Economic feasibility and environmental implications of permeable pavement in Palestine

Hassouna, Fady M.A.; Bdair, Reema; Ali, Mohamed; Mosa, Mohannad; Kayed, Mohammed; Daraghmeh, Faten

doi:10.20858/tp.2023.19.2.12

Artykuł - szczegóły

Tytuł artykułu

Economic feasibility and environmental implications of permeable pavement in Palestine

Autorzy

Hassouna Fady M.A. , Bdair Reema , Ali Mohamed , Mosa Mohannad , Kayed Mohammed , Daraghmeh Faten

Treść / Zawartość

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Identyfikatory

DOI

10.20858/tp.2023.19.2.12

Warianty tytułu

Języki publikacji

Abstrakty

Permeable pavement is considered one of the sustainable management options for roadway networks, which mitigates a number of problems associated with stormwater, ground water pollution, and traffic safety. In this study, the economic feasibility, vehicle operation, and environmental implications of implementing permeable pavement in Nablus, Palestine have been determined by selecting the local roadways that satisfy the permeable pavement requirement, such as low traffic volume, grade less than 5%, speed limit up to 50 km/h, and subgrade with good permeability. The total costs of construction and maintenance for both conventional asphalt and permeable pavement have also been compared based on the life cycle cost analysis (LCCA). Finally, the environmental implications such as the expected increase in the amount of ground water and the reduction in water pollutants have been investigated. The results of the analysis show that the permeable pavement is applicable for the local roadways that have satisfied the requirements, which are 61 roadways. Furthermore, it could lead to an annual significant increase in ground water by 107,404.7 m3 and slightly reduce the cost of construction and maintenance by up to 1,912,000 ILS during its life period compared to conventional asphalt pavement. Moreover, applying porous asphalt could enhance vehicular traffic safety by improving skid resistance.

Słowa kluczowe

Nablus Palestine pavement sustainability permeable pavement porous pavement sustainable pavement sustainable transportation Westbank

Nablus Palestyna zrównoważony rozwój nawierzchni nawierzchnia przepuszczalna nawierzchnia porowata zrównoważona nawierzchnia zrównoważony transport Westbank

Wydawca

Wydawnictwo Politechniki Śląskiej

Czasopismo

Transport Problems

Rocznik

2024

Tom

T. 19, z. 2

Strony

151--162

Opis fizyczny

Bibliogr. 19 poz.

Twórcy

autor

Hassouna Fady M.A.

fady.h@najah.edu

An-Najah National University, Civil Engineering Department, Nablus, P.O. Box 7, Palestine, Palestine

https://orcid.org/0000-0002-7766-3238

autor

Bdair Reema

rnassar@najah.edu

An-Najah National University, Civil Engineering Department, Nablus, P.O. Box 7, Palestine, Palestine

https://orcid.org/0000-0001-8403-4045

autor

Ali Mohamed

s11642774@najah.edu

An-Najah National University, Civil Engineering Department, Nablus, P.O. Box 7, Palestine, Palestine

https://orcid.org/0009-0002-7380-3480

autor

Mosa Mohannad

s11744278@najah.edu;

An-Najah National University, Civil Engineering Department, Nablus, P.O. Box 7, Palestine, Palestine

https://orcid.org/0009-0000-8540-1556

autor

Kayed Mohammed

s11524055@najah.edu

An-Najah National University, Civil Engineering Department, Nablus, P.O. Box 7, Palestine, Palestine

https://orcid.org/0009-0005-7207-8717

autor

Daraghmeh Faten

s11717844@najah.edu

An-Najah National University, Civil Engineering Department, Nablus, P.O. Box 7, Palestine, Palestine

https://orcid.org/0009-0007-1545-6077

Bibliografia

1. Hassouna, F.M.A. & Jung, Y.W. Developing a Higher Performance and Less Thickness Concrete Pavement: Using a Nonconventional Concrete Mixture. Advances in Civil Engineering. 2020. DOI: 10.1155/2020/8822994.
2. Zhao, Y. & Zhao, C. Research on the Purification Ability of Porous Asphalt Pavement to Runoff Pollution. Adv Mat Res [Internet]. 2012. Vol. 446-449. P. 2439-2448. Available at: https://www.scientific.net/AMR.446-449.2439.
3. Shreyas, K. & Lavanya, J. Comparison of Flexible (Dense Graded) and Porous (Open Graded) Asphalt Surface Course with Stone Dust as a Filler in Marshal Mix Design. The Asian Review of Civil Engineering [Internet]. 2016 Nov 5. Vol. 5(2). P. 1-6. Available at: https://ojs.trp.org.in/index.php/tarce/article/view/2232.
4. Hassouna, F.M.A. & Assad, M. & Koa, I. & Rabaya, W. & Aqhash, A. & Rahhal, A. & et al. Energy and environmental implications of using energy-harvesting speed humps in Nablus City. Palestine. Atmosphere (Basel). 2021 Jul 21. Vol. 12(8). P. 937.
5. Jendia, S. & AlDahdooh, Z. & AbuRahma M. & AbuJayyab, M. & ElDahdouh, A.E. Porous asphalt: a new pavement technology in Palestine. Journal of Engineering Research and Technology. 2018. Vol. 5(1). P. 1-6.
6. Chen, X. & Wang, H. & Najm, H. Environmental assessment and economic analysis of porous pavement at sidewalk. Conference: Pavement Life Cycle Assessment. 2017. Available at: https://www.researchgate.net/publication/317035506_Environmental_assessment_and_economic _analysis_of_porous_pavement_at_sidewalk.
7. Chen, J.S. & Yang, C.H. Porous asphalt concrete: A review of design, construction, performance and maintenance. International Journal of Pavement Research and Technology. 2020 Nov 6. Vol. 13(6). P. 601-612.
8. Zhang, K. & Kevern, J. Review of porous asphalt pavements in cold regions: the state of practice and case study repository in design, construction, and maintenance. Journal of Infrastructure Preservation and Resilience. 2021 Dec 8. Vol. 2(1). P. 1-17.
9. Jasni, N.E. & Masri, K.A. & Jaya, R.P. A Review of Morphological and Chemical Properties of Porous Asphalt. Construction. 2021 Oct 6. Vol. 1(2). P. 45-49.
10. Zhang, K. & Liu, Y. & Nassiri, S. & Li, H. & Englund, K. Performance evaluation of porous asphalt mixture enhanced with high dosages of cured carbon fiber composite materials. Constr Build Mater. 2021 Mar 8. Vol. 274. No. 122066.
11. Nakanishi, H. & Hamzah, M.O. & Mohd Hasan, M.R. & Karthigeyan, P. & Shaur, O. Mix design and application of porous asphalt pavement using Japanese technology. IOP Conf Ser Mater Sci Eng. 2019 Apr 24. Vol. 512. No. 012026.
12. Akhtar, M.N. & Al-Shamrani, A.M. & Jameel, M. & Khan, N.A. & Ibrahim, Z. & Akhtar, J.N. Stability and permeability characteristics of porous asphalt pavement: An experimental case study. Case Studies in Construction Materials. 2021 Dec 1. Vol. 15. No. e00591.
13. Thives, L.P. & Ghisi, E. & Brecht, D.G. & Pires, D.M. Filtering capability of porous asphalt pavements. Water. 2018 Feb 15. Vol. 10(206). P. 1-17. Available at: https://www.mdpi.com/2073- 4441/10/2/206/htm.
14. Kusumawardani, D.M. & Wong, Y.D. The influence of aggregate shape properties on aggregate packing in porous asphalt mixture (PAM). Constr Build Mater. 2020 Sep 20. Vol. 255. No. 119379.
15. Al-Kaissi, Z.A. & Mashkoor, O.G. Durability of porous asphalt pavement. Journal of Engineering and Sustainable Development. 2016. Vol. 20(4). P. 53-70.
16. Eisenberg, B. & Lindow, K.C. & Smith, D.R. Permeable Pavements (ASCE). American Society of Civil Engineers. 2015. DOI: 10.1061/9780784413784.
17. Ali, M. & Mousa, M. & Kayed, M. & Daraghmeh, F. Economic & Environmental Impact assessment for porous asphalt applications in Nablus. Palestine, Nablus: An-Najah National University. 2021.
18. Legret, M. & Colandini, V. Effects of a porous pavement with reservoir structure on runoff water: Water quality and fate of heavy metals. Water Science and Technology. 1999 Jan 1. Vol. 39(2). P. 111-117.
19. Zhang, L. & Ong, G.P. & Fwa, T.F. Developing an analysis framework to quantify and compare skid resistance performance on porous and nonporous pavements. Transportation Research Record: Journal of the Transportation Research Board. 2013 Jan 1. Vol. 2369(1). P. 77-86.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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