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Parameters of Modular Microwave Vacuum Evaporators
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PARAMETERS OF MODULAR MICROWAVE VACUUM EVAPORATORS
Gavrilov Alexander 1
Gerber Yuriy 2
Authors:
1.  V.I. Vernadsky Crimean Federal University

Simferopol, Russian Federation
2.  V.I. Vernadsky Crimean Federal University

Simferopol, Simferopol, Russian Federation
Type:
Article
DOI:
https://doi.org/10.21603/2074-9414-2024-1-2495
Pages:
from 135 to 145
Status:
Published
Received:
14.03.2023
Accepted:
04.07.2023
Published:
28.03.2024
Subject area:
VAC 4.3.1 Технологии, машины и оборудование для агропромышленного комплекса
VAC 4.3.3 Пищевые системы
UDK 66 Химическая технология. Химическая промышленность. Пищевая промышленность. Металлургия. Родственные отрасли
Language:
Russian, English
Keywords:
UHF field, steam content, boiling, juice, concentrate, metal consumption, overheating, vaporization, separation
Funding:
The research was conducted on the premises of the Agrotechnological Academy Institute, V.I. Vernadsky Crimean Federal University (Vernadsky CFU) as part of a state assignment.
Abstract and keywords
Abstract (English):
Microwave energy facilitates evaporation, thus producing more solids of higher quality than other concentration methods and traditional evaporators. Despite its effectiveness, the food industry has no methods for industrial microwave evaporation. This article introduces design and operating parameters for the working module of a novel microwave vacuum evaporation. The new microwave vacuum evaporator with cylindrical modules was used for juice concentration. The fluid phase level was calculated based on the development and growth of vapor bubbles across the fluid phase volume. The steam phase level depended on the minimal volume of the steam separator. When the operating pressure in the module was 7.4 kPa, the minimal radius of a vapor bubble was 5.6×10–5 m; 100% vapor content was observed 42 mm above the nucleation level of vapor bubbles. The average total height of the fluid phase level above the emitter was 26 mm, which exceeded the level of radiation penetration. The data obtained were used to develop an algorithm that made it possible to calculate the design and operating parameters of the microwave vacuum evaporator, as well as standard size modules with emitter powers of 600–3000 W. The modules with a diameter of 150 mm had the vapor zone at 43–8 mm and the transitional vapor-fluid zone at 9–16 mm. The boiling zone was at 45–60 mm. The new microwave vacuum evaporator covered the entire power range of industrial air-cooled magnetrons. However, the final stage required modules of ≤ 1100 W for high concentrations of ≥ 60–80%.

Keywords:
UHF field, steam content, boiling, juice, concentrate, metal consumption, overheating, vaporization, separation
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References

1. Tabakaev AV, Tabakaeva OV, Prikhodko YuV. Functional instant beverages. Foods and Raw Materials. 2023;11(2):187–196. https://doi.org/10.21603/2308-4057-2023-2-565

2. Reznichenko IYu, Frolova NA, Kuchebo VV, Turov SV. Syrups in sugar confectionery products of high nutritional value. Food Processing: Techniques and Technology. 2019;49(1):62–69. (In Russ.). https://doi.org/10.21603/2074-9414-2019-1-62-69

3. Ojileh PC, Okechukwu QN. Value-added zobo drink with date juice. Food Processing: Techniques and Technology. 2023;53(3):545–553. https://doi.org/10.21603/2074-9414-2023-3-2453

4. Shalunov AV, Khmelev VN, Terentiev SA, Nesterov VA, Golykh RN. Ultrasonic dehydration of food products with moisture removal without phase transition. Food Processing: Techniques and Technology. 2021;51(2):363–373. (In Russ.). https://doi.org/10.21603/2074-9414-2021-2-363-373

5. Gavrilov AV. Researching of process energy technologies development of vegetative raw materials. Transactions of Taurida Agricultural Science. 2018;179(16):82–89. (In Russ.). https://elibrary.ru/MJXFAL

6. Burdo OG, Ruzhitskaya NV, Makarenko TA, Malashevich SA. Concentrating stevia extracts in a microwave vacuum evaporation unit. Scientific works of the Odessa National Academy of Food Technologies. 2015;47(2):67–70. (In Russ.). https://elibrary.ru/YGUYAP

7. Dzhangiryan VG, Krivenko IV, Namestnikov VV, Afanasev AG, Prokhorov EN. Method and installation for concentration of acids. Russia patent RU 2651253C1. 2018.

8. Syomochkin AS, Khatsrinov AI, Khakimov MF, Namestnikov VV, Gatina RF. Microwave radiation for concentrating sulfuric acid in vacuum. Bulletin of Kazan Technological University. 2010;(8):410–411. (In Russ.). https://elibrary.ru/MVNDYV

9. Li H, Zhao Z, Xiouras C, Stefanidis GD, Li X, Gao X. Fundamentals and applications of microwave heating to chemicals separation processes. Renewable and Sustainable Energy Reviews. 2019;114. https://doi.org/10.1016/j.rser.2019.109316

10. Liu K, Zhao Z, Li H, Gao X. Microwave-induced vapor-liquid mass transfer separation technology – full of breakthrough opportunities in electrified chemical processes. Current Opinion in Chemical Engineering. 2023;39. https://doi.org/10.1016/j.coche.2022.100890

11. Ge X. Experimental study on concentrating apple juice by microwave. Advance Journal of Food Science and Technologies. 2014;6(4):544–546. https://doi.org/10.19026/ajfst.6.70

12. Yousefi S, Emam-Djomeh Z, Mousavi SMA, Askari GR. Comparing the effects of microwave and conventional heating methods on the evaporation rate and quality attributes of pomegranate (Punica granatum L.) juice concentrate. Food and Bioprocess Technology. 2012;5:1328–1339. https://doi.org/10.1007/s11947-011-0603-x

13. Dinçer C, ÇAM İB, TORUN M, Başünal Gülmez H, TOPUZ A. Mathematical modeling of concentrations of grape, pomegranate and black carrot juices by various methods. The Journal of Food. 2019;44(6):1092–1110. https://doi.org/10.15237/gida.GD19080

14. Bozkir H, Baysal T. Concentration of apple juice by vacuum microwave evaporator and in comparison to rotary evaporator. Journal of Food Processing and Technology. 2017;8(9):128. https://doi.org/10.4172/2157-7110-C1-069

15. Bozkir H, Baysal T. Concentration of apple juice using a vacuum microwave evaporator as a novel technique: Determination of quality characteristics. Journal of Food Process Engineering. 2017;40(5). https://doi.org/10.1111/jfpe.12535

16. Dinçer C. Effect of intermittent microwave vacuum concentration on quality parameters of apple juice and sour cherry nectar and mathematical modeling of concentration. Journal of Microwave Power and Electromagnetic Energy. 2021;55(3):175–196. https://doi.org/10.1080/08327823.2021.1952837

17. Lohrasbi-Nejad S, Shahedi M, Fathi M. Comparative study of microwave-assisted vacuum evaporation, microwave-assisted evaporation, and conventional evaporation methods on physicochemical properties of barberry juice. Journal of Agricultural Science and Technology. 2021;23(2):307–317.

18. Chua LS, Leong CY. Effects of microwave heating on quality attributes of pineapple juice. Journal of Food Processing and Preservation. 2020;44(10). https://doi.org/10.1111/jfpp.14786

19. Kumar A, Shrivastava SL. Temperature, concentration, and frequency dependent dielectric properties of pineapple juice relevant to its concentration by microwave energy. Journal of Food Process Engineering. 2019;42(3). https://doi.org/10.1111/jfpe.13013

20. Bozkir H, Tekgül Y. Production of orange juice concentrate using conventional and microwave vacuum evaporation: Thermal degradation kinetics of bioactive compounds and color values. Journal of Food Processing and Preservation. 2022;46(6). https://doi.org/10.1111/jfpp.15902

21. Trushechkin AV. Scientific support and equipment for two-stage vacuum evaporation of multicomponent vegetable mixes. Cand. eng. sci. abstract diss. Voronezh: Voronezh State University of Engineering Technologies; 2013. 18 p. (In Russ.).

22. Tao Y, Yan B, Zhang N, Wang M, Zhao J, Zhang H, et al. Microwave vacuum evaporation as a potential technology to concentrate sugar solutions: A study based on dielectric spectroscopy. Journal of Food Engineering. 2021;294. https://doi.org/10.1016/j.jfoodeng.2020.110414

23. Asghar MT, Yusof YA, Mokhtar MN, Yaacob ME, Ghazali HM, Varith J, et al. Processing of coconut sap into sugar syrup using rotary evaporation, microwave and open heat evaporation techniques. Journal of the Science of Food and Agriculture. 2020;100(10):4012–4019. https://doi.org/10.1002/jsfa.10446

24. Alvi T, Khan MKI, Maan AA, Nazir A, Ahmad MH, Khan MI, et al. Modelling and kinetic study of novel and sustainable microwave-assisted dehydration of sugarcane juice. Processes. 2019;7(10). https://doi.org/10.3390/pr7100712

25. Tao Y, Yan B, Zhang N, Wang M, Zhao J, Zhang H, et al. Microwave vacuum evaporation as a potential technology to concentrate sugar solutions: A study based on dielectric spectroscopy. Journal of Food Engineering. 2021;294. https://doi.org/10.1016/j.jfoodeng.2020.110414

26. Tao Y, Yan B, Zhang N, Zhao J, Zhang H, Chen W, et al. Decoupling thermal effects and possible non-thermal effects of microwaves in vacuum evaporation of glucose solutions. Journal of Food Engineering. 2023;338. https://doi.org/10.1016/j.jfoodeng.2022.111257

27. Burdo OG, Gavrilov AV, Sirotyuk IV, Ruzhitskaya NV, Goncharov DS. Electrodynamic apparatuses for solutions’ concentration. Surface Engineering and Applied Electrochemistry. 2022;58(3):290–298. https://doi.org/10.3103/S1068375522030073

28. Gerber YuB, Gavrilov AV. The device of a continuous microwave vacuum evaporator. Russia patent RU 213932U1. 2022.

29. Vankatesh MS, Raghavan GSV. An overview of microwave processing and dielectric properties of agri-food materials. Biosystems Engineering. 2004;88(1):1–18. https://doi.org/10.1016/j.biosystemseng.2004.01.007

30. Kutepov AM, Sterman LS, Styushin NG. Hydrodynamics and heat transfer during vaporization. Moscow: Vysshaya shkola; 1986. 447 p. (In Russ.).

31. Burdo OG, Trishyn FA, Terziev SG, Gavrilov AV, Sirotyuk IV. Electrodynamic processes as an effective solution of food industry problems. Surface Engineering and Applied Electrochemistry. 2021;57(3):330–344. https://doi.org/10.3103/S1068375521030030

32. Burdo OG, Gavrilov AV, Sirotyuk IV, Ruzhitskaya NV, Goncharov DS. Electrodynamic apparatuses for solutions’ concentration. Surface Engineering and Applied Electrochemistry. 2022;58(3):290–298. https://doi.org/10.3103/S1068375522030073

33. Gavrilov AV. Experimental modeling of the vaporization of liquid solutions under vacuum and microwave field conditions. Vestnik of Federal State Educational Establishment of Higher Professional Education “Moscow State Agroengineering University named after V.P. Goryachkin”. 2020;95(1):41–50. (In Russ.). https://doi.org/10.34677/1728-7936-2020-1-41-50

34. Lashchinskiy AA, Tolchinskiy AR. Fundamentals of chemical equipment design and calculation. Moscow: Alʹyans; 2011. 752 p. (In Russ.).

35. Borts BV, Kazarinov YuG, Skoromnaya SF, Tkachenko VI. An experimental study of air bubbles dynamics in water at the rapid decompression. Journal of Kharkiv University. Physical Series: Nuclei, Particles, Fields. 2012;999(1):95–101. (In Russ.).

36. Emets BG. Nuclear magnetic resonance as a method to determine the average sizes and concentrations of air bubbles in water. Technical Physics Letters. 1997;23(13):42–45. (In Russ.). https://elibrary.ru/RYNFPZ

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