Study on an indirect solar dryer for drying sliced bitter gourd using PCM
| dc.contributor.author | M.K. Murthi | eng |
| dc.contributor.author | P. Manoj Kumar | eng |
| dc.contributor.author | Sunil Kumar Bandili | eng |
| dc.contributor.author | Pradeep Johnson | eng |
| dc.contributor.author | M. Sakthivel | eng |
| dc.date.accessioned | 2025-02-06 00:00:00 | |
| dc.date.available | 2025-02-06 00:00:00 | |
| dc.date.issued | 2025-02-06 | |
| dc.description.abstract | Solar dryers are of significant importance in the food industry since they facilitate the preservation of various edible products, including cereals, vegetables, and fish, by effectively extracting moisture from products. In the current study, an indirect type cabinet solar dryer had been constructed to dry the bitter gourd pieces. To enhance the efficacy of the solar dryer during late evening hours, an inorganic salt, sodium thiosulfate pentahydrate (Na2S2O3. 5H2O) serving as a phase changing material (PCM), was incorporated into the collecting area of the dryer. The study examined the process parameters, including the moisture ratio, dryer inlet temperature and the outlet temperature, for the dehydration of sliced bitter gourds in two scenarios: an indirect solar dryer without phase change material (IDSD), and a solar dryer with PCM (IDSD-PCM). The experiment involved maintaining a constant mass flow rate of air at 0.07 kg/s, while operating the dryer for a duration of nine hours in an experimental day. The findings obtained were evaluated, and the impact of incorporating PCM into the indirect solar dryer was examined and reported. The findings of the study indicated that the inclusion of PCM inside the collecting area had a substantial impact on the temperature of the drying chamber, particularly during the late evening hours. Furthermore, the utilization of PCM resulted in a notable increase of 5.1% per day in the proportion of moisture extracted from sliced bitter gourds. | eng |
| dc.format.mimetype | application/pdf | eng |
| dc.identifier.doi | 10.32397/tesea.vol6.n1.665 | |
| dc.identifier.eissn | 2745-0120 | |
| dc.identifier.url | https://doi.org/10.32397/tesea.vol6.n1.665 | |
| dc.language.iso | eng | eng |
| dc.publisher | Universidad Tecnológica de Bolívar | eng |
| dc.relation.bitstream | https://revistas.utb.edu.co/tesea/article/download/665/448 | |
| dc.relation.citationedition | Núm. 1 , Año 2025 : Transactions on Energy Systems and Engineering Applications | eng |
| dc.relation.citationendpage | 14 | |
| dc.relation.citationissue | 1 | eng |
| dc.relation.citationstartpage | 1 | |
| dc.relation.citationvolume | 6 | eng |
| dc.relation.ispartofjournal | Transactions on Energy Systems and Engineering Applications | eng |
| dc.relation.references | Azwin Kamarulzaman, M. Hasanuzzaman, and N.A. Rahim. Global advancement of solar drying technologies and its future prospects: A review. Solar Energy, 221:559–582, June 2021. [2] Hany S. EL-Mesery, Ahmed I. EL-Seesy, Zicheng Hu, and Yang Li. Recent developments in solar drying technology of food and agricultural products: A review. Renewable and Sustainable Energy Reviews, 157:112070, April 2022. [3] P. Manoj Kumar, K. Mylsamy, Karthick Alagar, and K. Sudhakar. Investigations on an evacuated tube solar water heater using hybrid-nano based organic phase change material. International Journal of Green Energy, 17(13):872–883, August 2020. [4] Sashank Thapa, Raj Kumar, and Daeho Lee. Energetic and exergetic analysis of jet impingement solar thermal collector featuring discrete multi-arc shaped ribs absorber surface. Energy, 306:132392, October 2024. [5] K. Ravi Kumar, N.V.V. Krishna Chaitanya, and Natarajan Sendhil Kumar. Solar thermal energy technologies and its applications for process heating and power generation – a review. Journal of Cleaner Production, 282:125296, February 2021. [6] Saurabh P. Tembhare, Divya P. Barai, and Bharat A. Bhanvase. Performance evaluation of nanofluids in solar thermal and solar photovoltaic systems: A comprehensive review. Renewable and Sustainable Energy Reviews, 153:111738, January 2022. [7] G. Srinivasan and P. Muthukumar. A review on solar greenhouse dryer: Design, thermal modelling, energy, economic and environmental aspects. Solar Energy, 229:3–21, November 2021. [8] Patchimaporn Udomkun, Sebastian Romuli, Steffen Schock, Busarakorn Mahayothee, Murat Sartas, Tesfamicheal Wossen, Emmanuel Njukwe, Bernard Vanlauwe, and Joachim Müller. Review of solar dryers for agricultural products in asia and africa: An innovation landscape approach. Journal of Environmental Management, 268:110730, August 2020. [9] Anand Chavan, Vivek Vitankar, Arun Mujumdar, and Bhaskar Thorat. Natural convection and direct type (ncdt) solar dryers: a review. Drying Technology, 39(13):1969–1990, April 2020. [10] Vishnuvardhan Reddy Mugi, Pritam Das, Ramakrishna Balijepalli, and Chandramohan VP. A review of natural energy storage materials used in solar dryers for food drying applications. Journal of Energy Storage, 49:104198, May 2022. [11] N. Vigneshkumar, M. Venkatasudhahar, P. Manoj Kumar, A. Ramesh, Ram Subbiah, P. Michael Joseph Stalin, V. Suresh, M. Naresh Kumar, S. Monith, R. Manoj kumar, and M. Kriuthikeswaran. Investigation on indirect solar dryer for drying sliced potatoes using phase change materials (pcm). Materials Today: Proceedings, 47:5233–5238, 2021. [12] P. Manoj Kumar and K. Mylsamy. A comprehensive study on thermal storage characteristics of nano-ceo2 embedded phase change material and its influence on the performance of evacuated tube solar water heater. Renewable Energy, 162:662–676, December 2020. [13] Subhash Chand, Prabha Chand, and Harish Kumar Ghritlahre. Thermal performance enhancement of solar air heater using louvered fins collector. Solar Energy, 239:10–24, June 2022. [14] P. Manoj Kumar, K. Mylsamy, and P.T. Saravanakumar. Experimental investigations on thermal properties of nano-sio2/paraffin phase change material (pcm) for solar thermal energy storage applications. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 42(19):2420–2433, April 2019. [15] Mohammad Alhuyi Nazari, Akbar Maleki, Mamdouh El Haj Assad, Marc A. Rosen, Arman Haghighi, Hassan Sharabaty, and Lingen Chen. A review of nanomaterial incorporated phase change materials for solar thermal energy storage. Solar Energy, 228:725–743, November 2021. [16] A.K. Bhardwaj, Raj Kumar, Ranchan Chauhan, and Sushil Kumar. Experimental investigation and performance evaluation of a novel solar dryer integrated with a combination of shs and pcm for drying chilli in the himalayan region. Thermal Science and Engineering Progress, 20:100713, December 2020. [17] A.K. Bhardwaj, Raj Kumar, and Ranchan Chauhan. Experimental investigation of the performance of a novel solar dryer for drying medicinal plants in western himalayan region. Solar Energy, 177:395–407, January 2019. [18] A.K. Bhardwaj, Raj Kumar, Sushil Kumar, Bhasker Goel, and Ranchan Chauhan. Energy and exergy analyses of drying medicinal herb in a novel forced convection solar dryer integrated with shsm and pcm. Sustainable Energy Technologies and Assessments, 45:101119, June 2021. [19] S. Madhankumar, Karthickeyan Viswanathan, Wei Wu, and Muhammad Ikhsan Taipabu. Analysis of indirect solar dryer with pcm energy storage material: Energy, economic, drying and optimization. Solar Energy, 249:667–683, January 2023. [20] Dounia Chaatouf, Benyounes Raillani, Mourad Salhi, Samir Amraqui, and Ahmed Mezrhab. Experimental and numerical study of a natural convection indirect solar dryer with pcm tubes: Dynamic, thermal and nutritional quality analysis. Solar Energy, 264:111975, November 2023. [21] Mohammad Saleh Barghi Jahromi, Vali Kalantar, Hadi Samimi Akhijahani, and Hadi Kargarsharifabad. Recent progress on solar cabinet dryers for agricultural products equipped with energy storage using phase change materials. Journal of Energy Storage, 51:104434, July 2022. [22] Abuelnuor A.A. Abueluor, Majdi T. Amin, Mohamed Ali Abuelnour, and Obai Younis. A comprehensive review of solar dryers incorporated with phase change materials for enhanced drying efficiency. Journal of Energy Storage, 72:108425, November 2023. [23] V.V. Tyagi, K. Chopra, R.K. Sharma, A.K. Pandey, S.K. Tyagi, Muhammad Shakeel Ahmad, Ahmet Sarı, and Richa Kothari. A comprehensive review on phase change materials for heat storage applications: Development, characterization, thermal and chemical stability. Solar Energy Materials and Solar Cells, 234:111392, January 2022. [24] S. Vijayan, T.V. Arjunan, and Anil Kumar. Mathematical modeling and performance analysis of thin layer drying of bitter gourd in sensible storage based indirect solar dryer. Innovative Food Science amp; Emerging Technologies, 36:59–67, August 2016. [25] S. Vijayan, T.V. Arjunan, and Anil Kumar. Exergo-environmental analysis of an indirect forced convection solar dryer for drying bitter gourd slices. Renewable Energy, 146:2210–2223, February 2020. [26] Maria Telkes. Thermal energy storage in salt hydrates. Solar Energy Materials, 2(4):381–393, July 1980. [27] Zakaria Alimohammadi, Hadi Samimi Akhijahani, and Payman Salami. Thermal analysis of a solar dryer equipped with ptsc and pcm using experimental and numerical methods. Solar Energy, 201:157–177, May 2020. [28] A.K. Srivastava, S.K. Shukla, and Sandeep Mishra. Evaluation of solar dryer/air heater performance and the accuracy of the result. Energy Procedia, 57:2360–2369, 2014. [29] S.M. Shalaby and M.A. Bek. Experimental investigation of a novel indirect solar dryer implementing pcm as energy storage medium. Energy Conversion and Management, 83:1–8, July 2014. [30] Masoud Iranmanesh, Hadi Samimi Akhijahani, and Mohammad Saleh Barghi Jahromi. Cfd modeling and evaluation the performance of a solar cabinet dryer equipped with evacuated tube solar collector and thermal storage system. Renewable Energy, 145:1192–1213, January 2020. [31] Anand Jain, Anil Kumar, A. Shukla, and Atul Sharma. Development of Phase Change Materials (PCMs) for Solar Drying Systems, page 619–633. Springer Singapore, 2017. [32] Hana Ebrahimi, Hadi Samimi Akhijahani, and Payman Salami. Improving the thermal efficiency of a solar dryer using phase change materials at different position in the collector. Solar Energy, 220:535–551, May 2021. [33] A.K. Bhardwaj, Ranchan Chauhan, Raj Kumar, Muneesh Sethi, and Adit Rana. Experimental investigation of an indirect solar dryer integrated with phase change material for drying valeriana jatamansi (medicinal herb). Case Studies in Thermal Engineering, 10:302–314, September 2017. [34] AR. Umayal Sundari, P. Neelamegam, and C. V. Subramanian. An experimental study and analysis on solar drying of bitter gourd using an evacuated tube air collector in thanjavur, tamil nadu, india. Conference Papers in Energy, 2013:1–4, May 2013. [35] Wei Wang, Ming Li, Reda Hassanien Emam Hassanien, Yunfeng Wang, and Luwei Yang. Thermal performance of indirect forced convection solar dryer and kinetics analysis of mango. Applied Thermal Engineering, 134:310–321, April 2018. [36] Abhay Lingayat, V.P. Chandramohan, V.R.K. Raju, and Anil Kumar. Development of indirect type solar dryer and experiments for estimation of drying parameters of apple and watermelon. Thermal Science and Engineering Progress, 16:100477, May 2020. [37] Khalil E.J. Al-Juamily, Abdul Jabbar N. Khalifa, and Tadahmun A. Yassen. Testing of the performance of a fruit and vegetable solar drying system in iraq. Desalination, 209(1–3):163–170, April 2007. | eng |
| dc.rights | M.K. Murthi, P. Manoj Kumar, Sunil Kumar Bandili, Pradeep Johnson, M. Sakthivel - 2025 | eng |
| dc.rights.accessrights | info:eu-repo/semantics/openAccess | eng |
| dc.rights.coar | http://purl.org/coar/access_right/c_abf2 | eng |
| dc.rights.creativecommons | This work is licensed under a Creative Commons Attribution 4.0 International License. | eng |
| dc.rights.uri | https://creativecommons.org/licenses/by/4.0 | eng |
| dc.source | https://revistas.utb.edu.co/tesea/article/view/665 | eng |
| dc.subject | Solar dryers | eng |
| dc.subject | bitter gourd | eng |
| dc.subject | solar dryer | eng |
| dc.subject | PCM | eng |
| dc.subject | sodium thiosulfate pentahydrate | eng |
| dc.subject | inorganic salt | eng |
| dc.subject | solar dryer performance | eng |
| dc.title | Study on an indirect solar dryer for drying sliced bitter gourd using PCM | spa |
| dc.title.translated | Study on an indirect solar dryer for drying sliced bitter gourd using PCM | spa |
| dc.type | Artículo de revista | spa |
| dc.type.coar | http://purl.org/coar/resource_type/c_6501 | eng |
| dc.type.coarversion | http://purl.org/coar/version/c_970fb48d4fbd8a85 | eng |
| dc.type.content | Text | eng |
| dc.type.driver | info:eu-repo/semantics/article | eng |
| dc.type.local | Journal article | eng |
| dc.type.version | info:eu-repo/semantics/publishedVersion | eng |