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Further Cooling of Furnace Gases

Further Cooling of Furnace Gases. P M V Subbarao Professor Mechanical Engineering Department. Change the Modes of Heat Transfer for Better use…. Measures of Furnace Performance. Temperature Field Coefficient.

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Further Cooling of Furnace Gases

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  1. Further Cooling of Furnace Gases P M V Subbarao Professor Mechanical Engineering Department Change the Modes of Heat Transfer for Better use….

  2. Measures of Furnace Performance

  3. Temperature Field Coefficient • Temperature field coefficient accounts for the temperature distribution in the furnace. • It is a function of relative level of the burners and on the type of fuels burnt. • The expression of M is given as: • Z ris the relative position of highest temperature zone wrt to furnace bottom. • DZ is a correction factor for tilt of burners. • C1 &C2 are constants depend on fuel quality

  4. Distribution of Heat Flux • Average Heat flux can be calculated using: • As the temperature and emissivity of flame is not uniform in the furnace volume, the local heat flux is not uniform. • Actual local wall temperature depends on the value of local heat flux. • Special experiments are carried out to find the heat flux distribution on water wall.

  5. Measurement of Local Heat Flux Distribution & Control System

  6. Distribution of Heat Flux

  7. Distribution of Heat Flux

  8. Calculation of Non-uniformity of Heat Flux • Experimental determination of zone wise value of non-uniformity index, hi . • Calculate zone wise distribution of heat load. • Develop a local resistance network to compute local wall temperature.

  9. Elaborate Models for Better Analysis • Self-absorbing Models : • Directional Averaging Methods • 2-Flux, 4-Flux, Multiflux, DOM • Differential Approximation Method • Moment, Modified- Moment, PN – Appro • Energy Methods • Zone, MCM, Numerical (FD, FV) • Hybrid Methods • DTM, Ray Tracing ,Radiation Element

  10. Format of Report • At lease four references (journal/conference publications). • Basic theory, Verification through standard problems, Special problems solved. • Formulation of this method for Furnace cooling. • All clues to model: • Complex flame and furnace geometry. • Complex properties of flame and gas. • Boundary conditions.

  11. Evaluation • Submission of report : 20th April 2011. • Presentations: 23rd April 2011 (Saturday : 10.00 am onwards). • 30 to 40% weightage.

  12. Have we completed furnace cooling ????

  13. Thermal Structure of A SG DPNL SH R H T R drum screen tubes Platen SHTR LTSH Economiser stack BCW pump Furnace APH ESP ID Fan Bottom ash

  14. Paths of Steam and Gas Drum Water walls Economizer

  15. Furnace Energy Balance Enthalpy to be lost by hot gases: Water walls Economizer Furnace

  16. Other Radiative Exits of A Furnace

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