(a) Interpretation: Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions. Concept Introduction: Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Question

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Answer 1

Question

Chapter 7, Problem 7.27P

Interpretation Introduction

(a)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2218.23 kW.

Temperature of exhaust stream: 186⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =480⁰C, P1 =6 bar, n˙ = 200 mol/s, P2 =1 bar, η =0.8

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =480 ⁰C and P1 = 6 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.29 kJ/kg K

Specific enthalpy, H1 : 484.75 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :186 ⁰C

At this exhaust temperature, enthalpy, H2 : 167.86 kJ/kgTheoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 167.86−484.75) kJ/kg= −316.89 kJ/kg=−316.89 kJ/kg × 28 kg/kmol=−8872.92 kJ/kmol=−8872.92 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 200 mol/s × 8872.92 J/mol=1774584 J/s=1774584 W=1774.58 kW

Actual output power requirement = theoretical power / efficiency

= 1774.580.8 kW=2218.23 kW

Interpretation Introduction

(b)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1451.75 kW.

Temperature of exhaust stream: 157 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =400⁰C, P1 =5 bar, n˙ = 150mol/s, P2 =1 bar, η =0.75

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 400⁰C and P1 =5 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.22 kJ/kg K

Specific enthalpy, H1 :396.68 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :157⁰C

At this exhaust temperature, enthalpy, H2 : 137.44 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

= ( 137.44−396.68) kJ/kg= −259.24 kJ/kg= −259.24 kJ/kg × 28 kg/kmol= −7258.72 kJ/kmol= −7258.72 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 150 mol/s × 7258.72 J/mol=1088808 J/s=1088808 W=1088.81 kW

Actual output power requirement = theoretical power / efficiency

= 1088.810.75 kW=1451.75 kW

Interpretation Introduction

(c)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2176.73 kW.

Temperature of exhaust stream: 179 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =500⁰C, P1 =7 bar, n˙ = 175mol/s, P2 =1 bar, η =0.78

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =500⁰C and P1 =7 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.273 kJ/kg K

Specific enthalpy, H1 :507.01 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :179⁰C

At this exhaust temperature, enthalpy, H2 : 160.51 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 160.51−507.01) kJ/kg= −346.5 kJ/kg= −346.5 kJ/kg × 28 kg/kmol=−9702 kJ/kmol=−9702 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 175 mol/s ×9702 J/mol=1697850 J/s=1697850 W=1697.85 kW

Actual output power requirement = theoretical power / efficiency

= 1697.850.78 kW=2176.73 kW

Interpretation Introduction

(d)

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 816.51 kW.

Temperature of exhaust stream: 220 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 = 450⁰C, P1 =8 bar, n˙ = 100mol/s, P2 =2 bar, η =0.85

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 450⁰C and P1 = 8 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.159 kJ/kg K

Specific enthalpy, H1 :451.54 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :220⁰C

At this exhaust temperature, enthalpy, H2 : 203.67 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 203.67−451.54) kJ/kg= −247.87 kJ/kg= −247.87 kJ/kg × 28 kg/kmol=−6940.36 kJ/kmol=−6940.36 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 100 mol/s × 6940.36 J/mol=694036 J/s=694036 W=694.036 kW

Actual output power requirement = theoretical power / efficiency

= 694.0360.85 kW=816.51 kW

Interpretation Introduction

(e)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1973.86 Btu/s.

Temperature of exhaust stream: 352.13 ⁰F

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =900⁰F, P1 =95 psia, n˙ = 0.5 (lbmol)/s, P2 =15 psia, η =0.80

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 900⁰F and P1 = 95 psia inlet conditions for nitrogen,

Specific entropy, S1 : 1.737 Btu/lbm⁰R

Specific enthalpy, H1 : 209.55 Btu/lbm

Exhaust pressure is 15 psia.

To have the same specific entropy, exhaust temperature, T2 :352.13⁰F= 178⁰C

At this exhaust temperature, enthalpy, H2 : 68.56 Btu/lbm

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 68.56−209.55) Btu/lbm= −140.99Btu/lbm= −140.99Btu/lbm× 28 lbm/lbmol=−3947.72 Btu/lbmol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 0.5 lbmol/s × 3947.72 Btu/lbmol=1973.86 Btu/s=2082.53 kW

Actual output power requirement = theoretical power / efficiency

= 2082.530.8 kW=2603.16 kW

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Answer 2

Question

Chapter 7, Problem 7.27P

Interpretation Introduction

(a)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2218.23 kW.

Temperature of exhaust stream: 186⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =480⁰C, P1 =6 bar, n˙ = 200 mol/s, P2 =1 bar, η =0.8

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =480 ⁰C and P1 = 6 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.29 kJ/kg K

Specific enthalpy, H1 : 484.75 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :186 ⁰C

At this exhaust temperature, enthalpy, H2 : 167.86 kJ/kgTheoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 167.86−484.75) kJ/kg= −316.89 kJ/kg=−316.89 kJ/kg × 28 kg/kmol=−8872.92 kJ/kmol=−8872.92 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 200 mol/s × 8872.92 J/mol=1774584 J/s=1774584 W=1774.58 kW

Actual output power requirement = theoretical power / efficiency

= 1774.580.8 kW=2218.23 kW

Interpretation Introduction

(b)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1451.75 kW.

Temperature of exhaust stream: 157 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =400⁰C, P1 =5 bar, n˙ = 150mol/s, P2 =1 bar, η =0.75

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 400⁰C and P1 =5 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.22 kJ/kg K

Specific enthalpy, H1 :396.68 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :157⁰C

At this exhaust temperature, enthalpy, H2 : 137.44 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

= ( 137.44−396.68) kJ/kg= −259.24 kJ/kg= −259.24 kJ/kg × 28 kg/kmol= −7258.72 kJ/kmol= −7258.72 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 150 mol/s × 7258.72 J/mol=1088808 J/s=1088808 W=1088.81 kW

Actual output power requirement = theoretical power / efficiency

= 1088.810.75 kW=1451.75 kW

Interpretation Introduction

(c)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2176.73 kW.

Temperature of exhaust stream: 179 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =500⁰C, P1 =7 bar, n˙ = 175mol/s, P2 =1 bar, η =0.78

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =500⁰C and P1 =7 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.273 kJ/kg K

Specific enthalpy, H1 :507.01 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :179⁰C

At this exhaust temperature, enthalpy, H2 : 160.51 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 160.51−507.01) kJ/kg= −346.5 kJ/kg= −346.5 kJ/kg × 28 kg/kmol=−9702 kJ/kmol=−9702 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 175 mol/s ×9702 J/mol=1697850 J/s=1697850 W=1697.85 kW

Actual output power requirement = theoretical power / efficiency

= 1697.850.78 kW=2176.73 kW

Interpretation Introduction

(d)

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 816.51 kW.

Temperature of exhaust stream: 220 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 = 450⁰C, P1 =8 bar, n˙ = 100mol/s, P2 =2 bar, η =0.85

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 450⁰C and P1 = 8 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.159 kJ/kg K

Specific enthalpy, H1 :451.54 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :220⁰C

At this exhaust temperature, enthalpy, H2 : 203.67 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 203.67−451.54) kJ/kg= −247.87 kJ/kg= −247.87 kJ/kg × 28 kg/kmol=−6940.36 kJ/kmol=−6940.36 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 100 mol/s × 6940.36 J/mol=694036 J/s=694036 W=694.036 kW

Actual output power requirement = theoretical power / efficiency

= 694.0360.85 kW=816.51 kW

Interpretation Introduction

(e)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1973.86 Btu/s.

Temperature of exhaust stream: 352.13 ⁰F

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =900⁰F, P1 =95 psia, n˙ = 0.5 (lbmol)/s, P2 =15 psia, η =0.80

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 900⁰F and P1 = 95 psia inlet conditions for nitrogen,

Specific entropy, S1 : 1.737 Btu/lbm⁰R

Specific enthalpy, H1 : 209.55 Btu/lbm

Exhaust pressure is 15 psia.

To have the same specific entropy, exhaust temperature, T2 :352.13⁰F= 178⁰C

At this exhaust temperature, enthalpy, H2 : 68.56 Btu/lbm

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 68.56−209.55) Btu/lbm= −140.99Btu/lbm= −140.99Btu/lbm× 28 lbm/lbmol=−3947.72 Btu/lbmol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 0.5 lbmol/s × 3947.72 Btu/lbmol=1973.86 Btu/s=2082.53 kW

Actual output power requirement = theoretical power / efficiency

= 2082.530.8 kW=2603.16 kW

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Answer 3

Question

Chapter 7, Problem 7.27P

Interpretation Introduction

(a)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2218.23 kW.

Temperature of exhaust stream: 186⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =480⁰C, P1 =6 bar, n˙ = 200 mol/s, P2 =1 bar, η =0.8

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =480 ⁰C and P1 = 6 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.29 kJ/kg K

Specific enthalpy, H1 : 484.75 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :186 ⁰C

At this exhaust temperature, enthalpy, H2 : 167.86 kJ/kgTheoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 167.86−484.75) kJ/kg= −316.89 kJ/kg=−316.89 kJ/kg × 28 kg/kmol=−8872.92 kJ/kmol=−8872.92 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 200 mol/s × 8872.92 J/mol=1774584 J/s=1774584 W=1774.58 kW

Actual output power requirement = theoretical power / efficiency

= 1774.580.8 kW=2218.23 kW

Interpretation Introduction

(b)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1451.75 kW.

Temperature of exhaust stream: 157 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =400⁰C, P1 =5 bar, n˙ = 150mol/s, P2 =1 bar, η =0.75

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 400⁰C and P1 =5 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.22 kJ/kg K

Specific enthalpy, H1 :396.68 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :157⁰C

At this exhaust temperature, enthalpy, H2 : 137.44 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

= ( 137.44−396.68) kJ/kg= −259.24 kJ/kg= −259.24 kJ/kg × 28 kg/kmol= −7258.72 kJ/kmol= −7258.72 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 150 mol/s × 7258.72 J/mol=1088808 J/s=1088808 W=1088.81 kW

Actual output power requirement = theoretical power / efficiency

= 1088.810.75 kW=1451.75 kW

Interpretation Introduction

(c)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2176.73 kW.

Temperature of exhaust stream: 179 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =500⁰C, P1 =7 bar, n˙ = 175mol/s, P2 =1 bar, η =0.78

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =500⁰C and P1 =7 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.273 kJ/kg K

Specific enthalpy, H1 :507.01 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :179⁰C

At this exhaust temperature, enthalpy, H2 : 160.51 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 160.51−507.01) kJ/kg= −346.5 kJ/kg= −346.5 kJ/kg × 28 kg/kmol=−9702 kJ/kmol=−9702 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 175 mol/s ×9702 J/mol=1697850 J/s=1697850 W=1697.85 kW

Actual output power requirement = theoretical power / efficiency

= 1697.850.78 kW=2176.73 kW

Interpretation Introduction

(d)

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 816.51 kW.

Temperature of exhaust stream: 220 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 = 450⁰C, P1 =8 bar, n˙ = 100mol/s, P2 =2 bar, η =0.85

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 450⁰C and P1 = 8 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.159 kJ/kg K

Specific enthalpy, H1 :451.54 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :220⁰C

At this exhaust temperature, enthalpy, H2 : 203.67 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 203.67−451.54) kJ/kg= −247.87 kJ/kg= −247.87 kJ/kg × 28 kg/kmol=−6940.36 kJ/kmol=−6940.36 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 100 mol/s × 6940.36 J/mol=694036 J/s=694036 W=694.036 kW

Actual output power requirement = theoretical power / efficiency

= 694.0360.85 kW=816.51 kW

Interpretation Introduction

(e)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1973.86 Btu/s.

Temperature of exhaust stream: 352.13 ⁰F

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =900⁰F, P1 =95 psia, n˙ = 0.5 (lbmol)/s, P2 =15 psia, η =0.80

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 900⁰F and P1 = 95 psia inlet conditions for nitrogen,

Specific entropy, S1 : 1.737 Btu/lbm⁰R

Specific enthalpy, H1 : 209.55 Btu/lbm

Exhaust pressure is 15 psia.

To have the same specific entropy, exhaust temperature, T2 :352.13⁰F= 178⁰C

At this exhaust temperature, enthalpy, H2 : 68.56 Btu/lbm

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 68.56−209.55) Btu/lbm= −140.99Btu/lbm= −140.99Btu/lbm× 28 lbm/lbmol=−3947.72 Btu/lbmol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 0.5 lbmol/s × 3947.72 Btu/lbmol=1973.86 Btu/s=2082.53 kW

Actual output power requirement = theoretical power / efficiency

= 2082.530.8 kW=2603.16 kW

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Answer 4

Question

Chapter 7, Problem 7.27P

Interpretation Introduction

(a)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2218.23 kW.

Temperature of exhaust stream: 186⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =480⁰C, P1 =6 bar, n˙ = 200 mol/s, P2 =1 bar, η =0.8

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =480 ⁰C and P1 = 6 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.29 kJ/kg K

Specific enthalpy, H1 : 484.75 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :186 ⁰C

At this exhaust temperature, enthalpy, H2 : 167.86 kJ/kgTheoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 167.86−484.75) kJ/kg= −316.89 kJ/kg=−316.89 kJ/kg × 28 kg/kmol=−8872.92 kJ/kmol=−8872.92 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 200 mol/s × 8872.92 J/mol=1774584 J/s=1774584 W=1774.58 kW

Actual output power requirement = theoretical power / efficiency

= 1774.580.8 kW=2218.23 kW

Interpretation Introduction

(b)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1451.75 kW.

Temperature of exhaust stream: 157 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =400⁰C, P1 =5 bar, n˙ = 150mol/s, P2 =1 bar, η =0.75

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 400⁰C and P1 =5 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.22 kJ/kg K

Specific enthalpy, H1 :396.68 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :157⁰C

At this exhaust temperature, enthalpy, H2 : 137.44 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

= ( 137.44−396.68) kJ/kg= −259.24 kJ/kg= −259.24 kJ/kg × 28 kg/kmol= −7258.72 kJ/kmol= −7258.72 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 150 mol/s × 7258.72 J/mol=1088808 J/s=1088808 W=1088.81 kW

Actual output power requirement = theoretical power / efficiency

= 1088.810.75 kW=1451.75 kW

Interpretation Introduction

(c)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2176.73 kW.

Temperature of exhaust stream: 179 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =500⁰C, P1 =7 bar, n˙ = 175mol/s, P2 =1 bar, η =0.78

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =500⁰C and P1 =7 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.273 kJ/kg K

Specific enthalpy, H1 :507.01 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :179⁰C

At this exhaust temperature, enthalpy, H2 : 160.51 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 160.51−507.01) kJ/kg= −346.5 kJ/kg= −346.5 kJ/kg × 28 kg/kmol=−9702 kJ/kmol=−9702 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 175 mol/s ×9702 J/mol=1697850 J/s=1697850 W=1697.85 kW

Actual output power requirement = theoretical power / efficiency

= 1697.850.78 kW=2176.73 kW

Interpretation Introduction

(d)

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 816.51 kW.

Temperature of exhaust stream: 220 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 = 450⁰C, P1 =8 bar, n˙ = 100mol/s, P2 =2 bar, η =0.85

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 450⁰C and P1 = 8 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.159 kJ/kg K

Specific enthalpy, H1 :451.54 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :220⁰C

At this exhaust temperature, enthalpy, H2 : 203.67 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 203.67−451.54) kJ/kg= −247.87 kJ/kg= −247.87 kJ/kg × 28 kg/kmol=−6940.36 kJ/kmol=−6940.36 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 100 mol/s × 6940.36 J/mol=694036 J/s=694036 W=694.036 kW

Actual output power requirement = theoretical power / efficiency

= 694.0360.85 kW=816.51 kW

Interpretation Introduction

(e)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1973.86 Btu/s.

Temperature of exhaust stream: 352.13 ⁰F

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =900⁰F, P1 =95 psia, n˙ = 0.5 (lbmol)/s, P2 =15 psia, η =0.80

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 900⁰F and P1 = 95 psia inlet conditions for nitrogen,

Specific entropy, S1 : 1.737 Btu/lbm⁰R

Specific enthalpy, H1 : 209.55 Btu/lbm

Exhaust pressure is 15 psia.

To have the same specific entropy, exhaust temperature, T2 :352.13⁰F= 178⁰C

At this exhaust temperature, enthalpy, H2 : 68.56 Btu/lbm

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 68.56−209.55) Btu/lbm= −140.99Btu/lbm= −140.99Btu/lbm× 28 lbm/lbmol=−3947.72 Btu/lbmol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 0.5 lbmol/s × 3947.72 Btu/lbmol=1973.86 Btu/s=2082.53 kW

Actual output power requirement = theoretical power / efficiency

= 2082.530.8 kW=2603.16 kW

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Answer 5

Chapter 7, Problem 7.27P

Interpretation Introduction

(a)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2218.23 kW.

Temperature of exhaust stream: 186⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =480⁰C, P1 =6 bar, n˙ = 200 mol/s, P2 =1 bar, η =0.8

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =480 ⁰C and P1 = 6 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.29 kJ/kg K

Specific enthalpy, H1 : 484.75 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :186 ⁰C

At this exhaust temperature, enthalpy, H2 : 167.86 kJ/kgTheoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 167.86−484.75) kJ/kg= −316.89 kJ/kg=−316.89 kJ/kg × 28 kg/kmol=−8872.92 kJ/kmol=−8872.92 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 200 mol/s × 8872.92 J/mol=1774584 J/s=1774584 W=1774.58 kW

Actual output power requirement = theoretical power / efficiency

= 1774.580.8 kW=2218.23 kW

Interpretation Introduction

(b)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1451.75 kW.

Temperature of exhaust stream: 157 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =400⁰C, P1 =5 bar, n˙ = 150mol/s, P2 =1 bar, η =0.75

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 400⁰C and P1 =5 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.22 kJ/kg K

Specific enthalpy, H1 :396.68 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :157⁰C

At this exhaust temperature, enthalpy, H2 : 137.44 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

= ( 137.44−396.68) kJ/kg= −259.24 kJ/kg= −259.24 kJ/kg × 28 kg/kmol= −7258.72 kJ/kmol= −7258.72 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 150 mol/s × 7258.72 J/mol=1088808 J/s=1088808 W=1088.81 kW

Actual output power requirement = theoretical power / efficiency

= 1088.810.75 kW=1451.75 kW

Interpretation Introduction

(c)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2176.73 kW.

Temperature of exhaust stream: 179 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =500⁰C, P1 =7 bar, n˙ = 175mol/s, P2 =1 bar, η =0.78

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =500⁰C and P1 =7 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.273 kJ/kg K

Specific enthalpy, H1 :507.01 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :179⁰C

At this exhaust temperature, enthalpy, H2 : 160.51 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 160.51−507.01) kJ/kg= −346.5 kJ/kg= −346.5 kJ/kg × 28 kg/kmol=−9702 kJ/kmol=−9702 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 175 mol/s ×9702 J/mol=1697850 J/s=1697850 W=1697.85 kW

Actual output power requirement = theoretical power / efficiency

= 1697.850.78 kW=2176.73 kW

Interpretation Introduction

(d)

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 816.51 kW.

Temperature of exhaust stream: 220 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 = 450⁰C, P1 =8 bar, n˙ = 100mol/s, P2 =2 bar, η =0.85

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 450⁰C and P1 = 8 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.159 kJ/kg K

Specific enthalpy, H1 :451.54 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :220⁰C

At this exhaust temperature, enthalpy, H2 : 203.67 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 203.67−451.54) kJ/kg= −247.87 kJ/kg= −247.87 kJ/kg × 28 kg/kmol=−6940.36 kJ/kmol=−6940.36 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 100 mol/s × 6940.36 J/mol=694036 J/s=694036 W=694.036 kW

Actual output power requirement = theoretical power / efficiency

= 694.0360.85 kW=816.51 kW

Interpretation Introduction

(e)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1973.86 Btu/s.

Temperature of exhaust stream: 352.13 ⁰F

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =900⁰F, P1 =95 psia, n˙ = 0.5 (lbmol)/s, P2 =15 psia, η =0.80

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 900⁰F and P1 = 95 psia inlet conditions for nitrogen,

Specific entropy, S1 : 1.737 Btu/lbm⁰R

Specific enthalpy, H1 : 209.55 Btu/lbm

Exhaust pressure is 15 psia.

To have the same specific entropy, exhaust temperature, T2 :352.13⁰F= 178⁰C

At this exhaust temperature, enthalpy, H2 : 68.56 Btu/lbm

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 68.56−209.55) Btu/lbm= −140.99Btu/lbm= −140.99Btu/lbm× 28 lbm/lbmol=−3947.72 Btu/lbmol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 0.5 lbmol/s × 3947.72 Btu/lbmol=1973.86 Btu/s=2082.53 kW

Actual output power requirement = theoretical power / efficiency

= 2082.530.8 kW=2603.16 kW

Answer 6

Chapter 7, Problem 7.27P

Interpretation Introduction

(a)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2218.23 kW.

Temperature of exhaust stream: 186⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =480⁰C, P1 =6 bar, n˙ = 200 mol/s, P2 =1 bar, η =0.8

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =480 ⁰C and P1 = 6 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.29 kJ/kg K

Specific enthalpy, H1 : 484.75 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :186 ⁰C

At this exhaust temperature, enthalpy, H2 : 167.86 kJ/kgTheoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 167.86−484.75) kJ/kg= −316.89 kJ/kg=−316.89 kJ/kg × 28 kg/kmol=−8872.92 kJ/kmol=−8872.92 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 200 mol/s × 8872.92 J/mol=1774584 J/s=1774584 W=1774.58 kW

Actual output power requirement = theoretical power / efficiency

= 1774.580.8 kW=2218.23 kW

Answer 7

Chapter 7, Problem 7.27P

Interpretation Introduction

(a)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Answer 8

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2218.23 kW.

Temperature of exhaust stream: 186⁰C.

Answer 9

Expert Solution

Answer 10

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =480⁰C, P1 =6 bar, n˙ = 200 mol/s, P2 =1 bar, η =0.8

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =480 ⁰C and P1 = 6 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.29 kJ/kg K

Specific enthalpy, H1 : 484.75 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :186 ⁰C

At this exhaust temperature, enthalpy, H2 : 167.86 kJ/kgTheoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 167.86−484.75) kJ/kg= −316.89 kJ/kg=−316.89 kJ/kg × 28 kg/kmol=−8872.92 kJ/kmol=−8872.92 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 200 mol/s × 8872.92 J/mol=1774584 J/s=1774584 W=1774.58 kW

Actual output power requirement = theoretical power / efficiency

= 1774.580.8 kW=2218.23 kW

Answer 13

Interpretation Introduction

(b)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1451.75 kW.

Temperature of exhaust stream: 157 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =400⁰C, P1 =5 bar, n˙ = 150mol/s, P2 =1 bar, η =0.75

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 400⁰C and P1 =5 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.22 kJ/kg K

Specific enthalpy, H1 :396.68 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :157⁰C

At this exhaust temperature, enthalpy, H2 : 137.44 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

= ( 137.44−396.68) kJ/kg= −259.24 kJ/kg= −259.24 kJ/kg × 28 kg/kmol= −7258.72 kJ/kmol= −7258.72 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 150 mol/s × 7258.72 J/mol=1088808 J/s=1088808 W=1088.81 kW

Actual output power requirement = theoretical power / efficiency

= 1088.810.75 kW=1451.75 kW

Answer 14

Interpretation Introduction

(b)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Answer 15

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1451.75 kW.

Temperature of exhaust stream: 157 ⁰C.

Answer 16

Expert Solution

Answer 17

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =400⁰C, P1 =5 bar, n˙ = 150mol/s, P2 =1 bar, η =0.75

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 400⁰C and P1 =5 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.22 kJ/kg K

Specific enthalpy, H1 :396.68 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :157⁰C

At this exhaust temperature, enthalpy, H2 : 137.44 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

= ( 137.44−396.68) kJ/kg= −259.24 kJ/kg= −259.24 kJ/kg × 28 kg/kmol= −7258.72 kJ/kmol= −7258.72 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 150 mol/s × 7258.72 J/mol=1088808 J/s=1088808 W=1088.81 kW

Actual output power requirement = theoretical power / efficiency

= 1088.810.75 kW=1451.75 kW

Answer 20

Interpretation Introduction

(c)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2176.73 kW.

Temperature of exhaust stream: 179 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =500⁰C, P1 =7 bar, n˙ = 175mol/s, P2 =1 bar, η =0.78

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =500⁰C and P1 =7 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.273 kJ/kg K

Specific enthalpy, H1 :507.01 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :179⁰C

At this exhaust temperature, enthalpy, H2 : 160.51 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 160.51−507.01) kJ/kg= −346.5 kJ/kg= −346.5 kJ/kg × 28 kg/kmol=−9702 kJ/kmol=−9702 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 175 mol/s ×9702 J/mol=1697850 J/s=1697850 W=1697.85 kW

Actual output power requirement = theoretical power / efficiency

= 1697.850.78 kW=2176.73 kW

Answer 21

Interpretation Introduction

(c)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Answer 22

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 2176.73 kW.

Temperature of exhaust stream: 179 ⁰C.

Answer 23

Expert Solution

Answer 24

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =500⁰C, P1 =7 bar, n˙ = 175mol/s, P2 =1 bar, η =0.78

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 =500⁰C and P1 =7 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.273 kJ/kg K

Specific enthalpy, H1 :507.01 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :179⁰C

At this exhaust temperature, enthalpy, H2 : 160.51 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 160.51−507.01) kJ/kg= −346.5 kJ/kg= −346.5 kJ/kg × 28 kg/kmol=−9702 kJ/kmol=−9702 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 175 mol/s ×9702 J/mol=1697850 J/s=1697850 W=1697.85 kW

Actual output power requirement = theoretical power / efficiency

= 1697.850.78 kW=2176.73 kW

Answer 27

Interpretation Introduction

(d)

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 816.51 kW.

Temperature of exhaust stream: 220 ⁰C.

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 = 450⁰C, P1 =8 bar, n˙ = 100mol/s, P2 =2 bar, η =0.85

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 450⁰C and P1 = 8 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.159 kJ/kg K

Specific enthalpy, H1 :451.54 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :220⁰C

At this exhaust temperature, enthalpy, H2 : 203.67 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 203.67−451.54) kJ/kg= −247.87 kJ/kg= −247.87 kJ/kg × 28 kg/kmol=−6940.36 kJ/kmol=−6940.36 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 100 mol/s × 6940.36 J/mol=694036 J/s=694036 W=694.036 kW

Actual output power requirement = theoretical power / efficiency

= 694.0360.85 kW=816.51 kW

Answer 28

Interpretation Introduction

(d)

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Answer 29

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 816.51 kW.

Temperature of exhaust stream: 220 ⁰C.

Answer 30

Expert Solution

Answer 31

Expert Solution

Answer 32

Expert Solution

Answer 33

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 = 450⁰C, P1 =8 bar, n˙ = 100mol/s, P2 =2 bar, η =0.85

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 450⁰C and P1 = 8 bar inlet conditions for nitrogen,

Specific entropy, S1 : 7.159 kJ/kg K

Specific enthalpy, H1 :451.54 kJ/kg

Exhaust pressure is 1 bar.

To have the same specific entropy, exhaust temperature, T2 :220⁰C

At this exhaust temperature, enthalpy, H2 : 203.67 kJ/kg

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 203.67−451.54) kJ/kg= −247.87 kJ/kg= −247.87 kJ/kg × 28 kg/kmol=−6940.36 kJ/kmol=−6940.36 J/mol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 100 mol/s × 6940.36 J/mol=694036 J/s=694036 W=694.036 kW

Actual output power requirement = theoretical power / efficiency

= 694.0360.85 kW=816.51 kW

Answer 34

Interpretation Introduction

(e)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1973.86 Btu/s.

Temperature of exhaust stream: 352.13 ⁰F

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =900⁰F, P1 =95 psia, n˙ = 0.5 (lbmol)/s, P2 =15 psia, η =0.80

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 900⁰F and P1 = 95 psia inlet conditions for nitrogen,

Specific entropy, S1 : 1.737 Btu/lbm⁰R

Specific enthalpy, H1 : 209.55 Btu/lbm

Exhaust pressure is 15 psia.

To have the same specific entropy, exhaust temperature, T2 :352.13⁰F= 178⁰C

At this exhaust temperature, enthalpy, H2 : 68.56 Btu/lbm

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 68.56−209.55) Btu/lbm= −140.99Btu/lbm= −140.99Btu/lbm× 28 lbm/lbmol=−3947.72 Btu/lbmol

Negative sign implies work done by expander.

Total theoretical output power requirement = molar flow rate x theoretical power

= 0.5 lbmol/s × 3947.72 Btu/lbmol=1973.86 Btu/s=2082.53 kW

Actual output power requirement = theoretical power / efficiency

= 2082.530.8 kW=2603.16 kW

Answer 35

Interpretation Introduction

(e)

Interpretation:

Power output of the expander and the temperature of the exhaust stream for the given set of operating conditions.

Concept Introduction:

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

Answer 36

Expert Solution

Answer to Problem 7.27P

Power output of the expander: 1973.86 Btu/s.

Temperature of exhaust stream: 352.13 ⁰F

Answer 37

Expert Solution

Answer 38

Expert Solution

Answer 39

Expert Solution

Answer 40

Explanation of Solution

Given Information:

An expander operates adiabatically with nitrogen. Following conditions are given:

T1 =900⁰F, P1 =95 psia, n˙ = 0.5 (lbmol)/s, P2 =15 psia, η =0.80

Here, P1,T1are inlet pressure and temperature respectively and n˙ is the molar flow rate. P2 is the exhaust pressure and η is the efficiency of the expander.

Expansion through an expander is an isentropic process which implies entropy at the inlet and exhaust will be the same. For the given inlet pressure and temperature condition, specific entropy of nitrogen will be determined. Then exhaust temperature will be determined for the given outlet pressure condition.

To calculate power output, specific enthalpy of nitrogen will be calculated at the given inlet and exhaust pressure and temperature condition respectively. Theoretical power will be calculated equal to the difference in specific enthalpy at inlet and exhaust condition respectively. Actual power output will be calculated by dividing theoretical power by the given expander efficiency. It is to be noted that molecular weight of nitrogen is 28.

Calculation:

At T1 = 900⁰F and P1 = 95 psia inlet conditions for nitrogen,

Specific entropy, S1 : 1.737 Btu/lbm⁰R

Specific enthalpy, H1 : 209.55 Btu/lbm

Exhaust pressure is 15 psia.

To have the same specific entropy, exhaust temperature, T2 :352.13⁰F= 178⁰C

At this exhaust temperature, enthalpy, H2 : 68.56 Btu/lbm

Theoretical work for adiabatic expansion process, W˙ = ( H2 - H1 ) kJ/kg

=( 68.56−209.55) Btu/lbm= −140.99Btu/lbm= −140.99Btu/lbm× 28 lbm/lbmol=−3947.72 Btu/lbmol