Sustainable engineering

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Sustainable urban design and innovation: Photovoltaic ombrière SUDI is an autonomous and mobile station that replenishes energy for electric vehicles using solar energy.

Sustainable engineering is the process of designing or operating systems such that they use energy and resources sustainably, i.e., at a rate that does not compromise the natural environment, or the ability of future generations to meet their own needs.

What engineers can do

  • Water supply
  • Food production
  • Housing and shelter
  • Sanitation and waste management
  • Energy development
  • Transportation
  • Industrial processing
  • Development of natural resources
  • Cleaning up polluted waste sites
  • Sitting and planning projects to reduce environmental and social impacts
  • Restoring natural environments such as forests, lakes, streams, and wetlands
  • Improving industrial processes to eliminate waste and reduce consumption
  • Recommending the appropriate and innovative use of technology 1

Sustainable Engineering as an Aspect of Engineering Disciplines

Every engineering descipline is engaged in sustainable design, employing numerous initiatives, especially life cycle analysis (LCA), pollution prevention, design for the environment (DfE), design for disassembly (DfD), and design for recycling (DfR). These are replacing or at least changing pollution control paradigms. For example, concept of a “cap and trade” has been tested and works well for some pollutants. This is a system where companies are allowed to place a “bubble” over a whole manufacturing complex or trade pollution credits with other companies in their industry instead of a “stack-by-stack” and “pipe-by-pipe” approach, i.e. the so-called “command and control” approach. Such policy and regulatory innovations call for some improved technology based approaches as well as better quality-based approaches, such as leveling out the pollutant loadings and using less expensive technologies to remove the first large bulk of pollutants, followed by higher operation and maintenance (O&M) technologies for the more difficult to treat stacks and pipes. But, the net effect can be a greater reduction of pollutant emissions and effluents than treating each stack or pipe as an independent entity. This is a foundation for most sustainable design approaches, i.e. conducting a life-cycle analysis, prioritizing the most important problems, and matching the technologies and operations to address them. The problems will vary by size (e.g. pollutant loading), difficulty in treating, and feasibility. The most intractable problems are often those that are small but very expensive and difficult to treat, i.e. less feasible. Of course, as with all paradigm shifts, expectations must be managed from both a technical and an operational perspective.2 Historically, sustainability considerations have been approached by engineers as constraints on their designs. For example, hazardous substances generated by a manufacturing process were dealt with as a waste stream that must be contained and treated. The hazardous waste production had to be constrained by selecting certain manufacturing types, increasing waste handling facilities, and if these did not entirely do the job, limiting rates of production. Green engineering recognizes that these processes are often inefficient economically and environmentally, calling for a comprehensive, systematic life cycle approach. Green engineering attempts to achieve four goals:3

1. Waste reduction; 2. Materials management; 3. Pollution prevention; and, 4. Product enhancement.

Green engineering encompasses numerous ways to improve processes and products to make them more efficient from an environmental standpoint. Every one of these approaches depends on viewing possible impacts in space and time. Engineering and architecture have always been concerned with space. Architects consider the sense of place. Engineers view the site map as a set of fluxes across the boundary. The design must consider short and long-term impacts. Those impacts beyond the near-term are the province of sustainable design. The effects may not manifest themselves for decades. In the mid-twentieth century, designers specified the use of what are now known to be hazardous building materials, such as asbestos flooring, pipe wrap and shingles, lead paint and pipes, and even structural and mechanical systems that may have increased the exposure to molds and radon. Those decisions have led to risks to people inhabiting these buildings. It is easy in retrospect to criticize these decisions, but many were made for noble reasons, such as fire prevention and durability of materials. However, it does illustrate that seemingly small impacts when view through the prism of time can be amplified exponentially in their effects. Sustainable design requires a complete assessment of a design in place and time. Some impacts may not occur until centuries in the future. For example, the extent to which we decide to use nuclear power to generate electricity is a sustainable design decision. The radioactive wastes may have half-lives of hundreds of thousands of years. That is, it will take all these years for half of the radioactive isotopes to decay. Radioactive decay is the spontaneous transformation of one element into another. This occurs by irreversibly changing the number of protons in the nucleus. Thus, sustainable designs of such enterprises must consider highly uncertain futures. For example, even if we properly place warning signs about these hazardous wastes, we do not know if the English language will be understood. All four goals of green engineering mentioned above are supported by a long-term, life cycle point of view. A life cycle analysis is a holistic approach to consider the entirety of a product, process or activity, encompassing raw materials, manufacturing, transportation, distribution, use, maintenance, recycling, and final disposal. In other words, assessing its life cycle should yield a complete picture of the product. The first step in a life cycle assessment is to gather data on the flow of a material through an identifiable society. Once the quantities of various components of such a flow are known, the important functions and impacts of each step in the production, manufacture, use, and recovery/disposal are estimated. Thus, in sustainable design, engineers must optimize for variables that give the best performance in temporal frames.4

Accomplishments from 1992 to 2002

  • The World Engineering Partnership for Sustainable Development (WEPSD) was formed and they are responsible for the following areas: redesign engineering responsibilities and ethic to sustainable development, analyze and develop a long term plan, find solution by exchanging information with partners and using new technologies, and solve the critical global environment problems, such as fresh water and climate change
  • Developed environmental policies, codes of ethics, and sustainable development guidelines
  • Earth Charter was restarted as a civil society initiative
  • The World Bank, United Nations Environmental Program, and the Global Environment Facility joined programs for sustainable development
  • Launched programs for engineering students and practicing engineers on how to apply sustainable development concepts in their work
  • Developed new approaches in industrial processes

Future goals

  • Creating a comprehensive program to identify and provide the information that engineers in developing countries require to meet energy, water, food, health, and other basic human needs
  • Give education for student and practicing engineers to make them realize the importance of sustainability and become environment generalists
  • Engaged in decision-making processes and performing projects
  • Develop better approaches with the consideration of a project’s environmental costs, impacts, and conditions throughout a project’s life cycle
  • Improve the education on sustainability and provide help in developing countries

See also

References

  1. ^ Huesemann, Michael H., and Joyce A. Huesemann (2011). Technofix: Why Technology Won’t Save Us or the Environment, Chapter 13, “The Design of Environmentally Sustainable and Appropriate Technologies”, New Society Publishers, Gabriola Island, British Columbia, Canada, ISBN 0865717044, 464 pp.
  2. ^ D. Vallero and C. Brasier (2008), Sustainable Design: The Science of Sustainability and Green Engineering. John Wiley and Sons, Inc., Hoboken, NJ, ISBN 0470130628.|url=http://books.google.com/books/about/Sustainable_Design.html?id=vrj5DIQ-7m8C%7C
  3. ^ D. Vallero and C. Brasier (2008), Sustainable Design: The Science of Sustainability and Green Engineering. John Wiley and Sons, Inc., Hoboken, NJ, ISBN 0470130628.
  4. ^ D. Vallero and C. Brasier (2008), Sustainable Design: The Science of Sustainability and Green Engineering. John Wiley and Sons, Inc., Hoboken, NJ, ISBN 0470130628.







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