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Hygrometry objectives:

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Title: Hygrometry objectives:


1
ATMS 320 Meteorological Instrumentation
  • Hygrometry objectives
  • Understand how water vapor pressure is estimated
  • Know the different definitions associated with
    humidity
  • Learn the different methods for measuring
    humidity
  • Appreciate various factors in choosing a humidity
    sensor

2
ATMS 320 Hygrometry
  • The measurement of atmospheric humidity in the
    field has been and continues to be a challenge
  • Low cost, low power consumption, and reliability
    requirements make it especially difficult for
    automatic weather stations

http//www.musichead.com.au/site/artistPhotos.asp?
actID20206
3
ATMS 320 Hygrometry
  • Does the air really hold water vapor (like a
    sponge)?
  • Lets look at a cartoon!

(courtesy F. Remer)
4
Evaporation
  • Molecules in liquid water attract each other
  • In motion

(courtesy F. Remer)
5
Evaporation
  • Collisions
  • Molecules near surface gain velocity by
    collisions

(courtesy F. Remer)
6
Evaporation
  • Fast moving molecules leave the surface
  • Evaporation

(courtesy F. Remer)
7
Evaporation
  • Rate of evaporation
  • Constant
  • Function of water temperature

Twater
(courtesy F. Remer)
8
Evaporation
  • Soon, there are many water molecules in the air

(courtesy F. Remer)
9
Evaporation
  • Slower molecules return to water surface
  • Condensation

(courtesy F. Remer)
10
Evaporation
  • Rate of Condensation
  • Variable
  • Function of water vapor mass in air

(courtesy F. Remer)
11
Evaporation
  • Net Evaporation
  • Number leaving water surface is greater than the
    number returning
  • Evaporation greater than condensation

Net Evaporation
(courtesy F. Remer)
12
Evaporation
  • Rate at which molecule return increases with time
  • Evaporation continues to pump moisture into air
  • Water vapor increases with time

(courtesy F. Remer)
13
Equilibrium
  • Eventually, equal rates of condensation and
    evaporation
  • Air is saturated
  • Equilibrium

(courtesy F. Remer)
14
Equilibrium
  • At Equilibrium
  • Rate of evaporation is a function of temperature

Twater
Evaporation f(T)
Rate of evaporation
Rate of condensation

(courtesy F. Remer)
15
Equilibrium
  • At Equilibrium
  • Rate of condensation depends on water vapor mass
  • Also a function of temperature

Condensation f(T)
(courtesy F. Remer)
16
Equilibrium
  • At Equilibrium

Tair Twater
(courtesy F. Remer)
17
ATMS 320 Hygrometry
  • The pressure exerted by pure water vapor (es )
    is a function of the temperature of the vapor and
    liquid phases

derived by integration of the Clausius-Clapeyron
equation
(courtesy F. Remer)
18
ATMS 320 Hygrometry
  • Variations on the saturation vapor pressure theme

Buck (1981)
Wexler (1976, 1977)
http//www.sheetmusicplus.com/store/
19
ATMS 320 Hygrometry
Buck (1981)
Correction for the air pressure enhancement
effect
This equation form is preferred because it is
easier to invert to Obtain the dew-point
temperature given the ambient vapor pressure
20
ATMS 320 Hygrometry
Equilibrium vapor pressure over a plane surface
of liquid water
Equilibrium vapor pressure over a plane surface
of ice
Equilibrium vapor pressure varies over two orders
of magnitude in the normal temperature range, one
might expect the accuracy of almost any humidity
instrument to decrease with decreasing temperature
.
21
ATMS 320 Hygrometry
  • Humidity relationships
  • Starting point (A)
  • Saturation vapor pressure (B)
  • Dew-point temperature (D)
  • Wet-bulb temperature (C)

22
ATMS 320 Hygrometry
  • Humidity definitions
  • Be familiar with the definitions from Absolute
    humidity to Wet-bulb temperature and the
    accompanying formulas in Section 5.2 of the
    textbook.

http//www.onestopenglish.com/BookShop/BookShop/re
tail/dictionaries.htm
23
ATMS 320 Hygrometry
  • Sensors that respond to humidity and report
    dew-point temperature are common
  • The conversion leads to error since the
    relationship is non-linear and the inverted
    equations cannot be directly (analytically) solved

Sensor measures Td, converts to RH
Why is absolute error higher for lower dew-point
temps at a given RH?? Hint see EX on p. 91,92
24
ATMS 320 Hygrometry
Sensor measures RH, converts to Td
Why is absolute error higher for higher air temps
at a given Td?? Hint see EX on p. 92
25
ATMS 320 Hygrometry
  • Methods for measuring humidity
  • Removal of water vapor from moist air
  • Addition of water vapor to moist air
  • Equilibrium sorption of water vapor
  • Attainment of vapor-liquid or vapor-solid
    equilibrium
  • Measurement of physical properties of moist air
  • By chemical reactions

http//www.allergybuyersclubshopping.com/slanfinhu
mgf300.html
26
ATMS 320 Hygrometry
  • Methods removal of water vapor from moist air
  • Use a desiccant to absorb water
  • Freeze out water vapor
  • Separate moist air constituents using a semi
    permeable membrane
  • After removal determine mass of water vapor and
    of remaining sample and calculate humidity

http//cgi.ebay.com/
a substance that promotes drying (e.g., calcium
oxide absorbs water and is used to remove
moisture)
27
ATMS 320 Hygrometry
  • Methods addition of water vapor to air
  • psychrometry

http//www.city.niagarafalls.on.ca/
28
ATMS 320 Hygrometry
  • Addition of water vapor to air psychrometry
  • Dry bulb sensor measures ambient air temperature
  • Wet bulb sensor is covered with a wick moistened
    with water and measures a lower temperature,
    caused by evaporation of water into the ambient
    air stream
  • Forced ventilation is required for optimum
    performance

29
ATMS 320 Hygrometry
  • Sources of error in a psychrometer
  • A lack of sensitivity and accuracy in wet- and
    dry-bulb thermometers
  • Low ventilation rate
  • Radiation incident on the temperature sensors
  • Size, shape, material, and wetting of the wick
  • Air flow from wet- to dry-bulb thermometer
  • Dirty water used to moisten the wick

30
ATMS 320 Hygrometry
  • Addition of water vapor to air psychrometry
  • Conversion of wet- and dry-bulb temperatures to
    ambient vapor pressure
  • Slope of curves give the static sensitivity
  • Sensitivity increases markedly as the temperature
    increases for a given RH
  • Sensitivity increases slightly as the relative
    humidity decreases for a given ambient temperature

31
ATMS 320 Hygrometry
  • Addition of water vapor to air psychrometry
  • Difficult to have an error of less than 1 RH for
    air temperatures below 10oC
  • Hand-held sensors (e.g. Assmann psychrometer)
    must be held upwind of the observer
  • Automated psychrometry is challenging
    (constrained by low cost, low power requirements,
    and reliability)

32
ATMS 320 Hygrometry
http//www.allroutes.to/logging/history.htm
  • Equilibrium sorption of water vapor - hygrometers
  • The process of sorption (absorption and/or
    adsorption) causes a material to expand or
    contract, alters electrical resistance or
    capacitance
  • To be useful, the material must exhibit a change
    that is reversible and reproducible and detectable

First hygrometer wood (de Cusa, 1401-1464)
the accumulation of molecules of a gas to form a
thin film on the surface of a solid
33
ATMS 320 Hygrometry
  • Equilibrium sorption of water vapor electric
    hygrometers
  • Sorption sensors that take up water which causes
    a change in an electrical parameter such as
    resistance or capacitance

(top row)
(middle row)
Now a capacitor (formerly condenser) has the
ability to hold a charge of electrons. The number
of electrons it can hold under a given
electrical pressure (voltage) is called its
capacitance or capacity. Two metallic plates
separated by a non-conducting substance between
them make a simple capacitor.
http//www.electronics-tutorials.com/basics/capaci
tance.htm
34
ATMS 320 Hygrometry
  • Electric hygrometers (cont.)
  • Probe capacitance (Fig. 5-10) is converted to
    frequency and then to a voltage by electronics in
    the sensor probe.
  • Non-linearity in probe capacitance (slope of line
    is not constant)

35
ATMS 320 Hygrometry
  • Electric hygrometers (cont.) sources of drift
  • Dust accumulation
  • SO2 contamination
  • Aging of electronic components

36
ATMS 320 Hygrometry
  • Electric hygrometers sensor resistance (middle
    row of Fig. 5-9)
  • Bulk polymer resistance where resistance
    decreases with increasing RH (Fig. 5-11)
  • Difficult to maintain
  • Difficult to measure the very high resistance for
    low values of RH (less accurate at RH values of
    below 20)

37
ATMS 320 Hygrometry
  • Electric hygrometers carbon hygristor (bottom
    row of Fig. 5-9)
  • Experiences a dimensional change in response to a
    change in RH
  • Dimension (X) increases with increasing RH
  • Increasing X also increases the distance between
    the carbon particles (increasing resistance)
  • Subject to quite high drift rates
  • Used only on radiosondes

38
ATMS 320 Hygrometry
  • Electric hygrometers summary
  • Small and relatively inexpensive
  • Require calibration
  • Long lag times
  • Significant hysteresis
  • Sensitive to certain contaminants (e.g. SO2)

39
ATMS 320 Hygrometry
  • Equilibrium sorption of water vapor - mechanical
    hygrometers
  • Made from dimensionally variable materials (e.g.
    hair, skin, cotton, silk, nylon, paper, wood)
    mechanically coupled to an indicator or transducer

CAUTION!!
His appearance changes with the weather!!
40
ATMS 320 Hygrometry
Sasquatch
  • Mechanical hygrometers - defects
  • Drift
  • Large hysteresis
  • Large lag times

41
ATMS 320 Hygrometry
  • Measurement of physical properties of moist air
  • Refractive index
  • Radiative absorption
  • Thermal conductivity
  • Viscosity
  • Density
  • Sonic velocity
  • All vary with the amount of water vapor present

http//antwrp.gsfc.nasa.gov/apod/image/0102/sonicb
oomplane_navy_big.jpg
Photo credit Ensign John Gay
42
ATMS 320 Hygrometry
  • Measurement of physical properties of moist air
    spectroscopic hygrometer
  • Measures the attenuation of certain bands in the
    spectrum due to water vapor absorption
  • 1000 to 3000 nm infrared band is ideal since
    there is small amounts of solar and earth
    background radiation
  • Also, glass is transparent up to about 2800 nm
    and can be used to enclose the sensor source and
    detector

Beers law
43
ATMS 320 Hygrometry
  • Spectroscopic hygrometer Beers law applies for
    measuring humidity if
  • Water vapor were the only absorbing gas
    (satisfied for particular wavelengths)
  • The instrument wavelength resolution were small
    compared to the absorption lines (satisfied if a
    laser source is used)
  • Laser hygrometers are expensive and sensitive to
    orientation
  • IR broadband hygrometers are used

44
ATMS 320 Hygrometry
  • Spectroscopic hygrometer IR hygrometers
  • Sources and detectors drift with time
  • Windows change or get dirty
  • Impacts source strength, I0
  • Uses relative difference between two bands
    absorbing band (2600 nm) and non-absorbing or
    reference band (2300 nm). This subtracts out the
    apparent changing source strength

45
ATMS 320 Hygrometry
  • IR hygrometer
  • Two filters are rotated into the beam
  • Filter wheel allows sampling at three different
    times during its rotation while the absorbing
    (VW), neither (VD), or reference (VR) filters are
    in the beam

transfer equation of IR hygrometer
where l W, D, or R
46
ATMS 320 Hygrometry
  • IR hygrometer
  • Normalized signal
  • where S is the sensor static sensitivity
  • Eliminates drift and is insensitive to variations
    in source strength

It is necessary to also measure air temperature
and pressure to obtain absolute humidity
47
ATMS 320 Hygrometry
  • Spectroscopic hygrometer Lyman alpha
  • Uses Lyman-alpha emission line of atomic hydrogen
    at 121.56 nm (UV) as the source radiation
  • Windows made from magnesium fluoride
  • Oxygen and ozone are weak emitters at this
    wavelength
  • Motor and filter wheel not used
  • Transmission of windows changes due to
    interaction of the magnesium fluoride with
    atmospheric constituents

http//www.mierijmeteo.demon.nl/mierij/research/ly
man.htm
48
ATMS 320 Hygrometry
  • Spectroscopic hygrometer Lyman alpha (cont.)
  • Drift rate correction requires a reference
    instrument
  • Lyman alpha hygrometer is simpler, smaller, and
    much faster than the IR hygrometer
  • Suitable for research aircraft and for tower
    measurements of turbulence (both requiring a very
    fast response)

http//www.mierijmeteo.demon.nl/mierij/research/ly
man.htm
49
ATMS 320 Hygrometry
  • Attainment of Vapor-Liquid or Vapor-Solid
    Equilibrium dew- and frost-point hygrometer
  • Operates by cooling a surface until vapor-liquid
    or vapor-solid equilibrium is achieved
  • Frost or dew formation on the mirror is detected
    with a light-emitting diode and one or more
    photodetectors sense the change in light
    scattering when frost or dew forms on the mirror

Receives decreasing light if frost or dew has
formed
Receives light only if frost or dew has formed
50
ATMS 320 Hygrometry
  • Dew- and frost-point hygrometer (cont.)
  • Control unit uses the ratio of light received by
    the two detectors to determine if mirror heating
    or cooling is required
  • Control system controls current through the
    thermocouple heat pump and regulates the mirror
    temperature to the point where dew or frost just
    begins to form
  • Must avoid overshoot and still follow changes in
    ambient humidity quickly

51
ATMS 320 Hygrometry
  • Dew- and frost-point hygrometer (cont.) issues
  • Difficult to measure mirror temperature without
    interfering with the detection of frost or dew
  • Control unit must be capable of detecting rapid
    change
  • Water-soluble matter on the mirror can lower
    dew-point
  • Formation of very small droplets increases
    dew-point
  • Presence of supercooled water leads to error

52
ATMS 320 Hygrometry
  • Attainment of Vapor-Liquid or Vapor-Solid
    Equilibrium saturated salt solution (dewcel)
  • Contains a saturated solution of lithium chloride
    (LiCl) applied to a glass cloth that surrounds a
    temperature measuring device
  • A heater raises the solution to, and maintains it
    at, the equilibrium temperature

http//eol.jsc.nasa.gov/EarthObservatory/EffectofD
roughtonGreatSaltLake.htm
53
ATMS 320 Hygrometry
  • Chemical reactions
  • Remove the water vapor by use of a chemical
    reagent and then weigh the resulting water

http//www.drbrainzlab.com/drbrainzfiles/gallerydo
c_drfrankenstein.html
54
ATMS 320 Hygrometry
  • Factors in choosing a humidity sensor
  • Cost
  • Accuracy
  • Maintenance required
  • Speed of response
  • Power consumption

http//sargentwelch.com/product.asp_Q_pn_E_WLS4274
05FEA
55
ATMS 320 Hygrometry
  • Psychrometers - issues
  • Low-cost when hand-held
  • High-cost when automated
  • Automation made difficult by wick contamination
    and providing an adequate supply of pure water to
    the wick
  • Most sources of error can be readily detected
  • Requires adequate ventilation
  • Less susceptible to drift

http//sargentwelch.com/product.asp_Q_pn_E_WLS4274
05FEA
56
ATMS 320 Hygrometry
  • Sorption sensors - issues
  • Small size
  • Low cost
  • Moderate accuracy
  • Low power consumption
  • Maintenance requirements mainly are coping with
    drift
  • Problems rarely detectable by visual examination
  • Intercomparison between other stations needed to
    check for drift

http//sargentwelch.com/product.asp_Q_pn_E_WLS4274
05FEA
57
ATMS 320 Hygrometry
  • Spectroscopic hygrometers - issues
  • High cost
  • High power consumption
  • Potentially high maintenance requirements
  • Lyman-alpha has very fast response and subject to
    severe drift
  • IR absorption hygrometers have very limited
    response times
  • Limited applications

http//sargentwelch.com/product.asp_Q_pn_E_WLS4274
05FEA
58
ATMS 320 Hygrometry
  • Chilled-mirror dew-point sensors - issues
  • High cost
  • High power consumption
  • Slow response times
  • High maintenance requirements
  • High accuracy
  • Wide range of observable dew-points (at very low
    dew-points)
  • Well suited for laboratory applications

http//sargentwelch.com/product.asp_Q_pn_E_WLS4274
05FEA
59
ATMS 320 Hygrometry
  • Exposure of humidity sensors
  • Air temperature is almost always a requirement,
    so the exposure of humidity sensors is closely
    related to the exposure of air temperature
    sensors (Chap. 4)
  • Psychrometers require good ventilation and
    shielding from solar radiation

http//www.nps.gov/yell/
60
ATMS 320 Hygrometry
  • Psychrometers
  • Require good ventilation and shielding from solar
    radiation
  • Avoid contamination by salts which inhibit
    evaporation (problem for sites near the ocean)
  • Cannot work in freezing weather

61
ATMS 320 Hygrometry
  • Sorption sensors
  • Shield from radiation
  • Avoid forced aspiration
  • Dust filter
  • Keep liquid water away from sensor and dust
    filter
  • Sensitive to contamination by some gases (e.g.
    SO2)

http//cyranosciences.com/technology/sensor
62
ATMS 320 Hygrometry
  • Spectroscopic hygrometers
  • Same exposure requirements as for measuring air
    temperature
  • Lyman-alpha requires another kind of hygrometer
    to provide drift compensation

63
ATMS 320 Hygrometry
  • Chilled-mirror hygrometers
  • Mirror contamination problems seriously
    compromise the performance of this sensor in the
    field (contamination cannot be completely avoided
    for any reasonable outdoor exposure)
  • Requires a lot of attention from skilled
    technicians

http//www.nyad.com/principles_of_moisture.htm
64
ATMS 320 Hygrometry
  • Exposure issues general
  • Humidity at the measurement site may differ from
    the value at surrounding stations due to
    localized rainfall, proximity to a lake or river
    upwind of the site, and changes in nearby farming
    practice.

http//www.ehabweb.net/clake.html
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