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Basics of Materials and Energy Balance Today's lecture will be on Basics of Materials
and Energy balance. If time permits, I will introduce to Introduction to Metal Extraction,
where we will be doing Material and Energy Balance in various processes.
You know that materials and energy balance are the routine plant exercise. It is nothing
new that I have to tell you, because every businessman or every shopkeeper or every plant
owner, have to do auditing of
material and energy from the point of view of the economics.
He would like to know, what the inputs are and what are the outputs of material and where
are the losses. He would also like to know, what is the energy input into the system and
what the energy output is; so
that he can assess the energy consumption because energy consumption acts directly to
the cost of the product. Probably, he would like to introduce measures like saving of
energy or utilization of energy, if he
happens to know how the energy is being utilized.
Let us see, first of all, what are the basics of materials and energy balance. I mean it
is nothing very great, but it is very simple. We know that you also do a sort of balance,
whenever you go to the market and do
some expenditure. You are given 100 rupees. When you come back, you will like to know
how you have spent 100 rupees. So, you keep an account of input and output. So, if it
is possible, you can introduce
the measure of. Now, similar to it; here also, you have to think in terms of inputs and output
of material, energy. Now, in fact, the basic is - it is based on law of conversation of
mass. Now, mass of
an isolated
system remains constant, irrespective of the changes occurring within the system.
Now, let us consider an open system. For example, consider an open system at this point, which
is point 1 and this point 2. Here, we have input and at point 2 we have output. Now,
let us consider the volume as
V, mass is transferred in and out of the system. Mass will accumulate, when the input and output
rates are unequal. So, in this case, we can write down rate of mass in is equal to rate
of mass out plus rate of rate
of accumulation of mass. Now, writing down in terms of mathematical expression - m is
the mass, dm by dt and that will be equal to m dot in minus m dot out. Dot represents
the rate of change of mass with
reference to time. So, this is in fact valid for unsteady state operation. Now, this material balance
equation is written for each and every component of this system. Suppose, in a system, there
are 10 different
elements entering or 5 different elements entering and 5 different elements or 10 different
elements leaving the system. Then we have to write down the mass balance for each and
every component that is entering
in.
For example, if we have component 1 dm 1 upon dt will be equal to m dot 1 in minus m dot
1 out. Similarly, for component 2, we will write dm 2 upon dt will be equal to m 2 dot
in minus m 2 dot out and so on.
I can write down for third component d m 3 upon dt that will be equal to m 3 dot in minus
m 3 dot out and so on say for i th component that becomes dm i upon dt is equal to m dot
i in minus m dot i out. Now,
for a system with multiple inputs and output streams, the material balance equation for
i th component becomes dm i upon dt is equal to sigma m i in all components minus sigma m dot out of all components.
This is again for all components: say, for i th component that is what it means. Now,
for a steady state, as the name suggests that there is no accumulation of mass within the
system and therefore sigma m dot i in
will be equal to sigma m dot i out. That is the basis when the system is in steady state.
Now, for a chemically reacting system, in addition to the law of conservation of mass,
the following two laws must also
hold.
First law is law of definite proportions. Now, a given chemical compound always contains
the same constitutional elements in the same weight proportions. This is only true for
stoichiometric compounds and for
non-stoichiometric compounds, this may not hold good. For example, FeO has Fe 1 and O
1 atom and it is also available as Fe 0.95O So, in that case this law of definite proportion
will not be valid. So, I will just write down a given chemical
compound
always contains the same constitutional elements in the same weight proportions. For example, in Fe2O3,
there will be 2 atoms of iron combining with 3
atoms of oxygen. For example, in Cu2S, there are 2 atoms of copper combining with 1 atom
of sulphur. However, copper and sulphur are the same constitutional elements, but CuS
is also formed. So, in that
case, it will not be valid and that means, it is
true for stoichiometric compounds. For non- stoichiometric compound, you have to find
out in what proportion the elements are combined. Second important law is law of multiple proportions.
This law states, if two elements can form more than one compound, I repeat once again,
if two elements can form more than one compound, then the
respective weights of one element that combines with a given weight of the other are in the
ratio of a small whole number. I think, I should write it. If two elements
can form more than one, then
the respective weights respective of one element combines with other in the ratio of small
whole numbers. So, you will very often come
across the various compounds, stoichiometric as well non-stoichiometric in nature. In case
of stoichiometric compounds, the combination of elements is clear, but in case of non-
stoichiometric compound, you
must know in what proportion the elements are combined. So, you can perform the material
balance. Now, I mean this is basic and I think all of you are aware that input should be
equal to output, when there is a
steady state and this is a very simple thing.
Now, about the energy balance; one important thing for energy balance is energy balance
cannot be done without material balance; whenever, you are required to solve a problem of energy
balance without
performing material balance energy, balance cannot be done. So that is one important thing.
Now, here are some tips. For example, one can perform elemental balance either in kg
or kg mole. Now, it is a matter of practice and matter
of convince about how you perform the material balance. You can perform in kg or gram or
in gram mole or in kg mole also. If you ask me, I will prefer or I will do the
material balance by considering kg mole because I find it very convenient by determining the
input and output of masses in terms of kg mole because later on the thermodynamic values,
which I will be getting in
the literature are given in per kg mole and they are also given in per kg. So, what I
wanted to say is that you have to develop your own habit, whether kg is suitable for
you or kg mole is suitable for you. The
thermodynamic values are available in kg, kg mole, gram and as well as in gram mole
and there is no problem at all. It is just a matter of convenience; the material balance
in kg mole becomes little bit easier. Say,
if you write down the stoichiometric equations, then immediately, it is apparent how many
moles are entering in and how many moles are entering out. So, I find it little easier,
but you have to make your own style
of solving these problems. Once you have done the material balance of all inputs, it is
very important to know where the input of materials is going in.
Say, you have x kg or x kg mole of certain material and you have to see how much of that
is going into the products. The products could be metal, it could be slag, waste product
or in the gaseous form. So, to
collect all such information, make a box to determine material balance and then proceed
to solve the heat balance and that is very important. Another important thing for the
energy balance is to make the basis of
calculation. You have already made, while doing material balance. For example, 1 kg
mole and then you follow that kg mole until the end of your heat balance or you can do
100 kg mole or 10 kg mole, whatever
is convenient to you, but do not change the basis till the end of the problem number.
Number 2: the several energy balance is done by considering a reference temperature of
298 kelvin. Now, this is an advantage because the values
or the thermodynamic values like specific heat content, heat of reaction, heat of formation
are all available at 298 kelvin. It is again a matter of practice. Now, once
you have done this and then perform heat balance. Now, needless to mention heat input is equal
to heat output because we are talking of a steady state. We are not performing heat balance
under unsteady state,
we can also perform under unsteady state in that we know what is the accumulation of energy
in the system. Normally, in most of the plants, it is required that the plant is operating
at a steady state for days with
inputs and output of energy and so on. So, you perform the heat balance. It is very
simple; heat input is equal to heat output. Although it looks to be simple, but you have
to consider all sources from which heat is entering. If I write few sources for
you, for example, heat input is by chemical reaction. You have to see whether in a system, chemical reaction
is occurring. Now, I have already illustrated how to calculate the heat of reaction when
I was
discussing thermochemistry. Here, it is important to calculate chemical the heat of reaction
because of the chemical reaction. It could be exothermic or it could be endothermic.
Accordingly, the sign convention
must very clear negative for exothermic. If you want to do that for endothermic, it is
positive. You can declare it in the beginning that this is the convention I am going to
follow, but you have to stick to the
convention and that is an important thing. Now, the temperature is also very important.
You have to see whether the products, the reactants are entering at what temperature.
So, accordingly heat of reaction has to be calculated as per the formula, which I
have given in thermochemistry and that is the heat of reaction at 298 plus heat of reaction
at the prevailing temperature. You have to do these and proper calculations are very
important. The next step is - you
collect the thermodynamic data and this is the most important step while performing the
heat balance. You have to know from where, which data will be available while going through
the problems over here. I will
give you the data, I will give you the source, but in an unknown situation, if you are required
to do heat balance, you must know how to collect the data. In certain cases, the data may not
be available, then you
should be able to derive the data from basic thermodynamic and that is important.
So, collect the thermodynamic data on C p and that is a specific heat. It is available in kilocalorie per kg mole per
degree celsius or joule or kilo joule per kg mole per degree kelvin per degree Celsius
and all these
values are available. Follow a certain system of collection of the data in proper units.
So, you do not end up in a problem. Collect the data on heat of formation of compounds. Normally, these heat
of formation
of compounds are available at 298 kelvin. Now, you should know the state of elements or compound, why I am telling this
thing because if there is a transformation in the solid phase, I mean there could be
transformation within the solid phase and transformation in melting and boiling. So,
at all these transformations, temperature change does not occur, but you have to consider
the latent heat. So, with this context,
it is important to know the state of element or compound, when you attempt to make a heat
balance of a particular problem. So, if it is a solid state transformation,
then you have to know at what temperature the transformation is occurring from alpha
to beta and within what range. Accordingly, you have to use the C p value in that
range and you should also know the melting point. The important thing over here is to
know the latent heat and I have written it simply because many times, I have seen while
performing heat balance, we might
forget latent heat, but there is no reason for forgetting. So, latent heat can be for
transformation, either in the solid state transformation or in the liquid transformation,
from solid to liquid and liquid to gas. In that
stage, you have to see, what is the latent heat and also heat input could be of combustion
energy. Now, this fuel is used as a heat source, if
you use fuel as a heat source, then two things you must know. Number one: what is the chemical
composition? Number 2: what is the heat of formation? What is the
calorific value of the fuel and what is the energy that is released on combustion? So,
this is the combustion energy. In many processes, you will find that the reactants are heated,
for example, in various high
temperature processes, sometimes air is heated and the reactants are heated. So, you must
also know which is a sensible heat of reactants? Now, you have to calculate sensibly, but to calculate that you must
know what is the temperature at which the reactants are entering. It is an important
thing.
Now, some term for heat output. You have to see in what stream, heat is taken out. It
may be taken out as solid products. For solid products, you must know C p of all components. If there is a phase
transformation in the solid in that temperature range, then probably it is also important
to know the latent heats. b) Liquid product- In solid products, you also require to know
what the temperature is. In liquid
products, you have to know what the temperature is and whether a liquid product that is exiting
the system at the melting point or above the melting point and these are the important
issues. Here, you have to see
how products are forming. Temperature of each product, composition of each product, C p
value of each product and you should also know the heating value. To say, heat content
at that particular temperature
and if you are calculating latent heat from 298 degree at 298 kelvin, then heat of mixing...
if you recall in the lecture on thermodynamics, I said various heat input and various heat
output turns heat of mixing
because when a liquid solution forms, for example, if silicon dissolves in iron, there
is a heat of solution or there is a heat of mixing. Similarly, the two oxides that dissolve
in certain cases generates heat. So that
heat of mixing should be known. We should also know where heat of mixing is produced
by addition of which, oxide heat of mixing will be available. So that information must
be known in order to come to a
exact or accurate heat balance. Now, C) It is the gaseous product. Now, normally,
in almost all metal extraction processes that we are concerned have the output as solid
product, liquid product or gaseous product or combination of all the
three or two. So, for the gaseous product, you are required to calculate how much heat
is been taken out and we require the value of C p. Now, I would like to tell one important
thing that many students I found
they are doing the mistake not knowingly, but they are not cautious enough.
When you want to calculate heat content in water, So, you have to consider these steps.
Probably, it will help yoy, H2O liquid at 25 degree celsius is equal to H2O liquid at
100 degree celsius. You should know
the C p value of that. Then H2O liquid at 100 degree celsius is equal to H2O vapor at
100 degree celsius. Here, we should know that there is a transformation and so you must
know latent heat, say, H2O vapor
at100 degree celsius to H2O vapor at that temperature and you must again know the value
of C p. It is important here because the C p is also a function of temperature. Accordingly,
you must collect the
important values and many times a mistake occurs in calculating the heat content in
water. Suppose water or the water vapor is being discharged. For example, 1400 degree
celsius, if you select the state of water
as liquid, then you have to calculate the heat content. First of all, you bring vapor
from that temperature to 100. latent heat will be what Then from liquid to 25 degree.
So, I mean that these are the things you must consider. Another important one is D - calculation
of heat losses. Now, heat losses are very important feature and they are an integral
part of the high temperature
extraction processes. You must be able to calculate heat losses. Now, here the mechanism
is very clear- the conduction, convection and radiation. So, invoking the appropriate
loss and the method of calculation,
you should be able to calculate heat losses because these heat losses, if they are in
very large amount, then one should think of how to minimize these heat losses to conserve
the amount of energy. So, with this,
say, these are slight basics of materials and energy balance. I will again say it is
just a sort of a common sense. If I summarize, what I said until now. I will say it just
as a common sense. Everyday, your dad must
be giving 100 rupees and at night, he must be asking what is your balance? So, you must
be able to tell him, you gave me 100 rupees in the morning. Now, I am left with a 5 rupee
and immediately he will ask you,
where did you spend? Give me the balance, the same thing here. Your plan manager has
given you, for example, 100 tons of raw material and he wants to know what are the outputs.
So, his objective is to
minimize the losses, if at all they are occurring, this is what the whole objective of this material
and heat balance exercise. Now, let us apply these concept to actual
metal extraction processes. Now, before we go to that a brief account of the metal extraction
process is very much desirable because without this you may not be able to
understand how to apply these balances. So, with this I will give you a brief introduction
to metal extraction. Now, first thing, I would like to say, what are the sources of metals?
Sources of metals occur in the
nature as minerals. Metal in nature does not occur as metal and that is a very important
thing you must know. So, there are two sources: one is the primary source. Primary sources
are te natural reserves. Natural
reserves, as I said, metals are in form of minerals oxides or sulphides. It is important
to know what is a mineral because, when a question is asked as what is the difference
between mineral and ore. I found many
students sometimes get confuse. So, I be should very clear that a mineral is an inorganic
compound in which elements are combined in stoichiometric proportion. You should be very
clear in this. I repeat again, a
mineral is an inorganic compound in which elements are combined in stoichiometric proportion
and so the natural occurrence of metal is mineral and as I said it is an inorganic compound.
For example, I take a Fe2O3, 2 molecules of iron are combined with 1.5 molecules of oxygen.
The ratio of Fe upon O2 is equal to 2 upon 1.5. Take SiO2, 1 molecule of silicon is combined
with 1 molecule of
oxygen. Similarly, we take Fe2O4 and the ratio for example, if I write Fe upon O2 will be
3 by 2. Let us take Al2O3, the ratio of aluminum upon O2 will be equal to 2 upon 1.5 and that
is the meaning of mineral
is. The elements are combined in mixed proportions. Another source is secondary. The secondary
resource is a scrap or recycled products. The amount of metal or the amount of consumption
of metal with which we are concerned is enormous. It is in million tons
and hardly the secondary resources can meet a very large requirement of the human beings.
Therefore, the main resource or source of metal is the primary reserves. So, I will
write in red ink- natural reserve or
reserves of any metal is called , I will write with a different ink ore. So, remember, there
is a difference between ore and a mineral. A mineral is an inorganic compound in which
elements are combined in a
stoichiometric proportion. Whereas, an ore is an aggregate of minerals.
Remember, ore in fact is an aggregate of minerals. It means ore of a metal will consist of valuable
mineral plus all other minerals is called as gangue minerals. What does a valuable mineral
mean? A valuable
mineral is a one that we are interested in the production of metal. For example, I consider
a metal, name of the ore, constituent of the ore, valuable mineral and gangue mineral.
Now, gangue mineral is a waste. Now, remember, when I say it as a waste, it is vest with
reference to the metal in which I am interested in production. Otherwise, gangue is also a
mineral. So, remember, when I
say it is a gangue is waste, for production of that particular metal, rest all is a waste
with reference to that particular metal. So, for example, I take the metal as iron and
the name of the ore is hematite. Now,
hematite contains Fe2O2, SiO2, Al2O2, P2O5 etc. Now, we are interested in iron and so valuable
mineral is Fe2O3 and all other. For example, SiO2, Al2O3, P2O5 are considered to be gangue,
but they are also
mineral because SiO2, 1 molecule of silicon and 2 atoms of oxygen. Silicon is also a metal,
which is very important. Al2O3, aluminum is also a metal. Similarly, another example,
I have constituents as Fe3O4,
SiO2, Al2O2, P2O5and TiO2 etc. The valuable mineral is Fe3O4 and rest are all, say, SiO2, Al2O3, P2O5 and TiO2 etc are the
gangue minerals. Another example, I take aluminum and the name
of the ore is bauxite. Now, bauxite has Al2O3 into x H2O, Fe2O3, TiO2, SiO2 etc. Now, in
this aggregate of mineral, which is called an ore? The valuable one is
only Al2O3 and rest all, say, H2O, Fe2O3, TiO2 and SiO2 are gangue minerals. Another
example, I take zinc and sphalarite is the name of the ore. Sphalarite may contain zinc
sulphide, lead sulphide, Cu2S,
SiO2, Al2O3 etc. You do not know what the nature has stored for you. Here, I want to
get only zinc as it is the valuable material. So, zinc sulphide and with reference to this
PbS, Cu2S, SiO2, Al2O3 are gangue
mineral. Although Pb is also a metal, It can also be recovered from the gangue depending
upon its concentration Similarly, if I take an example, I can take titanium and Ilmenite
is the ore. In ilmenite composition,
you have Fe, TiO3, SiO2, MgO etc. Now, the valuable mineral is titanium dioxide and rest,
say, FeO, SiO2, MgO are all gangue minerals. Now, another important metal is copper. Ore
name is chalcopyrite and chalcopyrite constituents CuFeS2, SiO2, Al2O3, Fe2O3, calcium oxide
etc. Now, here the valuable mineral is only CuFeS2 and all other for
example, FeS, FeS2, SiO2, Al2O3 are all considered to be the gangue minerals. So, what we note
from here is that ore being an aggregate of minerals, we must know what is the quantity
of metal that an ore has
and so that quantity is quantified by defining metal grade.
Metal grade of an ore indicates ore value. Now, as I said, if the metal grade is high,
then the gangue mineral is low. Accordingly, less effort has to be taken to remove the
gangue. So, metal grade is a very
important issue. Now, how to define metal grade? Metal grade is equal to amount of metal upon amount of ore, if I want to define metal
grade in an ore. Now, for example, I can also define metal
grade of a pure mineral. In that case, I have to take the amount of metal in the mineral
upon amount of mineral. Now, for example, I take a pure mineral, Fe2O3, then iron
grade in pure Fe2O3 will be equal to 112 into 100 upon 160 and that makes 70 percent. What
does it mean? 30 percent is a waste and that has to be removed, if you want to get iron.
Now, for example, hematite,
which is an ore contains 80 percent of Fe2O3 and then the metal grade of ore or iron grade
of ore is equal to 56 percent. What does it mean? 44 percent is the gangue and that has
to be removed, if you are
possessing the natural reserve, which is hematite and that is important.
Now, let me give another example. Let us consider a mineral for copper, which is say CuFeS2.
Now, let us find out the copper grade. Copper grade in CuFeS2 pure mineral will be equal
to 64 upon 184 into 100
is equal to 34.78 percent. Now, see the copper grade in pure CuFeS2 is 34.78 percent. Now,
imagine if copper ore has 20 to 30 percent CuFeS2, which is normally the case or it could
be even less than that.
Thus the content of CuFeS2 could be 20 to 30 percent or could be even less than that.
In that case, the copper grade in ore will be 7 to 10 percent. What does this mean? It means out of every 100 kilo
gram of
ore, you have only 7 to 10 kilo gram of copper and rest is gangue or you can call it as a
waste with reference to the copper and they have to be removed. That is an important thing
you must understand from
here. Now, similarly, say nickel grade, which is again an important strategic metal. Nickel
grade in nickel ore also varies and it is for your information. Although it depends
on location to location, it varies between
2 to 5 percent. So, accordingly, the amount of waste that we are producing from synthesize
or from the processing of the natural reserves of these metal is an ore.
A nickel having only 5 percent nickel and 95 percent is a waste. Remember, these things
are not physically separable and it is chemically combined. For example, the hematite ore has
Fe2O3, chalcopyrite has
CuFeS2. So, copper and sulphur are not physically combined, but they are chemically combined.
Similarly, in Fe2O3, iron and oxygen are chemically combined. You cannot just do by breaking and
removing
sulphur from copper or removing oxygen from iron is not possible. So, what I mean is that
they are also chemically combined. So, what we can say, if you are looking from extraction
of metal from natural
reserves, what has to be done? What are the basics?
The extraction of metal
from natural reserves is going to use ore. What we have to do? First step is that you
have to remove oxygen or sulphur from valuable mineral because in ore of iron, we are interested
in
iron and nothing else. From valuable mineral, this is the first step that you have to do.
Removal of oxygen or sulphur from the valuable mineral is the first step in processing the
natural reserves in order to get the
metal. Second important step is separation of metal from the gangue minerals. Remember, separation
might convey it to you as a physical, no not that physical. I mean it may require certain
reaction that is all. The
separation I mean is that once you have got the oxygen or sulphur removed from the valuable
mineral, then you have an aggregate metal plus gangue. Now, you have to separate it
and you cannot separate it
chemically. You cannot separate it physically and so these are the two steps that are required
to extract metal from natural reserves. What are the techniques? Whatever technique
you adopt, these two are the important steps. First technique is pyrometallurgy. Pyrometallurgy
- the term 'pyro' means high temperature. Here, it is the temperature
or thermal energy. This pyrometallurgical root is thermal energy dependent and that
is where energy balance is an important issue. Second is hydrometallurgy. Root of hydrometallurgy
is not thermal energy
dependent, but it requires an enormous amount of liquids, mostly water. Third is not an
independent root, but, it is combined with hydrometallurgy and that is the electrometallurgy.
These are the three techniques,
which can be used to extract metal from the natural reserves.
So, the following unit processes are used. In the case of pyrometallurgical extractions;
pyromet, I am writing in the short form. First step is roasting, second step is smelting or reduction smelting, third step
is
converting and fourth step is refining. We will take these in our subsequent lectures along with
the material and energy balance. For hydrometallurgy, various unit processes are - one is the leaching
and second is
the separation of metal from an aqueous solution. Separation of metal from aqueous solution
is done because in hydrometallurgy, you have the metal in the solution. Now, various techniques
are used: One is the
cementation, aqueous solution reduction, electrolysis and solvent extraction technique. Now, for
example, copper by pyrometallurgical root uses roasting plus matte smelting plus converting
plus refining. It
combines all of them.
I will give one or two examples. I take zinc and it combines roasting, reduction smelting
plus refining. If you take, pig iron, it has reduction smelting. These are the combinations
of unique process to produce the
metal, say, steel by reduction smelting plus refining. So, in short, these are the various
processes that are used.