Fixed-bed drying of rice with airflow reversal for product quality and drying performance

In Malaysia, paddy is typically harvested at moisture contents (MC) of around 21% to more than 30% (w.b.) and is dried to 13 – 14 % by using the fixed bed dryer (one direction airflow) at drying air temperature of 42 - 45 °C and grain bed depth of around 100 cm. As drying progresses in this type of...

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Main Author: Rashti, Kobra Tajaddodi Talab
Format: Thesis
Language:English
Published: 2012
Subjects:
Online Access:http://psasir.upm.edu.my/id/eprint/38610/1/FK%202012%2069R.pdf
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id my-upm-ir.38610
record_format uketd_dc
institution Universiti Putra Malaysia
collection PSAS Institutional Repository
language English
topic Rice - Drying
Quality of product
Rice - Quality
spellingShingle Rice - Drying
Quality of product
Rice - Quality
Rashti, Kobra Tajaddodi Talab
Fixed-bed drying of rice with airflow reversal for product quality and drying performance
description In Malaysia, paddy is typically harvested at moisture contents (MC) of around 21% to more than 30% (w.b.) and is dried to 13 – 14 % by using the fixed bed dryer (one direction airflow) at drying air temperature of 42 - 45 °C and grain bed depth of around 100 cm. As drying progresses in this type of dryer, grains near the air inlet are equilibrated with heated air and become over-dried before the grains in top layers reach the target final moisture content (FMC). This leads to non uniformity of grain MC within the entire bed at the end of drying operation. The main objective of this study is to improve drying process of rough rice using fixed bed drying method by reversing the airflow direction. In order to evaluate the effect of airflow reversal drying method on rice quality and drying performance, a laboratory experimental dryer was designed and fabricated. The approach was initiated by modifying an existing computer simulation procedure for fixed bed drying to meet the purpose of this study. Matlab software was applied to write the computer simulation program. Graphic User Interface (GUI) was created to show the simulation results graphically and numerically. The maximum bending strength was close to 35.69 MPa and 33.64 MPa for 55 °C and 60 °C, respectively. The results also revealed that drying air temperature of 40 °C and FMC range of 12 – 13.5% could be appropriate selections to achieve high whole kernel percentage (WKP) for a Malaysian paddy variety (MR219). Glass transition temperature (Tg) for MR219 was observed to be in the range of 9.65 - 61.79 °C, with MC in the range of 26.8 – 7.4% (w.b.). Results fit ability of Zuritz equation showed that it would be suitable to represent equilibrium moisture content (EMC) for computer drying simulation and its parameters were modified based on MR219. Results of the computer drying simulation that were depicted on glass transition diagram revealed that drying air temperature of 50°C can be recommended as the first temperature to dry paddy with high initial moisture content (above 30%) for 2.20 h in two-stage drying of MR219. Reversing the direction of airflow every 2 or 3 h cannot be recommended especially for high moisture grain due to occurrences of several transitions from rubbery to glassy state and vice versa, as well as several moisture readsorption and re-desorption for grains in the top and bottom layers of the dryer during the entire drying process. The results illustrated that HRY could be improved by changing the airflow direction when MC of grains at bottom layers were above 12%, and at top layers were about 17 – 18% with grain bed depth of 50 cm. In this drying scenario, applying the downward drying air temperature of 36 °C – 36.5 °C may not cause significant HRY reduction after changing the direction of airflow. Generally, the results showed that drying capacity by airflow reversal drying increased above 20%. Electricity costs decreased 20.44%, 11.99%, 32.33%, 25.17%, and 18.26% for airflow reversal drying with grain depth of 100 cm, 75 cm (G= 59 m³/min. t), 75 cm (G= 28 m³/min. t), 50 cm (G= 59 m³/min. t), 50 cm (G= 35 m³/min. t), respectively compared to conventional drying. In order to minimize undesirable effects of high drying rate, recommended superficial velocity and airflow rate ranges could be 0.18 – 0.22 m/s and 43 – 52 m³/min .t, respectively, for airflow reversal drying with grain bed depth of 50 cm. Although airflow reversal drying with grain depth of 75 cm and airflow rate of 28 m³/min. t showed more HRY reduction than that of 50 cm drying treatments, but good results of that treatment compared to the other drying treatments (grain bed depth of 75 and 100 cm) indicated HRY could be improved by adjusting the grain bed depth, superficial air velocity (maximum 0.2 m/s) and related airflow rate.
format Thesis
qualification_name Doctor of Philosophy (PhD.)
qualification_level Doctorate
author Rashti, Kobra Tajaddodi Talab
author_facet Rashti, Kobra Tajaddodi Talab
author_sort Rashti, Kobra Tajaddodi Talab
title Fixed-bed drying of rice with airflow reversal for product quality and drying performance
title_short Fixed-bed drying of rice with airflow reversal for product quality and drying performance
title_full Fixed-bed drying of rice with airflow reversal for product quality and drying performance
title_fullStr Fixed-bed drying of rice with airflow reversal for product quality and drying performance
title_full_unstemmed Fixed-bed drying of rice with airflow reversal for product quality and drying performance
title_sort fixed-bed drying of rice with airflow reversal for product quality and drying performance
granting_institution Universiti Putra Malaysia
publishDate 2012
url http://psasir.upm.edu.my/id/eprint/38610/1/FK%202012%2069R.pdf
_version_ 1747811737560678400
spelling my-upm-ir.386102015-10-08T04:38:03Z Fixed-bed drying of rice with airflow reversal for product quality and drying performance 2012-02 Rashti, Kobra Tajaddodi Talab In Malaysia, paddy is typically harvested at moisture contents (MC) of around 21% to more than 30% (w.b.) and is dried to 13 – 14 % by using the fixed bed dryer (one direction airflow) at drying air temperature of 42 - 45 °C and grain bed depth of around 100 cm. As drying progresses in this type of dryer, grains near the air inlet are equilibrated with heated air and become over-dried before the grains in top layers reach the target final moisture content (FMC). This leads to non uniformity of grain MC within the entire bed at the end of drying operation. The main objective of this study is to improve drying process of rough rice using fixed bed drying method by reversing the airflow direction. In order to evaluate the effect of airflow reversal drying method on rice quality and drying performance, a laboratory experimental dryer was designed and fabricated. The approach was initiated by modifying an existing computer simulation procedure for fixed bed drying to meet the purpose of this study. Matlab software was applied to write the computer simulation program. Graphic User Interface (GUI) was created to show the simulation results graphically and numerically. The maximum bending strength was close to 35.69 MPa and 33.64 MPa for 55 °C and 60 °C, respectively. The results also revealed that drying air temperature of 40 °C and FMC range of 12 – 13.5% could be appropriate selections to achieve high whole kernel percentage (WKP) for a Malaysian paddy variety (MR219). Glass transition temperature (Tg) for MR219 was observed to be in the range of 9.65 - 61.79 °C, with MC in the range of 26.8 – 7.4% (w.b.). Results fit ability of Zuritz equation showed that it would be suitable to represent equilibrium moisture content (EMC) for computer drying simulation and its parameters were modified based on MR219. Results of the computer drying simulation that were depicted on glass transition diagram revealed that drying air temperature of 50°C can be recommended as the first temperature to dry paddy with high initial moisture content (above 30%) for 2.20 h in two-stage drying of MR219. Reversing the direction of airflow every 2 or 3 h cannot be recommended especially for high moisture grain due to occurrences of several transitions from rubbery to glassy state and vice versa, as well as several moisture readsorption and re-desorption for grains in the top and bottom layers of the dryer during the entire drying process. The results illustrated that HRY could be improved by changing the airflow direction when MC of grains at bottom layers were above 12%, and at top layers were about 17 – 18% with grain bed depth of 50 cm. In this drying scenario, applying the downward drying air temperature of 36 °C – 36.5 °C may not cause significant HRY reduction after changing the direction of airflow. Generally, the results showed that drying capacity by airflow reversal drying increased above 20%. Electricity costs decreased 20.44%, 11.99%, 32.33%, 25.17%, and 18.26% for airflow reversal drying with grain depth of 100 cm, 75 cm (G= 59 m³/min. t), 75 cm (G= 28 m³/min. t), 50 cm (G= 59 m³/min. t), 50 cm (G= 35 m³/min. t), respectively compared to conventional drying. In order to minimize undesirable effects of high drying rate, recommended superficial velocity and airflow rate ranges could be 0.18 – 0.22 m/s and 43 – 52 m³/min .t, respectively, for airflow reversal drying with grain bed depth of 50 cm. Although airflow reversal drying with grain depth of 75 cm and airflow rate of 28 m³/min. t showed more HRY reduction than that of 50 cm drying treatments, but good results of that treatment compared to the other drying treatments (grain bed depth of 75 and 100 cm) indicated HRY could be improved by adjusting the grain bed depth, superficial air velocity (maximum 0.2 m/s) and related airflow rate. Rice - Drying Quality of product Rice - Quality 2012-02 Thesis http://psasir.upm.edu.my/id/eprint/38610/ http://psasir.upm.edu.my/id/eprint/38610/1/FK%202012%2069R.pdf application/pdf en public phd doctoral Universiti Putra Malaysia Rice - Drying Quality of product Rice - Quality