pry iniektsiinomu zakriplenni gruntovykh masyviv. Naukovo-tekhnichnyi zbirnyk «Suchasni tekhnolohii, materialy i konstruktsii v budivnytstvi». 2013. № 1. S. 72-76.

Patent na korysnu model № 79358, MPK8 E02D 3/12, E02D 5/42. Iniektsiinyi sposib ukriplennia gruntiv / Kots I.V., Badora N.P.; zaiavnyk ta vlasnyk patentu Vinnytskyi natsionalnyi tekhnichnyi universytet. – № u 201209822; zaiavl. 14.08.2012; opubl. 25.04.2013 - Biul. №8.

Badora N.P., Kots I.V. Analiz teoretychnykh ta eksperymentalnykh doslidzhen iniektsiinoho zakriplennia gruntovykh masyviv. Visnyk Khmelnytskoho natsionalnoho tekhnichnoho universytetu. Tekhnichni nauky. 2014. №2 (211). S. 46-50.

Yakhno O.M., Uzunov O.V., Luhovskyi O.F., Kots I.V. ta insh Prykladna hidroaeromekhanika i mekhanotronika: pidruchnyk. Za zahalnoi redaktsii O.M. Yakhna. Vinnytsia, VNTU, 2017. 711 s.

Tuz, V., Lebed, N. (2019). Hidrodynamika hazoridynnykh potokiv na kapiliarno-porystykh strukturakh. Scientific Works, 83(1), 39-44. https://doi.org/10.15673/swonaft.v83i1.1415

Yakhno O.M., Dubovytskyi V.F. Osnovy reolohii polimeriv. K.: Vyshcha shk., 1976. 188 s.

Bruce R. Munson, Theodore H. Okiishi, Wade W. Huebsch, Alric P. Rothmayer. Fundamentals of Fluid Mechanics. Publisher: John Wiley & Sons. 2013. 747 pages.

Dwight, Herbert B. Tables of Integrals and Other Mathematical Data. Publisher ‏ : ‎ Macmillan USA; 4th edition (1 Dec. 1961). 336 pages.

Kochetkova I.B., Sushko L.F., Zaporozhchenko O.Ie. Vyshcha matematyka v formulakh ta tablytsiakh. Ch.2: Navch. posibnyk-dovidnyk. Dnipropetrovsk: NMetAU, 2014. 48 s.

Downloads

Abstract views: 0

Published

2023-12-29

How to Cite

[1]
I. V. Kots and O. O. Horiun, “PECULIARITIES OF THE DISTRIBUTION OF TECHNOLOGICAL FASTENING SOLUTIONS IN THE POROUS STRUCTURE OF THE CRUSHED STONE BASE OF THE ASPHALT CONCRETE PAVEMENT DURING IMPULSE INJECTION FASTENING”, СучТехнБудів, vol. 35, no. 2, pp. 62–69, Dec. 2023.

Issue

Section

BUILDING MATERIALS AND PRODUCTS

Metrics

Downloads

Download data is not yet available.