CONNECT FOR THERMODYNAMICS: AN ENGINEERI
CONNECT FOR THERMODYNAMICS: AN ENGINEERI
9th Edition
ISBN: 9781260048636
Author: CENGEL
Publisher: MCG
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Chapter 17.7, Problem 37P

(a)

To determine

The critical temperature of air.

The critical pressure of air.

The critical density of air.

(a)

Expert Solution
Check Mark

Answer to Problem 37P

The critical temperature of air is 355K_.

The critical pressure of air is 167kPa_.

The critical density of air is 1.65kg/m3_.

Explanation of Solution

Determine the stagnation temperature of ideal gas.

T0=T+V22cp (I)

Here, the static temperature of ideal gas is T, the specific heat of pressure for ideal gas is cp, and the velocity of the ideal gas flow is V.

Determine the stagnation pressure of ideal gas.

P0=P(T0T)k/(k1) (II)

Here, the static pressure of ideal gas is P, the specific heat ratio of ideal gas is k.

Determine the density of the ideal gas.

ρ0=P0RT0 (III)

Here, the pressure of the ideal gas is P.

Determine the critical temperature at the throat of nozzle.

T=T0(2k+1) (IV)

Here, the stagnation temperature of ideal gas is T0.

Determine the critical pressure at the throat of nozzle.

P=P0(2k+1)k/(k1) (V)

Here, the stagnation pressure of ideal gas is P0.

Determine the critical density at the throat of nozzle.

ρ=ρ0(2k+1)1/(k1) (VI)

Here, the stagnation density of ideal gas is ρ0.

Conclusion:

From the Table A-2, “Ideal-gas specific heats of various common gases” to obtain value of universal gas constant, specific heat of pressure, and the specific heat ratio of air at 300K temperature as 0.287kJ/kgK, 1.005kJ/kgK and 1.400.

Substitute 100°C for T, 325m/s for V, and 1.005kJ/kgK for cp in Equation (I).

T0=(100°C)+(325m/s)22×(1.005kJ/kgK)=(100°C)+(325m/s)22×(1.005kJ/kg°C)=(100°C)+(105625m2/s2)×(1kJ/kg1000m2/s2)(2.01kJ/kg°C)=152.5°C

    =152.5°C+273.2=425.7K

Substitute 200 kPa for P, 100°C for T, 425.7K for T0, and 1.400 for k in Equation (II).

P0=(200kPa)×(425.7K100°C)1.400/(1.4001)=(200kPa)×(425.7K100°C+273.2)1.400/(1.4001)=(200kPa)×(1.585138)=317.0kPa

Substitute 317.0 kPa for P0, 0.287kJ/kgK for R, and 425.7 K for T0 in Equation (III).

ρ0=317.0kPa(0.287kJ/kgK)(425.7K)=317.0kPa(0.287kJ/kgK)×(1kPam31kJ)(425.7K)=317.0kPa(122.1759kPam3/kg)=2.59462kg/m3

Substitute 425.7K for T0 and 1.400 for k in Equation (IV).

T=(425.7K)×(21.400+1)=(425.7K)×(0.8333)=354.75K355K

Thus, the critical temperature of air is 355K_.

Substitute 317.0kPa for P0 and 1.400 for k in Equation (V).

P=(317.0kPa)×(21.400+1)1.400/(1.4001)=(317.0kPa)×(0.528282)=167.4kPa167kPa

Substitute 2.595kg/m3 for ρ0, and 1.400 for k in Equation (VI).

ρ=(2.595kg/m3)(21.4+1)1/(1.41)=(2.595kg/m3)(0.633938)=1.6450kg/m31.65kg/m3

Thus, the critical density of air is 1.65kg/m3_.

(b)

To determine

The critical temperature of helium.

The critical pressure of helium.

The critical density of helium.

(b)

Expert Solution
Check Mark

Answer to Problem 37P

The critical temperature of helium is 256K_.

The critical pressure of helium is 104kPa_.

The critical density of helium is 0.195kg/m3_.

Explanation of Solution

Conclusion:

From the Table A-2, “Ideal-gas specific heats of various common gases” to obtain value of universal gas constant, specific heat of pressure, and the specific heat ratio of helium at 300K temperature as 2.0769kJ/kgK, 5.1926kJ/kgK and 1.667.

Substitute 60°C for T, 300m/s for V, and 5.1926kJ/kgK for cp in Equation (I).

T0=(60°C)+(300m/s)22×(5.1926kJ/kgK)=(60°C)+(300m/s)22×(5.1926kJ/kg°C)=(60°C)+(90000m2/s2)×(1kJ/kg1000m2/s2)(10.3852kJ/kg°C)=68.66°C

    =68.66°C+273.2=341.866K341.9K

Substitute 200 kPa for P, 60°C for T, 341.9K for T0, and 1.667 for k in Equation (II).

P0=(200kPa)×(341.9K60°C)1.667/(1.6671)=(200kPa)×(341.9K333.2K)1.667/(1.6671)=(200kPa)×(1.066539)=213.3kPa

Substitute 213.3 kPa for P0, 2.0769kJ/kgK for R, and 341.9 K for T0 in Equation (III).

ρ0=213.3kPa(2.0769kJ/kgK)(341.9K)=213.3kPa(2.0769kJ/kgK)×(1kPam31kJ)(341.9K)=213.3kPa(710.0921kPam3/kg)=0.30038kg/m3

     0.3004kg/m3

Substitute 341.9K for T0 and 1.667 for k in Equation (IV).

T=(341.9K)×(21.667+1)=(341.9K)×(0.749906)=256.39K256K

Thus, the critical temperature of helium is 256K_.

Substitute 213.3kPa for P0 and 1.667 for k in Equation (V).

P=(213.3kPa)×(21.667+1)1.667/(1.6671)=(213.3kPa)×(0.487092)=103.89kPa104kPa

Thus, the critical pressure of helium is 104kPa_

Substitute 0.3004kg/m3 for ρ0, and 1.667 for k in Equation (VI).

ρ=(0.3004kg/m3)(21.667+1)1/(1.6671)=(0.3004kg/m3)(0.649537)=0.195kg/m3

Thus, the critical density of helium is 0.195kg/m3_.

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Chapter 17 Solutions

CONNECT FOR THERMODYNAMICS: AN ENGINEERI

Ch. 17.7 - Prob. 11PCh. 17.7 - Prob. 12PCh. 17.7 - Prob. 13PCh. 17.7 - Prob. 14PCh. 17.7 - Prob. 15PCh. 17.7 - Prob. 16PCh. 17.7 - Prob. 17PCh. 17.7 - Prob. 18PCh. 17.7 - Prob. 19PCh. 17.7 - Prob. 20PCh. 17.7 - Prob. 21PCh. 17.7 - Prob. 22PCh. 17.7 - Prob. 23PCh. 17.7 - Prob. 24PCh. 17.7 - Prob. 25PCh. 17.7 - Prob. 26PCh. 17.7 - The isentropic process for an ideal gas is...Ch. 17.7 - Is it possible to accelerate a gas to a supersonic...Ch. 17.7 - Prob. 29PCh. 17.7 - Prob. 30PCh. 17.7 - A gas initially at a supersonic velocity enters an...Ch. 17.7 - Prob. 32PCh. 17.7 - Prob. 33PCh. 17.7 - Prob. 34PCh. 17.7 - Prob. 35PCh. 17.7 - Prob. 36PCh. 17.7 - Prob. 37PCh. 17.7 - Air at 25 psia, 320F, and Mach number Ma = 0.7...Ch. 17.7 - Prob. 39PCh. 17.7 - Prob. 40PCh. 17.7 - Prob. 41PCh. 17.7 - Prob. 42PCh. 17.7 - Prob. 43PCh. 17.7 - Is it possible to accelerate a fluid to supersonic...Ch. 17.7 - Prob. 45PCh. 17.7 - Prob. 46PCh. 17.7 - Prob. 47PCh. 17.7 - Consider subsonic flow in a converging nozzle with...Ch. 17.7 - Consider a converging nozzle and a...Ch. 17.7 - Prob. 50PCh. 17.7 - Prob. 51PCh. 17.7 - Prob. 52PCh. 17.7 - Prob. 53PCh. 17.7 - Prob. 54PCh. 17.7 - Prob. 57PCh. 17.7 - Prob. 58PCh. 17.7 - Prob. 59PCh. 17.7 - Prob. 60PCh. 17.7 - Prob. 61PCh. 17.7 - Air enters a nozzle at 0.5 MPa, 420 K, and a...Ch. 17.7 - Prob. 63PCh. 17.7 - Are the isentropic relations of ideal gases...Ch. 17.7 - What do the states on the Fanno line and the...Ch. 17.7 - It is claimed that an oblique shock can be...Ch. 17.7 - Prob. 69PCh. 17.7 - Prob. 70PCh. 17.7 - For an oblique shock to occur, does the upstream...Ch. 17.7 - Prob. 72PCh. 17.7 - Prob. 73PCh. 17.7 - Prob. 74PCh. 17.7 - Prob. 75PCh. 17.7 - Prob. 76PCh. 17.7 - Prob. 77PCh. 17.7 - Prob. 78PCh. 17.7 - Prob. 79PCh. 17.7 - Air flowing steadily in a nozzle experiences a...Ch. 17.7 - Air enters a convergingdiverging nozzle of a...Ch. 17.7 - Prob. 84PCh. 17.7 - Prob. 85PCh. 17.7 - Consider the supersonic flow of air at upstream...Ch. 17.7 - Prob. 87PCh. 17.7 - Prob. 88PCh. 17.7 - Air flowing at 40 kPa, 210 K, and a Mach number of...Ch. 17.7 - Prob. 90PCh. 17.7 - Prob. 91PCh. 17.7 - Prob. 92PCh. 17.7 - What is the characteristic aspect of Rayleigh...Ch. 17.7 - Prob. 94PCh. 17.7 - Prob. 95PCh. 17.7 - What is the effect of heat gain and heat loss on...Ch. 17.7 - Consider subsonic Rayleigh flow of air with a Mach...Ch. 17.7 - Prob. 98PCh. 17.7 - Prob. 99PCh. 17.7 - Air is heated as it flows subsonically through a...Ch. 17.7 - Prob. 101PCh. 17.7 - Prob. 102PCh. 17.7 - Prob. 103PCh. 17.7 - Air enters a rectangular duct at T1 = 300 K, P1 =...Ch. 17.7 - Prob. 106PCh. 17.7 - Prob. 107PCh. 17.7 - Air is heated as it flows through a 6 in 6 in...Ch. 17.7 - What is supersaturation? Under what conditions...Ch. 17.7 - Steam enters a converging nozzle at 5.0 MPa and...Ch. 17.7 - Steam enters a convergingdiverging nozzle at 1 MPa...Ch. 17.7 - Prob. 112PCh. 17.7 - Prob. 113RPCh. 17.7 - Prob. 114RPCh. 17.7 - Prob. 115RPCh. 17.7 - Prob. 116RPCh. 17.7 - Prob. 118RPCh. 17.7 - Prob. 119RPCh. 17.7 - Using Eqs. 174, 1713, and 1714, verify that for...Ch. 17.7 - Prob. 121RPCh. 17.7 - Prob. 122RPCh. 17.7 - Prob. 123RPCh. 17.7 - Prob. 124RPCh. 17.7 - Prob. 125RPCh. 17.7 - Prob. 126RPCh. 17.7 - Nitrogen enters a convergingdiverging nozzle at...Ch. 17.7 - An aircraft flies with a Mach number Ma1 = 0.9 at...Ch. 17.7 - Prob. 129RPCh. 17.7 - Helium expands in a nozzle from 220 psia, 740 R,...Ch. 17.7 - Helium expands in a nozzle from 0.8 MPa, 500 K,...Ch. 17.7 - Air is heated as it flows subsonically through a...Ch. 17.7 - Air is heated as it flows subsonically through a...Ch. 17.7 - Prob. 134RPCh. 17.7 - Prob. 135RPCh. 17.7 - Air is cooled as it flows through a 30-cm-diameter...Ch. 17.7 - Saturated steam enters a convergingdiverging...Ch. 17.7 - Prob. 138RPCh. 17.7 - Prob. 145FEPCh. 17.7 - Prob. 146FEPCh. 17.7 - Prob. 147FEPCh. 17.7 - Prob. 148FEPCh. 17.7 - Prob. 149FEPCh. 17.7 - Prob. 150FEPCh. 17.7 - Prob. 151FEPCh. 17.7 - Prob. 152FEPCh. 17.7 - Consider gas flow through a convergingdiverging...Ch. 17.7 - Combustion gases with k = 1.33 enter a converging...
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