Brayton cycle: Difference between revisions
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[[Image:Brayton-regen-Ts.png|400px|thumb|none|T-s diagram for the regenerative Brayton cycle]] | [[Image:Brayton-regen-Ts.png|400px|thumb|none|T-s diagram for the regenerative Brayton cycle]] | ||
== Regenerative Brayton cycle with reheat and intercooling == | |||
This cycle is an improvement on the simple regenerative Brayton cycle as it allows the compression and expansion to take place at closer to a uniform temperature, increasing the area inside T-s cycle loop. | |||
[[Image:Brayton-rri-config.png|400px|thumb|none|Configuration of the regenerative Brayton cycle with reheat and intercooling (Figure: Rachel Hogan)]] | |||
[[Image:Brayton-rri-Ts.png|400px|thumb|none|T-s diagram for the regenerative Brayton cycle with reheat and intercooling]] | |||
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Revision as of 23:13, 13 March 2013
The Brayton cycle the basic thermal power cycle implemented in gas turbines. ASCEND provides support for modelling Brayton cycles with a range of models of increasing complexity.
The models are provided in the file models/johnpye/brayton.a4c
See also Combined-cycle gas turbine
Split Brayton Cycle
This cycle has been identified as highly efficient when the working gas is supercritical carbon dioxide (sCO2). The configuration is shown below.
The model brayton_split_co2, contained in the file models/johnpye/brayton_split.a4c, implements this cycle. The T-s diagram of the cycle in our default configuration is shown below:
Regenerative Brayton cycle
This cycle is implemented in the model brayton_regen, contained in the file models/johnpye/brayton_fprops.a4c. The T-s diagram of the cycle in our default configuration is shown below:
Regenerative Brayton cycle with reheat and intercooling
This cycle is an improvement on the simple regenerative Brayton cycle as it allows the compression and expansion to take place at closer to a uniform temperature, increasing the area inside T-s cycle loop.
