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All issues Volume 519 (2024) E3S Web Conf., 519 (2024) 04011 References
Open Access
Issue
E3S Web Conf.
Volume 519, 2024
5th Talenta Conference on Engineering, Science and Technology (TALENTA CEST-5 2024)
Article Number 04011
Number of page(s) 9
Section Green Technology
DOI https://doi.org/10.1051/e3sconf/202451904011
Published online 01 May 2024
  1. M. M. U. Islam. A study on the integrated implementation of supplementary cementitious material and coarse aggregate for sustainable concrete, Journal of Building Engineering, 73 (2023). [Google Scholar]
  2. K. W. Nindhita, A. Zaki, and A. M. Zeyad. Effect of Bacillus Subtilis Bacteria on The Mechanical Properties of Corroded Self-Healing Concrete, Frattura ed Integrità Strutturale, 18(68), pp. 140–158 (2024). [CrossRef] [Google Scholar]
  3. A. Casal-Campos, S. M. K. Sadr, G. Fu, and D. Butler. Reliable, Resilient and Sustainable Urban Drainage Systems: An Analysis of Robustness under Deep Uncertainty, Environmental Science & Technology, 52(16), pp. 9008–9021 (2018). [CrossRef] [PubMed] [Google Scholar]
  4. A. Zaki, O. Putri, S. Yadi, and E. Rommel. Mechanical Behavior of Corroded Steel in Lightweight Concrete: A Review. in 3rd International Conference on Sustainable Infrastructure, Orlando, Florida, USA. pp 1–15. (2021). [Google Scholar]
  5. A. Zaki, S. Yadi, E. Khoirullianum, R. Suganda, and C. A. Wibisono. Effect of partial replacement of aggregate with oil palm shell on compressive and flexural strength of fiber concrete, Multidisciplinary Science Journal, 6(7) (2024). [Google Scholar]
  6. M. F. Hama, M. P. Anwar, and T. L. Lau. OIL PALM SHELL CONCRETE (OPSC): A SHORT REVIEW, Suranaree Journal of Science and Technology, 30(3) (2023). [Google Scholar]
  7. A. Zaki, I. R. A. Kirana, M. I. Shodiq, C. A. Wibisono, and F. Saleh. The effect of curing on flexural strength of concrete with oil palm shells as a substitute for coarse aggregate, AIP Conference Proceedings, 2846(1) (2023). [Google Scholar]
  8. A. Zaki, M. A. Fikri, C. A. Wibisono, and S. A. P. Rosyidi. Evaluating Pre-Corrosion and PostCorrosion of Oil Palm Shell Concrete with NonDestructive Testing, Key Engineering Materials, 942, pp. 137–162 (2023). [CrossRef] [Google Scholar]
  9. A. Zaki, H. K. Chai, A. Behnia, D. G. Aggelis, J. Y. Tan, and Z. Ibrahim. Monitoring fracture of steel corroded reinforced concrete members under flexure by acoustic emission technique, Construction and Building Materials, 136, pp. 609–618 (2017). [CrossRef] [Google Scholar]
  10. K. W. Nindhita and A. Zaki. State of the art: Correlation self-healing agent and corrosion on concrete. in ICCIM 2023, Jakarta, pp 1–11. (2023). [Google Scholar]
  11. C. A. Wibisono, A. Zaki, F. Saleh, and A. Fauzi. The Effect of Partial Replacement of Aggregate on the Flexural Strength of CorrodedOil Palm Shell Concrete. in AIP Conference Proceedings, pp (2023). [Google Scholar]
  12. N. M. Noor, J. Xiang-ONG, H. M. Noh, N. A. A. Hamid, S. Kuzaiman, and A. Ali. Compressive strength, flexural strength and water absorption of concrete containing palm oil kernel shell. in IOP Conference Series: Materials Science and Engineering, pp 012073. (2017). [CrossRef] [Google Scholar]
  13. S. Ahmad. Residual flexural capacity of corroded reinforced concrete beams. in IOP Conference Series: Materials Science and Engineering, pp 012121. (2018). [CrossRef] [Google Scholar]
  14. L. Song, Z. Fan, and J. Hou. Experimental and analytical investigation of the fatigue flexural behavior of corroded reinforced concrete beams, International Journal of Concrete Structures and Materials, 13(1), pp. 1–14 (2019). [CrossRef] [Google Scholar]
  15. M. N. Huda, M. Z. Jumaat, A. S. Islam, and W. A. Al-Kutti. Performance of high strength lightweight concrete using palm wastes, IIUM Engineering Journal, 19(2), pp. 30–42 (2018). [CrossRef] [Google Scholar]
  16. D. Oyejobi, S. Raji, and A. Jimoh. Performance Study of Fresh and Hardened Properties of Palm kernel Shell-Rice Husk Ash Aggregate Concrete, LAUTECH Journal of Civil and Environmental Studies, 2(1), pp. 45–53 (2019). [CrossRef] [Google Scholar]
  17. A. Zaki and Z. Ibrahim. Secondary AE Analysis of Pre-corroded Concrete Beam. in Proceedings of the 5th International Conference on Rehabilitation and Maintenance in Civil Engineering, Singapore, pp 243–255. (2023). [CrossRef] [Google Scholar]
  18. V. Swamynadh and K. Muthumani. Properties of structural lightweight concrete containing treated oil palm shell as coarse aggregate, Asian Journal of Civil Engineering, 19(6), pp. 673–678 (2018). [CrossRef] [Google Scholar]
  19. S. T. Lee, N. Handika, E. Tjahjono, and E. Arijoeni. Study on the effect of pre-treatment of Oil Palm Shell (OPS) as coarse aggregate using hot water 50-° C and room temperature water 28-° C to lightweight concrete strength. in MATEC Web of Conferences, pp 01023. (2019). [CrossRef] [EDP Sciences] [Google Scholar]
  20. M. Khan, W. L. Guong, T. J. Deepak, and S. Nair. Use of Oil Palm Shell as Replacement of Coarse Aggregate for Investigating Properties of Concrete, International Journal of Applied Engineering Research, 11(4), pp. 2379–2383 (2016). [Google Scholar]
  21. M. Wasim, T. D. Ngo, and M. Abid. Investigation of long-term corrosion resistance of reinforced concrete structures constructed with various types of concretes in marine and various climate environments, Construction and Building Materials, 237, pp. 117701. (2020). [CrossRef] [Google Scholar]
  22. Z. Amri, A. Abdullah, and S. Fonna. Perbandingan Laju Korosi Pada Tulangan Beton Busa Normal Dan Beton Busa Pozzolan, Jurnal Teknik Sipil, 1(4), pp. 885–894 (2018). [CrossRef] [Google Scholar]
  23. H. Rahayu, A. Zaki, F. Saleh, and A. Fauzi. The effect of different acceleration corrosion processes on flexural strength of oil palm shell concrete. in AIP Conference Proceedings, pp (2023). [Google Scholar]
  24. M. Saberian, J. Li, S. Kilmartin-Lynch, and M. Boroujeni. Repurposing of COVID-19 single-use face masks for pavements base/subbase, Science of the Total Environment, 769, pp. 145527. (2021). [CrossRef] [Google Scholar]
  25. BSN. Metode uji untuk analisis saringan agregat halus dan agregat kasar (Test method for sieve analysis of fine aggregate and coarse aggregate), Badan Standarisasi Nasional: Jakarta (2012). [Google Scholar]
  26. BSN. Tata Cara Pembuatan Rencana Campuran Beton Normal (Procedures for Making a Normal Concrete Mix Plan), Badan Standarisasi Nasional: Jakarta (2000). [Google Scholar]
  27. BSN. Metode uji kekuatan lentur beton menggunakan balok sederhana dengan beban terpusat di tengah bentang (The concrete flexural strength test method uses a simple beam with a concentrated load in the middle of the span), Badan Standarisasi Nasional: Jakarta. pp. 1–12. (2014). [Google Scholar]
  28. R. T. Loto. Pitting corrosion evaluation and inhibition of stainless steels: A review, J. Mater. Environ. Sci., 6(10), pp. 2750–2762 (2015). [Google Scholar]
  29. K. H. Mo, P. Visintin, U. J. Alengaram, and M. Z. Jumaat. Prediction of the structural behaviour of oil palm shell lightweight concrete beams, Construction and Building Materials, 102, pp. 722–732 (2016). [CrossRef] [Google Scholar]
  30. Y. Du, L. A. Clark, and A. H. Chan. Impact of reinforcement corrosion on ductile behavior of reinforced concrete beams, ACI Structural Journal, 104(3), pp. 285 (2007). [Google Scholar]
  31. W. Zhu, R. François, C. S. Poon, and J.-G. Dai. Influences of corrosion degree and corrosion morphology on the ductility of steel reinforcement, Construction and Building Materials, 148, pp. 297–306 (2017). [CrossRef] [Google Scholar]
  32. R. Othman, R. P. Jaya, K. Muthusamy, M. Sulaiman, Y. Duraisamy, M. M. A. B. Abdullah, A. Przybył, W. Sochacki, T. Skrzypczak, and P. Vizureanu. Relation between density and compressive strength of foamed concrete, Materials, 14(11), pp. 2967 (2021). [CrossRef] [PubMed] [Google Scholar]
  33. D. Falliano, D. De Domenico, G. Ricciardi, and E. Gugliandolo. Compressive and flexural strength of fiber-reinforced foamed concrete: Effect of fiber content, curing conditions and dry density, Construction and building materials, 198, pp. 479–493 (2019). [CrossRef] [Google Scholar]
  34. R. Abousnina, S. Premasiri, V. Anise, W. Lokuge, V. Vimonsatit, W. Ferdous, and O. Alajarmeh. Mechanical properties of macro polypropylene fibre-reinforced concrete, Polymers, 13(23) (2021). [Google Scholar]
  35. M. H. El Ouni, S. H. A. Shah, A. Ali, S. Muhammad, M. S. Mahmood, B. Ali, R. Marzouki, and A. Raza. Mechanical performance, water and chloride permeability of hybrid steel-polypropylene fiber-reinforced recycled aggregate concrete, Case Studies in Construction Materials, 16, pp. e00831. (2022). [CrossRef] [Google Scholar]
  36. J. Nepal. Modeling residual flexural strength of corroded reinforced concrete beams, ACI Structural Journal, 115(6), pp. 1625–1635 (2018). [Google Scholar]

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