Application of Polymer and Supported Membranes with 1-Decyl-4-Methylimidazole for Pertraction of Transition Metal Ions

Zinc-bearing sludge deposits resulting from metallurgical zinc production have been investigated. They were found to contain 11.0-13.0% of zinc, 1.4-1.5% of copper, 1.1-1.3% of arsenic, and ca 1% of lead, plus small amounts of cadmium and nickel (0.5 and 0.1%, respectively). The results of the leaching of these deposits with hydrochloric, sulfuric, and lactic acids, as well as with ammonia and NaOH, are presented. The composition of the leachates was dependent on the leaching reagent used. The effectiveness of leaching decreased in the following order of the reagents used: ammonia (10.5%), HNO 3 and NaOH (10.0% each), H 2 SO 4 (9.5%), HCl (9.0%), and lactic acid (8.0%). Due to the poor selectivity of the strong mineral acids used, the most effective leaching reagents were concentrated ammonia, NaOH, and lactic acid. The recovery of zinc using electrolysis and solvent extraction also was evaluated. As much as 92.0-99.0% of zinc was deposited on the cathode for a sulfuric acid solution having a pH in the range 1-2. The extractants used in the extraction process were a 60% TBP solution in toluene for acidic solutions and 1-decyl-2-methylimidazole for weakly acidic and weakly alkaline solutions. From a solution having a pH of around 2.7, Zn(II) ions were most effectively extracted (99.0%), whereas from those of a pH>4, also Cu(II) and Cd(II) (98.5 and 96.0%, respectively) ions were co-extracted along with Zn(II). The Ni(II) ions were most effectively extracted at a pH around 5.5 (74.0%). From solutions left after leaching with NaOH, 1-decyl-2-methylimidazole extracted mostly Zn(II) and Cu(II), whereas from those left after leaching with ammonia, Cd(II) could be extracted in addition to Zn(II) and Cu(II). An optimum pH for zinc recovery was 7.5-8.0.

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“…1-Decyl-2-methylimidazole was used as the carrier of non-ferrous ions across polymeric inclusion membranes [23].…”

Section: Introductionmentioning

confidence: 99%

Recovery of Zinc from Metallurgic Waste Sludges

Radzyminska-Lenarcik¹,

Sulewski²,

Urbaniak³

2015

Pol. J. Environ. Stud.

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“…industrial management (Maszke et al, 2018), materials science (Pietraszek and Gadek-Moszczak, 2013;Novy, 2016, Ulewicz et al, 2016;Dudek et al, 2017;Pietraszek et al, 2017;Jambor et al, 2018;Radek et al, 2018), especially supported by an image analysis (Gadek-Moszczak, 2017;Gadek-Moszczak and Matusiewicz, 2017), even in biomaterials (Gadek-Moszczak et al, 2015), hydraulic machines design (Pobedza and Sobczyk, 2013a;Pobedza and Sobczyk, 2013b;Guzowski and Sobczyk, 2014;Walczak and Sobczyk, 2014) and corrosion protection (Klimecka-Tatar, 2016). It may be also very useful in power industry (Dwornicka, 2014), chemical industry (Ulewicz and Radzyminska-Lenarcik, 2014;Gnatowski et al, 2018) or pharmaceutical and biotechnology industry (Skrzypczak- Pietraszek, 2016;Skrzypczak-Pietraszek et al, 2018b), where phytochemistry investigation (Skrzypczak- Pietraszek and Pietraszek, 2009;Skrzypczak-Pietraszek et al, 2017) are conducted with a huge random noise from individual differences in plant reactions.…”

Section: Resultsmentioning

confidence: 98%

The Smoothed Bootstrap Fine-Tuning

Dwornicka

Горошко

Pietraszek

2019

System Safety: Human - Technical Facility - Environment

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The bootstrap method is a well-known method to gather a full probability distribution from the dataset of a small sample. The simple bootstrap i.e. resampling from the raw dataset often leads to a significant irregularities in a shape of resulting empirical distribution due to the discontinuity of a support. The remedy for these irregularities is the smoothed bootstrap: a small random shift of source points before each resampling. This shift is controlled by specifically selected distributions. The key issue is such parameter settings of these distributions to achieve the desired characteristics of the empirical distribution. This paper describes an example of this procedure.

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“…The approach, similar to the one presented in this article, can also be very useful both in other branches of industry as well as in the research area. It seems that may successfully applied in metallurgy Salek and Klimecka-Tatar, 2016), materials science (Korzekwa et al, 2014;Ulewicz and Novy, 2016;Korzekwa et al, 2018), chemistry (Ulewicz and Radzyminska-Lenarcik, 2014;Ulewicz and Radzyminska-Lenarcik, 2015), machining (Radek et al, 2017a;Radek et al, 2017b;Pietraszek et al, 2017;Radek et al, 2018), even supported by an image analysis methods (Gadek et al, 2006;Gadek-Moszczak, 2017;Gadek-Moszczak and Matusiewicz, 2017), and especially in very environment-sensitive biotechnology (Skrzypczak- Pietraszek, 2016;Skrzypczak-Pietraszek et al, 2018a;Skrzypczak-Pietraszek et al, 2018b). It would be very interesting to include a fuzzy description of the problem (Fabis-Domagala et al, 2018;Filo et al, 2018), which allows you to express uncertainty about the process.…”

Section: Discussionmentioning

confidence: 99%

Tpm Safety Impact – Case Study

Maszke

2019

System Safety: Human - Technical Facility - Environment

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The global production companies of today are exposed to increasingly stronger pressure to implement new technologies, improve quality and decrease production costs. All this is related to ensuring a proper technical condition of machines and devices. This article presents the results of an analysis of the impact of implementation of TPM at the rolling mill on work safety. The number of near misses and accidents was used as a measure of the safety level.

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Application of Polymer and Supported Membranes with 1-Decyl-4-Methylimidazole for Pertraction of Transition Metal Ions

Cited by 24 publications

References 35 publications

Recovery of Zinc from Metallurgic Waste Sludges

Recovery of Zinc from Metallurgic Waste Sludges

The Smoothed Bootstrap Fine-Tuning

Tpm Safety Impact – Case Study

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