EN3004 Air Pollution Control Engineering Lecture 8 (24S1) PDF

Summary

This document contains lecture notes for a course on air pollution control engineering. It covers topics such as project assignments, syllabus, course schedule, and various engineering approaches to air pollution control.

Full Transcript

EN3004
Air Pollution Control Engineering
Week 8

Project Assignment &
Engineering Approaches for Air Pollution Control

Tuti Mariana Lim

School of Civil and Environmental Engineering
Nanyang Technological University

1
 Syllabus & Course Schedule
Lecture: Friday 15:30-17:20 Dr. Maszenan Venue: LT18
Tutorial: Friday 09:30-10:20 (G1@TR+35) & 12:30-13:20 (G2@TR+29)
Lecturer Week (date) Content

Tuti Lim 1 (16 Aug) Course Briefing; Introduction to Air Pollution
Tuti Lim 2 (23Aug) Air Pollution Control: Regulation, Philosophy & Monitoring, Tutorial 1
Tuti Lim 3 (30 Aug) The Atmosphere & Meteorology, Atmospheric Stability; Tutorial 2
Tuti Lim 4 (06 Sep) Air Quality Modeling & Plume Dispersion Models; Tutorial 3
Tuti Lim 5 (13 Sep) Indoor Air Pollution, Human Exposure, Box Model; Tutorial 4; Group Project
Tuti Lim 6 (20 Sep) SOD, Acid Rain, Green House Gases & Climate Change; Tutorial 5
Tuti Lim 7 (27 Sep) Special Issues: Combustion related emissions, Quiz #1; Tutorial 6 S5

No tutorial on week 1 & week 8 ; NTU Recess Week (30 Sep – 4 Oct)

Tuti Lim 08 (11 Oct) Disc on Project Assignment, General Idea of Air Pollution Control Approach
Tuti Lim 09 (18 Oct) Properties of Particles and Particle Collection Mechanism; Tutorial 8
Tuti Lim 10 (25 Oct) Particulate matters control; Tutorial 9
Tuti Lim 11 (01 Nov) VOCs and HCs – Characteristic & Control; Tutorial week 10
Tuti Lim 12 (08 Nov) Oxides of Sulfur and Nitrogen – Characteristic and Control; Tutorial 11

Tuti Lim 13 (15 Nov) Control of mobile source pollutant; Quiz #2; Tutorial 12

Note: Lecture materials may not be in accordance with the scheduled lectures.
SOD : Stratospheric Ozone Depletion
 EN3004 Project Assignment
Objectives
To train students :
Familiarize IAQ sampling process (sample collection, PM & GC-
MS working principles, instruments, etc)
Conduct proper data analysis through this project
Improving communication skills & promote team work.
High intensity light source used to
illuminate the room. The particles pass
through the light source and counting can
be done either via light scattering, light
obscuration & direct imaging.
Light scattering: redirected light is
detected by a photo detector.
Light obscuration/blocked: detect
the loss of light detected.
Direct imaging: HD camera to record passed particles & analyzed by computer to
measure particle characteristics. 3
 Gas Chromatography -Mass Spectrometry
(GC-MS)

Separation of volatile organic compounds
Separation is based on the vapor pressure and polarity of the
components.

4
 Working Principles
GC utilizes a capillary column to do the separation.
The difference in the chemical properties between different molecules in
a mixture will separate the molecules as the sample travels the length of
the column.
The molecules take different times (called the retention time) to come
out of the GC.

Injection
Recorder
port
Oven

Detector

Column
Nitrogen
cylinder

5
 The MS in the downstream will capture, ionize, accelerate,
deflect, and detect the ionized molecules separately.

The MS does this by breaking each molecule into ionized
fragments and detecting these fragments using their mass
to charge ratio.

6
What kind of information can MS give you?

 Molecular weight
 Elemental composition
 Structural information
7
 GC- separate VOCs
MS - analyze compositions

Each component ideally produces a specific spectral peak
The size of the peaks is proportional to the quantity of the
corresponding substances

8
How to read your experiment results?

Gas chromatogram
peak1

9
Peak 1 Mass spectrum

10
11
 Basic Requirement on the Report
1. Each group will submit one group report
2. The group report should not exceed 2000 WORD Counts with font size
of 12, font style being Times New Roman and 1.5 spacing, please include
a cover page that contains the name of each group member with
signature.
3. Please make sure to include the following information/discussion in your
report:
The sampling location you’ve chosen.
VOCs you’ve found and possible sources.
Compare your results with another given data and discuss the
differences and possible reasons.
Submit your group IAQ report by 08/11/2024 (week #12)
Central Environmental & Science Engineering Lab (CESEL)
Location: N1-B2A-02
Officer in Charge: Maria Chong Ai Shing 12
 A Good Project Report
❑Background or introduction (highlight the importance of
IAQ control, possible sources of VOCs in your selected
location, their impacts to environments, etc)
❑Objective /purpose of this project
❑Methodology/experiments of air sampling
❑Results and discussion (what have been found in the
sample, concentration levels vs. relevant emission standards,
consequences, comparison with provided data, etc.)
❑Conclusion & recommendation (e.g. how to improve air
quality).
❑References

13
Today’s Lecture

14
 Engineering Approaches for
Air Pollution Control

⚫ Three general approaches for air pollution control

✓ Dispersion

✓ Process change and pollution prevention

✓ Tailpipe control
⚫ Basic concepts in downstream pollution control processes
✓ Efficiency and penetration
✓ Economic considerations
✓ Units of measurement

⚫ Properties of particulate matters
15
General Idea of Air Pollution Control

⚫ What?
?
⚫ Why?

⚫ How?

16
Recap…..

Air Pollutants are…
Substances that are not part of composition of “air”, which in
sufficient amount can be harmful to people or their environment.

⚫ Primary Air Pollutants –
directly emitted from the
source

⚫ Secondary Air Pollutants –
formed from reactions between
existing air pollutants under
certain conditions

VOC + NOx + Heat + Sunlight = Ozone

17
Recap…..

Sources of air pollution : Natural & Human activities 18
Recap…..
Effects of Air Pollutions

Clear Day

Hazy Day

19
How to Control Air Pollutions?

20
 Three General Approaches
for Air Pollution Control

(1) Improved dispersion
(2) Process change and pollution prevention
(3) Downstream (Tailpipe) pollution control devices

Which one is the first choice?

21
 (1) Improved Dispersion (Dilution) of Air Pollutants
"Dilution is the solution to pollution"
⚫ Tall stacks
To emit pollutants so high that by the time
they reach ground level they’ve been diluted
by clean air to non-hazardous levels.
In the atmosphere,
SO2 + oxidants --> H2SO4.
Dispersed SO2 => dispersed H2SO4.
Acidic rain and snow.

In a sparsed populated
In a densely populated
world
world
29,000 persons/km2
1 person/km2

Smelter at Sudbury, Ontario
Singapore: 8,000 persons/km2 500 m tall smokestack
22
(1) Improved Dispersion (Dilution) of Air Pollutants

⚫ Intermittent control schemes
✓ Intermittent control schemes ban some activities in
times of poor dispersion
✓ In most cases, the short-term emission reduction is
brought about by a plant shutdown.

⚫ Relocate the plant
A new plant can be located where its emission will have
their greatest impact in non-populated areas.
Basis for industrial zoning and land-use planning regulation
Bhopal Gas Tragedy
23
 Bhopal Gas Tragedy

⚫ 40 tonnes of methyl isocyanate (MIC) was released.
⚫ MIC is extremely toxic, and can damage by inhalation,
H3C-N=C=O.
ingestion and contact in quantities as low as 0.4 ppm.
⚫ It was the the world's worst industrial Disaster.

The plant was located close to a densely populated area
24
(2) Process Change and Pollution Prevention

⚫ Replacing oil-based paints with water-based paints to
reduce HC emission
⚫ Changing open burning of wastes to closed burning
⚫ Switching fuels
Coal Mineral oil natural gas Hydrogen

H H
C C
H C C C H
H H H H
C C C H H H H H H H H H H
H H
H C C C C H C C C C C C C C C C
H H H H
H H H H H H H H H H C C C C H H
H C C C C H H H H H
C C C
Decane H:C = 2:1 Propane H:C = 2.7:1 Methane H:C = 4:1 Hydrogen H:C = 
H C C C H
C C
H H
Corones H:C = 0.5:1

25
 Changes in Vehicle Systems

http://autozine.kyul.net/technical_school/engine/te
ch_pic_eng_prius.jpg

Hybrid
http://www.redjellyfish.com/newima
ges/merlin.jpg

Fuel Cell http://www.evworld.com/archives/test
drives/carpicts/ecom_sm.jpg

Battery-Electric

Typical Engine Combustion:
Fuel + Air =>
Hydrocarbons + Nitrogen Oxides + Carbon Dioxide + Carbon Monoxide + water
26
(3) Downstream (Tailpipe) Air Pollution Control

⚫ Gravity settling (large drums or vessels)
⚫ Filtration
⚫ Chemical scrubbing (absorption)
⚫ Activated carbon adsorption
⚫ Biological oxidation – biofiltration or bioscrubbing
⚫ ………..

pollutants Clean stream
Main process
S42
Control device

27
28
 First choice
process change and pollution prevention

Second choice
downstream control device

Last choice
improved dispersion

for better air pollution control !

29
 Outdoor Air Pollution Control
Downstream control devices Improved dispersion

Process change:
Improved
Burns natural gas
Dispersion

Source: John Kraemer, 2002 30
Basic concepts in downstream
pollution control processes

31
Selection of Appropriate Air Pollution
Control Devices

⚫ Degree of reduction of emissions required to
meet emission standards

⚫ Process and effluent characteristics

⚫ Equipment capacities, efficiency and
limitations

⚫ Capital investment and operation costs

S37

32
 Gravity Settlers

Electrostatic
Precipitators (ESP)

33
Cyclones

34
Surface Filter
(Baghouse)

35
Scrubber

36
 Efficiency and Penetration
Incoming amount Outgoing amount
Collector

Incoming amount – Outgoing amount
Efficiency,  =
Incoming amount

Outgoing amount
Penetration, p =
Incoming amount

p = 1-  S32

the fraction not collected
37
 Efficiency and Penetration
Q0 Q1
C0 Collector C1

Efficiency,  = (Q0C0-Q1C1)/ Q0C0 = 1- Q1C1/ Q0C0

Penetration, p = 1-  = Q1C1/ Q0C0
C0: Influent concentration; Q0: Influent volumetric flow rate
C1: Effluent concentration; Q1: Effluent volumetric flow rate

38
Example 1:
Four control devices are placed in series, each of 90% efficiency.
Determine the overall efficiency,  (Assume the volumetric flow rate
does not change).

C0 C1 C2 C3 C4
90% 90% 90% 90%
Q0 Q0 Q0 Q0 Q0

p1 = C1/C0; p2 = C2/C1; p3 = C3/C2; p4 = C4/C3

p (overall) = C4/C0 = (C1/C0) (C2/C1) (C3/C2) (C4/C3)
= ( p1)( p2)( p3)( p4) = (1- 1) (1- 2) (1- 3) (1- 4)

 (overall) = 1- p (overall) = 1- ( p1)( p2)( p3)( p4)

In general, for n series of control devices
Ans: 99.99%
 (overall) = 1 - p (overall) = 1- ( p1)( p2)…( pn)
39
Four control devices are placed in series with different efficiencies.
The volumetric flow rate is changed after each device.

?
Efficiency,  = ?
Penetration, p=?

C0 C1 C2 C3 C4
1 2 3 4
Q0 Q1 Q2 Q3 Q4

40
In the current air pollution literature, it is common to
refer to the high efficiencies required for waste
incinerators as “four nines”, which means the
control efficiency is ___________.
?
A. 99.99
B. 99.9999%
C. 99.99%

41
 Economic Considerations

Factors affecting air pollution control costs
⚫ The amounts of gas to be treated Quantity
⚫ Pollution removal efficiency Quality
S27
For cost savings, we need to:

⚫ Try to use standard-size pollution control devices

⚫ Control fluid velocity in air pollution control equipment (~12 m/s)

⚫ Minimize volumetric flow rate and pressure drop

⚫ Resource recovery pump cost vs. capital
charge for equipment
Power ≈Q P/ 
42
 Fluid Velocities
in Air Pollution Control Equipment

Q= Db2 V
4

velocity cost of pumping
Diameter

Cost of the pipe

pumping cost
+
capital cost of pipes and ducts
43
 Minimizing Volumetric Flow Rate
and Pressure Drop

Q P
Power = , P = P1 − P2


Q P Power

Q = volumetric flow rate
η = fan or blower efficiency
P1 = inlet absolute pressure
P2 = outlet absolute pressure
44
 National Ambient Air Quality Standards
POLLUTANT STANDARD STANDARD
VALUE * TYPE
Carbon Monoxide (CO)
8-hour Average 9 ppm (10 mg/m3) Primary
1-hour Average 35 ppm (40 mg/m3) Primary

Nitrogen Dioxide (NO2)
Annual Arithmetic Mean 0.053 ppm (100 µg/m3) Primary & Secondary

Ozone (O3)
1-hour Average 0.12 ppm (235 µg/m3) Primary & Secondary
8-hour Average 0.08 ppm (157 µg/m3) Primary & Secondary

Lead (Pb)
Quarterly Average 1.5 µg/m3 Primary & Secondary

Particulate (PM 10) Particles with diameters of 10 micrometers or less
Annual Arithmetic Mean 50 µg/m3 Primary & Secondary
24-hour Average 150 µg/m3 Primary & Secondary

Particulate (PM 2.5) Particles with diameters of 2.5 micrometers or less
Annual Arithmetic Mean 15 µg/m3 Primary & Secondary
24-hour Average 65 µg/m3 Primary & Secondary

Sulfur Dioxide (SO2)
Annual Arithmetic Mean 0.030 ppm (80 µg/m3) Primary
24-hour Average 0.14 ppm (365 µg/m3) Primary
3-hour Average 0.50 ppm (1300 µg/m3) Secondary
* Parenthetical value is an approximately equivalent concentration. 45
(from http://www.epa.gov/air/criteria.html)
WHO Guidelines (1999) for Common Pollutants
Pollutant Annual ambient Guideline value Concentration at Exposure time
air concentration (µg/m3) which effects on
(µg/m3) health start to be
observed (µg/m3)
CO 500-7000 100,000 Not applicable 15 min
60,000 30 min
30,000 1 hour
10,000 8 hours

Lead 0.01-2.0 0.5 Not applicable 1 year

NO2 10-150 200 365-565 1 hour
40 1 year

O3 10-100 120 Not applicable 8 hour

SO2 5-400 500 1000 10 min
125 250 24 hour
50 100 1 year

46
(from http://www.who.int/inf-fs/en/fact187.html)
 Units of Measurement (Gas)
Volume
volume of pollutant gas *106
Parts Per Million ppm =
total volume of gas mixture
volume of pollutant gas *109
Parts Per Billion ppb = total volume of gas mixture
volume of pollutant gas *1012
Parts Per trillion ppt = total volume of gas mixture

μg/m3; mg/m3

Mass
47
 Conversion: ppm to mg/m3 & μg/m3

At T=298.15 K (25C), P=1 atm, 1 mol = 24.45 L

[ mg ]= ppm X MW 1000 MW
[ μg ] = ppm X
m3 24.45 m3 24.45

MW 273.15 (K) P (atm)
[ mg ] = ppm X X X
m3 22.4 T (K) 1 (atm)

1000MW 273.15 (K) P (atm)
[ μg ]= ppm X X X
m3 22.4 T (K) 1 (atm)

48
 Properties of Particulate Matters

PM – sums of all solid and liquid particles suspended in air,
many of which are hazardous.
-Vary in size, shape, composition & origin
49
 Common PM Pollutants
Solid particles larger than colloidal size capable of
Dust
temporary suspension in air
Finely divided particles of ash entrained in flue gas.
Fly ash
Particles may contain unburned fuel
Particles formed by condensation, sublimation, or
Fume chemical reaction, predominantly smaller than 1g
(tobacco smoke)
Dispersion of small liquid droplets of sufficient size to fall
Mist
from the air

Smoke Small gasborne particles resulting from combustion

Particle Discrete mass of solid or liquid matter

Fog Visible aerosol

Soot An agglomeration of carbon particles
50
 How Particulate Pollutants are Formed?
Midsize
Coarse particles(0.005-0.1μ)
Finest particles
particles (0.1-2μ) are
(2-100μ) formed bythe
enters agglomeration
atmosphere
mechanically generated and/or
by chemical
condensation
and can conversion
of
be removedhot by of gases
vapors. and
Overtime
capturing device
vaporasingravity
they grow
such thebyair. They can beonto
agglomeration
settler.. removed
each by rainout
other either(drops
in gasinphase
clouds) or washout
or inside cloud(rainfall).
or fog droplets.
Agglomeration process is slower than rainout & washout.
1: Condensation processes
atmospheric reactions
combustion

2. Accumulation processes
3 combustion
2
coagulation
1 condensation on existing particles
Rainout atmospheric reactions
and Sedimentation
Washout
3. Mechanical processes
wind blown dust
Emissions
Particle in air are either: Sea spray
1.Directly emitted (primary particles) – 3rd peak. Volcanoes
2.Indirectly formed from gaseous precursors in Plant Emitted Particles
the air (secondary particles) – 1st & 2nd peaks. 51
Coagulation: Particles collide and stick together.

Condensation: Gases condense onto a small solid
particle to form a liquid droplet.

Cloud/Fog Processes: Gases dissolve in a water droplet and chemically
react. A particle exists when the water evaporates.

Sulfate

Chemical Reaction: Gases react to form particles.
Source: Timothy S. Dye, et al. 52
 In the area close to the exhaust the aerosol shows high concentration and
narrow size distribution (primary particles).
As the air carries the aerosol away from the exhaust, the particles collide
with each other forming larger agglomerates (decreasing the number of
smaller particles.) This process also causes broadening of the size
distribution.
53
 Characteristics of Particulate Matters
N
The efficiency of the particle collection mechanisms E
X
strongly depends on particle size. T
W
e
The particle size distribution of flue gas determines the e
k
operating conditions necessary to collect the particles and
control device’s collection efficiency (control concern).
Particle size distribution are important in determining the
behavior of particles in the respiratory tract (health
concern).

dp > 10 m 1 < dp 10 m

PM2.5 Coarse 2.5 m < dp < =10 m

Particles less than 0.1 μm Fine 0.1 m < dp