Hot Air Drying and Microwave-Assisted Hot Air Drying of Broccoli Stalk Slices (<i>Brassica oleracea</i>L. Var.<i>Italica)</i>

Salim, Nora Salina Md; Gariépy, Yvan; Raghavan, V.

doi:10.1111/jfpp.12905

Cited by 32 publications

(25 citation statements)

References 40 publications

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“…It was also found that higher drying temperature resulted in larger heating energy leading to raising molecular water activity and raised D eff . The results of D eff value had a good agreement with the published values by other researchers (Ashtiani et al, ; Bhattacharya, Srivastav, & Mishra, ; Khoshtaghaza et al, ; Salim, Gariepy, & Raghavan, ; Wang, Li, et al, ).…”

Section: Resultssupporting

confidence: 86%

Use of artificial intelligence for the estimation of effective moisture diffusivity, specific energy consumption, color and shrinkage in quince drying

Taghinezhad

Kaveh

Jahanbakhshi

et al. 2020

J Food Process Engineering

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In the study, drying process of quince fruit was accomplished in a microwave‐convective dryer (MCD). The experiments were carried out at microwave power levels of 100, 200, and 300 W, air temperatures of 40, 55, and 70°C, and air velocities of 0.5, 1, and 1.5 m/s. Nevertheless, three artificial intelligence techniques consisted of artificial neural networks (ANNs), particle swarm optimizer (PSO), and grey wolf optimizer (GWO) were evaluated to predict the parameters of Deff, SEC, ΔE, and Sb. In the evaluation the data by ANNs, input parameters of networks consisted the values of air temperature, microwave power, and air velocity. According to the results, the maximum values of effective moisture diffusivity ( Deff) and specific energy consumption (SEC) were 1.71 × 10−9 m2/s and 126.07 kWh/kg, respectively. In addition, minimum values of total change in color (ΔE) and shrinkage ( Sb) of quince achieved 10.85 and 33.85%, respectively. For predicting all parameters, three models used in the study represented good predictive capability with R2 > 0.97. The obtained results showed that the GWO model had better predictive performance than the ANN and PSO models. Practical Application Drying food and agricultural products by application of microwave‐hot air blend dryers can be a good alternative to hot air and microwave dryers. Microwave energy infiltrates the product and facilitates heat release from the product and thus reduces drying time compared to single dryers. The main aim of applying such different models, mathematical simulation or modeling in the drying technology of agricultural products is to transform physical qualities and their interactions into numerical quantities and mathematical relationships.

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Section: Resultssupporting

confidence: 86%

Use of artificial intelligence for the estimation of effective moisture diffusivity, specific energy consumption, color and shrinkage in quince drying

Taghinezhad

Kaveh

Jahanbakhshi

et al. 2020

J Food Process Engineering

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“…Drying alters both physicochemical and nutritional characteristics of the agricultural crops by degrading and modifying the cellular components and promoting reactions between them, and concerted efforts are being made to modify such physicochemical changes in order to achieve a favorable result (Devahastin & Niamnuy, ). Quality of the final product depends largely on the choice of the technique: while low‐temperature processes such as freeze drying (FD) preserve most of the original characteristics of the product, high‐temperature processes such as hot air drying (HAD) destroy the squishy microstructure of plant products and degrade most of the thermolabile bioactive compounds(López et al, ; Md Salim, Gariépy, & Raghavan, ). Microwave drying (MWD), a novel dehydration technique based on electromagnetic (EM) radiation, offers a faster and more energy efficient alternative to these traditional techniques but is yet to be preferred by manufacturers for processing most of the agricultural crops because of its “destructive” effect on the food (Mandal, Mohan, & Hemalatha, ).…”

Section: Introductionmentioning

confidence: 99%

“…Figure 2a,b shows that there is good fit of experimental data for both MWD and FD and HAD processes with the Midilli et al's model. In earlier studies, Midilli et al's model also provided a better representation of MWD of broccoli stalk slices,leek, apple slices, and onion slices than other thin layer drying models(Md Salim et al, 2017;Süfer, Sezer, & Demir, 2017).…”

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confidence: 96%

mentioning

confidence: 99%

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Effect of microwave power on drying kinetics, structure, color, and antioxidant activities of corncob

Saha

Dey

Chakraborty

2019

J Food Process Engineering

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In this study, the effect of microwave drying (MWD) at four power levels (180, 300, 600, and 900 W) on kinetics, structure, color parameters, and antioxidant activity of corncob (CCB) was evaluated. Hot air‐dried (HAD) and freeze‐dried (FD) CCBs were used as controls. Drying conditions significantly affected the physicochemical characteristics as well as bioactivities of CCB. For MWD products, direct absorption of electromagnetic energy by water molecules greatly accelerated the evaporation process, leading to a faster dehydration with a very high moisture diffusivity value. Additionally, the application of microwave markedly enhanced disintegration of cellular components manifested in lowered values of structural and color attributes for MWD CCBs, which facilitated the liberation of bound polyphenols into fractions of free phenolic compounds and intensified the ultrasound‐assisted extraction of antioxidants. The presence of rutin, protocatechuic acid, gallic acid, caffeic acid, chlorogenic acid, and quercetin was responsible for high bioactivity of MWD CCB. However, thermal‐ and oxidation‐induced degradation of thermolabile polyphenols was responsible for the loss of antioxidant activity at higher (600 and 900 W) and lower (180 W) microwave powers. CCB dried using 300 W microwave power was the best drying process with the highest content of bioavailable antioxidants and antioxidant activity. Practical applications Using lignocellulosic plant part as a source of functional food or nutritional compounds requires intensive studies on the nutritional quality of products as well as bioavailabilities of such compounds. As most of the antioxidant compounds remain bound to cellulose and hemicellulose in seed, cob, and peel, techniques that promote the disintegration of bound polymeric complexes improve the bioactivity of these products. The present research highlights the potential benefits of microwave drying for the improvement in the bioactivity of corncob (CCB). The presence of several key phenolic compounds suggests a potential application of CCB in medicinal, cosmetic, and food industries.

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“…Combination drying methods (MW/IR drying assisted with hot air/VC, MW and IR combination) were introduced to compensate for the aforementioned drawbacks of individual drying methods. Several studies reported that combination drying methods promote faster drying time with rapid moisture diffusion and less change in color than in HA drying (Koné et al, 2013;Zhao et al, 2013;Wojdyło et al, 2014;Wu et al, 2014;Salim et al, 2016). Freeze-drying was considered a novel drying method in which frozen food or agricultural products could be dried by the sublimation of ice (Oetjen, 2000).…”

Section: Introductionmentioning

confidence: 99%

Drying Characteristics of Agricultural Products under Different Drying Methods: A Review

Lee

Park

Lee

et al. 2016

Journal of Biosystems Engineering

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Purpose: Drying is one of the most widely used methods for preserving agricultural products or food. The main purpose of drying agricultural products is to reduce their water content for minimizing microbial spoilage and deterioration reaction during storage. Methods: Although numerous drying methods are successfully applied to dehydrate various agricultural products with little drying time, the final quality of dried samples in terms of appearance and shape cannot be guaranteed. Therefore, based on published literature, this review was conducted to study the drying characteristics of various agricultural products when different drying methods were applied. Results: An increase in the drying power of sources-for example, increase in hot air temperature or velocity, infrared or microwave power-and the combination of drying power levels can reduce the drying time of various agricultural products. In addition, energy efficiency in drying significantly relies on the compositions of the dried samples and drying conditions. Conclusions: The drying power source is the key factor to control entire drying process of different samples and final product quality. In addition, an appropriate drying method should be selected depending on the compositions of the agricultural products.

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Hot Air Drying and Microwave-Assisted Hot Air Drying of Broccoli Stalk Slices (Brassica oleraceaL. Var.Italica)

Cited by 32 publications

References 40 publications

Use of artificial intelligence for the estimation of effective moisture diffusivity, specific energy consumption, color and shrinkage in quince drying

Use of artificial intelligence for the estimation of effective moisture diffusivity, specific energy consumption, color and shrinkage in quince drying

Effect of microwave power on drying kinetics, structure, color, and antioxidant activities of corncob

Drying Characteristics of Agricultural Products under Different Drying Methods: A Review

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