Due to fast industrialization the consumption as well as the cost of fossil fuels like petrol, diesel etc in the world is rising enormously leading to the generation of greenhouse gases like carbon monoxide, carbon dioxide etc besides decreasing the availability of the above fuels. The emission of these greenhouse gases rises the globe’s temperature leading the earth to face many dangerous complications. In order to save the earth from effect of rise of temperature and also to have an eco-friendly alternate energy fuel especially for the transport sector, attention is being focused on the generation of hydrogen gas which meets the above situations. During the combustion of hydrogen gas it emits only the beneficial water vapour to the atmosphere. In this research paper investigation has been carried out through CuCl-HCl electrolysis with 1M CuCl anolyte and 6M HCl catholyte for the generation of hydrogen gas at 70oC at normal atmospheric pressure employing a double compartment electrolytic cell having a nafion cation exchange membrane-324. Anode was graphite and cathode was 0.30 mg cm-2 platinum coated graphite. At a current density of 250 A m-2 the current efficiency for the oxidation of CuCl to CuCl2 and the formation of hydrogen gas was nearly 100% and the rate of hydrogen liberation was found to be 2 l h-1. Voltage efficiency and energy consumption values are calculated and are found to be more encouraging since they are more economical with less energy operation. The formed CuCl2 was reduced back to CuCl anolyte by chemical reduction with copper powder in 6M HCl at 70oC and the regenerated CuCl anolyte was again used in the CuCl-HCl electrolysis.
Published in | International Journal of Energy and Power Engineering (Volume 4, Issue 1) |
DOI | 10.11648/j.ijepe.20150401.13 |
Page(s) | 15-22 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2015. Published by Science Publishing Group |
Cuprous Chloride-Hydrochloric Acid, Nafion Cation Exchange Membrane-324, Divided Cell, Graphite, Platinum Coated Graphite, Hydrogen Gas, Cupric Chloride
[1] | C.H.Dharmaraj and S.Adish Kumar, “Economical Hydrogen Production by Electrolysis using Nano Pulsed DC”, International Journal of Energy and Environment, vol.3, no.1, pp. 129-136, 2012. |
[2] | Romdhane Ben Slama, “Production of Hydrogen by Electrolysis of Water: Effects of the Electrolyte Type on the Electrolysis Performances”, Computational Water, Energy and Environmental Engineering, vol.2, pp. 54-58, 2013. |
[3] | B.Robert Dopp, “Hydrogen Generation via Water Electrolysis using Highly Efficient Nano metal Electrodes”, Dopp Stein Enterprises. Inc., 1925 Fields Pond Glen, Marietta, GA, 30068, pp. 1-11, 2007. |
[4] | H.K.Abdel-Aal, K.M.Zohdy and M.Abdel Kareem,“Hydrogen Production Using Sea Water Electrolysis”, The Open Fuel Cell Journal, vol.3, pp. 1-7, 2010. |
[5] | Nobuko Hanada, Satoshi Hino, Takayuki Ichikawa, Hiroshi Suzuki, Kenichi Takai and Yoshitsugu Kojima, “Hydrogen Generation by Electrolysis of Liquid Ammonia”, Supplementary Material (ESI) for Journal of Chemical Communication of The Royal Society of Chemistry, vol.46, 2010. [DOI: 10.1039/c0cc01982h]. |
[6] | Sanjay Kumar Singh and Qiang Xu, “Nano catalysts for Hydrogen Generation from Hydrazine”, Catalysis Science and Technology,vol.3, pp. 1889-1900, 2013. |
[7] | M.A.Suarez-Gonzalez, A.M.Blanco-Marigorta and J.A.Pena-Quintana, “Review on Hydrogen Production Technologies from Solar Energy”, International Conference on Renewable Energies and Power Quality (ICREPQ’11), European Association for the Development of Renewable Energies, Environment and Power Quality (EA4EPQ), Las Palmas de Gran Canaria (Spain), 13th to 15th April, 2011. |
[8] | Nida Chaudhary, O.Ngadi Michael, K.Benjamin Simpson and S.Lamin Kassama, “Biosynthesis of Ethanol and Hydrogen by Glycerol Fermentation Using Escherichia Coli”, Advances in Chemical Engineering and Science, vol.1, pp.83-89, 2011 [DOI: 10.4236/aces.2011.13014]. |
[9] | Guido Collod, “Hydrogen Production via Stream Reforming with CO2 Capture”, Chemical Engineering Transactions, vol.19, pp. 37-42, 2010 [DOI: 10.3303/CET 1019007]. |
[10] | A.Rene Rozendal, V.M.Hubertus Hamelers, J.W.Gerrit Euverink, J.Sybrand Metz and J.N.Cees Buisaman, “Principle and perspective of hydrogen production through biocatalyzed electrolysis,” International Journal of Hydrogen Energy, vol.31, pp. 1632-1640, 2006 [DOI: 10.1016/j.ijhydene.2005.12.006]. |
[11] | R.H.Carty, M.M.Mazumder, J.D. Schreider and J.B. Panborn, “Thermochemical Hydrogen Production”, Gas Research Institute for the Institute of Gas Technology, GRI-80/0023, Chicago, IL 60616, pp.1-4, 1981. |
[12] | K.F.Knoche, P.Schuster and T.Ritterbex, “Thermochemical Production of Hydrogen by a Vanadium-Chlorine Cycle.II – Experimental Investigation of the Individual Reactions”, International Journal of Hydrogen Energy, vol.9, no.6, pp. 473-482, 1984 [DOI: 10.1016/0360-3199(84) 90099-5]. |
[13] | Y.Shindo,N.Ito,K.Haraya,T.Hakuta and H.Yoshitome, “Thermal Efficiency of the Magnesium-Iodine Cycle for Thermochemical Hydrogen Production”, International Journal of Hydrogen Energy, vol.8, no.7, pp. 509-513, 1983 [DOI: 10.1016/0360-3199 (83) 90003-4]. |
[14] | R.H.Elder, G.H.Priestman, B.C.Ewan and R.W.K.Allen, “The Separation of Hi X in the Sulphur-Iodine Thermochemical Cycle for Sustainable Hydrogen Production”, Journal of Process Safety and Environmental Protection, vol.83, no.4, pp. 343-350, 2005 [DOI: 10.1205/psep.0434]. |
[15] | N.Victor Balashov, S.Rich Schatz, Elena Chalkova, N.Nikolay Akinfiev, V.Mark Fedkin and N.Serguei Lvov, “CuCl Electrolysis for Hydrogen Production in the Cu-Cl Thermochemical Cycle”, Journal of The Electrochemical Society, vol.158, no.3, pp. B266-B275, 2011. |
[16] | A.Michele Lewis and G.Joseph Masin, “The Evaluation of Alternative Thermochemical Cycles – Part II: The Down-Selection Process”, International Journal of Hydrogen Energy, vol.xxx, pp. 1-11, 2008 (article in press) [DOI: 10.1016/j.ijhydene.2008.07.085]. |
[17] | G.Naterer, S.Suppiah, M.Lewis, K.Gabriel, I.Dincer, M.A.Rosen, M.Fowler, G.Rizvi, E.B.Easton, B.M.Ikeda, M.H.Kaye, L.Lu, I.Pioro, P.Spekkens, P.Tremaine, J.Mostaghimi, J.Avsec and J.Jiang, “Recent Canadian Advances in Nuclear-based Hydrogen Production and the Thermochemical Cu-Cl Cycle”, International Journal of Hydrogen Energy, vol.34, pp. 2901-2917, 2009. |
[18] | F.Mohammadi, S.N.A.Ashrafizadeh and A.Sattari, “Aqueous HCl Electrolysis Utilizing an Oxygen Reducing Cathode”, Chemical Engineering Journal,vol.155, pp. 757-762, 2009. |
[19] | M.A.Aziz, M.S.Ali and M.M.Islam, “Effect of solution concentration on oxidization”, Chemical Engineering and Research Bulletin, vol.10, pp. 762-763, 1980. |
[20] | G.Naterer, S.Suppiah, L.Stolberg, M.Lewis, Z.Wang, V.Daggupati, K.Gabriel, I.Dincer, M.A.Rosen, P.Spekkens, S.N.Lvov, M.Fowler, P.Tremaine, J.Mostaghimi, E.B.Easton, L.Travani, G.Rizvi, B.M.Ikeda, M.H.Kaye, L.Lu, I.Pioro, W.R.Smith, E.Secnik, J.Jiang and J.Avsec, “Recent Canadian Advances in Nuclear-based Hydrogen Production and the Thermochemical Cu-Cl Cycle”, International Journal of Hydrogen Energy, vol.35, pp. 10905-10926, 2010. |
[21] | A.Khelifa, S.Moulay, F.Hannane, S.Benslimene and M.Hecini, “Application of an Experimental Design Method to Study the Performance of Electrochlorination Cells”, Desalination, vol.160, pp. 91-98, 2004. |
[22] | R.Santhanam and G.Easton, “Novel Ceramic Carbon Electrode (CCE) Materials for CuCl Electrolysis”, ORF Workshop on Nuclear-Based Thermochemical Hydrogen Production, Chalk River, ON, Canada, E.B, 2008 (Unpublished Report). |
APA Style
Natarajan Sathaiyan, Venkataraman Nandakumar, Ganapathy Sozhan, Jegan Gandhibha Packiaraj, Elumalai Thambuswamy Devakumar, et al. (2015). Hydrogen Generation through Cuprous Chloride-Hydrochloric Acid Electrolysis. International Journal of Energy and Power Engineering, 4(1), 15-22. https://doi.org/10.11648/j.ijepe.20150401.13
ACS Style
Natarajan Sathaiyan; Venkataraman Nandakumar; Ganapathy Sozhan; Jegan Gandhibha Packiaraj; Elumalai Thambuswamy Devakumar, et al. Hydrogen Generation through Cuprous Chloride-Hydrochloric Acid Electrolysis. Int. J. Energy Power Eng. 2015, 4(1), 15-22. doi: 10.11648/j.ijepe.20150401.13
AMA Style
Natarajan Sathaiyan, Venkataraman Nandakumar, Ganapathy Sozhan, Jegan Gandhibha Packiaraj, Elumalai Thambuswamy Devakumar, et al. Hydrogen Generation through Cuprous Chloride-Hydrochloric Acid Electrolysis. Int J Energy Power Eng. 2015;4(1):15-22. doi: 10.11648/j.ijepe.20150401.13
@article{10.11648/j.ijepe.20150401.13, author = {Natarajan Sathaiyan and Venkataraman Nandakumar and Ganapathy Sozhan and Jegan Gandhibha Packiaraj and Elumalai Thambuswamy Devakumar and Damaraju Parvatalu and Anil Bhardwaj and Bantwal Narayana Prabhu}, title = {Hydrogen Generation through Cuprous Chloride-Hydrochloric Acid Electrolysis}, journal = {International Journal of Energy and Power Engineering}, volume = {4}, number = {1}, pages = {15-22}, doi = {10.11648/j.ijepe.20150401.13}, url = {https://doi.org/10.11648/j.ijepe.20150401.13}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijepe.20150401.13}, abstract = {Due to fast industrialization the consumption as well as the cost of fossil fuels like petrol, diesel etc in the world is rising enormously leading to the generation of greenhouse gases like carbon monoxide, carbon dioxide etc besides decreasing the availability of the above fuels. The emission of these greenhouse gases rises the globe’s temperature leading the earth to face many dangerous complications. In order to save the earth from effect of rise of temperature and also to have an eco-friendly alternate energy fuel especially for the transport sector, attention is being focused on the generation of hydrogen gas which meets the above situations. During the combustion of hydrogen gas it emits only the beneficial water vapour to the atmosphere. In this research paper investigation has been carried out through CuCl-HCl electrolysis with 1M CuCl anolyte and 6M HCl catholyte for the generation of hydrogen gas at 70oC at normal atmospheric pressure employing a double compartment electrolytic cell having a nafion cation exchange membrane-324. Anode was graphite and cathode was 0.30 mg cm-2 platinum coated graphite. At a current density of 250 A m-2 the current efficiency for the oxidation of CuCl to CuCl2 and the formation of hydrogen gas was nearly 100% and the rate of hydrogen liberation was found to be 2 l h-1. Voltage efficiency and energy consumption values are calculated and are found to be more encouraging since they are more economical with less energy operation. The formed CuCl2 was reduced back to CuCl anolyte by chemical reduction with copper powder in 6M HCl at 70oC and the regenerated CuCl anolyte was again used in the CuCl-HCl electrolysis.}, year = {2015} }
TY - JOUR T1 - Hydrogen Generation through Cuprous Chloride-Hydrochloric Acid Electrolysis AU - Natarajan Sathaiyan AU - Venkataraman Nandakumar AU - Ganapathy Sozhan AU - Jegan Gandhibha Packiaraj AU - Elumalai Thambuswamy Devakumar AU - Damaraju Parvatalu AU - Anil Bhardwaj AU - Bantwal Narayana Prabhu Y1 - 2015/01/28 PY - 2015 N1 - https://doi.org/10.11648/j.ijepe.20150401.13 DO - 10.11648/j.ijepe.20150401.13 T2 - International Journal of Energy and Power Engineering JF - International Journal of Energy and Power Engineering JO - International Journal of Energy and Power Engineering SP - 15 EP - 22 PB - Science Publishing Group SN - 2326-960X UR - https://doi.org/10.11648/j.ijepe.20150401.13 AB - Due to fast industrialization the consumption as well as the cost of fossil fuels like petrol, diesel etc in the world is rising enormously leading to the generation of greenhouse gases like carbon monoxide, carbon dioxide etc besides decreasing the availability of the above fuels. The emission of these greenhouse gases rises the globe’s temperature leading the earth to face many dangerous complications. In order to save the earth from effect of rise of temperature and also to have an eco-friendly alternate energy fuel especially for the transport sector, attention is being focused on the generation of hydrogen gas which meets the above situations. During the combustion of hydrogen gas it emits only the beneficial water vapour to the atmosphere. In this research paper investigation has been carried out through CuCl-HCl electrolysis with 1M CuCl anolyte and 6M HCl catholyte for the generation of hydrogen gas at 70oC at normal atmospheric pressure employing a double compartment electrolytic cell having a nafion cation exchange membrane-324. Anode was graphite and cathode was 0.30 mg cm-2 platinum coated graphite. At a current density of 250 A m-2 the current efficiency for the oxidation of CuCl to CuCl2 and the formation of hydrogen gas was nearly 100% and the rate of hydrogen liberation was found to be 2 l h-1. Voltage efficiency and energy consumption values are calculated and are found to be more encouraging since they are more economical with less energy operation. The formed CuCl2 was reduced back to CuCl anolyte by chemical reduction with copper powder in 6M HCl at 70oC and the regenerated CuCl anolyte was again used in the CuCl-HCl electrolysis. VL - 4 IS - 1 ER -