Natural exponential family: Difference between revisions
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In [[fluid dynamics]], '''stream thrust averaging''' is a process used to convert three dimensional flow through a duct into one dimensional uniform flow. It makes the assumptions that the flow is mixed [[adiabatic]]ally and without [[friction]]. However, due to the mixing process, there is a net increase in the entropy of the system. Although there is an increase in [[entropy]], the stream thrust averaged values are more representative of the flow than a simple average as a simple average would violate the [[second Law of Thermodynamics]]. | |||
==Equations for a perfect gas== | |||
Stream [[thrust]]: | |||
:<math> F = \int \left(\rho \mathbf{V} \cdot d \mathbf{A} \right) \mathbf{V} \cdot \mathbf{f} +\int pd \mathbf{A} \cdot \mathbf{f}.</math> | |||
[[Mass flow]]: | |||
:<math> \dot m = \int \rho \mathbf{V} \cdot d \mathbf{A}.</math> | |||
Stagnation [[enthalpy]]: | |||
:<math> H = {1 \over \dot m} \int \left({\rho \mathbf{V} \cdot d \mathbf{A}} \right) \left( h+ {|\mathbf{V}|^2 \over 2} \right),</math> | |||
:<math> \overline{U}^2 \left({1- {R \over 2C_p}}\right) -\overline{U}{F\over \dot m} +{HR \over C_p}=0.</math> | |||
===Solutions=== | |||
Solving for <math> \overline{U}</math> yields two solutions. They must both be analyzed to determine which is the physical solution. One will usually be a subsonic [[Root of a function|root]] and the other a supersonic root. If it is not clear which value of [[velocity]] is correct, the [[second law of thermodynamics]] may be applied. | |||
:<math> \overline{\rho} = {\dot m \over \overline{U}A},</math> | |||
:<math> \overline{p} = {F \over A} -{\overline{\rho} \overline{U}^2},</math> | |||
:<math> \overline{h} = {\overline{p} C_p \over \overline{\rho} R}.</math> | |||
Second law of thermodynamics: | |||
:<math> \nabla s = C_p \ln({\overline{T}\over T_1}) +R \ln({\overline{p} \over p_1}).</math> | |||
The values <math> T_1</math> and <math> p_1</math> are unknown and may be dropped from the formulation. The value of entropy is not necessary, only that the value is positive. | |||
:<math> \nabla s = C_p \ln(\overline{T}) +R \ln(\overline{p}).</math> | |||
One possible unreal solution for the stream thrust averaged velocity yields a negative entropy. Another method of determining the proper solution is to take a simple average of the velocity and determining which value is closer to the stream thrust averaged velocity. | |||
==References== | |||
* {{cite web |url=http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19990062664_1999094040.pdf |title=Inlet Development for a Rocket Based Combined Cycle, Single Stage to Orbit Vehicle Using Computational Fluid Dynamics |first1=J.R. |last1=DeBonis |first2=C.J. |last2=Trefny |first3=C.J. |last3=Steffen, Jr. |publisher=NASA |year=1999 |work=NASA/TM—1999-209279 |accessdate=18 February 2013}} | |||
[[Category:Equations of fluid dynamics]] | |||
[[Category:Fluid dynamics]] |
Revision as of 11:23, 14 April 2013
In fluid dynamics, stream thrust averaging is a process used to convert three dimensional flow through a duct into one dimensional uniform flow. It makes the assumptions that the flow is mixed adiabatically and without friction. However, due to the mixing process, there is a net increase in the entropy of the system. Although there is an increase in entropy, the stream thrust averaged values are more representative of the flow than a simple average as a simple average would violate the second Law of Thermodynamics.
Equations for a perfect gas
Stream thrust:
Stagnation enthalpy:
Solutions
Solving for yields two solutions. They must both be analyzed to determine which is the physical solution. One will usually be a subsonic root and the other a supersonic root. If it is not clear which value of velocity is correct, the second law of thermodynamics may be applied.
Second law of thermodynamics:
The values and are unknown and may be dropped from the formulation. The value of entropy is not necessary, only that the value is positive.
One possible unreal solution for the stream thrust averaged velocity yields a negative entropy. Another method of determining the proper solution is to take a simple average of the velocity and determining which value is closer to the stream thrust averaged velocity.