1. Air Dispersion Modeling & ALOHA
Prepared by:
Environment Section, HSEF Department
Haldia Petrochemicals Limited
2. Bhopal Tragedy: Environmental Perspective
Incident – Leak of Methyl Isocynate
Apart from system failure, other important reasons for mass
casualties were –
Low atmospheric temperature
Timing of accident
Wind direction
Release height
Molecular weight higher than air
The casualties could have been minimized, if the incident would
have occurred in daytime !!!!
3. Relevance in HPL Perspective
Handling of large quantity of hydrocarbons
Heavier than air
Highly Flammable in nature
Large no. of small sources capable to create havoc at local levels
Handling of highly toxic gas like Chlorine
Very low TLV
Heavier than air
4. What is Dispersion?
Dispersion is “Diffusion” of air contaminants in air
Atmospheric dispersion modeling is the mathematical
simulation of how air pollutants disperse in the ambient
atmosphere.
The dispersion models are used to estimate or to predict
the downwind concentration of air pollutants emitted from
sources such as industrial plants and vehicular traffic.
The models are typically employed to determine whether
existing or proposed new industrial facilities are or will be
in compliance with the National Ambient Air Quality
Standards (NAAQS)
5. Influencing Factors to Dispersion
Meteorology
Wind Speed
Wind Direction
Atmospheric Stability
Ambient Air Temperature
Height to the bottom of inversion
6. Wind
Wind is the natural horizontal motion of the atmosphere. It
occurs when warm air rises, and cool air comes in to take its
place
Wind is caused by differences in pressure in the atmosphere. The
pressure is the weight of the atmosphere at a given point. The
height and temperature of a column of air determines the
atmospheric weight.
Because cool air weighs more than warm air, a high pressure
mass of air is made up of cool and heavy air.
Conversely, a low pressure mass of air is made up of warmer
and lighter air.
Differences in pressure cause air to move from high pressure
areas to low pressure areas, resulting in wind.
7. Atmospheric Stability
Atmospheric stability refers to the vertical motion of the
atmosphere.
Unstable atmospheric conditions result in a vertical mixing.
Typically, the air near the surface of the earth is warmer in the day time
because of the absorption of the sun's energy. The warmer and lighter
air from the surface then rises and mixes with the cooler and heavier
air in the upper atmosphere causing unstable conditions in the
atmosphere.
This constant turnover also results in dispersal of polluted air.
Stable atmospheric conditions usually occur when warm air is above
cool air and the mixing depth is significantly restricted.
8. Atmospheric Stability
Adiabatic Lapse Rate : Negative of temperature gradient in the
atmosphere in adiabatic conditions. It equals to ~ 1o C/100 m.
Environmental Lapse Rate: Equals wet adiabatic lapse rate - ~
0.6o C/100 m
A
B
C
D E
ELR>ALR
Unstable
ELR=ALR
Neutral
ELR<<ALR
Strongly Stable
Temperature
A
l
t
i
t
u
d
e
9. Stability Class
A – Very Unstable
B - Unstable
C – Slightly Unstable
D - Neutral
E – Slightly Stable
F - Stable
10. Stability Class
Wind
Speed, m/s
Daytime Solar Insolation Night time Cloud Cover
Strong Moderate Slight <50% >50%
<2 A A-B B E F
2-3 A-B B C E F
3-5 B B-C C D E
5-6 C C-D D D D
>6 C D D D D
11. Inversion
Stable atmospheric conditions usually occur when warm air is
above cool air and the mixing depth is significantly restricted.
This condition is called a temperature inversion.
During a temperature inversion, air pollution released into the
atmosphere's lowest layer is trapped there and can be removed
only by strong horizontal winds.
Because high-pressure systems often combine temperature
inversion conditions and low wind speeds, their long residency
over an industrial area usually results in episodes of severe smog.
14. Influencing Factors
Terrain Elevation - Both source as well as receptor
Location, height and width of any obstruction
15. Building Effects or Downwash
Building effects or downwash: When an air pollution plume
flows over nearby buildings or other structures, turbulent eddies
are formed in the downwind side of the building.
Those eddies cause a plume from a stack source located within
about five times the height of a nearby building or structure to
be forced down to the ground much sooner than it would if a
building or structure were not present.
The effect can greatly increase the resulting near-by ground-level
pollutant concentrations downstream of the building or
structure.
If the pollutants in the plume are subject to depletion by contact
with the ground (particulates, for example), the concentration
increase just downstream of the building or structure will
decrease the concentrations further downstream
