ChemE 260 The Brayton Power Cycle and Variations - PowerPoint PPT Presentation

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ChemE 260 The Brayton Power Cycle and Variations

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ChemE 260 The Brayton Power Cycle and Variations Dr. William Baratuci Senior Lecturer Chemical Engineering Department University of Washington TCD 9: E & F – PowerPoint PPT presentation

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Title: ChemE 260 The Brayton Power Cycle and Variations


1
ChemE 260 The Brayton Power Cycleand Variations
  • Dr. William Baratuci
  • Senior Lecturer
  • Chemical Engineering Department
  • University of Washington
  • TCD 9 E FCB 8 1 - 3, 8 - 10

May 25, 2005
2
The Brayton Cycle
  • The ideal gas cycle for gas-turbine engines

Baratuci ChemE 260 May 25, 2005
3
The Air-Standard Brayton Cycle
  • Air-Standard Assumptions
  • Air is the working fluid and it behaves as an
    ideal gas.
  • The Brayton Cycle is modeled as as a closed
    cycle.
  • The combustor is replaced by HEX 1. (External
    Combustion)
  • All processes are internally reversible.
  • Step 1-2 Isobaric heating
  • Step 2-3 Isentropic expansion
  • Step 3-4 Isobaric cooling
  • Step 4-1 Isentropic compression

Baratuci ChemE 260 May 25, 2005
4
PV TS Diagrams
Baratuci ChemE 260 May 25, 2005
5
The Cold Air-Standard Assumption
  • The heat capacities of air are constant and
    always have the values determined at 25oC.
  • Compression Ratio
  • Thermal efficiency of an internally reversible,
    cold air-standard Brayton Cycle

Baratuci ChemE 260 May 25, 2005
6
Air-Standard Brayton Cycle Efficiency
Baratuci ChemE 260 May 25, 2005
7
Improvements to the Brayton Cycle
  • Regeneration
  • Use the hot turbine effluent to preheat the feed
    to the combustor.
  • Reheat
  • Use a 2-stage turbine and reheat the effluent
    from the HP turbine before putting into the LP
    turbine.
  • Intercooling
  • Use a 2-stage compressor with an intercooler.
  • Regeneration with Reheat and Intercooling
  • Use all of the techniques listed above to achieve
    high efficiency.

Baratuci ChemE 260 May 25, 2005
8
Regenerative Brayton Cycle
Baratuci ChemE 260 May 25, 2005
9
Regenerative Brayton Cycle Efficiency
Brayton Cycle
Regenerative Brayton Cycle T1 / T4 0.30
Regenerative Brayton Cycle T1 / T4 0.20
Baratuci ChemE 260 May 25, 2005
10
Reheat Brayton Cycle
Baratuci ChemE 260 May 25, 2005
11
Brayton Cycle with Intercooling
Baratuci ChemE 260 May 25, 2005
12
Regeneration, Reheat Intercooling
Baratuci ChemE 260 May 25, 2005
13
Next Class
  • Vapor-Compression Refrigeration Cycles
  • Cycle corresponds to the vapor power cycle.
  • TS Diagrams, Deviations from internal
    reversibility
  • Selecting a refrigerant
  • Enhanced Vapor-Compression Refrigeration Cycles
  • Cascade V-C Refrigeration Cycles
  • Two separate refrigeration cycles, Analogous to
    Binary Vapor Power Cycles
  • One provides cooling to the other
  • Two different refrigerants
  • Can reach very low temperatures
  • Multi-Stage V-C Refrigeration Cycles
  • Similar to Cascade V-C Refrigeration
  • Two cycles use the same refrigerant
  • Instead of exchanging heat between two cycles,
    the refrigerant streams are mixed. This is more
    efficient than heat exchange.

Baratuci ChemE 260 May 25, 2005
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