Fault Detection and Isolation in a Spiral-Wound Reverse Osmosis (RO) Desalination Plant

Pascual, Xavier; Gu, Hanyang; Bartman, Alex R.; Zhu, Aihua; Rahardianto, Anditya; Giralt, Jaume; Ralló, Robert; Christofides, Panagiotis D.; Cohen, Yoram

doi:10.1021/ie403603x

Cited by 5 publications

(4 citation statements)

References 42 publications

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“…In recent years there have also been mounting efforts to develop effective methods of plant fault detection and isolation so as to avoid plant failures and reduce maintenance costs. Effective self‐adaptive RO feed pretreatment that can handle temporal variability of raw feed water quality and production demand is also likely to lead to significant reduction in the use of feed treatment chemicals while reducing the frequency of membrane cleaning and replacement.…”

Section: The Path To Improving Ro Desalinationmentioning

confidence: 99%

A perspective on reverse osmosis water desalination: Quest for sustainability

2017

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Section: The Path To Improving Ro Desalinationmentioning

confidence: 99%

A perspective on reverse osmosis water desalination: Quest for sustainability

2017

Self Cite

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“…The two basic seawater desalination techniques are distillation and membrane separation. To handle the increasing need for freshwater, MSF (Multi-Stage Flash Distillation), MEE (Multi-Effect Evaporation) distillation, VC (Vapour Compression), and RO (Reverse Osmosis) are all the various technologies involved in desalination (Pascual, X, et al 2014). Figure 1 depicts the basic outlook of the desalination process.…”

Section: Introductionmentioning

confidence: 99%

Water Desalination Plant Fault Detection using Artificial Neural Network

2022

Global NEST: The International Journal

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<p>Water famine is very cruel. The desalination plant was brought in to alleviate the water shortage. A desalination plant has been set up in many places around the world. In the view of expanding worldwide need of fresh water, the usage of desalination plant becomes more common. There are more than twenty-five thousand desalination plants around the world. Many industries require treated water for production, water treatment, and other functions. Water quality is occasionally insufficient or does not satisfy the quality criteria for manufacturing causes. So, the enterprises utilize desalination systems to purify water for their own usage. It makes the water safe to drink as well as suitable for a variety of industrial applications. The fault occurring in the desalination plant, it slows down the processing the speed and reduce the output rate. In this study, focuses on the faults like not under system control, electrical fault, pump fault, control valve fault, inaccurate signal, old data fault, derived fault and transmitter fault. The proposed artificial neural network with the single and double component fault (ANN S-DCF) is introduced to detect the faults occurring in the desalination plant. The faults are splitted into two catagories and characteristics of each fault are trained in the artificial neural network. The result of this work achieves the best accuracy comparing to the existing techniques of SVR (support vector regression), PCA (principal component analysis) and DPLS (dynamic partial least square) method. This study achieves the accuracy rate of 96%, precision rate of 93% and sensitivity rate of 95% respectively with low complexity and high operational speed.</p>

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“…Seawater desalination is an important method to solve this problem. The installed capacity of seawater reverse osmosis (RO) facilities is increasing in recent years, covering industrial process water and potable water productions. − …”

Section: Introductionmentioning

confidence: 99%

Simultaneous Optimization of Size and Operation for Seawater Reverse Osmosis Network with Permeate Split and Interstage Permeate Split Designs

Sun

et al. 2021

Ind. Eng. Chem. Res.

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Simultaneous optimization of size and operation for the seawater reverse osmosis (RO) system is proposed through a superstructurebased mixed-integer differential-algebraic programming approach. The influences of operating conditions on the performance of pumps, RO membrane, and the properties of seawater are considered. The permeate split (PS) design, interstage permeate split (ISPS) design, and on−off model could give more operability and cost saving. For constant feed conditions, nearly constant profiles of control variables are obtained with a larger water tank. The maximum level in a water tank is an indicator to measure its buffer capacity. For the variation of temperature and time-of-use electricity price, although energy consumption can be effectively saved by one time shut off at a large water demand time period with high electricity price, not much water cost is reduced due to the increase of the plant size. Low load operation is an alternative solution. The ISPS design could balance the flux distributions inside the pressure vessel and extract more permeates with high quality; thus, the water cost and energy consumption could be reduced, compared with the interstage design (ISD) and the PS design. The uncertainties of the maximum concentration of product water and the membrane fouling factor are considered in a twostage stochastic program. It is useful for identifying a robust optimal design and operation solutions for membrane-based seawater desalination.

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Fault Detection and Isolation in a Spiral-Wound Reverse Osmosis (RO) Desalination Plant

Cited by 5 publications

References 42 publications

A perspective on reverse osmosis water desalination: Quest for sustainability

A perspective on reverse osmosis water desalination: Quest for sustainability

Water Desalination Plant Fault Detection using Artificial Neural Network

Simultaneous Optimization of Size and Operation for Seawater Reverse Osmosis Network with Permeate Split and Interstage Permeate Split Designs

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