TY - GEN
T1 - Developing hydraulic and water quality equivalent systems
AU - Raczynski, A.
AU - Kirkpatrick, W.
AU - Rehnstrom, D.
AU - Boulos, P.
AU - Lansey, K.
PY - 2009
Y1 - 2009
N2 - Water distribution system modelers organize system models by balancing model complexity and the effort to set up, solve and calibrate the model. The modeling goal is to represent the true system in the field with the least effort and calibration data. As a model increases in complexity as measured by the number of nodes and pipes, more field data is needed to estimate model parameters and the error associated with that model error increases. On the other hand, a simplified model may not capture the full system under all conditions. In terms of water quality, prevailing thought is that an "all-pipe" model is necessary. Here we examine the use of hydraulic equivalent systems on water quality estimates as represented by water age. A simple system is used to demonstrate the effect of applying existing series and parallel pipe simplification approaches. Although these methods preserve pressure conditions, water age is not and increasing levels of system reduction results in larger errors. We then demonstrate that a two step process can insure hydraulic and water quality equivalence for the full range of flows. This study demonstrates that a model skeletonized based on hydraulics to remove or reduce pipes must be re-calibrated for water quality at each level of model simplification.
AB - Water distribution system modelers organize system models by balancing model complexity and the effort to set up, solve and calibrate the model. The modeling goal is to represent the true system in the field with the least effort and calibration data. As a model increases in complexity as measured by the number of nodes and pipes, more field data is needed to estimate model parameters and the error associated with that model error increases. On the other hand, a simplified model may not capture the full system under all conditions. In terms of water quality, prevailing thought is that an "all-pipe" model is necessary. Here we examine the use of hydraulic equivalent systems on water quality estimates as represented by water age. A simple system is used to demonstrate the effect of applying existing series and parallel pipe simplification approaches. Although these methods preserve pressure conditions, water age is not and increasing levels of system reduction results in larger errors. We then demonstrate that a two step process can insure hydraulic and water quality equivalence for the full range of flows. This study demonstrates that a model skeletonized based on hydraulics to remove or reduce pipes must be re-calibrated for water quality at each level of model simplification.
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U2 - 10.1061/41024(340)73
DO - 10.1061/41024(340)73
M3 - Conference contribution
AN - SCOPUS:69949104713
SN - 9780784410240
T3 - Proceedings of the 10th Annual Water Distribution Systems Analysis Conference, WDSA 2008
SP - 844
EP - 851
BT - Proceedings of the 10th Annual Water Distribution Systems Analysis Conference, WDSA 2008
T2 - 10th Annual Water Distribution Systems Analysis Conference, WDSA 2008
Y2 - 17 August 2008 through 20 August 2008
ER -