15Mar 2020

ESTIMATION OF MECHANICAL PROPERTIES OF WATER AUGMENTED PULSE JET ENGINE

  • Department of Mechanical Engineering, SNS College Of Technology, Coimbatore, India.
  • Department of Aeronautical Engineering, SNS College Of Technology, Coimbatore, India.
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The objective of this project work is to understand the thermodynamic characteristics of conventional pulse jet. The geometrical parameters and performance aspects of the engine were studied including specific fuel consumption, thrust. Calculation was made on geometrical parameters for a design of a pulse jet engine of 100lb thrust. We use the valve less pulse jet engine to simplify engine complexity. We use the MAT LAB to analysis the pulse jet engine.

  1. Riffat, S. B., & Ma, X. (2003). Thermoelectrics: a review of present and potential applications. Applied thermal engineering, 23(8), 913-935.
  2. Mohamed, E. S. (2019). Development and performance analysis of a TEG system using exhaust recovery for a light diesel vehicle with assessment of fuel economy and emissions. Applied Thermal Engineering, 147, 661-674.
  3. Li, X., & Wang, Z. (2017). Exergy analysis of integrated TEG and regenerative cooling system for power generation from the scramjet cooling heat. Aerospace Science and Technology, 66, 12-19.
  4. Kilinc, E., Uysal, F., Celik, E., & Kurt, H. (2019). Steady-state thermal-electric analysis of a π-shaped 8-pair thermoelectric generator. Materials Today: Proceedings, 8, 523-530.
  5. Babu, C., & Ponnambalam, P. (2018). The theoretical performance evaluation of hybrid PV-TEG system. Energy conversion and management, 173, 450-460.
  6. Kwan, T. H., Wu, X. F., & Yao, Q. H. (2018). Thermoelectric device multi-objective optimization using a simultaneous TEG and TEC characterization (vol 168, pg 85, 2018). Energy Conversion and Management, 172, 645-645.
  7. Prakash, R. P. L., Selvam, M., Pandian, A. A. S., Palani, S., & Harish, K. A. (2016). Design and Modification of Radiator in IC Engine Cooling System for Maximizing Efficiency and Life. Indian Journal of Science and Technology, 9(2), 1-2.
  8. Zeutzius, M., Terao, K., Setoguchi, T., Matsuo, S., Nakano, T., & Fujita, Y. (1998). Active control of twin-pulse combustors. AIAA journal, 36(5), 823-829.
  9. Hussain, H. S. (2008). Theoretical and Experimental Evaluation of Pulse Jet Engine (Doctoral dissertation, University of Khartoum).
  10. Ahmad, M. T., Ahmadian, S., Zhahir, A., Ariff, O. K., & Romli, F. I. (2014). Computational Approach in Sizing of Pulsejet Engine. In Applied Mechanics and Materials (Vol. 629, pp. 131-136). Trans Tech Publications.
  11. Nakano, T., Matsuo, S., Teramoto, K., & Setoguchi, T. (2006). Effect of exit geometry of tail pipe on the performance of pulse jet engines. Journal of Thermal Science, 15(3), 263-268.
  12. Zhang, G., Kim, H. D., & Jin, Y. Z. (2017). Analysis of choked two-phase flows of gas and particle in a CD nozzle. Theoretical and Applied Mechanics Letters, 7(6), 331-338.

[M. Subramanian, N. Venkatesh, S. Gopikannan, V. Harish and V. Kavin (2020); ESTIMATION OF MECHANICAL PROPERTIES OF WATER AUGMENTED PULSE JET ENGINE Int. J. of Adv. Res. 8 (Mar). 747-755] (ISSN 2320-5407). www.journalijar.com

N.Venkatesh

DOI:

Article DOI: 10.21474/IJAR01/10689      
DOI URL: https://dx.doi.org/10.21474/IJAR01/10689

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