Effectiveness of seawater reverse osmosis (SWRO) pretreatment systems in removing transparent exopolymer particles (TEP) substances

Lee, Shang-Tse

05 1900

Transparent exopolymer particles (TEP) have been reported as one of the main factors of membrane fouling in seawater reverse osmosis (SWRO) process. Research has been focused on algal TEP so far, overlooking bacterial TEP. This thesis investigated the effects of coagulation on removal of bacterial TEP/TEP precursors in seawater and subsequent reduction on TEP fouling in ultrafiltration (UF), as a pretreatment of SWRO. Furthermore, the performance of pretreatment (coagulation + UF) has been investigated on a bench-scale SWRO system. TEP/TEP precursors were harvested from a strain of marine bacteria, Pseudoalteromonas atlantica, isolated from the Red Sea. Isolated bacterial organic matter (BOM), containing 1.5 mg xanthan gum eq./L TEP/TEP precursors, were dosed in Red Sea water to mimic a high TEP concentration event. Bacterial TEP/TEP precursors added to seawater were coagulated with ferric chloride and aluminum sulfate at different dosages and pH. Results showed that ferric chloride had a better removal efficiency on TEP/TEP precursors. Afterwards, the non-coagulated/coagulated seawater were tested on a UF system at a constant flux of 130 L/m2h, using two types of commercially available membranes, with pore sizes of 50 kDa and 100 kDa, respectively. The fouling potential of coagulated water was determined by the Modified Fouling Index (MFI-UF). Transmembrane pressure (TMP) was also continuously monitored to investigate the fouling development on UF membranes. TEP concentrations in samples were determined by the alcian blue staining assay. Liquid chromatography-organic carbon detection (LC-OCD) was used to determine the removal of TEP precursors with particular emphasis on biopolymers. Finally, SWRO tests showed that TEP/TEP precursors had a high fouling potential as indicated by MFI-UF, corresponding to the TMP measurements. Coagulation could substantially reduce TEP/TEP precursors fouling in UF when its dosage was equal or higher than 0.2 mg Fe/L. The flux decline experiments showed that coagulation + UF pretreated water had a smaller fouling potential than MF pretreated water. This thesis also provides useful and practical information on controlling bacterial TEP/TEP precursors fouling in UF and RO systems.

Biofouling

Coagulation

Ultrafiltration

Reverse Osmosis

Transparent Exopolymer Particles (TEP)

Desalination

Organic Carbon Reduction in Seawater Reverse Osmosis (SWRO) Plants, Jeddah, Saudi Arabia

Alshahri, Abdullah

12 1900

Desalination is considered to be a major source of usable water in the Middle East, especially the Gulf countries which lack fresh water resources. A key and sometimes the only solution to produce high quality water in these countries is through the use of seawater reverse osmosis (SWRO) desalination technology. Membrane fouling is an economic and operational defect that impacts the performance of SWRO desalination technology. To limit this fouling phenomenon, it is important to implement the appropriate type of intake and pre-treatment system design. In this study, two types of systems were investigated, a vertical well system and a surface-water intake at a 9m depth. The purpose of this investigation is to study the impact of the different intake systems and pre-treatment stages in minimizing the concentrations of algae, bacteria, natural organic matter (NOM) and transparent exopolymer particles (TEP), in the feed water prior to pre-treatment, through the pre-treatment stages, and in the product water and concentrate. Water samples were collected from the surface seawater, the intakes (wells for site A, 9 m depth open ocean intake at site B), after the media filter, after the cartridge filter, and from the permeate and reject streams. The measured parameters included physical parameters, algae, bacteria, total organic carbon (TOC), fractions of dissolved NOM, particulate and colloidal TEP. The results of this study prove that the natural filtration and biological treatment of the seawater which occur in the aquifer matrix are very effective in improving the raw water quality to a significant degree. The results demonstrated that algae and biopolymers were 100% removed, the bacterial concentrations were significantly removed and roughly 50% or greater of TOC concentrations was eliminated by the aquifer matrix at site A. The aquifer feeding the vertical wells reduced TEP concentrations, but to differing degree. There is a slight decrease in the concentrations of, algae, bacteria, TOC, NOM, and TEP in the feed water at 9 m depth compared to the surface seawater at site B. The pre-treatment was of significant effectiveness and the improvements in reducing the membrane fouling potential were quite high and strong at this site. Investigation of the permeate stream showed some breakthrough of bacteria which is of concern because it may indicate a problem within the membrane system (e.g., broken seal and perforation). The aquifer feeding the wells in the subsurface system plays a main role in the improvement of water quality, so the pre-treatment seems less effective in site A plant. This proves that the subsurface intake is better than open ocean intake in terms of providing better raw water quality and ultimately reducing membrane biofouling.

Seawater reverse osmosis (SWRO)

Subsurface intake

Open Ocean Intake

Pretreatment

Transparent Exopolymer Particles (TEP)

Les Particules d'Exopolymères Transparentes (Transparent Exopolymer Particles, TEP) en milieu pélagique lacustre : relation avec le phytoplancton et rôle dans les réseaux trophiques microbiens / Transparent Exopolymer Particles (TEP) in lake pelagic environment : relationship with phytoplankton and role in microbial food webs

Arnous, Mohamad Bashir

16 November 2010

Ce travail est une contribution à la connaissance de l’importance des particules de nature polysaccharidique, les TEP (Transparent Exopolymer Particles) ou particules d’Exopolymères Transparentes, en milieu pélagique lacustre.Les différentes études présentées dans ce mémoire se sont essentiellement focalisées sur la distribution de ces particules et leur relation avec le phytoplancton et les autres microorganismes du réseau trophique aquatique en milieu naturel (le lac Pavin, oligo-mésotrophe et le réservoir hypereutrophe de Grangent) et en conditions semi contrôlées(enclos limniques installés sur le lac de Créteil). Les résultats de l’étude printanière au lac Pavin indiquent que la majorité des TEP sont colonisées par les bactéries et que l’intensité de colonisation est fortement liée à la température et diminue avec l’augmentation en taille des particules. La distribution des nanoflagellés hétérotrophes (HNF) est fortement liée à la densité des TEP mais pas à l’intensité de colonisation de ces particules. L’abondance et la surface cumulée de TEP sont significativement plus élevées dans le lac oligo-mésotrophe que dans le réservoir hypereutrophe de Grangent. Les abondances et les concentrations élevées de particules dans le lac Pavin coïncident avec la présence de diatomées de grande taille au printemps et en automne et avec les chlorophycées à la fin de l’été.Dans le réservoir de Grangent les valeurs maximales de TEP coïncident avec le développement de la cyanobactérie Microcystis aeruginosa. Si les TEP augmentent avec la productivité de l’écosystème, la production de ces particules par unité de chlorophylle a dépend de la composition algale et tend à diminuer avec l’augmentation du niveau trophique du milieu. Les résultats issus de la biomanipulation en enclos limniques indiquent que la structure du réseau trophique aquatique (par la présence ou l’absence de poissons planctonophages) influence fortement la distribution,la dynamique et le spectre de taille des TEP. Dans le traitement poisson, l’abondance des TEP, la chlorophylle a et la biomasse des chlorophycées sont fortement corrélées. De par son broutage sur le phytoplancton, le zooplancton a un effet négatif sur les TEP dans le traitement sans poissons mais il contribue sans doute à la formation de TEP e tinfluence le spectre de taille de ces dernières dans ce traitement. Ce travail souligne l’importance des particules de nature polysaccharidique en milieu pélagique lacustre qui doivent être considérées comme une part importante du carbone organique qui transite des producteurs primaires vers les décomposeurs et vers le sédiment. / This work adds to the knowledge of the significance of polysaccharidic detrital particles or TEP (= Transparent Exopolymer Particles) in freshwater pelagic environments. Studies in this thesis have mainly focused on the distribution of TEP and their relationships with phytoplankton and other microorganisms in natural environments (the oligo-mesotrophic Lake Pavin and the hypereutrophic reservoir of Grangent) and in limnetic enclosures (lake of Créteil). The intensity of bacterial colonization during spring in Lake Pavin was strongly related to temperature and decreased with particle size. The abundance of heterotrophic nanoflagellates (HNF) in this lake was more significantly related to the density of the particles than to the density of total bacteria and the intensity of bacterial colonization of TEP, suggesting that TEP is a more important factor for HNF development than attached and free bacteria. The abundance and the total surface area of the particles were significantly higher in the hypereutrophic Lake Grangent than in the mesotrophic Lake Pavin. Maximum TEP density in Lake Pavin was recorded during the spring diatom bloom, while TEP concentration peaked in late summer when the phytoplankton community was largely dominated by small-size chlorophytes with an abundant polysaccharide cell coating. In the hypereutrophic Lake Grangent,maximum values of TEP appeared during the summer development of the cyanobacterium Microcystis aeruginosa. Per cell production of TEP, expressed by the ratio between TEP concentration and chlorophyll a concentration, was significantly higher in the less productive lake and the analysis of the size spectra of the particles indicated a greater proportion of small particles in this lake. TEP therefore appear as more significant for microbial development and aggregates formation in the less productive environment. Results from limnetic enclosures (either dominated by planktivorous fish or fishless) indicated that food-web structure strongly influences the distribution and size spectra of TEP. TEP abundances were related to chlorophyll a concentrations and the biomass of chlorophytes in the fish treatment. As expected by the trophic cascades theory, zooplankton had an indirect negative effect on TEP abundance. Our results suggest, however, that metazoan probably influence the formation and the size spectra of the particles in the fishless treatment. TEP must be regarded as a major part of the organic carbon which is transferred from the primary producers to the microbial food web and the sediments in freshwater ecosystems.

Phytoplancton

Bactérie

Nanoflagellés hétérotrophes (HNF)

Lac

Transparent exopolymer particles (TEP)

Phytoplankton

Bacteria

Heterotrophic nanoflagellates (HNF)

Lake