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Investigation of the Activation Conditions of Kutahya-Unye Bentonite for Removal of Nickel from Waste Water

Year 2019, Issue: 16, 229 - 234, 31.08.2019
https://doi.org/10.31590/ejosat.559920

Abstract

Any impurities above a certain concentration in water are harmful to the living spaces of living things. Therefore, the removal of pollutants in the water is very important in terms of maintaining the lives of living things. Nickel has an important place in metal coating due to its hardness, corrosion resistance and brilliance. Significant quantities of nickel are present in industrial and urban wastewater, particularly in steel enterprises and the electroplating industry waste waters. This study aims to investigate the effects of thermal and chemical activation conditions of Kutahya-Unye bentonite for removing nickel from wastewater. The bentonite samples were activated by two different methods: (i) thermal activation, (ii) acid activation. The operating range of the thermal activation studies was determined as 100, 300, 500, 700 0C. In the acid activation studies, the samples which were thermally activated, were entreated with 0.5 and 1 M HCl solutions. And, also acid activation was studied at different times to investigate the activation time on bentonite properties. The effects of temperature and acid treatment on calcium based-bentonite samples were investigated by Fourier Transform Infrared (FT-IR) between the region of 4000-400 cm−1. It was observed that increasing the activation temperature has increased the nickel amount at the waste water. The optimal activation time for nickel removal from wastewater was determined to be 120 minutes, which resulted in the use of activation temperature 700 0C and 0.5 M HCl acid. It was concluded that if we can increase the adsorption capacity and applicability, Ca-bentonite may be a promising clay for the removal of nickel in the wastewater stream.

References

  • Al-Shahrani S.S. (2012). Treatment of wastewater contaminated with nickel using Khulays activated bentonite, International Journal of Eng.& Techn., 12(4), 14-18.
  • Ertuğral F., Yakut H., Tabar E., Akkaya R., Demirci N., Zenginerler Z. (2015). Measurements of Radon Content in the Thermal Waters in Sakarya, Acta Physica Polonica A, 128(2), 251-252.
  • Madoni P. (2000). The acute toxicity of nickel to freshwater ciliates, Environmental Pollution, (109), 53-59.
  • Castrillo N., Mercado A., Volzone C. Sorption Water By Modified Bentonite, Procedia Materials Science, (8), 391-396.
  • Zong P., Wu X., Gou J., Lei X., Liu D., Deng H. (2015). Immobilization and recovery of uranium(VI) using Na-bentonite from aqueous medium: equilibrium, kinetics and thermodynamics studies, Journal of Molecular Liquids, (209), 358–366.
  • Vhahangwele M., Mugera G.W. (2015). The potential of ball-milled South African bentonite clay for attenuation of heavy metals from acidic wastewaters: Simultaneous sorption of Co2+, Cu2+, Ni2+, Pb2+, and Zn2+ ions, Journal of Env. Chem. Eng., 3, 2416-2425.
  • Yildiz N., Koroglu F., Calimli A. (2006). HDTMA-bentonitinin sentez ve karakterizasyonu, Journal of Eng&Arch.Fac. Eskişehir Osmangazi University, 19(2), 21-34.
  • Nigiz F.U., Unlu D., Hilmioglu N., (2017). Carbon Black Loaded Composite Poly(Dimethyl Siloxane) Membrane Preparation and Application for Hazardous Chemical Removal from Water, Acta Physica Polonica A, (132), 693-696.
  • Toor M., Jin B., Dai S., Vimonses V. (2015). Activating natural bentonite as a cost-effective adsorbent for removal of Congo-red in wastewater, Journal of Ind. and Eng. Chem., 21, 653–661.
  • Alver B.E., Alver O. (2012). Spectral characterization of non-clay minerals found in the clays (Central Anatolian-Turkey). Spectrochimica Acta Part A, 94, 331-333.
  • Pawar R.R., Lalhmunsiama Bajaj H.C., Lee S.M. 2(016). Clay catalysed rapid valorization of glycerol towards cyclic acetals and ketals, Journal of Industrial and Engineering Chemistry, 34, 213–223.
  • Maghni A., Ghelamallah M., Benghalem A. (2017). Sorptive Removal of Methyl Green from Aqueous Solutions using Activated Bentonite, Acta Physica Polonica A, 132, 448-450.
  • Bellifa A., Makhlouf M., Boumila Zh.H. (2016). Comparative Study of the Adsorption of Methyl Orange by Bentonite and Activated Carbon, Acta Physica Polonica A, 132, 466-468.
  • Tuğrul B., Erentürk S., Haciyakupoğlu S., Karatepe N., Altinsoy N., Baydoğan N., Baytaş F., Büyük B., Demir E., Gedik S. (2015). Kinetic and Thermodynamic Behavior of Selenium on Modified Bentonite and Activated Carbon using Radiotracer Technique, Acta Physica Polonica A, 128(2), 180-181.
  • Nones J., Riella H.G., Trentin A.G., Nones J. (2015). Effects of bentonite on different cell types: A brief review, App. Clay Sci., 105-106, 225-230.

Investigation of the Activation Conditions of Kutahya-Unye Bentonite for Removal of Nickel from Waste Water

Year 2019, Issue: 16, 229 - 234, 31.08.2019
https://doi.org/10.31590/ejosat.559920

Abstract

Any impurities above a certain concentration in
water are harmful to the living spaces of living things. Therefore, the removal
of pollutants in the water is very important in terms of maintaining the lives
of living things. Nickel has an important place in metal coating due to its
hardness, corrosion resistance and brilliance. Significant quantities of nickel
are present in industrial and urban wastewater, particularly in steel
enterprises and the electroplating industry waste waters.This study aims to investigate the effects of
thermal and chemical activation conditions of Kutahya-Unye bentonite for
removing nickel from wastewater. The bentonite samples were activated by two
different methods: (i) thermal activation, (ii) acid activation. The operating
range of the thermal activation studies were determined as 100, 300, 500, 700 0C.
In the acid activation studies, the samples which were thermally activated,
were entreated with 0.5 and 1 M HCl solutions. And, also acid activation was studied
at different times to investigate the activation time on bentonite properties.
The effect of temperature and acid treatment on calcium based-bentonite samples
were investigated by Fourier Transform Infrared (FT-IR) between the region of
4000-400 cm−1. It was observed that increasing temperature for
observing the thermal activation effect has increased the nickel removal
properties of bentonite. the optimal activation time for nickel removal from
wastewater was determined to be 120 minutes, which resulted in the use of
activation temperature 700 0C and 0.5 M HCl acid. It was concluded
that if we can increase the adsorption capacity and applicability, Ca-bentonite
may be a promising clay for the removal of nickel in the wastewater stream.

References

  • Al-Shahrani S.S. (2012). Treatment of wastewater contaminated with nickel using Khulays activated bentonite, International Journal of Eng.& Techn., 12(4), 14-18.
  • Ertuğral F., Yakut H., Tabar E., Akkaya R., Demirci N., Zenginerler Z. (2015). Measurements of Radon Content in the Thermal Waters in Sakarya, Acta Physica Polonica A, 128(2), 251-252.
  • Madoni P. (2000). The acute toxicity of nickel to freshwater ciliates, Environmental Pollution, (109), 53-59.
  • Castrillo N., Mercado A., Volzone C. Sorption Water By Modified Bentonite, Procedia Materials Science, (8), 391-396.
  • Zong P., Wu X., Gou J., Lei X., Liu D., Deng H. (2015). Immobilization and recovery of uranium(VI) using Na-bentonite from aqueous medium: equilibrium, kinetics and thermodynamics studies, Journal of Molecular Liquids, (209), 358–366.
  • Vhahangwele M., Mugera G.W. (2015). The potential of ball-milled South African bentonite clay for attenuation of heavy metals from acidic wastewaters: Simultaneous sorption of Co2+, Cu2+, Ni2+, Pb2+, and Zn2+ ions, Journal of Env. Chem. Eng., 3, 2416-2425.
  • Yildiz N., Koroglu F., Calimli A. (2006). HDTMA-bentonitinin sentez ve karakterizasyonu, Journal of Eng&Arch.Fac. Eskişehir Osmangazi University, 19(2), 21-34.
  • Nigiz F.U., Unlu D., Hilmioglu N., (2017). Carbon Black Loaded Composite Poly(Dimethyl Siloxane) Membrane Preparation and Application for Hazardous Chemical Removal from Water, Acta Physica Polonica A, (132), 693-696.
  • Toor M., Jin B., Dai S., Vimonses V. (2015). Activating natural bentonite as a cost-effective adsorbent for removal of Congo-red in wastewater, Journal of Ind. and Eng. Chem., 21, 653–661.
  • Alver B.E., Alver O. (2012). Spectral characterization of non-clay minerals found in the clays (Central Anatolian-Turkey). Spectrochimica Acta Part A, 94, 331-333.
  • Pawar R.R., Lalhmunsiama Bajaj H.C., Lee S.M. 2(016). Clay catalysed rapid valorization of glycerol towards cyclic acetals and ketals, Journal of Industrial and Engineering Chemistry, 34, 213–223.
  • Maghni A., Ghelamallah M., Benghalem A. (2017). Sorptive Removal of Methyl Green from Aqueous Solutions using Activated Bentonite, Acta Physica Polonica A, 132, 448-450.
  • Bellifa A., Makhlouf M., Boumila Zh.H. (2016). Comparative Study of the Adsorption of Methyl Orange by Bentonite and Activated Carbon, Acta Physica Polonica A, 132, 466-468.
  • Tuğrul B., Erentürk S., Haciyakupoğlu S., Karatepe N., Altinsoy N., Baydoğan N., Baytaş F., Büyük B., Demir E., Gedik S. (2015). Kinetic and Thermodynamic Behavior of Selenium on Modified Bentonite and Activated Carbon using Radiotracer Technique, Acta Physica Polonica A, 128(2), 180-181.
  • Nones J., Riella H.G., Trentin A.G., Nones J. (2015). Effects of bentonite on different cell types: A brief review, App. Clay Sci., 105-106, 225-230.
There are 15 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Meltem Yıldız 0000-0002-9442-4992

Publication Date August 31, 2019
Published in Issue Year 2019 Issue: 16

Cite

APA Yıldız, M. (2019). Investigation of the Activation Conditions of Kutahya-Unye Bentonite for Removal of Nickel from Waste Water. Avrupa Bilim Ve Teknoloji Dergisi(16), 229-234. https://doi.org/10.31590/ejosat.559920