Relevant bibliographies by topics / Water – Purification – Iron removal

Academic literature on the topic 'Water – Purification – Iron removal'

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Published: 4 June 2021
Last updated: 6 February 2022

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Journal articles on the topic "Water – Purification – Iron removal"

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Litynska, Marta, Tetiana Dontsova, Olena Yanushevska, and Volodymyr Tarabaka. "Development of iron-containing sorption materials for water purification from arsenic compounds." Eastern-European Journal of Enterprise Technologies 2, no. 10 (110) (April 30, 2021): 35–42. http://dx.doi.org/10.15587/1729-4061.2021.230216.

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The paper is devoted to the development of a method for obtaining and using iron-containing sorption materials for the effective removal of arsenic compounds of different oxidation states from an aqueous medium. It is known that arsenic compounds have a harmful effect on biota due to high toxicity. The paper theoretically and experimentally substantiates the choice of iron-containing materials as the main sorbent material for arsenic compounds removal from the aqueous medium. A series of iron-containing adsorbents, including powder, activated carbon-based granular and suspension sorbents, was synthesized by different methods (heterogeneous and homogeneous precipitation). Experimental studies have confirmed that the adsorption of arsenate ions on iron-containing sorption materials corresponds to the pseudo-second order of the reaction (R2=0.999), which is inherent in adsorption processes. It was determined that oxyhydroxide sorption materials obtained by the homogeneous precipitation demonstrate higher sorption activity (up to 70 mg/g for As(III) and over 70 mg/g for As(V)). It was found that activated carbon-based iron-containing sorption materials showed approximately 2 times lower efficiency than powder iron(III) oxide, iron(III) oxyhydroxide and amorphous iron(III) hydroxide. It was shown that the use of microfiltration membranes is promising for the removal of spent suspension iron-containing sorption materials. Experimental studies have confirmed that the use of the combination “fine-particle iron(III) oxyhydroxide/membrane” allows removing arsenic compounds from contaminated water to the sanitary requirements level (less than 10 μg As/l) and separating effectively the spent fine-particle sorbent from water
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Dave, Pragnesh N., and Lakhan V. Chopda. "Application of Iron Oxide Nanomaterials for the Removal of Heavy Metals." Journal of Nanotechnology 2014 (2014): 1–14. http://dx.doi.org/10.1155/2014/398569.

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In the 21st century water polluted by heavy metal is one of the environment problems. Various methods for removal of the heavy metal ions from the water have extensively been studied. Application of iron oxide nanaparticles based nanomaterials for removal of heavy metals is well-known adsorbents for remediation of water. Due to its important physiochemical property, inexpensive method and easy regeneration in the presence of external magnetic field make them more attractive toward water purification. Surface modification strategy of iron oxide nanoparticles is also used for the remediation of water increases the efficiency of iron oxide for the removal of the heavy metal ions from the aqueous system.
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Belova, Larisa, Alexandr Zhulin, and Olga Sidorenko. "Degassers in drinking water supply." E3S Web of Conferences 135 (2019): 01030. http://dx.doi.org/10.1051/e3sconf/201913501030.

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In the Tyumen region, groundwater is widely used for household and drinking water supply, the chemical composition of which is influenced by the increased marshland and peat resistance of soils and, in some cases, the presence of oil and gas-bearing horizons. Underground water typically has a high content of dissolved organic impurities (permanganate oxidability 11.7 - 23.0 mg/dm3), elevated concentrations of free carbon dioxide (20.0 200.0 mg/dm3), hydrogen sulfide (0.20 - 1.95 mg/dm3) and methane (5.3 - 60.0 mg/dm3), dissolved forms of iron (1.14 - 14.00 mg/dm3), manganese (0.02 - 3.80 mg/dm3). Analysis of iron removal plants operation was performed. Analysis of the region's iron removal plants showed that the process of iron removal of water depends on the degree of saturation of water with air oxygen with parallel removal of dissolved gases. Pre-degassing of water with high efficiency degassers is a necessary link of the process chain even when reagent purification techniques are used. Analysis and systematization of existing degassers to remove dissolved carbon dioxide have shown that despite the high-efficiency of some degasser models, they are complex in design and require considerable capital construction and operation costs. There is a need to develop a design not complicated in design, having high degassing efficiency at low economic costs.
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Hu, Feng Ping, Wei He, Chao Chun Tang, and Lv Zhong. "Purification Efficiency Study of Biological Treatment of Iron and Manganese for Groundwater." Advanced Materials Research 599 (November 2012): 383–86. http://dx.doi.org/10.4028/www.scientific.net/amr.599.383.

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The purification efficiency of biological removal of iron and manganese was probed by pilot tests. In this experiment, the raw water were iron concentration of 0.96~5.56 mg/L, manganese concentration of 0.87~2.38 mg/L, dissolved oxygen of 2~4 mg/L, pH value neutral. In the condition of filter speed of 6 m/h, the average removal rate of iron and manganese reached 97.6% and 90.9% respectively, the effluent concentration of Fe2+ and Mn2+ were keep in below 0.1 mg/L.
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Zhytsianiou, Barys N., and Lyudmila E. Yordanova. "Backwash water treatment by coagulation in the presence of phosphates at underground water iron removal stations." Vestnik MGSU, no. 4 (April 2020): 553–68. http://dx.doi.org/10.22227/1997-0935.2020.4.553-568.

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Introduction. The analysis of the present-day condition of water resources has proven the relevance and expediency of developing highly effective backwash water treatment methods to be used at iron removal stations designated for groundwater treatment. In accordance with effective technical regulations, backwash water must be reused. The operation of iron removal stations has proven the inefficiency of backwash water treatment facilities. Water and wastewater treatment companies stop using backwash water treatment facilities and refrain from reusing backwash water. Highly concentrated iron-bearing backwash water is discharged into sewage networks, nearby water bodies or onto the terrain, which means irrational use of high-quality groundwater and environmental pollution with iron compounds. Materials and methods. The results of experimental research efforts and statistical processing of data on the qualitative and quantitative composition of backwash water at iron removal stations are presented. The chemical nature of the components and the principle underlying the formation of the backwash water composition in the process of groundwater deferrization have been studied. It’s been identified that if backwash water supplied by iron removal stations is treated by sodium phosphate reagent Na3PO4 and aluminum sulphate Al2(SO4)3 as a coagulant, precipitation of iron compounds intensifies, as colloidal particles FePO4 are formed. They have very low solubility, and they are effectively removed by coagulation. It has been theoretically proven and experimentally confirmed that anions H2 PO4– and PO4 3– fformed in the process of hydrolysis of sodium phosphate Na3PO4 help to reduce the electrokinetic charge of the colloidal particle of iron hydroxide Fe(OH)3, and high purification efficiency reaching 99.0–99.9 % is attained by attaching iron compounds to the surface of the colloidal particle of aluminum hydroxide Al(OH)3. Conclusions. The co-authors have developed a math-and-stats model simulating the backwash water treatment process that employs coagulation in the presence of phosphates. It describes the dependence between the concentration of residual iron, doses of sodium phosphate Na3PO4, aluminum sulphate Al2(SO4)3 and the settling time. A backwash water treatment technology has been developed. It employs coagulation in the presence of phosphates, and it is designated for use at iron removal stations. This technology comprises a chemical plant for sodium phosphate and aluminum sulphate used as a coagulant, a post-treatment filter, and sludge dewatering facilities. The application of this technology enables to reduce iron concentration to 0.05–0.20 mg/l, to reuse backwash water for drinking and other household purposes, or to have this water reused by iron removal stations, this, preventing pollution of water sources with iron compounds.
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Jordanowska, Joanna, and Monika Jakubus. "Evaluation of Effectiveness Technological Process of Water Purification Exemplified on Modernized Water Treatment Plant at Otoczna." Civil And Environmental Engineering Reports 13, no. 2 (December 10, 2014): 49–62. http://dx.doi.org/10.2478/ceer-2014-0014.

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Abstract The article presents the work of the Water Treatment Plant in the town of Otoczna, located in the Wielkopolska province, before and after the modernization of the technological line. It includes the quality characteristics of the raw water and treated water with particular emphasis on changes in the quality indicators in the period 2002 -2012 in relation to the physicochemical parameters: the content of total iron and total manganese, the ammonium ion as well as organoleptic parameters(colour and turbidity). The efficiency of technological processes was analysed, including the processes of bed start up with chalcedonic sand to remove total iron and manganese and ammonium ion. Based on the survey, it was found that the applied modernization helped solve the problem of water quality, especially the removal of excessive concentrations of iron, manganese and ammonium nitrogen from groundwater. It has been shown that one year after modernization of the technological line there was a high reduction degree of most parameters, respectively for the general iron content -99%, general manganese - 93% ammonia - 93%, turbidity - 94%. It has been proved, that chalcedonic turned out to be better filter material than quartz sand previously used till 2008. The studies have confirmed that the stage of modernization was soon followed by bed start-up for removing general iron from the groundwater. The stage of manganese removal required more time, about eight months for bed start-up. Furthermore, the technological modernization contributed to the improvement of the efficiency of the nitrification process.
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Jung, Sunyu, and Soon-Ho Park. "Characteristics of iron oxide rust prepared by peracetic acid and its removal of heavy metals in water." E3S Web of Conferences 158 (2020): 04005. http://dx.doi.org/10.1051/e3sconf/202015804005.

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Fe2O3 is an especially promising material for water purification as it shows high heavy metal adsorption capacity. However, the high cost of commercial Fe2O3 makes it difficult to be widely used in developing countries. Herein, we probe the heavy metal removal performance of iron oxide rust. Rust was grown on iron nails in a controlled manner using peracetic acid (CH3CO3H), a safe and environment-friendly oxidizer. Arsenic was selected as an example of a heavy metal contaminant in this study. XRD and EDS analysis revealed that the iron oxide prepared with peracetic acid was nearly amorphous Fe2O3. Amorphous iron oxide is reported to show higher reactivity than crystalline iron oxide. The BET specific surface area of prepared Fe2O3 is 71 m2/g, which is larger than that of commercial Fe2O3, and the average pore diameter is 73 Å. Oxidized nails are highly effective for removing heavy metals: about 90% of 1ppm arsenic in water was removed at the residence time of 20 minutes, and the removal rate of 90% is maintained after 10 back-to-back arsenic removal experiments at the same residence time. Iron oxide prepared in this study can remove, per 1 cm2, up to 0.114 mg of arsenic.
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Nkurunziza, T., J. B. Nduwayezu, E. N. Banadda, and I. Nhapi. "The effect of turbidity levels and Moringa oleifera concentration on the effectiveness of coagulation in water treatment." Water Science and Technology 59, no. 8 (April 1, 2009): 1551–58. http://dx.doi.org/10.2166/wst.2009.155.

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Laboratory experiments were carried out to assess the water purification and antimicrobial properties of Moringa oleifera (MO). Hence different concentrations (25 to 300 mg/L) were prepared from a salt (1 M NaCl) extract of MO fine powder and applied to natural surface water whose turbidity levels ranged from 50 to 450 NTU. The parameters determined before and after coagulation were turbidity, pH, colour, hardness, iron, manganese and Escherichia coli. The experiments showed that turbidity removal is influenced by the initial turbidity since the lowest turbidity removal of 83.2% was observed at 50 NTU, whilst the highest of 99.8% was obtained at 450 NTU. Colour removal followed the same trend as the turbidity. The pH exhibited slight variations through the coagulation. The hardness removal was very low (0 to 15%). However, high removals were achieved for iron (90.4% to 100%) and manganese (93.1% to 100%). The highest E. coli removal achieved was 96.0%. Its removal was associated with the turbidity removal. The optimum MO dosages were 150 mg/L (50 NTU and 150 NTU) and 125 mg/L for the rest of the initial turbidity values. Furthermore all the parameters determined satisfied the WHO guidelines for drinking water except for E. coli.
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Szatyłowicz, Ewa, and Iwona Skoczko. "Magnetic Field Usage Supported Filtration Through Different Filter Materials." Water 11, no. 8 (July 31, 2019): 1584. http://dx.doi.org/10.3390/w11081584.

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Currently, methods of water purification and aqueous solutions leading to effective reduction of introduced chemical compounds into water purification systems have become the subject of research. Physical methods have become an alternative, because by subjecting water and aqueous solutions to UV (ultraviolet) radiation or magnetic fields (MF), either ultrasonic or electric, it is possible to influence the change of structure, which results in changes in the properties of water and aqueous solutions. This paper attempts to verify the influence of a weak magnetic field on the removal of iron and manganese compounds in the filtration process on gravel of 1–2 mm granulation, sand of 0.4–0.8 mm granulation, activated alumina and activated carbon. The conducted research proved that MF has a significant influence on the effectiveness of iron and manganese removal from water in the case of alumina, while in the filtration process through other filter materials the effect of MF was small.
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Albrektienė, Ramunė, and Dainius Paliulis. "Investigation of Lead Removal from Drinking Water Using Different Sorbents." Ecological Chemistry and Engineering S 27, no. 1 (March 1, 2020): 67–82. http://dx.doi.org/10.2478/eces-2020-0004.

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AbstractLead is a heavy metal with strong toxic properties. This chemical element is found in wastewater and sometimes in drinking water. The article deals with the removal of lead(II) ions from polluted water using a sorption process to determine the most effective sorbent for the removal of lead(II) ions. Three sorbents were used in the research: clay, sapropel, and iron sludge. All three sorbents investigated reduce the concentration of lead(II) ions in water: clay efficiency was of 65.7–90 %, sapropel of 94.3–100 %, and iron sludge of 84.3–97 %, depending on sorbent type and contact duration. The research has shown that the most effective way to remove lead(II) ions from the test water is sapropel. Using different amounts of sapropel (1, 2, 3, 4, 5, 6 g/dm3 and 0.1, 0.2, 0.4, 0.5, 0.6, 0.8 g/dm3) and different duration of contact (30, 60, 90, 120 and 150 minutes), the concentration of lead(II) ions in the test water after purification did not exceed the permissible values for drinking water (10 μg/dm3), so that the lowest sapropel content of 0.1 g/dm3 can be used for sorption. Lead(II) ions are most effectively removed when contact time is 30 min.
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Dissertations / Theses on the topic "Water – Purification – Iron removal"

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Isaeva, Margarita, and Castro Natasha Montes. "Water Treatment for the Removal of Iron and Manganese." Thesis, Högskolan i Skövde, Institutionen för teknik och samhälle, 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:his:diva-5357.

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The purpose of the study is to find a suitable method for removal of iron and manganese considering local economic and environmental aspects. El Salvador is situated in Central America with a coast line towards the Pacific Ocean. The country borders Guatemala and Honduras. Aguilares is a town situated in the department of San Salvador, with a population of approximately 33,000 people. Currently, the population is provided with water for about two hours per day, since it is the highest capacity of the existing wells. During these two hours many households fill a small tank with water to use for the remainder of the day. The water is not safe to use for oral consumption because of the levels of bacteria and other contamination. One of the wells, situated in the community of Florída is not in use at this date because of the high levels of Iron and Manganese in the ground water which cannot be removed with the present technique.Ground water is naturally pure from bacteria at a depth of 30 m or more, however solved metals may occur and if the levels are too high the water is unsuitable to drink. The recommended maximum levels by WHO (2008) [1] for Iron and Manganese are 2 mg/l and 0.5 mg/l respectively.Literature and field studies led to the following results; Iron and manganese can be removed by precipitation followed by separation. Precipitation is achieved by aeration, oxygenation or chemical oxidation and separation is achieved by filtration or sedimentation.The different methods all have advantages and disadvantages. However the conclusion reached in this report is that aeration and filtration should be used in the case of Florída. What equipment and construction that should be used depends on economic and resource factors as well as water requirements, which is up to the council of Aguilares to deliberate.
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Conley, LuAnne Simpson. "Removal of complexed iron by chemical oxidation and/or alum coagulation." Thesis, This resource online, 1992. http://scholar.lib.vt.edu/theses/available/etd-03172010-020643/.

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Swarna, Anitha. "Removal of Arsenic Using Iron Coated Limestone." TopSCHOLAR®, 2014. http://digitalcommons.wku.edu/theses/1342.

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Arsenic contamination in drinking water is a severe problem worldwide. The best way to prevent hazardous diseases from chronic arsenic exposure is to remove the exposure. Efforts to remediate arsenic in drinking water have taken two tracks. One is to provide surface or shallow well water sources as an alternative to the arsenic contaminated deep wells. Another approach is to remove arsenic from the contaminated water. Different removal technologies like oxidation, chemical coagulation, precipitation, adsorption and others are available. There are problems and benefits associated with each of these approaches that can be related to cultural, socio-economic and engineering influences. The method proposed in this research is adsorption of arsenic to iron coated limestone. Different iron coated limestone samples were prepared. Standard solutions of 100ppb arsenic were prepared and batch and kinetic experiments were conducted. The final solution concentrations were analyzed by Graphite Furnace Atomic Adsorption Spectroscopy (GFAAs) and the results showed that iron coated limestone removed arsenic below 10ppb with 5 grams of material. Variations in iron coverage impacted efficiency of arsenic removal.
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Coffey, Bradley Martin. "Removal of soluble iron and manganese from groundwater by chemical oxidation and oxide-coated multi-media filtration." Thesis, Virginia Tech, 1990. http://hdl.handle.net/10919/42068.

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Sinsabaugh, Robert L. "Removal of dissolved organic matter from surface waters by coagulation with trivalent iron." Diss., Virginia Polytechnic Institute and State University, 1985. http://hdl.handle.net/10919/49777.

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Beard, Kelly Marie. "Role of oxidants in the removal of iron and organics from Harwood's Mill Reservoir." Thesis, Virginia Polytechnic Institute and State University, 1985. http://hdl.handle.net/10919/104292.

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Shorney, Holly L. "The performance of free chlorine and chlorine dioxide oxidation and/or alum coagulation for the removal of complexed Fe(II) from drinking water." Thesis, Virginia Tech, 1992. http://hdl.handle.net/10919/44744.

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Past research regarding complexed iron has focused on the resistance to and kinetics of oxidation by O₂(aq) and the extent of stabilization. The 0.45 um filter was typically used to differentiate between dissolved and particulate iron. This research investigated Fe(II) oxidation by free chlorine and ClO₂ in the presence of DOC by varying the pH, DOC to Fe ratios, DOC sources, oxidant dosages, and contact time. Complexed iron removal by alum coagulation with and without oxidant addition was also examined. Particulate, colloidal, and soluble iron were differentiated by the use of 0.2 um filters and 100K ultrafilters. Ultrafiltration and oxidation studies revealed that, at the DOC-to-iron ratios used for this research, not all of the Fe(II) in solution was actually complexed. Thus, oxidation studies represented the oxidation of uncomplexed Fe(II) to Fe(III), which was then complexed by the higher molecular weight DOC. Results indicated that particulate iron formation (as defined as retention by a 0.2 um filter) was a function of the DOC source and oxidant used for testing. The formation of colloidal iron (as defined by retention on 100K ultrafilter) due to oxidation was dependent upon the initial DOC-to-iron ratio and the DOC source. A correlation between DOC adsorption to iron oxide solids and the solution pH, initial DOC-to-iron ratio, and the oxidant used was also evident. Complexed Fe(II) was removed from solution by alum coagulation. Oxidant addition to alum coagulation was necessary to effectively remove uncomplexed Fe(II) (in the presence of DOC) from solution.
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Leake, Thomas Russell. "Zinc removal using biogenic iron oxides." Pullman, Wash. : Washington State University, 2009. http://www.dissertations.wsu.edu/Thesis/Fall2009/T_Leake_120409.pdf.

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Thesis (M.S. in enviromental engineering)--Washington State University, December 2009.
Title from PDF title page (viewed on Jan. 28, 2010). "Department of Civil and Environmental Engineering." Includes bibliographical references (p. 27-31).
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Burner, Joe Gary. "Manganese removal from an organic-laden surface water." Thesis, Virginia Polytechnic Institute and State University, 1985. http://hdl.handle.net/10919/104297.

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Cordray, Antoine. "Phosphorus removal characteristics on biogenic ferrous iron oxides." Pullman, Wash. : Washington State University, 2008. http://www.dissertations.wsu.edu/Thesis/Fall2008/a_cordray_111708.pdf.

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Thesis (M.S. in environmental engineering)--Washington State University, December 2008.
Title from PDF title page (viewed on Dec. 23, 2008). "Department of Civil and Environmental Engineering." Includes bibliographical references (p. 69-72).
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Books on the topic "Water – Purification – Iron removal"

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Hermanson, Ronald E. The stainers--iron and manganese removal. [Pullman]: Cooperative Extension, Washington State University, 1991.

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Hermanson, Ronald E. The stainers--iron and manganese removal. [Pullman]: Cooperative Extension, Washington State University, 1991.

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author, Tompeck Mark, ed. Iron and manganese removal handbook. Denver, CO: American Water Works Association, 2015.

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Knocke, William R. Impacts of dissolved organic carbon on iron removal. Denver, CO: The Foundation and American Water Works Association, 1993.

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Olthoff, Reinhold. Die Enteisenung und Entmanganung von Grundwasser im Aquifer. Hannover: Institut für Siedlungswasserwirtschaft und Abfalltechnik der Universität Hannover, 1986.

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Jafar, Shamsuddin Abu, Mahmud Shamsul Gafur, and ITN-Bangladesh (Network), eds. Development of community based arsenic & iron removal unit for rural water supply system. Dhaka: ITN-Bangladesh, Centre for Water Supply and Waste Management, BUET, 2005.

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Benjamin, Mark M. Adsorption and filtration studies using iron-oxide-coated olivine as a medium. Denver, CO: AWWA Research Foundation and the American Water Works Association, 1995.

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Majcherek, Hanna. Metodyka obliczania stacji wodociągowych z zakładem odżelaziania wody ; Matematyczne modelowanie kanałów o założonej charakterystyce prędkości przepływu. Poznań: Wydawn. Politechniki Poznańskiej, 1990.

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Leung, David C. W. Removal of fluorides from water supplies. [Edmonton?]: Alberta Environment, Standards and Approvals Division, Municipal Engineering Branch, 1985.

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Frank, Phyllis. Arsenic (III) oxidation and removal from drinking water. Cincinnati, OH: U.S. Environmental Protection Agency, Water Engineering Research Laboratory, 1986.

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Book chapters on the topic "Water – Purification – Iron removal"

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AKRETCHE, DJAMAL-EDDINE. "METALS REMOVAL FROM INDUSTRIAL EFFLUENTS." In Water Purification and Management, 1–23. Dordrecht: Springer Netherlands, 2010. http://dx.doi.org/10.1007/978-90-481-9775-0_3.

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Radetic, Bogdanka, and Claudio Lehmann. "Carbon, Nitrogen, and Phosphorous Removal, Basics and Overview of Technical Applications." In Handbook of Water and Used Water Purification, 1–39. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-66382-1_93-1.

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Wijmans, J. G., R. W. Baker, and A. L. Athayde. "Pervaporation: Removal of Organics from Water and Organic/Organic Separations." In Membrane Processes in Separation and Purification, 283–316. Dordrecht: Springer Netherlands, 1994. http://dx.doi.org/10.1007/978-94-015-8340-4_14.

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Devika, S. L., P. Nimitha, Venkatesh Muganur, and S. Shrihari. "Removal of Dyes and Iron Using Eco-Friendly Adsorbents." In Climate Impacts on Water Resources in India, 233–42. Cham: Springer International Publishing, 2020. http://dx.doi.org/10.1007/978-3-030-51427-3_20.

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Kubuki, Shiro, and Tetsuaki Nishida. "Water Purification and Characterization of Recycled Iron-Silicate Glass." In Mössbauer Spectroscopy, 593–607. Hoboken, New Jersey: John Wiley & Sons, Inc., 2013. http://dx.doi.org/10.1002/9781118714614.ch31.

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Trad, Tarek, and Allen Apblett. "Removal of 4,6-Dinitro-o-Cresol, Congo Red Dye, and Decane from Water Using Magnetic-Activated Carbons." In Nanotechnology for Water Treatment and Purification, 261–74. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-06578-6_8.

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Kliučininkas, Linas, Viktoras Račys, Inga Radžiūnienė, and Dalia Jankūnaitė. "Collective Versus Household Iron Removal from Groundwater at Villages in Lithuania." In Sustainable Water Use and Management, 91–102. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-12394-3_5.

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Havezov, I., and E. Tsekulov. "Arsenic Species Isoformation — A Key Problem for Water Purification." In Water Treatment Technologies for the Removal of High-Toxity Pollutants, 119–33. Dordrecht: Springer Netherlands, 2009. http://dx.doi.org/10.1007/978-90-481-3497-7_10.

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Ma, Jie, Yao Ma, and Fei Yu. "As-Prepared Carbon Nanotubes for Water Purification: Pollutant Removal and Magnetic Separation." In Nanotechnology for Sustainable Water Resources, 329–70. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2018. http://dx.doi.org/10.1002/9781119323655.ch11.

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Rivera-Utrilla, José, Manuel Sánchez-Polo, and Raúl Ocampo-Pérez. "Removal of Antibiotics from Water by Adsorption/Biosorption on Adsorbents from Different Raw Materials." In Adsorption Processes for Water Treatment and Purification, 139–204. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-58136-1_6.

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Conference papers on the topic "Water – Purification – Iron removal"

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Averina, Julie. "METHODS OF INTENSIFICATION OF IRON-CONTAINING NATURAL WATER PURIFICATION PROCESSES." In 18th International Multidisciplinary Scientific GeoConference SGEM2018. STEF92 Technology, 2018. http://dx.doi.org/10.5593//sgem2018v/1.5/s02.043.

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Averina, Julie. "METHODS OF INTENSIFICATION OF IRON-CONTAINING NATURAL WATER PURIFICATION PROCESSES." In 18th International Multidisciplinary Scientific GeoConference SGEM2018. STEF92 Technology, 2018. http://dx.doi.org/10.5593/sgem2018v/1.5/s02.043.

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Rentz, Jeremy A., and Jeffrey L. Ullman. "Copper and Zinc Removal Using Biogenic Iron Oxides." In World Environmental And Water Resources Congress 2012. Reston, VA: American Society of Civil Engineers, 2012. http://dx.doi.org/10.1061/9780784412312.072.

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Thomas, Bintu, and L. K. Alexander. "Water purification using bio adsorbents for the removal of cationic dye." In 16TH INTERNATIONAL CONFERENCE ON CONCENTRATOR PHOTOVOLTAIC SYSTEMS (CPV-16). AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0029866.

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Weiss, Peter T., Zuhdi Y. Aljobeh, Chelsey Bradford, and E. Alex Breitzke. "An Iron-Enhanced Rain Garden for Dissolved Phosphorus Removal." In World Environmental and Water Resources Congress 2016. Reston, VA: American Society of Civil Engineers, 2016. http://dx.doi.org/10.1061/9780784479889.020.

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Pohrebennyk, Volodymyr. "PURIFICATION OF DRINKING WATER FROM IRON WITH THE HELP OF ACTIVATED ZEOLITES." In 18th International Multidisciplinary Scientific GeoConference SGEM2018. Stef92 Technology, 2018. http://dx.doi.org/10.5593/sgem2018/5.2/s20.098.

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Barlokova, Danka. "REMOVAL OF IRON AND MANGANESE FROM SMALL WATER RESOURCES." In 17th International Multidisciplinary Scientific GeoConference SGEM2017. Stef92 Technology, 2017. http://dx.doi.org/10.5593/sgem2017/31/s12.067.

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Girbaciu, Cristian Adrian. "IRON REMOVAL FROM UNDERGROUND WATER USING A LABORATORY INSTALATION." In 13th SGEM GeoConference on ECOLOGY, ECONOMICS, EDUCATION AND LEGISLATION. Stef92 Technology, 2013. http://dx.doi.org/10.5593/sgem2013/be5.v1/s20.082.

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Quamme, Michael, Talal Almeelbi, and Achintya Bezbaruah. "Selenium Removal from Surface Waters: Exploratory Research with Iron Nanoparticles." In World Environmental And Water Resources Congress 2012. Reston, VA: American Society of Civil Engineers, 2012. http://dx.doi.org/10.1061/9780784412312.016.

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Pop, A., C. Bordianu, R. Pode, I. Vlaicu, N. Lungar, K. Bodor, and F. Manea. "Drinking water treatment by iron anode-based electrocoagulation: humic acids and arsenic removal." In WATER POLLUTION 2016. Southampton UK: WIT Press, 2016. http://dx.doi.org/10.2495/wp160121.

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