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SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR

Year 2020, , 152 - 169, 30.03.2020
https://doi.org/10.18186/thermal.729318

Abstract

Solar water splitting is a promising process for the storage and conversion of sunlight power into clean-burning hydrogen gas, this paper presents a CFD analysis of hydrogen production via a proposed packed bed thermochemical receiver/reactor system. The idea of this study is the use of packed bed of spherical ceramic particles coated with active redox ferrite materials. The first step is an endothermic reaction, nickel ferrite (NiFe2O4) dissociate thermally into nickel oxide (NiO), ferrous oxide (FeO) and oxygen at 1473 K, this reaction take place under 2 KW concentrated solar energy. The second is the hydrolysis step at 1073 K to form hydrogen and NiFe2O4, the latter is recycled to the first step for a new production cycle. The CFD code solves the momentum, energy and species transport equations. The temperature fields of the reactor solid & the fluid phases were attained using the local thermal non-equilibrium model (LTNE). The LTNE model sources terms were computed through the user-defined functions to couple the energy equations of the fluid phase and solid phase. The complete model was used to analyse numerically the reaction through the packed bed in order to predict the thermal behavior under different conditions (inlet velocity, packing arrangement and solar concentrated flux).

References

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  • [2] Antunes, J.M.G. The use of hydrogen as a fuel for compression ignition engines.;2011.
  • [3] Antunes, J.G., R. Mikalsen, and A. Roskilly. An investigation of hydrogen-fuelled HCCI engine performance and operation. International journal of hydrogen energy, 2008; 33(20), 5823-5828.
  • [4] Chaubey, R., et al. A review on development of industrial processes and emerging techniques for production of hydrogen from renewable and sustainable sources. Renewable and Sustainable Energy Reviews, 2013; 23, 443-462.
  • [5] Blok, K., et al. Hydrogen production from natural gas, sequestration of recovered CO2 in depleted gas wells and enhanced natural gas recovery. Energy, 1997; 22(2-3), 161-168.
  • [6] Dunn, S. .Hydrogen futures: toward a sustainable energy system. International journal of hydrogen energy, 2002; 27(3), 235-264.
  • [7] Ramachandran, R. and R.K. Menon..An overview of industrial uses of hydrogen. International journal of hydrogen energy, 1998; 23(7), 593-598.
  • [8] Funk, J.E..Thermochemical hydrogen production: past and present. International journal of hydrogen energy, 2001; 26(3), 185-190.
  • [9] Agrafiotis, C., et al. Solar water splitting for hydrogen production with monolithic reactors. Solar Energy, 79(4), 2005; 409-421.
  • [10] Xiao, L., S.-Y. Wu, and Y.-R. Li..Advances in solar hydrogen production via two-step water-splitting thermochemical cycles based on metal redox reactions. Renewable Energy, 2012; 41, 1-12.
  • [11] BIČÁKOVÁ, O. and P. Straka.The resources and methods of hydrogen production. Acta Geodyn. Geomater,2010; 7(158), 175.
  • [12] Epstein, M. Solar thermal reforming of methane. SFERA Winter School. Switzerland. Zürich, 2011.
  • [13] Giaconia, A., et al. Multi-fuelled solar steam reforming for pure hydrogen production using solar salts as heat transfer fluid. Energy Procedia,2015; 69, 1750-1758.
  • [14] Simakov, D.S., et al. Solar thermal catalytic reforming of natural gas: a review on chemistry, catalysis and system design. Catalysis Science & Technology,2015; 5(4), 1991-2016.
  • [15] Dahl, J.K., et al. Solar-thermal processing of methane to produce hydrogen and syngas. Energy & fuels, 2001; 15(5), 1227-1232.
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  • [18] Steinfeld, A. Solar hydrogen production via a two-step water-splitting thermochemical cycle based on Zn/ZnO redox reactions. International journal of hydrogen energy,2002; 27(6), 611-619.
  • [19] Abanades, S. and G. Flamant. Thermochemical hydrogen production from a two-step solar-driven water-splitting cycle based on cerium oxides. Solar Energy,2006; 80(12), 1611-1623.
  • [20] Tamaura, Y., et al. Production of solar hydrogen by a novel, 2-step, water-splitting thermochemical cycle. Energy, 1995; 20(4), 325-330.
  • [21] Funk, J.E. and R.M. Reinstrom. Energy requirements in production of hydrogen from water. Industrial & Engineering Chemistry Process Design and Development, 1966; 5(3), 336-342.
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  • [29] Pagliaro, M., et al. Solar hydrogen: fuel of the near future. Energy & Environmental Science,2010; 3(3), 279-287.
  • [30] EnergyBusinessEurope. HYDROSOL Plant Project – Hydrogen power for zero CO2 emissions. 2016 [cited 2017 21/08]; Available from: http://www.energybusinesseurope.com/hydrogen-power-for-zero-co2-emissions-and-energy-security/.
  • [31] OTERO, A. Concentrating on Sunshine to Advance the Hydrogen Economy. 2013 [cited 2017 22 August]; Available from: http://crf.sandia.gov/concentrating-on-sunshine-to-advance-the-hydrogen-economy/.
  • [32] Alonso, E. and M. Romero..Review of experimental investigation on directly irradiated particles solar reactors. Renewable and Sustainable Energy Reviews,2015; 41, 53-67.
  • [33] CHAMBON, M. Thermochemical cycles based on the ZnO/Zn or SnO2/SnO redox couples : Kinetic characterizations and study of solar reactors, SFERA Winter School Solar Fuels & Materials: ETH Zürich, 13; 2011.
  • [34] Lichty, P.R., et al. Solar thermal reactor materials characterization, National Renewable Energy Laboratory (NREL), Golden, CO.2008.
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  • [36] E.E., K. Solar-Thermochemical Hydrogen. 2010 [cited 2017 22 August]; Available from: http://www.me.udel.edu/research_groups/prasad/research/solartherm.html.
  • [37] Tingate, G.Some geometrical properties of packings of equal spheres in cylindrical vessels. Nuclear Engineering and design, 1973; 24(2), 153-179.
  • [38] Burtseva, L., et al. Modeling of Monosized Sphere Packings into Cylinders: Univ., Fak. für Mathematik.;2015.
  • [39] Van Antwerpen, W., C. Du Toit, and P. Rousseau. A review of correlations to model the packing structure and effective thermal conductivity in packed beds of mono-sized spherical particles. Nuclear Engineering and design, 2010; 240(7), 1803-1818.
  • [40] Fumizawa, M., Y. Kaneko, and M. Izumi. Porosity Effect in the Core Thermal Hydraulics for Ultra High Temperature Gas-Cooled Reactor. Journal of Systemics, Cybernetics and Informatics, 2008; 6(6), 86-92.
  • [41] Oktajianto, H., E. Setiawati, and V. Richardina. Modelling of HTR (High Temperature Reactor) Pebble-Bed 10 MW to Determine Criticality as A Variations of Enrichment and Radius of the Fuel (Kernel) With the Monte Carlo Code MCNP4C. International Journal of Science and Engineering, 2015; 8(1), 42-46.
  • [42] Cervone, A., et al. Development of hydrogen peroxide monopropellant rockets. AIAA paper, 5239, 2006.
  • [43] Tuinier, M., et al. Cryogenic CO2 capture using dynamically operated packed beds. Chemical Engineering Science, 2010; 65(1), 114-119.
  • [44] Ali, A.H., S. Ganguly, and A.B.M. Shariff. Simulation of cryogenic packed bed using 1-dimensional pseudo homogeneous model. J. Appl. Sci.,2014; 14, 3118-3121.
  • [45] Wieckert, C., et al. Syngas production by thermochemical gasification of carbonaceous waste materials in a 150 kWth packed-bed solar reactor. Energy & fuels, 2013; 27(8), 4770-4776.
  • [46] Reich, L., et al. Heat and mass transfer model of a packed-bed reactor for solar thermochemical CO2 capture. in Proc. of 15th Int. Heat Trans. Conf. 2014.
  • [47] Piatkowski, N., C. Wieckert, and A. Steinfeld. Experimental investigation of a packed-bed solar reactor for the steam-gasification of carbonaceous feedstocks. Fuel processing technology, 2009; 90(3), 360-366.
  • [48] Bellouard, Q., et al.A high temperature drop-tube and packed-bed solar reactor for continuous biomass gasification. in AIP Conference Proceedings, AIP Publishing.2017.
  • [49] Wieckert, C. Solar Carbothermic Production of Zinc, SFERA Winter School Solar Fuels & Materials,2011; 32.
  • [50] Pvt.Ltd, D.I. Inert Ceramic Balls [cited 2016 07/09]; Available from: http://devsongroup.com/site/index.php?pid=0009.0001.
  • [51] Lopez-Hernandez, H.D. Experimental analysis and macroscopic and pore-level flow simulations to compare non-Darcy flow models in porous media. 2007.
  • [52] Getachew, D., W. Minkowycz, and J. Lage. A modified form of the κ–ε model for turbulent flows of an incompressible fluid in porous media. International Journal of Heat and Mass Transfer, 2000; 43(16), 2909-2915.
  • [53] Pedras, M.H. and M.J. de Lemos. Computation of Turbulent Flow in Porous Media Using a Low-Reynolds K-ε Modeland AN Infinite Array of Transversally Displaced Elliptic Rods. Numerical Heat Transfer: Part A: Applications, 2003; 43(6), 585-602.
  • [54] E, F., MACROSCOPIC MODELING OF TURBULENCE IN POROUS MEDIA
  • [55] Xu, C., Z. Song, and Y. Zhen. Numerical investigation on porous media heat transfer in a solar tower receiver. Renewable Energy,2011; 36(3), 1138-1144.
  • [56] Alazmi, B. and K. Vafai. Analysis of variants within the porous media transport models. Journal of Heat Transfer, 2000; 122(2), 303-326.
  • [57] Villafán-Vidales, H., et al. Heat transfer simulation in a thermochemical solar reactor based on a volumetric porous receiver. Applied Thermal Engineering,2011; 31(16), 3377-3386.
  • [58] Vafai, K.a.A., A. Non-Darcian Effects in a confined Forced convective Flows,. Chemical Engineering Sciences,1998; 2523-2532.
  • [59] Hwang, G.J.C.C.H. Heat Transfer Measurment and Analysis for Sintred Porous Channels ASME Journal Of Heat Transfer,1994; 456-464
  • [60] Dixon, A.G.C., D. L. Theoretical Prediction of effective Heat Transfer Parameters in Pached Bed AIChE Journal,1979; 663-676.
  • [61] Abenbach, E. Heat and flow charactaristics of packed beds. Experimental Thermal and fluid Science, 1995; 17-27.
  • [62] Vafai, K. and A. Amiri. Non-Darcian effects in confined forced convective flows. Transport phenomena in porous media, 1998; 1, 313-329.
  • [63] K, K., Modeling of composite heat transfer in open-cellular porous materials at hight temperatures
  • [64] Nelson, A.T., et al. Thermal expansion, heat capacity, and thermal conductivity of Nickel Ferrite (NiFe2O4). Journal of the American Ceramic Society, 2014; 97(5), 1559-1565.
  • [65] Massot, M., et al. Critical behavior of CoO and NiO from specific heat, thermal conductivity, and thermal diffusivity measurements. Physical Review B, 2008; 77(13), 134438.
  • [66] Schrettle, F., et al. Wüstite: electric, thermodynamic and optical properties of FeO. The European Physical Journal B-Condensed Matter and Complex Systems,2012; 85(5): p. 1-12.
  • [67] Lewis, F. and N. Saunders. The thermal conductivity of NiO and CoO at the Neel temperature. Journal of Physics C: Solid State Physics, 1973; 6(15), 2525.
  • [68] Wu, Z., et al. Coupled radiation and flow modeling in ceramic foam volumetric solar air receivers. Solar Energy,2011; 85(9),2374-2385.
Year 2020, , 152 - 169, 30.03.2020
https://doi.org/10.18186/thermal.729318

Abstract

References

  • [1] White, C., R. Steeper, and A. Lutz. The hydrogen-fueled internal combustion engine: a technical review. International journal of hydrogen energy, 2006; 31(10), 1292-1305.
  • [2] Antunes, J.M.G. The use of hydrogen as a fuel for compression ignition engines.;2011.
  • [3] Antunes, J.G., R. Mikalsen, and A. Roskilly. An investigation of hydrogen-fuelled HCCI engine performance and operation. International journal of hydrogen energy, 2008; 33(20), 5823-5828.
  • [4] Chaubey, R., et al. A review on development of industrial processes and emerging techniques for production of hydrogen from renewable and sustainable sources. Renewable and Sustainable Energy Reviews, 2013; 23, 443-462.
  • [5] Blok, K., et al. Hydrogen production from natural gas, sequestration of recovered CO2 in depleted gas wells and enhanced natural gas recovery. Energy, 1997; 22(2-3), 161-168.
  • [6] Dunn, S. .Hydrogen futures: toward a sustainable energy system. International journal of hydrogen energy, 2002; 27(3), 235-264.
  • [7] Ramachandran, R. and R.K. Menon..An overview of industrial uses of hydrogen. International journal of hydrogen energy, 1998; 23(7), 593-598.
  • [8] Funk, J.E..Thermochemical hydrogen production: past and present. International journal of hydrogen energy, 2001; 26(3), 185-190.
  • [9] Agrafiotis, C., et al. Solar water splitting for hydrogen production with monolithic reactors. Solar Energy, 79(4), 2005; 409-421.
  • [10] Xiao, L., S.-Y. Wu, and Y.-R. Li..Advances in solar hydrogen production via two-step water-splitting thermochemical cycles based on metal redox reactions. Renewable Energy, 2012; 41, 1-12.
  • [11] BIČÁKOVÁ, O. and P. Straka.The resources and methods of hydrogen production. Acta Geodyn. Geomater,2010; 7(158), 175.
  • [12] Epstein, M. Solar thermal reforming of methane. SFERA Winter School. Switzerland. Zürich, 2011.
  • [13] Giaconia, A., et al. Multi-fuelled solar steam reforming for pure hydrogen production using solar salts as heat transfer fluid. Energy Procedia,2015; 69, 1750-1758.
  • [14] Simakov, D.S., et al. Solar thermal catalytic reforming of natural gas: a review on chemistry, catalysis and system design. Catalysis Science & Technology,2015; 5(4), 1991-2016.
  • [15] Dahl, J.K., et al. Solar-thermal processing of methane to produce hydrogen and syngas. Energy & fuels, 2001; 15(5), 1227-1232.
  • [16] Abanades, S. and G. Flamant. High-temperature solar chemical reactors for hydrogen production from natural gas cracking. Chemical Engineering Communications,2008; 195(9), 1159-1175.
  • [17] Abánades, A., et al. Experimental analysis of direct thermal methane cracking. International journal of hydrogen energy, 2011; 36(20), 12877-12886.
  • [18] Steinfeld, A. Solar hydrogen production via a two-step water-splitting thermochemical cycle based on Zn/ZnO redox reactions. International journal of hydrogen energy,2002; 27(6), 611-619.
  • [19] Abanades, S. and G. Flamant. Thermochemical hydrogen production from a two-step solar-driven water-splitting cycle based on cerium oxides. Solar Energy,2006; 80(12), 1611-1623.
  • [20] Tamaura, Y., et al. Production of solar hydrogen by a novel, 2-step, water-splitting thermochemical cycle. Energy, 1995; 20(4), 325-330.
  • [21] Funk, J.E. and R.M. Reinstrom. Energy requirements in production of hydrogen from water. Industrial & Engineering Chemistry Process Design and Development, 1966; 5(3), 336-342.
  • [22] Perret, R. Solar Thermochemical hydrogen production research (STCH), Sandia National Lab.(SNL-CA), Livermore, CA (United States),2011.
  • [23] Yadav, D. and R. Banerjee A review of solar thermochemical processes. Renewable and Sustainable Energy Reviews, 2016; 54, 497-532.
  • [24] Konstandopoulos, A.G. and S. Lorentzou. Novel Monolithic Reactors for Solar Thermochemical Water Splitting. On Solar Hydrogen & Nanotechnology,2009; 621-639.
  • [25] Kaneko, H., et al..Simulation study of Tokyo Tech rotary-type solar reactor on solar field test at CSIRO in Australia. in Proceedings of the ASME 2011 5th International Conference on Energy Sustainability (ES2011), ESFuelCell2011-54568,2011; Washington, DC.
  • [26] ADMIN. High-Efficiency Solar Thermochemical Reactor for Hydrogen Production. 2014 [cited 2017 22 august]; Available from: http://energy.sandia.gov/high-efficiency-solar-thermochemical-reactor-for-hydrogen-production/.
  • [27] Neises, M., et al. Solar-heated rotary kiln for thermochemical energy storage. Solar Energy, 2012; 86(10), 3040-3048.
  • [28] Roeb, M., et al. Technologies and trends in solar power and fuels. Energy & Environmental Science,2011; 4(7), 2503-2511.
  • [29] Pagliaro, M., et al. Solar hydrogen: fuel of the near future. Energy & Environmental Science,2010; 3(3), 279-287.
  • [30] EnergyBusinessEurope. HYDROSOL Plant Project – Hydrogen power for zero CO2 emissions. 2016 [cited 2017 21/08]; Available from: http://www.energybusinesseurope.com/hydrogen-power-for-zero-co2-emissions-and-energy-security/.
  • [31] OTERO, A. Concentrating on Sunshine to Advance the Hydrogen Economy. 2013 [cited 2017 22 August]; Available from: http://crf.sandia.gov/concentrating-on-sunshine-to-advance-the-hydrogen-economy/.
  • [32] Alonso, E. and M. Romero..Review of experimental investigation on directly irradiated particles solar reactors. Renewable and Sustainable Energy Reviews,2015; 41, 53-67.
  • [33] CHAMBON, M. Thermochemical cycles based on the ZnO/Zn or SnO2/SnO redox couples : Kinetic characterizations and study of solar reactors, SFERA Winter School Solar Fuels & Materials: ETH Zürich, 13; 2011.
  • [34] Lichty, P.R., et al. Solar thermal reactor materials characterization, National Renewable Energy Laboratory (NREL), Golden, CO.2008.
  • [35] TRANSPORT, E.F.-A.a.A. The SOLAR-JET Project, ILA BERLIN.2014.
  • [36] E.E., K. Solar-Thermochemical Hydrogen. 2010 [cited 2017 22 August]; Available from: http://www.me.udel.edu/research_groups/prasad/research/solartherm.html.
  • [37] Tingate, G.Some geometrical properties of packings of equal spheres in cylindrical vessels. Nuclear Engineering and design, 1973; 24(2), 153-179.
  • [38] Burtseva, L., et al. Modeling of Monosized Sphere Packings into Cylinders: Univ., Fak. für Mathematik.;2015.
  • [39] Van Antwerpen, W., C. Du Toit, and P. Rousseau. A review of correlations to model the packing structure and effective thermal conductivity in packed beds of mono-sized spherical particles. Nuclear Engineering and design, 2010; 240(7), 1803-1818.
  • [40] Fumizawa, M., Y. Kaneko, and M. Izumi. Porosity Effect in the Core Thermal Hydraulics for Ultra High Temperature Gas-Cooled Reactor. Journal of Systemics, Cybernetics and Informatics, 2008; 6(6), 86-92.
  • [41] Oktajianto, H., E. Setiawati, and V. Richardina. Modelling of HTR (High Temperature Reactor) Pebble-Bed 10 MW to Determine Criticality as A Variations of Enrichment and Radius of the Fuel (Kernel) With the Monte Carlo Code MCNP4C. International Journal of Science and Engineering, 2015; 8(1), 42-46.
  • [42] Cervone, A., et al. Development of hydrogen peroxide monopropellant rockets. AIAA paper, 5239, 2006.
  • [43] Tuinier, M., et al. Cryogenic CO2 capture using dynamically operated packed beds. Chemical Engineering Science, 2010; 65(1), 114-119.
  • [44] Ali, A.H., S. Ganguly, and A.B.M. Shariff. Simulation of cryogenic packed bed using 1-dimensional pseudo homogeneous model. J. Appl. Sci.,2014; 14, 3118-3121.
  • [45] Wieckert, C., et al. Syngas production by thermochemical gasification of carbonaceous waste materials in a 150 kWth packed-bed solar reactor. Energy & fuels, 2013; 27(8), 4770-4776.
  • [46] Reich, L., et al. Heat and mass transfer model of a packed-bed reactor for solar thermochemical CO2 capture. in Proc. of 15th Int. Heat Trans. Conf. 2014.
  • [47] Piatkowski, N., C. Wieckert, and A. Steinfeld. Experimental investigation of a packed-bed solar reactor for the steam-gasification of carbonaceous feedstocks. Fuel processing technology, 2009; 90(3), 360-366.
  • [48] Bellouard, Q., et al.A high temperature drop-tube and packed-bed solar reactor for continuous biomass gasification. in AIP Conference Proceedings, AIP Publishing.2017.
  • [49] Wieckert, C. Solar Carbothermic Production of Zinc, SFERA Winter School Solar Fuels & Materials,2011; 32.
  • [50] Pvt.Ltd, D.I. Inert Ceramic Balls [cited 2016 07/09]; Available from: http://devsongroup.com/site/index.php?pid=0009.0001.
  • [51] Lopez-Hernandez, H.D. Experimental analysis and macroscopic and pore-level flow simulations to compare non-Darcy flow models in porous media. 2007.
  • [52] Getachew, D., W. Minkowycz, and J. Lage. A modified form of the κ–ε model for turbulent flows of an incompressible fluid in porous media. International Journal of Heat and Mass Transfer, 2000; 43(16), 2909-2915.
  • [53] Pedras, M.H. and M.J. de Lemos. Computation of Turbulent Flow in Porous Media Using a Low-Reynolds K-ε Modeland AN Infinite Array of Transversally Displaced Elliptic Rods. Numerical Heat Transfer: Part A: Applications, 2003; 43(6), 585-602.
  • [54] E, F., MACROSCOPIC MODELING OF TURBULENCE IN POROUS MEDIA
  • [55] Xu, C., Z. Song, and Y. Zhen. Numerical investigation on porous media heat transfer in a solar tower receiver. Renewable Energy,2011; 36(3), 1138-1144.
  • [56] Alazmi, B. and K. Vafai. Analysis of variants within the porous media transport models. Journal of Heat Transfer, 2000; 122(2), 303-326.
  • [57] Villafán-Vidales, H., et al. Heat transfer simulation in a thermochemical solar reactor based on a volumetric porous receiver. Applied Thermal Engineering,2011; 31(16), 3377-3386.
  • [58] Vafai, K.a.A., A. Non-Darcian Effects in a confined Forced convective Flows,. Chemical Engineering Sciences,1998; 2523-2532.
  • [59] Hwang, G.J.C.C.H. Heat Transfer Measurment and Analysis for Sintred Porous Channels ASME Journal Of Heat Transfer,1994; 456-464
  • [60] Dixon, A.G.C., D. L. Theoretical Prediction of effective Heat Transfer Parameters in Pached Bed AIChE Journal,1979; 663-676.
  • [61] Abenbach, E. Heat and flow charactaristics of packed beds. Experimental Thermal and fluid Science, 1995; 17-27.
  • [62] Vafai, K. and A. Amiri. Non-Darcian effects in confined forced convective flows. Transport phenomena in porous media, 1998; 1, 313-329.
  • [63] K, K., Modeling of composite heat transfer in open-cellular porous materials at hight temperatures
  • [64] Nelson, A.T., et al. Thermal expansion, heat capacity, and thermal conductivity of Nickel Ferrite (NiFe2O4). Journal of the American Ceramic Society, 2014; 97(5), 1559-1565.
  • [65] Massot, M., et al. Critical behavior of CoO and NiO from specific heat, thermal conductivity, and thermal diffusivity measurements. Physical Review B, 2008; 77(13), 134438.
  • [66] Schrettle, F., et al. Wüstite: electric, thermodynamic and optical properties of FeO. The European Physical Journal B-Condensed Matter and Complex Systems,2012; 85(5): p. 1-12.
  • [67] Lewis, F. and N. Saunders. The thermal conductivity of NiO and CoO at the Neel temperature. Journal of Physics C: Solid State Physics, 1973; 6(15), 2525.
  • [68] Wu, Z., et al. Coupled radiation and flow modeling in ceramic foam volumetric solar air receivers. Solar Energy,2011; 85(9),2374-2385.
There are 68 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Djamal Darfilal This is me 0000-0001-8538-2439

Publication Date March 30, 2020
Submission Date June 13, 2018
Published in Issue Year 2020

Cite

APA Darfilal, D. (2020). SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR. Journal of Thermal Engineering, 6(2), 152-169. https://doi.org/10.18186/thermal.729318
AMA Darfilal D. SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR. Journal of Thermal Engineering. March 2020;6(2):152-169. doi:10.18186/thermal.729318
Chicago Darfilal, Djamal. “SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR”. Journal of Thermal Engineering 6, no. 2 (March 2020): 152-69. https://doi.org/10.18186/thermal.729318.
EndNote Darfilal D (March 1, 2020) SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR. Journal of Thermal Engineering 6 2 152–169.
IEEE D. Darfilal, “SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR”, Journal of Thermal Engineering, vol. 6, no. 2, pp. 152–169, 2020, doi: 10.18186/thermal.729318.
ISNAD Darfilal, Djamal. “SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR”. Journal of Thermal Engineering 6/2 (March 2020), 152-169. https://doi.org/10.18186/thermal.729318.
JAMA Darfilal D. SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR. Journal of Thermal Engineering. 2020;6:152–169.
MLA Darfilal, Djamal. “SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR”. Journal of Thermal Engineering, vol. 6, no. 2, 2020, pp. 152-69, doi:10.18186/thermal.729318.
Vancouver Darfilal D. SOLAR HYDROGEN PRODUCTION BY THERMOCHEMICAL REACTION: DEVELOPMENT OF A PACKED-BED REACTOR. Journal of Thermal Engineering. 2020;6(2):152-69.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering