A Review on the Application of Bio-oil as an Additive for Asphalt
DOI:
https://doi.org/10.11113/jt.v72.3948Keywords:
Asphalt, biomass, pyrolysis, bio-oil, blendsAbstract
Raising the prices of crude petroleum is affected to good performance for the asphalt paving and has encouraged to modify or replace asphalt bitumen. Increasing numbers of commercial vehicles and increase axle load that this trend will continue yearly. Design, construction and maintenance facilitate asphalt roads to provide the high standards of safety and comfortable but certain areas of a road are higher stressed than others. For that reason road paving industry is interested in utilizing alternative and sustainable binder materials for modified asphalt to improve the production, placement and performance of asphalt mixtures. However, sources of materials should be considered economically and environtmentally viable after applied in pavement. According to previous research, that has been developed that non crude petroleum binder derived from the production of bio-oil through fast pyrolysis of biomass. The main source of bio-oil can be contributed from biomass industry or renewable organic industry such as timber waste, oil palm waste, rice husk; coconut trunk fibers, municipal waste and sugar cane waste. Alternatively, the bio-oil can be as substitute material as modification of asphalt. This paper presents a review on the source, characteristic of bio-oil and the effects of bio-oil on the properties of asphalt bitumen.Â
References
S. Dunn and J. Holloway. 2012. The Pricing of Crude Oil. 65–74.
P. Taylor, E. H. Fini, I. L. Al-qadi, Z. You, and B. Zada. 2012. International Journal of Pavement Engineering. Partial Replacement of Asphalt Binder With Bio-binder: Characterisation and Modification. 37–41.
H. Wen, M. Asce, S. Bhusal, and B. Wen. 2013. Laboratory Evaluation of Waste Cooking Oil-Based Bioasphalt as an Alternative Binder for Hot Mix Asphalt. 25(10): 1432–1437.
T. D. Miller. 2009. Sustainable Asphalt Pavements: Technologies, Knowledge Gaps and Opportunities.
J. A. Gambatese and S. Rajendran. 2005. Sustainable Roadway Construction: Energy Consumption And Material Waste Generation Of Roadways. 541: 1–13.
S. C. Huang, D.Salomon, and J. Haddock. 2012. Alternative Binders for Sustainable Asphalt Pavements. In Laboratory of Waste Cooking Oil-Based as Sustainable Binder for Hot-Mix Asphalt. August.
J. Peralta, C. R. Williams, Marjorie Rover, and Hugo M.R.D. Silva. 2012. Development of Rubber-Modified Fractionated Bio-Oil For Use as Noncrude Petroleum Binder in Flexible Pavements. Transp. Res. Circ. Altern. Bind. Alternative Binders For Sustainable Asphalt Pavements,
E. H. Fini, M. Asce, D. J. Oldham, and T. Abu-lebdeh. 2013. Synthesis and Characterization of Biomodified Rubber Asphalt: Sustainable Waste Management Solution for Scrap Tire and Swine Manure. 3(December): 1454–1461.
P. Taylor, S. Pouget, and F. Loup. 2013. Road Materials and Pavement Design Thermo-mechanical behaviour of mixtures containing bio-binders. November: 37–41.
P. Taylor and A. Demirbas. 2009. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects Fuel Properties of Pyrolysis Oils from Biomass. January 2014: 37–41.
A. A. Salema and F. N. Ani. 2010. Microwave Pyrolysis of Oil Palm Fibres. J. Mek. Univ. Teknol. Malaysia. 30: 77–86.
Q. Lu, W.-Z. Li, and X.-F. Zhu. 2009. Overview of Fuel Properties of Biomass Fast Pyrolysis Oils. Energy Conversion and Management. 50(5): 1376–1383.
P. Taylor, S. Kele, K. Kaygusuz, and M. Akgün. 2014. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects Pyrolysis of Woody Biomass for Sustainable Bio-oil. July: 37–41.
S. Ciuta, F. Patuzzi, M. Baratieri, and M. J. Castaldi. 2014. Journal of Analytical and Applied Pyrolysis Biomass Energy Behavior Study During Pyrolysis Process By Intraparticle Gas Sampling. J. Anal. Appl. Pyrolysis. 108: 316–322.
J. Alvarez, G. Lopez, M. Amutio, J. Bilbao, and M. Olazar. 2014. Bio-oil Production from Rice Husk Fast Pyrolysis in a Conical Spouted Bed Reactor. FUEL. 128:162–169.
P. Taylor and M. Balat. 2011. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects An Overview of the Properties and Applications of Biomass Pyrolysis Oils An Overview of the Properties and Applications of Biomass Pyrolysis Oils. July 2014: 37–41.
F. Abnisa, W. M. A. W. Daud, W. N. W. Husin, and J. N. Sahu. 2011. Utilization Possibilities of Palm Shell as a Source of Biomass Energy in Malaysia By Producing Bio-Oil in Pyrolysis Process. Biomass and Bioenergy. 35(5): 1863–1872.
Demirbas. 2009. Pyrolysis of Biomass for Fuels and Chemicals. Energy Sources, Part A Recover. Util. Environ. Eff. 31(12): 1028–1037.
M. Balat, M. Balat, E. Kırtay, and H. Balat. 2009. Main Routes for the Thermo-Conversion of Biomass Into Fuels and Chemicals. Part 1: Pyrolysis Systems. Energy Convers. Manag. 50(12): 3147–3157.
S. Xiu and A. Shahbazi. 2012. Bio-oil Production and Upgrading Research: A Review. Renewable and Sustainable Energy Reviews. 16(7): 4406–4414.
K. Sivaramakrishnan. 2011. Determination Of Higher Heating Value Of Biodiesels. 3(11): 7981–7987.
D. Chen, J. Zhou, and Q. Zhang. 2014. Bioresource Technology Effects of Heating Rate on Slow Pyrolysis Behavior, Kinetic Parameters and Products Properties of Moso Bamboo. Bioresour. Technol. 169: 313–319.
S. Kim, S. Jung, and J. Kim. 2010. Bioresource Technology Fast Pyrolysis of Palm Kernel Shells: Influence of Operation Parameters on the Bio-oil Yield and the Yield of Phenol and Phenolic Compounds. Bioresour. Technol. 101(23): 9294–9300.
S. W. Lee, T. Herage, I. He, and B. Young. 2008. Particulate Characteristics Data for the Management Of PM2.5 Emissions From Stationary Combustion Sources. Powder Technol. 180(1–2): 145–150.
J.-L. Zheng and Q. Wei. 2011. Improving the Quality of Fast Pyrolysis Bio-oil by Reduced Pressure Distillation. Biomass and Bioenergy. 35(5): 1804–1810.
A. Chaala, T. Ba, M. Garcia-Perez, C. Roy, and D. Rodrigue. 2004. Colloidal Properties of Bio-oils Obtained by Vacuum Pyrolysis of Softwood Bark: Aging and Thermal Stability. Energy & Fuels. 18(5): 1535–1542.
C. Wu, V. L. Budarin, M. J. Gronnow, M. De Bruyn, J. a. Onwudili, J. H. Clark, and P. T. Williams. 2014. Conventional and Microwave-Assisted Pyrolysis of Biomass Under Different Heating Rates. J. Anal. Appl. Pyrolysis. 107: 276–283.
S. Wu, J. Wang, and L. Jiesheng. 2010. Preparation and Fatigue Property of Nanoclay Modified Asphalt Binder. 2010 Int. Conf. Mech. Autom. Control Eng. 1595–1598.
G. D. Airey, M. H. Mohammed, and C. Fichter. 2008. Rheological Characteristics of Synthetic Road Binders. Fuel. 87: 10–11, 1763–1775.
M. Rahman. 2004. Characterisation of Dry Process Crumb Rubber Modified Asphalt Mixtures. The University of Nottingham.
M. Chen, B. Leng, S. Wu, and Y. Sang. 2014. Physical, Chemical And Rheological Properties Of Waste Edible Vegetable Oil Rejuvenated Asphalt Binders. Constr. Build. Mater. 66: 286–298.
P. Cong, J. Wang, K. Li, and S. Chen. 2012. Physical and Rheological Properties of Asphalt Binders Containing Various Antiaging Agents. Fuel. 97: 678–684.
Shell Bitumen. 2003. The Shell Bitumen Handbook. Fifth Edit. London, UK. 190.
L. N. Mohammad, M. Elseifi, S. B. Cooper, and P. Naidoo. 2013. Laboratory Evaluation of Asphalt Mixtures Containing Bio-Binder Technologies. 128–152.
S. H. Imam, C. Bilbao-Sainz, B.-S. Chiou, G. M. Glenn, and W. J. Orts. 2013. Biobased Adhesives, Gums, Emulsions, and Binders: Current Trends And Future Prospects. J. Adhes. Sci. Technol. 27(18–19): 1972–1997.
M. A. Raouf and C. R. Williams. 2010. General Rheological Properties of Fractionated Switchgrass Bio-Oil as a Pavement Material. Road Materials and Pavement Design. 11(sup1): 325–353.
J. Peralta, M. Raouf, S. Tang, and R. Williams. 2012. Bio-Renewable Asphalt Modifiers and Asphalt Substitutes. Sustain. Bioenergy.89–115.
J. Peralta, C. R. Williams, Marjorie Rover, and Hugo M.R.D. Silva, “Alternative Binders for Sustainable Asphalt Pavements,†in Development of rubber-modified fractionated bio-oil for use as noncrude petroleum binder in flexible pavements, 2012, pp. 23–36.
P. Taylor, E. H. Fini, I. L. Al-qadi, Z. You, and B. Zada, 2014. International Journal of Pavement Engineering Partial Replacement of Asphalt Binder With bio-Binder: Characterisation and Modification. 37–41.
X. Yang, Z. You, Q. Dai, and J. Mills-Beale. 2014. Mechanical Performance of Asphalt Mixtures Modified By Bio-Oils Derived From Waste Wood Resources. Constr. Build. Mater. 51: 424–431.
J. Zhu, B. Birgisson, and N. Kringos. 2014. Polymer Modification Of Bitumen : Advances and Challenges. Eur. Polym. J. 54: 18–38.
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