Drying ripe mango slices using step-down temperature far-infrared-hot air techniques

Authors

  • Suwit Paengkanya Sustainable Industrial Management Engineering, Faculty of Engineering, Rajamangala University of Technology Phra Nakhon, Bangkok 10800, Thailand
  • Sutinon Patcharatvirakul Sustainable Industrial Management Engineering, Faculty of Engineering, Rajamangala University of Technology Phra Nakhon, Bangkok 10800, Thailand
  • Ponlakrit Kumklam Industrial Materials Science, Faculty of Science and Technology, Rajamangala University of Technology Phra Nakhon, Bangkok 10800, Thailand

DOI:

https://doi.org/10.25165/ijabe.v18i6.9770

Keywords:

combined far-infrared-hot air drying, dried mango slices, drying kinetic, specific energy consumption, step-down temperature technique, texture

Abstract

A key challenge in food drying is achieving an optimal balance between processing efficiency, energy consumption, and maintaining high quality in the final product. This study investigates three drying methods for mango slices: conventional hot air drying (HA), far-infrared combined hot air drying (FIRHA), and step-down temperature FIRHA. The effects of various operating parameters were analyzed, including drying medium temperature and the influence of far-infrared assistance, on the drying kinetics and quality attributes of the mango slices. The quality attributes assessed include color, shrinkage percentage, texture profile, water activity, microstructure, and energy consumption. The results indicate that the drying rates for FIRHA were significantly higher than those for HA. Mango slices dried using FIRHA and step-down temperature FIRHA exhibited greater lightness and greenness, along with increased crispness, while demonstrating lower yellowness compared to those dried by HA. The far-infrared assistance resulted in larger pore sizes and a higher void area fraction in the mango slices, but it also led to reduced hardness and shrinkage percentage compared to those dried using HA. In terms of specific energy consumption, the electric heater consumed significantly more energy than the far-infrared radiator and blower. Additionally, the total specific energy consumption of step-down temperature FIRHA was lower than that of both HA and FIRHA under all drying conditions. Based on these findings, this study recommends using step-down temperature FIRHA at 90°C for 1 h for the effective drying of mango slices, offering an optimal solution to the core challenges in the field. Ultimately, this work provides a valuable framework and empirical evidence for the adoption of hybrid drying technologies, contributing significantly to the fields of food engineering and sustainable agricultural processing. Key words: combined far-infrared-hot air drying; dried mango slices; drying kinetic; specific energy consumption; step-down temperature technique; texture DOI: 10.25165/j.ijabe.20251806.9770 Citation: Paengkanya S, Patcharatvirakul S, Kumklam P. Drying ripe mango slices using step-down temperature far-infrared-hot air techniques. Int J Agric & Biol Eng, 2025; 18(6): 281–289.

References

Office of Agricultural Economics. Export statistics. 2023. https://impexpth.oae.go.th/export. Accessed on: [2024-12-10].

Akpinar E K, Bicer Y. Mathematical modelling of thin layer drying process of long green pepper in solar dryer and under open sun. Energy Conversion and Management, 2008; 49(6): 1367–1375.

Nathakaranakule A, Jaiboon P, Soponronnarit S. Far-infrared radiation assisted drying of longan fruit. Journal of Food Engineering, 2010; 100(4): 662–668.

Nathakaranakule A, Paengkanya S, Soponronnarit S. Durian chips drying using combined microwave techniques with step-down microwave power input. Food and Bioproducts Processing, 2019; 116: 105–117.

Chang A T, Zheng X, Xiao H W, Yao X D, Liu D C, Li X Y, et al. Short and medium-wave infrared drying of cantaloupe (Cucumis melon L.) slices: drying kinetics and process parameter optimization. Processes, 2022; 10: 114.

Meseguer J, Pérez-Grande I, Sanz-Andrés A. Thermal radiation heat transfer. In: Meseguer J, Pérez-Grande I, Sanz-Andrés A, editors. Spacecraft Thermal Control. Woodhead Publishing. 2012; pp.73–86. doi: 10.1533/9780857096081.73.

Xu B G, Zhang M, Bhandari B. Temperature and quality characteristics of infrared radiation–dried kelp at different peak wavelengths. Drying Technology, 2014; 32(4): 437–446.

Huang D, Yang P, Tang X H, Luo L, Sunden B. Application of infrared radiation in the drying of food products. Trends in Food Science & Technology, 2021; 110: 765–777.

Yao L Y, Fan L P, Duan Z H. Effect of different pretreatments followed by hot-air and far-infrared drying on the bioactive compounds, physicochemical property and microstructure of mango slices. Food Chemistry, 2020; 305: 125477.

Meeso N, Nathakaranakule A, Madhiyanon T, Soponronnarit S. Influence of FIR irradiation on paddy moisture reduction and milling quality after fluidized bed drying. Journal of Food Engineering, 2004; 65(2): 293–301.

Nimmol C, Devahastin S, Swasdisevi T, Soponronnarit S. Drying and heat transfer behavior of banana undergoing combined low-pressure superheated steam and far-infrared radiation drying. Applied Thermal Engineering, 2007; 27: 2483–2494.

Liu Z L, Wang S Y, Huang X J, Zhang X H, Xie L, Bai J W, et al. Quality changes and shelf-life prediction of far-infrared radiation heating assisted pulsed vacuum dried blueberries by SSA-ELM. Food Chemistry, 2025; 473: 143060.

Mongpraneet S, Abe T, Tsurusaki T. Accelerated drying of welsh onion by far infrared radiation under vacuum conditions. Journal of Food Engineering, 2002; 55(2): 147–156.

Lekcharoenkul P, Tanongkankit Y, Chiewchan N, Devahastin S. Enhancement of sulforaphane content in cabbage outer leaves using hybrid drying technique and stepwise change of drying temperature. Journal of Food Engineering, 2014; 122: 56–61.

Afzal T M, Abe T, Hikida Y. Energy and quality aspects during combined FIR-convection drying of barley. Journal of Food Engineering, 1999; 42(4): 177–182.

Bassey E J, Cheng J H, Sun D W. Improving drying kinetics, physicochemical properties and bioactive compounds of red dragon fruit (Hylocereus species) by novel infrared drying. Food Chemistry, 2022; 375: 131886.

Neamtang P, Nathakaranakule A, Paengkanya S, Thepa S, Soponronnarit S. Drying ripe mangoes using a step-down industrial microwave-hot air belt dryer. Drying Technology, 2024; 42: 2241–2255.

AOAC. Official Methods of Analysis, 16th ed. Washington, DC: Association of Official Agricultural Chemists. 1995;1018p.

Zhang W P, Pan Z L, Xiao H W, Zheng Z A, Chen C, Gao Z J. Pulsed vacuum drying (PVD) technology improves drying efficiency and quality of Poria cubes. Drying Technology, 2018; 36: 908–921.

Amini G, Salehi F, Rasouli M. Color changes and drying kinetics modeling of basil seed mucilage during infrared drying process. Information Processing in Agriculture, 2022; 9(3): 397–405.

Chen C, Liao C, Wongso I, Wang W B, Khir R, Huang G W, et al. Drying and disinfection of off-ground harvested almonds using step-down temperature hot air heating. LWT-Food Science and Technology, 2021; 152: 112282.

El-Mesery H S, Mwithiga G. Performance of a convective, infrared and combined infrared-convective heated conveyor-belt dryer. Journal of Food Science and Technology, 2015; 52: 2721–2730.

Chen C, Venkitasamy C, Zhang W P, Deng L Z, Meng X Y, Pan Z L. Effect of step-down temperature drying on energy consumption and product quality of walnuts. Journal of Food Engineering, 2020; 285: 110105.

Pott I, Marx M, Neidhart S, Hlbauer W M, Carle R. Quantitative determination of ‚ β-carotene stereoisomers in fresh, dried, and solar-dried mangoes (Mangifera indica L.). Journal of Agricultural and Food Chemistry, 2003; 51(16): 4527–4531.

Guiamba I R F, Svanberg U, Ahrn´ L. Effect of infrared blanching on enzyme activity and retention of β-carotene and vitamin c in dried mango. Journal of Food Science, 2015; 80(6): E1235–E1242.

Bootkote P, Soponronnarit S, Prachayawarakorn S. Process of producing parboiled rice with different colors by fluidized bed drying technique including tempering. Food Bioprocess Technology, 2016; 9: 1574–1586.

Ju H Y, Vidyarthi S K, Karim M A, Yu X L, Zhang W P, Xiao H W. Drying quality and energy consumption efficient improvements in hot air drying of papaya slices by step-down relative humidity based on heat and mass transfer characteristics and 3D simulation. Drying Technology, 2022; 41(3): 460–476.

Paengkanya S, Soponronnarit S, Nathakaranakule A. Application of microwaves for drying of durian chips. Food and Bioproducts Processing, 2015; 96: 1–11.

Huang Y, Wang X Y, Lyu Y, Li Y, He R R, Chen H M. Metabolomics analysis reveals the non-enzymatic browning mechanism of green peppers (Piper nigrum L.) during the hot-air drying process. Food Chemistry, 2025; 464: 141654.

Jiang D-L, Wang Q-H, Huang C, Sutar P P, Lin Y-W, Okaiyeto S A, et al. Effect of various different pretreatment methods on infrared combined hot air impingement drying behavior and physicochemical properties of strawberry slices. Food Chemistry: X, 2024; 22: 101299.

Xu M-Q, Ha B-E, Vidyarthi S K, Zhang F-L, Yang F, Jiang Y-H, et al. Innovative far-infrared radiation assisted pulsed vacuum freeze-drying of banana slices: Drying behaviors, physicochemical properties and microstructural evolution. Innovative Food Science & Emerging Technologies, 2025; 100: 103925.

Cao Y X, Yao X D, Zang Y Z, Niu Y B, Xiao H W, Liu H, et al. Real-time monitoring system for quality monitoring of jujube slice during drying process. Int J Agric & Biol Eng, 2022; 15(3): 234–241.

Jiang D L, Lin Z F, Wu Y T, Pei H J, Li C C. Effects of pulsation ratio on center temperature and drying characteristics of pineapple slices with pulsed vacuum drying. Int J Agric & Biol Eng, 2022; 15(6): 242–253.

Xu H H, Wu M, Zhang T, Gao F, Zheng Z A, Li Y. Effects of different pulsed vacuum drying strategies on drying kinetics, phenolic composition, and antioxidant capacity of chrysanthemum (Imperial chrysanthemum). Int J Agric & Biol Eng, 2022; 15(4): 236–242.

Jiang D L, Shirkole S S, Ju H Y, Niu X X, Xie Y K, Li X Y, et al. An improved infrared combined hot air dryer design and effective drying strategy analysis for sweet potato. LWT-Food Science and Technology, 2025; 215: 117204.

Guo Y T, Wu B G, Guo X Y, Ding F F, Pan Z L, Ma H L. Effects of power ultrasound enhancement on infrared drying of carrot slices: moisture migration and quality characterizations. LWT-Food Science and Technology, 2020; 126: 109312.

Jiang D L, Li C C, Zielinska S, Liu Y H, Gao Z J, Wang R Y, et al. Process performance and quality attributes of temperature and step-down relative humidity controlled hot air drying of Panax notoginseng roots. Int J Agric & Biol Eng, 2021; 14(6): 244–257.

Li B R, Lin J Y, Zheng Z A, Duan H, Li D, Wu M. Effects of different drying methods on drying kinetics and physicochemical properties of Chrysanthemum morifolium Ramat. Int J Agric & Biol Eng, 2019; 12(3): 187–193.

Nimmol C, Devahastin S, Swasdisevi T, Soponronnarit S. Drying of banana slices using combined low-pressure superheated steam and far-infrared radiation. Journal of Food Engineering, 2007; 81: 624–633.

Soponronnarit S, Wetchacama S, Trutassanawin S, Jariyatontivait W. Design, testing, and optimization of vibro-fluidized bed paddy dryer. Drying Technology, 2001; 19(8): 1891–1908.

Soponronnarit S, Prachayawarakorn S. Optimum strategy for fluidized bed paddy drying. Drying Technology, 1994; 12(7): 1667–1686. doi: 0.1080/07373939408962192.

Kitron Y, Tamir A. Performance of a coaxial gas-solid two-impinging-streams (TIS) reactor: Hydrodynamics, residence time distribution, and drying heat transfer. Industrial and Engineering Chemistry Research, 1988; 27: 1760–1767.

Downloads

Published

2025-12-26

How to Cite

Paengkanya, S., Patcharatvirakul, S., & Kumklam, P. (2025). Drying ripe mango slices using step-down temperature far-infrared-hot air techniques. International Journal of Agricultural and Biological Engineering, 18(6), 281–289. https://doi.org/10.25165/ijabe.v18i6.9770

Issue

Vol. 18 No. 6 (2025): IJABE

Section

Agro-product and Food Processing Systems

License

IJABE is an international peer reviewed open access journal, adopting Creative Commons Copyright Notices as follows.


Authors who publish with this journal agree to the following terms:


  1. Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.

  2. Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.

  3. Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See The Effect of Open Access).