Simulation of temperature influence on flow pattern and residence time in a detention tank
Journal article, 2006

Three-dimensional simulations were used to model how a temperature difference between the incoming water and tank water influences the flow pattern and residence time in a detention tank. Buoyant, neutrally buoyant and negatively buoyant incoming jets were simulated. The simulations were compared with measurements for neutrally buoyant jets in a large-scale model of a detention tank (13 × 9×1 m). The results show that a negatively buoyant jet gives slightly less effective volume, defined as the time when 50% of added tracer has passed the outlet divided by the nominal residence time, than a neutrally buoyant jet. The flow pattern for a negatively buoyant jet at low densimetric Froude numbers consists of a current that travels along the bottom towards the outlet and a counter current at the surface towards the inlet, while the neutrally buoyant jet excites a surface jet with two large eddies on each side of the jet. This implies that the short-circuiting will decrease when a negatively buoyant jet at low densimetric Froude number occurs in the tank. The difference between the flow pattern excited by a buoyant jet and a neutrally buoyant jet is small.

residence time

Computational fluid dynamics

negatively buoyant jet

storm water

detention tank

temperature

Author

Åsa Adamsson

Chalmers, Civil and Environmental Engineering, Water Environment Technology

Lars Bergdahl

Chalmers, Civil and Environmental Engineering, Water Environment Technology

Nordic Hydrology

0029-1277 (ISSN)

Vol. 37 1 53-68

Subject Categories

Water Engineering

DOI

10.2166/nh.2005.030

More information

Created

10/7/2017