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FARKLI MİKRODALGA GÜÇLERİNİN KÖPÜK KURUTMA YÖNTEMİ İLE KURUTULMUŞ YUMURTA BEYAZI TOZLARININ KURUMA KİNETİĞİ VE TOZ ÜRÜN ÖZELLİKLERİ ÜZERİNE ETKİSİ

Year 2019, , 328 - 339, 15.04.2019
https://doi.org/10.15237/gida.GD18126

Abstract

Bu çalışmanın amacı, farklı mikrodalga güçlerinin köpük
kurutma yöntemi ile kurutulmuş yumurta beyazı köpüğünün kuruma kinetiği ve toz
özellikleri üzerine etkisinin belirlenmesidir. Bu amaç doğrultusuna, yumurta
beyazı köpüğü blender kullanılarak (100W, 5dk.) elde edilmiş ve mikrodalga
fırında beş farklı mikrodalga gücünde (120-720W) kurutulmuştur. Artan
mikrodalga gücü ile kuruma süresi 360s’den 80s’ye azalmıştır (
P <0.05).
Yumurta beyazı tozunun kuruma kinetiğini belirlemek için, deneysel veriler
çeşitli yarı teorik modeller ve bir empirik model kullanılarak modellenmiştir.
Yüksek R
2 değeriyle (0.983-0.994) Page model yumurta beyazı
köpüğünün kuruma davranışının belirlenmesi için en uygun model olarak
seçilmiştir. Ayrıca, ortalama etkin nem difüzyon katsayısı ve ortalama
aktivasyon enerjisi hesaplanmış ve sırasıyla 3.3389E-08- 1.4139E-07 m
2/s
ve 28.0640 W/g olarak bulunmuştur.

References

  • Abbasi, E., Azizpour, M. (2016). Evaluation of physicochemical properties of foam mat dried sour cherry powder. LWT-Food Sci Technol, 68: 105-110.
  • Akdoğan, A., Çalışkan Koç, G., Dirim, S.N. (2017). Mathematical modeling of thin-layer microwave drying of corn husk and investigation of powder properties. Bulg Chem Commun, 49 (4) 986 – 993.
  • Alibas, I. (2006). Characteristics of chard leaves during microwave, convective, and combined microwave convective drying. Drying Technol, 24(1):1425- 1435.
  • Arabhosseini, A., Huisman, W., van Boxtel A., Müller, J. (2009). Modeling of thin layer drying of tarragon (Artemisia dracunculus L.). Ind Crops Prod. 29, 1: 53-59.
  • Ayadi, M.A., Khemakhem, M., Belgith, H., Attia. H. (2008). Effect of Moderate Spray Drying Conditions on Functionality of Dried Egg White and Whole Egg. J Food Sci, 73(6):281-287.
  • Baysal, T., İçier, F., Ersus, S. (2003). Effects of microwave and infrared drying on the quality of carrot and garlic. Eur Food Res Technol, 218(1):68–73.
  • Dadali, G., Demirhan, E., Özbek, B. (2007). Color change kinetics of spinach undergoing microwave drying. Drying Technol, 25(10):1713–23.
  • Demiray, E., Seker, A., Tulek, Y. (2017). Drying kinetics of onion (Allium cepa L.) slices with convective and microwave drying. Heat Mass Transfer, 53(5), 1817-1827.
  • Erbay, Z., Icier, F. (2009). A review of thin layer drying of foods: theory, modeling, and experimental results. Crit Rev Food Sci, 50: 441-464.
  • Goula, A.M., Adamopoulos, K.G., (2008). Effect of maltodextrin addition during spray drying of tomato pulp in dehumidified air: ΙΙ. powder properties. Drying Technol, 26, 726-737.
  • Jinapong, N., Suphantharika, M., Jamnong, P. (2008). Production of instant soymilk powders by ultrafiltration, spray drying and fluidized bed agglomeration. J Food Eng, 84, 194–205.
  • Kudra, T., Ratti, C. (2006). Foam-Mat Drying: Energy and Cost Analyses. Can Biosyst Eng, 48:27–32.
  • Ma, S., Zhao, S., Zhang, Y. Yu, Y., Liu, J., Xu, M. (2013). Quality characteristic of spray-drying egg white powders. Mol Biol Rep, 40: 5677.
  • Marzec, A., Kowalska, H., Zadrozna, M. (2010). Analysıs of instrumental and sensory texture attributes of microwave–convective dried apples. J Texture Study, 41, 417–439.
  • Maskan, M. (2000). Microwave/air and microwave finish drying of banana. J Food Eng, 44, 71-78.
  • Moradi, M., Maleki, A., Ghazavi, M.A. (2013). Mathematical Modeling, Moisture Diffusion and Energy efficiency of Thin Layer Drying of Potato. Int J Agri Crop Sci, 5(15),1663-1669.
  • Muthukumaran, A., Ratti, C., Raghavan, V.G.S. (2008a). Foam-Mat Freeze Drying of Egg White-Mathematical Modeling Part II: Freeze Drying and Modeling. Drying Technol, 26(4):513–18.
  • Muthukumaran, A., Ratti, C., Raghavan, V.G.S. (2008b). Foam-Mat Freeze Drying of Egg White and Mathematical Modeling Part I Optimization of Egg White Foam Stability. Drying Technol, 26(4):508–12.
  • Onwude, D.I., Hashim, N., Janius, R.B., Nawi, N.M., Abdan, K. (2016). Modeling the Thin-Layer Drying of Fruits and Vegetables: A Review. Comp Rev Food Sci Food Saf, 15, 599-618.
  • Ozkan, I.A., Akbudak, B., Akbudak, N. (2007). Microwave drying characteristics of spinach. J Food Eng, 78,2: 577-583.
  • Narindra, R., Ratti, C. (2010). Foam-Mat Freeze-Drying of Apple Juice Part 1: Experimental Data and Ann Simulations. J Food Process Eng, 33(1):268–283.
  • Rajkumar, P., Kailappan, R., Viswanathan, R., Raghavan, G.S.V., Ratti, C. (2007). Foam mat drying of alphonso mango pulp. Drying Technol, 25(2):357- 365.
  • Sadeghi, M., Mirzabeigi Kesbi, O., Mireei, S.A. (2013). Mass transfer characteristics during convective, microwave and combined microwave-convective drying of lemon slices. J Sci Food Agric, 93, 471–478.
  • Salahi, M.R., Mohebbi, M., Taghizadeh, M. (2015). Foam-mat drying of cantaloupe (cucumis melo): Optimization of foaming parameters and investigating drying characteristics. J Food Process Pres, 39: 1798-1808.
  • Sharada, S. (2013). Studies on Effect of Various Operating Parameters & Foaming Agents- Drying of Fruits and Vegetables. International Journal of Modern Engineering Research (IJMER), 3(3):1512–19.
  • Solval, K.E.M. (2011). Spray drying technology for the production and processing of microencapsulated omega-3 fish oil with egg powder, Master Thesis, 1390. Louisiana State University and Agricultural and Mechanical College, USA
  • Tekin, Z.H., Baslar, M. (2018). The effect of ultrasound-assisted vacuum drying on the drying rate and quality of red peppers. ‎J Therm Anal Calorim, 132(2), 1131–1143.
  • Venkatachalam S., Sangamithra A., John S.G., Kuppuswamy, K. (2014). Foam mat drying of food materials: a review. J Food Process Preserv, 39: 3165-3174.
  • Wang, Z., Sun, J., Chen, F., Liao, X., Hu X. (2007). Mathematical modelling on thin layer microwave drying of apple pomace with and without hot air pre-drying, J of Food Eng, 80:536–544.

THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER

Year 2019, , 328 - 339, 15.04.2019
https://doi.org/10.15237/gida.GD18126

Abstract



The aim of this study is
to determine the effect of different microwave powers on the drying kinetics
and powder properties of foam mat dried egg white powder. For this purpose, the
egg white foam was obtained by using kitchen blender (1000W, 5min) and dried in
a domestic microwave oven at five different microwave powers (120-720W).
According to the results, the drying time decreased from 360s to 80s according
to increasing microwave power (
P <0.05). In order to determine the
drying kinetic of egg white foam, the experimental data was fitted to various
semitheoretical models and one empirical model. Page model which showed the
highest R
2 values (0.983-0.994) was chosen as the most suitable
model for determining the drying behavior of egg white foam. In addition, the
average effective moisture diffusivity and activation energy values were
calculated and ranged between 3.3389E-08 to 1.4139E-07 m
2/s and
28.0640 W/g, respectively

References

  • Abbasi, E., Azizpour, M. (2016). Evaluation of physicochemical properties of foam mat dried sour cherry powder. LWT-Food Sci Technol, 68: 105-110.
  • Akdoğan, A., Çalışkan Koç, G., Dirim, S.N. (2017). Mathematical modeling of thin-layer microwave drying of corn husk and investigation of powder properties. Bulg Chem Commun, 49 (4) 986 – 993.
  • Alibas, I. (2006). Characteristics of chard leaves during microwave, convective, and combined microwave convective drying. Drying Technol, 24(1):1425- 1435.
  • Arabhosseini, A., Huisman, W., van Boxtel A., Müller, J. (2009). Modeling of thin layer drying of tarragon (Artemisia dracunculus L.). Ind Crops Prod. 29, 1: 53-59.
  • Ayadi, M.A., Khemakhem, M., Belgith, H., Attia. H. (2008). Effect of Moderate Spray Drying Conditions on Functionality of Dried Egg White and Whole Egg. J Food Sci, 73(6):281-287.
  • Baysal, T., İçier, F., Ersus, S. (2003). Effects of microwave and infrared drying on the quality of carrot and garlic. Eur Food Res Technol, 218(1):68–73.
  • Dadali, G., Demirhan, E., Özbek, B. (2007). Color change kinetics of spinach undergoing microwave drying. Drying Technol, 25(10):1713–23.
  • Demiray, E., Seker, A., Tulek, Y. (2017). Drying kinetics of onion (Allium cepa L.) slices with convective and microwave drying. Heat Mass Transfer, 53(5), 1817-1827.
  • Erbay, Z., Icier, F. (2009). A review of thin layer drying of foods: theory, modeling, and experimental results. Crit Rev Food Sci, 50: 441-464.
  • Goula, A.M., Adamopoulos, K.G., (2008). Effect of maltodextrin addition during spray drying of tomato pulp in dehumidified air: ΙΙ. powder properties. Drying Technol, 26, 726-737.
  • Jinapong, N., Suphantharika, M., Jamnong, P. (2008). Production of instant soymilk powders by ultrafiltration, spray drying and fluidized bed agglomeration. J Food Eng, 84, 194–205.
  • Kudra, T., Ratti, C. (2006). Foam-Mat Drying: Energy and Cost Analyses. Can Biosyst Eng, 48:27–32.
  • Ma, S., Zhao, S., Zhang, Y. Yu, Y., Liu, J., Xu, M. (2013). Quality characteristic of spray-drying egg white powders. Mol Biol Rep, 40: 5677.
  • Marzec, A., Kowalska, H., Zadrozna, M. (2010). Analysıs of instrumental and sensory texture attributes of microwave–convective dried apples. J Texture Study, 41, 417–439.
  • Maskan, M. (2000). Microwave/air and microwave finish drying of banana. J Food Eng, 44, 71-78.
  • Moradi, M., Maleki, A., Ghazavi, M.A. (2013). Mathematical Modeling, Moisture Diffusion and Energy efficiency of Thin Layer Drying of Potato. Int J Agri Crop Sci, 5(15),1663-1669.
  • Muthukumaran, A., Ratti, C., Raghavan, V.G.S. (2008a). Foam-Mat Freeze Drying of Egg White-Mathematical Modeling Part II: Freeze Drying and Modeling. Drying Technol, 26(4):513–18.
  • Muthukumaran, A., Ratti, C., Raghavan, V.G.S. (2008b). Foam-Mat Freeze Drying of Egg White and Mathematical Modeling Part I Optimization of Egg White Foam Stability. Drying Technol, 26(4):508–12.
  • Onwude, D.I., Hashim, N., Janius, R.B., Nawi, N.M., Abdan, K. (2016). Modeling the Thin-Layer Drying of Fruits and Vegetables: A Review. Comp Rev Food Sci Food Saf, 15, 599-618.
  • Ozkan, I.A., Akbudak, B., Akbudak, N. (2007). Microwave drying characteristics of spinach. J Food Eng, 78,2: 577-583.
  • Narindra, R., Ratti, C. (2010). Foam-Mat Freeze-Drying of Apple Juice Part 1: Experimental Data and Ann Simulations. J Food Process Eng, 33(1):268–283.
  • Rajkumar, P., Kailappan, R., Viswanathan, R., Raghavan, G.S.V., Ratti, C. (2007). Foam mat drying of alphonso mango pulp. Drying Technol, 25(2):357- 365.
  • Sadeghi, M., Mirzabeigi Kesbi, O., Mireei, S.A. (2013). Mass transfer characteristics during convective, microwave and combined microwave-convective drying of lemon slices. J Sci Food Agric, 93, 471–478.
  • Salahi, M.R., Mohebbi, M., Taghizadeh, M. (2015). Foam-mat drying of cantaloupe (cucumis melo): Optimization of foaming parameters and investigating drying characteristics. J Food Process Pres, 39: 1798-1808.
  • Sharada, S. (2013). Studies on Effect of Various Operating Parameters & Foaming Agents- Drying of Fruits and Vegetables. International Journal of Modern Engineering Research (IJMER), 3(3):1512–19.
  • Solval, K.E.M. (2011). Spray drying technology for the production and processing of microencapsulated omega-3 fish oil with egg powder, Master Thesis, 1390. Louisiana State University and Agricultural and Mechanical College, USA
  • Tekin, Z.H., Baslar, M. (2018). The effect of ultrasound-assisted vacuum drying on the drying rate and quality of red peppers. ‎J Therm Anal Calorim, 132(2), 1131–1143.
  • Venkatachalam S., Sangamithra A., John S.G., Kuppuswamy, K. (2014). Foam mat drying of food materials: a review. J Food Process Preserv, 39: 3165-3174.
  • Wang, Z., Sun, J., Chen, F., Liao, X., Hu X. (2007). Mathematical modelling on thin layer microwave drying of apple pomace with and without hot air pre-drying, J of Food Eng, 80:536–544.
There are 29 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Gülşah Çalışkan Koç

Burcu Çabuk 0000-0001-8836-6047

Publication Date April 15, 2019
Published in Issue Year 2019

Cite

APA Çalışkan Koç, G., & Çabuk, B. (2019). THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER. Gıda, 44(2), 328-339. https://doi.org/10.15237/gida.GD18126
AMA Çalışkan Koç G, Çabuk B. THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER. GIDA. April 2019;44(2):328-339. doi:10.15237/gida.GD18126
Chicago Çalışkan Koç, Gülşah, and Burcu Çabuk. “THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER”. Gıda 44, no. 2 (April 2019): 328-39. https://doi.org/10.15237/gida.GD18126.
EndNote Çalışkan Koç G, Çabuk B (April 1, 2019) THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER. Gıda 44 2 328–339.
IEEE G. Çalışkan Koç and B. Çabuk, “THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER”, GIDA, vol. 44, no. 2, pp. 328–339, 2019, doi: 10.15237/gida.GD18126.
ISNAD Çalışkan Koç, Gülşah - Çabuk, Burcu. “THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER”. Gıda 44/2 (April 2019), 328-339. https://doi.org/10.15237/gida.GD18126.
JAMA Çalışkan Koç G, Çabuk B. THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER. GIDA. 2019;44:328–339.
MLA Çalışkan Koç, Gülşah and Burcu Çabuk. “THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER”. Gıda, vol. 44, no. 2, 2019, pp. 328-39, doi:10.15237/gida.GD18126.
Vancouver Çalışkan Koç G, Çabuk B. THE EFFECT OF DIFFERENT MICROWAVE POWERS ON THE DRYING KINETICS AND POWDER PROPERTIES OF FOAM-MAT DRIED EGG WHITE POWDER. GIDA. 2019;44(2):328-39.

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