DESIGN OF HEAT STORAGE SYSTEM FOR PARABOLIC DISH TYPE SOLAR COOKER

##plugins.themes.academic_pro.article.sidebar##

Published
Deprecated: Function strftime() is deprecated in /home/iejrdcom/public_html/lib/pkp/lib/vendor/smarty/smarty/libs/plugins/modifier.date_format.php on line 81
Dec 4, 2021
https://doi.org/10.17605/OSF.IO/3TY45
Download
PDF
Statistic

Downloads

Download data is not yet available.
Vol. 6 No. 6 (2021): Voulme 6 Issue 6

##plugins.themes.academic_pro.article.main##

Harshal Patil
Phd Scholar, Mechanical Engineering, Prof. Ram Meghe Institute of Technology and Reseach, Badnera
Dr. Nishikant Kale
Professor, Mechanical Engineering, Prof. Ram Meghe Institute of Technology and Reseach, Badnera

Abstract

Solar energy is available freely and does not create any pollution to the environment. Hence, researchers from all around the world are always working on solar energy applications with enhancement technologies. The solar cooker is one of the largest solar energy application, which is used to cook the food. However, because the solar energy is available only during the daytime, solar cookers are not getting popularity as the main device for cooking. To store the heat during the day, energy storage system is required. Hence, this study presents the design of heat storage system for parabolic dish type solar cooker. Heat storage unit is used to store heat during daytime and use for other than daytime hours. Also, the two types of heat storing materials were considered for analysis and compared. Hence, with proposed heat storage unit the cooking is possible even in the evening with a solar cooker. So that, solar cooker with storage unit is very beneficial for the humans and as well as for the energy conservation

##plugins.themes.academic_pro.article.details##

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

How to Cite
[1]
Harshal Patil and Dr. Nishikant Kale, “DESIGN OF HEAT STORAGE SYSTEM FOR PARABOLIC DISH TYPE SOLAR COOKER”, IEJRD - International Multidisciplinary Journal, vol. 6, no. 6, p. 11, Dec. 2021.
Crossref
Scopus
Google Scholar
Europe PMC

References

  1. Kale DM (2012) Non-conventional energy sources: current scenario and future trends, a key-note address. In: 9th Biennial international conference and exposition on petroleum geophysics, Hyderabad
  2. Nandwani SS (2007) Design, construction and study of a hybrid solar food processor in the climate of Costa Rica. Renew Energy 32:427–441
  3. Hajian M (2013) Various aspects of solar energy utilization: review. Int J Adv Sci Technol 58:41–50
  4. Singh M, Sethi VP (2018) On the design, modelling and analysis of multi-shelf inclined solar cooker-cum-dryer. Sol Energy 162:620–636
  5. Jaluria Y (1989) Design, optimization and control of a thermal energy storage system. Energy storage systems. Kluwer Academic Publishers, pp 89–116
  6. Yettou F, Azoui B, Malek A, Gama A, Panwar NL (2014) Solar cooker realizations in actual use: an overview. Renew Sustain Energy Rev 37:288–306
  7. Mahavar S, Sengar N, Rajawat P, Verma M, Dashora P (2012) Design development and performance studies of a novel Single Family Solar. Renew Energy 47:67–76
  8. .uce E, Cuce PM (2013) A comprehensive review on solar cookers. Appl Energy 102:1399–1421
  9. Saxena A, Pandey SP, Srivastav G (2011) A thermodynamic review on solar box type cookers. Renew Sustain Energy Rev 15:3301–3318
  10. Avilés G, Juan J (2014) Thermal model of a solar cooker jorhejpataranskua.Energy Procedia 57:1623–1631
  11. Azam M, Jamil Y, Musadiq M, Zhaira R, Yasir Javed M (2009) Fabrication and performance study of slope type electric cum solar oven. Pak J Agric Sci 46(3):228–231
  12. Otte PP (2014) Solar cooking in Mozambique—an investigation of end- user’s needs for the design of solar cookers. Energy Policy 74:366–375
  13. Dheep GR (2014) Latent heat storage system for solar thermal energy applications. Voice of Research 2(4):80–86
  14. Muthusivagami RM, Velraj R, Sethumadhavan R (2010) Solar cookers with and without thermal storage—a review. Renew Sustain Energy Rev 14:691–701
  15. Prasanna LUUR (2011) Modeling and design of a solar thermal system for hybrid cooking application. Appl Energy 88:1740–1755
  16. Abdulateef AM, Abdulateef J, Mat S, Sopian K, Elhub B, Mussa MA (2018) Experimental and numerical study of solidifying phase-chang Experimental and numerical study of solidifying phase-change material in a triplex-tube heat exchanger with longitudinal/triangular fins. Int Commun Heat Mass Transfer 90:73–84
  17. Sosa LBL, Avilés MG, Pérez DG, Gutiérrez YS (2014) Rural Solar Cookers, an alternative to reduce the timber resource extraction through the use of renewable energy sources: technology transfer and monitoring project. Energy Procedia 57:1593–1602
  18. Prasanna LUUR (2011) Optimization and design of energy transport system for solar cooking application. Appl Energy88:242–251
  19. Bansal M, Saini RP, Khatod DK (2013) Development of cooking sector in rural areas in India—a review. Renew Sustain Energy Rev 17:44–53
  20. Zhao J, Ji Y, Yuan Y, Zhang Z, Lu J (2018) Energy-saving analysis of solar heating system with PCM storage tank. Energies 11:1–19
  21. Hussein HE-GSNHMS (2008) Experimental investigation of novel indirect solar cooker with indoor PCM thermal storage and cooking unit. Energy Convers Manag 49:2237–2246
  22. Hossain RSHFNRMIJAMRMS (2011) Review on solar water heater collector and thermal energy performance of circulating pipe. Renew Sustain Energy Rev 15:3801–3912
  23. Kalogirou SA (2004) Solar thermal collectors and applications. Prog Energy Combust Sci 30:231–295
  24. Kumar N, Budhiraja A, Rohilla S (2016) Feasibility of a solar cooker in off sunshine hours using pcm as the source of heat. Adv Eng Int J 1(1):33–39
  25. Sulaiman FSA (2011) Development of a thermal energy storage for the integrated solar energy project. R&D J South Afric Inst Mech Eng, pp 6–11
  26. Indora S, Kandpal TC (2018) Financial appraisal of using Scheffler dish for steam based institutional. Renew Energy 30:1–12
  27. Flueckiger SM, Yang Z, SV Garimella (2013) Design of moltensalt thermocline tanks for solar thermal energy storage. CTRC Research Publications, pp 1–50
  28. Qiu S, White M (2013) Phase change material thermal energy storage system design and optimization. In: Proceeding of ASME 2013, 7th international conference on energy sustainability and 11th fuel cell science, engg & tech conference, ESfuel cell 2013, Minneapolis, MN, USA
  29. Magin BWMJASDDTRL (1961) Transition temperatures of the hydrates of Na2S04, Na2HP04 and KF as fixed points in biomedical thermometry. J Res Natl Bureau Stand 86(2):181–192
  30. Thulukkanam, K., 2013. Classification of Heat Exchanger. Heat Exchanger Design Handbook, 2nd ed.; CRC Press Taylor & Francis Group: Boca Raton, FL, USA, pp.1-27.
  31. Thermopedia B. R.J., Standards of the Tubular Exchanger Manufacturers Association, (TEMA [Online]. Available: http://dx.doi.org/10.1615/AtoZ.s.shell_and_tube_heat exchangers.,
  32. HPLubricants," Hindustan Petrolium, 2019. [Online]. Available: at https://www.hplubricants.in/products/specialties/thermic-fluids/hytherm-500-and-600-thermic-fluid-oil.
  33. "Heat Transfer Fluid by SOLUTIA," Sollutia, [Online]. Available: http://twt.mpei.ac.ru/TTHB/HEDH/HTF-66.PDF.
  34. J. P. Holman, 2010. Heat Transfer, Ney York: McGraw Hill Companies, Inc.
  35. A. Solé, X. Fontanet, C. Barreneche, I. Martorell, A. I. Fernández and L. F. Cabeza, "Parameters to take into account when developing a new thermochemical energy storage system, Energy Procedia, no. 30, pp. 380-387, 2012.
  36. Solé, A., Neumann, H., Niedermaier, S., Cabeza, L.F. and Palomo, E., 2014. Thermal stability test of sugar alcohols as phase change materials for medium temperature energy storage application. Energy Procedia, 48, pp.436-439.
  37. Tian, Y. and Zhao, C.Y., 2013. A review of solar collectors and thermal energy storage in solar thermal applications. Applied energy, 104, pp.538-553.
  38. Solé, A., Fontanet, X., Barreneche, C., Martorell, I., Fernández, A.I. and Cabeza, L.F., 2012. Parameters to take into account when developing a new thermochemical energy storage system. Energy Procedia, 30, pp.380-387.
  39. Qiu, S., Galbraith, R. and White, M., 2013, July. Phase change material thermal energy storage system design and optimization. In Energy Sustainability (Vol. 55515, p. V001T11A011). American Society of Mechanical Engineers
  40. Gasia, J., Martin, M., Solé, A., Barreneche, C. and Cabeza, L.F., 2017. Phase change material selection for thermal processes working under partial load operating conditions in the temperature range between 120 and 200° C. Applied Sciences, 7(7), p.722.

Deprecated: Return type of Stringy\Stringy::count() should either be compatible with Countable::count(): int, or the #[\ReturnTypeWillChange] attribute should be used to temporarily suppress the notice in /home/iejrdcom/public_html/lib/pkp/lib/vendor/danielstjules/stringy/src/Stringy.php on line 270

Deprecated: Return type of Stringy\Stringy::getIterator() should either be compatible with IteratorAggregate::getIterator(): Traversable, or the #[\ReturnTypeWillChange] attribute should be used to temporarily suppress the notice in /home/iejrdcom/public_html/lib/pkp/lib/vendor/danielstjules/stringy/src/Stringy.php on line 453

Deprecated: Return type of Stringy\Stringy::offsetExists($offset) should either be compatible with ArrayAccess::offsetExists(mixed $offset): bool, or the #[\ReturnTypeWillChange] attribute should be used to temporarily suppress the notice in /home/iejrdcom/public_html/lib/pkp/lib/vendor/danielstjules/stringy/src/Stringy.php on line 850

Deprecated: Return type of Stringy\Stringy::offsetGet($offset) should either be compatible with ArrayAccess::offsetGet(mixed $offset): mixed, or the #[\ReturnTypeWillChange] attribute should be used to temporarily suppress the notice in /home/iejrdcom/public_html/lib/pkp/lib/vendor/danielstjules/stringy/src/Stringy.php on line 873

Deprecated: Return type of Stringy\Stringy::offsetSet($offset, $value) should either be compatible with ArrayAccess::offsetSet(mixed $offset, mixed $value): void, or the #[\ReturnTypeWillChange] attribute should be used to temporarily suppress the notice in /home/iejrdcom/public_html/lib/pkp/lib/vendor/danielstjules/stringy/src/Stringy.php on line 893

Deprecated: Return type of Stringy\Stringy::offsetUnset($offset) should either be compatible with ArrayAccess::offsetUnset(mixed $offset): void, or the #[\ReturnTypeWillChange] attribute should be used to temporarily suppress the notice in /home/iejrdcom/public_html/lib/pkp/lib/vendor/danielstjules/stringy/src/Stringy.php on line 906