Abstract
The palm oil industry contributes about 85 percent of the total biomass production in Malaysia, hence offering great potential for renewable power generation and other green products. However, supply chain literature and industry players have identified that one of the main barriers to a successful biorefinery industry is the lack of sustainable supply chain for feedstocks, particularly feedstock logistics. Feedstock logistics encompass all necessary operations that source and supply feedstocks from the plantation field or forest to the throat of conversion reactor at a biorefinery plant. Depending on the biomass type, the feedstock major logistics components typically include harvest and collection, storage, pre-processing, and transport. These components are interdependent and should be considered and planned from a chain perspective rather than separately in order to achieve an efficient and cost-effective biomass supply. Feedstock logistics, particularly in developing economies such as Malaysia, has received limited attention in the biorefinery supply chain literature. Therefore, it is imperative that we highlight some of the barriers and challenges faced by the industry players along the oil palm biomass feedstock logistics chain. The overview of feedstock logistics issues associated with the oil palm biomass will provide a perspective from which an industry’s viability can be evaluated and help the industry players to better understand feedstock logistics risks and improve their logistics processes for a sustainable, efficient and cost-effective feedstock supply.
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References
AIM (Agensi Inovasi Malaysia). (2013). National biomass strategy 2020. www.nbs2020.gov.my/. Accessed 20.10.16.
Allen, J., Browne, M., Hunter, A., Boyd, J., & Palmer, H. (1998). Logistics management and costs of biomass fuel supply. International Journal of Physical Distribution and Logistics Management, 28(6), 463–477.
Badger, P. C., & Fransham, P. (2006). Use of mobile fast pyrolysis plants to densify biomass and reduce biomass handling costs – A preliminary assessment. Biomass and Bioenergy, 30(4), 321–325.
Carpenter, D., Westover, T. L., Czernik, S., & Jablonski, W. (2014). Biomass feedstocks for renewable fuel production: A review of the impacts of feedstock and pre-treatment on the yield and product distribution of fast pyrolysis bio-oils and vapors. Green Chemistry, 16, 384–406.
Chin, K. L., H’ng, P. S., Go, W. Z., Wong, W. Z., Lim, T. W., Maminski, M., & Luqman, A. C. (2013). Optimization of torrefaction conditions for high energy density solid biofuel from oil palm biomass and fast growing species available in Malaysia. Industrial Crops and Products, 49, 768–774.
Darr, M. J., & Shah, A. (2012). Biomass storage: An update on industrial solutions for baled biomass feedstocks. Biofuels, 3(3), 321–332.
De Meyer, A., Cattrysse, D., & Van Orshoven, J. (2015). A generic mathematical model to optimise strategic and tactical decisions in biomassbased supply chains (OPTIMASS). European Journal of Operational Research, 245(1), 247–264.
El-Chichakli, B., von Braun, J., Lang, C., Barben, D., & Philp, J. (2016). Five cornerstones of a global bioeconomy. Nature, 535, 221–223.
European Commission. (2016). Bioeconomy. www.ec.europa.eu/research/bioeconomy/. Accessed 15.08.16.
Hansen, U. E., & Ockwell, D. (2014). Learning and technological capability building in emerging economies: The case of the biomass power equipment industry in Malaysia. Technovation, 34, 617–630.
Hess, J. R., Wright, C. T., & Kenney, K. L. (2007). Cellulosic biomass feedstocks and logistics for ethanol production. Biofuels, Bioproducts & Biorefining, 1(3), 181–190.
Kenney, K. L., Smith, W. A., Gresham, G. L., & Westover, T. L. (2013). Understanding biomass feedstock variability. Biofuels, 4(1), 111–127.
Khoo, D. (2014). Palm oil industry needs to invest more in downstream activities. www.thestar.com.my/business/business-news/2014/06/21/call-to-venture-downstream-palm-oil-industry-needs-to-invest-more-in-downstream-activities-to-reduc/. Accessed 20.10.16.
Kumar, P., Barrett, D. M., Delwiche, M. J., & Stroeve, P. (2009). Methods for pre-treatment of lignocellulosic biomass for efficient hydrolysis and biofuel production. Industrial & Engineering Chemistry Research, 48(8), 3713–3729.
Kurian, J. K., Nair, G. P., Hussain, A., & Raghavan, G. S. V. (2013). Feedstocks, logistics and pre-treatment processes for sustainable lignocellulosic biorefineries: A comprehensive review. Renewable and Sustainable Energy Reviews, 25, 205–219.
Lim, C. H., & Lam, H. L. (2016). Biomass supply chain optimisation via novel Biomass Element Life Cycle Analysis (BELCA). Applied Energy, 161, 733–745.
Lin, T., Rodríguez, L. F., Yogendra, N., Shastri, Y. N., Hansen, A. C., & Ting, K. C. (2014). Integrated strategic and tactical biomass–biofuel supply chain optimization. Bioresource Technology, 156, 256–266.
Malaysian Bioeconomy Development Corporation. (2016). Bioeconomy Malaysia. www.bioeconomycorporation.my/bioeconomy-malaysia/. Accessed 02.08.16.
McKendry, P. (2002). Energy production from biomass (Part 1): Overview of biomass. Bioresource Technology, 83, 37–46.
Miao, Z., Shastri, Y., Grift, T. E., Hansen, A. C., & Ting, A. C. (2012). Lignocellulosic biomass feedstock transportation alternatives, logistics, equipment configurations, and modeling. Biofuels, Bioproducts & Biorefining, 6(3), 351–362.
MPOB. (2017). Economics and industry development division. Malaysia Palm Oil Board. http://bepi.mpob.gov.my/index.php/my/. Accessed 02.01.17.
Oudenhoven, S. R. G., van der Ham, A. G. J., van den Berg, H., Westerhof, R. J. M., & Kersten, S. R. A. (2016). Using pyrolytic acid leaching as a pre-treatment step in a biomass fast pyrolysis plant: Process design and economic evaluation. Biomass and Bioenergy, 95, 388–404.
Piotrowski, S., Carus, M., & Carrez, D. (2016). European bioeconomy in figures, bio-based industries consortium. Brussels. biconsortium.eu/sites/biconsortium.eu/files/downloads/20160302_Bioeconomy_in_figures.pdf. Accessed 30.04.16.
Rentizelas, A. A., Tolis, A. J., Tatsiopoulos, I. P., & I.P. (2009). Logistics issues of biomass: The storage problem and the multi-biomass supply chain. Renewable and Sustainable Energy Reviews, 13, 887–894.
Rodriguez, C., Alaswad, A., Mooney, J., Prescott, T., & Olabi, A. G. (2015). Pre-treatment techniques used for anaerobic digestion of algae. Fuel Processing Technology, 138, 765–779.
Samiran, N. A., Jaafar, M. N. M., Ng, J. N., Lam, S. S., & Chong, C. T. (2016). Progress in biomass gasification technique – With focus on Malaysian palm biomass for syngas production. Renewable and Sustainable Energy Reviews, 62, 1047–1062.
Shafawati, S. N., & Siddiquee, S. (2013). Composting of oil palm fibres and Trichoderma spp. as the biological control agent: A review. International Biodeterioration & Biodegradation, 85, 243–253.
Sharma, B., Ingalls, R. G., Jones, C. L., & Khanchi, A. (2013). Biomass supply chain design and analysis: Basis, overview, modeling, challenges, and future. Renewable and Sustainable Energy Reviews, 24, 608–627.
Tabil, L., Adapa, P., & Kashaninejad, M. (2011). In A. M. Santos Bernardes (Ed.), Biofuel's engineering process technology (pp. 411–438). Croatia: InTech.
Tay, D. H. S., Ng, D. K. S., & Tan, R. R. (2012). Robust optimization approach for synthesis of integrated biorefineries with supply and demand uncertainties. Environmental Progress & Sustainable Energy, 32(2), 384–389.
US Energy Information Administration (EIA). (2016). Chapter 1: World energy demand and economic outlook. www.eia.gov/outlooks/ieo/world.cfm. Accessed 20.12.16.
Viaggi, D. (2016). Towards an economics of the bioeconomy: Four years later. Bio-based and Applied Economics, 5(2), 101–112.
Zahari, M. A. K. M., Zakaria, M. R., Ariffin, H., Mokhtar, M. N., Salihon, J., Shirai, Y., & Hassan, M. A. (2012). Renewable sugars from oil palm frond juice as an alternative novel fermentation feedstock for value-added products. Bioresource Technology, 110, 556–561.
Zakariah, Z. (2016). Boost for renewable energy sector. www.nst.com.my/news/2016/11/193062/boost-renewable-energy-sector. Accessed 02.12.16.
Zhang, J., Osmani, I., Awudu, I., & Gonela, V. (2013). An integrated optimization model for switchgrass-based bioethanol supply chain. Applied Energy, 102, 1205–1217.
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Yatim, P., Ngan, S.L., Lam, H.L. (2018). Sustainable Supply Chain: Feedstock Logistics Issues of Palm Oil Biomass Industry in Malaysia. In: Sayigh, A. (eds) Transition Towards 100% Renewable Energy. Innovative Renewable Energy. Springer, Cham. https://doi.org/10.1007/978-3-319-69844-1_43
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DOI: https://doi.org/10.1007/978-3-319-69844-1_43
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