Pengeringan Bagasse Menggunakan Metode Rotary Dryer Kapasitas 69,628 Kg Per Jam

Toniyah Jaelani; Heru Kuncoro

doi:10.36815/majamecha.v4i1.1780

Authors

Toniyah Jaelani Universitas Gunadarma
Heru Kuncoro Universitas Gunadarma

DOI:

https://doi.org/10.36815/majamecha.v4i1.1780

Keywords:

Pengeringan, Bagasse, Rotary Dryer, Konversi Energi

Abstract

Bagasse merupakan produk salah satu produk samping dari produksi gula tebu. Bagasse digunakan sebagai bahan bakar boiler untuk menghasilkan steam yang berfungsi untuk mejalankan sistem kelistrikan maupun kegiatan produktivitas pabrik gula. pada penelitian ini ditujukan untuk merancang alat rotary dryer dengan aliran udara pengering searah dengan aliran bagasse (co-current). Evaluasi dari perhitungan dilakukan untuk mengeringkan bagasse berkapsitas 69,628 kg/jam dengan kandungan air sebesar 55% menjadi 20%. Hasil pemodelan ditemukan bahwa dibutuhkan temperatur udara pengering 135 ?, kecepatan udara 1.5 m/s, dan menghasilkan energi uap panas sebesar 155.3 kJ/kg pada zona III, 140 kJ/kg pada zona II dan pada zoma I energi uap panas sebesar 170.3 kJ/kg. Air yang dapat ter evaporasi pada sistem ini 30462.15 kg.

References

Adeodu, A. O., Akinola, S. O., Daniyan, I. A., Akinlosola, D. O., Oloyede, R, O., & Alufa, O. O. (2019). Development and Performance Evaluation of Thermostat Controlled Rotary Dryer for Agricultural Produce. International Conference on Engineering for Sustainable World, Journal of Physics. https://doi.org/10.1088/1742-6596

Allita, Y., Gala, V., Citra, A. A., & Retnoningtyas, E. S. (2018). Pemanfaatan ampas tebu dan kulit pisang dalam pembuatan kertas serat campuran. Jurnal Teknik Kimia Indonesia, 11(2), 101–107.

Amin, M. C., Taufiq, A. J., & Kurniawan, I. H. (2019). Pemanfaatan Ampas Tebu Sebagai Pembangkit Listrik Biomassa Di PG. Sragi Pekalongan. Jurnal Riset Rekayasa Elektro, 1(1).

Arun S. Mujumdar. (1987). Handbook of Industrial Drying: Vol. Part 1. Marcel Dekker, Inc.

Camargo, J. M. O., Gallego-Ríos, J. M., Neto, A. M. P., Antonio, G. C., Modesto, M., & Leite, J. T. C. (2020). Characterization of sugarcane straw and bagasse from dry cleaning system of sugarcane for cogeneration system. Renewable Energy, 158, 500–508. https://doi.org/https://doi.org/10.1016/j.renene.2020.05.107

Chinenye, N. M. (2009). Effect of Drying Temperature and Drying Air Velocity on the Drying Rate and Drying Constant of Cocoa Bean. Agricultural Engineering International: The CIGR Ejournal.

de Araujo Guilherme, A., Dantas, P. V. F., de Araújo Padilha, C. E., dos Santos, E. S., & de Macedo, G. R. (2019). Ethanol production from sugarcane bagasse: Use of different fermentation strategies to enhance an environmental-friendly process. Journal of Environmental Management, 234, 44–51.

IESR. (2021). Indonesia Energy Transition Outlook 2022. Tracking Progress of Energy Transition in Indonesia?: Aiming for Net-Zero Emissions by 2050.

Larasati, S. A., Abidin, Z., & Endaryanto, T. (2020). Analisis Finansial Pemanfaatan Ampas Tebu (Bagasse) Sebagai Bahan Bakar Pembangkit Listrik Di Pt Gunung Madu Plantations. Jurnal Ilmu Ilmu Agribisnis: Journal of Agribusiness Science, 7(3), 314–322.

Lisboa, M. H., Alves, M. C., Vitorino, D. S., Delaiba, W. B., Finzer, J. R. D., & Barrozo, M. A. S. (2004). Study of the Performance of the Rotary Dryer with Fluidization. Proceedings of the 14th International Drying Symposium.

Lisboa, M. H., Vitorino, D. S., Delaiba, W. B., Finzer, J. R. D., & Barrozo, M. A. S. (2007). A Study Of Particle Motion In Rotary Dryer. Brazilian Journal of Chemical Engineering.

Miranda, N. T., Motta, I. L., Filho, R. M., & Maciel, M. R. W. (2021). Sugarcane bagasse pyrolysis: A review of operating conditions and products properties. Renewable and Sustainable Energy.

Mujumdar, A. S. (2006). Handbook of Industrial Drying (A. S. Mujumdar, Ed.; 3rd Editio). Taylor & Francis Group.

Nguyen, H. N., Nguyen, P. L. T., & Tran, V. B. (2021). Zero-waste biomass gasification: Use of residues after gasification of bagasse pellets as CO2 adsorbents. Thermal Science and Engineering Progress, 26, 101080. https://doi.org/https://doi.org/10.1016/j.tsep.2021.101080

PACHECO, C. R. F., & STELLA, S. S. (1998). Calculating Capacity Trends In Rotary Dryers. Brazil Journal Chemical Engineering. https://doi.org/https://doi.org/10.1590/S0104-66321998000300002

Sai, P. S. T. (2013). Drying of Solids in a Rotary Dryer. Drying Technology: An International Journal.

Shrivastav, S., & Hussain, I. (2013). Design of Bagasse Dryer to Recover Energy of Water Tube Boiler in a Sugar Factory. International Journal of Science and Research (IJSR).

Singh, O. (2009). Applied Thermodynamics (3rd Editio). New Age International (P) Ltd.

Tawfik, A. A., Abdel-Rahman, A. K., Bayoumi, M. R., & Morsy, M. G. (n.d.). BAGASSE DRYING: ADVANTAGES AND MERITS (PERFORMANCE OF A FLUIDIZED-BED BAGASSE DRYER).

Toscano Miranda, N., Lopes Motta, I., Maciel Filho, R., & Wolf Maciel, M. R. (2021). Sugarcane bagasse pyrolysis: A review of operating conditions and products properties. Renewable and Sustainable Energy Reviews, 149, 111394. https://doi.org/https://doi.org/10.1016/j.rser.2021.111394

Wae-hayee, M., Yeranee, K., Suksuwan, W., Ameen, A., Sae-ung, S., & Chayut Nuntadusit. (2020). Heat transfer enhancement in rotary drum dryer by incorporating jet impingement to accelerate drying rate. Drying Technology: An International Journal.

Yarnal, G. S., & Puranik, V. S. (2010a). Energy Management Study in Sugar Industries by Various Bagasse Drying Methods. Strategic Planning for Energy and the Environment, 29(3), 56–78. https://doi.org/10.1080/10485231009595087

Yarnal, G. S., & Puranik, V. S. (2010b). Energy Management Study in Sugar Industries by Various Bagasse Drying Methods. Strategic Planning for Energy and the Environment, 29(3), 56–78. https://doi.org/10.1080/10485231009595087