thermochap9lecture. Heat and temperature 12

CHAPTER 9
GAS POWER CYCLES
Lecture slides by
Mehmet Kanoglu
Copyright © The McGraw-Hill Education. Permission required for reproduction or display.
Thermodynamics: An Engineering Approach
8th Edition
Yunus A. Çengel, Michael A. Boles
McGraw-Hill, 2015

2
Objectives
• Evaluate the performance of gas power cycles for which the
working fluid remains a gas throughout the entire cycle.
• Develop simplifying assumptions applicable to gas power
cycles.
• Review the operation of reciprocating engines.
• Analyze both closed and open gas power cycles.
• Solve problems based on the Otto, Diesel, Stirling, and
Ericsson cycles.
• Solve problems based on the Brayton cycle; the Brayton cycle
with regeneration; and the Brayton cycle with intercooling,
reheating, and regeneration.
• Analyze jet-propulsion cycles.
• Identify simplifying assumptions for second-law analysis of
gas power cycles.
• Perform second-law analysis of gas power cycles.

3
BASIC CONSIDERATIONS IN THE
ANALYSIS OF POWER CYCLES
Most power-producing devices operate on cycles.
Ideal cycle: A cycle that resembles the actual cycle
closely but is made up totally of internally reversible
processes is called an.
Reversible cycles such as Carnot cycle have the
highest thermal efficiency of all heat engines operating
between the same temperature levels. Unlike ideal
cycles, they are totally reversible, and unsuitable as a
realistic model.
Thermal efficiency of
heat engines:

4
The ideal cycles are internally reversible, but, unlike the Carnot cycle, they are not
necessarily externally reversible.
Therefore, the thermal efficiency of an ideal cycle, in general, is less than that of a
totally reversible cycle operating between the same temperature limits.
However, it is still considerably higher than the thermal efficiency of an actual cycle
because of the idealizations utilized.

5
The idealizations and simplifications in the
analysis of power cycles:
1. The cycle does not involve any friction.
Therefore, the working fluid does not
experience any pressure drop as it flows in
pipes or devices such as heat exchangers.
2. All expansion and compression processes
take place in a quasi-equilibrium manner.
3. The pipes connecting the various
components of a system are well
insulated, and heat transfer through them
is negligible.
On a T-s diagram, the ratio of the
area enclosed by the cyclic curve to
the area under the heat-addition
process curve represents the thermal
efficiency of the cycle.
Any modification that increases the
ratio of these two areas will also
increase the thermal efficiency of the
cycle.

6
THE CARNOT CYCLE AND ITS
VALUE IN ENGINEERING
The Carnot cycle is composed of four totally reversible
processes: isothermal heat addition, isentropic
expansion, isothermal heat rejection, and isentropic
compression.
For both ideal and actual cycles: Thermal efficiency
increases with an increase in the average temperature at
which heat is supplied to the system or with a decrease
in the average temperature at which heat is rejected
from the system.
A steady-flow Carnot engine.

7
Derivation of the
Efficiency of the
Carnot Cycle

8
AIR-STANDARD ASSUMPTIONS
Air-standard assumptions:
1. The working fluid is air, which
continuously circulates in a closed loop
and always behaves as an ideal gas.
2. All the processes that make up the
cycle are internally reversible.
3. The combustion process is replaced by
a heat-addition process from an
external source.
4. The exhaust process is replaced by a
heat-rejection process that restores the
working fluid to its initial state.
Cold-air-standard assumptions: When the working fluid is considered
to be air with constant specific heats at room temperature (25°C).
Air-standard cycle: A cycle for which the air-standard assumptions are
applicable.

9
AN OVERVIEW OF RECIPROCATING ENGINES
• Spark-ignition (SI) engines
• Compression-ignition (CI) engines
Compression ratio

10
Mean effective pressure
The mean effective pressure can be used as
a parameter to compare the performances of
reciprocating engines of equal size.
The engine with a larger value of MEP
delivers more net work per cycle and thus
performs better.

11
OTTO CYCLE: THE IDEAL CYCLE FOR SPARK-IGNITION ENGINES

12
Schematic of a two-stroke
reciprocating engine.
The two-stroke engines are
generally less efficient than
their four-stroke counterparts
but they are relatively simple
and inexpensive, and they
have high power-to-weight
and power-to-volume ratios.
Four-stroke cycle
1 cycle = 4 stroke = 2 revolution
Two-stroke cycle
1 cycle = 2 stroke = 1 revolution

14
Air enters the cylinder through the open
intake valve at atmospheric pressure P0
during process 0-1 as the piston moves from
TDC to BDC.
The intake valve is closed at state 1 and air is
compressed isentropically to state 2. Heat is
transferred at constant volume (process 2-3);
it is expanded isentropically to state 4; and
heat is rejected at constant volume (process
4-1).
Air is expelled through the open exhaust
valve (process 1-0).
Work interactions during intake and exhaust
cancel each other, and thus inclusion of the
intake and exhaust processes has no effect
on the net work output from the cycle.
However, when calculating power output from
the cycle during an ideal Otto cycle analysis,
we must consider the fact that the ideal Otto
cycle has four strokes just like actual four-
stroke spark-ignition engine.

15
In SI engines, the
compression ratio
is limited by
autoignition or
engine knock.

16
DIESEL CYCLE: THE IDEAL CYCLE
FOR COMPRESSION-IGNITION ENGINES
In diesel engines, only air is compressed during the
compression stroke, eliminating the possibility of autoignition
(engine knock). Therefore, diesel engines can be designed to
operate at much higher compression ratios than SI engines,
typically between 12 and 24.
1-2 isentropic
compression
2-3 constant-
volume heat
addition
3-4 isentropic
expansion
4-1 constant-
volume heat
rejection.

17
Thermal
efficiency of the
ideal Diesel cycle
as a function of
compression and
cutoff ratios
(k=1.4).
Cutoff
ratio
for the same compression ratio

18
Dual cycle: A more realistic ideal
cycle model for modern, high-speed
compression ignition engine.
In modern high-speed compression
ignition engines, fuel is injected into
the combustion chamber much
sooner compared to the early diesel
engines.
Fuel starts to ignite late in the
compression stroke, and
consequently part of the combustion
occurs almost at constant volume.
Fuel injection continues until the
piston reaches the top dead center,
and combustion of the fuel keeps
the pressure high well into the
expansion stroke.
Thus, the entire combustion process
can better be modeled as the
combination of constant-volume and
constant-pressure processes.

19
STIRLING AND ERICSSON CYCLES
Stirling cycle
1-2 T = constant expansion (heat
addition from the external source)
2-3 v = constant regeneration (internal
heat transfer from the working fluid
to the regenerator)
3-4 T = constant compression (heat
rejection to the external sink)
4-1 v = constant regeneration (internal
heat transfer from the regenerator
back to the working fluid)

20
T-s and P-v diagrams of Carnot, Stirling, and Ericsson cycles.

21
The Ericsson cycle is very much like the
Stirling cycle, except that the two constant-
volume processes are replaced by two
constant-pressure processes.
Both the Stirling and Ericsson cycles are
totally reversible, as is the Carnot cycle,
and thus:
The Stirling and Ericsson cycles
give a message: Regeneration
can increase efficiency.

22
BRAYTON CYCLE: THE IDEAL CYCLE FOR
GAS-TURBINE ENGINES
The combustion process is replaced by a constant-pressure heat-addition
process from an external source, and the exhaust process is replaced by a
constant-pressure heat-rejection process to the ambient air.
1-2 Isentropic compression (in a compressor)
2-3 Constant-pressure heat addition
3-4 Isentropic expansion (in a turbine)
4-1 Constant-pressure heat rejection

24
The two major application areas of gas-
turbine engines are aircraft propulsion
and electric power generation.
The highest temperature in the cycle is
limited by the maximum temperature that
the turbine blades can withstand. This
also limits the pressure ratios that can be
used in the cycle.
The air in gas turbines supplies the
necessary oxidant for the combustion of
the fuel, and it serves as a coolant to
keep the temperature of various
components within safe limits. An air–fuel
ratio of 50 or above is not uncommon.

25
Development of Gas Turbines
1. Increasing the turbine inlet (or firing) temperatures
2. Increasing the efficiencies of turbomachinery components (turbines,
compressors):
3. Adding modifications to the basic cycle (intercooling, regeneration or
recuperation, and reheating).
Deviation of Actual Gas-Turbine
Cycles from Idealized Ones
Reasons: Irreversibilities in turbine and
compressors, pressure drops, heat losses
Isentropic efficiencies of the compressor
and turbine

26
THE BRAYTON CYCLE WITH
REGENERATION
In gas-turbine engines, the temperature of the
exhaust gas leaving the turbine is often considerably
higher than the temperature of the air leaving the
compressor.
Therefore, the high-pressure air leaving the
compressor can be heated by the hot exhaust gases
in a counter-flow heat exchanger (a regenerator or a
recuperator).
The thermal efficiency of the Brayton cycle increases
as a result of regeneration since less fuel is used for
the same work output.
A gas-turbine
engine with
regenerator.

27
Effectiveness
of regenerator
Effectiveness under cold-
air standard assumptions
Under cold-air
standard assumptions
The thermal efficiency depends on the ratio
of the minimum to maximum temperatures
as well as the pressure ratio.
Regeneration is most effective at lower
pressure ratios and low minimum-to-
maximum temperature ratios.
Can regeneration
be used at high
pressure ratios?

28
THE BRAYTON CYCLE WITH
INTERCOOLING, REHEATING,
AND REGENERATION
For minimizing work input to compressor and
maximizing work output from turbine:
T-s diagram of an
ideal gas-turbine
cycle with
intercooling,
reheating, and
regeneration.

29
Multistage compression with intercooling: The work required to compress a gas between
two specified pressures can be decreased by carrying out the compression process in stages
and cooling the gas in between. This keeps the specific volume as low as possible.
Multistage expansion with reheating keeps the specific volume of the working fluid as high
as possible during an expansion process, thus maximizing work output.
Intercooling and reheating always decreases the thermal efficiency unless they are
accompanied by regeneration. Why?

30
IDEAL JET-PROPULSION CYCLES
Gas-turbine engines are widely used to power aircraft because they are light and
compact and have a high power-to-weight ratio.
Aircraft gas turbines operate on an open cycle called a jet-propulsion cycle.
The ideal jet-propulsion cycle differs from the simple ideal Brayton cycle in that the gases
are not expanded to the ambient pressure in the turbine. Instead, they are expanded to a
pressure such that the power produced by the turbine is just sufficient to drive the
compressor and the auxiliary equipment.
The net work output of a jet-propulsion cycle is zero. The gases that exit the turbine at a
relatively high pressure are subsequently accelerated in a nozzle to provide the thrust to
propel the aircraft.
Aircraft are propelled by accelerating a fluid in the opposite direction to motion. This is
accomplished by either slightly accelerating a large mass of fluid (propeller-driven
engine) or greatly accelerating a small mass of fluid (jet or turbojet engine) or both
(turboprop engine).

31
Propulsive efficiency
Propulsive power
Thrust (propulsive force)

33
Modifications to Turbojet Engines
The first airplanes built were all propeller-driven, with propellers powered by
engines essentially identical to automobile engines.
Both propeller-driven engines and jet-propulsion-driven engines have their own
strengths and limitations, and several attempts have been made to combine the
desirable characteristics of both in one engine.
Two such modifications are the propjet engine and the turbofan engine.
The most widely used engine in aircraft propulsion is the turbofan (or fanjet)
engine wherein a large fan driven by the turbine forces a considerable
amount of air through a duct (cowl) surrounding the engine.

35
Various engine types:
Turbofan, Propjet, Ramjet, Sacramjet, Rocket

36
SECOND-LAW ANALYSIS OF GAS POWER CYCLES
Exergy
destruction for a
closed system
For a steady-
flow system
Steady-flow, one-inlet, one-exit
Exergy destruction of a cycle
For a cycle with heat transfer
only with a source and a sink
Closed system exergy
Stream exergy
A second-law analysis of these cycles reveals where the largest
irreversibilities occur and where to start improvements.

37
Summary
• Basic considerations in the analysis of power cycles
• The Carnot cycle and its value in engineering
• Air-standard sssumptions
• An overview of reciprocating engines
• Otto cycle: The ideal cycle for spark-ignition engines
• Diesel cycle: The ideal cycle for compression-ignition
engines
• Stirling and Ericsson cycles
• Brayton cycle: The ideal cycle for gas-turbine engines
• The Brayton cycle with regeneration
• The Brayton cycle with intercooling, reheating, and
regeneration
• Ideal jet-propulsion cycles
• Second-law analysis of gas power cycles

thermochap9lecture. Heat and temperature 12

More Related Content

Similar to thermochap9lecture. Heat and temperature 12 (20)

Recently uploaded (20)

thermochap9lecture. Heat and temperature 12