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Simple conceptual water quality models
Woldegioris, B.T.; Van Grinensven, A.; Pereira, F.; Bauwens, W. (2015). Simple conceptual water quality models, in: E-proceedings of the 36th IAHR World Congress 28 June – 3 July, 2015, The Hague, the Netherlands. pp. [1-11]
In: (2015). E-proceedings of the 36th IAHR World Congress 28 June – 3 July, 2015, The Hague, the Netherlands. IAHR: [s.l.]. , more

Available in  Authors 
Document type: Conference paper

Keywords
    Modelling
    Water quality
Author keywords
    Analytical solution; Qual2e; Conceptual modelling

Authors  Top 
  • Woldegioris, B.T.
  • Van Grinensven, A.
  • Pereira, F., more
  • Bauwens, W., more

Abstract
    The riverine system plays vital role in the ecological functioning. Efficient and reliable method of planning and managing the ever increasing water quality problems is a key to maintaining a healthy aquatic environment and computer modelling plays a vital role in this regard. Most river water quality models have large simulation times because they are based on hydrodynamic simulators. This limits their applicability for operational purposes as well as management purposes and simulations involving long-term statistical information. For instance, imperfect nature of data monitoring and the approximate conceptualization of the reality are often causes for suspicion in model predictive capacity and hence, uncertainty analysis is required. Therefore, fast and accurate models are crucially complementary to the detailed models in operational, management and planning activities. Traditional QUAL2E model is widely in use for river water quality modelling and it can be considered as an approach with less parameters than detailed models while taking the pollutant interactions into account.

    This paper presents quasi-analytical solutions of river water quality modelling approach that integrates QUAL2E pollutant transformation ODEs in to dynamic CSTR method as an improvement over the numerical solution approaches used in conceptual water quality models. We compared it with the Euler method implemented in the widely applied SWAT model and explicit as well as implicit fourth order Rung-Kuta methods implemented in conceptual water quality models such as QUASAR and QUESTOR. The improvement mainly aimed at increasing model accuracy and solution stability with special emphasis for simulations during the low flow periods. We evaluated the behaviors of results from the Euler numerical solutions and the Runge Kuta4 numerical integration methods. It turned out that the numerical methods show serious instability for large residence times because of overestimations of decay processes. To overcome the instability we derived, based on simplifying assumptions, quasi-analytical solutions of inhomogeneous first order differential equations resulting from integration of the QUAL2E transformation formulations in to the CSTR-based mass balance equations. Finally, we tested the stability of the quasi-analytical method for real simulations and hypothetical extreme low flow scenarios. The new quasi-analytical solution gives unconditionally stable solution even when advanced implicit fourth order Rung-Kuta schemes give unstable results. It also gives fairly comparable results with the reference RWQM while running 130,000 times faster than it. Water quality processes are so critical during the low flow periods that it is fair to conclude that this approach is preferable to the numerical solutions of solute transformation ODEs. Besides the riverine system, this approach is well suited for water quality modelling in conveyance systems associated with large residence times like navigation canals. Furthermore, we demonstrated that the dynamic quasi-analytical CSTR solution of non-conservative pollutant modelling is analogous to the classical steady linear reservoir approach with variable and residence-time-dependent reservoir constant.

    In the context of decision support system, we believe that the implementation of this approach combined with conceptual water quantity modelling methods makes it vitally complementary to detailed models for management and operation of water quality problems demanding fast and fairly accurate results.


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