Synthetic Macrofiber: Material Key to Enhancing Infrastructure Sustainability

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Title: Synthetic Macrofiber: Material Key to Enhancing Infrastructure Sustainability

Author(s): Julie K. Buffenbarger, Michael A. Mahoney, and Hessam AzariJaFari

Publication: Symposium Paper

Volume: 361

Issue:

Appears on pages(s): 92-108

Keywords: carbon footprint, durability, fiber-reinforced composite, life cycle assessment

DOI: 10.14359/51740609

Date: 3/1/2024

Abstract:
Worldwide, the need for additional and improved infrastructure is critical. The deterioration of infrastructure has become an increasing challenge and burden on the world's economy, environment, and society. Historically, most structures worldwide have been built without durability and service-life consideration, and their premature failure reflects an acute crisis within the construction industry and the environment. Including synthetic polypropylene macrofiber in concrete structures ensures the maximizing of durability and service life extension and offers potential reductions in the binder content and reinforcing steel materials that contribute to resource depletion, environmental impacts, and increased economic burden. These material reductions and service life improvements present housing and infrastructure construction opportunities that protect the environment and ensure public safety, health, security, serviceability, and life cycle cost-effectiveness.

Related References:

1. Skinner, Jr., R.E., "Highway Design and Construction: The Innovation Challenge," The Bridge, Vol. 38, No. 2, Summer 2008, pp. 5-12.

2. American Association of State Highway and Transportation Officials, "Transportation Invest in Our Future – America's Freight Challenge, May 2007.

3. United Nations Development Programme, "Paving the Way for Climate-Resilient Infrastructure: Guidance for Practitioners and Planners," New York, New York, 2011

4. Rigaud, K.K. and Iqbal, F.Y., "Thematic Note 2: How the PPCR is Supporting Climate Resilient Infrastructure", World Bank Pilot Program for Climate Resilience Coordination Unit, October 31, 2011.

5. Department for Environment, Food and Rural Affairs, Climate Resilient Infrastructure: Preparing for a Changing Climate, United Kingdom, 2011.

6. National Research Council (U.S.), Committee on Climate Change and U.S. Transportation Research Board, Division on Earth and Life Studies; Transportation Research Board Special Report 290: Potential Impacts of Climate Change on U.S. Transportation, Washington DC, 2008.

7. ASCE, 2021, Infrastructure Report Card – Bridges, Accessed on October 10, 2021, at https://infrastructurereportcard.org/wp-content/uploads/2020/12/National_IRC_2021-report.pdf

8. ECD, 2020, Today's Infrastructure Improvements will Drive Tomorrow's Economy, Solutions Brief. Accessed on October 10, 2021, at https://www.ced.org/pdf/TCB-CED-2020-Solutions-Brief-Today%E2%80%99s-Infrastructure-Improvements..pdf

9. PricewaterhouseCoopers Global Division, Rebuilding for resilience-fortifying infrastructure to withstand disaster, 2013, Accessed on October 18, 2021, at https://www.preventionweb.net/publication/rebuildingresilience-fortifying-infrastructure-withstand-disaster.

10. Carpinteri A., Cadamuro, E., and Ventura, G., 2015, Fiber-reinforced concrete in flexure: a cohesive/overlapping crack model application, Materials and Structures, Vol. 48, pp. 235-247.

11. Oh, B.H., Kim, J.C., and Choi, C., 2007, Fracture behavior of concrete members reinforced with structural synthetic fibers, Engineering Fracture Mechanics, Vol. 74, pp 243-257.

12. Zhang P, Li Q-F, 2013, Durability of high-performance concrete composites containing silica fume. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications. 2013;227(4):343-349. doi: 10.1177/1464420712460617.

13. Hejazi, S.M.; Sheikhzadeh, M.; Abtahi, S.M.; Zadhoush, A., 2012, A simple review of soil reinforcement by using natural and synthetic fibers. Construction Building Materials, Vol. 30, pp. 100–116.

14. Mohajerani, Abbas, Siu-Qun Hui, Mehdi Mirzababaei, Arul Arulrajah, Suksun Horpibulsuk, Aeslina Abdul Kadir, Md T. Rahman, and Farshid Maghool. 2019. "Amazing Types, Properties, and Applications of Fibres in Construction Materials" Materials 12, no. 16: 2513, doi: 10.3390/ma12162513.

15. Brandt, A. M., 2008, Fibre reinforced cement-based (FRC) composites after over 40 years of development in building and civil engineering, Composite Structures, Vol 86, pp. 3-9.

16. Saha, P.; Chowdhury, S.; Roy, D.; Adhikari, B.; Kim, J.K.; Thomas, S., 2016, A brief review on the chemical modifications of lignocellulosic fibers for durable engineering composites. Polymer Bulletin, Vol. 73, pp. 587–620.

17. Yin, S.; Tuladhar, R.; Shi, F.; Combe, M.; Collister, T.; Sivakugan, N. Use of macro plastic fibres in concrete: A review. Constr. Build. Mater. 2015, 93, 180–188.

18. Naaman, A.E., 2018, Fiber-reinforced concrete: Five decades of progress. In Proceedings of the 4th Brazilian Conference on Composite Materials, io de Janeiro, Brazil, 22–25 July 2018; pp. 35–56.

19. ASTM International, D7508-20 Standard Specification for Polyolefin Chopped Strands for Use in Concrete.

20. Maier, C. and Calafut, T., 1998, Polypropylene: the definitive user's guide and databook. Norwich, NY: Plastics Design Library. http://www.books24x7.com/marc.asp?bookid=37249.

21. Ding, C., Wu, C., Meng, Z., and Fang, G., 2019). Mechanical properties and characteristic analysis of the new concave-convex polypropylene macro fiber. Journal of Engineered Fibers and Fabrics, 14, pp. 1-7.

22. Brown, R., Shukla, A., and Natarajan, K.R., 2002, Fiber reinforcement of concrete structures University of Rhode Island, URITC PROJECT NO. 536101. URL: https://rosap.ntl.bts.gov/view/dot/16102

23. Yao, Z., Li, X., Fu, C. and Xue, W., 2019. Mechanical properties of polypropylene macrofiber-reinforced concrete. Advances in Materials Science and Engineering, pp.8.

24. Roesler, J. R., Altoubat, S. A., Lange, D. A., Rieder, K. A., & Ulreich, G. R. (2006). Effect of synthetic fibers on the structural behavior of concrete slabs-on-ground. ACI Materials Journal, 103(1), 3-10.

25. Yin, S., Tuladhar, R., Shi, F., Combe, M., Collister, T., and Sivakugan, N., 2015, Use of macro plastic fibres in concrete: A review, Construction and Building Materials, Volume 93, pp. 180-188, ISSN 0950-0618, doi: 10.1016/j.conbuildmat.2015.05.105.

26. Paul, Suvash C., Gideon P.A.G. van Zijl, and Branko Šavija. 2020. "Effect of Fibers on Durability of Concrete: A Practical Review" Materials 13, no. 20: 4562. doi: 10.3390/ma13204562C

27. Khalighi, A., Izadifard, R.A. & Zarifian, A. Role of macro fibers (steel and hybrid-synthetic) in the residual response of R.C. beams exposed to high temperatures. S.N. Appl. Sci. 2, 1981 (2020). doi: 10.1007/s42452-020-03790-z

28. Niu, X., Zhao, Q. and Nie, Y., 2014, "Effect of Polypropylene Macro-Fiber on Properties of High-Strength Concrete at Elevated Temperatures." Key Engineering Materials 629-630 (2014): 284 - 290.

29. Rodrigues, J.P.C, Laím, L., Correia, A.M., 2010, Behaviour of fiber reinforced concrete columns in fire, Composite Structures, Volume 92, Issue 5, pp. 1263-1268. doi: 10.1016/j.compstruct.2009.10.029.

30. Berkowskia, P. and Kosior-Kazberukb, M., 2015, Effect of fiber on the concrete resistance to surface scaling due to cyclic freezing and thawing, Procedia Engineering 111, pp. 121 – 127.

31. Brown, J.J., 2012, Macro Synthetic Fiber Addition to Concrete Marine Structures in Freeze-Thaw Environments (Masters of Applied Science Thesis), Dalhousie University, Halifax, Nova Scotia, Semantic Scholar, https://www.semanticscholar.org/paper/Macro-Synthetic-Fiber-Addition-To-Concrete-Marine-Brown/c1fdb27bd7921472f7e1ab977ad64aeb7b88b397

32. MacDonald, C.N., Ballou, M.L., and Biddle, D.T., 2009, Case Histories Using Synthetic Fiber Reinforced Concrete, Proceedings of Shotcrete for Underground Support XI.

33. Cutright, T., Mahoney, M., Franey, K., and Patnaik, A., 2013, Carbon Footprint Assessment of Polypropylene Fiber Reinforced Concrete Floors. International Journal of the Constructed Environment, 3(1).

34. RSG, Ohio DOT Infrastructure Resiliency Plan, May 2016. It was accessed on October 18, 2021, at https://www.dot.state.oh.us/Divisions/Planning/Environment/Documents/Ohio%20DOT%20Infrastructure%20Resiliency%20Plan.pdf.

35. Rostami, R., Zarrebini, M, Sanginabadi, K, Mostofinejad, D., Abtahi, S.M. and Fashandi, H., 2018, The effect of the specific surface area of macro fibers on the energy absorption capacity of concrete, The Journal of the Textile Institute, Vol. 110, (5), pp. 707-714.

36. Miller, S.A., 2020. The role of cement service life on the efficient use of resources. Environmental Research Letters, 15(2), p.24.

37. American Society of Civil Engineers, Report Card for America's Infrastructure – State of Ohio, Accessed on October 10, 2021, at https://infrastructurereportcard.org/state-item/ohio/.

38. Ohio Department of Transportation, 2021, Slab Bridge Defects: Longitudinal Reinforcing Steel Exposed (not including the edge of the slab) accessed on November 15, 2021, at https://www.dot.state.oh.us/Divisions/Engineering/Structures/bridge%20operations%20and%20maintenance/Pr

eventiveMaintenanceManual/BPMM/repairs/slabbridgemainpage.htm

39. Patnaik, A., and Baah, P., 2015, "Cracking Behavior of Structural Slab Bridge Decks," Final Report, FHWA/OH-2015/4, Ohio Department of Transportation, Columbus, Ohio, Jan. 2015, pp. 1-120.

40. Patnaik, A., Baah, P., Ricciardi, P. and Khalifa, W., 2017, Reduction of Crack Widths in Steel Reinforced Concrete Bridge Decks with Fiber Addition, ACI-SP 319, pp.1-20.

41. Ohio Department of Transportation, 2019, Section 499.03 – Concrete Mix Design, Construction Materials and Specifications, ODOT, Columbus, Ohio. It was accessed on January 8, 2019, at https://www.dot.state.oh.us/Divisions/ConstructionMgt/OnlineDocs/Specifications/2019CMS/2019_CMS_10162018%20Final%20to%20Printer.pdf.