Effects On Bitumen Mix By Using Wollastonite And Recycled Polyethylene Terephthalate Granules As Iller
Keywords:
Wollastonite; PET; Marshall stability; Additives; BC mix.
Abstract
India is an emerging economy. India does have world's second-largest motorway network. The road infrastructure is our nation 's backbone, which plays1a vital role1in its4development. The transport infrastructure is our country's biggest means of transport. Substitution of Stone Powder by Wollastonite Dust in the BC mixture fulfills all MORTH requirements and demonstrates enhanced strength properties. The rise in the PET composition of a mixture, the Marshall stability value goes up to 7% PET but instead began to decrease. Maximum stability was seen at 7% PET material, which would have been 56 percent greater than the control mixture. Marshall flow prices have also improved with a rise in PET content. Adding PET improves the mix's Marshall Quotient (MQ), trying to make it stiffer than that of the control mix, and enhancing deformation resistance. Sufficient PET material with highest capacity and high Marshall Quotient has been found to be 7 percent. Sufficient PET quality is considered to be 7%, including average longevity and a large Marshall Quotient.
References
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2. AASHTO T 324. (2011). “Standard method of test for Hamburg wheel-track testing of compacted hot-mix asphalt (HMA)”. Standard Specifications for Transportation Materials and Methods of Sampling and Testing.
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15. IRC: 111. (2009). “Specification for dense graded bituminous mix”. In Indian Road Congress.
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21. Kalantar, Zahra Niloofar, Mohamed Rehan Karim, and Abdelaziz Mahrez. "A review of using waste and virgin polymer in pavement." Construction and Building Materials 33 (2012): 55-62.
22. Karahrodi, Marzieh Habibi, et al. "Modification of thermal and rheological characteristics of bitumen by waste PET/GTR blends." Construction and Building Materials 134 (2017): 157-166.
23. Karaşahin, Mustafa, and Serdal Terzi. "Evaluation of marble waste dust in the mixture of asphaltic concrete." Construction and Building Materials 21.3 (2007): 616-620.
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25. Mistry, R., & Roy, T. K. (2016). “Effect of using fly ash as alternative filler in hot mix asphalt”. Perspectives in Science, 8, 307-309.
26. Modarres, A., & Hamedi, H. (2014). “Effect of waste plastic bottles on the stiffness and fatigue properties of modified asphalt mixes”. Materials & Design, 61, 8-15.
27. Moghaddam, T. B., Karim, M. R., & Syammaun, T. (2012). “Dynamic properties of stone mastic asphalt mixtures containing waste plastic bottles”. Construction and Building Materials, 34, 236-242.
28. Moghaddam, Taher Baghaee, Mehrtash Soltani, and Mohamed Rehan Karim. "Experimental characterization of rutting performance of polyethylene terephthalate modified asphalt mixtures under static and dynamic loads." Construction and Building Materials 65 (2014): 487-494.
29. MoRTH (Ministry of Road Transport and Highways). (2013). “Specifications for road and bridge works”. In Indian Road Congress. New Delhi, India: Author.
30. Murphy, M., et al. "Recycled polymers for use as bitumen modifiers." Journal of materials in civil engineering 13.4 (2001): 306-314.
31. Niazi, Y., and M. Jalili. "Effect of Portland cement and lime additives on properties of cold in-place recycled mixtures with asphalt emulsion." Construction and Building Materials 23.3 (2009): 1338-1343.
32. Punith, V. S., and A. Veeraragavan. "Behavior of reclaimed polyethylene modified asphalt cement for paving purposes." Journal of Materials in Civil Engineering 23.6 (2010): 833-845.
33. Rokade, S. (2012). “Use of waste plastic and waste rubber tyres in flexible highway pavements”. In International conference on future environment and energy, IPCBEE (Vol. 28).
34. Sangita, G. R., & Verinder, K. (2011). “A novel approach to improve road quality by utilizing plastic waste in road construction”. Journal of Environmental Research and Development, 5(4), 1036-1042.
35. Soliman, A. M., & Nehdi, M. L. (2011). “Effect of natural Wollastonite microfibers on early-age behaviour of UHPC”. Journal of Materials in Civil Engineering, 24(7), 816-824.
36. Taha, Ramzi, et al. "Use of cement bypass dust as filler in asphalt concrete mixtures." Journal of materials in civil engineering 14.4 (2002): 338-343.
37. Vasudevan, Gunalaan. "Performance on coal bottom ash in hot mix asphalt." Int. J. Res. Eng. Technol 2319.1167 (2013): 24-33.
38. Vasudevan, R., Sekar, A. R. C., Sundarakannan, B., & Velkennedy, R. (2012). “A technique to dispose waste plastics in an eco-friendly way–Application in construction of flexible pavements”. Construction and Building Materials, 28(1), 311-320.
39. Wahab, Mona Abdel, et al. "The use of Wollastonite to enhance the mechanical properties of mortar mixes." Construction and Building Materials 152 (2017): 304-309.
40. Singh, A., Anand, V., Singh, S., & Sharma, A. (2023). Examining GIS Methodologies and Their Diverse Applications in Solid Waste Management. Journal of Survey in Fisheries Sciences, 10(1), 1442-1447.
2. AASHTO T 324. (2011). “Standard method of test for Hamburg wheel-track testing of compacted hot-mix asphalt (HMA)”. Standard Specifications for Transportation Materials and Methods of Sampling and Testing.
3. AASHTO, T. (1997). 245, “Standard Method of Test for Resistance to Plastic Flow of Bituminous Mixtures Using Marshall Apparatus”. American Association of 59 State Highway and Transportation Officials, Washington, DC.
4. Ahmad, A. F., Razali, A. R., & Razelan, I. S. M. (2017, May). “Utilization of polyethylene terephthalate (PET) in asphalt pavement: A review”. In IOP Conference Series: Materials Science and Engineering (Vol. 203, No. 1, p. 012004). IOP Publishing.
5. Ahmadinia, E., Zargar, M., Karim, M. R., Abdelaziz, M., & Shafigh, P. (2011). “Using waste plastic bottles as additive for stone mastic asphalt”. Materials & Design, 32(10), 4844-4849.
6. Al Sayed, Mohammed H., Ismail M. Madany, and A. Rahman M. Buali. "Use of sewage sludge ash in asphaltic paving mixes in hot regions." Construction and Building Materials 9.1 (1995): 19-23.
7. Al-Hadidy, A. I., & Yi-qiu, T. (2009). “Effect of polyethylene on life of flexible pavements”. Construction and Building Materials, 23(3), 1456-1464.
8. ASTM, E. 303-93 (2003). “Standard Method for Measuring Frictional Properties Using the British Pendulum Tester”. Annual book of ASTM Standards, Road and Paving Materials.
9. Bansal, Shubham, Anil Kumar Misra, and Purnima Bajpai. "Evaluation of modified bituminous concrete mix developed using rubber and plastic waste materials." International Journal of Sustainable Built Environment 6.2 (2017): 442-448.
10. Casey D, McNally C, Gibney A, Gilchrist MD. “Development of a recycled polymer modified binder for use in stone mastic asphalt”. J Resour Conserv Recy 2008; 52:1167–74.
11. Chandra, Satish, and Rajan Choudhary. "Performance characteristics of bituminous concrete with industrial wastes as filler." Journal of materials in civil engineering 25.11 (2012): 1666-1673.
12. Chavan, Miss Apurva J. "Use of plastic waste in flexible pavements." International Journal of Application or Innovation in Engineering and Management 2.4 (2013): 540-552.
13. Gautam, Pradeep Kumar, et al. "Sustainable use of waste in flexible pavement: A review." Construction and Building Materials 180 (2018): 239-253.
14. Gürü, M., Çubuk, M. K., Arslan, D., Farzanian, S. A., & Bilici, I. (2014). “An approach to the usage of polyethylene terephthalate (PET) waste as roadway pavement material”. Journal of hazardous materials, 279, 302-310.
15. IRC: 111. (2009). “Specification for dense graded bituminous mix”. In Indian Road Congress.
16. IRC: SP: 53. (2010). “Guidelines on Use of Modified Bitumen In Road Construction”. In Indian Road Congress. New Delhi.
17. IRC: SP: 98. (2013). “Guidelines for the Use of Waste Plastic in Hot Bituminous Mixes (Dry Process) in Wearing Courses”. In Indian Road Congress. New Delhi.
18. IS: 1202 – 1209. (1978). “Indian Standard methods for testing tar and bituminous materials. Bureau of Indian Standards”. New Delhi.
19. IS: 2386- Parts 1 to 5. (1997). “Indian Standard Methods of Test for Aggregate for Concrete. Bureau of Indian Standards”. New Delhi.
20. IS: 73. (2013). “Indian Standard Specification for Paving Bitumen”. Bureau of Indian Standards. New Delhi.
21. Kalantar, Zahra Niloofar, Mohamed Rehan Karim, and Abdelaziz Mahrez. "A review of using waste and virgin polymer in pavement." Construction and Building Materials 33 (2012): 55-62.
22. Karahrodi, Marzieh Habibi, et al. "Modification of thermal and rheological characteristics of bitumen by waste PET/GTR blends." Construction and Building Materials 134 (2017): 157-166.
23. Karaşahin, Mustafa, and Serdal Terzi. "Evaluation of marble waste dust in the mixture of asphaltic concrete." Construction and Building Materials 21.3 (2007): 616-620.
24. Leng, Z., Padhan, R. K., & Sreeram, A. (2018). “Production of a sustainable paving material through chemical recycling of waste PET into crumb rubber modified asphalt”. Journal of cleaner production, 180, 682-688.
25. Mistry, R., & Roy, T. K. (2016). “Effect of using fly ash as alternative filler in hot mix asphalt”. Perspectives in Science, 8, 307-309.
26. Modarres, A., & Hamedi, H. (2014). “Effect of waste plastic bottles on the stiffness and fatigue properties of modified asphalt mixes”. Materials & Design, 61, 8-15.
27. Moghaddam, T. B., Karim, M. R., & Syammaun, T. (2012). “Dynamic properties of stone mastic asphalt mixtures containing waste plastic bottles”. Construction and Building Materials, 34, 236-242.
28. Moghaddam, Taher Baghaee, Mehrtash Soltani, and Mohamed Rehan Karim. "Experimental characterization of rutting performance of polyethylene terephthalate modified asphalt mixtures under static and dynamic loads." Construction and Building Materials 65 (2014): 487-494.
29. MoRTH (Ministry of Road Transport and Highways). (2013). “Specifications for road and bridge works”. In Indian Road Congress. New Delhi, India: Author.
30. Murphy, M., et al. "Recycled polymers for use as bitumen modifiers." Journal of materials in civil engineering 13.4 (2001): 306-314.
31. Niazi, Y., and M. Jalili. "Effect of Portland cement and lime additives on properties of cold in-place recycled mixtures with asphalt emulsion." Construction and Building Materials 23.3 (2009): 1338-1343.
32. Punith, V. S., and A. Veeraragavan. "Behavior of reclaimed polyethylene modified asphalt cement for paving purposes." Journal of Materials in Civil Engineering 23.6 (2010): 833-845.
33. Rokade, S. (2012). “Use of waste plastic and waste rubber tyres in flexible highway pavements”. In International conference on future environment and energy, IPCBEE (Vol. 28).
34. Sangita, G. R., & Verinder, K. (2011). “A novel approach to improve road quality by utilizing plastic waste in road construction”. Journal of Environmental Research and Development, 5(4), 1036-1042.
35. Soliman, A. M., & Nehdi, M. L. (2011). “Effect of natural Wollastonite microfibers on early-age behaviour of UHPC”. Journal of Materials in Civil Engineering, 24(7), 816-824.
36. Taha, Ramzi, et al. "Use of cement bypass dust as filler in asphalt concrete mixtures." Journal of materials in civil engineering 14.4 (2002): 338-343.
37. Vasudevan, Gunalaan. "Performance on coal bottom ash in hot mix asphalt." Int. J. Res. Eng. Technol 2319.1167 (2013): 24-33.
38. Vasudevan, R., Sekar, A. R. C., Sundarakannan, B., & Velkennedy, R. (2012). “A technique to dispose waste plastics in an eco-friendly way–Application in construction of flexible pavements”. Construction and Building Materials, 28(1), 311-320.
39. Wahab, Mona Abdel, et al. "The use of Wollastonite to enhance the mechanical properties of mortar mixes." Construction and Building Materials 152 (2017): 304-309.
40. Singh, A., Anand, V., Singh, S., & Sharma, A. (2023). Examining GIS Methodologies and Their Diverse Applications in Solid Waste Management. Journal of Survey in Fisheries Sciences, 10(1), 1442-1447.
Published
2024-11-08
How to Cite
Suresh Kumar Choudhary, Ghanshyam Gupta, Deepak Bahuguna, & Abhishek Singh. (2024). Effects On Bitumen Mix By Using Wollastonite And Recycled Polyethylene Terephthalate Granules As Iller. Revista Electronica De Veterinaria, 25(2), 1481-1486. https://doi.org/10.69980/redvet.v25i2.1860
Section
Articles
