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FRACTIONAL DISTILLATION

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The composition of the liquid and vapor in equilibrium changes constantly over time. ... is the mole fraction of A and NBliquid is the mole fraction of B ... – PowerPoint PPT presentation

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Title: FRACTIONAL DISTILLATION


1
FRACTIONAL DISTILLATION
  • ORG I LAB
  • Dr. W. J. KELLY

2
THE BOILING POINT
  • The Boiling Point is the temperature at which
    internal vapor pressure of the liquid is equal to
    the pressure exerted by its surroundings
  • If the liquid is open to the atmosphere, the
    boiling point is the temperature at which the
    internal vapor pressure of the liquid becomes
    equal to atmospheric pressure (760 mm Hg).
  • The internal vapor pressure of a pure liquid
    rises steadily as the temperature is increased
    until the boiling point is reached.
  • P ยต e -C/T
  • The temperature remains constant throughout the
    boiling process of a pure liquid. At the boiling
    point, the liquid and vapor are in
    equilibrium...if the composition of each phase
    remains constant, the temperature will remain
    constant

In a Distillation Process a liquid is heated to
its boiling point, the vapors expand out of the
container and are then cooled below the boiling
point temperature, where they recondense as a
liquid
3
THE TEMP/TIME RELATIONSHIP
  • A thermometer placed in the vapor of a boiling
    pure liquid registers the liquids boiling point.
  • The temperature remains constant throughout the
    boiling process of a pure liquid. At the boiling
    point, the liquid and vapor are in
    equilibrium...if the composition of each phase
    remains constant, the temperature will remain
    constant
  • The temperature of a liquid mixture AB, where
    BPAltBPB will rise steadily over time. The
    composition of the liquid and vapor in
    equilibrium changes constantly over time. At the
    beginning the vapor contains more A, at the end
    more B.

4
Raoults Law
  • For a mixture of two miscible liquids (A and B),
    the total vapor pressure is the sum of the
    individual vapor pressures
  • Ptotal PA PB
  • where
  • PA NAliquid x PA And PB NBliquid x PB
  • where
  • PA is the vapor pressure of pure A and PB is
    the vapor pressure of pure B
  • and
  • NAliquid is the mole fraction of A and NBliquid
    is the mole fraction of B
  • where
  • NAliquid moles A/moles A B and NBliquid
    moles B/moles A B

5
Vapor Enrichment
  • From Raoults Law we can obtain the following
    relationships
  • NAvapor PA/PT
  • And
  • NBvapor PB/PT
  • If A is more volatile than B, BPA lt BPB and PA gt
    PB
  • Then
  • NAvapor gt NAliquid
  • The result of this process is that when a
    mixture of two miscible liquids with different
    boiling points is heated,the vapor will have a
    different composition than the liquid. THE VAPOR
    IS ENRICHED IN THE MORE VOLATILE (LOWER BOILING)
    COMPONENT.

6
Distillation Process
Liquid-Vapor Composition Diagram
  • When a mixture AB of a specific composition is
    heated, the total vapor pressure (composed of the
    contributions of PA and PB) will rise until it is
    equal to the external vapor pressure. The
    mixture will begin to boil.
  • The vapor which first forms is enriched in the
    more volatile component. This behavior is shown
    at right,
  • Assume a two component mixture with a composition
    of 30A70B (point W). The boiling point of
    this mixture is found by drawing a vertical line
    from W to where it intersects the lower curve
    (point X). A horizontal line drawn from X to
    where it intersects the vertical axis (the
    temperature) gives the bp of composition W. From
    the point (Y) where this horizontal line
    intersects the upper curve (vapor) drop a
    vertical line to intersect the lower axis (the
    composition). Point Z gives the composition of
    the vapor which is in equilibrium with a liquid
    of composition W at its boiling point.

7
Fractional Distillation
  • AB at composition of 5 A boils at temperature L1
    and the vapors with composition V1 enter the
    column at that temperature. The vapor will
    condense to a liquid with composition V1. The
    condensate L2 has a lower boiling point (because
    it has more of the lower boiling liquid A) and
    will thus vaporize at a lower temperature (warmed
    up by coming in contact with the additional
    vapors from below) to give vapors of composition
    V2. These vapors will condense somewhat farther
    up the column to give a condensate L3. If the
    column is long enough or contains sufficient
    surface area that many successive
    vaporization-condensation steps (theoretical
    plates) can occur, the distillate that comes over
    the top is nearly pure A. Distillation yielding
    pure A continues until all of A is removed, after
    which the temperature at the thermometer rises to
    the boiling point of B.

8
Distillation Efficiency
  • The efficiency of a fractional distillation is
    determined by the amount of pure liquid
    components obtained. Keep in mind that if a
    liquid is pure it will have a constant boiling
    point. The temperature of vapors in equilibrium
    with liquid at the boiling point will be
    constant. A plot of temperature vs. time for a
    pure liquid will look like A below.
  • The efficiency of a fractional distillation can
    be demonstrated graphically by plotting the
    change in temperature of the distillate over time
    (or over volume of distillate, as in this
    experiment). In a fractional distillation with
    low efficiency, separation will be poor. There
    will be little or no pure component as
    distillate. The composition of the distillate
    will be constantly changing and the bp of the
    vapor in equilibrium with liquid will be
    constantly changing. It will give a plot such as
    B.
  • An efficient distillation will give pure
    components which will have constant boiling
    points. Such a process is shown below in plot C.
    The relatively flat horizontal regions at the
    beginning and end of the plot indicate pure
    components A and B are obtained.
  • The closer to this ideal sigmoid shape the better
    the fractional distillation.

9
Distillation Setups
10
Fractional Distillation Set-up
11
Proper Thermometer Depth
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