INVESTIGATION OF GAS SWIRL BURNER CHARACTERISTIC ON BIOMASS GASIFICATION SYSTEM USING COMBUSTION UNIT EQUIPMENT (CUE)

Authors

  • Adi Surjosatyo Department of Mechanical Engineering, Faculty of Engineering, University of Indonesia, 16424 Depok, Indonesia
  • Yudho Danu Priambodho Department of Mechanical Engineering, Faculty of Engineering, University of Indonesia, 16424 Depok, Indonesia

Keywords:

Gasification, low swirl gas burner, computational fluid dynamics (CFD)

Abstract

Swirling flow burners have been essential to both premixed and non-premixed combustion system because of their significant beneficial influences on flame stability, combustion intensity and combustor performance. This research explores the flame characteristics of the low-swirl burners, especially using low calorific gas produced by biomass gasification system. One of the problems during burning of the mixed gas is the poor distribution of heat released in the chamber. Therefore, to increase the flame quality, or flame strength, it is necessary to reduce the diameter of the inlet fuel with variation of 6, 8 and 10 blades of the swirler vanes, with the vanes inclined at 30 degrees from the horizontal axis. Variations of vane design are correlated with quality of the flame, heat release rate and emissions formation in combustion unit. The methodology used includes implementation of three-dimensional (3D) Computational Fluid Dynamics (CFD) simulation using the commercial software FLUENT and gasification experiments which included assembly of a new combustion equipment unit. The experimental results identified the maximum temperature, which occurred at swirl vane of 8 blades at 795OC. The maximum heat release was achieved at 11.15 kJ/s for biomass. The lowest content of CO emission was 0.02% volume of biomass the lowest NOx emission was the 1108 ppm for biomass. Results of this study indicate that swirl vanes with 8 blades and diameter of 55 mm perform better than other number of blades of swirl vane burners.

References

Cheng, R.K., D. Littlejohn, P. Strakey, and T. Sidwell, 2009. Laboratory Investigations of Low-Swirl Injectors with H2 and CH4 at Gas Turbine Conditions. Proc. Comb. Inst., p.32.

Chan, C.K. et al., 1992 “Freely Propagating Open Premixed Turbulent Flames Stabilized by Swirl,â€Proc. Comb. Inst., 24 p 511-518;

Bedat, B. and Cheng, R.K., 1995.“Experimental Study of Premixed Flames in Intense Isotropic Turbulence,†Combustion and Flame 100, no. 3 p 485-494;

Cheng, R.K., 1995, “Velocity and Scalar Characteristics of Premixed Turbulent Flames Stabilized By Weak Swirl,†Combustion and Flame 101, no.1-2 p.1-14.

Surjosatyo, A. and Ani, F.N., 2005. Experimental and Prediction of the Development of Low-Calorific Swirl Burner, Reric International Energy Journal, Asian Institute Technology (AIT), Bangkok,Vol 6.No 2.

Surjosatyo, A. and Ani, F.N., 2002. “Development of Swirl Burner Incorporated with a Biomass Combustion Systemâ€. 6

thAsia-Pacific International Symposium on Combustion and Energy Utilization, Kuala Lumpur, Malaysia.

Syred. N. and J.M. Beer, 1974. “Combustion in Swirling Flow: A Review,†Combustion and Flame 23 p. 143-201.

Plessing. T. et al., 2000. “Measurement of the Turbulent Burning Velocity and the Structure of Premixed Flames on a Low Swirl Burner,†Proc. Comb. Inst. 28 p 359-366.

Shepherd. I. G. et al., 2002 “Premixed Flame Front Structure in Intense Turbulence,â€Proc. Comb. Inst. 29 p.1833-1840.

Bridgwater, A.V. 1995. The technical and economic feasibility of biomass gasification for power generation. Fuel. Vol 74 No.5, pp. 631-653.

Brunner, C.R. 1985. Hazardous Air Emission form Incinerator, Chapman & Hall.

Tangirala, V., Chen, R. H., and Driscoll, J. F., 1987, â€Effect of Heat Release and Swirl on the Recirculation within Swirl-Stabilization Flames,†Combustion Science and Technology, Vol. 51, pp. 75-95.

Chen, R. H., and Driscoll, J. F., 1988, “The Rule of the Recirculation Vortex in Improving Fuel-Air Mixing within Swirling Flames,†Twenty-Second Symposium (International) on Combustion, Combustion Institute, Pittsburgh, pp. 531-440.

Agung Hidayat and A. Surjosatyo, 2008. Cold flow simulation on a Biomass Gasification. Final Year Project, Departemen Teknik Mesin, FT, UI, Indonesia.

Ala Qubbaj, 2005. Numerical Simulation of Natural Gas-Swirl Burner. Final Technical Report, University of Texas Pan American.

Hatziapostolou, A., et. al., 2006. CFD modeling of the swirl-stabilised flame produced by a laboratory-scale combustor: selection of the turbulence model. Proceedings of the 4th WSEAS Int. Conf. on Heat Transfer, Thermal Engineering and Environment, Elounda, Greece, pp 83-88.

Fluent Inc, 6.3. , “User Guideâ€, Fluent Incorporated, Lebanon

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Published

2018-04-03

How to Cite

Surjosatyo, A., & Priambodho, Y. D. (2018). INVESTIGATION OF GAS SWIRL BURNER CHARACTERISTIC ON BIOMASS GASIFICATION SYSTEM USING COMBUSTION UNIT EQUIPMENT (CUE). Jurnal Mekanikal, 33(2). Retrieved from https://jurnalmekanikal.utm.my/index.php/jurnalmekanikal/article/view/83

Issue

Issue 33: December 2011

Section

Mechanical

License

Copyright of articles that appear in Jurnal Mekanikal belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions or any other reproductions of similar nature.

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