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Chapter 7

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As isobaric cooling proceeds from P, sublimation will not generally occur at F. ... A sling (wet-bulb) psychrometer used to calculate RH ... – PowerPoint PPT presentation

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Title: Chapter 7


1
Chapter 7 Moist Air
  • The Dew (Frost) Point
  • As isobaric cooling proceeds from P, sublimation
    will not generally occur at F.
  • Between F and D, air will be supersaturated with
    respect to ice, but only condense water at D.
  • Tf and Tdew only indicate the point where
    condensation or sublimation can occur. They do
    not guarantee that such will occur.

2
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Consider a closed system consisting of dry air,
    water vapor (moist air), and water (or ice).
  • The enthalpy of the system can be written as
  • where we have made use of lv(T) hv hw and mt
    mv mw. We can substitute h cpT for vapor
    and liquid phase.

3
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Consider two states of the system linked by an
    isenthalpic process (?H 0). Each state may be
    represented by a form of the previous expression.
  • where md, mt, and const are the same in both
    states. Then, since ?H 0,

4
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • We can rewrite this as
  • The denominator on each side is a constant for
    any (closed) system. Each of the 2 sides of the
    equation is a function of the state of the system
    only, i.e., the expression on either side of the
    equation is an invariant for an isenthalpic
    process.

5
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Divide both numerator and denominator in the
    quotients by md and use the fact that wt (mv
    mw)/md mt/md to get
  • Note that (cpd wtcw) is constant for a given
    system, but will vary for different systems
    according to their total water value (liquid
    vapor).

6
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • We can simplify this expression first by
    neglecting the heat capacity of the water (wt ?
    w) yielding,
  • Now the denominator is no longer constant.
    Consider wcw as small compared with cpd and make
    lv a constant, we get

7
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • In this expression cp can be taken as cpd, or
    approximated, to a better degree of accuracy, as
    where the mixing ratio is an
    average value of w.
  • Consider the physical process that links 2
    specific states (T, w) unsaturated moist air
    water and (T, w) saturated or unsaturated
    moist air without water of the system to which
    our approximate equation applies.
  • We have dry air with w gm of water vapor and (w
    w) gm of liquid water (may or may not be
    droplets in suspension).

8
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Assume w gt w and that saturation is not reached
    at any time (except eventually when the final
    state is achieved).
  • Liquid water evaporates so the mixing ratio
    increases from w to w.
  • As water evaporates, it takes up heat of
    vaporization from moist air and water (system is
    adiabatically isolated).
  • Cooling results reducing temperature from T to
    T.
  • At any instant, the system state differs finitely
    from saturation process is spontaneous and
    irreversible.

9
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Equivalent temperature (isobaric equivalent
    temperature) Tei, is defined as the temperature
    moist air would reach if it were completely dried
    by condensation of all its water vapor.
  • Water is withdrawn in a continuous fashion,
    process is performed isobarically, and system is
    thermally isolated.
  • The formulation assumes no liquid water initially
    and starts from an infinitesimal variation dH,
    condensing

10
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • In this expression, dmv is considered negative,
    i.e., we are condensing a mass dmv of vapor to
    liquid.
  • Having condensed this infinitesimal amount of
    liquid, we remove it before condensing any more
    vapor.
  • The enthalpy of the system will decrease by
    hwdmv, but T is not affected.
  • For the next infinitesimal condensation, the
    equation is valid with a new value of mv.
  • Our equation describes the process with mv as a
    variable.

11
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Dividing through by md, and rewriting the
    differentials as differences, we get
  • Assuming the latent heat to be constant, we get
  • Assuming Ti T, Tf Tei, wi w, and wf 0, we
    get
  • Leading to

12
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Next we consider the Wet-Bulb Temperature,
    defined by the following process, the reverse of
    Tei.
  • We are following a process that goes from any
    mixing ratio, w, to saturation, wsw.
  • Closed, adiabatic system with unsaturated moist
    air and liquid water, temperature T, and total
    mixing ratio, wt
  • Water will evaporate drawing heat from moist air
  • Change in T related to change in wt due to
    evaporation
  • When saturation is reached, the temperature is
    the isobaric wet-bulb temperature, Tw.

13
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Examples
  • A sling (wet-bulb) psychrometer used to calculate
    RH
  • Evaporative cooling of air by rain falling
    through unsaturated region below cloud base
  • Have the same equation to start with, same
    assumptions.
  • Here we have wt instead of w because we have
    liquid water.
  • Assuming md gtgt mt ( mv mw), Tf Tw (the
    limiting temperature), Ti T, wi w, wf wsw,
    and wtcw ltlt cpd, we get

14
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • Note that Tei can be approximated (assuming wcw lt
    cpd) as
  • We see that there is a relation between
    equivalent and wet-bulb temperatures, to wit
  • The definition of wet-bulb temperature also lends
    itself to the defining of a relationship between
    Tw and Tdew using the approximate form for w ?
    ?e/p and cp cpd wtcw,

15
Chapter 7 Moist Air
  • Equivalent and Wet-Bulb Temperatures
  • In general the relationships between e and T can
    be given by
  • The adiabatic isobaric process we are discussing
    occurs along a straight line with slope
    .
  • Extending the line to increasing T will intersect
    at Tei, where e 0.

16
Chapter 7 Moist Air
  • Moist Air Adiabats
  • Poissons equation for adiabatic ascent (descent)
    between (p, T) and (p, T) is
  • Noting that ?m ?d(1 0.26q) varies with the
    moisture content, the adiabats passing through a
    point p, T will be different for different values
    of q (w).
  • Since ?m ? ?d, the adiabats for moist air will be
    slightly less steep than those for dry air (T
    will vary slightly more slowly). HOWEVER

17
Chapter 7 Moist Air
  • Moist Air Adiabats
  • The potential temperature for moist, unsaturated
    air is
  • If we substitute T ? (1000/p)-?d for T we get
  • If p 100 mb and q 0.01 kg/kg, we get ?m
    0.9983?.
  • If p 900 mb and q 0.01 kg/kg, we get ?m
    0.9999?.
  • This tells us we can treat moist ascent as dry
    ascent.
  • Substitute Tv for T we have the virtual potential
    temp, ?v.

18
Chapter 7 Moist Air
  • Moist Air Adiabats
  • This also leads to a statement of the moist
    (unsaturated) adiabatic lapse rate.
  • We have to account for the moisture in the value
    of the specific heat capacity of moist air,
  • We apply the binomial theorem to the denominator
    to give
  • As with the potential temperature, this says that
    moist air cooling adiabatically, cools less
    rapidly than dry air.

19
Chapter 7 Moist Air
  • Saturation of Air by Adiabatic Ascent
  • The equation for the saturation temperature at
    the LCL is,
  • On the diagram, P is the initial state, arrow
    indicates adiabatic ascent starting from P.
  • As T changes, esw changes according to arrow from
    S along saturation curve.
  • Two arrows will meet at Ts (not shown).
  • Ts is solved for iteratively.

20
Chapter 7 Moist Air
  • Reversible Saturated Adiabatic Ascent
  • The system under consideration is a parcel of
    cloud that rises and expands adiabatically and
    reversibly, indicating that all condensed water
    is kept (a closed system).
  • Since it is adiabatic and reversible, the process
    is isentropic.
  • What we derive here is valid for an ice cloud as
    well.
  • The expression for the entropy of this system is

21
Chapter 7 Moist Air
  • Reversible Saturated Adiabatic Ascent
  • If we divide by md and note that the entropy S
    const,
  • Where wt,w mt/md wsw mw/md and the
    subscript w indicates saturation values (except
    in mw).
  • If we differentiate the expression, we get
  • This equation describes the saturated adiabatic
    process.
  • If T and pd are independent variables, wsw
    ?esw/pd and esw f (T), so the equation
    determines a curve in T, pd plane.

22
Chapter 7 Moist Air
  • Reversible Saturated Adiabatic Ascent
  • We can make several assumptions to get an
    approximate and somewhat simpler form of the
    equation
  • Assume wt,w lt cpd and esw lt pd. This yields
  • Next assume that lv varies slowly with T, we
    differentiate
  • Use of the approximate form is good to within a
    few percent.

23
Chapter 7 Moist Air
  • Pseudoadiabatic Ascent
  • In saturated adiabatic ascent, the equations
    depend on wt.
  • While the saturation vapor mixing ratio, wsw, is
    determined, the liquid water mixing ratio, mw/md
    is arbitrary.
  • This creates the situation where on a T, p
    diagram where saturation is just reached, there
    will be an infinite number of reversible
    saturated adiabats passing through, each
    differing ever so slightly from each other,
    depending on the amount of liquid water in the
    parcel.
  • This dilemma can be avoided with a simple
    assumption.

24
Chapter 7 Moist Air
  • Pseudoadiabatic Ascent
  • We assume that all the condensed liquid water (or
    ice) falls out of the parcel as soon as it
    appears.
  • This is a process of saturated expansion, but the
    system is now open and irreversible.
  • It is called a pseudoadiabatic process and gives
    unique curves through each T, p point on a
    diagram.
  • Assume that mw 0 and wt,w ww, yielding
  • The cooling is slightly greater in
    pseudoadiabatic than in reversible expansion for
    the same change in pressure.

25
Chapter 7 Moist Air
  • Equivalent Potential Temperature
  • Go back to our isentropic equation
  • Keep latent heat as lv lv(T) and differentiate
  • We can introduce a potential temperature of the
    form
  • Logarithmically differentiating this we get

26
Chapter 7 Moist Air
  • Equivalent Potential Temperature
  • Comparing this with our other differential we see
    that
  • If we integrate this we have
  • We can get rid of the constant by taking the
    value of ? to be equal to ?e when all vapor has
    condensed , wsw 0

27
Chapter 7 Moist Air
  • Equivalent Potential Temperature
  • What we have is the representation of a
    reversible saturated adiabatic process where all
    the water vapor has condensed out (take parcel to
    a very cold temperature).
  • ?e is the equivalent potential temperature
    (conserved).
  • As the equation stands, it applies to saturated
    air.
  • We can apply it to unsaturated moist air by
    lifting the parcel to the LCL, yielding

28
Chapter 7 Moist Air
  • Summary of Temperatures

29
Chapter 7 Moist Air
  • Summary
  • of Temperatures
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