Tatsiana Savitskaya scite author profile

Rheological properties of corn starch and sodium alginate blend solutions have been measured at different polymer ratios in the temperature range from 303 to 343 K bya R/S Brook field rheometer with аcoaxial cylinder measuring unit. Dynamic viscosity of blends has been shown to decrease with shear rate increase and to increase with sodium alginate content increase. The influence of shear rate on activation energy of viscous flow depends on sodium alginate content and is different for below and over 5% (mass) content. Applicability of Ostwald-de-Waele, Herschel-Bulkley, Bingham and Casson models for the description of CS:SA blend solutions flow has been analyzed. Rheological properties of CS:SA blend solutions allow one to look at them as an alternative to starch solutions for edible films casting and production by dry method.

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Stepping Control of Electrochemical Process for Simultaneous Removal of COD and Ammonia with High Efficiency and Energy Saving

Yao¹,

Chen²,

Ye³

et al. 2021

J. Electrochem. Soc.

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To maximize pollutant removal efficiency with minimal energy consumption, electrochemical process for wastewater treatment should be further conducted. The stepping control of electrochemical process for simultaneous removal of chemical oxygen demand (COD) and ammonia from simulated and actual wastewater with high efficiency and energy saving was studied in this work. Flow rate, initial pH value, Cl− concentration, and applied current density were determined to be the influencing factors for the degradation performance, and analyses of pollutant removal efficiency further revealed that applied current density was the significant parameter in this case. A stepping control system by operating applied current density timely based on the degradation pathway of organic matter and variation of anodic working potential was then proposed; results indicated that 90.9% COD and 100% ammonia could be removed, and energy consumption of 7.6 kWh m−3 was calculated, which was substantially lower than that of the traditional electro-oxidation system (11.7 kWh m−3). Additionally, the developed stepping control system was validated by treating an actual pharmaceutical wastewater, results for which showed that removal efficiencies of 81.7% and 100% were achieved for COD and ammonia, respectively, and energy saving could be up to 37.2%.

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Bicomponent Solutions of Food Polysaccharide and Edible Films on Their Basis

Huo¹,

Savitskaya²,

Gotina³

et al. 2015

FNS

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The study of the rheological properties of aqueous solutions of corn starch (CS) blends with sodium alginate (SA) and agar-agar (AA) as well as the physical and mechanical properties of bicomponent films on their basis has been carried out. The data show that adding of both polymers to starch solution causes an increase in viscosity which is higher in the case of SA. Activation energy for viscosity flow of solutions of CS blended with SA has minimum value at CS:SA ratio = 98:2. The above mentioned dependence is not typical for AA, as flow activation energy in this case raises steadily with the growth of AA content in the solution, like viscosity of the CS:AA. The extreme behavior of polymer blends with low content of one of the polymers is described in terms of mutual solubility or thermodynamic compatibility. There is a tendency that mechanical properties and water solubility increase with the increasing of SA and AA polymers in corn starch matrix. Obtained data evidence the benefits of bicomponent films production instead of starch-based films.

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Study into the internal structure of metal in the process of melting

et al. 2000

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Utilizing Spent Batteries to Fabricate Ni/ZnO-MnO₂ Electrodes for Electrochemical Ammonia Oxidation

Yao¹,

Mei²,

Wang³

et al. 2021

J. Electrochem. Soc.

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In this work, a novel Ni/ZnO-MnO2 electrode was fabricated by utilizing spent zinc-manganese batteries and then was applied to the electrochemical treatment of ammonia-containing wastewater. The obtained Ni/ZnO-MnO2 electrode was characterized by scanning electron microscopy, X-ray diffraction, and linear scanning voltammetry, suggesting that the fabricated electrode had a flower-like structure and showed high oxygen evolution potential and electrochemical activity. The electrochemical performance of the ZnO-MnO2 electrode in regard to ammonia removal and product selectivity was then investigated with different operating factors (i.e., electrolyte concentration, initial pH value, current density, and Cl− concentration), and the results indicated that the ammonia removal efficiency could reach 100% with a N2 selectivity of 91.8% under optimal conditions. Additionally, the mechanism of ammonia oxidation was proposed by cyclic voltammetry tests and active radical measurements, showing that ammonia was mainly oxidized via direct electron transfer, hydroxyl radicals, and active chlorine. Finally, the ZnO-MnO2 electrode was equipped for the treatment of actual pharmaceutical wastewater, results for which showed that ammonia could be completely removed with a current efficiency of 26.2% and an energy consumption of 52.7 kWh/kg N. Thus, the ZnO-MnO2 electrode prepared by recycling spent batteries is a promising anode for wastewater treatment.

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