The themes of technological innovation, entrepreneurship, and organizing
SUSTAINABILITY ASSESSMENT METHODS APPLIED TO THE BUILT ENVIRONMENT
The built environment and urban systems are a complex interaction between human activity (economy), human well-being (social), and the natural systems (air, land, water) with each other and with the civil infrastructures and the interface at which they converge.
The built environment is a system that consists of all types of buildings such as houses, shops, together with engineering works such as roads, treatment plants, storm-water management systems, bridges, power generation facilities, and other civil infrastructures that support and enable human activity and urbanization. Water and wastewater treatment facilities and storm-water management systems are design to protect human lives, other civil infrastructures, and the environment by removing and or reducing contaminants.
Power generating facilities enable human activity, industrial processes, and transportation to be possible and also sustain society. Transportation systems including roads, bridges are the “veins” or “conduits” that provide accessibility to goods and services from the natural and built environment and maintain and/or improve human well-being. They also enable dynamic interaction of human activity (e. g., economic activity), human wellbeing, and the natural environment with each other and other infrastructure that makes up the built environment. These civil infrastructures are part of the considered human system.
Engineering projects that build these infrastructures are always hinged on a single reductionist assessment method, e. g. economic approach to evaluating the project across all life cycle stages (planning, design, to construction, to operation and maintenance and demolition/retrofitting). The piece of the puzzle that is often not connected in practice is that the built environment also encompasses socio-cultural activities and human interaction with the physical infrastructure and with the natural environment. Hence social and environmental assessment methods are also critical. Human activity influences behavior of the built environment components in unexpected ways. When these interactions are not considered the analysis remains incomplete. In order to assess the impacts of various projects, a holistic, systematic approach that considers the triple bottom line is essential for long-term and possible short-term planning.
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Table 1. Reductionist and systematic approaches to addressing sustainability (adaptedfrom Muga, 2009)
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We can evaluate the impacts of process, products, and activities in the built environment using a single-method approach, Table 1. Or alternatively, we can reduce the problem into smaller problems and evaluate them separately, then appropriately reconnect them within a systems context - a ‘sum of all the parts’ approach. Once we’ve reduced the problem to smaller problems we can then apply a systematic analysis to each of the specific problems or component. For example in the built environment, we can study buildings and we can
study pavements/roads separately then reconnect them to a systems context.
According to General Systems Theory, reductionist approaches are best applied in the study of sub-systems whereas the systems approach looks at whole systems (Checkland, 1993). Therefore the reductionist approach is used to attempt to solve problems within a system while the complex systems approach is used to thereafter to frame and define the issues (Checkland, 1993; Greenwood, 2006; Muga, 2009). The various reductionist approaches to addressing sustainability can be seen in Table 1. As an example, a company may focus on the economic aspect by reducing costs in order to achieve short-term gain often times at the detriment of environmental and social dimensions (i. e. a reductionist or subsystem approach). Strategies that are top-down and/or bottom-up approach have the potential to move a company or entity towards sustainability or away from it.
Applying reductionist approach to the built environment, the system can be divided into smaller parts that inherently are connected and support its overall function. Some of the critical components or parts of the built environment include buildings/structural support, transportation systems, services, gas and water lines, water reservoirs, information systems, etc. Once each ‘part’ is identified, a systematic approach to assessment, one that incorporates the triple bottom line (societal, economic, and environmental assessment) can then be applied to each part. Each of these ‘parts’ may be put together to gauge the overall sustainability of the system. With such a complex system as the built environment, a reductionist approach to identifying a problem along with the application of a systematic approach to assessment is often the best option. Such an option is also best suited when long-term strategies are concerned.
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Extraction of |
Manufacturing of |
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Virgin/Raw Materials |
Processing of virgin materials |
materials to |
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product |
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Manufacturing Stage |
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Product reaches its end of life and disposed by consumer |
Consumers or customers utilize the products |
Products are distributed to consumer |
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Extraction Stage |
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End-of-life Stage |
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Processing Stage |
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Use Stage |
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Distribution Stage |
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Figure 3. Life cycle stages involved in the manufacture of a product. Integrated assessment methods such as LCA and LCCA may be used at the planning and design stage to evaluate the impacts of alternative materials, processes, and end of life uses of a product before a project begins. These methods may also be used to evaluate the operation and maintenance stages when it is in progress. |
A systematic methods approach such as an integratedframework of life cycle assessment (LCA), life cycle cost analysis (LCCA), and indicators are necessary to evaluate these component-specific impacts from a sustainability perspective. Life cycle assessment (LCA), Economic-Input Output Model (EIO-LCA), and Simapro are tools that can be used to evaluate the environmental impacts of a given product, process, activity/service at various life stages (raw material extraction, manufacturing, distribution, use, and disposal, Figure 3). With LCA/EIO-LCA/Simapro we can determine the environmental outputs for, for example raw materials that are used to build a commercial property. We can also use these tools to evaluate the outputs from various energy sources used during the operation of the facility. LCA/EIO-LCA/ Simapro enables us to identify what stage of a product’s or process’ life significant environment
emissions occur and where improvements can be made. They are useful tools in aiding decisionmaking.
While the integrated assessment methods for sustainability enable us to compare alternatives processes, and technologies with the least negative impacts, they also enable us to identify, processes, technologies, and pathways where innovation can take place further reducing undesirable outcomes or increasing desirable outcomes. The life cycle stages, Figure 3, of various competing alternatives can be compared using LCA, LCCA or other assessment methods, to determine the alternative with the least environmental, economic and societal impacts. Innovation can also take place when performing an LCA or LCCA over the different life cycle stages. For example in Figure 3, in the extraction stage, an innovation might be what kind of equipments do we use and how do we carry out the extraction so that have minimal impacts. In the processing and manufacturing stages, an innovation might be re-designing a process so that less energy is consumed, or capturing heat for in-house energy use, or utilizing waste material that might otherwise be landfilled. In the use stage it might be, an innovation might be re-designing and manufacturing the products so that they have long-lives. In the end - of-life stage, an innovation might be to re-use of the product in another process, or recycle the product in order to make a completely different product, hence avoiding land-fill.
When it comes innovating and designing sustainably, it pays to think light. Products made with less material have less negative impact all the way from production to disposal, often making them cheaper to produce. It is clear how a light-weight truck can save energy as it takes less fuel to operate. But for any product that is made lighter it affects the entire LCA since it reduces costs from materials required to shipping of raw materials and final products. Thus this whole system thinking or systems approach to innovating sustainably has been captured by the Rock Mountain Institute in the following principles to be considered for sustainable integrative design, innovation and engineering:
Define the shared and aggressive goals
Collaborate across disciplines
Design nonlinearly
Reward desired outcomes
Define the end-use
Optimize over time and space
Establish baseline parametric values
Establish the minimum energy or resource
theoretically required, then identify and
minimize constraints to achieving that
minimum in practice
Start with a clean sheet
Use measures data and explicit analysis,
not assumptions and rules
Start downstream
Seek radical simplicity
Tunnel through the cost barrier
Wring multiple benefits from single
expenditures
Meet minimized peak demand; optimize over integrated demand Include feedback in the design
