RT Journal Article T1 Performance assessment and modeling of an SWRO pilot plant with an energy recovery device under variable operating conditions A1 Ruiz GarcĂ­a, A. A1 Nuez, I. A1 Khayet Souhaimi, Mohamed AB Reverse osmosis (RO) is one of the most widespread desalination technologies in use today due to its good performance and reliability. Given that it is an energy intensive technology, using variable renewable energy sources (VRES) to power RO systems is an interesting option. Work with the RO system under variable operating conditions is one of the strategies that can be employed to take advantage of all the energy that is available at any given time from an off-grid renewable system. However, this will entail additional challenges in terms of, among other factors, plant maintenance and permeate production rate and quality. In grid-connected seawater RO (SWRO) desalination plants, energy recovery devices (ERD) are commonly used to increase energy efficiency performance. In these cases, the ERD usually operates under constant operating conditions. This work aims to assess the performance of an SWRO system with an ERD under widely variable operating conditions. The SWRO system has six membrane elements in pressure vessels. The ERD is a Pelton turbine connected to a generator to measure the energy produced by the turbine. An artificial neural network (ANN) based model was developed to estimate the performance of the SWRO-ERD system under variable operating conditions. According to the results, power savings of between 2.9 and 6.08 kW can be achieved for a wide range of operating conditions, allowing an increase in the produced permeate flux (Qp). The proposed ANN-based model is able to estimate Qp and permeate electrical conductivity with error intervals of 1.56 x 10-6 -8.49 x 10-2 m3 h-1 and 8.33 x 10-5 -31.06 mu S cm-1, respectively. The experimental data and the developed model could help to obtain a better performance pre-diction of VRES-powered SWRO systems that are operating under variable operating conditions and with ERDs. PB Elsevier Science Bv SN 0011-9164 YR 2023 FD 2023-06-01 LK https://hdl.handle.net/20.500.14352/72326 UL https://hdl.handle.net/20.500.14352/72326 LA eng NO This research was co-funded by the ERDF and the ACLIEMAC Project (MAC2/3.5b/380) of the INTERREG V-A MAC 2014-2020 program. NO European Regional Development Fund (ERDF) NO ACLIEMAC Project of the INTERREG V-A MAC 2014-2020 program DS Docta Complutense RD 6 abr 2025