Abstract
This paper describes an experimental study on a combined assembly of a solar pond and two-phase thermosyphon toward thermoelectric power generation under actual weather conditions and proposes its mandatory association with the biomass energy-based system. Experiments under the studied solar radiation intensity ranging between 26 W/m2 and 976 W/m2 reveal that the maximum steady-state temperature potential during the actual operation of a solar pond is not sufficient to generate the minimum threshold thermoelectric voltage for deriving necessary power needed to recharge a 12 V battery. It is also highlighted that solar radiation heats both the upper and the lower layers nearly equally; however, the heat is lost at a faster rate from the upper layer than the lower layer. Consequently, with the passage of time, the temperature of the lower layer rises, and interestingly, the probability of obtaining maximum voltage during a day is maximum during the early morning. Under the present set of conditions, the maximum temperature gain is 26.58 °C, whereas a minimum temperature potential of 45.62 °C is found necessary to produce the required voltage. The economic analysis of the proposed system reveals that the electricity generation obtained from the proposed system is better than diesel power generation. In particular, the system is suitable for locations where access to the conventional grid-based power is difficult. The work opens opportunities and establishes the necessity of developing low-cost thermoelectric materials for further improving the cost of power generation.
References
1.
Farahbod
, F.
, Mowla
, D.
, Jafari Nasr
, M. R.
, and Soltanieh
, M.
, 2012
, “Investigation of Solar Desalination Pond Performance Experimentally and Mathematically
,” ASME J. Energy Resour. Technol.
, 134
(4
), p. 041201
. 10.1115/1.40071942.
Ding
, L. C.
, Akbarzadeh
, A.
, Date
, A.
, and Frawley
, D. J.
, 2016
, “Passive Small Scale Electric Power Generation Using Thermoelectric Cells in Solar Pond
,” Energy
, 117
(1
), pp. 149
–165
. 10.1016/j.energy.2016.10.0853.
Karakilcik
, M.
, Dincer
, I.
, Bozkurt
, I.
, and Atiz
, A.
, 2013
, “Performance Assessment of a Solar Pond With and Without Shading Effect
,” Energy Convers. Manage.
, 65
, pp. 98
–107
. 10.1016/j.enconman.2012.07.0014.
Khalilian
, M.
, 2017
, “Experimental Investigation and Theoretical Modelling of Heat Transfer in Circular Solar Ponds by Lumped Capacitance Model
,” Appl. Therm. Eng.
, 121
, pp. 737
–749
. 10.1016/j.applthermaleng.2017.04.1295.
Abdullah
, A. A.
, Fallatah
, H. M.
, Lindsay
, K. A.
, and Oreijah
, M. M.
, 2017
, “Measurements of the Performance of the Experimental Salt-Gradient Solar Pond at Makkah One Year After Commissioning
,” Sol. Energy
, 150
, pp. 212
–219
. 10.1016/j.solener.2017.04.0406.
Velmurugan
, V.
, and Srithar
, K.
, 2008
, “Prospects and Scopes of Solar Pond: A Detailed Review
,” Renew. Sustain. Energy Rev.
, 12
(8
), pp. 2253
–2263
. 10.1016/j.rser.2007.03.0117.
Abbassi Monjezi
, A.
, and Campbell
, A. N.
, 2017
, “A Comparative Study of the Performance of Solar Ponds Under Middle Eastern and Mediterranean Conditions With Batch and Continuous Heat Extraction
,” Appl. Therm. Eng.
, 120
, pp. 728
–740
. 10.1016/j.applthermaleng.2017.03.0868.
Ramadan
, M. R. I.
, El-Sebaii
, A. A.
, Aboul-Enein
, S.
, and Khallaf
, A. M.
, 2004
, “Experimental Testing of a Shallow Solar Pond With Continuous Heat Extraction
,” Energy Buildings
, 36
(9
), pp. 955
–964
. 10.1016/j.enbuild.2004.03.0029.
Fuqiang
, C.
, Yanji
, H.
, and Chao
, Z.
, 2014
, “A Physical Model for Thermoelectric Generators With and Without Thomson Heat
,” ASME J. Energy Resour. Technol.
, 136
(1
), p. 011201
. 10.1115/1.402628010.
Chen
, J.
, and Wu
, C.
, 1999
, “Analysis on the Performance of a Thermoelectric Generator
,” ASME J. Energy Resour. Technol.
, 122
(2
), pp. 61
–63
. 10.1115/1.48316311.
Crane
, D. T.
, and Bell
, L. E.
, 2009
, “Design to Maximize Performance of a Thermoelectric Power Generator With a Dynamic Thermal Power Source
,” ASME J. Energy Resour. Technol.
, 131
(1
), p. 012401
. 10.1115/1.306639212.
Hendricks
, T. J.
, 2007
, “Thermal System Interactions in Optimizing Advanced Thermoelectric Energy Recovery Systems
,” ASME J. Energy Resour. Technol.
, 129
(3
), pp. 223
–231
. 10.1115/1.275150413.
Schock
, H.
, Brereton
, G.
, Case
, E.
, D'Angelo
, J.
, Hogan
, T.
, Lyle
, M.
, Maloney
, R.
, Moran
, K.
, Novak
, J.
, Nelson
, C.
, Panayi
, A.
, Ruckle
, T.
, Sakamoto
, J.
, Shih
, T.
, Timm
, E.
, Zhang
, L.
, and Zhu
, G.
, 2013
, “Prospects for Implementation of Thermoelectric Generators as Waste Heat Recovery Systems in Class 8 Truck Applications
,” ASME J. Energy Resour. Technol.
, 135
(2
), p. 022001
. 10.1115/1.402309714.
Ran
, Y.
, Deng
, Y.
, Hu
, T.
, Su
, C.
, and Liu
, X.
, 2018
, “Energy Efficient Thermoelectric Generator-Powered Localized Air-Conditioning System Applied in a Heavy-Duty Vehicle
,” ASME J. Energy Resour. Technol.
, 140
(7
), p. 072007
. 10.1115/1.403960715.
Singh
, R.
, Tundee
, S.
, and Akbarzadeh
, A.
, 2011
, “Electric Power Generation From Solar Pond Using Combined Thermosyphon and Thermoelectric Modules
,” Sol. Energy
, 85
(2
), pp. 371
–378
. 10.1016/j.solener.2010.11.01216.
Ding
, L. C.
, Akbarzadeh
, A.
, and Date
, A.
, 2016
, “Electric Power Generation via Plate Type Power Generation Unit From Solar Pond Using Thermoelectric Cells
,” Appl. Energy
, 183
, pp. 61
–76
. 10.1016/j.apenergy.2016.08.16117.
Huminic
, G.
, and Huminic
, A.
, 2011
, “Heat Transfer Characteristics of a Two-Phase Closed Thermosyphons Using Nanofluids
,” Exp. Therm. Fluid Sci.
, 35
(3
), pp. 550
–557
. 10.1016/j.expthermflusci.2010.12.00918.
Omer
, S. A.
, Riffat
, S. B.
, and Ma
, X.
, 2001
, “Experimental Investigation of a Thermoelectric Refrigeration System Employing a Phase Change Material Integrated With Thermal Diode (Thermosyphons)
,” Appl. Therm. Eng.
, 21
(12
), pp. 1265
–1271
. 10.1016/S1359-4311(01)00010-219.
Tan
, L.
, Singh
, R.
, and Akbarzadeh
, A.
, 2012
, “Thermal Performance of Two-Phase Closed Thermosyphon in Application of Concentrated Thermoelectric Power Generator Using Phase Change Material Thermal Storage
,” Front. Heat Pipes
, 2
(4
), p. 043001
. 10.5098/fhp.v2.4.300120.
Kumar
, A.
, Singh
, K.
, and Das
, R.
, 2019
, “Response Surface Based Experimental Analysis and Thermal Resistance Model of a Thermoelectric Power Generation System
,” Appl. Therm. Eng.
, 159
, p. 113935
. 10.1016/j.applthermaleng.2019.11393521.
Singh
, B.
, Gomes
, J.
, Tan
, L.
, Date
, A.
, and Akbarzadeh
, A.
, 2012
, “Small Scale Power Generation Using Low Grade Heat From Solar Pond
,” Procedia Eng.
, 49
, pp. 50
–56
. 10.1016/j.proeng.2012.10.11122.
Kumar
, A.
, Singh
, K.
, Verma
, S.
, and Das
, R.
, 2018
, “Inverse Prediction and Optimization Analysis of a Solar Pond Powering a Thermoelectric Generator
,” Sol. Energy
, 169
, pp. 658
–672
. 10.1016/j.solener.2018.05.03523.
Fathurrohman
, M. I.
, Maspanger
, D. R.
, and Sutrisno
, S.
, 2015
, “Vulcanization Kinetics and Mechanical Properties of Ethylene Propylene Diene Monomer Thermal Insulation
,” Bull. Chem. React. Eng. Catal.
, 10
(2
), pp. 104
–110
. 10.9767/bcrec.10.2.6682.104-11024.
Naresh
, Y.
, and Balaji
, C.
, 2017
, “Experimental Investigations of Heat Transfer From an Internally Finned Two Phase Closed Thermosyphon
,” Appl. Therm. Eng.
, 112
, pp. 1658
–1666
. 10.1016/j.applthermaleng.2016.10.08425.
Goswami
, R.
, and Das
, R.
, 2020
, “Waste Heat Recovery From a Biomass Heat Engine for Thermoelectric Power Generation Using Two-Phase Thermosyphons
,” Renew. Energy
, 148
, pp. 1280
–1291
. 10.1016/j.renene.2019.10.06726.
Goswami
, R.
, and Das
, R.
, 2019
, “Investigation of Thermal and Electrical Performance in a Salt Gradient Solar Pond
,” J. Phys. Conf. Ser.
, 1240
, p. 012111
. 10.1088/1742-6596/1240/1/01211127.
Taggar
, G. K.
, Singh
, R.
, Kumar
, R.
, and Pathania
, P. C.
, 2012
, “First Report of Flower Chafer Beetle, Oxycetonia Versicolor, on Pigeonpea and Mungbean From Punjab, India
,” Phytoparasitica
, 40
(3
), pp. 207
–211
. 10.1007/s12600-012-0222-828.
Goswami
, R.
, and Das
, R.
, 2020
, “Energy Cogeneration Study of Red Mulberry (Morus Rubra)-Based Biomass
,” Energy Sources A.
, 42
(8
), pp. 979
–1000
. 10.1080/15567036.2019.160221029.
Jadhao
, J. S.
, and Thombare
, D. G.
, 2013
, “Review on Exhaust Gas Heat Recovery for IC Engine
,” Int. J. Eng. Innov. Technol.
, 2
(12
), pp. 93
–100
.30.
Wu
, C. Z.
, Huang
, H.
, Zheng
, S. P.
, and Yin
, X. L.
, 2002
, “An Economic Analysis of Biomass Gasification and Power Generation in China
,” Bioresource Technol.
, 83
(1
), pp. 65
–70
. 10.1016/S0960-8524(01)00116-X31.
Panwar
, N. L.
, and Rathore
, N. S.
, 2009
, “Potential of Surplus Biomass Gasifier Based Power Generation: A Case Study of an Indian State Rajasthan
,” Mitig. Adapt. Strateg. Glob. Change
, 14
(8
), pp. 711
–720
. 10.1007/s11027-009-9192-732.
Ghosh
, S.
, Das
, T. K.
, and Jash
, T.
, 2004
, “Sustainability of Decentralized Woodfuel-Based Power Plant: An Experience in India
,” Energy
, 29
(1
), pp. 155
–166
. 10.1016/S0360-5442(03)00158-033.
Kumar
, A.
, Kumar
, K.
, Kaushik
, N.
, Sharma
, S.
, and Mishra
, S.
, 2010
, “Renewable Energy in India: Current Status and Future Potentials
,” Renew. Sustain. Energy Rev.
, 14
(8
), pp. 2434
–2442
. 10.1016/j.rser.2010.04.00334.
Leung
, D. Y.
, Yin
, X. L.
, and Wu
, C. Z.
, 2004
, “A Review on the Development and Commercialization of Biomass Gasification Technologies in China
,” Renew. Sustain. Energy Rev.
, 8
(6
), pp. 565
–580
. 10.1016/j.rser.2003.12.01035.
Ravindranath
, N. H.
, and Balachandra
, P.
, 2009
, “Sustainable Bioenergy for India: Technical, Economic and Policy Analysis
,” Energy
, 34
(8
), pp. 1003
–1013
. 10.1016/j.energy.2008.12.01236.
Singh
, K.
, and Das
, R.
, 2016
, “An Experimental and Multi-Objective Optimization Study of a Forced Draft Cooling Tower With Different Fills
,” Energy Convers. Manage.
, 111
, pp. 417
–430
. 10.1016/j.enconman.2015.12.080Copyright © 2020 by ASME
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