Abstract
Responding to pressure on the natural and built environments from population growth, the need for safe and secure water to support resilient and liveable communities, and the need to adapt to increased climate risk and variability, many cities around the world have sought new ways to develop, manage and sustain their urban environments. Indeed, in recent years, three important and related concepts have emerged in relation to cities and urban development: first, the need to design cities so as to minimise the impact of climatic events on populations, infrastructure and the environment; second, the need to optimise human consumption of scarce natural resources, particularly land, water, energy and nutrients; and third, the need to protect and where possible conserve the natural environment in and between cities. Over time, these concepts have evolved into a variety of different concepts, approaches and ‘visions’ to guide future land use development. One such concept is ‘water sensitive urban design’ (WSUD), a term whose definition varies but which is nevertheless now readily accepted internationally as a core aspiration of urban development (Wong and Brown 2011).
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Notes
- 1.
For a comprehensive definition of WSUD and its relationship with integrated water cycle management, see Wong and Brown 2011.
- 2.
The best practice environmental management objectives for stormwater are referenced as a compliance measure in Clause 56.07-4 and these objectives are supported by industry compliance software. The objectives are published in the Victoria Government’s Urban Stormwater Best Practice Management Guidelines (Victorian Stormwater Committee, CSIRO Publishing, 1999) providing a consistent numerical compliance standard for all Victorian WSUD projects. The post-construction standard requires pollution reduction when compared to the typical urban load of 80% of Suspended solids, 45% of Total nitrogen, 45% of Total phosphorus, 70% of litter and discharges for the 1.5 ARI maintained at the pre-development level.
- 3.
VCAT is the Victorian Civil and Administrative Tribunal.
References
ARQ (Australian Rainfall Quality). (2004). Australian runoff quality: A guide to WSUD. Engineers Australia, National Committee for Water Engineering.
Brown, R. R. (2008). Social and institutional considerations. In T. D. Fletcher & A. Deletic (Eds.), Data requirements for integrated urban water management (pp. 159–169). London: Taylor & Francis.
Brown, R.R., Farrelly, M., & Keath, N. (2007). Summary report: Perceptions of institutional drivers and barriers to sustainable urban water management in Australia (Report No. 07/06). Melbourne: National Urban Water Governance Program, Monash University.
Burns, M. J., Fletcher, T. D., Walsh, C. J., Ladson, A. R., & Hatt, B. E. (2012). Hydrologic shortcomings of conventional urban stormwater management and opportunities for reform. Landscape and Urban Planning, 105, 230–240.
Clearwater. (2012). Building capacity with regional and rural councils – Water sensitive urban design. Presentation by Anna Jennings to Stormwater Victoria annual conference, Melbourne.
Hussey, K., Price, R., Pittock, J., Livingstone, J., Dovers, S., Fisher, D., & Hatfield Dodds, S. (2013). Statutory frameworks, institutions and policy processes for climate adaptation: Do Australia’s existing statutory frameworks, associated institutions and policy processes support or impede national adaptation planning and practice? (p. 193). Gold Coast: National Climate Change Adaptation Research Facility. Available at http://www.nccarf.edu.au/publications/statutory-frameworks-policy-processes.
JSCWSC. (2009). Evaluating options for WSUD – A national guide: Prepared by the Joint Steering Committee for Water Sensitive Cities: In delivering Clause 92(ii) of the National Water Initiative, Joint Steering Committee for Water Sensitive Cities, Canberra. Available at http://www.environment.gov.au/system/files/resources/1873905a-f5b7-4e3c-8f45-0259a32a94b1/files/wsud-guidelines.pdf. Accessed 21 Aug 2013.
National Water Initiative. (2004). Intergovernmental agreement on a national water initiative between the commonwealth of Australia and the governments of New South Wales, Victoria, Queensland, South Australia, the Australian Capital Territory and the Northern Territory, Council of Australian Governments.
NWC (National Water Commission). (2009). Evaluating options for water sensitive urban design – a national guide. Prepared by the joint steering committee for water sensitive cities in delivering clause 92(ii) of the National Water Initiative 2004. NWC, Canberra. Available here http://www.environment.gov.au/resource/evaluating-options-water-sensitive-urban-design-%E2%80%93-national-guide
NWC (National Water Commission). (2011). The National Water Initiative – Securing Australia’s water future: 2011 assessment. Canberra: NWC.
PMSEIC (Prime Ministers Science, Engineering and Innovation Council). (2007). Water for our cities: Building resilience in a climate of uncertainty. A report of the PMSEIC working group, June. Available at http://www.innovation.gov.au/science/PMSEIC/Documents/WaterforOurCities.pdf
Wong, T. H. F., & Brown, R. R. (2011). WSUD. In Q. Grafton & K. Hussey (Eds.), Water resources planning and management (pp. 483–504). New York: Cambridge University Press.
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Hussey, K., Kay, E. (2015). The Opportunities and Challenges of Implementing ‘Water Sensitive Urban Design’: Lessons from Stormwater Management in Victoria, Australia. In: Grafton, Q., Daniell, K., Nauges, C., Rinaudo, JD., Chan, N. (eds) Understanding and Managing Urban Water in Transition. Global Issues in Water Policy, vol 15. Springer, Dordrecht. https://doi.org/10.1007/978-94-017-9801-3_27
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