PHYSICS HIGH SCHOOL

The diffuser in a jet engine is designed to decrease the kinetic energy of the air entering the engine compressor without any work or heat interactions. Calculate the velocity at the exit of a diffuser when air at 100 kPa and 30°C enters it with a velocity of 357 m/s and the exit state is 200 kPa and 90°C. The specific heat of air at the average temperature of 60°C = 333 K is cp = 1.007 kJ/kg·K.

Answers

Answer 1

Answer:

Answer:

81.29 m/s

Explanation:

Given:

60°C = 333 K is cp = 1.007 kJ/kg·K.

at air inlet:

Pressure $P_(1)$ = 100 kPa

Temperature $T_(1)$ = 30°C

Velocity $V_(1)$ = 357 m/s

at air outlet:

Pressure $P_(2)$ = 200kPa

Temperature $T_(2)$ = 90°C

We can define the energy balance as:

$E _(in)$ - $E_(out)$ = Δ $E_(system)$ = 0

therefore, $E _(in)$ = $E_(out)$

m $h_(1)$ + m $(V_(1)^(2) )/(2)$ =m $h_(2)$ + $(V_(2)^(2) )/(2)$ (taking m common and cancelling it)

4 $h_(1)$ + $(V_(1)^(2) )/(2)$ = $h_(2)$ + $(V_(2)^(2) )/(2)$

The velocity at the exit of a diffuser:

$V_(2)$ = [ $V_(1)^(2)$ + 2 $c_p{}$ ( $T_(1)$ - $T_(2)$ ) $]^(0.5)$

$V_(2)$ = [ $357^(2)$ + 2 x 1000 x 1.007 x (30-90) $]^(0.5)$

$V_(2)$ = 81.29 m/s

therefore, the velocity at the exit of a diffuser is 81.29 m/s

Answer 2

Answer:

Exit velocity = 498.3m/s

Explanation:

The energy balance for the system is given by:

Ein - Eout = ◇Esystem

Ein = Eout

Therefore

m' (h1 + V1^2/2) = m' (h2 + V2^2/2)

h1 + V1^2/2 = h2 + V2^2/2

The exit velocity will be:

V2 = [V1^2 + 2(h1 - h2)^0.5 = [V1^2 + 2(cp(T1 - T2)]^0.5

But cp = 1.007kJ/kg

V2 = [(357)^2 + 2(1.007)(90-30)(1000m^2/s^2)]^0.5

V2 = [127449 + 120840]^0.5

V2 = [248289]^0.5

V2 = 498.3m/s

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Answers

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Answers

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Answers

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Answers

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https://en.wikipedia.org/wiki/Relative_dating

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