Homework Help is Here – Start Your Trial Now!
Engineering
Chemical Engineering
A multi-unit process first combusts propane and then removes water from the exhaust stream. The process is designed to run at steady state. The company designing the process knows that they want to burn 70% of the propane (i.e. yield of CO₂ is only 70% of complete combustion of propane). The simple combustion reaction for propane is given below. Use the shortcut method to calculate the Degrees of Freedom around the Combustion Chamber. Stream A Rate: A-0.4 mol/hour Composition: Oxygen: A, 22.8% Nitrogen: AN-76.4% Water: Aw=?? Stream B Rate: B=0.01 mol/hour Composition: Propane: B, 100% C3H8 +502 4H20 + 3C02 Combustion Chamber Stream C Rate: C= Composition: Oxygen: Co= Nitrogen: CN= Water: Cw= Propane: C₂= CO₂: CC= Stream D Rate: D=?? Composition: Dw-100% Condenser Stream E Rate: E = ??mol/s Composition: Oxygen: E- Nitrogen: E= Water: Ew=2% Propane: E= CO₂: Ec=

A multi-unit process first combusts propane and then removes water from the exhaust stream. The process is designed to run at steady state. The company designing the process knows that they want to burn 70% of the propane (i.e. yield of CO₂ is only 70% of complete combustion of propane). The simple combustion reaction for propane is given below. Use the shortcut method to calculate the Degrees of Freedom around the Combustion Chamber. Stream A Rate: A-0.4 mol/hour Composition: Oxygen: A, 22.8% Nitrogen: AN-76.4% Water: Aw=?? Stream B Rate: B=0.01 mol/hour Composition: Propane: B, 100% C3H8 +502 4H20 + 3C02 Combustion Chamber Stream C Rate: C= Composition: Oxygen: Co= Nitrogen: CN= Water: Cw= Propane: C₂= CO₂: CC= Stream D Rate: D=?? Composition: Dw-100% Condenser Stream E Rate: E = ??mol/s Composition: Oxygen: E- Nitrogen: E= Water: Ew=2% Propane: E= CO₂: Ec=

Introduction to Chemical Engineering Thermodynamics
Introduction to Chemical Engineering Thermodynamics
8th Edition
ISBN:9781259696527
Author:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Chapter1: Introduction
Section: Chapter Questions
Problem 1.1P
See similar textbooks
icon
Related questions
Question

A multi-unit process first combusts propane and then removes water from the exhaust stream. The 
process is designed to run at steady state. The company designing the process knows that they want to 
burn 70% of the propane (i.e. yield of CO2 is only 70% of complete combustion of propane). The simple 
combustion reaction for propane is given below. 
Use the shortcut method to calculate the Degrees of Freedom around the Combustion Chamber. 

A multi-unit process first combusts propane and then removes water from the exhaust stream. The process is designed to run at steady state. The company designing the process knows that they want to burn 70% of the propane (i.e. yield of CO₂ is only 70% of complete combustion of propane). The simple combustion reaction for propane is given below. Use the shortcut method to calculate the Degrees of Freedom around the Combustion Chamber. Stream A Rate: A = 0.4 mol/hour Composition: Oxygen: A, 22.8% Nitrogen: AN = 76.4% Water: Aw = ?? Stream B Rate: B=0.01 mol/hour Composition: Propane: B, 100% C3H8 +502 →→ 4H₂O + 3C02 Combustion Chamber Stream C Rate: C= Composition: Oxygen: Co= Nitrogen: CN= Water: Cw= Propane: Cp = CO₂: CC= Stream D Rate: D= ?? Composition: Dw= 100% Condenser Stream E Rate: E = ??mol/s Composition: Oxygen: E= Nitrogen: EN= Water: Ew=2% Propane: Ep = CO₂: Ec=
Transcribed Image Text:A multi-unit process first combusts propane and then removes water from the exhaust stream. The process is designed to run at steady state. The company designing the process knows that they want to burn 70% of the propane (i.e. yield of CO₂ is only 70% of complete combustion of propane). The simple combustion reaction for propane is given below. Use the shortcut method to calculate the Degrees of Freedom around the Combustion Chamber. Stream A Rate: A = 0.4 mol/hour Composition: Oxygen: A, 22.8% Nitrogen: AN = 76.4% Water: Aw = ?? Stream B Rate: B=0.01 mol/hour Composition: Propane: B, 100% C3H8 +502 →→ 4H₂O + 3C02 Combustion Chamber Stream C Rate: C= Composition: Oxygen: Co= Nitrogen: CN= Water: Cw= Propane: Cp = CO₂: CC= Stream D Rate: D= ?? Composition: Dw= 100% Condenser Stream E Rate: E = ??mol/s Composition: Oxygen: E= Nitrogen: EN= Water: Ew=2% Propane: Ep = CO₂: Ec=
Expert Solution
steps

Step by step

Solved in 3 steps with 2 images

SEE SOLUTIONCheck out a sample Q&A here
Blurred answer
Recommended textbooks for you
Introduction to Chemical Engineering Thermodynami…
Introduction to Chemical Engineering Thermodynami…
Chemical Engineering
ISBN:
9781259696527
Author:
J.M. Smith Termodinamica en ingenieria quimica, Hendrick C Van Ness, Michael Abbott, Mark Swihart
Publisher:
McGraw-Hill Education
Elementary Principles of Chemical Processes, Bind…
Elementary Principles of Chemical Processes, Bind…
Chemical Engineering
ISBN:
9781118431221
Author:
Richard M. Felder, Ronald W. Rousseau, Lisa G. Bullard
Publisher:
WILEY
Elements of Chemical Reaction Engineering (5th Ed…
Elements of Chemical Reaction Engineering (5th Ed…
Chemical Engineering
ISBN:
9780133887518
Author:
H. Scott Fogler
Publisher:
Prentice Hall
Process Dynamics and Control, 4e
Process Dynamics and Control, 4e
Chemical Engineering
ISBN:
9781119285915
Author:
Seborg
Publisher:
WILEY
Industrial Plastics: Theory and Applications
Industrial Plastics: Theory and Applications
Chemical Engineering
ISBN:
9781285061238
Author:
Lokensgard, Erik
Publisher:
Delmar Cengage Learning
Unit Operations of Chemical Engineering
Unit Operations of Chemical Engineering
Chemical Engineering
ISBN:
9780072848236
Author:
Warren McCabe, Julian C. Smith, Peter Harriott
Publisher:
McGraw-Hill Companies, The
SEE MORE TEXTBOOKS