The recovery of plastic waste has a positive impact on two fronts: The environment, through waste reduction, and the economy, through its use in road construction. This work involves recycling plastic variants such as Polypropylene (PP) 50% and LDPE (Low Density Polyethylene) 50% in proportions of 2% to 8%, incorporated into a 0/14 BBSG. The results of the Marshall test gave stability values ranging from 826 to 1523 kg and creep values from 5.5 to 2.45 mm. The Duriez test gave r/R values ranging from 0.769 to 0.786, with water absorption percentages from 2.24% to 0.69%. The PCG test at 80 gyrations gave void percentages ranging from 11.9% to 5.23%. The rutting test gives a rutting depth percentage that drops at 30,000 cycles from 11.5% to 1.3%. This study shows a considerable increase in the mechanical characteristics of asphalt mixes by adding plastic waste.
The premature deterioration that appears on many road and motorway pavements during their first years of service is a major concern for the authorities concerned with the sustainability of infrastructure and the profitability of road investments.
Bituminous mixes are the materials most commonly used in the construction of road surfaces in Senegal. This wearing course is directly affected by traffic-induced loads, and fatigue failure and rutting are often observed in this layer [
Doping the road bitumen conventionally used with plastic bag waste to form a new binder is suited to the climatic conditions of our road surfaces [
KOWANOU [
The quantities of plastic waste produced in the world’s ever-growing populations are a real threat to the environment. In West Africa, estimates of plastic waste in Senegal are among the highest. The average production of solid household waste is 171.82 kg/capita/year [
From an environmental point of view, the incineration of this waste releases toxic gases that are harmful to health. To combat plastic waste pollution, we have opted to recycle it in road construction, using it as a polymer to improve the mechanical performance of bituminous mixes. Using this plastic waste is an approach that will help to protect the environment and produce high-performance bituminous mixes at low cost. In Senegal, we haven’t found any such studies, although they do exist, but they haven’t been published. This is still an innovative approach in Senegal, as it has not yet been exploited.
The methodology used consisted firstly of a literature review to establish the current state of knowledge about asphalt mixes based on plastic waste. Sampling was then carried out at the Ngoundiane basalt quarry, and the bitumen was supplied by the ERES plant. The basalt aggregates were subjected to physico-mechanical testing for geotechnical characterization for classes 0/3, 3/8 and 8/14 (
The bitumen underwent geotechnical acceptance testing using penetrability tests to confirm its class and TBA (Ring and Ball Temperature) tests to determine its softening temperature. This physical-mechanical characterization, supplemented by bitumen identification tests, was used as the basis for formulating a control 0/14 asphalt concrete. Once the basic formula had been obtained, percentages of plastic waste shredded into small particles with an average size of between 2 and 5 mm were incorporated into the bitumen in order to monitor changes in the mechanical performance of the asphalt mixes. In this article, this polymer-based asphalt concrete will be studied using level 1 formulas (
So, several tests will be doing such as and Marshall, Duriez, PCG and rutting tests were carried out to monitor the evolution of the mechanical performance of waste plastic-based mixes (
The aggregates used in this study are the 0/3, 3/8 and 8/14 basaltic fractions commonly used in Senegal to manufacture bituminous concrete for wearing courses. They were sampled at the GECAMINE quarry. The tests carried out on the aggregates relate to their intrinsic characteristics, giving an idea of their physical and mechanical identification. The granulometry allows the distribution of basalt grains according to the mesh and the drawing of curves for each granular class as shown in
The aggregate characterization results are compared with the technical specifications of the contract as shown in
| Physics | Characteristics | Results | Specifications | ||
|---|---|---|---|---|---|
| Granular Class | 0/3 | 3/8 | 8/14 | ||
| Specific Gravity | 2.96 | 2.94 | 2.95 | ||
| Sand equivalent | - | 78.6 | - | >50 | |
| Bulk density | 1.77 | 1.51 | 1.70 | ||
| Mechanics | LA | - | 18.90 | 10.70 | ≤25 |
| MDE | - | 17.50 | 6.10 | ≤20 | |
| Tests | Results | Specifications | Conformity |
|---|---|---|---|
| Penetration Test (1/10) | 47 | 35 - 50 | Conform |
| Temperature of softening (˚C) | 53 | 50 - 50 | Conform |
To characterize the bitumen, penetrability and ball and ring temperature tests were carried out in accordance with EN 1426 and EN 142 respectively. The results are given in
In this study we used two types of plastic waste.
· LDPE: Low Density Polyethylene
This clear or translucent plastic is flexible, chemically resistant and waterproof. It is more transparent than high-density polyethylene (HDPE). It is used for plastic bags, plastic food wrap, flexible packaging materials, freezer bags, water sachets, etc.
The theoretical melting temperature of LDPE is between 120˚C and 140˚C.
· PP: Polypropylene
Polypropylene (PP) is a thermoplastic and can be identified by the number 5 in the tracking arrow symbol. It has many properties similar to PET, HDPE and LDPE.
Density and melting temperature test results for these plastics are given in
These plastics have low densities and very high melting temperatures compared with ambient temperature.
The study of bituminous mix design consists of finding the optimum binder content to ensure a certain threshold of stability, compactness, compactability, resistance to water (uncoating) and creep. To do this, we proceeded to choose a granular mix composed of the three particle size fractions (0/3, 3/8 and the 8/14) fitting perfectly into a reference spindle (
| Parameter | Low-density polyethylene (LDPE) | Polypropylene (PP) |
|---|---|---|
| Temperature (˚C) | 140.8 | 155.3 |
| Density | 0.93 | 0.95 |
Once the basic formula had been worked out, percentages of plastics ranging from 0% to 8% by a 2% interval were added to the initial mix, and Marshall, Duriez and PCG tests were carried out to monitor the evolution of the mechanical performance of waste plastic-based mixes.
The Marshall test is carried out in accordance with standard NF EN 12697-34 on a sample compacted using a Marshall tamper at a rate of 50 blows per face for a road mix. The cylindrical specimen is then immersed in a hydrostatic bath at 60˚C for 30 minutes before passing through a Marshall press. The results of the Marshall stability and creep tests are shown in
The Duriez test is used to determine the resistance to stripping under the action of water or the level of resistance to water of asphalt concrete. It is carried out in accordance with standard NF P 98-251-1, 2002. The results are given in
The PCG test is carried out in accordance with the standard (NF EN 12697-31, 2019) and is used to characterize the compactibility of bituminous mixes with or without plastic. It is a combination of gyratory shear and a resultant axial force applied by a mechanical head. It is used to calculate the percentage of voids and compactness according to the number of gyrations using the measured height of the specimen. This test was carried out on BBSG 0/14 with percentages of 0% and 7% plastic. The results are shown in
The results of the rutting test show that the percentage of voids decreases with the number of gyrations. They also show that the addition of 7% plastic considerably reduces the percentage of voids at 80 gyrations, from 11.9% to 6.23%, and increases compactness, which varies between 88.1% and 93.7%. This shows that the plastic occupies the voids and increases the compactness of the asphalt mix. It also makes it possible to correct the ideal number of voids for an asphalt mix.
The rutting test was carried out in accordance with standard NF EN 12697-22, and is used to determine the percentage rutting depth of an asphalt mix. It was carried out on bituminous concrete with two plastic percentages, 0% and 7%. The results are shown in
The results show that the incorporation of plastic considerably reduces the percentage of rutting depth, which drops from 11.5% to 1.3% after 30,000 cycles, a reduction of more than 80% in rutting. This can be explained by the fact that the plastic fills the voids, increasing compactness and thus resistance to rutting.
The table shows that the 7% mixture gives the best characteristics. It reduces sensitivity to water, increases the rigidity of the asphalt and reduces rutting.
| Characteristics | Obtained values | Acceptable values | ||
|---|---|---|---|---|
| 0% of Plastic | 7% of plastic | |||
| DURIEZ NF P98-251-1 | Rc’/Rc | 0.769 | 0.786 | >0.75 |
| Compact (%) | 89.61 | 97.7 | ≤97 | |
| % Water absorption | 2.24 | 0.69 | 0.93 | |
| Characteristics | Obtained values | Acceptable values | ||
|---|---|---|---|---|
| 0% of Plastic | 7% of plastic | |||
| DURIEZ NF P98-251-1 | Rc’/Rc | 0.769 | 0.786 | >0.75 |
| Compact (%) | 89.61 | 97.7 | ≤97 | |
| % Water absorption | 2.24 | 0.69 | 0.93 | |
| PCG | % voids at 80 girations | 11.9 | 6.23 | [4 - 9] |
| Rutting | Deep of rutting at 30,000 cycles | 11.55 | 1.3 | ≤5 |
The study showed that large quantities of plastic waste can be recovered and recycled in road construction. In fact, the addition of percentages of plastic ranging from 2% to 7% increases the Marshall stability, reduces creep and increases the compactness of bituminous mixes. It also shows that incorporating plastic increases water resistance and asphalt compactibility, and reduces water absorption and rutting. In the light of these results, this study certifies that the addition of plastic to BBSG is of capital benefit and contributes to a considerable increase in the mechanical characteristics of bituminous mixes. This solves an environmental problem and creates a value chain that will help to improve the quality and durability of our wearing courses.
We are very grateful to the NGO Aventurin Waste, which fully funded this research project.
We would also like to thank the Geotechnics laboratory of the UFR SI for hosting the students and the Front de Terre sectoral training center.
We would also like to thank ERES bitume Senegal and the GECAMINE quarry, which provided the bitumen and basalt aggregates free of charge.
The authors declare no conflicts of interest regarding the publication of this paper.
Dione, A., Faye, P.S., Thiam, M.M., Diouf, B., Diallo, C., Becker, A., Diouf, D., Sow, M., Thiam, M. and Ba, M. (2023) Evaluation of the Influence of Plastic Waste in Improving the Mechanical Characteristics of Asphalt Mixes (Senegal, West Africa). Open Journal of Civil Engineering, 13, 517-527. https://doi.org/10.4236/ojce.2023.133037