Air pressure in building drainage systems
Based on extensive site and laboratory investigations, the academics have undertaken a fundamental re-assessment of the mechanisms determining air pressure transient propagation within building drainage vent systems leading to comprehensive system simulations.
Propagation of positive transients within building drainage networks has been a source of concern for decades, and the group were responsible for the invention and development of a Positive Air Pressure Attenuator in conjunction with Studor Ltd. This device acts to absorb positive air pressure transients between their source and any branch connections where trap seals may be lost as a result of positive air pressure.
In addition, the team is responsible, through EPSRC and industry funding, for the first non-invasive, non-destructive, remote access monitoring system to detect depleted trap seals in complex buildings. This product is now ready for market through the University’s successful partnership with Studor Ltd.
Water conservation, and in particular reduced WC flush volume operation, requires modifications to the design of drainage networks. Application of increased flow rates to ensure drain clearance will no longer be an option. Through collaboration with international industry solutions aimed at water conservation and economy of design and installation have been developed.
Studies of low water use solid transport in 'real' building drainage installations led to a comprehensive multi-storey building drainage simulation, DRAINET. This simulation enables designers to predict the flow and associated solid transport performance of any network in response to the discharge of any appliance characterised by its flow-time discharge profile.
Through this work, the researchers have contributed to legislation that has the potential to cut water consumption in commercial and domestic premises by up to 25%.
Rainwater drainage systems
The numerical modelling techniques developed at Heriot-Watt also apply to conventional (gravity) and siphonic rainwater drainage systems.
Siphonic rainwater systems, an innovative and leading edge solution to large building roof drainage, are susceptible to design errors leading to a failure to prime. The team has developed simulations to define the conditions for system priming and dynamic network balancing.
With climate change now an overriding concern for the UK, this work has been extended, through both consortium and individual EPSRC funded projects, to encompass a focus on realising the potential benefits to property drainage design and adaptation as facilitated by the use of probabilistic-based UKCP09 data. The identification of failure locations and the extent of any flooding allows the development of decision-making tools to facilitate cost-effective design and adaptation of systems with the overall aim of mitigating flood risk. Modelling is supported by site monitoring in key locations in Edinburgh, Glasgow and London.
Staff contributing to this research area include:
We welcome applications from suitably qualified candidates. Please visit our How to apply page.