Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2019, Cilt: 2 Sayı: 1, 1 - 7, 30.06.2019

Öz

Kaynakça

  • 1. American Chemistry Council. "Chlorine Chemistry Division : Ferric Chloride: Clearing the stuff out of water." americanchemistry.com : Chemistry is essential2living - The American Chemistry Council N.p., Sept. 2003. Web. 20 Sept. 2010.
  • 2. Citulski, Joel, Khosrow Farahbakhsh, and Fraser Kent. "Optimization of phosphorus removal in secondary effluent using immersed ultrafiltration membranes with in-line coagulant pretreatment — implications for advanced water treatment and reuse applications." Journal of Environmental Engineering and Science 36 (2009): 1272-1283.
  • 3. Stumm, W., and J.J. Morgan. 1962. Chemical Aspects of Coagulation. Jour. AWWA, 54(8):971-994. 4. Stumm, W., and C.R. O’ Melia. 1968. Stoichiometry of Coagulation. Jour. AWWA, 60(5):514-539.
  • 5. Black, A.P. 1967. Electrokinetic Characteristics of Hydrous Oxies of Aluminum and Iron. In Principles and Application of Water Chemistry. Edited by S.D. Faust and J.V. Hunter. New York: John Wiley and Sons.
  • 6. Johnson, P.N., and A. Amirtharajah. 1983. Ferric Chloride and Alum as Single and Dual Coagulants. Jour. AWWA, 75(5):232-239.
  • 7. Matijevic, E, and G.E. Janauer. 1966. Coagulation and Reversal of Charge of Lyophilic Colloids by Hydrolyzed Metal Ions. II. Ferric Nitrate. J. Colloid Interface Sci., 21(2):197-223.
  • 8. Phosphorous Removal from Wastewater. Water Treatment and Purification - Lenntech. Lenntech, 2009. Web. 1 Mar. 2010. <http://www.lenntech.com/phosphorous-removal.htm>.
  • 9. Tang, H-X. and Stumm, W., 1987. The Coagulating Behaviors of Fe(III) Polymeric Species—I and II. Water Research, 21(1):115-128.
  • 10. California Water Technologies. “Phosphorus Removal." California Water Technologies. N.p., 2004. Web. 2 Oct. 2010.
  • 11. Dejian Ding, Hao Peng, Wangjun Peng, Yaowei Yu, Guangxin Wu, Jieyu Zhang, 2017. Isothermal hydrogen reduction of oxide scale on hot-rolled steel strip in 30 pct H2-N2 atmosphere. International Journal of Hydrogen Energy, 42, 29921-29928.
  • 12. West,G.D., Birosca, S., Higginson, R.L., J., 2005. Phase determination and microstructure of oxide scales formed on steel at high temperature. Jour. Microsc. 217, 122–129. https://doi.org/10.1111/j.1365-2818.2005.01409.x
  • 13. Chen, R.Y., Yuen, W.Y.D. Review of the High-Temperature Oxidation of Iron and Carbon Steels in Air or Oxygen. Oxidation of Metal, 59, 433–468.
  • 14. Weihua, S. Tieu, A.K., Zhengyi, J.,Cheng, L., Zhu, H., 2003. Surface characteristics of oxide scale in hot strip rolling. Journal of Materials Processing Technology, 140(1-3):76-83. DOI: 10.1016/S0924-0136(03)00823-9.
  • 15. Higginson, R.L., Roebuck, B, Palmiere EJ., 2002. Texture development in oxide scales on steel substrates. Scripta Materialia, 47:337–342. doi:10.1016/S1359-6462(02)00154-9.
  • 16. Barrie, J and Hallbergs, K. B., 2005. Acid mine drainage remediation options: a review. Science of the Total Environment, 338, 3-14.
  • 17. Magnone E., Kim S. D., Park J. H., 2018. A systematic study of the iron hydroxide-based adsorbent for removal of hydrogen sulphide from biogas. Microporous and Mesoporous Materials 270, 155–160.
  • 18. Nisachon, N. K., Sirilak, Y., Thanasak, N., 2018. Adhesion behaviour of scales on hot-rolled steel strips produced from continuous casting slabs. Materials Today: Proceedings, 5,9359–9367 (The 10th Thailand International Metallurgy Conference (The 10th TIMETC)).
  • 19. Guan C, Li J, Tan N, He YQ, Zhang SG., 2014. Reduction of oxide scale on hot-rolled steel by hydrogen at low temperature. Int J Hydrogen Energy, 39:15116e24.
  • 20. Shi J, Wand DR, He YD, Qi HB, Wei G., 2008. Reduction of oxide scale on hot-rolled strip steels by carbon monoxide. Mater Lett., 62:3500e2.
  • 21. Yang,Y.U., Chang WANG., Lin WANG., Jin CHEN, Ya-jun HUI, Chang-ku SUN, 2015. Combination Effect of Si and P on Tertiary Scale Characteristic of Hot Rolled Strip Mater. Journal of Iron and Steel Research, International, 22, 3, 232-237.
  • 22. Nilsonthi, T., 2018. Oxidation behaviour of hot-rolled Si-containing steel in water vapour between 600 and 900°C. Materials Today: Proceedings 5,9552–9559 (The 10th Thailand International Metallurgy Conference (The 10th TIMETC)).
  • 23. Ghosh, A. Chatterjee, A., 2008. Ironmaking and steelmaking: Theory and practice, Prentice Hall of India, New Delhi, India.
  • 24. Hiroaki Ichikawa, Shogo Sato, Nobuyuki Iwata, and Hiroshi Yamamoto, 2014. Synthesis and characterization of intercalated few-layer graphenes. Japanese Journal of Applied Physics 53, 02BD04.
  • 25. LingFeng Dai, Yuan He, Xiang Huang, Xin Cuia Shihui Wanga Dongtao Ge, Nifang Zhao, Yue Li, Yanan Sun and Wei Shi, 2015. Versatile method for the synthesis of porous nanostructured thin films of conducting polymers and their composites. Royal Society of Chemistry, 5, 34616.
  • 26. Gracien Bakambo Ekoko, Joseph Kanza-Kanza Lobo, Omer Muamba Mvele,Jérémie Lunguya Muswema, Jean-Felix Senga Yamambe, Peter Kimpende Mangwala, 2014. Gamma irradiation inducing the synthesis of magnetic Fe3O4 nanorod particles in alkaline medium. International Journal of Materials Science and Applications, 3(6), 339-343.
  • 27. Hefa Chenga, Weipu Xub, Junliang Liu, Huanjun Wang, Yanqing He, Gang Chen, 2007. Pretreatment of wastewater from triazine manufacturing by coagulation, electrolysis, and internal microelectrolysis. Journal of Hazardous Materials 146, 385–392.

PRODUCTION OF FERRIC COMPLEX COMPOUNDS FOR WASTEWATER TREATMENT FROM HOT ROLLED IRON-STEEL SOLID WASTE

Yıl 2019, Cilt: 2 Sayı: 1, 1 - 7, 30.06.2019

Öz

Abstract



Study on oxide scales of
products is of greater importance to manufacturers and consumers. these
secondary and tertiary scales must be recycled because of high iron content. if
these residues are not effectively treated, not only the environment will be
seriously polluted, but also the resources will be wasted. In this study, the
extraction of iron from Turkish hot rolled iron-steel oxide scale was attempted
using atmospheric acid leaching. the effects of the several parameters which
included solid/liquid ratio, leaching time, leaching temperature and acid
concentration upon leaching efficiency of iron were investigated. The
volumetric titration results showed that the amount of Fe+2
 and Fe+3 could reach respectively %47 and %38 at 60°C temperature in 6N HCl acid
concentration during 60 minutes leaching time. Two alternative methods which
were atmospheric evaporation and alkaline precipitation have been successfully
applied by using leaching solution as iron chloride source. The experimental
results show that FeCl
3 was obtained by atmospheric evaporation
method with a small amount of FeCl
2. Alkaline precipitation method’s
results show that the iron was existed in ferric hydroxide formation. both
precipitate and crystalized products have been iron products which are
frequently used as an adsorbent to remove various heavy metals (i.e., arsenic
and chromium) from contaminated soil and water and also flocculation agent.

Kaynakça

  • 1. American Chemistry Council. "Chlorine Chemistry Division : Ferric Chloride: Clearing the stuff out of water." americanchemistry.com : Chemistry is essential2living - The American Chemistry Council N.p., Sept. 2003. Web. 20 Sept. 2010.
  • 2. Citulski, Joel, Khosrow Farahbakhsh, and Fraser Kent. "Optimization of phosphorus removal in secondary effluent using immersed ultrafiltration membranes with in-line coagulant pretreatment — implications for advanced water treatment and reuse applications." Journal of Environmental Engineering and Science 36 (2009): 1272-1283.
  • 3. Stumm, W., and J.J. Morgan. 1962. Chemical Aspects of Coagulation. Jour. AWWA, 54(8):971-994. 4. Stumm, W., and C.R. O’ Melia. 1968. Stoichiometry of Coagulation. Jour. AWWA, 60(5):514-539.
  • 5. Black, A.P. 1967. Electrokinetic Characteristics of Hydrous Oxies of Aluminum and Iron. In Principles and Application of Water Chemistry. Edited by S.D. Faust and J.V. Hunter. New York: John Wiley and Sons.
  • 6. Johnson, P.N., and A. Amirtharajah. 1983. Ferric Chloride and Alum as Single and Dual Coagulants. Jour. AWWA, 75(5):232-239.
  • 7. Matijevic, E, and G.E. Janauer. 1966. Coagulation and Reversal of Charge of Lyophilic Colloids by Hydrolyzed Metal Ions. II. Ferric Nitrate. J. Colloid Interface Sci., 21(2):197-223.
  • 8. Phosphorous Removal from Wastewater. Water Treatment and Purification - Lenntech. Lenntech, 2009. Web. 1 Mar. 2010. <http://www.lenntech.com/phosphorous-removal.htm>.
  • 9. Tang, H-X. and Stumm, W., 1987. The Coagulating Behaviors of Fe(III) Polymeric Species—I and II. Water Research, 21(1):115-128.
  • 10. California Water Technologies. “Phosphorus Removal." California Water Technologies. N.p., 2004. Web. 2 Oct. 2010.
  • 11. Dejian Ding, Hao Peng, Wangjun Peng, Yaowei Yu, Guangxin Wu, Jieyu Zhang, 2017. Isothermal hydrogen reduction of oxide scale on hot-rolled steel strip in 30 pct H2-N2 atmosphere. International Journal of Hydrogen Energy, 42, 29921-29928.
  • 12. West,G.D., Birosca, S., Higginson, R.L., J., 2005. Phase determination and microstructure of oxide scales formed on steel at high temperature. Jour. Microsc. 217, 122–129. https://doi.org/10.1111/j.1365-2818.2005.01409.x
  • 13. Chen, R.Y., Yuen, W.Y.D. Review of the High-Temperature Oxidation of Iron and Carbon Steels in Air or Oxygen. Oxidation of Metal, 59, 433–468.
  • 14. Weihua, S. Tieu, A.K., Zhengyi, J.,Cheng, L., Zhu, H., 2003. Surface characteristics of oxide scale in hot strip rolling. Journal of Materials Processing Technology, 140(1-3):76-83. DOI: 10.1016/S0924-0136(03)00823-9.
  • 15. Higginson, R.L., Roebuck, B, Palmiere EJ., 2002. Texture development in oxide scales on steel substrates. Scripta Materialia, 47:337–342. doi:10.1016/S1359-6462(02)00154-9.
  • 16. Barrie, J and Hallbergs, K. B., 2005. Acid mine drainage remediation options: a review. Science of the Total Environment, 338, 3-14.
  • 17. Magnone E., Kim S. D., Park J. H., 2018. A systematic study of the iron hydroxide-based adsorbent for removal of hydrogen sulphide from biogas. Microporous and Mesoporous Materials 270, 155–160.
  • 18. Nisachon, N. K., Sirilak, Y., Thanasak, N., 2018. Adhesion behaviour of scales on hot-rolled steel strips produced from continuous casting slabs. Materials Today: Proceedings, 5,9359–9367 (The 10th Thailand International Metallurgy Conference (The 10th TIMETC)).
  • 19. Guan C, Li J, Tan N, He YQ, Zhang SG., 2014. Reduction of oxide scale on hot-rolled steel by hydrogen at low temperature. Int J Hydrogen Energy, 39:15116e24.
  • 20. Shi J, Wand DR, He YD, Qi HB, Wei G., 2008. Reduction of oxide scale on hot-rolled strip steels by carbon monoxide. Mater Lett., 62:3500e2.
  • 21. Yang,Y.U., Chang WANG., Lin WANG., Jin CHEN, Ya-jun HUI, Chang-ku SUN, 2015. Combination Effect of Si and P on Tertiary Scale Characteristic of Hot Rolled Strip Mater. Journal of Iron and Steel Research, International, 22, 3, 232-237.
  • 22. Nilsonthi, T., 2018. Oxidation behaviour of hot-rolled Si-containing steel in water vapour between 600 and 900°C. Materials Today: Proceedings 5,9552–9559 (The 10th Thailand International Metallurgy Conference (The 10th TIMETC)).
  • 23. Ghosh, A. Chatterjee, A., 2008. Ironmaking and steelmaking: Theory and practice, Prentice Hall of India, New Delhi, India.
  • 24. Hiroaki Ichikawa, Shogo Sato, Nobuyuki Iwata, and Hiroshi Yamamoto, 2014. Synthesis and characterization of intercalated few-layer graphenes. Japanese Journal of Applied Physics 53, 02BD04.
  • 25. LingFeng Dai, Yuan He, Xiang Huang, Xin Cuia Shihui Wanga Dongtao Ge, Nifang Zhao, Yue Li, Yanan Sun and Wei Shi, 2015. Versatile method for the synthesis of porous nanostructured thin films of conducting polymers and their composites. Royal Society of Chemistry, 5, 34616.
  • 26. Gracien Bakambo Ekoko, Joseph Kanza-Kanza Lobo, Omer Muamba Mvele,Jérémie Lunguya Muswema, Jean-Felix Senga Yamambe, Peter Kimpende Mangwala, 2014. Gamma irradiation inducing the synthesis of magnetic Fe3O4 nanorod particles in alkaline medium. International Journal of Materials Science and Applications, 3(6), 339-343.
  • 27. Hefa Chenga, Weipu Xub, Junliang Liu, Huanjun Wang, Yanqing He, Gang Chen, 2007. Pretreatment of wastewater from triazine manufacturing by coagulation, electrolysis, and internal microelectrolysis. Journal of Hazardous Materials 146, 385–392.
Toplam 26 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Malzeme Üretim Teknolojileri
Bölüm Articles
Yazarlar

Elif Uzun

Yayımlanma Tarihi 30 Haziran 2019
Kabul Tarihi 6 Şubat 2019
Yayımlandığı Sayı Yıl 2019 Cilt: 2 Sayı: 1

Kaynak Göster

APA Uzun, E. (2019). PRODUCTION OF FERRIC COMPLEX COMPOUNDS FOR WASTEWATER TREATMENT FROM HOT ROLLED IRON-STEEL SOLID WASTE. The International Journal of Materials and Engineering Technology, 2(1), 1-7.