Your search keyword '"Pavel Raschman"' showing total 21 results

1. Determination of the kinetic parameters of leaching from experimental data using the non-porous shrinking particle model: Effect of error propagation

Author

Pavel Raschman, Ľuboš Popovič, and Gabriel Sučik

Subjects

Materials Chemistry, Metals and Alloys, Industrial and Manufacturing Engineering

Published

2023

2. Reactive, Sparingly Soluble Calcined Magnesia, Tailor-Made as the Reactive Material for Heavy Metal Removal from Contaminated Groundwater Using Permeable Reactive Barrier

Author

Pavel Raschman, Alena Fedoročková, Agnesa Doráková, Gabriel Sučik, and Mária Švandová

Subjects

Aqueous solution, permeable reactive barrier (PRB), Chemistry, Magnesium, caustic calcined magnesia (CCM), chemistry.chemical_element, Geology, engineering.material, heavy metal, precipitation, Geotechnical Engineering and Engineering Geology, Mineralogy, law.invention, chemistry.chemical_compound, Chemical engineering, law, Permeable reactive barrier, groundwater, engineering, Calcination, Solubility, Magnesite, Reactive material, Lime, QE351-399.2

Abstract

A laboratory method was designed and verified that allows for the testing of alkaline, magnesite-based reactive materials for permeable reactive barriers (PRBs) to remove heavy metals from contaminated groundwater. It was found that caustic calcined magnesia (CCM) with high reactivity and low solubility to remove Cu2+, Zn2+, Ni2+, and Mn2+ cations from mixed aqueous solutions can be prepared by calcination at a suitable temperature and residence time. Regarding the solubility of both the reactive material itself and the precipitates formed, the CCM should contain just a limited content of lime. One way is the calcination of a ferroan magnesite at temperatures above 1000 °C. However, the decrease in pH is accompanied by lower efficiency, attributed to the solid-phase reactions of free lime. A different way is the calcination of magnesite under the conditions when CaCO3 is not thermally decomposed. The virtually complete removal of the heavy metals from the model solution was achieved using the CCM characterised by the fraction of carbonates decomposed of approximately 80% and with the highest specific surface area. CCM calcined at higher temperatures could also be used, but this would be associated with higher consumption of crude magnesite. Under the conditions considered in the present work, the product obtained by the calcination at 750 °C for 3 h appeared to be optimal. The full heavy metal removal was observed in this case using less magnesite, and, moreover, at a lower temperature (resulting, therefore, in a lower consumption of energy for the calcination and material handling).

Published

2021

3. Influence of Different Mineral Precursors on the Properties of Fly Ash Based Alkali-Activated Mortars

Author

Matej Špak and Pavel Raschman

Subjects

Materials science, Mineral, Mechanical Engineering, Metallurgy, 0211 other engineering and technologies, 02 engineering and technology, 021001 nanoscience & nanotechnology, Mechanics of Materials, Fly ash, 021105 building & construction, Alkali activated, General Materials Science, Mortar, 0210 nano-technology

Abstract

Alkali-activated materials based on fly ash are widely developed and also produced on the present. Some of fly ashes are not suitable for production of alkali-activated materials because of their inconvenient chemical composition. Alumina-silicates are the most important components that are needed to accomplish the successful reaction. The proper content of amorphous phase of alumina-silicates and its proportion as well should be provided for the final composition of alkali-activated materials. The influence of pure aluminum oxide powder as well as raw milled natural perlite on mechanical properties and durability of alkali-activated mortars was investigated. These minerals were used as partial replacement of fly ash coming from black coal combustion. In addition, the mortars were prepared by using different alkali activators.

Published

2018

4. Utilization of Chrysotile-Type Tailings for Synthesis of High-Grade Silica by Controlled Precipitation

Author

Pavel Raschman, J. Kavuličova, Alena Fedoročková, D. Ivanova, and Gabriel Sučik

Subjects

Hydrometallurgy, Silicon, Chemistry, Mechanical Engineering, Metallurgy, chemistry.chemical_element, Hydrochloric acid, 02 engineering and technology, General Chemistry, Geotechnical Engineering and Engineering Geology, Tailings, 020501 mining & metallurgy, chemistry.chemical_compound, 0205 materials engineering, Chemical engineering, Impurity, Chrysotile, Economic Geology, Leaching (metallurgy), Sodium metasilicate

Abstract

This study demonstrates an efficient synthesis of highly reactive silica using hydrometallurgical processing of serpentinite tailings. Proposed process uses two-stage (acid and alkaline) leaching of serpentinite tailings and precipitation of silica from the sodium metasilicate solution using hydrochloric acid. The alkaline leaching and the effect of impurities on the precipitation of amorphous silica under the conditions of maximum sol stability were examined in detail. The proposed route is technologically advantageous because the product did not contain residues of the original raw serpentinite and was characterized by high purity (99.4 wt. % SiO2), large specific area (541 m2 g–1), and consistent quality. Moreover, less sensitivity to the presence of impurities and longer gelation times, offering a longer time period for manipulating the product in the final stages of the process, were achieved. The total yield of silicon in the overall process was 90–91%.

Published

2016

5. Generalized shrinking particle model of leaching: Effect of the order of surface chemical reaction, liquid-to-solid ratio and non-ideal behaviour of the liquid phase

Author

Ľuboš Popovič, Gabriel Sučik, Jan Spisak, Pavel Raschman, and Alena Fedoročková

Subjects

Activity coefficient, Order of reaction, Chemistry, 0211 other engineering and technologies, Metals and Alloys, Thermodynamics, Hydrochloric acid, 02 engineering and technology, Kinetic energy, Chemical reaction, Industrial and Manufacturing Engineering, chemistry.chemical_compound, 020401 chemical engineering, Materials Chemistry, Leaching (metallurgy), 0204 chemical engineering, Stoichiometry, 021102 mining & metallurgy, Magnesite

Abstract

A generalized non-porous shrinking particle model (G NSPM) of leaching has been verified and used for numerical simulations. Unlike the commonly used “simple” non-porous shrinking particle model (S NSPM), the G NSPM assumes n−th order chemical reaction, the influence of the L/S ratio and non-ideal behaviour of the leach solution. The leaching of dead-burned magnesite with hydrochloric acid has been chosen to verify the proposed mathematical model, as the (apparent) reaction order for HCl, n, may be both positive and negative, depending on the HCl concentration. Comparison of the simulations with experiments revealed that the S NSPM does not reflect the qualitatively different leaching behaviour at positive and negative n, especially at near-to-stoichiometric HCl/MgO ratio. The G NSPM reflects the effect of n not only qualitatively, but also with acceptable accuracy. At the stoichiometric HCl/MgO ratio, the mean squared error of the predictions obtained using the S NSPM was 100–130 rel. % as compared to those provided by the G NSPM. The common effect of the reaction order, n, L/S ratio (represented by the reduced HCl/MgO molar ratio, ϕ) and non-ideal behaviour of the acid were studied in detail by means of numerical simulations. The values of parameters n and ϕ can alter the leaching behaviour qualitatively. In contrast, the activity coefficient of HCl only slightly modifies the shape of the kinetic curves, but does not change the overall picture. The error of the time for complete conversion of MgO calculated using the S NSPM can reach more than 100 rel. % for n = − 0.5 and even up to several hundred rel. % for n = 1, because the conversion vs. time curves predicted by the G NSPM are markedly skewed towards longer leaching times.

Published

2020

6. Activated Zeolite and Magnesite as Potential Reactive Materials for Passive Acidic Groundwater Treatment Technology

Author

Pavel Raschman, Alena Fedoročková, and Gabriel Sučik

Subjects

Materials science, Precipitation (chemistry), Environmental remediation, Inorganic chemistry, chemistry.chemical_element, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, chemistry.chemical_compound, Chromium, Adsorption, chemistry, General Materials Science, Solubility, Groundwater, Magnesite, Reactive material

Abstract

Permeable reactive barriers (PRBs) are passive, in-situ remediation systems that comprise the filtration of a contaminated groundwater through a reactive media able to degrade, adsorb or precipitate the pollutants. Selection of the reactive media depends on the nature of the contamination. While the majority of PRBs are used to treat groundwater contaminated with chlorinated volatile organic compounds or acid mine drainage, the present study is focused on heavy metals, namely Fe, Al, Cu, Ni, Zn, Mn and As. To remove such inorganic pollutants, four methodologies are usually implemented: a) redox reaction, b) adsorption and ion exchange, c) biological treatment (e.g. metal sulphides precipitation) and d) pH control and precipitation. The present paper deals with the last methodology in which an adjustment of pH by alkalinity-generating materials leads to the precipitation of metal hydroxides and the decrease in the concentration of dissolved species. As the solubility of metals depends on their valence, redox-potential, concentrations and kinetics of reaction, the target pH varies with respect to the considered metal. A pH of about 10 allows the precipitation of hydroxides of divalent ions (zinc, manganese, copper, lead, nickel, cobalt and cadmium), while a pH of around 6-7 is adapted to trivalent ions (iron, aluminium and chromium). However, the accumulation of precipitates in the pore spaces can cause clogging of the pores, hence decrease the porosity and hydraulic conductivity of the reactive media and alter its efficiency. To validate this assumption, the neutralizing ability of alkaline materials such as activated zeolite and magnesite were examined in a test column by monitoring the resultant pH with attention to impact of precipitates on the hydraulic properties of reactive materials. Based on the test results, both materialls are considered suitable to remove the groundwater contaminants with high efficiency (up to 99%) and suitable grain size to encourage flow through the PRB.

Published

2015

7. Mechanical Properties of Mortars Prepared by Alkali Activated Fly Ash Coming from Different Production Batches

Author

Matej Špak and Pavel Raschman

Subjects

Materials science, business.industry, Metallurgy, Raw material, Condensed Matter Physics, Combustion, Atomic and Molecular Physics, and Optics, Distilled water, Fly ash, General Materials Science, Coal, Leaching (metallurgy), Composite material, Mortar, business, Chemical composition

Abstract

Fly ash is a well utilizable secondary raw material for the production of alkali activated construction materials. It is a significant alumina-silicates source suitable for the chemical reaction resulting in hardened composites. Physical and chemical properties of fly ashes as a co-product of coal burning mainly depend on characteristics of coal, burning temperature and combustion conditions. High variability of the properties of fly ash causes an uncertainty in the properties of alkali activated mortars. Time behaviour of the composition of the fly ash produced in a heating plant located in Košice, Slovakia as well as leaching behaviour of both alumina and silica from particular batches during one-year period was documented. Leaching tests were carried out using the distilled water and alkali solutions with three different concentrations. Both compressive and tensile strengths of alkali activated mortars were measured, and the correlation between the mechanical properties of hardened mortars and the chemical composition of fly ashes as well as their leaching characteristics was investigated.

Published

2015

8. REMOVAL OF HEAVY METALS FROM WASTEWATER USING CAUSTIC CALCINED MAGNESIA

Author

Alena Fedoročková, Pavel Raschman, Mária Švandová, Agnesa Doráková, and Gabriel Sučik

Subjects

lcsh:TN1-997, Cement, Materials science, Environmental remediation, Magnesium, removal, Metallurgy, Metals and Alloys, chemistry.chemical_element, Zinc, precipitation, engineering.material, chemistry.chemical_compound, chemistry, Wastewater, engineering, caustic calcined magnesia, heavy metals, lcsh:Mining engineering. Metallurgy, Magnesite, Lime, Reactive material

Abstract

Slovakia holds 4th to 5th position in the world with respect to the supplies and mining output of magnesite. The most important product of natural magnesite processing is magnesia. While dead-burnt magnesia is used for producing basic refractory materials for metallurgy and cement industry, caustic calcined magnesia (CCM) founds new applications in industries, agriculture and environment protection. Use of CCM, due to its alkaline nature, as a reactive material for remediation of wastewaters, can provide all advantages of methods based on neutralization (pH adjustment) by lime. In this study, CCM was experimentally tested as a reactive material for the removal of cations Cu2+, Zn2+ and Ni2+ from wastewaters. The effects of chemical composition of model wastewaters tested and water-to-CCM weight ratio were investigated. The results have shown that CCM is a suitable material for the removal of heavy metals, especially copper, zinc and nickel, from acid wastewaters. The efficiency of cation removal up to 100% has been observed.

Published

2015

9. Characteristics of amorphous silica prepared from serpentinite using various acidifying agents

Author

Gabriel Sučik, Alena Fedoročková, Beatrice Plešingerová, Agnesa Doráková, and Pavel Raschman

Subjects

Silica gel, Inorganic chemistry, Hydrochloric acid, Geotechnical Engineering and Engineering Geology, Silicate, chemistry.chemical_compound, chemistry, Pulmonary surfactant, Geochemistry and Petrology, Specific surface area, Leaching (metallurgy), Mesoporous material, Stoichiometry, Nuclear chemistry

Abstract

This paper examines the effect of the nature of the precipitating agent (HCl, CO 2 and (NH 4 ) 2 CO 3 ) on the surface area of the resulting silica powders synthesized from serpentinite after its leaching in hydrochloric acid. In order to prepare a product consisting of small discrete particles polymerized into three-dimensional networks without using additives (surfactant and/or flocculant), synthesis from nearly-saturated sodium metasilicate solution at laboratory temperature under alkaline and acid-set conditions was applied in the present work. In highly acidic solution (e.g. at significant stochiometric excess of hydrochloric acid over the silicate) a regular density xerogel with a high specific surface area (541 m 2 g − 1 ) was achieved. Through synthesis of silica gel by acidification using CO 2 and (NH 4 ) 2 CO 3 , the values 392 m 2 g − 1 and 414 m 2 g − 1 respectively of the specific surface area were obtained. The microporosity of silica samples precipitated by HCl was confirmed by t -methods and α -methods, whereas powders prepared using CO 2 and (NH 4 ) 2 CO 3 were identified as being mesoporous. The mesopore size distribution calculated using the BJH method and DFT model shifted with rising pore diameter in the following order: silica precipitated by HCl, (NH 4 ) 2 CO 3 and CO 2 .

Published

2014

10. Non-porous shrinking particle model of leaching at low liquid-to-solid ratio

Author

Maryna Kyslytsyna, Ľuboš Popovič, Pavel Raschman, Alena Fedoročková, and Gabriel Sučik

Subjects

Order of reaction, Mathematical model, 0211 other engineering and technologies, Metals and Alloys, Thermodynamics, Hydrochloric acid, 02 engineering and technology, Activation energy, Chemical reaction, Industrial and Manufacturing Engineering, chemistry.chemical_compound, 020401 chemical engineering, chemistry, Materials Chemistry, Leaching (metallurgy), 0204 chemical engineering, Porosity, Stoichiometry, 021102 mining & metallurgy

Abstract

A generalized non-porous shrinking particle model (NSPM) of leaching is proposed, which - unlike commonly used “simplified” mathematical models - takes into account the influence of the L/S ratio (by means of the so-called reduced A/B molar ratio, ϕ, which indicates how many times the leaching agent (A)-to-valuable substance (B) molar ratio actually used exceeds its stoichiometric value) and non-ideal behaviour of concentrated lixiviants. Moreover, n-th order chemical reaction with power-law kinetics is considered, which makes determination of the rate-determining step of the overall process more reliable. Correlation between the proposed model and experiment was tested using the hydrochloric acid leaching of dead-burned magnesite, which provides the opportunity to experimentally verify how the mathematical model fits the leaching data for both the positive and negative reaction order. Calculated values of the reaction order for HCl, n, different from unity (n = 0.28 and n = −0.23 obtained for low (0.20–1.03 M) and high HCl concentrations (2.06–3.83 M), respectively), together with relatively high values of the activation energy (57.5 J mol−1 and 56.6 J mol−1) indicate that the leaching rate is controlled by the intrinsic chemical reaction under the conditions considered in the present work. Simulations made using the calculated values of the parameters have shown that the proposed generalized NSPM model clearly reflects two most important experimental facts: (a) L/S ratio affects the leaching process; and (b) qualitatively different leaching behaviour has been observed for the positive and negative reaction order. Unlike the simplified NSPM model, the generalized model describes the leaching process quantitatively in the whole range of the parameter ϕ, for both n > 0 and n

Published

2019

11. Thermal activation of serpentine prior to acid leaching

Author

Alena Fedoročková, Gabriel Sučik, and Pavel Raschman

Subjects

Magnesium, Inorganic chemistry, technology, industry, and agriculture, Metals and Alloys, chemistry.chemical_element, Hydrochloric acid, Industrial and Manufacturing Engineering, law.invention, Corrosion, Acetic acid, chemistry.chemical_compound, chemistry, law, Materials Chemistry, Calcination, Ammonium chloride, Leaching (metallurgy), Dissolution

Abstract

The overall process for producing pure magnesium compounds from serpentinite usually starts with acid leaching. However, if serpentinite is calcined prior to leaching, not only faster magnesium dissolution is achieved, but use of thermally activated serpentine also significantly reduces the problems relating to corrosion of the leaching equipment, because less aggressive leaching agents can be used and/or lower leaching temperatures and pressures can be applied. This paper compares how calcination influences the dissolution behaviour of magnesium in solutions of hydrochloric acid, acetic acid and ammonium chloride. Fine-grained serpentinite, characterized by the extent of serpentine decomposition between 85 and 95%, displayed the highest reactivity. The initial magnesium dissolution rate of calcined serpentinite was up to 30-, 125- and 165-times higher as compared to that of uncalcined serpentinite in solutions of hydrochloric acid, acetic acid and ammonium chloride, respectively, under identical reaction conditions.

Published

2013

12. Dissolution of magnesium from calcined serpentinite in hydrochloric acid

Author

Alena Fedoročková, Martin Hreus, Gabriel Sučik, and Pavel Raschman

Subjects

Reaction conditions, Chemistry, Magnesium, Mechanical Engineering, Metallurgy, chemistry.chemical_element, Hydrochloric acid, General Chemistry, Geotechnical Engineering and Engineering Geology, Corrosion, law.invention, chemistry.chemical_compound, Chemical engineering, Control and Systems Engineering, law, Calcination, Leaching (metallurgy), Dissolution

Abstract

In the production of pure magnesium compounds from serpentinite, acid leaching is usually the first stage of the overall process. However, faster magnesium dissolution can be achieved and the size of a potential leaching reactor can be reduced if serpentinite is calcined prior to leaching. Moreover, use of calcined serpentinite can reduce problems relating to corrosion of the reactor (lower leaching temperatures and pressures can be applied) and foam formation (chemically bonded water, which forms bubbles when released in the reactor, can be removed by calcining). This paper examines how calcination temperature and time influence the amount of magnesium dissolved during the initial period of leaching of calcined serpentine in hydrochloric acid. Fine-grained serpentinite calcined between 640 °C and 700 °C displayed the highest reactivity. The fraction of magnesium dissolved was up to 30-times higher as compared to leaching of uncalcined serpentine under identical reaction conditions.

Published

2012

13. Kinetics of leaching of stibnite by mixed Na2S and NaOH solutions

Author

Pavel Raschman and Emília Sminčáková

Subjects

Order of reaction, Chemistry, Inorganic chemistry, Kinetics, Metals and Alloys, Analytical chemistry, Activation energy, Kinetic energy, Chemical reaction, Industrial and Manufacturing Engineering, Materials Chemistry, Particle size, Leaching (metallurgy), Stibnite

Abstract

The kinetics of the reaction between particulate stibnite and mixed Na2S + NaOH solutions were studied. The effects of the concentration of the Na2S and NaOH (from 0.5% to 2.0%), temperature (from 292 K to 327 K) and particle size (from 40 μm to 500 μm) were investigated. The results are presented in terms of the shrinking (non-reacted) core model and the shrinking porous-particle model. The apparent activation energy was approximately 44 kJ mol− 1, and the apparent reaction order for Na2S varied from 1.4 to 1.7. The calculated values of the kinetic parameters indicate that the leaching process is controlled by both the intrinsic chemical reaction between Sb2S3 and Na2S at the liquid/solid interface and pore diffusion.

Published

2012

14. Leaching of Natural Stibnite Using Na2S and NaOH Solutions

Author

Pavel Raschman and Emília Sminčáková

Subjects

Order of reaction, Antimony, Chemistry, chemistry.chemical_element, Particle size, Activation energy, Leaching (metallurgy), Raw material, Stibnite, Chemical reaction, Nuclear chemistry

Abstract

First stage of the hydrometallurgical production of antimony is leaching of the raw material that contains antimonybearing mineral. The raw material can be ore or concentrate. Leaching can be carried out either in alkaline (Na2S+NaOH; NaOH) or acid (HCl; H2SO4; HF) solutions. In order to achieve good antimony recovery it is essential to leach the raw material under optimum conditions.Kinetics of the reaction between particulate stibnite and mixed Na2S + NaOH solutions were studied. The effects of concentrations of Na2S and NaOH, temperature, particle size and liquid-to-solid ratio were investigated. It was observed that the rate of leaching of stibnite: a) increased with an increase in both Na2S and NaOH concentration (from 0.5 wt. % to 2.0 wt. %), and temperature (from 292 K to 327 K); b) reached its maximum at Na2S: NaOH weight ratio equal to 1:1; c) decreased with an increase in particle size (from 40 μm to 500 μm) and L/S ratio (from 10 to 100). The results are presented in terms of the shrinking (nonreacted) core model and shrinking porous-particle model. Apparent activation energy is approximately 44 kJ mol and the apparent reaction order for Na2S varies from 1.4 to 1.7. Calculated values of the kinetic parameters indicate that the leaching process is controlled by both intrinsic chemical reaction between Sb2S3 and Na2S at the liquid/solid interface, and pore diffusion. Keywords-Stibnite, Kinetics, Alkaline leaching, Activation energy, Order of reaction

Published

2011

15. Effects of pH and acid anions on the dissolution kinetics of MgO

Author

Alena Fedoročková and Pavel Raschman

Subjects

Order of reaction, General Chemical Engineering, Kinetics, Inorganic chemistry, Protonation, General Chemistry, Activation energy, Chemical reaction, Industrial and Manufacturing Engineering, Ion, chemistry.chemical_compound, chemistry, Environmental Chemistry, Physical chemistry, Hydroxide, Dissolution

Abstract

The kinetics of the dissolution of particulate sintered polycrystalline MgO under advanced kinetic regime conditions were investigated, with special regard to the effects of concentration of H+ ions, temperature and the type of the inorganic acid used (HCl, HNO3 and H2SO4). It was observed that the rate of chemical dissolution of MgO accelerated with increase in both concentration of H+ ions (from 10−4 to 10−2 M) and temperature (from 25 to 60 °C). The overall process of MgO dissolution was found to be controlled by the surface chemical reaction of MgO with H+ ions. The presented values of the reaction order for H+ ions are consistent, allowing for experimental error, with current kinetic theories and most other experiments. However, the rate-controlling step could not be assigned unambiguously, because the same value of the reaction order for H+ ions can be predicted by various theories for different rate-determining steps. Measured values of the reaction order for H+ ions are indicative that the rate is limited by the second protonation reaction, i.e. the slow reaction of surface hydroxide with a second proton. Though the reaction order for H+ ions seems not to be affected by the type of acid used, the apparent activation energy changes in the order HCl ≤ HNO3

Published

2008

16. Dissolution kinetics of periclase in dilute hydrochloric acid

Author

Pavel Raschman and Alena Fedoročková

Subjects

Order of reaction, Magnesium, Applied Mathematics, General Chemical Engineering, Kinetics, Analytical chemistry, chemistry.chemical_element, Hydrochloric acid, General Chemistry, Activation energy, Industrial and Manufacturing Engineering, Ion, chemistry.chemical_compound, chemistry, Physical chemistry, Particle size, Dissolution

Abstract

Kinetics of the reaction between particulate sintered polycrystalline MgO and dilute hydrochloric acid were studied. The effects of process parameters, i.e., concentrations of H+ and Mg2+ ions, temperature and particle size were investigated. It was observed that the rate of chemical dissolution of MgO: (a) increased with increase in both HCl concentration (from 10-4 to 10-2M) and temperature (from 25 to 60∘C); (b) decreased with increase in particle size (from 63 to 355μm); (c) was not affected by Mg2+ ion concentration. Thorough comparison of our results with those published by other authors revealed that the “initial” stage of MgO dissolution has never been observed under the conditions of the experiments in the present work. It was concluded that the initial stage of MgO dissolution was probably too short to be detected and just the “advanced” kinetic regime was investigated. Values of the kinetic parameters were calculated, and apparent activation energy between 93 and 101kJmol-1 and the reaction order for H+ ions from 0.41 to 0.76 were obtained. The presented values of the reaction order for H+ ions are consistent, allowing for experimental error, with current kinetic theories and most of other experiments. However, the rate-controlling step could not be assigned unambiguously, because the same value of the reaction order for H+ ions can be predicted by various theories for different rate-determining steps. The broad variety of likely rate-determining steps indicates some intrinsic diversity in current kinetic models.

Published

2008

17. Changes in the surface morphology of magnesia particles due to the leaching using hydrochloric acid

Author

Jaroslav Briančin, Gabriel Sučik, Pavel Raschman, and Alena Fedoročková

Subjects

Morphology, lcsh:TN1-997, lcsh:Geology, Kinetics, Magnesia, lcsh:QE1-996.5, Leaching, Hydrochloric acid, Non-porous shrinking particle model (NSPM), lcsh:Mining engineering. Metallurgy

Abstract

Thorough kinetic analysis of the magnesia leaching based on measuring the changes in lixiviant composition revealed that there are differences between the actual leaching behaviour and predictions obtained using the non-porous shrinking particle model (NSPM). A detailed study of the morphology of the solid during the leaching process using SEM showed that observed deviations from the NSPM model depend on the particle size; chemical (mineralogical) composition and the polycrystalline nature of magnesia.

Published

2007

18. Dissolution of periclase in excess of hydrochloric acid: Study of inhibiting effect of acid concentration on the dissolution rate

Author

Alena Fedoročková and Pavel Raschman

Subjects

Order of reaction, Chemistry, Magnesium, General Chemical Engineering, Inorganic chemistry, Kinetics, chemistry.chemical_element, Hydrochloric acid, General Chemistry, Activation energy, Chemical reaction, Industrial and Manufacturing Engineering, chemistry.chemical_compound, Environmental Chemistry, Physical chemistry, Particle size, Dissolution

Abstract

Kinetics of the dissolution of particulate polycrystalline MgO in excess of hydrochloric acid were investigated, with special regard to the effect of activity of H + ions, temperature and particle size. The results are presented in terms of the shrinking particle model. The overall process is controlled by the chemical reaction of MgO with H + ions at the liquid–solid interface. The apparent activation energy was 58 kJ mol −1 . Acid concentration (from 0.5 M to 5.1 M) was surprisingly found to have a decelerating effect on the dissolution rate of MgO, resulting in negative values of reaction order for H + ions (from −0.16 to −0.18). We conclude that the regime studied here, characterised by decrease in the dissolution rate of MgO with an increase in H + activity, occurs under far from mass-transfer control conditions in the solutions with low Mg 2+ :H + molar ratio.

Published

2006

19. Study of inhibiting effect of acid concentration on the dissolution rate of magnesium oxide during the leaching of dead-burned magnesite

Author

Alena Fedoročková and Pavel Raschman

Subjects

Order of reaction, Hydrometallurgy, Chemistry, Magnesium, Inorganic chemistry, Metals and Alloys, Concentration effect, chemistry.chemical_element, Chemical reaction, Industrial and Manufacturing Engineering, chemistry.chemical_compound, Materials Chemistry, Leaching (metallurgy), Dissolution, Magnesite

Abstract

Kinetics of the reaction between dead-burned magnesite and hydrochloric acid were investigated with special regard to the rate of chemical dissolution of MgO. The effect of process parameters viz. temperature, activity of H + ions, and particle size and composition of the solid was investigated. The dissolution of MgO was strongly affected by temperature (from 45 to 75 °C) and particle size (from 63 to 355 μm), while the effect of composition of the solid was weak. The results are presented in terms of the shrinking particle model. The dissolution of MgO is controlled by the chemical reaction of MgO with H + ions at the liquid–solid interface. The apparent activation energy was 58–64 kJ mol −1 . Acid concentration (from 1.0 to 5.3 M) was surprisingly found to have a decelerating effect on the dissolution rate of MgO, resulting in negative values of reaction order for H + ions (from −0.1 to −0.2). We conclude that the leaching behaviour studied here corresponds to the regime referred to in the literature as the “initial stage of dissolution of MgO”. This regime, during which the dissolution rate increases rapidly despite a decrease in H + concentration, is characterised by far from mass-transfer control conditions, which was exactly the situation analysed in the present work.

Published

2004

20. Leaching of calcined magnesite using ammonium chloride at constant pH

Author

Pavel Raschman

Subjects

Lixiviant, Hydrometallurgy, Magnesium, Inorganic chemistry, Metals and Alloys, Lessivage, chemistry.chemical_element, Industrial and Manufacturing Engineering, chemistry.chemical_compound, chemistry, Materials Chemistry, Particle size, Leaching (metallurgy), Dissolution, Magnesite

Abstract

The leaching of calcined magnesite using ammonium chloride has been tested in a pH-stat to ascertain the effect of process parameters viz. temperature, concentration of NH 4 Cl, pH, and particle size and reactivity of the solid. The main purpose of the approach adopted was to keep the lixiviant composition constant during individual measurements. A simple mathematical model has been used to describe the dissolution of magnesium during leaching and to analyse the kinetic data. The apparent activation energy of leaching was found to depend on the particle size of the solid — the values 57.8 and 48.5 kJ mol −1 were obtained for the leaching of particles of −100+90 and −180+160 μm, respectively. It was concluded that the leaching process is controlled by the chemical reaction of MgO with H + ions at the liquid–solid interface and by pore diffusion.

Published

2000

21. Management of the Quality of Teaching at Universities - a course for teachers at the Technical University of Kosice developed within the operational programme 'Education'

Author

Michal Blasko and Pavel Raschman

Subjects

Medical education, Engineering, Quality management, Quality of teaching, business.industry, Quality education, Technical university, ComputingMilieux_COMPUTERSANDEDUCATION, Computer aided instruction, business, Course (navigation), Professional skills

Abstract

The aim of this contribution is to provide the basic information concerning the course “Management of the Quality of Teaching at Universities”. This course was prepared within the framework of the operational programme Education “Package of Innovative Elements for the Transformation of Education at TUKE” (code ITMS 26110230018). In recent weeks we finished the implementation of the pilot course that was focused to the development of professional skills of teachers and to the enhancement of quality education at TUKE (Technical University of Kosice).

Published

2012