Turbine for Electricity Generation Using Chimney Flue Gases: A short review

Sanskar Manish Sane, Smit Bhupendra Kore, Bhavik Nitin Tamore, Ojas Laxman Gatkal
Journal of Thermal and Fluid Science
Volume 3: Issue 2, December 2022, pp 50-52

Author's Information
Sanskar Manish Sane1 
Corresponding Author
1Department Of Mechanical Engineering, St. John College of Engineering & Management University of Mumbai, India, India
Email

 Smit Bhupendra Kore2, Bhavik Nitin Tamore2, Ojas Laxman Gatkal2
2Department Of Mechanical Engineering, St. John College of Engineering & Management University of Mumbai, India, India

Short Article -- Peer Reviewed
Published online – 31 December 2022

Open Access article under Creative Commons License

Cite this article – Sanskar Manish Sane, Smit Bhupendra Kore, Bhavik Nitin Tamore, Ojas Laxman Gatkal“Turbine for Electricity Generation Using Chimney Flue Gases: A review ”, Journal of Thermal and Fluid Science, RAME Publishers, vol. 3, issue 2, pp. 50-52, December 2022.
https://doi.org/10.26706/jtfs.3.2.20221202

Abstract:-
A chimney is a type of architectural ventilation system made of masonry, clay, or metal that is used to isolate hot, dangerous exhaust gases or smoke from inhabited areas produced by appliances such as a boiler, stove, furnace, incinerator, or fireplace. Chimneys are usually vertical, or as close to vertical as possible, to ensure that the gases flow smoothly and attract air into the combustion, a phenomenon known as the stack, or chimney effect. This study proposes a novel idea for on-site power generation by harvesting kinetic energy from synthetic wind resources using ducted turbine systems. An attached horizontal axis ducted turbine uses the kinetic energy of flue gases to generate power at the chimney's top.
Index Terms:-
Turbine, flue gases, chimney, electricity generation .
REFERENCES
  1. Harjeet S. Mann, Pradeep K. Singh, “Kinetic Energy Recovery from the Chimney Flue Gases Using Ducted Turbine System” Chin. J. Mech. Eng, 2017 30:472–482.
  2. Chen T Y, Liao Y T, Cheng C C., Development of small wind turbines for moving vehicles: Effects of flanged diffusers on rotor performance, Experimental Thermal and Fluid Science, 2012, 42: 136–142.
  3. Chaudhari C D, Waghmare S A, Kotwal A P., Numerical analysis of venturi ducted horizontal axis wind turbine for efficient power generation, International Journal of Mechanical Engineering and Computer Applications, 2013, 1(5): 90–93.
  4. Ahmed N A, Cameron M., The challenges and possible solutions of horizontal axis wind turbines as a clean energy solution for the future, Renewable and Sustainable Energy Reviews, 2014, 38: 439–460.
  5. Falohun, Oke, Abolaji and Oladejo, Dangerous gas detection using an integrated circuit and MQ-9, International Journal of Computer Applications (0975–8887) Volume. 2016
  6. Katole, K. R., Bagade, V., Bangade, B., Soni, A., & Kamde, H., Hazardous Gas Detection using Arduino, International Journal of Science Technology & Engineering, 2(10). 2016
  7. B. S. Rao, D. K. S. Rao, and N. Om Internet of Things (IoT) based weather monitoring system, International Journal of Advanced Research in Computer and Communication Engineering, vol. 5, no. 9, pp. 312–319, 2016.
  8. Chilugodu N, Yoon Y-J, Chua KS, et al. Simulation of train induced forced wind draft for generating electrical power from Vertical Axis Wind Turbine (VAWT) [J]. International Journal of Precision Engineering and Manufacturing, 2012, 13(7): 1177–1181.

    9. To view full paper, Download here


For authors

Author's guidelines Publication Ethics Publication Policies Artical Processing Charges Call for paper Frequently Asked Questions(FAQS) View All Volumes and Issues

Publishing with