Substantiation of application technology of hygroscopic materials for dust prevention of roads with the lowest type of surfaces

Authors

DOI:

https://doi.org/10.15587/1729-4061.2022.263573

Keywords:

hygroscopic materials, dust prevention, dustiness, roadside zone, roads, sources of pollution, dust exposure

Abstract

The article presents the results of experimental study for types of loose soils are easily subject to dusting. In connection with this problem, the task is the study and study of the causes and structure of the formation of dustiness in the roadside zone of roads with common types of coatings or without coatings. The experimental study aims to determine the drying time of chemical dust prevention solutions under the influence of solar radiation and the norm of their distribution.

The object of the research is dust generated on roads with low transport and operational performance (temporary roads in places of road repair work, roads to quarries, etc.), and materials used for dedusting road surfaces.

The problem to be solved is to reduce the emission of a large amount of dust on roads without pavements or with inferior types of pavements, which adversely affects the human body.

The results obtained are the identification of a way to combat dust on road surfaces, ensuring a decrease in wear when vehicles move on roads without pavements.

At the same time, the classification of dust according to their sources of formation is expected at the output result.

Due to their features and characteristics, these results allowed the author to solve this problem - effective ways to combat dust on road surfaces are: treating them with dust-removing materials that reduce wear; maintaining the original evenness; reduction of air pollution; improvement of traffic conditions for cars and the sanitary and hygienic condition of roads near settlements.

For experimental tests, traditional salt solutions of various concentrations (NaCl, MgCl2, CaCl2, MgCl2×6H2O, etc.) and solutions of foreign–made stabilizing additives Durasoil and Soiltac from SOILWORKS were taken.

Supporting Agency

  • We express our gratitude to the KazADI laboratory.

Author Biographies

Saniya Kiyalbay, Kazakh Automobile and Road Institute named after L. B. Goncharov (KazADI)

PhD, Associate Professor

Department of Transport Construction and Production of Building Materials

Akmaral Sagybekova, Kazakh Automobile and Road Institute named after L. B. Goncharov (KazADI)

PhD, Associate Professor

Department of Transport Construction and Production of Building Materials

Abdy Kiyalbaev, Kazakh Automobile and Road Institute named after L. B. Goncharov (KazADI)

Doctor of Technical Sciences, Professor

Department of Transport Construction and Production of Building Materials

Kabdullagazy Nauruzbayev, Kazakh Automobile and Road Institute named after L. B. Goncharov (KazADI)

Doctor of Technical Sciences, Professor

Department of Transport Construction and Production of Building Materials

Gulsum Espayeva, Kazakh Automobile and Road Institute named after L. B. Goncharov (KazADI)

PhD, Associate Professor

Department of Transport Construction and Production of Building Materials

Gulnar Bektursunova, Kazakh Automobile and Road Institute named after L. B. Goncharov (KazADI)

Magistr of Technical Sciences, Lector

Department of transport construction and production of building materials

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Published

2022-08-31

How to Cite

Kiyalbay, S., Sagybekova, A., Kiyalbaev, A., Nauruzbayev, K., Espayeva, G., & Bektursunova, G. (2022). Substantiation of application technology of hygroscopic materials for dust prevention of roads with the lowest type of surfaces. Eastern-European Journal of Enterprise Technologies, 4(6(118), 67–77. https://doi.org/10.15587/1729-4061.2022.263573

Issue

Vol. 4 No. 6(118) (2022): Technology organic and inorganic substances

Section

Technology organic and inorganic substances

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Copyright (c) 2022 Saniya Kiyalbay, Akmaral Sagybekova, Abdy Kiyalbaev, Kabdullagazy Nauruzbayev, Gulsum Espayeva, Gulnar Bektursunova

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