Investigation of Heat and Moisture Transport in Bananas during Microwave Heating Process

Thuto, Wisara; Banjong, Kittichai

doi:10.3390/pr7080545

Cited by 14 publications

(10 citation statements)

References 52 publications

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“…At present, the techniques commonly used for drying grain include hot-air drying, freeze drying, and microwave drying [3][4][5]. Of these techniques, microwave drying only works on polar molecules and is very popular due to its advantages, such as fast drying speed, lower energy consumption, and ease of control [6][7][8][9][10]. Hemis et al [11,12] studied microwave drying of wheat, soybean and canola seeds, and established a new coupling model.…”

Section: Introductionmentioning

confidence: 99%

Microwave Drying Characteristics and Drying Quality Analysis of Corn in China

Liu

et al. 2021

Processes

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To identify the microwave drying characteristics of corn, microwave drying tests were conducted on corn. By taking the moisture content, drying rate, and drying temperature as indices, this research revealed the effects of different microwave powers and loads on the microwave drying characteristics of corn. Moreover, energy consumption and quality of dried corn were analysed under different drying conditions. The results demonstrate that microwave drying has significant energy-saving effects. The energy consumption by microwave drying is less than 0.3 times that used by electrothermal drying under the same load. Both microwave power and load exert significant influences on drying characteristics. Higher microwave power results in a greater average drying rate, wherein shorter periods of time are required to reach the maximum drying rate and higher temperatures of the corn. However, the load shows the opposite tendency. The smaller the load, the higher the temperature of the corn in the early stage of drying. However, as drying continues, the temperature curve changes significantly, and the temperature rises with the increase in load in the later stage of drying. In consideration of energy consumption and dried quality, the load of corn should be increased as appropriate, and the microwave intensity should be limited to no higher than 0.7 W/g in the experiment.

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Section: Introductionmentioning

confidence: 99%

Microwave Drying Characteristics and Drying Quality Analysis of Corn in China

Liu

et al. 2021

Processes

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“…These disadvantages not only affect the color, flavor, texture, taste, and nutrients of dried materials but also reduce the density and water absorbance ability of dried products and the shift of solutes from the interior to the surface [12]. Compared to hot air drying, microwave drying technology is another method that has been widely used to dry various vegetables and fruits because of its high energy efficiency and high drying rate [13,14]. It is applicable for the drying of fruit and vegetable products especially with high moisture content (e.g., grape, carrot, and apple).…”

Section: Introductionmentioning

confidence: 99%

“…The interior heat generated by "molecular friction" within the materials leads to water evaporation and subsequently creates a pressure environment with the pressure decreasing from the interior of drying materials to the surface. Thus, the pressure gradient can greatly speed up the drying process, shorten drying period, and improve energy efficiency [13,15]. Nevertheless, microwave drying is well known to cause non-uniform heating.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Microwave Coupled Hot Air Drying for Chinese Yam Using Response Surface Methodology

Wang¹,

Liu²,

Yu³

et al. 2019

Processes

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The effect of microwave coupled hot air drying on rehydration ratio (RR) and total sugar content (TSC) of Chinese yam was investigated. Single factor test and response surface methodology were used for process parameter optimization with hot air temperature, hot air velocity, slice thickness, and microwave power density as variables and RR and TSC of dried products as responses. The effect of variables on RR followed the order: slice thickness > hot air temperature > microwave power density > hot air velocity. The effect of variables on TSC followed the order: slice thickness > microwave power density > hot air velocity > hot air temperature. The optimized process parameters were hot air velocity of 2.5 m/s, hot air temperature of 61.7 °C, slice thickness of 8.5 mm, and microwave power density of 5.9 W/g. Under the optimal conditions, the predicted values of RR and TSC were 1.90 g/g and 5.74 g/100 g, respectively, which is very close to corresponding actual values (1.83 g/g and 5.72 g/100 g). The desirability of 0.913 further validated the effectiveness of the model. The findings from this work may apply to other agricultural products.

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“…In addition to thermal profiles, in models that simulate the heating process of foods with high moisture or in small volume size, where the mass transfer can make a great difference to the final results, the moisture change due to the microwave power should also be validated. The total moisture loss [ 3 , 46 , 49 , 50 , 67 , 72 , 73 ] and/or transient point moisture content [ 74 ] have been measured for validation. Besides, the pressure generated due to moisture evaporation was also measured for validation [ 46 ].…”

Section: Mechanistic Modelsmentioning

confidence: 99%

Mechanistic and Machine Learning Modeling of Microwave Heating Process in Domestic Ovens: A Review

Yang

Chen

2021

Foods

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The domestic microwave oven has been popularly used at home in heating foods for its rapid heating rate and high power efficiency. However, non-uniform heating by microwave is the major drawback that can lead to severe food safety and quality issues. In order to alleviate this problem, modeling of microwave heating process in domestic ovens has been employed to simulate and understand the complicated interactions between microwaves and food products. This paper extensively reviews the mechanistic models with different geometric dimensions and physics/kinetics that simulated the microwave heating process. The model implementation and validation strategies related to the model accuracy and efficiency are also discussed. With the emergence of the machine learning technique, this paper also discusses the recent development of hybrid models that integrate machine learning with mechanistic models in improving microwave heating performance. Besides, pure machine learning models using only experimental data as input are also covered. Further research is needed to improve the model accuracy, efficiency, and ease of use to enable the industrial application of the models in the development of microwave systems and food products.

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Investigation of Heat and Moisture Transport in Bananas during Microwave Heating Process

Cited by 14 publications

References 52 publications

Microwave Drying Characteristics and Drying Quality Analysis of Corn in China

Microwave Drying Characteristics and Drying Quality Analysis of Corn in China

Optimization of Microwave Coupled Hot Air Drying for Chinese Yam Using Response Surface Methodology

Mechanistic and Machine Learning Modeling of Microwave Heating Process in Domestic Ovens: A Review

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