REFERENCES
- [1] Kejing An, Dandan Zhao, Zhengfu Wang, Jijun Wu, Yujuan Xu, and Gengsheng Xiao. Comparison of different drying methods on Chinese ginger (Zingiber officinale Roscoe): Changes in volatiles, chemical profile, antioxidant properties, and microstructure. Food Chemistry, 197:1292–1300, 2016.
- [2] A. Angeline Rajathi, A. Allwyn Sundarraj, Shilu Leslie, and M. M. Pragalyaashree. Processing and medicinal uses of cardamom and ginger - A review. Journal of Pharmaceutical Sciences and Research, 9(11):2117–2122, 2017.
- [3] Jaleel Kizhakkayil and B. Sasikumar. Diversity, characterization and utilization of ginger: A review. Plant Genetic Resources: Characterisation and Utilisation, 9(3):464– 477, 2011.
- [4] Huijuan Li, Yanan Liu, Dan Luo, Yuzhen Ma, Jie Zhang, Meixuan Li, Liang Yao, Xiue Shi, Xingrong Liu, and Kehu Yang. Ginger for health care: An overview of systematic reviews. Complementary Therapies in Medicine, 45(March):114–123, 2019.
- [5] Khanuengnit Chapchaimoh, Nattapol Poomsa-Ad, Lamul Wiset, and John Morris. Thermal characteristics of heat pump dryer for ginger drying. Applied Thermal Engineering, 95:491–498, 2016.
- [6] FAO. Crops - Cassava, 2020.
- [7] Statistics Indonesia. Statistics of Medicinal Plants Indonesia. 2018.
- [8] Singhanat Phoungchandang and Supawinee Saentaweesuk. Effect of two stage, tray and heat pump assisted-dehumidified drying on drying characteristics and qualities of dried ginger. Food and Bioproducts Processing, 89(4):429–437, 2011.
- [9] S. H. Ding, K. J. An, C. P. Zhao, Y. Li, Y. H. Guo, and Z. F. Wang. Effect of drying methods on volatiles of Chinese ginger (Zingiber officinale Roscoe). Food and Bioproducts Processing, 90(3):515–524, 2012.
- [10] D. K. Rabha, P. Muthukumar, and C. Somayaji. Energy and exergy analyses of the solar drying processes of ghost chilli pepper and ginger. Renewable Energy, 105:764–773, 2017.
- [11] Indonesian National Standard. SNI 01-3393-1994 - Jahe Kering, 1994.
- [12] Elsamila Aritesty and Dyah Wulandani. Performance of the rack type-greenhouse effect solar dryer for wild ginger (curcuma xanthorizza roxb.) drying. Energy Procedia, 47:94–100, 2014.
- [13] Jnyana R. Pati, Santosh K. Hotta, and P. Mahanta. Effect of waste heat recovery on drying characteristics of sliced ginger in a natural convection dryer. Procedia Engineering, 105(Icte 2014):145–152, 2015.
- [14] A. Waheed Deshmukh, Mahesh N. Varma, Chang Kyoo Yoo, and Kailas L. Wasewar. Investigation of Solar Drying of Ginger ( Zingiber officinale ): Emprical Modelling, Drying Characteristics, and Quality Study. Chinese Journal of Engineering, 2014:1–7, 2014.
- [15] A. M. Castro, E. Y. Mayorga, and F. L. Moreno. Mathematical modelling of convective drying of fruits: A review. Journal of Food Engineering, 223:152–167, 2018.
- [16] L. Blanco-Cano, A. Soria-Verdugo, L. M. GarciaGutierrez, and U. Ruiz-Rivas. Modeling the thin-layer drying process of Granny Smith apples: Application in an indirect solar dryer. Applied Thermal Engineering, 108:1086–1094, 2016.
- [17] Om Prakash, Vinod Laguri, Anukul Pandey, Anil Kumar, and Arbind Kumar. Review on various modelling techniques for the solar dryers. Renewable and Sustainable Energy Reviews, 62:396–417, 2016.
- [18] Laszlo Imre. Solar Drying. In Arun S. Mujumdar, editor, Handbook of Industrial Drying, volume 4, chapter 13, pages 308–363. CRC Press, Florida, 4 edition, 2014.
- [19] David Gudiño-Ayala and Ángel Calderón-Topete. Pineapple drying using a new solar hybrid dryer. Energy Procedia, 57:1642–1650, 2014.
- [20] S. Murali, P. R. Amulya, P. V. Alfiya, D. S.Aniesrani Delfiya, and Manoj P. Samuel. Design and performance evaluation of solar - LPG hybrid dryer for drying of shrimps. Renewable Energy, 147:2417–2428, 2020.
- [21] S Dhanushkodi, Vincent H Wilson, and K Sudhakar. Design and thermal performance of the solar biomass hybrid dryer for cashew drying. Facta universitatisseries: Mechanical Engineering, 12(3):277–288, 2014.
- [22] Daniel I. Onwude, Norhashila Hashim, Rimfiel B. Janius, Nazmi Mat Nawi, and Khalina Abdan. Modeling the Thin-Layer Drying of Fruits and Vegetables: A Review. Comprehensive Reviews in Food Science and Food Safety, 15(3):599–618, 2016.
- [23] Olawale Usman Dairo, Adewole Ayobami Aderinlewo, Olayemi Johnson Adeosun, Ibukun Adekola Ola, and Tolulope Salaudeen. Solar drying kinetics of cass ava slices in a mixed flow dryer. Acta Technologica Agriculturae, 18(4):102–107, 2015.
- [24] A. K. Karthikeyan and S. Murugavelh. Thin layer drying kinetics and exergy analysis of turmeric (Curcuma longa) in a mixed mode forced convection solar tunnel dryer. Renewable Energy, 128:305–312, 2018.
- [25] Suparerk Charmongkolpradit and Ratinun Luampon. Study of Thin Layer Drying Model for Cassava Pulp. Energy Procedia, 138:354–359, 2017.
- [26] S. Dhanushkodi, Vincent H. Wilson, and K. Sudhakar. Mathematical modeling of drying behavior of cashew in a solar biomass hybrid dryer. Resource-Efficient Technologies, 3(4):359–364, 2017.
- [27] Can Ertekin and M. Ziya Firat. A comprehensive review of thin-layer drying models used in agricultural products. Critical Reviews in Food Science and Nutrition, 57(4):701–717, 2017.
- [28] Dimitrios A. Tzempelikos, Alexandros P. Vouros, Achilleas V. Bardakas, Andronikos E. Filios, and Dionissios P. Margaris. Experimental study on convective drying of quince slices and evaluation of thin-layer drying models. Engineering in Agriculture, Environment and Food, 8(3):169–177, 2015.
- [29] S. Suzanne Nielsen. Food Analysis. Springer, 4th editio edition, 2010.
- [30] Suherman Suherman, Mohammad Djaeni, Dyah H. Wardhani, Mukhtar R. Dzaki, and Muhammad N.F. Bagas. Performance Analysis of Solar Tray Dryer for Cassava Starch. MATEC Web of Conferences, 156:0–3, 2018.
- [31] A. Bosomtwe, J. K. Danso, E. A. Osekre, G. P. Opit, G. Mbata, P. Armstrong, F. H. Arthur, J. Campbell, N. Manu, S. G. McNeill, and J. O. Akowuah. Effectiveness of the solar biomass hybrid dryer for drying and disinfestation of maize. Journal of Stored Products Research, 83:66–72, 2019.
- [32] Suherman Suherman and Nur Hidayati. Performance Evaluation of Pneumatic Dryer for Aren (Arenga piñata) Flour. In The 24th Regional Symposium on Chemical Engineering (RSCE 2017), volume 156, page 05023, Semarang, 2018. MATEC Web of Conferences.
- [33] Tadahmun A. Yassen and Hussain H. Al-Kayiem. Experimental investigation and evaluation of hybrid solar/thermal dryer combined with supplementary recovery dryer. Solar Energy, 134:284–293, 2016.
- [34] Evangelos Tsotsas and Arun S. Mujumdar. Modern Drying Technology, Volume 4: Energy Savings. WileyVCH, Weinheim, 2011.
- [35] Ehsan Baniasadi, Saeed Ranjbar, and Omid Boostanipour. Experimental investigation of the performance of a mixed-mode solar dryer with thermal energy storage. Renewable Energy, 112:143–150, 2017.
- [36] Hamid Mortezapour, Barat Ghobadian, Saeid Minaei, and Mohammad Hadi Khoshtaghaza. Saffron drying with a heat pump-assisted hybrid photovoltaic-thermal solar dryer. Drying Technology, 30(6):560–566, 2012.
- [37] Mohamed A. Eltawil, Mostafa M. Azam, and Abdulrahman O. Alghannam. Energy analysis of hybrid solar tunnel dryer with PV system and solar collector for drying mint (MenthaViridis). Journal of Cleaner Production, 181:352–364, 2018.
- [38] D. V.N. Lakshmi, P. Muthukumar, Apurba Layek, and Prakash Kumar Nayak. Drying kinetics and quality analysis of black turmeric (Curcuma caesia) drying in a mixed mode forced convection solar dryer integrated with thermal energy storage. Renewable Energy, 120:23– 34, 2018.
- [39] Ndubisi A. Aviara, Lovelyn N. Onuoha, Oluwakemi E. Falola, and Joseph C. Igbeka. Energy and exergy analyses of native cassava starch drying in a tray dryer. Energy, 73:809–817, 2014.
- [40] Alejandro Reyes, Andrea Mahn, and Francisco Vásquez. Mushrooms dehydration in a hybrid-solar dryer, using a phase change material. Energy Conversion and Management, 83:241–248, 2014.
- [41] Ahmad Fudholi, Kamaruzzaman Sopian, Mohd Yusof Othman, and Mohd Hafidz Ruslan. Energy and exergy analyses of solar drying system of red seaweed. Energy and Buildings, 68(PARTA):121–129, 2014.
- [42] W.B. Asiru, A.O. Raji, J.C. Igbeka, and G.N. Elemo. Mathematical Modelling of Thin Layer Dried Cashew Kernels. Nigerian Food Journal, 31(2):106–112, 2013.
- [43] Qing-An Zhang, Yun Song, Xi Wang, Wu-Qi Zhao, and Xue-Hui Fan. Mathematical modeling of debittered apricot ( Prunus armeniaca L .) kernels during thinlayer drying . CyTA - Journal of Food, 14(4):509–517, 2016.
- [44] O. R. Alara, N. H. Abdurahman, and O. A. Olalere. Mathematical modelling and morphological properties of thin layer oven drying of Vernonia amygdalina leaves. Journal of the Saudi Society of Agricultural Sciences, 18(3):309–315, 2019.
- [45] Ndubisi A. Aviara and Joseph C. Igbeka. Modeling for Drying of Thin Layer of Native Cassava Starch in Tray Dryer. Journal of Biosystems Engineering, 41(4):342–356, 2016.
- [46] Fei Shen, Lin Peng, Yanzong Zhang, Jun Wu, Xiaohong Zhang, Gang Yang, Hong Peng, Hui Qi, and Shihuai Deng. Thin-layer drying kinetics and quality changes of sweet sorghum stalk for ethanol production as affected by drying temperature. Industrial Crops and Products, 34(3):1588–1594, 2011.
- [47] Jun Qiu, Parag Acharya, Doris M. Jacobs, Remko M. Boom, and Maarten A.I. Schutyser. A systematic analysis on tomato powder quality prepared by four conductive drying technologies. Innovative Food Science and Emerging Technologies, 54(October 2018):103–112, 2019.
- [48] Aicha Jelled, ngela Fernandes, Lillian Barros, Hassiba Chahdoura, Lotfi Achour, Isabel C.F.R. Ferreira, and Hassen Ben Cheikh. Chemical and antioxidant parameters of dried forms of ginger rhizomes. Industrial Crops and Products, 77:30–35, 2015.