Application of Granulated Cable Plastic Waste for Soil Stabilization

Martin Lidmila; Marcel Jogl; Wojciech Kubissa; Roman Jaskulski; Pavel Reiterman

doi:10.4028/www.scientific.net/KEM.760.171

Paper Titles

Dynamic Stability of Multi-Functional Composite Developed for Application in Permanent Way of Prague Underground
p.147

Prefabrication of the Thin-Walled U-Profile UHPFRC Footbridge
p.152

Soft Insert for Support Modeling of Slightly Textile Reinforced Concrete
p.158

Aggregate Segregation of Ultra-High Performance Concrete
p.164

Application of Granulated Cable Plastic Waste for Soil Stabilization
p.171

The Comparison of Properties of Fine Recycled Aggregate Concrete from Different Sources of Recycled Aggregate
p.176

Optimization of the Composition of the Binder Based on CFBC Fly Ash
p.184

The Properties of Fine Recycled Aggregate Concrete Containing Recycled Bricks from Construction and Demolition Waste
p.193

Usage of Recycled Concrete as Subsoil under Industrial Floor
p.199

HomeKey Engineering MaterialsKey Engineering Materials Vol. 760Application of Granulated Cable Plastic Waste for...

Application of Granulated Cable Plastic Waste for Soil Stabilization

Abstract:

Paper deals with the assessment of practical utilization of granulated cable plastic waste (GCPW) for the production of stabilized soil layers in transport engineering. The main goal of the experimental work was the evaluation of the influence of GCPW on mechanical properties of soil stabilization based on the fluidized fly ash. Mechanical properties were investigated using standard procedures in soil mechanics. GCPW was dosed as a partial replacement of fluidized fly ash up to 30 %. It was concluded, that the studied level of replacement performs critical level, additional increasing of GCPW would lead to a decline of required mechanical properties. Besides, replacement by studied waste material caused lower values of the bulk density.

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Periodical:

Key Engineering Materials (Volume 760)

Pages:

171-175

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.760.171

Citation:

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Online since:

January 2018

Authors:

Martin Lidmila, Marcel Jogl, Wojciech Kubissa, Roman Jaskulski, Pavel Reiterman*

Keywords:

Compressive Strength, Fluidized Fly Ash, Granulated Cable Plastic Waste, Proctor Test, Soil Stabilization, Waste Material

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* - Corresponding Author

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