Study of color kinetics of banana <i>(Musa cavendish)</i> under microwave drying by application of image analysis

Nagvanshi, Sagar; Venkata, Subbarao Kotra; Goswami, T.K.

doi:10.1177/1082013220981334

Cited by 9 publications

(5 citation statements)

References 55 publications

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“…In thicker samples, the water must travel a longer distance inside the product to reach the surface, i.e., it takes longer to remove moisture. Such an increment in drying time led to higher energy consumption [41]. Similar reports were also emphasized by researchers elsewhere [29,43,51] for drying kiwi, apple, and onion by microwave dryer, respectively.…”

Section: Specific Energy Consumptionsupporting

confidence: 80%

“…This phenomenon accelerated the vapor motion, guiding the water toward the surface of the samples. For constant microwave power, a rise in the sample thickness will increase the path the moisture has to pass to reach the surface which will eventually enhance the drying time [41]. Other researchers also addressed the effect of the MW power and sample thickness on the drying time of the agricultural products, among which the works by Beigi and Torki [29] on onion slices, Çınkır and Süfer [42] on red meat radish, and Darvishi et al [43] on sweet potato can be mentioned.…”

Section: Kinetics Of Dryingmentioning

confidence: 99%

“…The increase in the energy consumption by changing the power from 180 to 540 W was significant at all thicknesses (p < 0.05); the results indicated that a rise in the MW power and a decrement in the sample thicknesses can decrement the energy consumption. The reason could be the enhanced destruction of the product thickness and accelerated moisture release [39,41]. Moreover, with increasing MW output power, the thermal gradient inside the sample increased, followed by an increment in evaporation rate and a decrease in drying time.…”

Section: Specific Energy Consumptionmentioning

confidence: 99%

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Exergy and Energy Analyses of Microwave Dryer for Cantaloupe Slice and Prediction of Thermodynamic Parameters Using ANN and ANFIS Algorithms

et al. 2021

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The study targeted towards drying of cantaloupe slices with various thicknesses in a microwave dryer. The experiments were carried out at three microwave powers of 180, 360, and 540 W and three thicknesses of 2, 4, and 6 mm for cantaloupe drying, and the weight variations were determined. Artificial neural networks (ANN) and adaptive neuro-fuzzy inference systems (ANFIS) were exploited to investigate energy and exergy indices of cantaloupe drying using various afore-mentioned input parameters. The results indicated that a rise in microwave power and a decline in sample thickness can significantly decrease the specific energy consumption (SEC), energy loss, exergy loss, and improvement potential (probability level of 5%). The mean SEC, energy efficiency, energy loss, thermal efficiency, dryer efficiency, exergy efficiency, exergy loss, improvement potential, and sustainability index ranged in 10.48–25.92 MJ/kg water, 16.11–47.24%, 2.65–11.24 MJ/kg water, 7.02–36.46%, 12.36–42.70%, 11.25–38.89%, 3–12.2 MJ/kg water, 1.88–10.83 MJ/kg water, and 1.12–1.63, respectively. Based on the results, the use of higher microwave powers for drying thinner samples can improve the thermodynamic performance of the process. The ANFIS model offers a more accurate forecast of energy and exergy indices of cantaloupe drying compare to ANN model.

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Section: Specific Energy Consumptionsupporting

confidence: 80%

Section: Kinetics Of Dryingmentioning

confidence: 99%

Section: Specific Energy Consumptionmentioning

confidence: 99%

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Exergy and Energy Analyses of Microwave Dryer for Cantaloupe Slice and Prediction of Thermodynamic Parameters Using ANN and ANFIS Algorithms

et al. 2021

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“…Thus, the moisture transfer from inside the sample to the surface and evaporation will be accelerated which results in a shorter drying time (Beigi & Torki, 2021). Similar results were reported by Nagvanshi et al, 2020 for banana and by Darvishi et al (2016) for kiwifruit. Based on Figure 1b, by increasing the microwave power and sonication time the drying time reduced as the mass transfer within the kiwi samples was accelerated.…”

Section: Resultssupporting

confidence: 91%

Use of ultrasound pre‐treatment before microwave drying of kiwifruits – An optimization approach with response surface methodology

Kaveh¹,

Taghinezhad

Witrowa‐Rajchert

et al. 2022

Food Processing Preservation

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In the present study, the thermal properties (drying time, effective moisture diffusion (Deff), specific energy consumption (SEC)), and quality (color and shrinkage) of kiwi slices were optimized using the response surface methodology (RSM). The optimization process was done using central composite design (CCD) in Design Expert software with three independent variables including microwave power (100, 200, and 300 W), sample thickness (4, 6, and 8 mm), and ultrasound pretreatment time (10, 20, and 30 min). The results showed that by increasing the microwave power and ultrasound pretreatment time and decreasing the thickness, the SEC, and drying time decreased in quadratic form, while the Deff linearly increased. Moreover, decreasing microwave power and sample thickness as well as increasing the treatment time diminished the shrinkage and color. The obtained optimal results (4 mm thickness, ultrasound for 30 min, 257.2 W of microwave power) were: drying time for 13.779 min, Deff equal 6.67 × 10−9 m2/s, SEC equal 6.343 MJ/kg, the total color difference of 17.94, and shrinkage of 46%. Novelty impact statement Numerous studies have addressed the drying of food products using ultrasound pre‐treatment. However, the optimization process is required for different methods of drying, parameters of treatment as well as type of the material. Thus, the response surface methodology (RSM) was applied for optimization and modeling the drying process and chosen physical properties of ultrasound‐treated kiwifruits slices prior to microwave drying.

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“…On the other hand, the use of microwave power increases the moisture-absorption capacity of the air, due to the increase in temperature difference between the air and the product, and causes the product to heat up faster and water to evaporate better. As a result, the drying time is reduced [ 19 , 20 ]. Furthermore, the use of higher power for the microwave reduced the drying time.…”

Section: Resultsmentioning

confidence: 99%

Effect of Thermal and Non-Thermal Technologies on Kinetics and the Main Quality Parameters of Red Bell Pepper Dried with Convective and Microwave–Convective Methods

Rybak

Wiktor

Kaveh³

et al. 2022

Molecules

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The drying process preserves the surplus of perishable food. However, to obtain a good-quality final product, different pretreatments are conducted before drying. Thus, the aim of the study was the evaluation of the effect of thermal (blanching treatments with hot water) and non-thermal technologies (pulsed electric field (PEF) and ultrasound (US)) on the kinetics of the drying process of red bell pepper. The convective and microwave–convective drying were compared based on quality parameters, such as physical (water activity, porosity, rehydration rate, and color) and chemical properties (total phenolic content, total carotenoids content, antioxidant activity, and total sugars content). The results showed that all of the investigated methods reduced drying time. However, the most effective was blanching, followed by PEF and US treatment, regardless of the drying technique. Non-thermal methods allowed for better preservation of bioactive compounds, such as vitamin C in the range of 8.2% to 22.5% or total carotenoid content in the range of 0.4% to 48%, in comparison to untreated dried material. Moreover, PEF-treated red bell peppers exhibited superior antioxidant activity (higher of about 15.2–30.8%) when compared to untreated dried samples, whereas sonication decreased the free radical scavenging potential by ca. 10%. In most cases, the pretreatment influenced the physical properties, such as porosity, color, or rehydration properties. Samples subjected to PEF and US treatment and dried by using a microwave-assisted method exhibited a significantly higher porosity of 2–4 folds in comparison to untreated material; this result was also confirmed by visual inspection of microtomography scans. Among tested methods, blanched samples had the most similar optical properties to untreated materials; however non-thermally treated bell peppers exhibited the highest saturation of the color.

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Study of color kinetics of banana (Musa cavendish) under microwave drying by application of image analysis

Cited by 9 publications

References 55 publications

Exergy and Energy Analyses of Microwave Dryer for Cantaloupe Slice and Prediction of Thermodynamic Parameters Using ANN and ANFIS Algorithms

Exergy and Energy Analyses of Microwave Dryer for Cantaloupe Slice and Prediction of Thermodynamic Parameters Using ANN and ANFIS Algorithms

Use of ultrasound pre‐treatment before microwave drying of kiwifruits – An optimization approach with response surface methodology

Effect of Thermal and Non-Thermal Technologies on Kinetics and the Main Quality Parameters of Red Bell Pepper Dried with Convective and Microwave–Convective Methods

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