Experimental analysis of low-temperature grain drying performance of vertical packed clay and clay-additives composite desiccant beds

A laboratory model of a forced circulation desiccant based green pea drying system operating in an open-loop is constructed and tested. The green pea drying process is divided into two stages involving dehumidification by the desiccant bed and green peas drying by dehumidified process air. Removal o...

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Veröffentlicht in:	Sadhana (Bangalore) 2021, Vol.46 (1), Article 37
Hauptverfasser:	Hiremath, C R, Ravikiran, Kadoli
Format:	Artikel
Sprache:	eng
Schlagworte:	Additives Calcium chloride Clay Dehumidification Desiccants Drying Dung Engineering Enthalpy Heat treatment Horses Low temperature Moisture Peas Sawdust
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creator	Hiremath, C R Ravikiran, Kadoli
description	A laboratory model of a forced circulation desiccant based green pea drying system operating in an open-loop is constructed and tested. The green pea drying process is divided into two stages involving dehumidification by the desiccant bed and green peas drying by dehumidified process air. Removal of moisture from the process air has been achieved by vertical packed composite desiccant beds. The composite desiccant used are heat treated clay with CaCl 2 being impregnated and clay with additives like horse dung and sawdust, again being heated, treated and later impregnated with CaCl 2 . The green peas were dried for a process time of one hour. The drying was quite sharp during the initial process time of 500 s and from then onwards proceeded at a constant rate. For the identical bed masses, The performance of heat treated clay-additives based beds in moisture reduction and enhancement in enthalpy of process air is higher. The experimental study reveals the average heat content of air entering the dryer is 1.46, 2.46 and 2.38 kJ for heat-treated clay-CaCl 2 , clay-horse dung-CaCl 2 and clay-sawdust-CaCl 2 composite desiccant beds of 700 g mass.
doi_str_mv	10.1007/s12046-021-01558-8
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The green pea drying process is divided into two stages involving dehumidification by the desiccant bed and green peas drying by dehumidified process air. Removal of moisture from the process air has been achieved by vertical packed composite desiccant beds. The composite desiccant used are heat treated clay with CaCl 2 being impregnated and clay with additives like horse dung and sawdust, again being heated, treated and later impregnated with CaCl 2 . The green peas were dried for a process time of one hour. The drying was quite sharp during the initial process time of 500 s and from then onwards proceeded at a constant rate. For the identical bed masses, The performance of heat treated clay-additives based beds in moisture reduction and enhancement in enthalpy of process air is higher. The experimental study reveals the average heat content of air entering the dryer is 1.46, 2.46 and 2.38 kJ for heat-treated clay-CaCl 2 , clay-horse dung-CaCl 2 and clay-sawdust-CaCl 2 composite desiccant beds of 700 g mass.</abstract><cop>New Delhi</cop><pub>Springer India</pub><doi>10.1007/s12046-021-01558-8</doi></addata></record>
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source	Indian Academy of Sciences; Springer Nature - Complete Springer Journals; EZB-FREE-00999 freely available EZB journals
subjects	Additives Calcium chloride Clay Dehumidification Desiccants Drying Dung Engineering Enthalpy Heat treatment Horses Low temperature Moisture Peas Sawdust
title	Experimental analysis of low-temperature grain drying performance of vertical packed clay and clay-additives composite desiccant beds
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