Difference between revisions of "Biomass for Bioenergy Production"
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− | < | + | == '''<font size="3">Introduction</font>''' == |
− | = '''<font size=" | + | <font face="arial,arial" size="3"><font face="arial,arial" size="3"><font size="3">Developing renewable energy sources have become favorable given policies that are geared towards enhancing the currently dependent global energy system on limited and unsustainable fossil fuel resources. That notwithstanding, current trends also calls for reducing related environmental emissions of fossil fuels. Therefore, taking advantage of biomass energy, which is the transformation of biomass into practical forms of energy such as heat, electricity and liquid fuels,</font>'''<font face="arial,arial" size="1"><font face="arial,arial" size="1">i</font></font>'''<font size="3">appears to be a more feasible alternative for the future production of energy, including a wide range of other potentially environmental friendly processes. Some of the difficulties facing the increased usage of biomass waste utilization for energy production however include: access to information on the possibilities, affordability of the technology and the operation and maintenance of plants. This article gives an overview on biomass and bioenergy sources, environmental and social effects, global demand and bioenergy opportunities, and barriers and issues.</font></font></font> |
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+ | == '''<font face="arial,arial" size="3"><font face="arial,arial" size="3">Bioenergy</font></font>''' == | ||
− | == Bioenergy | + | <font face="arial,arial" size="3"><font face="arial,arial" size="3">Bioenergy is entrenched in multifaceted ways in global biomass systems for food, fodder and fibre production and for forest crops as well as in wastes and residue management. Bioenergy plays a critical role in the livelihoods of billions of people in developing countries. Sources of bioenergy vary from both plant and animal sources. In principle, biomass serves as the primary source of bioenergy'''<font size="1">ii</font>'''<font face="arial,arial" size="3"><font face="arial,arial" size="3">. In developing countries and marginalized populations, traditional biomass is utilized for cooking purposes, heating and lighting. Charcoal for instance is becoming increasingly a secondary energy carrier in rural areas with the probability of generating productive chains. The incremental magnitude of traditional biomass use and the global primary energy supply from traditional biomass to the world’s industrial wood production is shown in Figure 1a. Nonetheless, the frequency and unsustainable use of this traditional biomass sources (wood, charcoal, residue from agriculture processes, and animal dung) through combustion generate serious negative impacts on health and living conditions '''<font size="1">ii</font>'''<font size="1">iii</font><font face="arial,arial" size="3"><font face="arial,arial" size="3">.</font></font></font></font></font></font> |
− | + | <br/><font face="arial,arial" size="3"><font face="arial,arial" size="3">Figure 1b shows the types of biomass used for bioenergy.</font></font> <font face="arial,arial" size="3"><font face="arial,arial" size="3">Intensification of bioenergy production implies refining land and water use management and this requires a more global productive increase in feedstock for food, fodder, fibre, forest products and energy; important improvements in technology adaptation; and an advanced understanding of related social, energy and environmental connections linked to bioenergy production and usage. Modern bioenergy uses high efficiency and convenient solids, liquids and gases as secondary energy movers to generate heat, electricity, combined heat and power (CHP), and also fuels for transport in various sectors. Gases resulting from biomass are primarily methane which is obtained through anaerobic digestion of agricultural residues and municipal solid waste treatment and used for generation of electricity, heat or both</font></font> | |
+ | <br/><font face="arial,arial" size="3"><font face="arial,arial" size="3"><font size="1"><font size="1">Figure 1:</font></font></font></font> | ||
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+ | <font face="arial,arial" size="3"><font face="arial,arial" size="3"><font size="1"><font size="1"><font face="arial,arial" size="1"><font face="arial,arial" size="1">a) Shares of global primary biomass sources for energy (b) Fuel wood used in developing countries parallels world industrial roundwood</font></font>'''<font size="1">1</font>'''<font face="arial,arial" size="1"><font face="arial,arial" size="1">production levels.</font></font></font></font></font></font> | ||
+ | <br/><font face="arial,arial" size="3"><font face="arial,arial" size="3"><font size="1"><font size="1"><font face="arial,arial" size="1"><font face="arial,arial" size="1">Source: IPCC 2011, Special Report on Renewable Energies</font></font></font></font></font></font> | ||
+ | <br/><font face="arial,arial" size="3"><font face="arial,arial" size="3">'''''''<font size="3">Figure 1(b) shows the magnitude of traditional biomass use and the global primary energy supply from traditional biomass to the world’s industrial wood production.</font></font></font> | ||
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− | <font face="arial,arial" size=" | + | <font face="arial,arial" size="3"><font face="arial,arial" size="3"><font size="3">Source:IPCC 2011, Special Report on Renewable Energies</font></font></font> |
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− | + | === <br/>References === | |
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− | + | iAntonia V. Herzog et al. 2001 RENEWABLE ENERGY SOURCES | |
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+ | </font><font face="calibri,calibri" size="1"><font face="calibri,calibri" size="1">ii IPCC, 2011: IPCC Special Report on Renewable Energy Sources and Climate Change Mitigation. Prepared by Working Group III of the Intergovernmental Panel on Climate Change [O. Edenhofer, R. Pichs-Madruga, Y. Sokona, K. Seyboth, P. Matschoss, S. Kadner, T. Zwickel, P. Eickemeier, G. Hansen, S. Schlömer, C. von Stechow (eds)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1075 pp.</font></font> |
Revision as of 15:06, 25 June 2014
Biomass for bioenergy production
Introduction
Developing renewable energy sources have become favorable given policies that are geared towards enhancing the currently dependent global energy system on limited and unsustainable fossil fuel resources. That notwithstanding, current trends also calls for reducing related environmental emissions of fossil fuels. Therefore, taking advantage of biomass energy, which is the transformation of biomass into practical forms of energy such as heat, electricity and liquid fuels,iappears to be a more feasible alternative for the future production of energy, including a wide range of other potentially environmental friendly processes. Some of the difficulties facing the increased usage of biomass waste utilization for energy production however include: access to information on the possibilities, affordability of the technology and the operation and maintenance of plants. This article gives an overview on biomass and bioenergy sources, environmental and social effects, global demand and bioenergy opportunities, and barriers and issues.
Bioenergy
Bioenergy is entrenched in multifaceted ways in global biomass systems for food, fodder and fibre production and for forest crops as well as in wastes and residue management. Bioenergy plays a critical role in the livelihoods of billions of people in developing countries. Sources of bioenergy vary from both plant and animal sources. In principle, biomass serves as the primary source of bioenergyii. In developing countries and marginalized populations, traditional biomass is utilized for cooking purposes, heating and lighting. Charcoal for instance is becoming increasingly a secondary energy carrier in rural areas with the probability of generating productive chains. The incremental magnitude of traditional biomass use and the global primary energy supply from traditional biomass to the world’s industrial wood production is shown in Figure 1a. Nonetheless, the frequency and unsustainable use of this traditional biomass sources (wood, charcoal, residue from agriculture processes, and animal dung) through combustion generate serious negative impacts on health and living conditions iiiii.
Figure 1b shows the types of biomass used for bioenergy. Intensification of bioenergy production implies refining land and water use management and this requires a more global productive increase in feedstock for food, fodder, fibre, forest products and energy; important improvements in technology adaptation; and an advanced understanding of related social, energy and environmental connections linked to bioenergy production and usage. Modern bioenergy uses high efficiency and convenient solids, liquids and gases as secondary energy movers to generate heat, electricity, combined heat and power (CHP), and also fuels for transport in various sectors. Gases resulting from biomass are primarily methane which is obtained through anaerobic digestion of agricultural residues and municipal solid waste treatment and used for generation of electricity, heat or both
Figure 1:
a) Shares of global primary biomass sources for energy (b) Fuel wood used in developing countries parallels world industrial roundwood1production levels.
Source: IPCC 2011, Special Report on Renewable Energies
''Figure 1(b) shows the magnitude of traditional biomass use and the global primary energy supply from traditional biomass to the world’s industrial wood production.
Source:IPCC 2011, Special Report on Renewable Energies
References
iAntonia V. Herzog et al. 2001 RENEWABLE ENERGY SOURCES
ii IPCC, 2011: IPCC Special Report on Renewable Energy Sources and Climate Change Mitigation. Prepared by Working Group III of the Intergovernmental Panel on Climate Change [O. Edenhofer, R. Pichs-Madruga, Y. Sokona, K. Seyboth, P. Matschoss, S. Kadner, T. Zwickel, P. Eickemeier, G. Hansen, S. Schlömer, C. von Stechow (eds)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 1075 pp.