Kurutma Sistemleri, Enerji Tüketimleri ve Ürün Kalitesine Etkileri ve Örnek Sistem Tasarımı
Year 2018,
Volume: 8 Issue: 2, 25 - 39, 30.07.2018
Tuğba Kovacı
,
Erkan Dikmen
Prof. Dr.arzu Şencan Şahin
Abstract
Ürünlerin
su ve mikrobiyal aktivitesini azaltıp hacmini küçülterek uzun süreli depolama,
nakliye gibi işlemleri gerçekleştirmek için en yaygın kullanılan yöntemlerin
başında kurutma gelmektedir. Kurutma işlemi
boyunca sürekli değişen koşullar, kurutma süresi, enerji tüketimi ve
ürün kalitesi gibi kurutma işlemini gerçekleştirmek için en uygun çalışma
koşullarını belirlemeyi zorlaştırmaktadır. Yüksek enerji tüketimi ve her ürün
için farklı kurutma sonuçlarının olması nedeniyle, araştırmacılar farklı
ürünlerde farklı kurutma teknolojilerini ve bunların kombinasyonlarını
kullanılmışlardır. Bu derleme son yıllarda farklı kurutma teknolojileriyle
yapılan ürün kurutulması ve deney sonuçlarındaki gelişmeler, enerji tüketimleri
ve kurutma sonrası üründeki değişiklikler üzerine bir araştırmadır. Çalışmada ek
olarak ısı pompalı dondurarak kurutucu tasarımı örnek çalışma olarak
verilmiştir. Yaygın olarak kullanılan mevcut teknolojiler ve bu teknolojilerin
mevcut sınırlamaları ve kurutma işlemi sonrası ürün kalitesi üzerine yapılan
çalışmaların daha fazla araştırılması ve geliştirilmesi gerekmektedir.
References
- [1] Agrawal, S. G. ve Methekar, R. N. 2017. Mathematical model for heat and mass transfer during convective drying of pumpkin. Food and Bioproducts Processing, 101 (2017), 68-73.[2] Aktas, T., Fujii, S., Kawano, Y. ve Yamamoto, S. 2007. Effects of pretreatments of sliced vegetables with trehalose on drying characteristics and quality of dried products. Food and Bioproducts Processing, 85 (2007), 178-183.[3] Aktaş, M., Khanlari, A., Amini, A. ve Şevik, S. 2017. Performance analysis of heat pump and infrared–heat pump drying of grated carrot using energy-exergy methodology. Energy Conversion and Management, 132 (2017), 327-338.[4] Artnaseaw, A., Theerakulpisut, S. ve Benjapiyaporn, C. 2010. Drying characteristics of Shiitake mushroom and Jinda chili during vacuum heat pump drying. Food and Bioproducts Processing, 88 (2010), 105-114.[5] Askari, G. R., Emam-Djomeh, Z. ve Mousavi, S. M. 2016. Effects of combined coating and microwave assisted hot-air drying on the texture, microstructure and rehydration characteristics of apple slices. Food Science and Technology International, 12 (2016), 39-46.[6] Azzouz, S., Hermassi, I., Chouikh, R., Guizani, A. ve Belghith, A. 2018. The convective drying of grape seeds: Effect of shrinkage on heat and mass transfer. Journal of Food Process Engineering, 41 (2018), e12614.[7] Bai, Y., Yang, Y. ve Huang, Q. 2012. Combined electrohydrodynamic (EHD) and vacuum freeze drying of sea cucumber. Drying Technology, 30 (2012), 1051-1055.[8] Cao, X., Zhang, M., Mujumdar, A. S., Zhong, Q. ve Wang, Z. 2017. Effects of ultrasonic pretreatments on quality, energy consumption and sterilization of barley grass in freeze drying. Ultrason Sonochem, 40 (2017), 333-340.[9] Carrión, C., Mulet, A., García-Pérez, J. V. ve Cárcel, J. A. 2018. Ultrasonically assisted atmospheric freeze-drying of button mushroom. Drying kinetics and product quality. Drying Technology, (2018), 1-10.[10] Chapchaimoh, K., Poomsa-ad, N., Wiset, L. ve Morris, J. 2016. Thermal characteristics of heat pump dryer for ginger drying. Applied Thermal Engineering, 95 (2016), 491-498.[11] Chen, X. D. ve Mujumdar, A. S. 2008. Drying Technologies in Food Processing, Blackwell Publishing Ltd: 350.[12] Chou, S. K. ve Chua, K. J. 2001. New hybrid drying technologies for heat sensitive foodstuff. Trends in Food Science & Technology, 12 (2001), 359–369.[13] Chua, K. J., Chou, S. K., Ho, J. C. ve Hawlader, M. N. A. 2007. Heat pump drying: Recent developments and future trends. Drying Technology, 20 (2007), 1579-1610.[14] Chua, K. J., Chou, S. K., Mujumdar, A. S., Ho, J. C. ve Hon, C. K. 2004. Radiant-convective drying of osmotic treated agro-products: effect on drying kinetics and product quality. Food Control, 15 (2004), 145-158.[15] Chua, K. J., Chou, S. K. ve Yang, W. M. 2010. Advances in heat pump systems: A review. Applied Energy, 87 (2010), 3611-3624.[16] Colucci, D., Fissore, D., Rossello, C. ve Carcel, J. A. 2018. On the effect of ultrasound-assisted atmospheric freeze-drying on the antioxidant properties of eggplant. Food Res Int, 106 (2018), 580-588.[17] Cuccurullo, G., Giordano, L., Metallo, A. ve Cinquanta, L. 2018. Drying rate control in microwave assisted processing of sliced apples. Biosystems Engineering, 170 (2018), 24-30.[18] Çakmak, R. Ş., Tekeoğlu, O., Bozkır, H., Ergün, A. R. ve Baysal, T. 2016. Effects of electrical and sonication pretreatments on the drying rate and quality of mushrooms. LWT - Food Science and Technology, 69 (2016), 197-202.[19] Daghigh, R. ve Shafieian, A. 2016. Energy-exergy analysis of a multipurpose evacuated tube heat pipe solar water heating-drying system. Experimental Thermal and Fluid Science, 78 (2016), 266-277.[20] Defraeye, T., Nicolaï, B., Mannes, D., Aregawi, W., Verboven, P. ve Derome, D. 2016. Probing inside fruit slices during convective drying by quantitative neutron imaging. Journal of Food Engineering, 178 (2016), 198-202.[21] Dhanushkodi, S., Wilson, V. H. ve Sudhakar, K. 2017. Mathematical modeling of drying behavior of cashew in a solar biomass hybrid dryer. Resource-Efficient Technologies, (2017), [22] Dikmen, E., Ayaz, M., Kovacı, T. ve Şencan Şahin, A. 2018. Mathematical modelling of drying characteristics of medical plants in a vacuum heat pump dryer. International Journal of Ambient Energy, (2018), 1-8.[23] Estrada, J. A. ve Litchfield, J. B. 2008. High humidity drying of corn: Effect on drying rate and product quality. Drying Technology, 11 (2008), 65-84.[24] Gulcimen, F., Karakaya, H. ve Durmus, A. 2016. Drying of sweet basil with solar air collectors. Renewable Energy, 93 (2016), 77-86.[25] Hemis, M., Gariépy, Y., Choudhary, R. ve Raghavan, V. 2017. New coupling model of microwave assisted hot-air drying of a capillary porous agricultural product: Application on soybeans and canola seeds. Applied Thermal Engineering, 114 (2017), 931-937.[26] Ho, J. C., Chou, S. K., Chua, K. J., Mujumdar, A. S. ve Hawlader, M. N. A. 2002. Analytical study of cyclic temperature drying:effect on drying kinetics and product quality. Journal of Food Engineering, 51 (2002), 65-75.[27] Horuz, E., Bozkurt, H., Karatas, H. ve Maskan, M. 2017. Effects of hybrid (microwave-convectional) and convectional drying on drying kinetics, total phenolics, antioxidant capacity, vitamin C, color and rehydration capacity of sour cherries. Food Chem, 230 (2017), 295-305.[28] Huang, J., Zhang, M., Adhikari, B. ve Yang, Z. 2016. Effect of microwave air spouted drying arranged in two and three-stages on the drying uniformity and quality of dehydrated carrot cubes. Journal of Food Engineering, 177 (2016), 80-89.[29] Huang, L.-l., Zhang, M., Mujumdar, A. S. ve Lim, R.-x. 2011. Comparison of four drying methods for re-structured mixed potato with apple chips. Journal of Food Engineering, 103 (2011), 279-284.[30] Islam, M. N., Zhang, M., Adhikari, B., Xinfeng, C. ve Xu, B.-g. 2014. The effect of ultrasound-assisted immersion freezing on selected physicochemical properties of mushrooms. International Journal of Refrigeration, 42 (2014), 121-133.[31] İsmail, O. ve Akyol, E. 2016. Open-air sun dryıng:the effect of pretreatment on drying kinetic of cherry tomato. Sigma J Eng & Nat Sci, 34 (2016), 141-151.[32] Jangam, S. V., Law, C.-L. ve Mujumdar, A. S. 2010. Drying of foods vegetables and fruits [33] Jiang, J., Dang, L., Yuensin, C., Tan, H., Pan, B. ve Wei, H. 2017. Simulation of microwave thin layer drying process by a new theoretical model. Chemical Engineering Science, 162 (2017), 69-76.[34] Karel, M. ve Lund, D. B. 2003. Physical principles of food preservation. New York, Marcel Dekker Inc.639.[35] Krokida, M. K. ve Bisharat, G. I. 2004. Heat recovery from dryer exhaust air. Drying Technology, 22 (2004), 1661-1674.[36] Krokida, M. K. ve Maroulis, Z. 2000. Quality changes during drying of food materials. Drying Technology in Agricultural and Food Sciences, Science Publishers.[37] Kumoro, A. C., Pestaño, L. D. B., Bautista, J. P. T., Leguiab, R. J. R. H., Puri, S. D. D., Hadiyanto, Roces, S. A., Yung, L., Rong, X., Lothongkum, A. W., Phong, M. T., Hussain, M. A., Daud, W. R. W. ve Nam, P. T. S. 2018. Mathematical modeling of the drying kinetics of thinly-sliced Saba (Musa Balbasiana) using hot-air dryer. MATEC Web of Conferences. 156: 02004.[38] Lenaerts, S., Van Der Borght, M., Callens, A. ve Van Campenhout, L. 2018. Suitability of microwave drying for mealworms (Tenebrio molitor) as alternative to freeze drying: Impact on nutritional quality and colour. Food Chem, 254 (2018), 129-136.[39] Liliana, S.-C., Diana, P. V.-M. ve Alfredo, A. A. 2015. Structural, physical, functional and nutraceutical changes of freeze-dried fruit. African Journal of Biotechnology, 14 (2015), 442-450.[40] Lin, L., Lei, F., Sun, D. W., Dong, Y., Yang, B. ve Zhao, M. 2012. Thermal inactivation kinetics of Rabdosia serra (Maxim.) Hara leaf peroxidase and polyphenol oxidase and comparative evaluation of drying methods on leaf phenolic profile and bioactivities. Food Chem, 134 (2012), 2021-2029.[41] Lv, H., Chen, X., Liu, X., Fang, C., Liu, H., Zhang, B. ve Fei, B. 2018. The vacuum-assisted microwave drying of round bamboos: Drying kinetics, color and mechanical property. Materials Letters, 223 (2018), 159-162.[42] Madhava Naidu, M., Vedashree, M., Satapathy, P., Khanum, H., Ramsamy, R. ve Hebbar, H. U. 2016. Effect of drying methods on the quality characteristics of dill (Anethum graveolens) greens. Food Chem, 192 (2016), 849-856.[43] Minea, V. 2015. Overview of heat-pump–assisted drying systems, part II: Data provided vs. results reported. Drying Technology, 33 (2015), 527-540.[44] Monteiro, R. L., Carciofi, B. A. M., Marsaioli, A. ve Laurindo, J. B. 2015. How to make a microwave vacuum dryer with turntable. Journal of Food Engineering, 166 (2015), 276-284.[45] Monteiro, R. L., Link, J. V., Tribuzi, G., Carciofi, B. A. M. ve Laurindo, J. B. 2018. Microwave vacuum drying and multi-flash drying of pumpkin slices. Journal of Food Engineering, 232 (2018), 1-10.[46] Morad, M. M., El-Shazly, M. A., Wasfy, K. I. ve El-Maghawry, H. A. M. 2017. Thermal analysis and performance evaluation of a solar tunnel greenhouse dryer for drying peppermint plants. Renewable Energy, 101 (2017), 992-1004.[47] Muliterno, M. M., Rodrigues, D., de Lima, F. S., Ida, E. I. ve Kurozawa, L. E. 2017. Conversion/degradation of isoflavones and color alterations during the drying of okara. LWT - Food Science and Technology, 75 (2017), 512-519.[48] Ndukwu, M. C., Dirioha, C., Abam, F. I. ve Ihediwa, V. E. 2017. Heat and mass transfer parameters in the drying of cocoyam slice. Case Studies in Thermal Engineering, 9 (2017), 62-71.[49] Ng, M. X., Tham, T. C., Gan, S. H., Chua, L. S., Aziz, R., Baba, M. R., Abdullah, L. C., Chin, N. L., Ong, S. P. ve Law, C. L. 2017. Clinacanthus nutans Lindau: Effects of drying methods on the bioactive compounds, colour characteristics and water activity. Drying Technology, (2017), 1-49.[50] Nguyen, T. K., Mondor, M. ve Ratti, C. 2018. Shrinkage of cellular food during air drying. Journal of Food Engineering, 230 (2018), 8-17.[51] Oikonomopoulou, V. P. ve Krokida, M. K. 2012. Structural properties of dried potatoes, mushrooms, and strawberries as a function of freeze-drying pressure. Drying Technology, 30 (2012), 351-361.[52] Onwude, D. I., Hashim, N. ve Chen, G. 2016. Recent advances of novel thermal combined hot air drying of agricultural crops. Trends in Food Science & Technology, 57 (2016), 132-145.[53] Orikasa, T., Koide, S., Okamoto, S., Imaizumi, T., Muramatsu, Y., Takeda, J.-i., Shiina, T. ve Tagawa, A. 2014. Impacts of hot air and vacuum drying on the quality attributes of kiwifruit slices. Journal of Food Engineering, 125 (2014), 51-58.[54] Pal, U. S., Khan, M. K. ve Mohanty, S. N. 2008. Heat pump drying of green sweet pepper. Drying Technology, 26 (2008), 1584-1590.[55] Parniakov, O., Bals, O., Lebovka, N. ve Vorobiev, E. 2016. Pulsed electric field assisted vacuum freeze-drying of apple tissue. Innovative Food Science & Emerging Technologies, 35 (2016), 52-57.[56] Pei, F., Yang, W., Ma, N., Fang, Y., Zhao, L., An, X., Xin, Z. ve Hu, Q. 2016. Effect of the two drying approaches on the volatile profiles of button mushroom (Agaricus bisporus) by headspace GC–MS and electronic nose. LWT - Food Science and Technology, 72 (2016), 343-350.[57] Peters, B. H., Staels, L., Rantanen, J., Molnar, F., De Beer, T., Lehto, V. P. ve Ketolainen, J. 2016. Effects of cooling rate in microscale and pilot scale freeze-drying - Variations in excipient polymorphs and protein secondary structure. Eur J Pharm Sci, 95 (2016), 72-81.[58] Prasertsan, S. ve Saen-saby, P. 1998. Heat pump drying of agricultural materials. Drying Technology, 16 (1998), 235-250.[59] Pu, H., Li, Z., Hui, J. ve Raghavan, G. S. V. 2016. Effect of relative humidity on microwave drying of carrot. Journal of Food Engineering, 190 (2016), 167-175.[60] Qiu, Y., Li, M., Hassanien, R. H. E., Wang, Y., Luo, X. ve Yu, Q. 2016. Performance and operation mode analysis of a heat recovery and thermal storage solar-assisted heat pump drying system. Solar Energy, 137 (2016), 225-235.[61] Rabha, D. K., Muthukumar, P. ve Somayaji, C. 2017. Energy and exergy analyses of the solar drying processes of ghost chilli pepper and ginger. Renewable Energy, 105 (2017), 764-773.[62] Reyes, A., Mahn, A. ve Huenulaf, P. 2011. Drying of apple slices in atmospheric and vacuum freeze dryer. Drying Technology, 29 (2011), 1076-1089.[63] Ricce, C., Rojas, M. L., Miano, A. C., Siche, R. ve Augusto, P. E. D. 2016. Ultrasound pre-treatment enhances the carrot drying and rehydration. Food Research International, 89 (2016), 701-708.[64] Rodriguez, O., Gomes, W., Rodrigues, S. ve Fernandes, F. A. 2017. Effect of acoustically assisted treatments on vitamins, antioxidant activity, organic acids and drying kinetics of pineapple. Ultrason Sonochem, 35 (2017), 92-102.[65] Saavedra, J., Córdova, A., Navarro, R., Díaz-Calderón, P., Fuentealba, C., Astudillo-Castro, C., Toledo, L., Enrione, J. ve Galvez, L. 2017. Industrial avocado waste: Functional compounds preservation by convective drying process. Journal of Food Engineering, 198 (2017), 81-90.[66] Sadıkoğlu, H. ve Özdemir, M. 2003. Dondurarak Kurutma Evreleri. GIDA, 28 (2003), 643-649.[67] Saha, B., Bucknall, M., Arcot, J. ve Driscoll, R. 2018. Derivation of two layer drying model with shrinkage and analysis of volatile depletion during drying of banana. Journal of Food Engineering, 226 (2018), 42-52.[68] Samadi, S. H., Ghobadian, B., Najafi, G. ve Motevali, A. 2014. Potential saving in energy using combined heat and power technology for drying agricultural products (banana slices). Journal of the Saudi Society of Agricultural Sciences, 13 (2014), 174-182.[69] Sette, P., Salvatori, D. ve Schebor, C. 2016. Physical and mechanical properties of raspberries subjected to osmotic dehydration and further dehydration by air- and freeze-drying. Food and Bioproducts Processing, 100 (2016), 156-171.[70] Silva, V., Costa, J. J., Figueiredo, A. R., Nunes, J., Nunes, C., Ribeiro, T. I. B. ve Pereira, B. 2016. Study of three-stage intermittent drying of pears considering shrinkage and variable diffusion coefficient. Journal of Food Engineering, 180 (2016), 77-86.[71] Song, X., Hu, H. ve Zhang, B. 2016. Drying characteristics of Chinese Yam (Dioscorea opposita Thunb.) by far-infrared radiation and heat pump. Journal of the Saudi Society of Agricultural Sciences, (2016), [72] Sonmete, M. H., Mengeş, H. O., Ertekin, C. ve Özcan, M. M. 2016. Mathematical modeling of thin layer drying of carrot slices by forced convection. Journal of Food Measurement and Characterization, 11 (2016), 629-638.[73] Söylemez, M. S. 2006. Optimum heat pump in drying systems with waste heat recovery. Journal of Food Engineering, 74 (2006), 292-298.[74] Szadzinska, J., Lechtanska, J., Kowalski, S. J. ve Stasiak, M. 2017. The effect of high power airborne ultrasound and microwaves on convective drying effectiveness and quality of green pepper. Ultrason Sonochem, 34 (2017), 531-539.[75] Şevik, S., Aktaş, M., Doğan, H. ve Koçak, S. 2013. Mushroom drying with solar assisted heat pump system. Energy Conversion and Management, 72 (2013), 171-178.[76] Talens, C., Arboleya, J. C., Castro-Giraldez, M. ve Fito, P. J. 2017. Effect of microwave power coupled with hot air drying on process efficiency and physico-chemical properties of a new dietary fibre ingredient obtained from orange peel. LWT - Food Science and Technology, 77 (2017), 110-118.[77] Tao, Y., Wang, P., Wang, Y., Kadam, S. U., Han, Y., Wang, J. ve Zhou, J. 2016. Power ultrasound as a pretreatment to convective drying of mulberry (Morus alba L.) leaves: Impact on drying kinetics and selected quality properties. Ultrason Sonochem, 31 (2016), 310-318.[78] Thirugnanasambandham, K. ve Sivakumar, V. 2016. Enhancement of shelf life of Coriandrum sativum leaves using vacuum drying process: Modeling and optimization. Journal of the Saudi Society of Agricultural Sciences, 15 (2016), 195-201.[79] Tian, Y., Zhao, Y., Huang, J., Zeng, H. ve Zheng, B. 2016. Effects of different drying methods on the product quality and volatile compounds of whole shiitake mushrooms. Food Chem, 197 (2016), 714-722.[80] Torki-Harchegani, M., Ghanbarian, D., Maghsoodi, V. ve Moheb, A. 2016. Infrared thin layer drying of saffron (Crocus sativus L) stigmas: Mass transfer parameters and quality assessment. Chinese Journal of Chemical Engineering, (2016), [81] Wang, J., Fang, X. M., Mujumdar, A. S., Qian, J. Y., Zhang, Q., Yang, X. H., Liu, Y. H., Gao, Z. J. ve Xiao, H. W. 2017. Effect of high-humidity hot air impingement blanching (HHAIB) on drying and quality of red pepper (Capsicum annuum L.). Food Chem, 220 (2017), 145-152.[82] Wang, J., Law, C.-L., Nema, P. K., Zhao, J.-H., Liu, Z.-L., Deng, L.-Z., Gao, Z.-J. ve Xiao, H.-W. 2018. Pulsed vacuum drying enhances drying kinetics and quality of lemon slices. Journal of Food Engineering, 224 (2018), 129-138.[83] Wang, R., Zhang, M. ve Mujumdar, A. S. 2010. Effects of vacuum and microwave freeze drying on microstructure and quality of potato slices. Journal of Food Engineering, 101 (2010), 131-139.[84] Wojdylo, A., Figiel, A., Legua, P., Lech, K., Carbonell-Barrachina, A. A. ve Hernandez, F. 2016. Chemical composition, antioxidant capacity, and sensory quality of dried jujube fruits as affected by cultivar and drying method. Food Chem, 207 (2016), 170-179.[85] Xin, Y., Zhang, M. ve Adhikari, B. 2014. The effects of ultrasound-assisted freezing on the freezing time and quality of broccoli (Brassica oleracea L. var. botrytis L.) during immersion freezing. International Journal of Refrigeration, 41 (2014), 82-91.[86] Xu, B., Wang, L., Wei, B. ve Zeng, R. 2017. Low frequency ultrasound pretreatment of carrot slices: Effect on the moisture migration and quality attributes by intermediate-wave infrared radiation drying. Ultrason Sonochem, 40 (2017), 619-628.[87] Xu, W., Song, C., Li, Z., Song, F., Hu, S., Li, J., Zhu, G. ve Vijaya Raghavan, G. S. 2018. Temperature gradient control during microwave combined with hot air drying. Biosystems Engineering, 169 (2018), 175-187.[88] Xu, Y., Zhang, M., Mujumdar, A. S., Duan, X. ve Jin-cai, S. 2006. A two-stage vacuum freeze and convective air drying method for strawberries. Drying Technology, 24 (2006), 1019-1023.[89] Zhou, L., Wang, X., Bi, J., Liu, X., Yi, J. ve Wu, X. 2017. Effect of different moisture equilibration process on the quality of apple chips dried by instant controlled pressure drop (dic)-assisted hot air drying. Journal of Food Processing and Preservation, 42 (2017), e13316.[90] Zielinska, M. ve Markowski, M. 2016. The influence of microwave-assisted drying techniques on the rehydration behavior of blueberries (Vaccinium corymbosum L.). Food Chem, 196 (2016), 1188-1196.[91] Zielinska, M., Zapotoczny, P., Alves-Filho, O., Eikevik, T. M. ve Blaszczak, W. 2013. A multi-stage combined heat pump and microwave vacuum drying of green peas. Journal of Food Engineering, 115 (2013), 347-356.
Year 2018,
Volume: 8 Issue: 2, 25 - 39, 30.07.2018
Tuğba Kovacı
,
Erkan Dikmen
Prof. Dr.arzu Şencan Şahin
References
- [1] Agrawal, S. G. ve Methekar, R. N. 2017. Mathematical model for heat and mass transfer during convective drying of pumpkin. Food and Bioproducts Processing, 101 (2017), 68-73.[2] Aktas, T., Fujii, S., Kawano, Y. ve Yamamoto, S. 2007. Effects of pretreatments of sliced vegetables with trehalose on drying characteristics and quality of dried products. Food and Bioproducts Processing, 85 (2007), 178-183.[3] Aktaş, M., Khanlari, A., Amini, A. ve Şevik, S. 2017. Performance analysis of heat pump and infrared–heat pump drying of grated carrot using energy-exergy methodology. Energy Conversion and Management, 132 (2017), 327-338.[4] Artnaseaw, A., Theerakulpisut, S. ve Benjapiyaporn, C. 2010. Drying characteristics of Shiitake mushroom and Jinda chili during vacuum heat pump drying. Food and Bioproducts Processing, 88 (2010), 105-114.[5] Askari, G. R., Emam-Djomeh, Z. ve Mousavi, S. M. 2016. Effects of combined coating and microwave assisted hot-air drying on the texture, microstructure and rehydration characteristics of apple slices. Food Science and Technology International, 12 (2016), 39-46.[6] Azzouz, S., Hermassi, I., Chouikh, R., Guizani, A. ve Belghith, A. 2018. The convective drying of grape seeds: Effect of shrinkage on heat and mass transfer. Journal of Food Process Engineering, 41 (2018), e12614.[7] Bai, Y., Yang, Y. ve Huang, Q. 2012. Combined electrohydrodynamic (EHD) and vacuum freeze drying of sea cucumber. Drying Technology, 30 (2012), 1051-1055.[8] Cao, X., Zhang, M., Mujumdar, A. S., Zhong, Q. ve Wang, Z. 2017. Effects of ultrasonic pretreatments on quality, energy consumption and sterilization of barley grass in freeze drying. Ultrason Sonochem, 40 (2017), 333-340.[9] Carrión, C., Mulet, A., García-Pérez, J. V. ve Cárcel, J. A. 2018. Ultrasonically assisted atmospheric freeze-drying of button mushroom. Drying kinetics and product quality. Drying Technology, (2018), 1-10.[10] Chapchaimoh, K., Poomsa-ad, N., Wiset, L. ve Morris, J. 2016. Thermal characteristics of heat pump dryer for ginger drying. Applied Thermal Engineering, 95 (2016), 491-498.[11] Chen, X. D. ve Mujumdar, A. S. 2008. Drying Technologies in Food Processing, Blackwell Publishing Ltd: 350.[12] Chou, S. K. ve Chua, K. J. 2001. New hybrid drying technologies for heat sensitive foodstuff. Trends in Food Science & Technology, 12 (2001), 359–369.[13] Chua, K. J., Chou, S. K., Ho, J. C. ve Hawlader, M. N. A. 2007. Heat pump drying: Recent developments and future trends. Drying Technology, 20 (2007), 1579-1610.[14] Chua, K. J., Chou, S. K., Mujumdar, A. S., Ho, J. C. ve Hon, C. K. 2004. Radiant-convective drying of osmotic treated agro-products: effect on drying kinetics and product quality. Food Control, 15 (2004), 145-158.[15] Chua, K. J., Chou, S. K. ve Yang, W. M. 2010. Advances in heat pump systems: A review. Applied Energy, 87 (2010), 3611-3624.[16] Colucci, D., Fissore, D., Rossello, C. ve Carcel, J. A. 2018. On the effect of ultrasound-assisted atmospheric freeze-drying on the antioxidant properties of eggplant. Food Res Int, 106 (2018), 580-588.[17] Cuccurullo, G., Giordano, L., Metallo, A. ve Cinquanta, L. 2018. Drying rate control in microwave assisted processing of sliced apples. Biosystems Engineering, 170 (2018), 24-30.[18] Çakmak, R. Ş., Tekeoğlu, O., Bozkır, H., Ergün, A. R. ve Baysal, T. 2016. Effects of electrical and sonication pretreatments on the drying rate and quality of mushrooms. LWT - Food Science and Technology, 69 (2016), 197-202.[19] Daghigh, R. ve Shafieian, A. 2016. Energy-exergy analysis of a multipurpose evacuated tube heat pipe solar water heating-drying system. Experimental Thermal and Fluid Science, 78 (2016), 266-277.[20] Defraeye, T., Nicolaï, B., Mannes, D., Aregawi, W., Verboven, P. ve Derome, D. 2016. Probing inside fruit slices during convective drying by quantitative neutron imaging. Journal of Food Engineering, 178 (2016), 198-202.[21] Dhanushkodi, S., Wilson, V. H. ve Sudhakar, K. 2017. Mathematical modeling of drying behavior of cashew in a solar biomass hybrid dryer. Resource-Efficient Technologies, (2017), [22] Dikmen, E., Ayaz, M., Kovacı, T. ve Şencan Şahin, A. 2018. Mathematical modelling of drying characteristics of medical plants in a vacuum heat pump dryer. International Journal of Ambient Energy, (2018), 1-8.[23] Estrada, J. A. ve Litchfield, J. B. 2008. High humidity drying of corn: Effect on drying rate and product quality. Drying Technology, 11 (2008), 65-84.[24] Gulcimen, F., Karakaya, H. ve Durmus, A. 2016. Drying of sweet basil with solar air collectors. Renewable Energy, 93 (2016), 77-86.[25] Hemis, M., Gariépy, Y., Choudhary, R. ve Raghavan, V. 2017. New coupling model of microwave assisted hot-air drying of a capillary porous agricultural product: Application on soybeans and canola seeds. Applied Thermal Engineering, 114 (2017), 931-937.[26] Ho, J. C., Chou, S. K., Chua, K. J., Mujumdar, A. S. ve Hawlader, M. N. A. 2002. Analytical study of cyclic temperature drying:effect on drying kinetics and product quality. Journal of Food Engineering, 51 (2002), 65-75.[27] Horuz, E., Bozkurt, H., Karatas, H. ve Maskan, M. 2017. Effects of hybrid (microwave-convectional) and convectional drying on drying kinetics, total phenolics, antioxidant capacity, vitamin C, color and rehydration capacity of sour cherries. Food Chem, 230 (2017), 295-305.[28] Huang, J., Zhang, M., Adhikari, B. ve Yang, Z. 2016. Effect of microwave air spouted drying arranged in two and three-stages on the drying uniformity and quality of dehydrated carrot cubes. Journal of Food Engineering, 177 (2016), 80-89.[29] Huang, L.-l., Zhang, M., Mujumdar, A. S. ve Lim, R.-x. 2011. Comparison of four drying methods for re-structured mixed potato with apple chips. Journal of Food Engineering, 103 (2011), 279-284.[30] Islam, M. N., Zhang, M., Adhikari, B., Xinfeng, C. ve Xu, B.-g. 2014. The effect of ultrasound-assisted immersion freezing on selected physicochemical properties of mushrooms. International Journal of Refrigeration, 42 (2014), 121-133.[31] İsmail, O. ve Akyol, E. 2016. Open-air sun dryıng:the effect of pretreatment on drying kinetic of cherry tomato. Sigma J Eng & Nat Sci, 34 (2016), 141-151.[32] Jangam, S. V., Law, C.-L. ve Mujumdar, A. S. 2010. Drying of foods vegetables and fruits [33] Jiang, J., Dang, L., Yuensin, C., Tan, H., Pan, B. ve Wei, H. 2017. Simulation of microwave thin layer drying process by a new theoretical model. Chemical Engineering Science, 162 (2017), 69-76.[34] Karel, M. ve Lund, D. B. 2003. Physical principles of food preservation. New York, Marcel Dekker Inc.639.[35] Krokida, M. K. ve Bisharat, G. I. 2004. Heat recovery from dryer exhaust air. Drying Technology, 22 (2004), 1661-1674.[36] Krokida, M. K. ve Maroulis, Z. 2000. Quality changes during drying of food materials. Drying Technology in Agricultural and Food Sciences, Science Publishers.[37] Kumoro, A. C., Pestaño, L. D. B., Bautista, J. P. T., Leguiab, R. J. R. H., Puri, S. D. D., Hadiyanto, Roces, S. A., Yung, L., Rong, X., Lothongkum, A. W., Phong, M. T., Hussain, M. A., Daud, W. R. W. ve Nam, P. T. S. 2018. Mathematical modeling of the drying kinetics of thinly-sliced Saba (Musa Balbasiana) using hot-air dryer. MATEC Web of Conferences. 156: 02004.[38] Lenaerts, S., Van Der Borght, M., Callens, A. ve Van Campenhout, L. 2018. Suitability of microwave drying for mealworms (Tenebrio molitor) as alternative to freeze drying: Impact on nutritional quality and colour. Food Chem, 254 (2018), 129-136.[39] Liliana, S.-C., Diana, P. V.-M. ve Alfredo, A. A. 2015. Structural, physical, functional and nutraceutical changes of freeze-dried fruit. African Journal of Biotechnology, 14 (2015), 442-450.[40] Lin, L., Lei, F., Sun, D. W., Dong, Y., Yang, B. ve Zhao, M. 2012. Thermal inactivation kinetics of Rabdosia serra (Maxim.) Hara leaf peroxidase and polyphenol oxidase and comparative evaluation of drying methods on leaf phenolic profile and bioactivities. Food Chem, 134 (2012), 2021-2029.[41] Lv, H., Chen, X., Liu, X., Fang, C., Liu, H., Zhang, B. ve Fei, B. 2018. The vacuum-assisted microwave drying of round bamboos: Drying kinetics, color and mechanical property. Materials Letters, 223 (2018), 159-162.[42] Madhava Naidu, M., Vedashree, M., Satapathy, P., Khanum, H., Ramsamy, R. ve Hebbar, H. U. 2016. Effect of drying methods on the quality characteristics of dill (Anethum graveolens) greens. Food Chem, 192 (2016), 849-856.[43] Minea, V. 2015. Overview of heat-pump–assisted drying systems, part II: Data provided vs. results reported. Drying Technology, 33 (2015), 527-540.[44] Monteiro, R. L., Carciofi, B. A. M., Marsaioli, A. ve Laurindo, J. B. 2015. How to make a microwave vacuum dryer with turntable. Journal of Food Engineering, 166 (2015), 276-284.[45] Monteiro, R. L., Link, J. V., Tribuzi, G., Carciofi, B. A. M. ve Laurindo, J. B. 2018. Microwave vacuum drying and multi-flash drying of pumpkin slices. Journal of Food Engineering, 232 (2018), 1-10.[46] Morad, M. M., El-Shazly, M. A., Wasfy, K. I. ve El-Maghawry, H. A. M. 2017. Thermal analysis and performance evaluation of a solar tunnel greenhouse dryer for drying peppermint plants. Renewable Energy, 101 (2017), 992-1004.[47] Muliterno, M. M., Rodrigues, D., de Lima, F. S., Ida, E. I. ve Kurozawa, L. E. 2017. Conversion/degradation of isoflavones and color alterations during the drying of okara. LWT - Food Science and Technology, 75 (2017), 512-519.[48] Ndukwu, M. C., Dirioha, C., Abam, F. I. ve Ihediwa, V. E. 2017. Heat and mass transfer parameters in the drying of cocoyam slice. Case Studies in Thermal Engineering, 9 (2017), 62-71.[49] Ng, M. X., Tham, T. C., Gan, S. H., Chua, L. S., Aziz, R., Baba, M. R., Abdullah, L. C., Chin, N. L., Ong, S. P. ve Law, C. L. 2017. Clinacanthus nutans Lindau: Effects of drying methods on the bioactive compounds, colour characteristics and water activity. Drying Technology, (2017), 1-49.[50] Nguyen, T. K., Mondor, M. ve Ratti, C. 2018. Shrinkage of cellular food during air drying. Journal of Food Engineering, 230 (2018), 8-17.[51] Oikonomopoulou, V. P. ve Krokida, M. K. 2012. Structural properties of dried potatoes, mushrooms, and strawberries as a function of freeze-drying pressure. Drying Technology, 30 (2012), 351-361.[52] Onwude, D. I., Hashim, N. ve Chen, G. 2016. Recent advances of novel thermal combined hot air drying of agricultural crops. Trends in Food Science & Technology, 57 (2016), 132-145.[53] Orikasa, T., Koide, S., Okamoto, S., Imaizumi, T., Muramatsu, Y., Takeda, J.-i., Shiina, T. ve Tagawa, A. 2014. Impacts of hot air and vacuum drying on the quality attributes of kiwifruit slices. Journal of Food Engineering, 125 (2014), 51-58.[54] Pal, U. S., Khan, M. K. ve Mohanty, S. N. 2008. Heat pump drying of green sweet pepper. Drying Technology, 26 (2008), 1584-1590.[55] Parniakov, O., Bals, O., Lebovka, N. ve Vorobiev, E. 2016. Pulsed electric field assisted vacuum freeze-drying of apple tissue. Innovative Food Science & Emerging Technologies, 35 (2016), 52-57.[56] Pei, F., Yang, W., Ma, N., Fang, Y., Zhao, L., An, X., Xin, Z. ve Hu, Q. 2016. Effect of the two drying approaches on the volatile profiles of button mushroom (Agaricus bisporus) by headspace GC–MS and electronic nose. LWT - Food Science and Technology, 72 (2016), 343-350.[57] Peters, B. H., Staels, L., Rantanen, J., Molnar, F., De Beer, T., Lehto, V. P. ve Ketolainen, J. 2016. Effects of cooling rate in microscale and pilot scale freeze-drying - Variations in excipient polymorphs and protein secondary structure. Eur J Pharm Sci, 95 (2016), 72-81.[58] Prasertsan, S. ve Saen-saby, P. 1998. Heat pump drying of agricultural materials. Drying Technology, 16 (1998), 235-250.[59] Pu, H., Li, Z., Hui, J. ve Raghavan, G. S. V. 2016. Effect of relative humidity on microwave drying of carrot. Journal of Food Engineering, 190 (2016), 167-175.[60] Qiu, Y., Li, M., Hassanien, R. H. E., Wang, Y., Luo, X. ve Yu, Q. 2016. Performance and operation mode analysis of a heat recovery and thermal storage solar-assisted heat pump drying system. Solar Energy, 137 (2016), 225-235.[61] Rabha, D. K., Muthukumar, P. ve Somayaji, C. 2017. Energy and exergy analyses of the solar drying processes of ghost chilli pepper and ginger. Renewable Energy, 105 (2017), 764-773.[62] Reyes, A., Mahn, A. ve Huenulaf, P. 2011. Drying of apple slices in atmospheric and vacuum freeze dryer. Drying Technology, 29 (2011), 1076-1089.[63] Ricce, C., Rojas, M. L., Miano, A. C., Siche, R. ve Augusto, P. E. D. 2016. Ultrasound pre-treatment enhances the carrot drying and rehydration. Food Research International, 89 (2016), 701-708.[64] Rodriguez, O., Gomes, W., Rodrigues, S. ve Fernandes, F. A. 2017. Effect of acoustically assisted treatments on vitamins, antioxidant activity, organic acids and drying kinetics of pineapple. Ultrason Sonochem, 35 (2017), 92-102.[65] Saavedra, J., Córdova, A., Navarro, R., Díaz-Calderón, P., Fuentealba, C., Astudillo-Castro, C., Toledo, L., Enrione, J. ve Galvez, L. 2017. Industrial avocado waste: Functional compounds preservation by convective drying process. Journal of Food Engineering, 198 (2017), 81-90.[66] Sadıkoğlu, H. ve Özdemir, M. 2003. Dondurarak Kurutma Evreleri. GIDA, 28 (2003), 643-649.[67] Saha, B., Bucknall, M., Arcot, J. ve Driscoll, R. 2018. Derivation of two layer drying model with shrinkage and analysis of volatile depletion during drying of banana. Journal of Food Engineering, 226 (2018), 42-52.[68] Samadi, S. H., Ghobadian, B., Najafi, G. ve Motevali, A. 2014. Potential saving in energy using combined heat and power technology for drying agricultural products (banana slices). Journal of the Saudi Society of Agricultural Sciences, 13 (2014), 174-182.[69] Sette, P., Salvatori, D. ve Schebor, C. 2016. Physical and mechanical properties of raspberries subjected to osmotic dehydration and further dehydration by air- and freeze-drying. Food and Bioproducts Processing, 100 (2016), 156-171.[70] Silva, V., Costa, J. J., Figueiredo, A. R., Nunes, J., Nunes, C., Ribeiro, T. I. B. ve Pereira, B. 2016. Study of three-stage intermittent drying of pears considering shrinkage and variable diffusion coefficient. Journal of Food Engineering, 180 (2016), 77-86.[71] Song, X., Hu, H. ve Zhang, B. 2016. Drying characteristics of Chinese Yam (Dioscorea opposita Thunb.) by far-infrared radiation and heat pump. Journal of the Saudi Society of Agricultural Sciences, (2016), [72] Sonmete, M. H., Mengeş, H. O., Ertekin, C. ve Özcan, M. M. 2016. Mathematical modeling of thin layer drying of carrot slices by forced convection. Journal of Food Measurement and Characterization, 11 (2016), 629-638.[73] Söylemez, M. S. 2006. Optimum heat pump in drying systems with waste heat recovery. Journal of Food Engineering, 74 (2006), 292-298.[74] Szadzinska, J., Lechtanska, J., Kowalski, S. J. ve Stasiak, M. 2017. The effect of high power airborne ultrasound and microwaves on convective drying effectiveness and quality of green pepper. Ultrason Sonochem, 34 (2017), 531-539.[75] Şevik, S., Aktaş, M., Doğan, H. ve Koçak, S. 2013. Mushroom drying with solar assisted heat pump system. Energy Conversion and Management, 72 (2013), 171-178.[76] Talens, C., Arboleya, J. C., Castro-Giraldez, M. ve Fito, P. J. 2017. Effect of microwave power coupled with hot air drying on process efficiency and physico-chemical properties of a new dietary fibre ingredient obtained from orange peel. LWT - Food Science and Technology, 77 (2017), 110-118.[77] Tao, Y., Wang, P., Wang, Y., Kadam, S. U., Han, Y., Wang, J. ve Zhou, J. 2016. Power ultrasound as a pretreatment to convective drying of mulberry (Morus alba L.) leaves: Impact on drying kinetics and selected quality properties. Ultrason Sonochem, 31 (2016), 310-318.[78] Thirugnanasambandham, K. ve Sivakumar, V. 2016. Enhancement of shelf life of Coriandrum sativum leaves using vacuum drying process: Modeling and optimization. Journal of the Saudi Society of Agricultural Sciences, 15 (2016), 195-201.[79] Tian, Y., Zhao, Y., Huang, J., Zeng, H. ve Zheng, B. 2016. Effects of different drying methods on the product quality and volatile compounds of whole shiitake mushrooms. Food Chem, 197 (2016), 714-722.[80] Torki-Harchegani, M., Ghanbarian, D., Maghsoodi, V. ve Moheb, A. 2016. Infrared thin layer drying of saffron (Crocus sativus L) stigmas: Mass transfer parameters and quality assessment. Chinese Journal of Chemical Engineering, (2016), [81] Wang, J., Fang, X. M., Mujumdar, A. S., Qian, J. Y., Zhang, Q., Yang, X. H., Liu, Y. H., Gao, Z. J. ve Xiao, H. W. 2017. Effect of high-humidity hot air impingement blanching (HHAIB) on drying and quality of red pepper (Capsicum annuum L.). Food Chem, 220 (2017), 145-152.[82] Wang, J., Law, C.-L., Nema, P. K., Zhao, J.-H., Liu, Z.-L., Deng, L.-Z., Gao, Z.-J. ve Xiao, H.-W. 2018. Pulsed vacuum drying enhances drying kinetics and quality of lemon slices. Journal of Food Engineering, 224 (2018), 129-138.[83] Wang, R., Zhang, M. ve Mujumdar, A. S. 2010. Effects of vacuum and microwave freeze drying on microstructure and quality of potato slices. Journal of Food Engineering, 101 (2010), 131-139.[84] Wojdylo, A., Figiel, A., Legua, P., Lech, K., Carbonell-Barrachina, A. A. ve Hernandez, F. 2016. Chemical composition, antioxidant capacity, and sensory quality of dried jujube fruits as affected by cultivar and drying method. Food Chem, 207 (2016), 170-179.[85] Xin, Y., Zhang, M. ve Adhikari, B. 2014. The effects of ultrasound-assisted freezing on the freezing time and quality of broccoli (Brassica oleracea L. var. botrytis L.) during immersion freezing. International Journal of Refrigeration, 41 (2014), 82-91.[86] Xu, B., Wang, L., Wei, B. ve Zeng, R. 2017. Low frequency ultrasound pretreatment of carrot slices: Effect on the moisture migration and quality attributes by intermediate-wave infrared radiation drying. Ultrason Sonochem, 40 (2017), 619-628.[87] Xu, W., Song, C., Li, Z., Song, F., Hu, S., Li, J., Zhu, G. ve Vijaya Raghavan, G. S. 2018. Temperature gradient control during microwave combined with hot air drying. Biosystems Engineering, 169 (2018), 175-187.[88] Xu, Y., Zhang, M., Mujumdar, A. S., Duan, X. ve Jin-cai, S. 2006. A two-stage vacuum freeze and convective air drying method for strawberries. Drying Technology, 24 (2006), 1019-1023.[89] Zhou, L., Wang, X., Bi, J., Liu, X., Yi, J. ve Wu, X. 2017. Effect of different moisture equilibration process on the quality of apple chips dried by instant controlled pressure drop (dic)-assisted hot air drying. Journal of Food Processing and Preservation, 42 (2017), e13316.[90] Zielinska, M. ve Markowski, M. 2016. The influence of microwave-assisted drying techniques on the rehydration behavior of blueberries (Vaccinium corymbosum L.). Food Chem, 196 (2016), 1188-1196.[91] Zielinska, M., Zapotoczny, P., Alves-Filho, O., Eikevik, T. M. ve Blaszczak, W. 2013. A multi-stage combined heat pump and microwave vacuum drying of green peas. Journal of Food Engineering, 115 (2013), 347-356.