A steam boiler heats liquid water at 200°C to superheated steam at 4 MPa and 400°C. Methane fuel (CH4) is burned at atmospheric pressure with 50 percent excess air. The fuel and air enter the boiler at 25°C and the products of combustion leave at 227°C. Calculate (a) the amount of steam generated per unit of fuel mass burned, (b) the change in the exergy of the combustion streams, in kJ/kg fuel, (c) the change in the exergy of the steam stream, in kJ/kg steam, and (d) the lost work potential, in kJ/kg fuel. Take T0 = 25°C.
(a)
The amount of steam generated per unit of fuel mass burned.
Answer to Problem 112RP
The amount of steam generated per unit of fuel mass burned is
Explanation of Solution
Write the energy balance equation using steady-flow equation.
Here, the total energy entering the system is
Substitute
Here, the enthalpy of formation for product is
Calculate the molar mass of the
Here, the number of carbon atoms is
Determine the amount of steam generated per unit mass of fuel burned from an energy balance.
Here, the mass of the steam is
Conclusion:
Perform unit conversion of temperature at state 1 from degree Celsius to Kelvin.
For air temperature enter in the machine,
For air temperature exit from the machine,
Write the combustion equation of 1 kmol for
Here, liquid methane is
Refer Appendix Table A-18, A-19, A-20, and A-23, obtain the enthalpy of formation, at 298 K , and 500 K for
Substance | |||
-74,850 | --- | --- | |
0 | 8682 | 14,770 | |
0 | 8669 | 14,581 | |
-241820 | 9904 | 16,828 | |
-393,520 | 9364 | 17,678 |
Refer Equation (V), and write the number of moles of reactants.
Here, number of moles of reactant methane, oxygen and nitrogen is
Refer Equation (V), and write the number of moles of products.
Here, number of moles of product carbon dioxide, water, oxygen and nitrogen is
Substitute the value of substance in Equation (II).
Therefore the heat transfer for
Substitute 1 for
Calculate the heat loss per unit mass of the fuel.
From the table A-4, “Saturated water-Temperature” obtain the value of the saturated enthalpy and entropy of liquid at the
From the table A-6, “Superheated water” obtain the value of the enthalpy and entropy at the
Substitute
Thus, the amount of steam generated per unit of fuel mass burned is
(b)
The change in the exergy of the combustion steams, in
Answer to Problem 112RP
The change in the exergy of the combustion steams, in
Explanation of Solution
Write the expression for entropy generation during this process.
Write the combustion equation of Equation (VI)
Here, the entropy of the product is
Determine the entropy at the partial pressure of the components.
Here, the partial pressure is
Write the expression for exergy change of the combustion steam is equal to the exergy destruction.
Here, the thermodynamic temperature of the surrounding is
Conclusion:
Refer Equation (VIII) for reactant and product to calculation the entropy in tabular form as:
For reactant entropy,
Substance |
(T, 1 atm) | ||||
1 | --- | 186.16 | --- | 186.16 | |
3 | 0.21 | 205.04 | -12.98 | 654.06 | |
11.28 | 0.79 | 191.61 | -1.960 | 2183.47 | |
For product entropy,
Substance |
(T, 1 atm) | ||||
1 | 0.0654 | 234.814 | -22.67 | 257.48 | |
2 | 0.1309 | 206.413 | -16.91 | 446.65 | |
1 | 0.0654 | 220.589 | -22.67 | 243.26 | |
11.28 | 0.7382 | 206.630 | -2.524 | 2359.26 | |
Substitute
Substitute
Calculate the exergy destruction per unit mass of the basis.
Thus, the change in the exergy of the combustion steams, in
(c)
The exergy change of the steam, in
Answer to Problem 112RP
The exergy change of the steam, in
Explanation of Solution
Determine the exergy change of the steam stream.
Here, the final enthalpy is
Conclusion:
Substitute
Thus, the exergy change of the steam, in
(d)
The lost work potential, in
Answer to Problem 112RP
The lost work potential, in
Explanation of Solution
Determine the lost work potential is the negative of the net exergy change both streams.
Conclusion:
Substitute
Thus, the lost work potential, in
Want to see more full solutions like this?
Chapter 15 Solutions
Thermodynamics: An Engineering Approach
- A boiler delivers steam at 100 bar and 500 C. the feed water inlet temperature is 160 C. the steam is produced at the rate of 100 tonnes/h and the boiler efficiency is 88%. Estimate the fuel burning rate in kg/h if the calorific value of the fuel is 21MJ/kgarrow_forwardINTERNAL COMBUSTION.arrow_forwardIn a gas turbine unit, air enters the combustion chamber at 550 kpa 275oC and 45 m/s. The products of combustion leave the combustor at 511 kpa, 1000oC and 180 m/s. Liquid fuel enters with a heating value of 43000 kJ/kg and fuel-air ratio is 0.0229 by mass. Take cp = 1.00 kJ/kg-K for air and cp = 1.08 kJ/kg-K for flue gas. Determine the combustor efficiency?arrow_forward
- 8 An SI engine operating on stoichiometric propane fuel burns 0.00005 kg of fuel in each cylinder during each cycle with a combustion efficiency of 95%. When combustion starts at the end of compression, the temperature and pressure in the cylinder are T 700 K and P = 2000 kPa. Exhaust temperature leaving the cylinder after combustion is Tex = 1200 K. Calculate: 1. combustion heat input into each cylinder during each cycle using Q = E N,h; - E N,h, PROD REACT 2. heat input using Qin = nm,QLHV Indicate the source of the Tables of Properties used in your calculation. Assume Ah; = 29,711k] /kmol for %3D propane gas.arrow_forwardA boiler delivers steam at 100 bar and 500 C. the feed water inlet temperature is 160 C. the steam is produced at the rate of 100 tonnes/h and the boiler efficiency is 88%. Estimate the fuel burning rate in kg/h if the calorific value of the fuel is 21MJ/kgarrow_forwardShow transcribed data A coal used in a boiler contains 80% carbon, 10% hydrogen, 2% oxygen and 4% sulfur. There are 24% excess air needed for complete combustion. The supply air is at standard atmospheric condition at 24 degrees C. The boiler generates steam at superheat condition with a pressure of 8.0 mpa and temperature of 420 degrees C. The water is supplied to the boiler at 24 kg per minute with a temperature of 92.4 degrees C. Due to boiler age, it has only 92.4% efficiency. Compute the actual amount of air in m3/hr needed to burn the fuel if the feedwater losses 8% of its mass due to evaporation.arrow_forward
- A boiler furnace releases 10 400 kj of heat for each kg of fuel burned and produces dry staturated steam at 14000 kpa from feedwater at 200 degrees celcius . How many kg of steam will be produced for each kg of fuel burned if the boiler had an efficiency of 66% ? .arrow_forwardThe figure shows a PV diagram for an engine that uses a monatomic ideal gas as the working substance. The temperature at point A is 470.0 K.(a) How much net work does this engine do per cycle?(b) Assuming that the efficiency of the engine is 0.444, what is the heat input into the gas per cycle?(c) How much heat is exhausted per cycle?(d) How many moles of gas are used in this engine?(e) What is the total change in internal energy of this gas in one cycle?arrow_forwardThermodynamics: Solve using function of specific heat table (A2-c)arrow_forward
- A coal-fired boiler is used to supply 18 000 kg/hr of steam at 12.5 bar with a dryness fraction of 0.97 to a dyehouse. Feedwater temperature is 105 °C with coal supplied at 2 040 kg per hour to the combustion chamber. Assuming the calorific value of coal to be 27.4 MJ / kg and the specific heat capacity of feedwater to be 4.18 kJ/kg K , determine: the heat rate in kJ/hr the thermal efficiency of the boiler Complaints are received from the neighbourhood about the deposit of fly-ash and particulate matter on houses and buildings. Discuss briefly ONE POSSIBLE cause of this problem referring to the boiler operation and maintenance. Suggest TWO ways of addressing the above problem.arrow_forwardThermodynamics: Calculate using average specific heat table (A2-b)arrow_forwardQIAt the commencement of the compression stroke, the cylinder of an oil engine is charged with air at 96.5kPa and 65°C. Compression takes place to 1/14th of the original volume according to the law PV.35 =C. Fuel the injected, the mass of the fuel injected being 1/40th of that of the air in the cylinder, and combustion takes place at constant pressure. Taking t5he calorific value of the oil as 44000OKJ/kg, determine a- the theoretical pressure and temperature after compression b- the theoretical temperature after combustion c- the fraction of the stroke at which combustion is theoretically complete, cp=1.003KJ/kg.K (3400kPa, 579°C, 1649°C, 0.0967)arrow_forward
- Elements Of ElectromagneticsMechanical EngineeringISBN:9780190698614Author:Sadiku, Matthew N. O.Publisher:Oxford University PressMechanics of Materials (10th Edition)Mechanical EngineeringISBN:9780134319650Author:Russell C. HibbelerPublisher:PEARSONThermodynamics: An Engineering ApproachMechanical EngineeringISBN:9781259822674Author:Yunus A. Cengel Dr., Michael A. BolesPublisher:McGraw-Hill Education
- Control Systems EngineeringMechanical EngineeringISBN:9781118170519Author:Norman S. NisePublisher:WILEYMechanics of Materials (MindTap Course List)Mechanical EngineeringISBN:9781337093347Author:Barry J. Goodno, James M. GerePublisher:Cengage LearningEngineering Mechanics: StaticsMechanical EngineeringISBN:9781118807330Author:James L. Meriam, L. G. Kraige, J. N. BoltonPublisher:WILEY