1 / 29

Lecture Objectives:

Lecture Objectives:. Continue with power generation Learn basics about boilers and furnaces. Ideal Rankine Cycle. 1-2 isentropic pump 2-3 constant pressure heat addition 3-4 isentropic turbine 4-1 constant pressure heat rejection. Reheat Cycle.

rpuccio
Download Presentation

Lecture Objectives:

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Lecture Objectives: • Continue with power generation • Learn basics about boilers and furnaces

  2. Ideal Rankine Cycle 1-2 isentropic pump 2-3 constant pressure heat addition 3-4 isentropic turbine 4-1 constant pressure heat rejection

  3. Reheat Cycle • It allows increase boiler pressure without problems of low quality at turbine exit

  4. Regeneration • Preheats steam entering boiler using a feed-water heater, improving efficiency

  5. Improvements

  6. Gas powered turbine http://www.youtube.com/watch?feature=player_embedded&v=rxps0sZ8T3Y

  7. Combustion product gas powered turbines • Limited to gas or oil as a major source of fuel • Approximately 55 to 65% of the power produced by the turbine is used for compressor. • Gas temperatures at the turbine inlet can be 1200ºC to 1400ºC • Because of the power required to drive the compressor, energy conversion efficiency for a simple cycle gas turbine plant is ~ 30%

  8. Combined Cycle(gas and steam) http://www.youtube.com/watch?feature=player_embedded&v=D406Liwm1Jc

  9. Combined heat and power(cogeneration CHP or three generation CCHP) Here, we use thermal energy for heating and/or cooling

  10. Other method for CHP Here, we use mechanical energy for powering vapor compression cooling systems

  11. Boilersare integral part of power generation system It is much more complex system than presented in this graph

  12. Coal Boilers

  13. Coal Boiler

  14. Coal burning method Long time ago: Today: 1) Fluidized bed: http://www.youtube.com/watch?v=8n78CDI3GoU 2) Powdered coal: http://www.youtube.com/watch?v=g1ojza-nbqs

  15. Formation of NOx and CO in Combustion Thermal NOx • Oxidation of atmospheric N2 at high temperatures • Formation of thermal NOx is at higher temperature Fuel NOx • Oxidation of nitrogen compounds contained in the fuel Formation of CO • Incomplete Combustion • Dissociation of CO2 at high temperature

  16. Coal-fired power plant filters Higher the temperature of combustion mean more NOx • Chemistry for NOxreduction: • Large boilers typically use chemistry that produce N2 and H2O. Example is addition of Ammonia (NH3) • Use of catalysts for NOxreduction: • Often in combination with NH3

  17. Coal-fired power plant filters • For Particulate Maters • Electrostatic precipitator • Filter bags • Scrubber for SO2 (to prevent formation of Sulfuric acid – H2SO4) • Grinded Limestone in water (slurry) sprayed into the gas fluid stream SO2 + Limestone slurry → Gypsum (used for wallboard)

  18. Oil – Gas based boilers Gas circulate through tubes water is in-between Water tube boiler

  19. Furnaces For homes Roof tops and induct heaters

  20. Fuel combustion - Stoichiometry • Boiler efficiency as a function of excessive air • Stoichiometry • Chemistry of reactants, products and energy in chemical reactions • A stoichiometric ratio of a reagent is the optimum amount or ratio where, assuming that the reaction proceeds to completion: +Q combustion Stoichiometric combustion

  21. Air Pollutants from Combustion Air-Fuel Ratio • - Rich mixture - more fuel than necessary • (AF) mixture < (AF)stoich • - Lean mixture • - more air than necessary • (AF) mixture > (AF)stoich • Most combustion systems • operate under lean conditions! • However, too-lean mixture • results in Nox products!

  22. Stoichiometric air/fuel ratio for selected gases

  23. Energy densities of fuels

  24. Higher heating value (HHV) vs. Lower heating value (HHV) • HHV is the heat of combustion of the fuel when the water product is at liquid state (water vapor from the product are condensed) • LHV is the heat of combustion of the fuel when the combustion product contain water vapor For methane ~10% difference!

  25. Condensing vs. noncondensing boilers Example is for a small residential gas powered boiler - wall mount fan coils, or baseboard hearts

  26. Condensing vs. noncondensing boilers ~86% (depends on fuel)

  27. Boiler Efficiency Definitions • ASHRAE Standard 90.1-2004 describes the minimum acceptable ratings for new boilers • Combustion Efficiency % = ((Fuel Input – Stack Losses) / Fuel Input) x 100 • Thermal Efficiency % = (Output / Input) x 100 • Annual or Seasonal Efficiency …..

  28. Boiler and Furnace Efficiency Definitions Example (for large coal based boilers)

  29. Typical boiler and furnace efficiency (based on the higher heating value) • Condensing boilers manufacturers claim up to 98% (be careful with this number; check for which conditions) • Older conventional boilers 70%-80% • Typical new models around 90% • New gas furnaces are in the rage of 80-90% • These numbers are for well maintained and tuned boilers & furnaces. Also, Seasonal Efficiency can be significantly smaller!

More Related