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Good morning. In the last two classes, we discussed in detail, the concept of availability
or exergy balance in both open and close system. We should have a hurried recapitulation of
what we did. We are appreciated that availability that is the work potential of low grade energy
is not conserved the way energy is conserved. There is always a destruction or reduction
of the availability in any natural process. This was the outcome of the availability balance.
It can be put in this way that if there is a closed system which executes a process from
one initial state to another final state and in doing so, if it interacts with the surrounding
in the form of heat and work energy then associated with that heat and work, there is an availability
transfer to the system. If we equate or determine the availability
at the final state and availability at the initial state, and if we find out what is
the net availability transfer into the system, then we see that, what we have seen; rather,
the availability at the final state is not equal to the availability at the initial state
plus the net availability transferred in which it should be if it could have been conserved,
but it equals to this thing; that means, the availability at the final state equals to
the availability at the initial state plus the net availability transferred into the
system minus the destruction of availability which equals to the temperature of a reference
environment times the entropy change of the universe and it is termed as irreversibility.
For a reversible process, this is 0 and the availability is conserved in the same way
as the energy is conserved. Similarly, if we think of a control volume, in that case
what is the difference between a control volume and a close system that is a mass inflow and
outflow? Then we have to take balance of the energy coming in, associated with that what
is the availability coming in and availability going out these are known as flow availability.
In the similar way, we can tell the flow availability at the outlet should be equal to the flow
availability at the inlet plus the net availability transferred into the control volume, if it
was conserved like energy quantity. Net availability transferred in comes because there is an energy
interaction in terms of heat and work with the surrounding but it does not happen so.
In the similar line as it is stated in close system, for close system this balance is that
availability coming out; that means, the flow availability at the outlet stream equals to
the flow availability at the inlet stream plus the net availability transferred into
the control volume minus the availability destruction which is the irreversibility that
is T0 times entropy change of the universe. Next, we recognize that for any natural process.
Therefore, this destruction of availability is because of the irreversibility and more
is the departure from the reversible process; that means, more is irreversibility then more
is the destruction of the availability and this is gauged or measured by a parameter
known as the second law efficiency which we started for the different operators or different
equipment. We started with the work to different devices rather work producing device turbine.
We will do it again now. Before that, one should know what should be
our target. Our target should be to make the process as close as possible to the reversible
process, so that the destruction of availability is minimum. The destruction of work potential
of the low grade energy from which our main object is to find the useful work should be
minimum, so that always the energy which is available to us for converting into work should
have a higher potential. We start with this second law efficiency.
Second law efficiency, first part is the repetition. Again, I must start second law efficiency.
We started with a turbine. We just recognize a turbine first. What is a turbine? Consider
an adiabatic turbine. In all practical cases, a turbine is insulated; that means an adiabatic,
that is mounted on a shaft so that we get and work at the rate of let per unit mass.
In a steady state as I have told that everything is done in unit mass so this is section one
this is section two that is the outlet section that is the inlet stick that is the outlet
stick. The gas or air whatever is the working fluid,
comes at section one with an enthalpy h1 and goes out with an enthalpy h2. If we neglect
the changes in kinetic and potential energies, we know that del w divided by dell m. That
is the first law or the energy balance for the steady flows open system is h1minus h2.
If we neglect the changes in kinetic and potential energy that means we get work out of the difference
in enthalpy. If at the same time, we defined af1 and af2. What is af2? By definition, af2
is equal to h2 minus T0s2. This is specific flow availability. h2 and af1 is equal to
h1 minus T0 s1; then, af2 minus af1, if I just write this from their definitions. Let
us write af1 minus af2 instead of af2 minus af1. That will be equal to h1minus h2 plus
T0 s2 minus s1. We see the decrease in availability is equal
to enthalpy change plus this quantity. But the change in enthalpy is what? del w divided
by del m plus T0 s2 minus s1. What is T0 s2 minus s1? It is T0 delta s universe, because
it is adiabatic. So, change in entropy of this working system is the entropy change
of the universe. If the process could have been reversible,
so this part could have been 0, because entropy changes of the universe is 0. In that case,
we see, it is the difference of availability which could have been the work done per unit
mass. Therefore, we see, the actual work done which is the difference between h1 minus h2
is less than the ideal work done which is equal to af1 minus af2; decrease in flow availability.
Therefore, we could have got more work which is equal to the difference in flow availability
at the inlet and outlet, if the process could have been reversible. This is gauged by an
efficiency known; second law efficiency, which is defined as del w divided by del m that
is the actual work divided by af1 minus af2 which is nothing but sometimes we can write
this as theoretical work, where this we can write as actual work and this becomes equal
to 1 when process is reversible.
Similar is the case, if we consider an adiabatic compressor. The difference between the turbine
and the compressor is that it is also an work interacting device, but not work producing
device, but it takes work per unit mass basis. del w divided by del m is the work which is
being added to the compressor and let this is state section one inlet and section two
outlet. Similar is the case, let h1 and h2 and corresponding
af1 and af2. Again, from the steady flow energy equation, we can write h2 minus h1. Here,
I am always writing the positive value of del w divide by del m; that means, again a
work is added. So, it will be negative. So, if we write, it will become h1 minus h2. I
am writing in terms of the positive value. Obviously, when work is added enthalpy will
be more at the outlet than at the inlet provided we change. We neglect the changes in kinetic
and potential energy. I always write the positive value of the work and we always recognize,
before that this is the work taken by the compressor. If I tell that there is no harm.
If I apply the positive value that is true. Here, if we find out the increase in availability
rather af2 minus af1. Therefore, af2 minus af1is equal to h2 minus T0 s2 minus h1 minus
T0s1. This becomes equal to h2 minus h1 minus T0 s2 minus s1, just the reverse. Here, you
see that h2 minus h1 is the work required by the compressor to go from state one to
state two, but the change in availability, increase in availability is less than the
work required; that means the availability is destructed. If you compare these with your
availability balance equation, this is alright. That means the availability here is availability
here plus the availability taken in by the compressor; that means, del w divide by del
m minus some amount which is I, that means T0 delta s universe.
In this case, this is a compressor that demands more work as compared to that which it could
have taken if the process was reversal; if the process was reversible. So, that was 0;
that means, this I can write af2 minus af1 could have been the work requirement. Therefore,
we see, the actual work requirement is more than the ideal work requirement. In this case,
this will go this side. Therefore, here eta 2, the second law efficiency
is written as the work which is needed is more. But the ideal work that means af2 minus
af1 that is the ideal work is less, because it is taking work divided by the del w divided
by del m. del w divided by dell m is the actual the work required which is af2 minus af1 plus
T0 s2 minus s1 divided by del w divided by del m. This is the way by which we define
the second law efficiency of a compressor. Make your concept clear at this stage. So,
if your concept is clear, slowly, you write down the equations and you will arrive at
the correct answer.
Compressor is not adiabatic then the Q quantity will come here definitely. If the compressor
is not adiabatic, I am just giving you a simple case that compressor is adiabatic.
If compressor is not adiabatic then Q term will come here. Then you have to consider
that Q is coming or going. In case of compressor, if you do not consider it is adiabatic, then
Q may come out. In case of turbine also, Q may come out or deliberately Q may be given.
So, it has to be specified. In that case, the energy equations will be modified. At
the same time, the availability equations will be modified. Everything we are writing
forms that concept. We will see automatically that when there is a heat transfer, also the
change in availability will correspond to availability balance equation, but the definition
is same; that is at the ideal work requirement by the actual work requirement.
That is left as an exercise, you do it. If there is any heat interaction, let us consider
some heat is coming out from the system. Then what it will be if you change this thing.
Definition of the availability will remain the same, but h1 minus h2 simply will not
account for the del w divide by del m. Some heat quantity will come in that case.
Next is heat exchanger; non-work producing devices. let us consider heat exchangers.
There are two types of heat exchangers. So, we will read afterwards. One is a mixing type.
Let us consider simply, without telling in terms for the heat exchanger rather a mixing
device; that means, two fluids are mixed, one and two and goes at three.
Let the fluid stream. The flow rate is m1 dot. Let the fluid or the working fluid of
the system be m2 dot and m1 comes at a temperature T1, and m2 comes at a temperature T2 corresponding
enthalpy h1 and entrusted with enthalpy h2. This is the m3 dot with the enthalpy h3. How
to define this second law efficiency of the process? How to analyze this process?
There are three things: one is the mass balance another is the energy balance another is the
availability balance. Availability balance and entropy balance are almost parallel. If
these four things can be determined then one can determine everything. Let us consider
the entire system as adiabatic; that means these two streams at different enthalpy mix
and goes out. So, no heat and work transfer from this entire system. That means if we
take this as the control volume, the control volume does not have any work and heat interactions.
Then mass balance tells m3 dot is equal to m1 dot plus m2 dot. Then what is your energy
balance? Energy balance is m1 dot h1, this is the energy coming in, plus m2 dot h2. Here,
I neglect the changes in potential and kinetic energy so that the kinetic energy is part
of the flowing energy. I am neglecting with all these streams or if it is there, specified
that one side kinetic energy is very high, whereas the outlet kinetic energy is very
low or between the two streams that there is a large difference between kinetic energies.
Then, we will have to take into account. But if the kinetic energies are almost same for
all the fluids then we can neglect the kinetic energy part. This must be equal to m3 dot
h3.
That means m1 dot h1 plus m2 dot h2 is equal to m1 dot plus m2 dot into h3. How will h
relate to T? That depends upon the property relationship of the working system. So, this
is energy balance. This is the mass balance and this is energy balance. This energy balance
can be written in this fashion also; that is, m1 dot into h1 minus h3 is equal to m2
dot h3 minus h2. Let us consider m1 as the hot fluid and this as the relatively cold
fluid but does not matter. The energy released by one will be energy gained by the other.
This is clear from this type of expression. Now what will be the availability? What is
the af1? af1 is h1 minusT0 s1. What is af2? af2 is h2 minus T0 s2. These are the specific
flow availability. Then af3 is h3 minus T0s3. Now I write the availability balance. Without
writing availability balance, let us write m1 dot af1 plus m2 dot af2 minus m3 dot af3.
What is the result? m1 dot af1 plus m2 dot af2 minus m3 dot af3. So what is m1 dot af1?
It is m1 dot into h1 minus T0s1, plus m2 dot. What is af2? It is h2 minus T0 s2 and what
is m3 dot af3? m1 dot plus m2 dot into h3 minusT0s3. If we write, We get, m1 dot into
h1 minus T0s1 plus m2 dot into h2 minusT0s2 minus m1 dot plus m2 dot into h3 minusT0s3.
If we write m1 dot h1 plus m1 dot h2 and m1 dot plus m2 dot they cancels each other. So,
I am leaving with minus T0 which is constant. So, we get T0 into minus m1 dot s1 minus m2
dot s2 plus m1 dot plus m2 dot s3.
This becomes T0 into m1 dot s3 minus s1 plus m2 dot s3 minus s2. What is this quantity?
This is delta s universe. That is T0 into delta s universe. This is the irreversibility
rate. If we make an availability balance, I see
that availability outlet; that means, availability in plus m2 dot af2 is equal to m3 dot af3
plus I dot or other way. That m3 dot af3 is the availability out is equal to availability
in, in terms of rate minus the destruction. This is the availability balance. In this
case, entropy balance also. Side by side, everything will be clear. Entropy balance
is that m1 dot s3 minus s1 m2 dot s3 minus s2 is the change of the other.
If anybody writes this entropy balance, we will be writing m1 dot s3 minus s1 plus m2
dot s3 minus s2 is the delta s universe, where this m1 dot s3 plus m2 dot s3 are the entropy
going out; that means, for a better understanding one can write this. Everything will be very
clear and this is the entropy which came into the system with the flow. That means always
entropy is being added, while going out you take more entropy. That means it is generated
while that exergy or the availability is going out something is being taken for that, is
the concept. So, this is the entropy balance. Any way you
can write. This shows a clear picture. Entropy going out is entropy coming in plus increase
in entropy generation. Availability is same thing; availability going out is availability
coming in minus the irreversibility. In this case, how do you define the second
law efficiency? Second law efficiency in this case, is defined like this.
We have taken the availability balance. You can see the availability balance. Let us write
the availability balance again. Let us write, availability balance. Let me write again.
Availability balance is m1 dot plus m2 dot into af3 is m1 dot af1. Again, plus m2 dot
af2 minus I dot. If I write the second law efficiency, second law efficiency in this
case can be written in terms of any of the fluid.
Let this is the hot fluid. Sometimes, it is written in terms of cold fluid. This is the
cold fluid which has gained the availability; that means m2 dot af3 minus af2. Corresponding
loss of availability by the hot fluid is af1 minus af3, this is the definition; that means,
the availability increase in the cold fluid divided by the availability decrease in the
hot fluid. If you transfer it, term irreversibility will
come into picture. That means this is the gain which is less than this by the amount
irreversibility. If you transfer here m2 dot af3 minus m2 dot af2, it will be m1 dot af1
minus m1 dot af3 minus I dot. That means it will be this thing. Let this thing is x; x
minus I. That means the availability released by this
fluid, if I consider this as the hot fluid, is the convention we define in terms of the
cold fluid that is not being taken by the cold fluid. Cold fluid availability gain will
be less than the reverse by the hot fluid. This way, we define the second law efficiency
for heat exchangers. This is a mixing type. There may be non-mixing type that the masses
are not mixed. They go separately with a separating wall. That will be clear, if we solve a problem.
There is one interesting problem after this, I like to place before you. So, after all
these things, I think we are in solid positions.
We are in a solid position to solve the problems. Let us consider a problem. An adiabatic turbine
receives a gas whose properties are given cp, cv. and this type of gas always you take
h is equal to cpT. that is not given in this problem, you can take if it is required. I
do not know. At seven bar and 1000 degree Celsius these are the important.
Discharges at 1.5 bar and 665 degree Celsius. Determine the second law and isentropic efficiencies.
What is the difference between second law and isentropic efficiencies? Isentropic efficiencies of the turbine; means
take T0 that is the environment temperature and it is already given for the problem cpdT
and p v you take RT, where R is cp minus cv. So, what is this problem? Now let us draw
the sketch. The problem is like this.
There is an adiabatic turbine which gives del w divided by del m is the work. It is
coming in section one, the working fluid goes at section two that is one and two. Then,
what is the value of del w divided by del m? del w divided by del m is h1 minus h2,
per unit mass basis I am doing.
h is given. Then dh is cpdT.
That means I can write cp. T1 minus T2, where T1 is 1000 degree Celsius and T2 is 665 degree
Celsius. I can write in terms of Celsius, because it is the difference and cp value
quals to the value of cp given. cp is 1.09 kilo Joule per kg. So, this comes out to be
365.15 kilo Joule per kg. So, per unit mass basis I find out what is the actual work done.
Now, what is the ideal work done af1 minus af2? What is that? af1 minus af2 is 365.15
plus which could have become if the process was reversible plus T0, T0 is 298 into delta
s universe. What is delta s universe? It is the delta s of the system. So, delta s of
the system in this case if you have to find out, you have to use this equation.
Tds is why I am writing? This is not du plus vdp, because it is better to write in this
fashion. You can write, Tds du plus also does not matter I write both this. So, if we write
this, then ds is dh divided by T minus v divided by T into dp. dh is cpdT that means delta
s is cpln into T2 divided by T1 minus, what is v by t? p v into RT that means R by P.
R is cv ln into p2 divided by p1. So this is the expression. If we equate this, this
will be
I am extremely sorry very good you are following nicely. So I am very happy. cv ln into T2
divided by T1 plus R into ln into v2 divided by v1. These two expressions are identical.
So, any of these two equations I can write. Here, if you calculate T2 is what given 665
degree Celsius. Corresponding to that, you can find out what is the absolute temperature
T1, p2 by p1 ratio we can put it in any unit seven and 1.5 bar accordingly. You put it
and get the value. af1 minus af2 will be equal
to 381.65. What is second law efficiency? Second law efficiency we will be 365.15 divided
by 381.65 and that comes to be
0.956 You have already done it very good. But what is isentropic efficiency? The evaluation
of second law efficiency is the routine job. As we have already applied, this thing, in
general for a turbine compressor, this is a routine job by putting the numerical values.
Now, isentropic efficiency concept is like this. This is a turbine. It comes at state
one and it goes at state two. Isentropic efficiency will come afterwards in the cycle analysis.
This state one is fixed and state two is fixed. This is the turbine and we get a work del
w divided by del m. Now, isentropic efficiency is like this. If
I plot a Ts diagram, let us consider this is the constant pressure line p1 and let us
consider this as a constant pressure line p2. If we consider this as a gas, either a
superheated vapor or air or any gas, where the constant pressure line looks like this.
If this is state one and this is adiabatic, but this is not a reversible process; that
means, adiabatic reversible [.] will be isentropic. Otherwise, it is not isentropic. Now, the
question comes. It is isentropic means it will be vertical. If it is not isentropic
that means a natural process that means irreversible adiabatic. From the figure or the graph, it
can be either this side or this side healing but it cannot heal on this left side. This
is because the entropy of the system will decrease which will lead to the decrease in
the entropy of the universe, since the process is adiabatic. So, entropy change of the surrounding
is zero. Therefore, the only solution is that the entropy
of the system will increase. That is because internal irreversibility. So, the process
is like this. So, this is the end two. What we have considered in the second law efficiency
that between the same state point one and two, if we could have considered hypothetically
that irreversibility part is zero then the efficiency which I arrive is this second law
efficiency. It is very difficult to understand. I am telling
you, think yourself so that you can understand. This difference is very subtle between the
second law and isentropic efficiency. Second law efficiency is that we fix these two states,
but there is an irreversibility between the two states. If irreversibility could not have
been there but the system state two that means we are finding out af1 and af2 difference
that we are telling the af1 minus af2 is the ideal work, provided the system comes from
state one to state two, is the theoretical abstraction or theoretical concept. Because
this availability is always designated to the state point. Though it is a composite
property, but if we consider the environment fixed that this composite property becomes
a function of the state points of the system. When the two states are fixed then af1 and
af2 are fixed and their difference is the ideal work; that means, the work which could
have been obtained if we discard the irreversibility If we discard the irreversibility for the
process connecting the same state points. But now, if I consider another picture that
this system starts from same initial state but it goes under a reversible adiabatic process.
If we consider a reversible adiabatic process or isentropic process with the same initial
state, then this process could have ended here and not there; that means, this is the
ideal process. That means if the process could have been ideal, we give a relaxation on the
final state point very important no book has defined this thing. I am telling you. You
will not get such illusion explanation in any book the difference between second law
and isentropic efficiency. If we are not bothered about the final state
point but if we consider that for the same initial state point, what could have been
the final state point? If I could have made a reversible adiabatic process then the work
output of this process del w divided by del m.
if I consider this as the work for the isentropic process. Then the isentropic efficiency is
del w divided by del m divided by del w divided by del m into i.
How to find out the work done in this process? That means the same initial state, but a reversible
adiabatic process which ends up to a difference states, then we have to find out s2 and corresponding
h2. So, how to find out this h2? That means, we have to find out this T2; that means s2
means the change of the entropy of the universe will be zero.
How do you write the change of the entropy of this thing? We can write delta s universe
is equal to dh that means cp which is 1.09 into ln into T2 divided by T1. What is T1
is 1273 minus Rln between the same pressure. So, pressure ratio remains the fix; same remains
fix that means ln 1.5 divided by 7 this gives you a temperature T2 .
Let me tell you I have done it. This gives you a temperature T2 which is equal to 891.
I am sorry there is a problem. What was your temperature there? cpln T2 divided by T1.
This T2 has to be more than this. So, there may be a calculation mistake. T2 in this case
isentropic expansion is 891.58 k that is less than this, because this is 665 degree Celsius.
This T2 is 665 plus 273 k. This T2 comes out to be this. The del w divide by del m into
I will be then h1 minus h2 dash which becomes equals to cp into T2 dash minus T1, because
the property relationship is dh is cpdT. We can find out this del w divide by del m
and this becomes isentropic work; so, that becomes equal to 415.75 kJ per kg and accordingly
eta two is 365.15 divided by 415.75 which becomes equal to 0.878.
Sorry Sorry eta I eta I so clear. Isentropic efficiency and the second law efficiency
are proportional to each other. Both of them are the measure of the departure from the
irreversibility, but it is visualize to different concept. There is nothing great in it. Just
the way we characterize it. Sometime we characterize it with the same end state points by this
formula; that is eta. Second law efficiency or we characterize the process in this way
that if for the same initial state, within the same pressure ratio, there could have
been an isentropic process. What could have been the end and what could have been the
ideal work? That we gauge the departure from reversibility and define that parameter as
the ratio of these two works that is the actual work by ideal work as the isentropic efficiency.
Another very simple problem. After this conceptual problem, we should have one very simple problem.
You just see this problem.
In a counter flow heat exchanger, oil whose property values are given; oil at cp is 2.1kilo
Joule per kgk is cooled from 440k to 320k. This is the problem of heat exchanger. While
water is heated from 290k to a temperature of T unknown temperature and this is a heat
exchanger, where there is separation; they do not mix. The respective mass flow rates
of oil and water are 800 and 3200kg per hour. Neglecting pressure drop, these are usual
assumptions. If they are not given, you will assume this there is a steady flow process.
So, pressure drop, we will neglect. If there is a incompressible fluid flowing
steadily through a duct, so pressure drop is only because of the viscosity. So, one
can neglect that viscous pressure drop within a short length of duct. This is the practical
thing. Changes in kinetic and potential energies and heat loss from the heat exchanger; that
means there is no heat loss from the heat exchanger. That means the transfer of heat
is between the two fluids oil and water. Determine the temperatures T, the rate of exergy destruction,
the second law efficiency. Take the environment temperature.
It is a straightforward application for the definition of second law efficiency or application
of second law efficiency in a heat exchanger. Let us think of this problem. You have taken
the problem. I am drawing this block diagram then it will be clear. Not necessarily always
you will have to take in language. However, again I am repeating; in a counter flow heat
exchanger oil, specific heat at constant pressure 2.1 kilo Joule per kgk is cooled from 440k
to 320k. While, specific heat at constant pressure 4.2kilo Joule per kgk is heated from
290k to a temperature of T; unknown temperature that we have to find out. The respective mass
flow rates of oil and water are 800 and 3200kg per hour neglecting pressure drop changes
in kinetic and potential energies and heat loss from the heat exchanger, determine the
temperature T, while the rate of exergy destruction in the process the second law efficiency,
given the reference the ambient temperature.
First of all, we must draw the figure here. This is the heat exchanger. This is divided
into two partitions. In this, there is coil for the oil. Let oil goes in this direction
and this is the inflow. Counter flow means they go in the opposite direction. They are
parallel flowing parallel but in the opposite direction, water going out.
Let m dot o is the mass flow rate of oil and m dot w is the flow rate of water. They remain
same. From the conservation of mass, entire thing is adiabatic. Very simple problem. Let
this section is one, this section is two, this is three and this is four. So, one pertains
to the inlet of oil, two pertains to the outlet of oil, three pertains to the inlet of water,
and four outlet of water. So this T1, T2, T3 given T4 has to be found.
T4 is to be found out .Now, write the energy balance equation. Energy balance equation
is m dot o h1 plus m dot w h3 must be equal to leaving out m dot o h2 plus m dot w h4.
In this problem, we have to consider, again the same thing that dh is cpdT that means
dh is cpdT for the water; also, water and oil that is the fluid.
Therefore, we can take in one side cp into T1 minus T2 is equal to m dot w that is cp0
oil and cpw into h4 minus h3 that means T minus T3. Everything is given; T1 is given,
m dot o is given, cp0 is given and Tw is given. We may convert the unit in kg per second.
We may put it in kg per hour, because this will cancel each other, all in the consistent
units. So, we can find out the T. Everything is given Tw now sorry I am extremely
sorry this will be T minus T three I am sorry T three. Value of T will be what 305 k, a
school level thing. Enthalpy coming in; that means, the energy coming in with oil with
water these are the energy coming in, because there is no heat, work interaction. changes
in kinetic potential energies are same sorry negligible and this is going out.
So, I bring it in one. Since dh is cpdT; therefore, h1 minus h2 is cp divided T1 minus T2 and
h4 minus h3 is cpw T minus T3. Now, you are not told to find out the change in the flow
availability, because calculation will be little more. But if you are asked to find
out the irreversibility, or what rate of exergy destruction? That means a dot that is exergy
destruction which is nothing but I dot which is nothing but T0 delta s universe.
We do not bother to find out the availability at the terminal points and make an availability
balance. It is not required. We can simply write that, from the availability balance
concept, we know the rate of destruction of the availability is the rate of irreversibility
which is T0 into delta s universe. What is delta s universe dot? Delta s universe dot
looks better if you write in terms of rate of generation of entropy which is oil is from
one to two that means this is delta s dot oil plus delta s dot water that is m dot o
cpo ln. Then you tell ln T2 divided by T1. So, what is T2?
T2 is 320, because now it is cooled and it becomes 320 divided by 440 plus m dot. cpw
ln T, T is 305 and T1 is 290.
So, you find out this. I dot is T0 sigma dot and the value is what? Destruction in the
availability. That value will come 41.4. If we do not convert here also per hour then
this rate will also be in the same time unit for T1 does not matter, Mega Joule per hour.
Why unnecessarily you convert it? There is no need. Nobody has asked this question. Just
like a primary school boy that you find out the I dot in terms of jper Second. If it is
not told then let us find it in terms of hour. How to find out second law efficiency? Second
law efficiency here the same way we can find out that m dot water into af4 minus af3 divided
by
m dot oil into
af1 minus af2 two. You can find out the second law efficiency will be equals to 10.9 percent.
You see this heat transfer through a very very finite temperature difference in such
irreversibility loss 10.9 percent. This is the definition of this second law efficiency.
We can express one in terms of the other through this, because this will be this minus I dot
so that you can calculate only this one, because since the I dot is calculated, you can make
the calculation. It does not matter. Anyway you can do it clear please tell me
this concept is clear.
I can expect that you can solve any problems in availability. Now I will start a new chapter
today. I could have left you but you see this is a studio class, where I cannot leave you
before one hour. Let us start the next one; the important property relations.
Important thermodynamic property relations; let us find out what we have known up to the
date. You know Tds is equal to du plus pdV. This is the property relations we know and
at the same time, this can be written in a form du is equal to Tds minus p dV. I can
write dH is equal to Tds plus vdp where from it comes H plus .very good so you are more
knowledgeable than me. H is equal to u plus pV. So, from there we can find du plus pdV
is Tds plus Vdp. I will introduce two new properties one is Helmholtz function.
I told you that any jugglery between the properties will be another property, but just like that
we cannot define a number of millions of millions properties. These must have a physical significance.
The way, u plus pV has been made like that. A combination u minus pV or u by pV does not
bear any physical sense, but u plus pV has an enormous physical significance that enthalpy.
Similarly, Helmholtz function F is defined as u minus Ts such a combination and Gibbs
function. These are the names of the scientists who discovered Gibbs function.
H minus Ts. I think that some physical significance have to be told that the moment otherwise,
you will not feel interested. For mathematical operation, it is enough to know the definition
mathematically that F is equal to u minus Ts. G is equal to H minus Ts, the way you
define the enthalpy u plus V. This Helmholtz function, if we recollect that
our availability that is the maximum work is some phi, at any state minus phi zero,
where phi u plus p0 V minus T0 s and phi zero is corresponding to that u0 plus p0 sorry
not V zero V . p0V0 minus T0s0. This is our availability function which is a composite
function or a composite property of system and surrounding. Why because this p0 that
is T0. This p0 part, if I neglect that means if I
consider that the system, the work which is being done. The work to compress the surrounding
I neglect or I consider a system whose pressure and temperature is same as that of the surrounding.
but you can tell, sir if it is a single component system then both the properties are same;
that means, they are in the same state and that is a dead state. So, nothing will happen.
Therefore, I relax. I consider the system temperature T0; if any process be same as
that of the environment, and system performs a process isothermally; that means, the temperature
remaining the same then this T0 can be written as simply temperature of the systems, because
temperature remains constant and that becomes equals to the temperature of the environment.
I can express a property of the system which is F. Let me denote it by F which is u minus
Ts, whose physical significance is that the changes in this function represent the maximum
work, reversible work. That we can obtain from a close system under an isothermal condition,
where the constant temperature of the system equals to that of the surrounding.
Again, I am telling then you will ask it is the maximum work obtained along with the non
useful work, unuseful work; that means, inclusive of the displacement work obtained by a system.
This is a concept. You try to think, if it executes an isothermal process means that
constant temperature and that temperature equals to the environment temperature.
For example, when I equate pdV, sometimes at a constant pressure process becomes equal
to d of pV. No pressure is constant. So, this and this is the same thing. Similarly, if
the temperature of the environment and temperature of the system remains same throughout; that
means, we can take T0 and we can replace T0 as T. That means one can tell, sir it is u
minus Ts; that means, if I know the system property I can find out. So, surrounding has
not to be spelled. If I tell that is system has got this internal energy, this entropy
and this temperature and it comes to a state where this is the internal energy and the
same temperature and the entropy and the surrounding has a temperature of which is same as the
system temperature under isothermal condition. Then though the surrounding temperature is
given, but only thing is that I have to take into mind that system temperature and surrounding
temperature is the same. It is the difference between the Helmholtz
function which gives the reversible work or the maximum work in that process. This is
very important in chemical reactions; reaction process which takes place at constant volume
where the isothermal condition is maintained. This is not beyond the scope of our study
here. How this Helmholtz function is being used. Similar is the case in the Gibbs function,
but it is with respect to a control volume or open system. We have seen in open system,
what is the availability A. A is equal to H minus T0 s. Changes in this composite function,
because T0 is there not only of the system. Change of this is responsible for the maximum
work, reversible work by a particular system at a different state flowing through a control
volume. If I consider that the system is an isothermal
system sorry process and the working system maintains the isothermal condition, where
the end and the initial temperature remains the same. That becomes equal to reference
environment temperature. Then I can replace T0 as Ts and can define a property or function
which is a property of the system. Only that is the Gibbs function.
Gibbs function is the maximum work available from a control volume for a given a state
of its working system at the inlet, provided the process is isothermal and the temperature
constant temperature equals to the surrounding temperature. For example, again I am telling
if I have a control volume, if I have a system at state one and system at state two, no isothermal
condition, no constant pressure, then the maximum work which we can get is the difference
between the two functions at outlet and inlet, which are the composite functions of system
and the environment, where only temperature of the environment comes into picture.
What is that? H minus T0 s is that function; that is H1 minus T0 s1 minus H2 minus T0 s2,
difference of these two. But if I tell that similar thing, but with added restriction,
or constant that the process is isothermal and that temperature equals to the temperature
of the surrounding. In that case, the maximum work which we could obtain is the difference
between Gibbs function which is purely a system property, not the composite environment property,
because does not matter, environment temperature and system temperature thy are same and this
is very important in a constant pressure reaction process, where the reactor is continuously
cooled to the ambient temperature at a fix reference temperature and the reaction takes
place in an isothermal process. They are the availability loss or the maximum work obtained.
From a chemical reaction, no work is obtained, but we are interested in finding out the destruction
of the availability or exergy in this chemical reaction.
The difference in Gibbs function gives you that concept. This physical concept, I think
enough for our class because we are not going to implement this in the physical processes
because this is beyond our scope. This difference in Helmholtz or Gibbs function, but for the
time being, this physical understanding is enough. We should only remember this formula
that F is equal to u minus Ts that is Helmholtz function. G is equal to H minus s. We add
two extra properties. Now what is dF? and what is dG? please tell me. dF is equal to
du minus Tds minus sdT. What is du? du minus Tds is minus pdV. So,
this is minus pdV minus sdT. What is dG? dG is equal to dH minus Tds minus sdT. dH minus
Tds is Vdp minus sdT. These four relations are the very basic property relations of thermodynamics,
from which we will derive many important and interesting relations afterwards in the next
class, because time is up. We will start from this point; that means,
four properties internal energy important property, enthalpy Helmholtz and Gibbs function
are expressed in terms of their differentials and in terms of other two properties. So up
to this today. Thank you.