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Experimental determination of the effective moisture diffusivity and activation energy during convective solar drying of olive pomace waste

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  • Koukouch, Abdelghani
  • Idlimam, Ali
  • Asbik, Mohamed
  • Sarh, Brahim
  • Izrar, Boujemaa
  • Bostyn, Stéphane
  • Bah, Abdellah
  • Ansari, Omar
  • Zegaoui, Omar
  • Amine, Amina

Abstract

The drying of olive pomace waste was performed using a partially indirect solar convective dryer operating in forced convection. This comparative study is focused on the drying kinetics of two types of residue, namely, raw olive pomace and deoiled olive pomace. These products have been spread out in thin layers on perforated circular racks before they be placed in the dryer. The sample thicknesses considered are 0.5, 1.0 and 1.5 cm. Kinetic measurements are carried out for three temperatures (40, 60 and 80 °C) and two drying air flow rates (0.042 and 0.083 m3 s−1). The relative humidity varies between 28% and 65% throughout the drying period. The increase of temperature in the environment reduces significantly the drying time. The characteristic drying curve (CDC) applicable to both types of olive pomace has been established as a polynomial of order 4 in reduced moisture content. Data obtained from dried products were used to determine the effective diffusivity values during the drying period with decreasing curve. In this period, the moisture transfer from the pomace was described by applying the Fick diffusion model. Effective diffusivity varies between 1.6 × 10−8 and 34.7 × 10−8 m2 s−1 with the increase of the medium air drying temperature but also with the sample thickness. The activation energy value is estimated at 29.06 kJ mol−1.

Suggested Citation

  • Koukouch, Abdelghani & Idlimam, Ali & Asbik, Mohamed & Sarh, Brahim & Izrar, Boujemaa & Bostyn, Stéphane & Bah, Abdellah & Ansari, Omar & Zegaoui, Omar & Amine, Amina, 2017. "Experimental determination of the effective moisture diffusivity and activation energy during convective solar drying of olive pomace waste," Renewable Energy, Elsevier, vol. 101(C), pages 565-574.
    • Handle: RePEc:eee:renene:v:101:y:2017:i:c:p:565-574
    DOI: 10.1016/j.renene.2016.09.006
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    References listed on IDEAS

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    1. Lahsasni, Siham & Kouhila, Mohammed & Mahrouz, Mostafa & Idlimam, Ali & Jamali, Abdelkrim, 2004. "Thin layer convective solar drying and mathematical modeling of prickly pear peel (Opuntia ficus indica)," Energy, Elsevier, vol. 29(2), pages 211-224.
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    2. Hidar, Nadia & Ouhammou, Mourad & Mghazli, Safa & Idlimam, Ali & Hajjaj, Abdessamad & Bouchdoug, Mohamed & Jaouad, Abderrahim & Mahrouz, Mostafa, 2020. "The impact of solar convective drying on kinetics, bioactive compounds and microstructure of stevia leaves," Renewable Energy, Elsevier, vol. 161(C), pages 1176-1183.
    3. Hadibi, Tarik & Boubekri, Abdelghani & Mennouche, Djamel & Benhamza, Abderrahmane & Kumar, Anil & Bensaci, Cheyma & Xiao, Hong-Wei, 2022. "Effect of ventilated solar-geothermal drying on 3E (exergy, energy, and economic analysis), and quality attributes of tomato paste," Energy, Elsevier, vol. 243(C).
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    5. Mejdi Jeguirim & Patrick Dutournié & Antonis A. Zorpas & Lionel Limousy, 2017. "Olive Mill Wastewater: From a Pollutant to Green Fuels, Agricultural Water Source and Bio-Fertilizer—Part 1. The Drying Kinetics," Energies, MDPI, vol. 10(9), pages 1-16, September.
    6. Abderrahman, Mellalou & Abdelaziz, Bacaoui & Abdelkader, Outzourhit, 2022. "Thermal performances and kinetics analyses of greenhouse hybrid drying of two-phase olive pomace: Effect of thin layer thickness," Renewable Energy, Elsevier, vol. 199(C), pages 407-418.
    7. Samimi-Akhijahani, Hadi & Arabhosseini, Akbar, 2018. "Accelerating drying process of tomato slices in a PV-assisted solar dryer using a sun tracking system," Renewable Energy, Elsevier, vol. 123(C), pages 428-438.
    8. Badaoui, Ouassila & Hanini, Salah & Djebli, Ahmed & Haddad, Brahim & Benhamou, Amina, 2019. "Experimental and modelling study of tomato pomace waste drying in a new solar greenhouse: Evaluation of new drying models," Renewable Energy, Elsevier, vol. 133(C), pages 144-155.
    9. Azadbakht, Mohsen & Torshizi, Mohammad Vahedi & Noshad, Fatemeh & Rokhbin, Arash, 2018. "Application of artificial neural network method for prediction of osmotic pretreatment based on the energy and exergy analyses in microwave drying of orange slices," Energy, Elsevier, vol. 165(PB), pages 836-845.

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