Abstract
This paper proposes an iterative mathematical optimization framework to solve the layout and hydraulic design problems of sewer networks. The layout selection model determines the flow rate and direction per pipe using mixed-integer programming, which results in a tree-like structured network. This network layout parametrizes a second model that determines hydraulic features including the diameter and the upstream and downstream invert elevations of pipes using a shortest path algorithm. These models are embedded in an iterative scheme that refines a cost function approximation for the first model upon learning the actual design cost from the second model. The framework was successfully tested on two sewer network benchmarks from the literature and a real sewer network located in Bogotá, Colombia, that is proposed as a new instance. For both benchmarks, the proposed methodology found a better solution with up to 42% cost reduction compared to the best methodologies reported in the literature. These are near-optimal solutions with respect to construction cost that satisfy all hydraulic and pipe connectivity constraints of a sewer system.
Highlights
A sewer network is an infrastructure that fundamentally comprises pipes and manholes, and is characterized by a network layout and a hydraulic design
Column 1 describes the statistics of interest; column 2 shows the results reported in Moeini and Afshar [31], column 3 shows the results when we only apply the hydraulic design (HD) component of our algorithm on the layout reported by Moeini and Afshar [31]; and column 4 shows the results of our algorithm
The layout selection (LS) is modelled as an mixed-integer programming (MIP) and is solved exactly with an off-the-shelf optimization solver
Summary
A sewer network is an infrastructure that fundamentally comprises pipes and manholes, and is characterized by a network layout and a hydraulic design. The sewer network design (SND) problem aims to obtain a minimum-cost design capable of transporting a specific flow rate for each pipe, while satisfying all hydraulic and operational constraints to comply with local regulations. Water 2020, 12, 3337 the SND problem includes inflows at each manhole (rain and/or wastewater), topographic information, available pipe materials and diameters, density and water viscosity, and hydraulic design constraints. The predominant approach to solve the problem considers the layout selection (LS) and hydraulic design (HD) as independent (and subsequent) problems. This separation allows for tractability of the problem at the price of design optimality
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