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Fluid Catalytic Cracking Video Lecture | Chemical Technology - Chemical Engineering
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FAQs on Fluid Catalytic Cracking Video Lecture - Chemical Technology - Chemical Engineering
| 1. What is fluid catalytic cracking (FCC) in chemical engineering? |  |
Ans. Fluid catalytic cracking (FCC) is a process used in chemical engineering to convert heavy hydrocarbon feedstocks into lighter and more valuable products, such as gasoline and diesel fuel. It involves the use of a catalyst and high temperatures to break down large hydrocarbon molecules into smaller ones through a process called cracking.
| 2. How does fluid catalytic cracking work? | |
Ans. Fluid catalytic cracking works by introducing the hydrocarbon feedstock into a reactor vessel, where it is mixed with a powdered catalyst. The mixture is then heated to temperatures ranging from 480 to 550 degrees Celsius. The high temperature causes the hydrocarbon molecules to break apart, forming smaller molecules. The catalyst helps facilitate this cracking reaction. The cracked products, along with unreacted catalyst, are then separated in a fractionation unit.
| 3. What are the advantages of fluid catalytic cracking? | |
Ans. Fluid catalytic cracking offers several advantages in chemical engineering. Firstly, it allows for the production of a higher yield of valuable light hydrocarbon products from heavy feedstocks. Secondly, it helps in the removal of impurities and contaminants present in the feedstock. Additionally, FCC can be operated continuously, making it a highly efficient process. Lastly, the spent catalyst from FCC can be regenerated and reused, reducing the overall cost of the process.
| 4. What are the main challenges in fluid catalytic cracking? | |
Ans. One of the main challenges in fluid catalytic cracking is the deactivation of the catalyst over time. The high temperatures and exposure to contaminants can lead to the formation of coke deposits on the catalyst surface, reducing its activity. Another challenge is the control of the cracking reactions to ensure the desired product yield and quality. Maintaining the proper balance between temperature, catalyst activity, and feedstock composition can be challenging.
| 5. What are the environmental impacts of fluid catalytic cracking? | |
Ans. Fluid catalytic cracking has both positive and negative environmental impacts. On the positive side, FCC helps in the production of cleaner-burning fuels, such as gasoline and diesel, which can reduce air pollution. However, the process also produces greenhouse gas emissions, such as carbon dioxide and methane. Efforts are being made to optimize FCC processes and catalysts to minimize the environmental impact by reducing emissions and improving energy efficiency.
Text Transcript from Video
PRESENTER: Fluid catalytic
cracking, or FCC,
is the last step in
the evolution of cat
cracking processes--
also introduced in 1942,
just like TCC or Thermafor
Cat Cracking, during
the Second World War
in an effort to make
high-octane number gasoline.
Remember that high-octane
number relates to high power
as you can have higher
compression ratios
in the combustion engines.
FCC really shows an
excellent integration
of the cracking reactor,
an endothermic reactor,
with the catalyst regenerator
and exothermic reactor for very
high thermal efficiency.
FCC is now used universally
in oil refineries
throughout the world--
has replaced all the previous
cat cracking processes.
Now, in FCC, in
the feed, that is
gas oil preheated to about
300 degrees Fahrenheit--
is introduced into the
reactor with steam.
The riser part of the reactor
where the hot catalyst
particles-- as you see,
the green line coming from
the catalyst regenerator--
are full of dyes.
The particles are full
of dyes because they're
smaller particles.
They are full of dyes and
flowing gases and vapors.
So they have a huge surface
area to meet the incoming feed
at temperatures that are close
to 1,000 degrees Fahrenheit.
So cracking reactions on
these very fine particles that
are full of dyes and
flowing with the reactants
takes place in a very short
space of time, something that
could be measured with seconds.
And the products are
sent to a fractionator
after going through
a series of cyclones,
obviously, to separate
the small fluid dyes,
the particles of the catalyst.
In the fractionators,
the products, as usual,
are separated into gas,
gasoline, light cycle
oil, heavy cycle oil,
and, finally, the heaviest
fractions, decant oil.
Remember that LCO
is used in the US
for making diesel fuel
through hydrocracking
and hydrogenation.
And decant oil could be used
as fuel oil or as feedstock
for making carbon black or
white coking to make needle
coke for graphites, electrodes.
Coming back to the reactors,
the cat cracking reactor,
the coked catalyst now,
the end of the riser where
this cracking
reaction takes place,
are sent through
the regenerator.
It's not fully coked on the
surface, lost its activity.
Through the red line, it's
sent to the regenerator
where air is introduced
to burn off the coke.
The temperatures
in the regenerator
could reach to 1,300 to
1,400 degrees Fahrenheit.
You should remember
that the catalysts now
are much improved, as well.
It may include
zeolites that would
take high temperatures and
very controlled reactivities
through pore size
distribution and so forth.
So the combustion
products or flue gases
from this catalyst regenerator
could be sent to a CO boiler
because the gas may contain
significant amount of carbon
monoxide, which could be
burned to CO2 to provide
additional heat or to
generate additional heat.
So the catalysts that
are now regenerated
are sent to the reactor to
close the catalyst cycle
through that green line, as you
see, to meet the incoming feed.
So our catalyst cycle is pretty
much complete at this point.
But note this
excellent integration,
thermal integration, of
the catalyst regeneration,
the exothermic process,
with the cracking reactions
where the catalysts that are
heated in the regenerator
are sent in a very effective
manner to the reactor
without much heat loss.
So that is the ultimate, if
you will, thermal efficiency
of a process.
And that's why FCC is now
the universally accepted
catalytic cracking process.
cracking, or FCC,
is the last step in
the evolution of cat
cracking processes--
also introduced in 1942,
just like TCC or Thermafor
Cat Cracking, during
the Second World War
in an effort to make
high-octane number gasoline.
Remember that high-octane
number relates to high power
as you can have higher
compression ratios
in the combustion engines.
FCC really shows an
excellent integration
of the cracking reactor,
an endothermic reactor,
with the catalyst regenerator
and exothermic reactor for very
high thermal efficiency.
FCC is now used universally
in oil refineries
throughout the world--
has replaced all the previous
cat cracking processes.
Now, in FCC, in
the feed, that is
gas oil preheated to about
300 degrees Fahrenheit--
is introduced into the
reactor with steam.
The riser part of the reactor
where the hot catalyst
particles-- as you see,
the green line coming from
the catalyst regenerator--
are full of dyes.
The particles are full
of dyes because they're
smaller particles.
They are full of dyes and
flowing gases and vapors.
So they have a huge surface
area to meet the incoming feed
at temperatures that are close
to 1,000 degrees Fahrenheit.
So cracking reactions on
these very fine particles that
are full of dyes and
flowing with the reactants
takes place in a very short
space of time, something that
could be measured with seconds.
And the products are
sent to a fractionator
after going through
a series of cyclones,
obviously, to separate
the small fluid dyes,
the particles of the catalyst.
In the fractionators,
the products, as usual,
are separated into gas,
gasoline, light cycle
oil, heavy cycle oil,
and, finally, the heaviest
fractions, decant oil.
Remember that LCO
is used in the US
for making diesel fuel
through hydrocracking
and hydrogenation.
And decant oil could be used
as fuel oil or as feedstock
for making carbon black or
white coking to make needle
coke for graphites, electrodes.
Coming back to the reactors,
the cat cracking reactor,
the coked catalyst now,
the end of the riser where
this cracking
reaction takes place,
are sent through
the regenerator.
It's not fully coked on the
surface, lost its activity.
Through the red line, it's
sent to the regenerator
where air is introduced
to burn off the coke.
The temperatures
in the regenerator
could reach to 1,300 to
1,400 degrees Fahrenheit.
You should remember
that the catalysts now
are much improved, as well.
It may include
zeolites that would
take high temperatures and
very controlled reactivities
through pore size
distribution and so forth.
So the combustion
products or flue gases
from this catalyst regenerator
could be sent to a CO boiler
because the gas may contain
significant amount of carbon
monoxide, which could be
burned to CO2 to provide
additional heat or to
generate additional heat.
So the catalysts that
are now regenerated
are sent to the reactor to
close the catalyst cycle
through that green line, as you
see, to meet the incoming feed.
So our catalyst cycle is pretty
much complete at this point.
But note this
excellent integration,
thermal integration, of
the catalyst regeneration,
the exothermic process,
with the cracking reactions
where the catalysts that are
heated in the regenerator
are sent in a very effective
manner to the reactor
without much heat loss.
So that is the ultimate, if
you will, thermal efficiency
of a process.
And that's why FCC is now
the universally accepted
catalytic cracking process.
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