Research Article
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Year 2018, Volume: 4 Issue: 1, 1648 - 1655, 11.12.2017
https://doi.org/10.18186/journal-of-thermal-engineering.364489

Abstract

References

  • 1]FAO statistics database. Food and Agriculture Organization (FAOSTAT). http://www.fao.org/faostat/en/#data/QC (Accessed August 04, 2014).
  • [2] Abano, E. E., Ma, H., & Qu, W. (2012). Influence of combined microwave-vacuum drying on drying kinetics and quality of dried tomato slices. Journal of Food Quality, 35(3), 159–168.
  • [3] Izli, N., & Isik, E. (2015). Color and microstructure properties of tomatoes dried by microwave, convective, and microwave-convective methods. International Journal of Food Properties, 18(2), 241–249.
  • [4] Ando, Y., Maeda, Y., Mizutani, K., Wakatsuki, N., Hagiwara, S., & Nabetani, H. (2016). Impact of blanching and freeze-thaw pretreatment on drying rate of carrot roots in relation to changes in cell membrane function and cell wall structure. LWT - Food Science and Technology, 71, 40–46.
  • [5] Afolabi, T. J., Tunde-Akintunde, T. Y., & Adeyanju, J. A. (2015). Mathematical modeling of drying kinetics of untreated and pretreated cocoyam slices. Journal of Food Science and Technology, 52(5), 2731–2740.
  • [6] Ju, H. Y., El-Mashad, H. M., Fang, X. M., Pan, Z., Xiao, H. W., Liu, Y. H., & Gao, Z. J. (2016). Drying characteristics and modeling of yam slices under different relative humidity conditions. Drying Technology, 34(3), 296–306.
  • [7] Bennamoun, L., Khama, R., & Léonard, A. (2015). Convective drying of a single cherry tomato: Modeling and experimental study. Food and Bioproducts Processing, 94, 114–123.
  • [8] Li, X., Guo, H., Yang, G., Zhang, Y., Zeng, Y., & Shen, F. (2015). Thin-Layer Drying of Jerusalem Artichoke Tuber Slices and Sugar Conversion as Affected by Drying Temperature. Journal of Biobased Materials and Bioenergy, 9(4), 456-462.
  • [9] Kingsly, R. P., Goyal, R. K., Manikantan, M. R., & Ilyas, S. M. (2007). Effects of pretreatments and drying air temperature on drying behaviour of peach slice. International Journal of Food Science and Technology, 42(1), 65–69. [10] Doymaz, I. (2004). Effect of pre-treatments using potassium metabisulphide and alkaline ethyl oleate on the drying kinetics of apricots. Biosystems Engineering, 89(3), 281–287.
  • [11] Hiranvarachat, B., Devahastin, S., & Chiewchan, N. (2011). Effects of acid pretreatments on some physicochemical properties of carrot undergoing hot air drying. Food and Bioproducts Processing, 89(2), 116–127.
  • [12] Tunde‐Akintunde, T. Y. (2014). Effect of pretreatments on drying characteristics and energy requirements of plantain (Musa aab). Journal of Food Pprocessing and Preservation, 38(4), 1849-1859.
  • [13] Pirone, B. N., De Michelis, A., & Salvatori, D. M. (2014). Pretreatments Effect in Drying Behaviour and Colour of Mature and Immature “Napolitana” Sweet Cherries. Food and Bioprocess Technology, 7(6), 1640–1655.
  • [14] Adiletta, G., Russo, P., Senadeera, W., & Di Matteo, M. (2016). Drying characteristics and quality of grape under physical pretreatment. Journal of Food Engineering, 172, 9–18.
  • [15] Association of Official Analytical Chemists (AOAC). Official Methods of Analysis of AOAC International, 6th ed.; Virginia, 1995.
  • [16] Balbay, A., & Şahin, Ö. (2012). Microwave Drying Kinetics of a Thin-Layer Liquorice Root. Drying Technology, 30(8), 859–864.
  • [17] Falade, K. O., & Solademi, O. J. (2010). Modelling of air drying of fresh and blanched sweet potato slices. International Journal of Food Science and Technology, 45(2), 278–288.
  • [18] Taghian Dinani, S., & Havet, M. (2015). Effect of voltage and air flow velocity of combined convective-electrohydrodynamic drying system on the physical properties of mushroom slices. Industrial Crops and Products, 70, 417–426.
  • [19] Alibas, I. (2013). Microwave, air and combined microwave-air drying of grape leaves (vitis vinifera l.) and the determination of some quality parameters. International Journal of Food Engineering, 10(1), 69–88.
  • [20] Bal, L. M., Kar, A., Satya, S., & Naik, S. N. (2010). Drying kinetics and effective moisture diffusivity of bamboo shoot slices undergoing microwave drying. International Journal of Food Science and Technology, 45(11), 2321–2328. [21] Zogzas, N. P., Maroulis, Z. B., & Marinos-Kouris, D. (1996). Moisture Diffusivity Data Compilation in Foodstuffs. Drying Technology, 14(10), 2225–2253.
  • [22] Akanbi, C. T., Adeyemi, R. S., & Ojo, A. (2006). Drying characteristics and sorption isotherm of tomato slices. Journal of Food Engineering, 73(2), 157–163.
  • [23] Giovanelli, G., Zanoni, B., Lavelli, V., & Nani, R. (2002). Water sorption, drying and antioxidant properties of dried tomato products. Journal of Food Engineering, 52(2), 135–141.
  • [24] Vega-Gálvez, A., Zura-Bravo, L., Lemus-Mondaca, R., Martinez-Monzó, J., Quispe-Fuentes, I., Puente, L., & Di Scala, K. (2015). Influence of drying temperature on dietary fibre, rehydration properties, texture and microstructure of Cape gooseberry (Physalis peruviana L.). Journal of Food Science and Technology, 52(4), 2304–2311. https://doi.org/10.1007/s13197-013-1235-0.

EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO

Year 2018, Volume: 4 Issue: 1, 1648 - 1655, 11.12.2017
https://doi.org/10.18186/journal-of-thermal-engineering.364489

Abstract

The effects of pre-treatment and air temperature
with on drying and rehydration characteristics of cherry tomato slices were
studied. Drying experiments are carried out with the air temperature of 55, 65,
and 75°C. Drying time decreased with pre-treatment, and it also decreased
considerably with increase in air temperature. The results indicated that the
cherry tomatoes which were pre-treated with potassium solution were explored
within the shortest time. Furthermore, superior rehydration was observed the
samples which were pre-treated with potassium solution. The moisture effective
diffusivity calculated from the second Fick’s law of diffusion ranged from 2.26
to 6.22
´10-9 m2/s over the
temperature range studied. Activation energy was estimated by an Arrhenius type
equation and the activation energy values varied from 26.51 to 32.79 kJ/mol.

References

  • 1]FAO statistics database. Food and Agriculture Organization (FAOSTAT). http://www.fao.org/faostat/en/#data/QC (Accessed August 04, 2014).
  • [2] Abano, E. E., Ma, H., & Qu, W. (2012). Influence of combined microwave-vacuum drying on drying kinetics and quality of dried tomato slices. Journal of Food Quality, 35(3), 159–168.
  • [3] Izli, N., & Isik, E. (2015). Color and microstructure properties of tomatoes dried by microwave, convective, and microwave-convective methods. International Journal of Food Properties, 18(2), 241–249.
  • [4] Ando, Y., Maeda, Y., Mizutani, K., Wakatsuki, N., Hagiwara, S., & Nabetani, H. (2016). Impact of blanching and freeze-thaw pretreatment on drying rate of carrot roots in relation to changes in cell membrane function and cell wall structure. LWT - Food Science and Technology, 71, 40–46.
  • [5] Afolabi, T. J., Tunde-Akintunde, T. Y., & Adeyanju, J. A. (2015). Mathematical modeling of drying kinetics of untreated and pretreated cocoyam slices. Journal of Food Science and Technology, 52(5), 2731–2740.
  • [6] Ju, H. Y., El-Mashad, H. M., Fang, X. M., Pan, Z., Xiao, H. W., Liu, Y. H., & Gao, Z. J. (2016). Drying characteristics and modeling of yam slices under different relative humidity conditions. Drying Technology, 34(3), 296–306.
  • [7] Bennamoun, L., Khama, R., & Léonard, A. (2015). Convective drying of a single cherry tomato: Modeling and experimental study. Food and Bioproducts Processing, 94, 114–123.
  • [8] Li, X., Guo, H., Yang, G., Zhang, Y., Zeng, Y., & Shen, F. (2015). Thin-Layer Drying of Jerusalem Artichoke Tuber Slices and Sugar Conversion as Affected by Drying Temperature. Journal of Biobased Materials and Bioenergy, 9(4), 456-462.
  • [9] Kingsly, R. P., Goyal, R. K., Manikantan, M. R., & Ilyas, S. M. (2007). Effects of pretreatments and drying air temperature on drying behaviour of peach slice. International Journal of Food Science and Technology, 42(1), 65–69. [10] Doymaz, I. (2004). Effect of pre-treatments using potassium metabisulphide and alkaline ethyl oleate on the drying kinetics of apricots. Biosystems Engineering, 89(3), 281–287.
  • [11] Hiranvarachat, B., Devahastin, S., & Chiewchan, N. (2011). Effects of acid pretreatments on some physicochemical properties of carrot undergoing hot air drying. Food and Bioproducts Processing, 89(2), 116–127.
  • [12] Tunde‐Akintunde, T. Y. (2014). Effect of pretreatments on drying characteristics and energy requirements of plantain (Musa aab). Journal of Food Pprocessing and Preservation, 38(4), 1849-1859.
  • [13] Pirone, B. N., De Michelis, A., & Salvatori, D. M. (2014). Pretreatments Effect in Drying Behaviour and Colour of Mature and Immature “Napolitana” Sweet Cherries. Food and Bioprocess Technology, 7(6), 1640–1655.
  • [14] Adiletta, G., Russo, P., Senadeera, W., & Di Matteo, M. (2016). Drying characteristics and quality of grape under physical pretreatment. Journal of Food Engineering, 172, 9–18.
  • [15] Association of Official Analytical Chemists (AOAC). Official Methods of Analysis of AOAC International, 6th ed.; Virginia, 1995.
  • [16] Balbay, A., & Şahin, Ö. (2012). Microwave Drying Kinetics of a Thin-Layer Liquorice Root. Drying Technology, 30(8), 859–864.
  • [17] Falade, K. O., & Solademi, O. J. (2010). Modelling of air drying of fresh and blanched sweet potato slices. International Journal of Food Science and Technology, 45(2), 278–288.
  • [18] Taghian Dinani, S., & Havet, M. (2015). Effect of voltage and air flow velocity of combined convective-electrohydrodynamic drying system on the physical properties of mushroom slices. Industrial Crops and Products, 70, 417–426.
  • [19] Alibas, I. (2013). Microwave, air and combined microwave-air drying of grape leaves (vitis vinifera l.) and the determination of some quality parameters. International Journal of Food Engineering, 10(1), 69–88.
  • [20] Bal, L. M., Kar, A., Satya, S., & Naik, S. N. (2010). Drying kinetics and effective moisture diffusivity of bamboo shoot slices undergoing microwave drying. International Journal of Food Science and Technology, 45(11), 2321–2328. [21] Zogzas, N. P., Maroulis, Z. B., & Marinos-Kouris, D. (1996). Moisture Diffusivity Data Compilation in Foodstuffs. Drying Technology, 14(10), 2225–2253.
  • [22] Akanbi, C. T., Adeyemi, R. S., & Ojo, A. (2006). Drying characteristics and sorption isotherm of tomato slices. Journal of Food Engineering, 73(2), 157–163.
  • [23] Giovanelli, G., Zanoni, B., Lavelli, V., & Nani, R. (2002). Water sorption, drying and antioxidant properties of dried tomato products. Journal of Food Engineering, 52(2), 135–141.
  • [24] Vega-Gálvez, A., Zura-Bravo, L., Lemus-Mondaca, R., Martinez-Monzó, J., Quispe-Fuentes, I., Puente, L., & Di Scala, K. (2015). Influence of drying temperature on dietary fibre, rehydration properties, texture and microstructure of Cape gooseberry (Physalis peruviana L.). Journal of Food Science and Technology, 52(4), 2304–2311. https://doi.org/10.1007/s13197-013-1235-0.
There are 22 citations in total.

Details

Journal Section Articles
Authors

A. S. Kipcak

Publication Date December 11, 2017
Submission Date June 15, 2016
Published in Issue Year 2018 Volume: 4 Issue: 1

Cite

APA Kipcak, A. S. (2017). EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO. Journal of Thermal Engineering, 4(1), 1648-1655. https://doi.org/10.18186/journal-of-thermal-engineering.364489
AMA Kipcak AS. EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO. Journal of Thermal Engineering. December 2017;4(1):1648-1655. doi:10.18186/journal-of-thermal-engineering.364489
Chicago Kipcak, A. S. “EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO”. Journal of Thermal Engineering 4, no. 1 (December 2017): 1648-55. https://doi.org/10.18186/journal-of-thermal-engineering.364489.
EndNote Kipcak AS (December 1, 2017) EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO. Journal of Thermal Engineering 4 1 1648–1655.
IEEE A. S. Kipcak, “EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO”, Journal of Thermal Engineering, vol. 4, no. 1, pp. 1648–1655, 2017, doi: 10.18186/journal-of-thermal-engineering.364489.
ISNAD Kipcak, A. S. “EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO”. Journal of Thermal Engineering 4/1 (December 2017), 1648-1655. https://doi.org/10.18186/journal-of-thermal-engineering.364489.
JAMA Kipcak AS. EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO. Journal of Thermal Engineering. 2017;4:1648–1655.
MLA Kipcak, A. S. “EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO”. Journal of Thermal Engineering, vol. 4, no. 1, 2017, pp. 1648-55, doi:10.18186/journal-of-thermal-engineering.364489.
Vancouver Kipcak AS. EFFECT OF PRE-TREATMENT AND AIR TEMPERATURE ON DRYING TIME OF CHERRY TOMATO. Journal of Thermal Engineering. 2017;4(1):1648-55.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering