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Parabolik Oluklu Solar Kollektörlerin Termal Verimliliğinin Artırılması: Genel Bakış

Year 2023, , 781 - 800, 15.09.2023
https://doi.org/10.31466/kfbd.1213666

Abstract

Bu çalışmada, parabolik oluklu güneş kolektörlerin termal verimliliğini hem teorik hem de pratik olarak artırmak için çeşitli yöntemler incelenmiştir. Bu yöntemler arasında güneş enerjisini absorbe etme yeteneğini artırmak için emici tüpün yüzey alanını artırmak, ısı transferini iyileştirmek için tüp içine turbülatör yerleştirmek yer almaktadır. Ayrıca emici tüpün yüzeyinden yansımayı azaltmak için seçici kaplamalar kullanarak yansımayı en aza indirmek gibi yöntemler de bulunmaktadır. Bunlara ek olarak, çalışma sıvısı için termal iletkenliği artırmak, emici tüpün şeklini değiştirmek ve kollektör ve yansıtıcı yüzeyin geometrisini iyileştirmek gibi diğer tekniklerin de emicinin termal performansını artırabildiği ortaya konulmuştur. Bu teknikler, parabolik oluklu güneş kollektörünün verimliliğini ve termal performansını artırmaya yol açmaktadır. Ancak aynı zamanda çalışma sıvısının basınç düşüşünü ve malzeme maliyetinde artışı da beraberinde getirmektedir. Bu çalışmada, bu teknikler önceki çalışmaların sonuçlarına bağlı olarak ayrıntılı olarak sunulmuştur.

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References

  • Abed, N.et al.,. (2021). Thermal-Hydraulic Analysis of Parabolic Trough Collectors Using Straight Conical Strip Inserts with Nanofluids. Nanomaterials, 11(853), 1-30.
  • Al-Ansary, H. et al.,. (2011). Numerical study of conduction and convection heat losses from a half-insulated air-filled annulus of the receiver of a parabolictrough collector. Solar Energy, 85, 3036–3045.
  • Ambrosini, A. et al.,. (2015). Thermal stability of oxide-based solar selective coatings for CSP central receivers. ASME 9th International Conference on Energy Sustainability Collocated : American Society of Mechanical Engineers Digital Collection.
  • Asaad, Y. A.-R. (2022). Selective Absorber Coatings and Technological Advancements in Performance Enhancement for Parabolic Trough Solar Collector. Journal of Thermal Science, 11630-022, 1990-2008.
  • Arutyunov, Vladimir S.et al.,. (2017). Energy resources of the 21st century: Problems and forecasts. Can renewable energy sources replace fossil fuels, Russian Chemical Reviews 86.8 777.
  • Bellos, E. et al.,. (2017). Multi-criteria evaluation of parabolic trough collector with internally finned absorbers. Applied Energy, 205, 540-561.
  • Bellos, E. et al.,. (2016). Thermal enhancement of solar parabolic trough collectors by using nanofluids and converging-diverging absorber tube. Renewable Energy 94, 213–222.
  • Benabderrahmane, A. et al.,. (2016). Heat Transfer Enhancement in a Parabolic Trough Solar Receiver using Longitudinal Fins and Nanofluids. Journal Of Thermal Science, 25, 410-417.
  • Benito, R. et al.,. (2015). Enhancing heat transfer in air tubular absorbers for concentrated solar thermal applications. Applied Thermal Engineering, 50(1), 1076-1083.
  • Chakraborty, O. (2021). Effect of helical absorber tube on the energy and exergy analysis of parabolic solar trough collector – A computational analysis. Sustainable Energy Technologies, 44(101), 70-83.
  • Chen, C. J. (2011). Physics Of Solar Energy.
  • Diwan, K. et al.,. (2015). Heat Transfer Enhancement in Absorber Tube of Parabolic Trough Concentrators Using Wire-Coils Inserts. Universal Journal of Mechanical Engineering, 3(3), 107-112.
  • Ediger, V. Et al.,. (1999). Renewable energy potential as an alternative to fossil fuels in Turkey. Energy Conversion And Management, 40(7) 743-755.
  • Ghasemi, S. E. et al.,. (2017). Numerical thermal study on effect of porous rings on performance of solar parabolic trough collector. Applied Thermal Engineering, 118, 807-816.
  • Jamal-Abad, M. T. et al.,. (2017). Experimental investigation on a solar parabolic trough collector for absorber tube filled with porous media. Renewable Energy, 107, 156-163.
  • Jaramillo, O. et al.,. (2016). Parabolic trough solar collector for low enthalpy processes: An analysis of the efficiency enhancement by using twisted tape inserts. Renewable Energy, 93, 125–141.
  • Kilic, A. et al.,. (1983). Solar Energy (in Turkish). Kipas Distribution Inc.
  • Kulahli, M.C. et al., (2019). Numerical simulation of a parabolic trough collector containing a novel parabolic reflector with varying focal length. Applied Thermal Engineering, 161, 114210.
  • Mao, Q. et al.,. (2014). Study on radiation flux of the receiver with a parabolic solar concentrator system. Energy Conversion and Management, 84, 1-6.
  • Marefati, M. et al.,. (2018). Optical and thermal analysis of a parabolic trough solar collector for production of thermal energy in different climates in Iran with comparison between the conventional nanofluids. Journal Of Cleaner Production, 175, 294–313.
  • Mohammad, S. D. (2021). Efficiency of the parabolic through solar collector using NiFe2O4/Water nanofluid and U-tube. Journal of the Taiwan Institute of Chemical Engineers 120, 136-149.
  • Muñoz, J. et al.,. (2011). A technical note on application of internally finned tubes in solar parabolic trough absorber pipes. Solar Energy, 85(3), 609-612.
  • Öner. (2022). Investigation of the effects of flipped triangle pipe inserts on thermal efficiency in a parabolic trough solar collector. Heat Transfer Research, 54(3), 1-22.
  • Özakin. (2022). CFD analysis of using umbrella shaped turbulators to improve heat transfer in a horizontal pipe. International Journal of Innovative Research and Reviews, 6(1), 30-34.
  • Ozakin, A. N. et al.,. (2020). Performance analysis of photovoltaic-heat pump (PV/T) combined systems: A comparative numerical study. Journal of Solar Energy Engineering, 142(2).
  • Premjit, D. (2011). Numerical investigation of parabolic trough receiver performance with outer vacuum shell. Solar Energy, 85, 1910–1914.
  • Reddy, k. S. et al.,. (2015). Experimental investigation of porous disc enhanced receiver for solar parabolic trough collector. Renewable Energy, 77, 308-319.
  • Rehan, M. A. et al.,. (2018). Experimental performance analysis of low concentration ratio solar parabolic trough collectors with nanofluids in winter conditions. Renewable Energy, 118, 742–751.
  • Saedodin, S. et al.,. (2021). Hydrothermal analysis of heat transfer and thermal performance characteristics in a parabolic trough solar collector with Turbulence-Inducing elements. Sustainable Energy Technologies, 46, 141-166.
  • Sahin, H. M. et al.,. (2015). Investigation of heat transfer enhancement in a new type heat exchanger using solar parabolic trough systems. International Journal of Hydrogen, 40(44), 15254-15266.
  • Sanaz, A. (2020). Energy and exergy analysis of a parabolic trough collector usinghelically corrugated absorber tube. Renewable Energy, 155, 735-747.
  • Sharma, K. et al.,. (2014). An Experimental Investigation into the Performance of a Nanofluid Based Concentrating Parabolic Solar Collector (NCPSC). PhD diss. Thapar Institute.
  • Soudani, M. E. et al.,. (2017). Experimental and theoretical study of parabolic trough collector (PTC) with a flat glass cover in the region of Algerian sahara (Ouargla). Journal of Mechanical Science and Technology, 31(8), 4003-4009.
  • Taher, M.A. et al.,.(2023). A novel design to optimize the optical performances of parabolic trough collector using Taguchi, ANOVA and grey relational analysis methods. Renewable Energy, 216,119105.
  • Wang, E. A. (2020). Progress in concentrated solar power technology with parabolic trough collector system: A comprehensive review. School of Automobile Engineering.
  • Yesildal, F. (2022). Experimental Optimization and CFD Model Verification of the Parabolic Trough Collector with a Staggered Butterfly Finned Pipe Inserts. Heat Transfer Research, 53(1).
  • York, R. (2019). Energy transitions or additions?: Why a transition from fossil fuels requires more than the growth of renewable energy. Energy Research & Social Science, 51, 40-43.

Improving the Thermal Efficiency of the Parabolic Trough Solar Collector: An Overview

Year 2023, , 781 - 800, 15.09.2023
https://doi.org/10.31466/kfbd.1213666

Abstract

This article examines various methods to enhance the thermal efficiency of parabolic trough solar collectors (PTCs), both theoretically and experimentally. These methods include increasing the surface area of the absorber tube to increase its ability to absorb solar energy, placing a tube inserts inside the tube to induce turbulence and hence improve heat transfer. Among other methods are also minimization of reflection by using selective coatings on the surface of the absorber tube. Additionally, increasing the thermal conductivity of the working fluid, or modifying or altering the shape of the absorber tube or the reflective surface have also been shown to have improved thermal performance by minimizing energy losses due to conduction, convection, and radiation. All these and similar approaches that address and improve system parameters lead to improved efficiency and thermal performance, but they also entail a pressure drop and increase the cost of the system. In this study, the techniques that are used to improve the thermal efficiency of PTCs are addressed and presented in detail along with the findings of previous studies.

Project Number

Yok

References

  • Abed, N.et al.,. (2021). Thermal-Hydraulic Analysis of Parabolic Trough Collectors Using Straight Conical Strip Inserts with Nanofluids. Nanomaterials, 11(853), 1-30.
  • Al-Ansary, H. et al.,. (2011). Numerical study of conduction and convection heat losses from a half-insulated air-filled annulus of the receiver of a parabolictrough collector. Solar Energy, 85, 3036–3045.
  • Ambrosini, A. et al.,. (2015). Thermal stability of oxide-based solar selective coatings for CSP central receivers. ASME 9th International Conference on Energy Sustainability Collocated : American Society of Mechanical Engineers Digital Collection.
  • Asaad, Y. A.-R. (2022). Selective Absorber Coatings and Technological Advancements in Performance Enhancement for Parabolic Trough Solar Collector. Journal of Thermal Science, 11630-022, 1990-2008.
  • Arutyunov, Vladimir S.et al.,. (2017). Energy resources of the 21st century: Problems and forecasts. Can renewable energy sources replace fossil fuels, Russian Chemical Reviews 86.8 777.
  • Bellos, E. et al.,. (2017). Multi-criteria evaluation of parabolic trough collector with internally finned absorbers. Applied Energy, 205, 540-561.
  • Bellos, E. et al.,. (2016). Thermal enhancement of solar parabolic trough collectors by using nanofluids and converging-diverging absorber tube. Renewable Energy 94, 213–222.
  • Benabderrahmane, A. et al.,. (2016). Heat Transfer Enhancement in a Parabolic Trough Solar Receiver using Longitudinal Fins and Nanofluids. Journal Of Thermal Science, 25, 410-417.
  • Benito, R. et al.,. (2015). Enhancing heat transfer in air tubular absorbers for concentrated solar thermal applications. Applied Thermal Engineering, 50(1), 1076-1083.
  • Chakraborty, O. (2021). Effect of helical absorber tube on the energy and exergy analysis of parabolic solar trough collector – A computational analysis. Sustainable Energy Technologies, 44(101), 70-83.
  • Chen, C. J. (2011). Physics Of Solar Energy.
  • Diwan, K. et al.,. (2015). Heat Transfer Enhancement in Absorber Tube of Parabolic Trough Concentrators Using Wire-Coils Inserts. Universal Journal of Mechanical Engineering, 3(3), 107-112.
  • Ediger, V. Et al.,. (1999). Renewable energy potential as an alternative to fossil fuels in Turkey. Energy Conversion And Management, 40(7) 743-755.
  • Ghasemi, S. E. et al.,. (2017). Numerical thermal study on effect of porous rings on performance of solar parabolic trough collector. Applied Thermal Engineering, 118, 807-816.
  • Jamal-Abad, M. T. et al.,. (2017). Experimental investigation on a solar parabolic trough collector for absorber tube filled with porous media. Renewable Energy, 107, 156-163.
  • Jaramillo, O. et al.,. (2016). Parabolic trough solar collector for low enthalpy processes: An analysis of the efficiency enhancement by using twisted tape inserts. Renewable Energy, 93, 125–141.
  • Kilic, A. et al.,. (1983). Solar Energy (in Turkish). Kipas Distribution Inc.
  • Kulahli, M.C. et al., (2019). Numerical simulation of a parabolic trough collector containing a novel parabolic reflector with varying focal length. Applied Thermal Engineering, 161, 114210.
  • Mao, Q. et al.,. (2014). Study on radiation flux of the receiver with a parabolic solar concentrator system. Energy Conversion and Management, 84, 1-6.
  • Marefati, M. et al.,. (2018). Optical and thermal analysis of a parabolic trough solar collector for production of thermal energy in different climates in Iran with comparison between the conventional nanofluids. Journal Of Cleaner Production, 175, 294–313.
  • Mohammad, S. D. (2021). Efficiency of the parabolic through solar collector using NiFe2O4/Water nanofluid and U-tube. Journal of the Taiwan Institute of Chemical Engineers 120, 136-149.
  • Muñoz, J. et al.,. (2011). A technical note on application of internally finned tubes in solar parabolic trough absorber pipes. Solar Energy, 85(3), 609-612.
  • Öner. (2022). Investigation of the effects of flipped triangle pipe inserts on thermal efficiency in a parabolic trough solar collector. Heat Transfer Research, 54(3), 1-22.
  • Özakin. (2022). CFD analysis of using umbrella shaped turbulators to improve heat transfer in a horizontal pipe. International Journal of Innovative Research and Reviews, 6(1), 30-34.
  • Ozakin, A. N. et al.,. (2020). Performance analysis of photovoltaic-heat pump (PV/T) combined systems: A comparative numerical study. Journal of Solar Energy Engineering, 142(2).
  • Premjit, D. (2011). Numerical investigation of parabolic trough receiver performance with outer vacuum shell. Solar Energy, 85, 1910–1914.
  • Reddy, k. S. et al.,. (2015). Experimental investigation of porous disc enhanced receiver for solar parabolic trough collector. Renewable Energy, 77, 308-319.
  • Rehan, M. A. et al.,. (2018). Experimental performance analysis of low concentration ratio solar parabolic trough collectors with nanofluids in winter conditions. Renewable Energy, 118, 742–751.
  • Saedodin, S. et al.,. (2021). Hydrothermal analysis of heat transfer and thermal performance characteristics in a parabolic trough solar collector with Turbulence-Inducing elements. Sustainable Energy Technologies, 46, 141-166.
  • Sahin, H. M. et al.,. (2015). Investigation of heat transfer enhancement in a new type heat exchanger using solar parabolic trough systems. International Journal of Hydrogen, 40(44), 15254-15266.
  • Sanaz, A. (2020). Energy and exergy analysis of a parabolic trough collector usinghelically corrugated absorber tube. Renewable Energy, 155, 735-747.
  • Sharma, K. et al.,. (2014). An Experimental Investigation into the Performance of a Nanofluid Based Concentrating Parabolic Solar Collector (NCPSC). PhD diss. Thapar Institute.
  • Soudani, M. E. et al.,. (2017). Experimental and theoretical study of parabolic trough collector (PTC) with a flat glass cover in the region of Algerian sahara (Ouargla). Journal of Mechanical Science and Technology, 31(8), 4003-4009.
  • Taher, M.A. et al.,.(2023). A novel design to optimize the optical performances of parabolic trough collector using Taguchi, ANOVA and grey relational analysis methods. Renewable Energy, 216,119105.
  • Wang, E. A. (2020). Progress in concentrated solar power technology with parabolic trough collector system: A comprehensive review. School of Automobile Engineering.
  • Yesildal, F. (2022). Experimental Optimization and CFD Model Verification of the Parabolic Trough Collector with a Staggered Butterfly Finned Pipe Inserts. Heat Transfer Research, 53(1).
  • York, R. (2019). Energy transitions or additions?: Why a transition from fossil fuels requires more than the growth of renewable energy. Energy Research & Social Science, 51, 40-43.
There are 37 citations in total.

Details

Primary Language English
Subjects Mechanical Engineering
Journal Section Articles
Authors

Faruk Yeşildal 0000-0002-7307-3556

Ahmet Numan Özakın 0000-0002-2083-8703

Safaa Baamel 0000-0002-5828-3301

Ahmad Alagele 0000-0001-6353-1157

Project Number Yok
Publication Date September 15, 2023
Published in Issue Year 2023

Cite

APA Yeşildal, F., Özakın, A. N., Baamel, S., Alagele, A. (2023). Improving the Thermal Efficiency of the Parabolic Trough Solar Collector: An Overview. Karadeniz Fen Bilimleri Dergisi, 13(3), 781-800. https://doi.org/10.31466/kfbd.1213666