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Reverse Osmosis Purification

The ionic clusters observed are not limited to aqueous electrolyte solutions only. In fact very similar results were obtained for methanolic solutions as well [25]. This shows that sufficiently large and stable ionic clusters are a fairly common occurrence whenever ions are dissolved in polar solvents. The clusters are an essential factor in the facilitation of reverse osmosis purification. Since many industrially important solutions include ions in polar solvents, it is important to account for them in separation involving such solvents. [Pg.793]

D.T. Bray, Reverse Osmosis Purification Apparatus, US Patent 3,417,870 (December, 1968). [Pg.160]

First multi-leaf spiral wound membrane module developed by Don Bray and others at Gulf General Atomic, under US Patent no. 3,417,870, "Reverse Osmosis Purification Apparatus," December, 1968. A multi-leaf spiral configuration improves the flow characteristics of the RO module by minimizing the pressure drop encountered by permeate as it spirals into the central collection tube. [Pg.11]

A.V. Sharikova and D. K. Killinger, Laser-induced fluorescence studied of water processed by a reverse osmosis purification unit, Proc. ofSPlE 5994, 59940B-1-59940B-5 (2005). [Pg.67]

Fighting water scarcity also involves figuring out how to produce it from waste water, sea water and even clouds. Desahnation by reverse osmosis, purification by membrane filters, mist collectors in desert environments all of these methods involve the use of plastics, or even the creation of new products. The first fog sensor, 4 m high and 12 m wide, made of a hundred nets or polypropylene panels, was installed in the desert of Chile in 2010. The fine particles of water (0.05 to 0.5 g per m of fog) slide along the nets toward gutters which direct them into tanks. A completely passive process, using neither pumps nor electricity, it can collect 15,0001 of water per day, on average. [Pg.53]

In other areas, POD has been used to improve the wear resistance of a mbber latex binder by incorporation of 25% of Oksalon fibers. Heat-resistant laminate films, made by coating a polyester film with POD, have been used as electrical insulators and show good resistance to abrasion and are capable of 126% elongation. In some instances, thin sheets of PODs have been used as mold release agents. For this appHcation a resin is placed between the two sheets of POD, which is then pressed in a mold, and the sheets simply peel off from the object and mold after the resin has cured. POD-based membranes exhibit salt rejection properties and hence find potential as reverse osmosis membranes in the purification of seawater. PODs have also been used in the manufacturing of electrophotographic plates as binders between the toner and plate. These improved binders produce sharper images than were possible before. [Pg.535]

Makeup. Makeup treatment depends extensively on the source water. Some steam systems use municipal water as a source. These systems may require dechlorination followed by reverse osmosis (qv) and ion exchange. Other systems use weUwater. In hard water areas, these systems include softening before further purification. Surface waters may require removal of suspended soHds by sedimentation (qv), coagulation, flocculation, and filtration. Calcium may be reduced by precipitation softening or lime softening. Organic contaminants can be removed by absorption on activated carbon. Details of makeup water treatment may be found in many handbooks (22—24) as well as in technical Hterature from water treatment chemical suppHers. [Pg.363]

Cellulose acetate films, specially cast to have a dense surface and a porous substmcture, are used in reverse osmosis to purify brackish water (138—141) in hollow fibers for purification of blood (artificial kidney) (142), and for purifying fmit juices (143,144) (see Membrane technology). [Pg.259]

R/0 unit Reverse Osmosis Unit for water purification in small aquariums and miniature yard-ponds, utilizes a membrane under pressure to filter dissolved solids and pollutants from the water. Two different filter membranes can be used the CTA (cellulose triacetate) membrane is less expensive, but only works with chlorinated water and removes 50-70% of nitrates, and the TFC membrane, which is more expensive, removes 95% of nitrates, but is ruined by chlorine. R/0 wastes water and a system that cleans 100 gallons a day will cost ft-om 400 to 600 with membrane replacement adding to the cost. A unit that handles 140 gallons a day will cost above 700,00. [Pg.624]

Over the past three decades, there has been a growing industrial interest in using reverse osmosis for several objectives such as water purification and demineralization as well as environmental plications (e.g.. Comb, 1994 Rorech and Bond, 1993, El-Halwagi, 1992). The first step in designing the system is to understand the operating principles and modeling of RO modules. [Pg.264]

Rorech, G. J. and Bond, S. G. (1993). Reverse Osmosis A Cost Effective Versatile Water Purification Tool, I EC, pp. 35-37. [Pg.287]

Electro-osmosis has been defined in the literature in many indirect ways, but the simplest definition comes from the Oxford English Dictionary, which defines it as the effect of an external electric held on a system undergoing osmosis or reverse osmosis. Electro-osmosis is not a well-understood phenomenon, and this especially apphes to polar non-ionic solutions. Recent hterature and many standard text and reference books present a rather confused picture, and some imply directly or indirectly that it cannot take place in uniform electric fields [31-35]. This assumption is perhaps based on the fact that the interaction of an external electric held on a polar molecule can produce only a net torque, but no net force. This therefore appears to be an ideal problem for molecular simulation to address, and we will describe here how molecular simulation has helped to understand this phenomenon [26]. Electro-osmosis has many important applications in both the hfe and physical sciences, including processes as diverse as water desahnation, soil purification, and drug delivery. [Pg.786]

Reverse osmosis requires good pretreatment to prevent membrane fouling and loss of performance. Because it is seldom better than 60 to 70% efficient, there is a relatively high cost for pumping and discharging the additional supply water consumed. Nevertheless, it is good as a bulk water roughing process for purification. [Pg.344]

Reverse osmosis is at its best when employed to significantly reduce TDS in water. It is effective at all levels of TDS, although not to the same degree of efficiency. As such, it is often entirely suitable as a purification technology for boiler MU water. It is efficient at removing... [Pg.360]

Osmosis is the flow of solvent through a semipermeable membrane into a solution the osmotic pressure is proportional to the molar concentration of the solute. Osmometry is used to determine the molar masses of compounds with large molecules, such as polymers reverse osmosis is used in water purification. [Pg.459]

Additional water purification steps, such as reverse osmosis may be required (Section 8.17), depending on the source and condition of the water. [Pg.755]

Applications RO is primarily used for water purification seawater desalination (35,000 to 50,000 mg/L salt, 5.6 to 10.5 MPa operation), brackish water treatment (5000 to 10,000 mg/L, 1.4 to 4.2 MPa operation), and low-pressure RO (LPRO) (500 mg/L, 0.3 to 1.4 MPa operation). A list of U.S. plants can be found at www2.hawaii.edu, and a 26 Ggal/yr desalination plant is under construction in Ashkelon, Israel. Purified water product is recovered as permeate while the concentrated retentate is discarded as waste. Drinking water specifications of total dissolved solids (TDS) < 500 mg/L are published by the U.S. EPA and of < 1500 mg/L by the WHO [Williams et ak, chap. 24 in Membrane Handbook, Ho and Sirkar (eds.). Van Nostrand, New York, 1992]. Application of RO to drinking water is summarized in Eisenberg and Middlebrooks (Reverse Osmosis Treatment of Drinking Water, Butterworth, Boston, 1986). [Pg.45]

The third membrane process that has been used successfully in water purification is ultrafiltration. As with reverse osmosis, the driving force is pressure. However, in ultrafiltration the separation is merely based on the size of the molecules. Here the passage of molecules having molecular weights above 100 can be deterred. The pressure differences are usually between 20 and 50 psi (1.4-3.5 kg/cm2). [Pg.445]

Procedure Flavonoids are then further purified with 2 ml of methanolic HC1 (2 N), followed by centrifugation (2 min, 15 600 g), hydrolyzation of 150 il of suspension in an autoclave (15 min, 120 C). A reverse osmosis-Millipore UF Plus water purification system is used in high performance liquid chromatography (HPLC) with an autosampler. After injections of 5 pg of samples, the mobile phases flow at a rate of 1 ml/minute with isocratic elution in a column at 30 C. [Pg.213]

Furthermore, the environmental impact of PET production should be reduced by substituting the commonly used antimony-based catalyst for an antimony-free catalyst leg, for a titanium-based catalyst. The pollution by liquid effluents could be reduced by installing a reverse-osmosis unit on top of the glycol distillation unit for the purification of water from the esterification process. [Pg.104]

Purification and separation—solvent extraction, ion exchange, cementation, adsorption, liquid membranes, reverse osmosis, etc. [Pg.612]

Reverse osmosis as an alternative or substitute method for the purification 1-2 US5221485 Johnson/ 19... [Pg.116]

Deionized water often meets the pharmacopoeial criteria laid down for purified water . Sometimes, however, further purification may be necessary to attain this standard. This often entails a distillation or reverse-osmosis step. Deionized water will, however, not meet the pharmacopoeial requirements for WFI. WFI is best generated by distillation of deionized water. Distillation entails converting water to vapour by heat, followed by passing over a condenser, which results in condensation of pure water. Dissolved minerals and most organics are not volatile at 100°C. [Pg.107]

In summary, water can be a source of contaminants. If the raw material (drinking water) complies with the quahty parameters established by authorities, contaminants still present can be eliminated by usual water purification processes available to the pharmaceutical industry. While distillation and reverse osmosis provide water with the quality specifications for purified water and highly purified water, WFI is generally obtained by membrane filtration (associated with another purification process) not only because of chemical contamination but mainly because of sterility requirements. [Pg.463]


See other pages where Reverse Osmosis Purification is mentioned: [Pg.37]    [Pg.946]    [Pg.900]    [Pg.946]    [Pg.37]    [Pg.946]    [Pg.900]    [Pg.946]    [Pg.145]    [Pg.778]    [Pg.91]    [Pg.309]    [Pg.97]    [Pg.412]    [Pg.12]    [Pg.198]    [Pg.262]    [Pg.298]    [Pg.252]    [Pg.12]    [Pg.44]    [Pg.146]    [Pg.313]    [Pg.36]   


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