Quick question about exhaust velocity

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    Exhaust Velocity
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In rocket propulsion calculations, exhaust velocity can be determined using either the exit temperature or the temperature change between the combustion chamber and the exit. The choice between these two methods depends on the specific parameters of the problem being solved. The exit temperature is used when it is directly provided or calculated, while the temperature change is applied when analyzing the energy conversion from combustion to kinetic energy. Understanding the context of each problem is crucial for selecting the appropriate formula. Clarity on how temperatures are defined in each scenario is essential for accurate calculations.
Jason Weiner
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I'm working on some propulsion homework for rockets. Basically combustion happens, and the gas velocity increases.
sometimes we use:
exhaust velocity = sqrt ( 2*Cp*exit temp)
other times we use
exhaust velocity = sqrt (2*Cp*(initial temp - final temp))

so the difference is, sometimes exit temp is used, others the 'change' in temp is used. I can't tell when or why the difference!
 
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How are those three temperatures defined?
 
I'm not sure what you mean by 'defined'
in both cases, the initial (combustion temp) was given, and exit was found and needed for other calculations.
So for two different questions, of the same 'basic' principals (rocket combustion)
to find exit velocity:
for one problem, we used exit temp
for another problem, we were supposed to use delta temp (change between chamber and exit)
even though they both seem to be combustion flowing out a nozzle!
 

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