skip to main content

Gasification of Pelletized Corn Residues with Oxygen Enriched Air and Steam

1School of Energy and Environment, University of Phayao, Thailand

2Department of Mechanical Engineering, Faculty of Engineering, Chiang Mai University, Thailand

3Department of Chemical Engineering, College of Engineering and Computing, University of South Carolina, United States

Received: 26 May 2019; Revised: 17 Aug 2019; Accepted: 6 Oct 2019; Available online: 30 Oct 2019; Published: 27 Oct 2019.
Editor(s): H Hadiyanto

Citation Format:
Cover Image
Abstract
This work studied generation of producer gas using oxygen-enriched air and steam mixture as gasifying medium. Corn residues consisting of cobs and stover were used as biomass feedstock. Both corn residues were pelletized and gasified separately with normal air, oxygen enriched air and steam mixture in a fixed bed reactor. Effects of oxygen concentration in enriched air (21-50%), equivalence ratio (0.15-0.35), and steam to biomass ratio (0-0.8) on the yield of product gas, the combustible gas composition such as H2, CO, and CH4, the lower heating value (LHV), and the gasification efficiency were investigated. It was found that the decrease in nitrogen dilution in oxygen enriched air increased proportion of combustible gas components, improved the LHV of producer gas, but gasification efficiency was not affected. The increase in equivalence ratio favoured high product gas yield but decreased combustible gas components and LHV. It was also observed that introduction of steam enhanced H2 production but excessive steam degraded fuel gas quality and decreased gasification efficiency. The highest gasification efficiency of each oxygen concentration was at equivalence ratio of 0.3 and steam to biomass ratio of 0.58 for cob, and 0.22 and 0.68 for stover, respectively. ©2019. CBIORE-IJRED. All rights reserved
Fulltext View|Download
Keywords: Agricultural residues; Biomass energy; Producer gas; Thermochemical conversion; Renewable energy
Funding: Thailand Research Fund, Chiang Mai University

Article Metrics:

  1. Campoy, M., Gómez-Barea, A., Vidal, B.F., and Ollero, P. (2009) Air-steam gasification of biomass in a fluidized bed: process optimization by enriched air. Fuel Processing Technology, 90, 677-685
  2. Fu, Q., Huang, Y., Niu, M., Yang, G., Shao, Z. (2014) Experimental and predicted approaches for biomass gasification with enriched air-steam in a fluidised bed. Waste Management & Research, 32(10), 988-996
  3. Huynh, C.V., and Kong, S.C. (2013) Performance characteristics of a pilot-scale biomass gasifier using oxygen-enriched air and steam. Fuel, 103, 987-996
  4. Kumar, A., Eskridge, K., Jones, D.D., and Hanna M.A. (2009) Steam-air fluidized bed gasification of distiller’s grains: effects of steam to biomass ratio, equivalence ratio and gasification temperature. Bioresource Technology, 100, 2062–2068
  5. Lv, P.M., Xiong, Z.H., Chang, J., Wu, C.Z., Chen, Y., and Zhu, J.X. (2004) An experimental study on biomass air–steam gasification in a fluidized bed. Bioresource Technology, 95(1), 95-101
  6. Nam, H., Maglinao, A.L., Capareda, S., Rodriguez-Alejandro, D.A. (2016) Enriched-air fluidized bed gasification using bench and pilot scale reactors of dairy manure with sand bedding based on response surface methods. Energy, 95, 187-199
  7. Niu, M., Huang, Y., Jin, B., and Wang, X. (2014) Oxygen gasification of municipal solid waste in a fixed-bed gasifier. Chinese Journal of Chemical Engineering, 22(9), 1021-1026
  8. Punnarapong, P., Sucharitakul, T., and Tippayawong, N. (2017) Performance evaluation of premixed burner fueled with biomass derived producer gas. Case Studies in Thermal Engineering, 9, 40-46
  9. Sittisun, P., and Tippayawong, N. (2019) Characterization of laminar premixed flame firing biomass derived syngas with oxygen enriched air. International Journal of Smart Grid & Clean Energy, 8(6), 702-709
  10. Tippayawong, N., Chaichana, C., Promwungkwa, A., and Rerkkriangkrai, P. (2011) Gasification of cashew nut shells for thermal application in local food processing factory. Energy for Sustainable Development, 15(1), 69-72
  11. Tippayawong, N., Chaichana, C., Promwungkwa, A., and Rerkkriangkrai, P. (2013) Investigation of a small biomass gasifier – engine system operation and its application to water pumping in rural Thailand. Energy Sources Part A, 35(5), 476-486
  12. Wang, H., Werth, S., Schiestel, T., and Caro, J. (2005) Perovskite hollow-fiber membranes for the producing of oxygen-enriched air. Angewadte Chemie; 44(42), 6906-6909
  13. Wang, Y., Yoshikawa, K., Namioka, T., and Hashimoto, Y. (2007) Performance optimization of two-staged gasification system for woody biomass. Fuel Processing Technology, 88, 243–250
  14. Wei, L., Xu, S., Zhang, L, Liu, C., Zhu, H., and Liu, S. (2007) Steam gasification of biomass for hydrogen-rich gas in a free-fall reactor. International Journal of Hydrogen Energy, 32(1), 24-31
  15. Wongsiriamnuay, T., and Tippayawong, N. (2012) Product gas distribution and composition from catalyzed gasification of mimosa. International Journal of Renewable Energy Research, 2(3), 363-368
  16. Wongsiriamnuay, T., and Tippayawong, N. (2015) Effect of densification parameters on property of maize residue pellets. Biosystems Engineering, 139, 111-120
  17. Wongsiriamnuay, T., Kannang, N., and Tippayawong, N. (2013) Effect of operating conditions on catalytic gasification of bamboo in a fluidized bed. International Journal of Chemical Engineering, Article ID 297941
  18. Yuzbasi, N.S., and Selçuk, N. (2011) Air and oxy-fuel combustion characteristics of biomass/lignite blends in TGA-FTIR. Fuel Processing Technology, 92, 1101-1108
  19. Zheng, J.L., Zhu, M.Q., Wen J.L., and Sun, R.C. (2016) Gasification of bio-oil: effects of equivalence ratio and gasifying agents on product distribution and gasification efficiency. Bioresource Technology, 211, 164-172

Last update:

  1. Demand and cost analysis of agricultural residues utilized as biorenewable fuels for power generation

    Korrakot Y. Tippayawong, Nichari Chaidi, Tarinee Ngamlertsappakit, Nakorn Tippayawong. Energy Reports, 6 , 2020. doi: 10.1016/j.egyr.2020.11.040
  2. Gasification of refuse-derived fuel from municipal solid waste for energy production: a review

    Yan Yang, Rock Keey Liew, Arularasu Muthaliar Tamothran, Shin Ying Foong, Peter Nai Yuh Yek, Poh Wai Chia, Thuan Van Tran, Wanxi Peng, Su Shiung Lam. Environmental Chemistry Letters, 19 (3), 2021. doi: 10.1007/s10311-020-01177-5
  3. Critical review on technological advancements for effective waste management of municipal solid waste - Updates and way forward

    Environmental Technology & Innovation, 2021. doi: 10.1016/j.eti.2021.101749
  4. Critical review on technological advancements for effective waste management of municipal solid waste — Updates and way forward

    Priya Prajapati, Sunita Varjani, Reeta Rani Singhania, Anil Kumar Patel, Mukesh Kumar Awasthi, Raveendran Sindhu, Zengqiang Zhang, Parameswaran Binod, Sanjeev Kumar Awasthi, Preeti Chaturvedi. Environmental Technology & Innovation, 23 , 2021. doi: 10.1016/j.eti.2021.101749
  5. Investigation of Process Parameters Influence on Municipal Solid Waste Gasification with CO2 Capture via Process Simulation Approach

    Fadilla Noor Rahma, Cholila Tamzysi, Arif Hidayat, Muflih Arisa Adnan. International Journal of Renewable Energy Development, 10 (1), 2021. doi: 10.14710/ijred.2021.31982
  6. Simulation and experimental study of refuse-derived fuel gasification in an updraft gasifier

    Thanh Xuan Nguyen-Thi, Thi Minh Tu Bui, Van Ga Bui. International Journal of Renewable Energy Development, 12 (3), 2023. doi: 10.14710/ijred.2023.53994
  7. Energy Recovery from Polymeric 3D Printing Waste and Olive Pomace Mixtures via Thermal Gasification—Effect of Temperature

    Daniel Díaz-Perete, Manuel Jesús Hermoso-Orzáez, Luís Carmo-Calado, Cristina Martín-Doñate, Julio Terrados-Cepeda. Polymers, 15 (3), 2023. doi: 10.3390/polym15030750
  8. Analysis of reaction kinetics for torrefaction of pelletized agricultural biomass with dry flue gas

    Thossaporn Onsree, Nakorn Tippayawong. Energy Reports, 6 , 2020. doi: 10.1016/j.egyr.2020.10.038
  9. Effect of biomass co-digestion and application of artificial intelligence in biogas production: A review

    Moses Oluwatobi Fajobi, Olumuyiwa Ajani Lasode, Adekunle Akanni Adeleke, Peter Pelumi Ikubanni, Ayokunle Olubusayo Balogun. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 44 (2), 2022. doi: 10.1080/15567036.2022.2085823
  10. A Review on Hydrogen Production from Biomass and Commercialization Assessment Through Technology Readiness Levels (TRLs)

    Pranay Rajendra Lanjekar, Narayan Lal Panwar. BioEnergy Research, 2023. doi: 10.1007/s12155-023-10697-1
  11. Recent advances in hydrogen production from biomass waste with a focus on pyrolysis and gasification

    Van Giao Nguyen, Thanh Xuan Nguyen-Thi, Phuoc Quy Phong Nguyen, Viet Dung Tran, Ümit Ağbulut, Lan Huong Nguyen, Dhinesh Balasubramanian, Wieslaw Tarelko, Suhaib A. Bandh, Nguyen Dang Khoa Pham. International Journal of Hydrogen Energy, 2023. doi: 10.1016/j.ijhydene.2023.05.049

Last update: 2024-10-11 05:50:45

  1. Demand and cost analysis of agricultural residues utilized as biorenewable fuels for power generation

    Korrakot Y. Tippayawong, Nichari Chaidi, Tarinee Ngamlertsappakit, Nakorn Tippayawong. Energy Reports, 6 , 2020. doi: 10.1016/j.egyr.2020.11.040
  2. Gasification of refuse-derived fuel from municipal solid waste for energy production: a review

    Yan Yang, Rock Keey Liew, Arularasu Muthaliar Tamothran, Shin Ying Foong, Peter Nai Yuh Yek, Poh Wai Chia, Thuan Van Tran, Wanxi Peng, Su Shiung Lam. Environmental Chemistry Letters, 19 (3), 2021. doi: 10.1007/s10311-020-01177-5
  3. Analysis of reaction kinetics for torrefaction of pelletized agricultural biomass with dry flue gas

    Thossaporn Onsree, Nakorn Tippayawong. Energy Reports, 6 , 2020. doi: 10.1016/j.egyr.2020.10.038
  4. Investigation of process parameters influence on municipal solid waste gasification with co2 capture via process simulation approach

    Rahma F.N.. International Journal of Renewable Energy Development, 10 (1), 2021. doi: 10.14710/ijred.2021.31982