Evaluation of minimum residual pressure as design criterion for South African water distribution systems
Department of Civil Engineering, University of Stellenbosch, Private Bag X1, Matieland, 7602, South Africa; GLS Consulting (Pty) Ltd, Stellenbosch, South Africa
The South African civil engineering fraternity has grown to accept 24 m as the design criterion for minimum residual pressure in water distribution systems. However, the theoretical peak demand in many systems has increased beyond the point where minimum residual pressure exceeds 24 m - at least according to hydraulic models. Additions of customers to existing supply systems have led to increased peak fows with time, often without infrastructure upgrades to internal reticulation. Increased fows imply reduced pressures. This is not necessarily a concern: peak fow conditions rarely occur in a supply system and also, customer complaints often act as a frst sign of 'low pressures'. No complaints imply 'no low pressures'. The researchers analysed hydraulic models for 14 different towns in 5 municipal areas of South Africa, including 2 large metros, to identify the minimum residual pressures currently expected. The results include almost 55 000 model nodes and show that about 20% of the nodes in the distribution systems analysed have pressures of below 24 m, while pressures of below 14 m are not uncommon. Whether this relatively common occurrence of low pressures under modelled peak demand is found in practice is not known at this stage. A new guideline for minimum residual pressure based on previous criteria and results from this study is presented, noting that a physical lower limit of about 10 m water pressure is specifed in home appliance specifcations.
Customer complaints; Design criterion; Design standard; Distribution systems; Home appliances; Low pressures; Lower limits; Peak demand; Peak fow; Reduced pressure; Residual pressure; Residual pressures; South Africa; Supply system; Water pressures; Civil engineering; Design; Domestic appliances; Hydraulic models; Hydraulic structures; Local area networks; Water supply; Water distribution systems; civil engineering; design; distribution system; hydrological modeling; infrastructure; peak flow; pressure; water supply; Africa; South Africa; Southern Africa; Sub-Saharan Africa