Wastewater Treatment Lecture 14 PDF

Summary

This lecture discusses wastewater treatment, including primary, secondary, and tertiary treatment methods, and the importance of BOD testing. It also covers pathogen removal techniques and drinking water treatment processes. The lecture details the various methods used to treat wastewater, and their impacts on water quality. Topics also included the role of microorganisms in these processes.

Full Transcript

Wastewater Treatment
 Nature of Wastewater
Domestic wastewater is a combination
of human feces, urine, and
“graywater”
Gray water = water from washing,
bathing, and meal preparation

How do we treat wastewater?
 Based on one major
metric: BOD
Biological Oxygen
Demand: the amount of
dissolved oxygen consumed
by microorganisms during
the biochemical oxidation of
organic and inorganic
matter.

Organics –carbon-based
Inorganics-ammonia/N
How do we
perform the BOD
test?
BOD5 test: measure of oxygen
consumed by a microbial
community of heterotrophic
bacteria in dark conditions at
room temperature over 5 days
Dissolved oxygen determined
at time 0, and after a 5-day
incubation period
Carried out on a series of
dilutions of incoming
wastewater
https://www.youtube.com/
watch?v=v33CgWJ2TZ0
How do we perform
the BOD test?
BOD (mg/L) = D1-D5/P
Where,
D1 = initial dissolved oxygen (DO;
mg/L)
D5 = final DO (mg/L)
P = decimal volumetric fraction of
sample used
Why use this test?
Determines amount of oxygen needed for
biological treatment of organic matter
present in wastewater
Determines required size of treatment
facilities needed
Required via wastewater discharge
permitting

BOD5 of wastewater ranges 110 – 440 mg/L
and by the end? Reduced by 95%
The Wastewater Treatment
Process
Main goal is to remove and
degrade organic matter under
“controlled conditions”
Three major steps: primary,
secondary, tertiary treatment
Primary Treatment
Physical separation of large solids from the
waste stream
Metal grating  Bar screens  Grit tanks 
primary settling tank
~50% of suspended organic solid settle as
sludge in setting tank = primary sludge
Secondary Treatment
Biological degradation through
decomposition by microorganisms
Other benefit? Pathogens also
reduced in number
This biological treatment is
performed by (1) aeration tanks (2)
trickling filter beds (3) sewage
lagoon
Disinfection is usually done after
one of these treatment steps
Trickling Filters
Composed of plastic units but older
facilities composed of stones or plastic
sheets
Effluent pumped over onto a filter bed
which allows for microbial growth and
biofilms form
Microorganisms in the biofilm intercept
organics as it trickles past them and
degraded or decomposes them aerobically
Decomposition helps aid in biofilm
maintenance as OM converts to microbial
biomass via growth
This biofilm is a zoogleal film composed of
bacteria, fungi, algae, protozoa
BOD removal by TFs? ~85%
Schematic of biofilm in TF bed
Vayenas 2011
Aeration tanks
Activated sludge process where effluent
mixed with bacterial-rich slurry
Air or pure oxygen gas pumped into
mixtures to encourage bacterial growth and
aerobic decomposition
Secondary sludge is removed, added to
primary sludge, and anaerobically digested
to produce biosolids
Pathogens are removed during this
activated sludge process from (1) other
microbes outcompeting them in sludge (2)
pathogen adsorption to sludge itself
through physical processes
Detention time in aeration tanks = 4-8
hours
Activated
Slduge
Aeration tank contents
Mixed liquor suspended solids (MLSS) is its contents
Organic component of MLSS is mixed-liquor volatile
suspended solids (MLVSS)
Activated sludge must be maintained with a proper
ratio of substrate (organic load) to microbes (food-
to-microorganism ratio; F/M)

F/M = (Q x BOD5)/(MLSS x V)

where,

Q = flow rate of sewage in million gallons per day (MGD)
BOD5 we know!
MLSS = in mg/L
V = volume of aeration tank in gallons
Aeration tank contents
F/M is typically 0.2 to 0.5 lb BOD5/day/lb MLSS
What this means: many more microbes than food
Low F/M (given above) is what we want! Microbes
that are starving will breakdown wastewater more
efficiently

F/M = (Q x BOD5)/(MLSS x V)

where,

Q = flow rate of sewage in million gallons per day (MGD)
BOD5 we know!
MLSS = in mg/L
V = volume of aeration tank in gallons
More about activated sludge
Processes can be modified for
nitrogen or phosphorous removal
Nitrogen = encourage nitrification
followed by denitrification
>>>Nitrifying bacteria must be
greater growth than other
heterotrophic bacteria --- can be
accomplished through an older sludge
age as nitrifiers are slow growers
>>>To encourage denitrification,
anaerobic conditions must be set
Phosphorous = modification of the
A/O process
>>> anaerobic/oxic process has an
anaerobic zone added upstream of
aeration tank
Tertiary Treatment
Further reduces organics, turbidity, N, P, metals,
pathogens
Physiochemical treatment such as….
Coagulation, Filtration, Activated Carbon Adsorption,
Reverse Osmosis, Disinfection
Pathogen Removal
Processes before tertiary treatment remove most
pathogens, but in order to reuse water we must
make sure they are reduced even further!
 Pathogen Removal
Processes before tertiary treatment remove most pathogens,
but in order to reuse water we must make sure they are
reduced even further!
Activated sludge removes 90% of enteric bacteria, up to 99%
of enteroviruses and rotaviruses, up to 90% of Giardia and
Cryptospiridium

”Crypto” is a genus of eukaryotic parasites that cause
respiratory and GI illness

ttps://www.youtube.com/watch?v=xHztEOsiZ9E
Cryptospiridium
Transmitted from
animals to human via
waste via zoonotic
species
Oocysts are excreted by
host and then when in a
new host, oocysts
release sporozoites and
then parasitize epithelial
cells
Oocysts are very hardy
and difficult to disinfect!
Tertiary treatment of a
mixed-sand media
filtration will remove
almost all of these!
Septic tanks
Wastewater enters tank and oils
rise to top, solids sink to bottom
Anaerobic decomposition occurs
that results in septic tank sludge
Wastewater in tank for 24-72
hours before channeling to a
drainage field but sometimes
residual sludge must be pumped
out.
Contaminants are much greater
in septic tanks and can pollute
groundwater during leakage
Beneficial for rural or suburban
populations of low densities
Wetlands https://texanbynature.org/projects/constructed-wetlands/

An additional treatment for secondary effluents via
constructed wetlands
Vegetation provides increased surface area for
microbes and also helps filter and remove
contaminants
Two types of constructed wetlands: free water
surface systems (FWS) and subsurface flow systems
(SFS)
FWS = natural wetland or marsh exposed to atmosphere
SFS = channels filled with media to support vegetation
Drinking Water Treatment
In the past, very basic treatment
processes were implemented such
as slow sand filtration
The germ theory of disease was
created in 1870s, and Koch
demonstrated chlorine kills bacteria
in 1880s
Disinfection used during typhoid
fever caused large declines in
outbreaks
Process Train
Simplest treatment -
chlorination to disinfect
Filtration may be added
through sand or coal to
reduce turbidity
In-line filtration adds a
coagulant to flocculate
suspended particles for
easier filtration
Coagulation
The addition of chemicals to
remove dissolved and suspended
solids by sedimentation and
filtration
Most common chemicals include
hydrolyzing metal salts such
“alum” or charged organic
molecules called polyelectrolytes
These can be added before or
after flocculation but before the
filtration step
Flocculati
on
Physical process of
stirring water to
increase particle
collision and promote
larger particles
coming together so
filtration is easier
Microorganisms in
water will be trapped
in these ”floccs” and
removed
Sedimentati Sedimentation allows settling of particles
through a sand bed and filtration is filtering
on & out particles
Together, removal efficiencies will remove >
Filtration 99.99% of microorganisms, including viruses
 Filtration is an important barrier in the removal of
protozoan parasites like Giardia lamblia and

Filtration Cryptosporidium.
Cysts and oocysts are resistant to inactivation by
disinfectants so additional steps must be used to
prevent illness
Drinking Water
Distribution Systems
Once treated, water is transported
miles to consumers
During transport, quality can degrade
due to several factors
Reduced impact of disinfectant
residual
Biofilm sloughing
Pipe breaks and pipe sediments
Regrowth of bacteria in pipes
themselves
Microbial Growth
Bacterial concentrations vary from < 1 CFU
or as high as 106 CFU per milliliter in
distribution water
In pipe biofilms, up to 107 CFU per square
centimeter
Biofilms in pipe sections can be extremely
variable and patchy --- low levels of organic
matter will allow their growth
Biofilms can coexist with chlorine residuals
during distribution
E. coli is 2400X more resistant when attached in
a biofilm versus free-living cells
Legionella in distribution systems
More resistant to chlorine than
even E. coli and small numbers
can routinely survive in pipes
Hot-water tanks in homes and
hospitals favors growth
Legionella survives well at 50C
and can be capable of growth at
42C
Organic Matter
Growth is greatly influenced by
biodegradable OM, temperature, detention
time
Example: Pseudomonas aeruginosa are
able to grow in tap water with low
concentrations of low-molecular weight
organic substrates (acetate, lactate, amino
acids)
Amount of biodegradable OM is difficult to
directly measure
Assimilable organic carbon (AOC) in water
is the biggest issue – 0.1-9% of total
organic carbon can be AOC
Monday
Quiz 6 over todays lecture
Go over Exam 2
Being Organic Pollutants
chapter and last emerging
topic