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5. Eco-friendly technology for 'Nitrofos' fertilizer obtained from radioactive man-made waste

Author

Mukhachev Anatoliy, Yelatontsev Dmytro, Shevchenko Volodymyr, Bozhko Kateryna, and Kharуtonova Olena

Subjects
Environmental sciences, GE1-350
Abstract

The article presents the results of research into the process of purification of phosphoric acid from radioactive isotopes after extraction of uranium, thorium, and REE. It is shown that the main purification of acid is achieved in the process of gypsum precipitation with sulfuric acid and barium nitrate. Additional purification of nitrate-phosphate solution is achieved after uranium extraction and sorption-extraction purification of REE. The sorption raffinate with a concentration of P2O5 25 g/L, REE 0.5 g/L and NH4NO3 300 g/L were used for fertilizer production. Additional purification of NH4NO3 solution from isotopes 226Ra, 210Po, 227Ac is achieved in the process of REE extraction purification. The aggregate of all refining processes of purification of nitrate-phosphate solution from radioactive isotopes provided NP-fertilizer “Nitrofos”, which meets the quality standards. Extraction of P2O5 from raw materials into NP-fertilizer – 90%; extraction of REE from raw materials into collective chemical concentrate – 95%; direct commercial extraction of REE from raw materials into the product – 85%.

Published
2024
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8. Production of Neutron-Absorbing Zirconium-Boron Alloy by Self-Propagating High-Temperature Synthesis and Its Refining via Electron Beam Melting.

Author

Mukhachev, Anatoly, Yelatontsev, Dmytro, Kharytonova, Olena, and Grechanyuk, Nickolay

Subjects
ZIRCONIUM alloys, SELF-propagating high-temperature synthesis, ELECTRON beam furnaces, THERMAL neutron capture, CRYSTALLIZATION
Abstract

The paper presents the results of the study of the processes of self-propagating high-temperature synthesis of Zr-1%B alloy and its refining by electron beam melting. Experiments on the influence of boron's amorphous and crystalline modifications on the safety parameters of the synthesis process of Zr-1%B alloy necessitated the conversion of amorphous boron into crystalline form by electron beam melting, with an increase in its purity from 94% to 99.9%. High efficiency of vacuum induction and electron beam equipment was demonstrated, which provided a high purity of the Zr-1%B alloy of at least 99.9%. The alloy ingots had a uniform distribution of the alloying element (boron) all over the volume. The obtained alloy is suitable for the production of materials with thermal neutron capture cross-sections of up to 40 barns for neutron protection. [ABSTRACT FROM AUTHOR]

Published
2024
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14. AN EFFECTIVE BIOSORBENT DERIVED N EFFECTIVE BIOSORBENT DERIVED FROM PRODUCTION WASTE ROM PRODUCTION WASTE FOR WATER TREATMENT: STUDYING OR WATER TREATMENT: STUDYING THE ADSORPTION OF SYNTHETIC DYES HE ADSORPTION OF SYNTHETIC DYES

Author

Olena Ivaniuk, Yelatontsev Dmytro, and Anatoly Mukhachev

Subjects
Information Systems and Management, Management of Technology and Innovation, Law, Engineering (miscellaneous), Computer Science Applications
Abstract

Introduction. Eco-friendly disposal of food waste, in particular, nutshells and fruit kernels, is an important issue to ensure sustainable nature management. These secondary raw materials are the source of valuable polymeric materials, cellulose and lignin.Problem Statement. IGiven the capacity of the food industry in Ukraine and the amount of waste produced, the development of technologies for processing lignin-cellulose biomass is an important research and practical issue.Purpose. The purpose of this research is to study the adsorption properties of chemically modified biosorbent based on plant materials concerning synthetic dyes of different types and classes; to assess the feasibility of biosorbent production and efficiency of its application in water treatment.Materials and Methods. Lignocellulose sorbent (LCS) has been synthesized from non-wood raw materials by chemical modification with the use of phosphoric acid with the addition of urea in an aqueous media. The Fourier transform infrared and standard methods of plant raw material analysis have been used to determine the physicochemical characteristics of LCS. The adsorption of anionic (methyl orange, alizarin red S, eosin Y), cationic (methylene blue, neutral red), and nonionic (aniline yellow) dyes on LCS from aqueous solution has been studied in the batch mode.Results. The adsorption capacity of LCS towards cationic dyes (47.0–53.3 mg/g) is higher than that of anionic (22.2–36.9 mg/g) and nonionic (4.7 mg/g) ones. The adsorption kinetics have been adequately described by a pseudo-second-order equation. Adsorption of all classes of dyes on LCS is thermodynamically feasible, spontaneous, and endothermic process. The liquid by-product of LCS production contains 15% nitrogen and 10% phosphorus, so it may be used as a fertilizer. Conclusions. The proposed method for processing food waste provides obtaining effective sorbent and liquid NP-fertilizer. LCS removes both cationic and anionic pollutants from water, so it may be considered a promisingbiosorbent for water purification.

Published
2021
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15. APPLICATION OF ACID-ACTIVATED ZEOLITE IN DYES WASTEWATER PURIFICATION TECHNOLOGIES

Author

Yelatontsev Dmytro and Ivanchenko Anna

Abstract

The work aims to study the process of activation of natural zeolite by inorganic acids, in particular, HNO3and H3PO4to verify their effectiveness when extracting dyes from aqueous media in batch mode.It is proposed to use the method of purification with sorbents modified with mineral acids nitric, hydrochloric, and ortho-phosphate to increase the absorption capacity concerning water-soluble dyes. The analysis of the process of purification and neutralization of dyes in water systems with the help of zeolite of the Sokernyanskoye deposit was carried out experimentally. Chemical activation, which was carried out by the impregnation method, was used to improve the sorption properties. Samples of chemically activated zeolite were obtained. Due toacid activation, Al, K, Na, Ca, Mg, Fe ions are released, which release micro-and mesopores in the sorbent, which increases its porosity and improves sorption properties. The composition of activated natural mineral zeolite with HNO3, HCl, H3PO4acids were characterized. The chemical composition of activated zeolite was determined by X-ray fluorescence.The efficiency of acid-activated zeolite for the extraction of dyes from wastewater was tested. The dependences of the dye extraction process from model solutions using ordinary and acid-activated zeolite have been established. The dye content in the treated wastewater was determined by the photometric method. The kinetic regularities of the dye adsorption process during contact of natural and activated zeolite samples in the time interval every 6 h for 24 h have been established. It was found that the concentration of pollutants varies and depends on the type of acid and has a decisive influence on the obtained chemical properties of the modified samples.It is recommended to use zeolite activated with hydrochloric acid asa natural adsorbent at a dose of 4 g/dm3with a contact time of 24 hours. According to these technological parameters, the dye content in water decreases from 117 mg/dm3to 41 mg/dm3.The obtained results allow to significantly expand the knowledge about the areas of application of natural sorbents in various technological processes.

Published
2021
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18. ИССЛЕДОВАНИЕ ПРОЦЕССА ОЧИСТКИ СТОЧНЫХ ВОД КОКСОХИМИЧЕСКОГО ПРОИЗВОДСТВА ГЛАУКОНИТОВОЙ ГЛИНОЙ

Author

Ivanchenko, Anna V., Khavikova , Karina Ye., Yelatontsev, Dmytro O., and Panasenko , Vladimir O.

Subjects
фенолы, роданиды, дифференциальная термограмма, differential thermogram, phenols, glauconite, ammonia, аммиак, ізотерма адсорбції, коксохімічні стоки, Water treatment, смолисті речовини, resinous substances, диференційна термограма, rhodanides, Colloid chemistry, глауконіт, изотерма адсорбции, coke wastewater, коксохимические стоки, adsorption isotherm, феноли, смолистые вещества, глауконит, амоніак, роданіди
Abstract

The process of complex purification of coke wastewater from phenols, rhodanides, ammonia, and resinous substances with the use of glauconite clay has been studied. Natural and activated glauconite, glauconite in combination with cationic flocculant brand Extraflock P 70, and activated carbon brand UAF (for comparison of cleaning efficiency) were used in this research. The activation of natural glauconite was carried out with a 7 % solution of HNO3 at 95–100 °C, at a ratio "mineral sorbent:acid solution" of 1:6 and an activation time of 5 hours It has been established that acid activation leads to a change in the chemical composition of glauconite and increases the specific surface area from 32 m2/g to 128 m2/g. Based on the results of natural glauconite thermal analysis, a conclusion was made about the phase transformations and chemical reactions that occur in glauconite clay during heating or cooling. Also, the thermal effects that accompany these changes, and some qualitative characteristics of the glauconite mineral were found. It was established that the maximum degree of phenols extraction from industrial effluent is up to 50% and is achieved when glauconite is used in combination with a flocculant. The maximum degree of purification from total ammonia is 57–58 % when using activated glauconite and glauconite with flocculant. The lowest degree of purification is achieved for rhodanides removal, not exceeding 20 % for any adsorbent. The highest degree of purification of 96.8 % is observed when removing resinous substances with glauconite in combination with a flocculant. Activation of glauconite by HNO3 leads to an increase in sorption capacity by 5–15 % depending on the pollutant. The coke wastewater purification degree of these pollutants with activated carbon is 20 % of phenols, 14 % of rhodanides, 28 % of total ammonia, and 72 % of resinous substances, respectively. Therefore, in industrial practice, it is recommended to use glauconite at a concentration of 2 g/dm3 in combination with 0.1 % solution of cationic flocculant with a volume of 30 cm3/dm3 with the duration of wastewater treatment 20–180 minutes for complex processing of effluents., Исследован процесс комплексной очистки коксохимических стоков от фенолов, роданидов, общего аммиака и смолистых веществ с использованием глауконитовой глины. В работе использован природный и активированный глауконит, а также глауконит в сочетании с катионным флокулянтом марки Extraflock P 70 и активированный уголь марки УАФ (для сравнения эффективности очистки). Активация природного глауконита проведена 7 %-ным раствором HNO3 при температуре кипения – 95–100 °С, соотношении «минеральный сорбент : раствор кислоты» 1 : 6 и времени активации 5 ч. Установлено, что кислотная активация приводит к изменению химического состава глауконита и увеличению удельной поверхности с 32 до 128 м2/г. По результатам термического анализа природного глауконита сделан вывод о фазовых превращениях и химических реакциях, протекающих в глауконитовой глине при нагревании или охлаждении, по термическим эффектам, сопровождающим эти изменения и получено качественную характеристику минерала глауконита. Установлено, что максимальная степень извлечения фенолов из промышленных стоков составляет до 50 % и достигается при использовании глауконита в сочетании с флокулянтом. Максимальная степень очистки от общего аммиака составляет 57–58 % при использовании активированного глауконита и глауконита с флокулянтом. Наименьшая степень очистки достигается при извлечении роданидов и не превышает 20% для любого из адсорбентов. Наибольшая степень очистки 96,8 % наблюдается при удалении смолистых веществ глауконитом в сочетании с флокулянтом. Активация глауконита раствором HNO3 приводит к увеличению сорбционной емкости на 5–15% в зависимости от полютанта. Степень очистки коксохимических стоков от приведенных полютантов активированным углем составляет 20 % от фенолов, 14 % от роданидов, 28 % от общего аммиака и 72 % от смолистых веществ, соответственно. Следовательно, в промышленной практике для комплексной переработки стоков рекомендуется использовать глауконит концентрацией 2 г/дм3 в сочетании с 0,1% раствором катионного флокулянта объемом 30 см3/дм3 при длительности обработки стоков 20–120 мин., Досліджено процес комплексного очищення коксохімічних стоків від фенолів, роданідів, загального амоніаку та смолистих речовин із використанням глауконітової глини. У роботі використано природний і активований глауконіт, глауконіт в поєднанні з катіонним флокулянтом марки Extraflock P 70 та активоване вугілля марки УАФ (для порівняння ефективності очищення). Активацію природного глауконіту проведено 7 %-им розчином HNO3 при температурі кипіння – 95–100 °С, співвідношенні «мінеральний сорбент:розчин кислоти» 1:6 та часі активації 5 год. Встановлено, що кислотна активація призводить до зміни хімічного складу глауконіту та збільшенню питомої поверхні з 32 м2/г до 128 м2/г. За результатами термічного аналізу природного глауконіту зроблено висновок про фазові перетворення та хімічні реакції, які протікають у глауконітовій глині при нагріванні або охолодженні, по термічним ефектам, що супроводжують ці зміни та отримати якісну характеристику мінералу глауконіту. Встановлено, що максимальний ступінь очищення фенолів із промислових стоків становить до 50 % і досягається при використанні глауконіту в поєднанні з флокулянтом. Максимальний ступінь очищення від загального амоніаку складає 57–58 % при застосуванні активованого глауконіту та глауконіту з флокулянтом. Найменший ступінь очищення досягається при вилученні роданідів, що не перевищує 20 % для будь-якого адсорбенту. Найбільший ступінь очищення 96.8 % спостерігається при видаленні смолистих речовин глауконітом в поєднанні з флокулянтом. Активація глауконіту HNO3 призводить до збільшення сорбційної ємності на 5–15 % в залежності від полютанта. Ступінь очищення коксохімічних стоків від наведених полютантів активованим вугіллям складає 20 % від фенолів, 14 % від роданідів, 28 % від загального амоніаку та 72 % від смолистих речовин, відповідно. Отже, в промисловій практиці рекомендовано використовувати для комплексної переробки стоків глауконіт концентрацією 2 г/дм3 в поєднанні з 0,1 % розчином катіонного флокулянту об’ємом 30 см3/дм3 за тривалості обробки стоків 20–120 хв.

Published
2022
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24. RESEARCH OF COKE WASTEWATER TREATMENT PROCESS WITH GLAUCONITE CLAY.

Author

Ivanchenko, Anna V., Khavikova, Karina Ye., Yelatontsev, Dmytro O., and Panasenko, Volodymyr O.

Subjects
WASTEWATER treatment, GLAUCONITE, THIOCYANATES, PHENOLS, CATIONIC surfactants
Abstract

Copyright of Journal of Chemistry & Technologies is the property of Oles Honchar Dnipro National University and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2021
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27. Developing of effective treatment technology of the phenolic wastewater

Author

Klymenko, Irina, Yelatontsev, Dmytro, Ivanchenko, Anna, Dupenko, Olga, Voloshyn, Nikolay, Klymenko, Irina, Yelatontsev, Dmytro, Ivanchenko, Anna, Dupenko, Olga, and Voloshyn, Nikolay

Abstract

It is found that a high degree of purification from emulsified coal tar is achieved in the phenolic wastewater treatment using 88 mg/dm3 of sodium bentonite with the addition of 8 mg/dm3 of cationic flocculant in conditions the closest to industrial. This innovative method of phenolic wastewater treatment is cost­effective because of the low cost of bentonite. It is shown that the deposit formed during the wastewater treatment with bentonite floats to the liquid surface and can be separated by a scraper device for further utilization in construction. The process of biological treatment of phenolic wastewater in the combined aerator­clarifier unit is shown. It is determined that the optimum time for efficient phenol extraction from wastewater is 6 hours. It is experimentally proved that the use of this unit makes the biological treatment process 4 times faster giving significant economic benefits by reducing energy consumption for aeration. The flow diagram of complex wastewater purification from coal tar and phenol is developed. The use of it at coke and chemical plants will significantly increase the treatment efficiency and product profitability.

Published
2016

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