Development and assessment of generalized drying kinetics in multi-tray solar cabinet dryer

Abstract This work evaluates the feasibility and determines a generalized drying characteristic curve in an indirect mode multi-tray solar cabinet dryer. The study considers a combination of tray reordering pattern and dryer performance index (DPI) method to map the influence of four primary factors, which influence the drying kinetics into a generalized curve. Three levels of each of the four factors, such as the mass flow rate (0.03–0.05 kg/s), heat input (500–1000 W/m2), loading density (1.0–2.5 kg/m2), and flake thickness (2–8 mm), represent twelve different drying kinetic curves. Therefore, the DPI value corresponding to the generalized curve would directly indicate the dryer performance and reduce the complexity in assessing the agro-product samples' drying behaviour in multiple trays. This study was initially validated, and it highlighted the merits of a tray reordering pattern in achieving drying uniformity per batch. Dimensionless drying process time ( τ ), a function of drying constant ( k ) and drying time ( t ), resulted in a maximum percentage deviation of 27.93% among the twelve drying kinetic curves. In contrast, expressing the moisture ratio as a function of DPI and drying process time ( τ ) reduced the maximum percentage deviation to 2.33%, with the value of correlation coefficient ( r ) above 0.972 for all the twelve drying kinetic curves. These consolidated findings pointed out that the adopted tray reordering pattern greatly influences the DPI method’s success in establishing a generalized curve in a multi-tray dryer.

[1]  S. Jayaraj,et al.  Performance analysis of a double-pass solar air heater system with asymmetric channel flow passages , 2018, Journal of Thermal Analysis and Calorimetry.

[2]  Yézouma Coulibaly,et al.  The evaporative capacity as a performance index for a solar-drier air-heater , 1998 .

[3]  Yanjun Dai,et al.  Multi-objective optimization of solar powered adsorption chiller combined with river water heat pump system for air conditioning and space heating application , 2019 .

[4]  A. A. El-Sebaii,et al.  Solar drying of agricultural products: A review , 2012 .

[5]  M. Mohanraj,et al.  Performance of a forced convection solar drier integrated with gravel as heat storage material , 2009 .

[6]  Anil Kumar,et al.  Mathematical modeling and performance investigation of mixed-mode and indirect solar dryers for natural rubber sheet drying , 2016 .

[7]  S. Jayaraj,et al.  Transient CFD Analysis of Macro-Encapsulated Latent Heat Thermal Energy Storage Containers Incorporated within Solar Air Heater , 2020 .

[8]  Shobhana Singh,et al.  New approach for thermal testing of solar dryer: Development of generalized drying characteristic curve , 2012 .

[9]  S. I. Gilani,et al.  Performance evaluation of hybrid solar chimney for uninterrupted power generation , 2019, Energy.

[10]  Aymen El Khadraoui,et al.  Thermal behavior of indirect solar dryer: Nocturnal usage of solar air collector with PCM , 2017 .

[11]  S. Jayaraj,et al.  A cost-effective method to improve the performance of solar air heaters using discrete macro-encapsulated PCM capsules for drying applications , 2019, Applied Thermal Engineering.

[12]  V. Hegde,et al.  Design, fabrication and performance evaluation of solar dryer for banana , 2015, Energy, Sustainability and Society.

[13]  Pankaj Khatak,et al.  Progress in solar dryers for drying various commodities , 2016 .

[14]  S. Jayaraj,et al.  Drying of untreated Musa nendra and Momordica charantia in a forced convection solar cabinet dryer with thermal storage , 2020 .

[15]  Muneesh Sethi,et al.  Experimental investigation of an indirect solar dryer integrated with phase change material for drying valeriana jatamansi (medicinal herb) , 2017 .

[16]  A. Kuhe,et al.  Effect of air mass flow rate on the performance of a mixed-mode active solar crop dryer with a transpired air heater , 2019, International Journal of Ambient Energy.

[17]  P. Muthukumar,et al.  Performance analyses of mixed mode forced convection solar dryer for drying of stevia leaves , 2019, Solar Energy.

[18]  R. Daghigh,et al.  A multistate investigation of a solar dryer coupled with photovoltaic thermal collector and evacuated tube collector , 2020 .

[19]  B. Ashok,et al.  Development and performance comparison of mixed-mode solar crop dryers with and without thermal storage , 2018, Renewable Energy.

[20]  K. Arun,et al.  Numerical studies on the effect of location and number of containers on the phase transition of PCM-integrated evacuated tube solar water heater , 2019, Journal of Thermal Analysis and Calorimetry.

[21]  Halil Atalay,et al.  Performance analysis of a solar dryer integrated with the packed bed thermal energy storage (TES) system , 2019, Energy.

[22]  P. Muthukumar,et al.  Drying kinetics and quality analysis of black turmeric (Curcuma caesia) drying in a mixed mode forced convection solar dryer integrated with thermal energy storage , 2018 .

[23]  K. Arun,et al.  Influence of the location of discrete macro-encapsulated thermal energy storage on the performance of a double pass solar plate collector system , 2020 .

[24]  Shobhana Singh,et al.  Testing method for thermal performance based rating of various solar dryer designs , 2012 .

[25]  S. Jayaraj,et al.  CFD modeling of macro-encapsulated latent heat storage system used for solar heating applications , 2019, International Journal of Thermal Sciences.

[26]  V. P. Chandramohan,et al.  Design, Development and Performance of Indirect Type Solar Dryer for Banana Drying ☆ , 2017 .

[27]  S. Jayaraj,et al.  Numerical simulation of a heat pump assisted solar dryer for continental climates , 2019 .

[28]  K. Arun,et al.  Active drying of unripened bananas (Musa Nendra) in a multi-tray mixed-mode solar cabinet dryer with backup energy storage , 2019, Solar Energy.

[29]  López-Vidaña Erick César,et al.  Thermal performance of a passive, mixed-type solar dryer for tomato slices (Solanum lycopersicum) , 2020 .

[30]  T. V. Arjunan,et al.  Exergo-environmental analysis of an indirect forced convection solar dryer for drying bitter gourd slices , 2020 .

[31]  T. V. Arjunan,et al.  Thermodynamic analysis of a triple-pass solar dryer for drying potato slices , 2018, Journal of Thermal Analysis and Calorimetry.

[32]  F. Calise,et al.  Transient analysis of solar polygeneration systems including seawater desalination: A comparison between linear Fresnel and evacuated solar collectors , 2019, Energy.

[33]  S. Jayaraj,et al.  Computational fluid dynamics analysis on solar water heater: Role of thermal stratification and mixing on dynamic mode of operation , 2020 .