Investigations of Properties of Soil-Aggregate Mixtures
More details
Hide details
Rzeszow University of Technology, Rzeszów, Poland
Online publication date: 2022-10-13
Publication date: 2022-09-01
Civil and Environmental Engineering Reports 2022;32(3):116-132
The subject of this paper is the evaluation of the use of waste material, which is the native soil. On the example of the base ground taken from the village of Lipie (Podkarpackie voivodeship), soil-aggregate mixtures were prepared with a different degree of addition of natural aggregate. The study analysed the quantitative and qualitative parameters of the prepared mixtures and assessed their physical and mechanical properties to determine their suitability for the construction of nfrastructural facilities. It should be noted that most specifications recommend the use of primarily aggregate mixtures. The paper presents the results of a study analysing the effect of aggregate admixture to the native soil on selected physical and strength properties of the mixtures developed. The obtained results confirmed the validity of research on the use of soil-aggregate mixtures for construction purposes.
Dong, Y 2007. Experimental study on intensity character of rock-soil aggregate mixture. Rock and Soil Mechanics 28, 1269–1274.
Xu, XC, Chen, SX and Jiang, LF 2015. On Compaction Characteristics and Particle Breakage of Soil-aggregate Mixture. 1st International Conference on Information Sciences, Machinery, Materials and Energy (ICISMME). Proceedings of the First International Conference on Information Sciences, Machinery, Materials and Energy, 126, 83–87.
Xu, XC, Zhou, W, (...), Li, JX 2010. Research on compaction properties of soil-aggregate mixture. Rock and Soil Mechanics 31, 115–120.
Hopkins, TC, Beckham and TL 2000. Influence of clay fraction and moisture on the behaviour of soil-aggregate mixtures. 5th International Symposium on Unbound Aggregates in Road Construction (UNBAR 5). Unbound Aggregates in Road Construction, 21–28.
Skrzypczak, I, Kokoszka, W, Buda-Ożóg, L, Kogut and J, Słowik, M 2017. Environmental aspects and renewable energy sources in the production of construction aggregate. ASEE17, E3S Web of Conferences 22, 1–8.
Knapik, K and Bzówka, J 2017. Permeability of the mixture of fine grained soil and fly ash from fluidized bed combustion. Sborník vědeckých prací Vysoké školy báňské - Technické Univerzity Ostrava 17, 25–30.
Kokoszka,W 2019. Impact of Water Quality on Concrete Mix and Hardened Concrete Parameters. Civil and Environmental Engineering Reports 29, 174–182.
Bakir, N, Abbeche, K, Panczer, G and Belagraa, L 2020. Study of the effect of waste glass fibers incorporation on the collapsible soil stability behavior. KnE Engineering 5, 157–166.
Directive 2006/12/EC of the European Parliament and of the Council of 5 April 2006 on waste. https://op.europa.eu/pl/public....
Regulation (EU) no 305/2011 of the European Parliament and of the Council of 9 March 2011 laying down harmonised conditions for the marketing of construction products and repealing Council Directive 89/106/EE. https://www.itb.pl/rozporzadze....
Skrzypczak, I, Kokoszka, W, Zientek, D, Tang, Y and Kogut, J 2021. Landslide Hazard Assessment Map as an Element Supporting Spatial Planning: The Flysch Carpathians Region Study. Remote Sensing 13, 317.
Skrzypczak, I, Kogut, J, Kokoszka, W and Zientek, D 2017. Monitoring of landslide areas with the use of contemporary methods of measuring and mapping, Civil and Environmental Engineering Reports 24, 069–082.
Skrzypczak, I, Kokoszka, W, Kogut, J and Oleniacz, G 2017. Methods of measuring and mapping of landslide areas, IOP Conference Series: Earth and Environmental Science 95, 022013.
Mrówczyńska, M and Sztubecki, J 2021. The network structure evolutionary optimization to geodetic monitoring in the aspect of information entropy Measurement. Journal of the International Measurement Confederation 179, 109369.
Mrówczyńska, M 2011. Neural networks and neuro-fuzzy systems applied to the analysis of selected problems of geodesy. Computer Assisted Mechanics and Engineering Sciences 18, 161–173.
Pisarczyk, S 2005. Geoengineering. Subsoil modification methods. Warsaw: PWN Publishers.
Ismail, M 2008. Mathematical correlations between the effective diameter of soil and other properties. Engineering and Technology, 26 (10),1274–128.
Kokoszka, W, Skrzypczak, I and Wilk, K 2018. Analysis of Geotechnical Properties of Miocene Deposits of the Carpathian Foredeep. Civil and Environmental Engineering Reports 28, 62–70.
Kopciuch, D 2021. Wpływ parametrów granulometrycznych na wytrzymałość ośrodka gruntowego. Praca dyplomowa. Opiekun I. Skrzypczak. In: APD Politechnika Rzeszowska.
PN-EN ISO 14688-1:2006 Geotechnical investigation. Determination and classification of soils. Part 1: Determination and description.
PN-EN ISO 14688-2:2006 Geotechnical investigation. Determination and classification of soils. Part 2: Principles of classification.
PN-EN 1997-1:2009 Eurocode 7: Geotechnical design. Part 2: Identification and investigation of subsoils.
Myślińska, E 2016. Laboratory studies of soils and grounds. Warsaw: University of Warsaw Publishers.
Wiłun, Z 2000. Outline of geotechnics. Warsaw: WKŁ Publishers.
Journals System - logo
Scroll to top