Authors: A. M. Hasna

Abstract:

Today global warming, climate change and energy supply are of greater concern as it is widely realized that the planet earth does not provide an infinite capacity for absorbing human industrialization in the 21st century. The aim of this paper is to analyze upstream and downstream electricity production in selected case studies: a coal power plant, a pump system and a microwave oven covering and consumption to explore the position of energy efficiency in engineering sustainability. Collectively, the analysis presents energy efficiency as a major pathway towards sustainability that requires an inclusive and a holistic supply chain response in the engineering design process.

Keywords: Sustainability, technology, efficiency, engineering, energy.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1060489

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1497

References:

[1] G. O. Brunt land, G., ed. Our Common Future. United Nations World Commission on Environment and Development (WCED). 1987, Oxford University Press: New York.
[2] Johnston, S.F. Sustainability and Globalization: a positive role for engineering. in 4th Annual AAEE Australasian Association for Engineering Education Conference,. 2003. Melbourne, Australia, 29 Sept - 1 Oct, 2003. Australasian Association for Engineering Education.
[3] (EESD), International Conference: Translating Sustainability into Concrete Targets,. Lyons, France, ed. E.E.i.S. Development. 2006.
[4] Mohandas, Taher-shamsiA., and R. Maknoun, the role of environmental engineering education in sustainable development in Iran: AUT experience International Journal of Sustainability in Higher Education, 2007. 8(2): p. 123 - 130.
[5] "The engineer-s response to sustainable development." World Federation of Engineering Organizations. http://www.ecouncil.ac.cr/rio/focus/ report/english/wfeo.htm) (September 2007) in World Federation of Engineering Organizations (WFEO). 1997.
[6] WFEO. Overview of Engineering Response at the International Level to the call for Sustainable Development. (cited 2008 3 December); World Federation of Engineering Organizations (WFEO)]. Available from: www.iies.es/FMOI-WFEO/desarrollosostenible/main/progress.htm.
[7] Mitchell, C.A., Integrating sustainability in chemical engineering practice and education: concentricity and its consequences. Process Safety and Environmental Protection, 2000. 78(B4): p. 237-242.
[8] Crofton, F., Educating for sustainability: opportunities in undergraduate engineering. Journal of Cleaner Production, 2000. 8 p. 397-405.
[9] Cortes, A.D., The Critical Role of Higher Education in Creating a Sustainable Future, planning for higher education. 2003, Boston, Massachusetts.
[10] Wane, V., T. Gag, and S. Sharma, The role of technical institutions in developing a techno-entrepreneurial workforce for sustainable development of SMEs in India. International Journal of Management and Enterprise Development, 2003. 1(1): p. 71 - 88.
[11] Mitchell, C.A., A. Care, and R. Cleft, The role of the professional engineers and scientists in sustainable development, in Sustainable development in practice: case studies for engineers and scientists, A.P. Azapagic, Clift, R, Editor. 2004, John Wiley & Sons: Chichester, UK,. p. 29-55.
[12] Mihelcic, J.R., et al., Sustainability Science and Engineering: The Emergence of a New Metadiscipline. Environent Science Technol, 2003. 37: p. 5314-5324.
[13] Haghighi, 2005.
[14] Batterham, R.J., Sustainability The next chapter. Chemical Engineering Science, 2006. 61(13): p. 4188-4193.
[15] Garcia, F.J.L., K. Kevany, and D. Huisingh, Sustainability in higher education: what is happening? Journal of Cleaner Production, 2006. 14(9-11): p. 757-760.
[16] Dijkema, G.P.J., et al., Trends and opportunities framing innovation for sustainability in the learning society. Technological Forecasting and Social Change, 2006. 73(3).
[17] Costa, S. and M. Scoble, An interdisciplinary approach to integrating sustainability into mining engineering education and research. Journal of Cleaner Production, 2006. 14(3-4): p. 366-373.
[18] Chen, K.C., et al., Infusing the Materials Engineering Curriculum with Sustainability Principles, in American Society for Engineering Education Annual Conference Proceedings. 2006.
[19] Kamp, L., Engineering education in sustainable development at Delft University of Technology. Journal of Cleaner Production, 2006. 14(9- 11): p. 928-931.
[20] Seliger, G., et al., Approaches to sustainable manufacturing. International Journal of Sustainable Manufacturing, 2008. 1(1-2): p. 58 - 77.
[21] Holmberg, J., et al., Embedding sustainability in higher education through interaction with lecturers: Case studies from three European technical universities. European Journal of Engineering Education, 2008. 33(3): p. 271-282.
[22] Segalas, J., D. Ferrer-Balas, and K.F. Mulder, Conceptual maps: measuring learning processes of engineering students concerning sustainable development. European Journal of Engineering Education, 2008. 33(3): p. 297-306.
[23] Conlon, E., The new engineer: between employability and social responsibility. European Journal of Engineering Education, 2008. 33(2): p. 151 - 159.
[24] Manfred, F., Overcoming Established Thinking Models. The Role of Engineering Education in Environmental Sustainabilit. Industry & Higher Education, 2003. 17 (4): p. 283-89.
[25] Lockyer, J., Evolution of Engineering Education in Canada, New Challenges for Canadian Universities. Canadian academy of engineering, 1999. Engineering Issues (8,).
[26] Hammond, G.P., Energy, environment and sustainable development: a UK perspective. Transactions of the Institution of Chemical Engineers, 2000. Part B: Process Safety and Environmental Protection (78): p. 304- 323.
[27] Duncan, R.C., World energy production, population growth, and the road to the Olduvai Gorge. Population and Environment, 2001. 5.
[28] Edmonds, J. and J.M. Reiley, Global energy - assessing the future. 1985, New York, NY: Oxford University Press.
[29] Price, L., et al., Sectoral Trends and Driving Forces of Global Energy Use and Greenhouse Gas Emissions. Mitigation and Adaptation Strategies for Global Change, 1998. 3(2-4).
[30] Bodart, M. and A. De Herde, Global energy savings in offices buildings by the use of day lighting. Energy & Buildings, 2002. 34( 5): p. 421- 429.
[31] Leggett, J.K., Half gone: oil, gas, hot air, and the global energy crisis, in Portobello Books. 2005.
[32] Lieberthal, K. and M. Herberg, China's Search for Energy Security: Implications for US Policy. National Bureau of Asian Research NBR analysis, 2006. 17(1).
[33] Kreith, F. and D.Y. Goswami, Handbook of Energy Efficiency and Renewable Energy. 2007: CRC Press.
[34] Kato, N. and H. Akimoto, Anthropogenic emissions of SO2 and NOx in Asia: Emission inventories. Atmospheric Environment, 2007. 41(1): p. 171-191.
[35] Heger, M., The Price Is Wrong for Oil Shale and Tar Sand Tech. IEEE Spectrum, 2008.
[36] Bush, G.W., the Energy Independence and Security Act of 2007, in President of United States of America,. 2007.
[37] Oktay, Z., Investigation of coal-fired power plants in Turkey and a case study: Can plant. Applied Thermal Engineering, 2009. 29: p. 550-557.
[38] Anderson, D., Part IV, where do we go from here? Energy and economic prosperity, in chapter11, World Energy Assessment: Energy and the Challenge of Sustainability. 2004. p. 394.
[39] Lee, H. and S.K. Verma, Coal or Gas: The Cost of Cleaner Power in the Midwest, in BCSIA Discussion Paper 2000-08, ENRP Discussion Paper E-2000-08. 2000, Harvard University: Kennedy School of Government.
[40] Lovins, A.B., More Profit with Less Carbon, Science America. 2005. 293: p. 74-82.
[41] Himmelblau, D.M. and J.B. Riggs, Basic principles and calculations in chemical engineering. 7th ed. 2004: Prentice-Hall.
[42] George, K.D., The Economics Of Nuclear And Conventional Coal-Fired Stations in the United kingdom, in Oxford Economic Papers. 1960. p. 294.
[43] Pouris, A., On the Economics of Nuclear and Coal - Fired Electricity Generation. South African Journal of Economics, 1987. 55(4): p. 267- 276.
[44] Johansson, T.B. and J. Goldemberg, World Energy Assessment Overview: 2004 Update. 2004-05: UNDP, UN-DESA and the World Energy Council.
[45] Engineering, T.R.A.O., Costs of Generating Electricity. 2004: Westminster, London.
[46] Ramage, J., Energy A Guidebook. Oxford. 1997: Oxford University Press.
[47] PERSPECTIVES, E.T., International Energy Agency. 2006, Paris, France.
[48] Akmal, M. and D. Riwoe, AUSTRALIAN ENERGY, national and state projections to 2029-30. ABARE eReport 05.9. 2005, Canberra: Commonwealth of Australia.
[49] Kobayashi, K., Energy Efficiency in the Apec Region The Power Sector, ed. A.A. Aponte. 2008, Tokyo, Japan: Asia Pacific Energy Research Centre (APERC).
[50] Okura, R., et al., Completion of High-efficiency Coal-fired Power Plant.Hitachi Review, 2003. 52(2): p. 79-83.
[51] Soares, C., Gas Turbines: A Handbook of Air, Land and Sea Applications. 2007, Amsterdam: Butterworth-Heinemann.
[52] Commission, E.E., Eurostat (historical data), Primes Energy Model, (European Commission 2006) for projections, in EN19 Efficiency of conventional thermal electricity production. 2006.
[53] IEA (2003) small hydro data from international association for small hydro.
[54] Pacey, P., The Culture of Technology. 1983: Basil Blackwell.
[55] Sondreal, E.A., M.L. Jones, and G.H. Groenewold, Tides and Trends in the World's Electric Power Industry. The Electricity Journal, 2001. 14(1): p. 61-79.
[56] DETR Department of the Environment Transport regions, Energy savings in industrial water pumping systems. Good practice guide 249. 1998, Oxfordshire, England.
[57] Lovins, A.B., L.H. Lovins, and P. Hawken, A Road Map for Natural Capitalism. Harvard business review, 1999.
[58] Norton, M., Science and Engineering and Society, in Environmental Impacts and Global responses. 2004, Tokyo Institute of technology.
[59] Mott, R.L., Applied Fluid Mechanics. 6th ed. 2006, Jurong, Singapore: Pearson Publication, Inc.
[60] Cengel, Y.A. and M.A. Boles, Thermodynamics An Engineering Approach. 5th ed ed. 2006, New York: McGraw-Hill.
[61] Shiels, S., Locating the greatest centrifugal pump energy savings. Centrifugal Pump Academy, 1998. 1998(384): p. 56-59.
[62] Buffler, C.R., Microwave Cooking And Processing: Engineering Fundamentals For The Food Scientist. 1992, New York: Van Nostrand Reinhold.
[63] Tetsuji, O., Microwave Oven Evaluation Standard Subcommittee Energy Efficiency Standards Subcommittee of the Advisory Committee for Natural Resources and Energy, in Japan's "Top Runner" Standard. 2005.
[64] Ehrlich, P.R. and J.P. Holdren Impact of Population Growth. Science, 1971. 171 p. 1212-17.
[65] Holdren, J.P. and P.R. Ehrlich, Human population and the global environment. American Scientist 1974. 62(3): p. 282-292.
[66] Schulze, P.C., I=PAT. Ecological Economics, 2002. 40: p. 149-150.
[67] Jacob, M., Sustainable Development: A Reconstructive Critique of the United Nations Debate. 1996, Dept of Theory of Science and Research: Göteborg, Sweden.
[68] Daily, G.C. and P.R. Ehrlich, Population, sustainability, and earth's carrying capacity. Bioscience, 1992. 42(10): p. 761-771.
[69] Dietz, T. and E.A. Rosa Rethinking the environmental impacts of Population, Affluence and Technology. Human Ecology Review, 1994. Summer/Autumn, 1.
[70] Fuchs, D.A. and S. Lorek, An inquiry into the impact of globalization on the potential for ÔÇÿsustainable consumption- in households, in Workshop on Sustainable Household Consumption: Impacts, Goals and Indicators for Energy-use, Transport and Food. 2000, ProSus/CSTM: Enschede, Norway.
[71] Van der Wal, J. and K.J. Noorman, Analysis of Household Metabolic Flows. In Green Households? Domestic Consumers, Environment, and Sustainability, K.J.N.a.T.S. Uiterkamp, Editor. 1998, Earthscan: London.
[72] D├╝rrenberger, G. and P. Nikola, Energy Metabolism of Swiss Households, in the Second International Symposium on Sustainable Household Consumption. 1999: Groningen-Paterswolde.
[73] Ferguson, R., et al., Benefits of electricity generation. Engineering Science and Education Journal, 1997.
[74] Burkett, P., the Value Problem in Ecological Economics: Lessons from the Physiocrats and Marx. Organization Environment, 2003. 16: p. 137- 167.
[75] Detchon, R., Over a Barrel? Myths and Facts about U.S. Dependence on Foreign Oil. 2004: The Century Foundation, Inc.
[76] EIA, E.I.A., Annual Oil Market Chronology, in U.S. Department of Energy. 2008.
[77] Factbook, O., Economic, Environmental and Social Statistics Energy - Energy production and prices. Oil prices OECD, 2007.
[78] Flavin, C. and A.B. Durning, Building on success, The age of energy efficiency. The Worldwatch Institute. 1988, Washington, DC.
[79] Hawken, P., A. Lovins, and L.H. Lovins, Natural Capitalism: Creating the Next Industrial Revolution. 1999, London: Earthscan.
[80] Alexander, C., Notes on the Synthesis of Form. Harvard University Press. 1964, Cambridge, Massachusetts.