Wastewater Treatment ENBT 401 (PDF)

Summary

This document includes lecture notes on wastewater treatment, focusing on the physical, chemical, and biological parameters involved. It covers topics such as solids, turbidity, odor, temperature, and chemical oxygen demand (COD).

Full Transcript

Environmental
Biotechnology (ENBT
401)

Wastewater Treatment

Course director: Prof. Dr. Mahmoud
Wafeek
Demonstra
tors:
Afaf Abdelaty Mostafa El-
Mariam Mohandes

Prepared by: Mariam Mohamed Aysha Soliman
Mohamed Donia Wafaa
 ‫رؤية كلية التكنولوجيا الحيوية‬

‫أن تكون كلية معتمدة اكاديميًا ورائدة في مجاالت‬
‫التكنولوجيا الحيوية على المستوى المحلى واألقليمى‬
‫والدولى‬
 ‫رسالة كلية التكنولوجيا الحيوية‬

‫تلتزم كلية التكنولوجيا الحيوية – جامعة مصر للعلوم‬
‫والتكنولوجيا بتخريج مهندس تكنولوجيا حيوية طبقًا للمعايير‬
‫األكاديمية المعتمدة يلبى إحتياجات سوق العمل المحلى‬
‫واإلقليمي في القطاعات الطبية والصيدالنية والزاعية‬
‫والبيئية وإجراء بحوث علمية مبتكرة وتقديم خدمات مجتمعية‬
‫وإستشارات علمية في إطار قيم ارتقائية‪.‬‬
 Wastew
ater
Wastewater is water that has been
affected by human use, including a
range of contaminants from
residential, industrial, agricultural, and
commercial activities.

It typically contains organic and
inorganic pollutants, pathogens, and
various chemical substances, which
can pose risks to human health and
the environment if not properly
managed.
Toilet Factorie
s s
 Wastewater Treatment

Wastewater treatment is a process used to remove contaminants from
wastewater and convert it into an effluent that can be returned to the
water cycle. Once returned to the water cycle, the effluent creates an
acceptable impact on the environment or is reused for various purposes
(called water reclamation).
Importance of wastewater
treatment

Waste reduction

Energy production

Fertilizer production

Save money
Figure 1.
Quantitative assessments of the quality of
wastewater
Physical Chemical Biological
parameters parameter parameters
 Biochemical
 Temperature  Chemical Oxygen Demand
Oxygen Demand
 Solids (COD)
(BOD)
 Turbidity  Dissolved Oxygen
 Total Coliform
 Color  Chlorides, Nitrogen
and Fecal
 Odor  Phosphorus
Coliform Counts
 Sulphur
 E. coli Count

 Pathogens
Physical
Parameters
Solids
 Solid material in wastewater may be dissolved,
suspended, or settled.
 Total dissolved solids or TDS is measured as the
mass of residue remaining when a measured
volume of filtered water is evaporated.
 The mass of dried solids remaining on the filter is
called total suspended solids (TSS) or
nonfiltrable residue.
 Settleable solids are measured as the visible
volume accumulated at the bottom after water has
Turbidity

 Clarity of water is usually measured
by its turbidity. Turbidity is a measure
of the extent to which light is either
absorbed or scattered by suspended
material in water.
 Turbidity is measured by comparing
the intensity of light scattered by the
sample with the intensity of light
scattered by a standard solution.
Odour

 The most characteristic odour of
wastewater is that of hydrogen sulphide
(H2S), which is produced by anaerobic
microorganisms.
 The concentration of malodorous gases
such as hydrogen sulphide, ammonia,
mercaptans etc. emitted into the air from
wastewater can be measured by gas
monitor.
Temperature
 Temperature is very important parameter because
of its effect on chemical reactions on reaction
rates, aquatic life, and the solubility of essential
gases such as oxygen in water.
 Depending on the geographical location, the mean
annual temperature of wastewater varies from

about 10 to 21.1 º C.
 The temperature of a wastewater sample can be
measured with the help of ordinary mercury or
Chemical
Parameters
 pH
 The hydrogen-ion concentration is an
important quality parameter of both
natural water and wastewater. The
pH of wastewater needs to remain
between 6 and 9 to protect
organisms.
 Acids and other substances that alter
pH can inactivate treatment
processes.
 Biochemical Oxygen Demand (BOD) and Chemical
Oxygen Demand (COD) are two key indicators used to assess
water pollution by measuring the amount of oxygen needed to
break down organic materials in water.
 Biochemical Oxygen Demand (BOD)
 (BOD) represents the amount of oxygen
consumed by bacteria and other
microorganisms while they decompose
organic matter under aerobic (oxygen is
present) conditions at a specified temperature
and time.
 Usually, the time is taken as 5 days and the
temperature 20°C as per the global standard.
 The presence of a sufficient concentration of
dissolved oxygen is critical to maintaining
the aquatic life and aesthetic quality of
Biochemical Oxygen Demand (BOD)
1.Specialized 300 mL BOD bottles designed to allow full filling with no air. The bottles
are filled with dilution (distilled or deionized) water and various amounts of the
wastewater sample.
2. Dissolved oxygen DO meter is used to measure the initial dissolved oxygen
concentration (mg/L) in each bottle.
3.Each bottle in then placed into a dark incubator at 20°C for five days.
4.After five days, the DO meter is used again to measure a final dissolved oxygen
concentration (mg/L).
5.The final DO reading is then subtracted from the initial DO reading and the result is
the BOD concentration (mg/L).
Chemical Oxygen Demand (COD)
 The equivalent amount of oxygen required to oxidize organic matter present in a
water sample by means of a strong chemical oxidizing agent is called chemical
oxygen demand (COD).
 COD values include the oxygen demand created by biodegradable as well as non-
biodegradable substances.
 As a result, COD values are greater than BOD.
 Wastewater
Treatment Fill-
in Activity