TY  - BOOK
AU  - Alfiya, P V
AU  - Rajesh, G K (Guide)
TI  - Development and evaluation of semi-continuous microwave convective dryer for food products 
U1  - 631.56 
PY  - 2024///
CY  - Tavanur
PB  - Department of Processing and Food Engineering, Kelappaji College of  Agricultural Engineering
KW  - Processing and Food Engineering
KW  - Agricultural Engineering
KW  - Semi-continuous microwave
KW  - Microwave convective dryer
KW  - Food products
N1  - Ph.D
N2  - The research work aimed to develop a semi-continuous microwave convective dryer
for foods and evaluate the performance of the dryer for drying of shrimp and oyster mushroom.
The study also aimed to assess the shelf-life of the dried products under different packaging
technologies and packaging materials. The quality of conventionally dried shrimp and oyster
mushrooms were compared and evaluated with the hot air assisted microwave (HAMW) dried
products. The developed HAMW drying system comprised of a drying chamber, conveyor belt,
magnetron to generate microwaves at frequency of 2450 MHz±50 MHz, hot air generation
system with air heater, axial fan and other controls.
The drying experiments for shrimp were performed according to a second-order Box-
Behnken design (BBD) with three factors at three levels: microwave power (600, 800 and 1000
W), air temperature (50, 60 and 70 °C), and air velocity (0.5, 1.0 and 1.5m/s). Drying time,
water activity, and rehydration ratio was selected as the response variables. A three-factor,
three-level Box-Behnken design (BBD) experimental design was used in optimizing the drying
conditions for shrimp in a hot air-assisted microwave (HAMW) drying system.
The optimization was performed to optimize the conditions with minimum values of
drying time and water activity, and maximum value of rehydration ratio. The design plan
consisted of 17 runs with 5 centre points. The optimum conditions of process variables were
derived using the desirability function. Design Expert Statistical Software package 9.0.0 (Stat
Ease Inc., Minneapolis, MN, USA) was used to perform statistical analysis.
The moisture content of shrimp decreased from an initial value of 80.55% to a final
value of 16.5% within 2.9 h of drying. HAMW drying of shrimp was represented by reduction
in moisture percent as a function of drying time. Moisture ratio obtained during drying were
fitted into thin layer drying models by non-linear regression analysis. Page model was
identified as the best fit model with higher R2 value of 0.9984, lower χ2 value of 0.000134 and
RMSE value of 0.01552.
Drying efficiency of the dryer under HAMW mode was observed to be 35.71%. This
was a result of volumetric hearing effect of microwave radiation combined with convective
effect of hot air. The SEC value for HAMW of shrimp was found to be 1.75 kWh/kg. The total
value of colour change (ΔE) determined for dried shrimp was 16.95 ± 2.14. The ‘L’ value of
the dried shrimp (41.31 ± 1.63) decreased during drying whereas the ‘a’ and ‘b’ values
increased from 3.56 ± 1.54 to 14.23± 2.36 and 12.42 ± 0.65 to 19.42 ± 1.61 during the drying
process.
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Solar radiation, ambient temperature and relative humidity (RH) were measured using
sensors at each hour of the study. The solar radiation intensity during the experimental
conditions was observed to be in range of 320 to 840 W/m2, ambient temperature varied from
27.5 to 36.5 0C and RH from 62.45% to 77.24% on a typical day of the experiment. The
moisture content of shrimp was reduced from 80.2% to 15.7% (w.b.) within 6 h of drying in
the solar dryer. The drying conditions were maintained at temperature, air velocity and RH of
55±1.5 0C, 1.5 ± 0.25 m/s and 60±0.5 % respectively.
The drying rate of solar and microwave dried shrimp was found to be 1.63 kg/kgh and
2.74 kg/kgh at the beginning of drying. Drying rate exhibited a maximum value of 2.74 during
The average rehydration ratio was observed to be 2.39 and 2.53 for SD and HAMW drying
respectively. The shrinkage percentage of SD and HAMW shrimp was observed to be 24.67
and 14.14% respectively.
Storage studies of hot air assisted microwave dried and solar dried shrimps were carried
out under MAP and vacuum conditions in three types of packaging materials namely LDPE
(150 μ), polyester polyethylene laminate (72 μ) and metallised polyester (84 μ). Shelf life of
the dried shrimps was quantified with respect to the microbial growth and other quality
parameters. Maximum storage life was exhibited for SD and HAMW dried shrimp under
polyethylene-polyester laminated (72 μ) packaging material.
The response surface methodology plots of Oyster mushrooms showed that drying
time decreased with an increase in air temperature (40 to 60℃) and microwave power (600 to
1000W). Based on the value of maximum desirability (0 to 1), optimum conditions were
selected. The methodology of desired function was applied to indicate 55.05 ℃ air temperature,
1000 W microwave power and 0.81 m/s air velocity which indicated the drying time, water
activity and rehydration ratio of 5.05 h and 0.532 and 2.49, respectively with a desirability
value of 0.830.
Moisture content of Oyster mushroom decreased from 92.35 to 8.42% within 5 h of
drying. Volumetric heating effect of microwaves can be attributed for the reduction in drying
time. Microwave heating falls under dielectric heating method wherein the moisture content of
the product directly influences the heating rate. Drying rate exhibited maximum value of 3.47
during the initial stages in drying that can be due to the higher moisture content of sample that
created more friction and heat generation due to dipole rotation.
Drying efficiency of the dryer under HAMW mode for oyster mushroom was
observed to be 23.12%. The SEC value for HAMW of oyster mushroom was found to be 2.71
kWh/kg. Solar drying efficiency of the collector was calculated using the whole collector area
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and solar irradiation received instantaneously during drying. The instantaneous collector
efficiency values varied in the range of 30.9 to 42.4%.
The L*, a* and b* colour values of fresh mushrooms were determined to be
84.12±0.46, 3.3±0.24 and 15.57±0.62 respectively. The colour values of the microwave dried
mushrooms under optimized conditions were recorded as 56.15±0.25 (L*), 4.95±0.24 (a*) and
20.85±0.51 (b*) respectively. The ‘L’ value of the dried oyster mushroom decreased whereas
the ‘a’ and ‘b’ values increased during microwave convective drying.
The drying rate of SD and HAMW dried oyster mushrooms were found to be 3.47
kg/kgh and 2.14 kg/kgh at the beginning of drying. Drying rate exhibited a maximum value of
3.47 during the initial stages of drying that can be due to the higher moisture content of a sample
that created more friction and heat generation due to dipole rotation. Drying reduced the TPC
value of oyster mushroom to 1.2 × 104 and 3.9 ×105 CFU/g respectively under MW and SD
drying conditions.
The optimized sample was analysed for microstructure to study the pore size
distribution in the dried product. The pore size for microwave dried oyster mushroom samples
ranged from 8.65 – 32.4 μm. Scanning electron microscopy analysis of microwave dried oyster
mushroom showed the formation of pores of diameters ranging from 2.06 – 15.7 μm.
Storage studies of hot air assisted microwave dried and solar dried oyster mushrooms
were carried out under MAP and vacuum conditions in three types of packaging materials
namely LDPE (150 μ), polyester polyethylene laminate (72 μ) and metallised polyester (84 μ).
Shelf life of the dried oyster mushroom was quantified with respect to the microbial growth
and other quality parameters and maximum value of 9 months was achieved for SD and
HAMW dried oyster mushroom in polyethylene-polyester (72 μ) laminated packaging
material
UR  - https://krishikosh.egranth.ac.in/handle/1/5810218980
ER  -