GNE 335 Lecture 3 - Water Quality Impacts PDF

Summary

This presentation covers Lecture 3 of GNE 335, focusing on water quality impacts. It discusses the hydrologic cycle, water budget, water footprint, the water crisis, water treatment, and wastewater treatment. It also provides a case study on Malta.

Full Transcript

CIE 355 – Introduction to Sustainable Engineering
Fall 2024

Dr. Miriam Tawk
 Lecture 3
Water Quality Impacts

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Chapter Outline
1. Introduction
2. The Hydrologic Cycle
3. Watershed and Runoff
4. Water Budget
5. Water Footprint
6. The Water Crisis
7. Water Treatment
8. Wastewater Treatment

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Introduction
Every year more people die from unsafe
water than from all forms of violence,
including war.

The most significant sources of water pollution
are lack of adequate treatment of human
wastes and inadequately managed and
treated industrial and agricultural waste.

Every day, 2 million tonnes of sewage and
other effluents drain into the world’s waters.

The quality of water necessary for each
human use varies, as do the criteria used to
assess water quality.

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The Hydrologic Cycle
Definitions
The atmosphere is a mixture of gases Hydrology is “the science that treats the waters of
extending from the surface of the Earth the Earth, their occurrence, circulation, and
toward space distribution, their chemical and physical
properties, and their reaction with the
environment, including the relations to living
The lithosphere is the soil crust that lies on
things”
the surface of the planet where we live

The hydrosphere is the portion of the Earth
that accounts for most of the water storage
and consists of oceans, lakes, streams, and
shallow groundwater bodies.

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The Hydrologic Cycle

The hydrologic cycle, or water
cycle, describes the movement of
water from one biogeochemical
cycle to another.

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The Hydrologic Cycle
Oceans contain 97% of the water
on the planet

The largest repository of freshwater on the planet lies in
the Arctic and Antarctic ice caps
Groundwater is the largest source of freshwater actively used
by the human species: 30.1% of freshwater on the planet
and 99% of the freshwater available for human use

Only 0.3% of the world’s total freshwater is available in
surface waters.

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The Hydrologic Cycle
Precipitation

Water moves from the atmosphere to the surface of the
planet through precipitation.

Precipitation may occur when the atmosphere becomes
completely saturated with water (100% humidity) and
the droplets have enough mass to fall from the
atmosphere.

Evaporation from the oceans and eventual cooling of
the water vapor from the oceans account for
approximately 90% of the Earth’s precipitation.

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The Hydrologic Cycle
Precipitation

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The Hydrologic Cycle
Infiltration

Some fraction of precipitation seeps into
the ground through a process called
infiltration.

Groundwater tables are replenished and
sustainable when the rate of infiltration is
equal to or greater than the rate of
withdrawal from the groundwater table.

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The Hydrologic Cycle
Infiltration

Water table, also called groundwater
table, upper level of an underground
surface in which the soil or rocks are
permanently saturated with water.

The upper surface of this zone of
saturation is called the water table. The
saturated zone beneath the water table
is called an aquifer, and aquifers are
huge storehouses of water.

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The Hydrologic Cycle
Infiltration

Wells can be drilled into the aquifers and water can
be pumped out.
Precipitation eventually adds water (recharge) into the
porous rock of the aquifer.
The rate of recharge is not the same for all aquifers,
though, and that must be considered when pumping
water from a well.
Pumping too much water too fast draws down the
water in the aquifer and eventually causes a well to
yield less and less water and even run dry.

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The Hydrologic Cycle
Key components of the hydrologic cycle

Green Water Soil Moisture (nonproductive green Grey Water Recycled, reusable
water is evaporated from soil and wastewater
open water surfaces)

Blue Water Groundwater, Lakes, Rivers, Virtual Water Water embodied in
Groundwater Recharge, Surface production of goods and
Runoff, Streamflow services

Blue Water Diversions, including reservoirs Desalination Augmentation in water-
(engineered) scarce areas

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Watershed and Runoff
The watershed is the region that
collects rainfall. When the height of
the groundwater table is equal to the
surface, a stream is formed.

The precipitation may also flow over
saturated land through runoff in small
rivulets that may be collected into
intermittent streams.

The intermittent streams flow into
groundwater-based stream or river
systems. The river systems transport the
water back to the oceans.

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Watershed and Runoff

Drainage basins, catchments, and
watersheds are 3 synonymous terms
that refer to the topographic area
that collects and discharges surface
stream flow through one outlet.

All the runoff within a watershed
exits a single point downhill or
downstream from all other points in
the watershed

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Water Budget
The water budget balances the flows of water Inputs = Outputs + Storage
into and out of a watershed or system.
P=R+I+E+T+S
The watershed boundaries determine the
boundaries for the system of concern.
Precipitation (P) is the input into the watershed
In natural watersheds, the highest points in those on the left-hand side of the water budget
watersheds create the watershed boundaries. equation.

Water is removed from the watershed by
evaporation (E), transpiration (T), runoff (R),
and infiltration (I) into the soil.

Water stored (S) in the system is also
accounted for on the right-hand side of the
equation

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Water Budget
Consumptive water use Inputs = Outputs + Storage + Consumption
“water removed from available supplies without
return to a water resources system (e.g., water used P=R+I+E+T+S+C
in manufacturing, agriculture, and food preparation
that is not returned to a stream, river, or water Precipitation (P) is the input into the watershed
treatment plant)” on the left-hand side of the water budget
equation.

Withdrawal use Water is removed from the watershed by
“the use of water for any purpose which requires evaporation (E), transpiration (T), runoff (R),
that it be physically removed from the source” and infiltration (I) into the soil.

Nonwithdrawal use Water stored (S) in the system is also
“the use of water for any purpose which does not accounted for on the right-hand side of the
require that it be removed from the original source, equation
such as water used for navigation”

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Water Budget
Case Study - Malta

You are asked to evaluate the urgency of water management measures for the island nation of Malta.
Referring to the data you are provided with (handout):

a. Determine how much water is available per person if all the rainfall in Malta could be collected and
used? (provide answer in liters/day)
b. Determine the water storage per person? Hint: determine groundwater and surface storage available for
use
c. What is your assessment of the situation? :)

Given:
Assume area of Malta = 316 km2
Population = 398000

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Water Budget
General Notes

Engineers are currently examining water availability and have identified many water-scarce areas in both the
developed and developing worlds where there are existing or expected water shortages.

A sustainable level of consumption is one where the net storage term is greater than zero for a watershed.

When the consumption terms increase from human demand to the point where the storage term becomes
negative in value, then there is non-sustainable water use in the watershed.

Archaeologists believe that water shortages have been a significant factor in the collapse of many civilizations.

Today in regions where consumptive withdrawals are greater than inputs into the watershed, water must be
acquired from beyond the watershed boundaries, or water-rationing measures can be adopted to prevent the
degradation and disruption of ecosystems and human systems within the watershed of concern.

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Water Budget
General Notes

“The rapid global rise in living standards combined with population growth presents the major threat to
sustainability of water resources and environmental services.” (World Water Assessment Programme, 2009).

Technological advances in water development and energy development have the potential to help meet the
growing water demand.

At the same time, technological and industrial development may also increase the demand for water associated
with agriculture, energy demand, and industrialization.

Engineers, scientists, and policymakers must work across regional and national boundaries to meet the future
demand for water in many water-scarce areas.

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Water Footprint
Everything we use, wear, buy, sell and eat takes water to make.

The water footprint measures the amount of water used to produce each of the goods and services we
use.

It can be measured for a single process, such as growing rice, for a product, such as a pair of jeans, for the
fuel we put in our car, or for an entire multi-national company.

The water footprint can also tell us how much water is being consumed by a particular country – or
globally – in a specific river basin or from an aquifer.

The water footprint is a measure of humanity’s appropriation of fresh water in volumes of water consumed
and/or polluted.

https://youtu.be/b1f-G6v3voA

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Water Footprint
Three types of water footprints

Green Water Footprint Water from precipitation that is stored in the root zone of the soil and evaporated,
transpired or incorporated by plants. It is particularly relevant for agricultural,
horticultural and forestry products.

Blue Water Footprint Water that has been sourced from surface or groundwater resources and is either
evaporated, incorporated into a product or taken from one body of water and
returned to another, or returned at a different time. Irrigated agriculture, industry
and domestic water use can each have a blue water footprint.

Grey Water Footprint The amount of fresh water required to assimilate pollutants to meet specific water
quality standards. The grey water footprint considers point-source pollution
discharged to a freshwater resource directly through a pipe or indirectly through
runoff or leaching from the soil, impervious surfaces, or other diffuse sources.

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The Water Crisis
1.1 billion people
without access to a
protected well or spring Far more people endure the
Nearly half of the people within reasonable walking largely preventable effects of
in the world do not have distance of their homes poor sanitation and
access to improved sanitation
and one quarter lack water supply than are
access to improved safe affected by war, terrorism,
drinking water and weapons of mass
destruction combined.

A silent
humanitarian
crisis kills an
estimated
3,900 children
every day

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The Water Crisis

1. Water-related diseases are Water Crisis in low-
income populations
among the most common causes of
illness and death in developing
countries, especially in sub-
Saharan Africa.
Symptom and cause of
Poverty

Sickness
Lost educational opp.
Lost Employment opp.
Early Death

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The Water Crisis
What is your role as an engineer?

Water and sanitation systems may be costly to
construct.

The operation and maintenance (O&M) expenses
Remember
for water and sanitation systems are often “Appropriate
overlooked and may cause failure due to the
inability to collect revenue, which is especially Technology”?
problematic in low-income countries.

Growing urban centres challenge engineers,
scientists, and policymakers to implement
appropriate use of technology.

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The Water Crisis
What is your role as an engineer?

Low- to medium-income
countries lack adequately
trained staff to operate and
manage facilities in urban and
rural areas

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The Water Crisis
What is your role as an engineer?

Low- to medium-income
countries lack adequately
trained staff to operate and
manage facilities in urban and
rural areas

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Water Treatment

Few diseases are spread by water in highly
economically developed countries.

In contrast, in less economically developed countries,
a safe, reliable supply of water may be unavailable,
and a sanitation infrastructure is often absent.

Your Role as an Engineer
Environmental engineers apply the basic principles of science and engineering to design water
treatment systems for drinking water and treating human and industrially contaminated wastewater.

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Water Treatment

Design water treatment systems to protect public health
The engineer’s goal

while balancing environmental, economic, social, and
political constraints.

knowledge of the constituents of concern
the impact of these constituents
The transformation and fate of the constituents
treatment methods to remove or reduce the toxicity of the constituents
methods to dispose of or recycle treatment byproducts

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Water Treatment
Importance of Adopting Water Treatment Technologies

Cholera and typhoid outbreaks did not
begin to decrease until chlorination for
treating drinking water received
widespread acceptance in 1908–1911.

Mortality and water supply records kept
by the Commonwealth of Massachusetts
show how improved water filtration and
chlorination led to a rapid decline in
typhoid fever deaths
Check Figure on the left :)

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Water Demand Management
Many developing
communities and many
large urban areas are
in regions of the world
where water is scarce.

Water Demand management
Engineers now consider Think of water as a limited considers the total quantity of
both the supply and resource and use water water abstracted from a
demand of water demand management source of supply using
resources strategies. measures to control waste
and excessive consumption.

Consider efficiency,
effectiveness, and demand
management VS. providing
for maximum possible
demand

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Wastewater Treatment
Wastewater is discharged from homes,
commercial establishments, and industrial
plants by means of sanitary sewers.

The system of sewers has to be designed so
that the collecting sewers, which collect the
wastewater from homes and industries, all
converge to a central point where the water
flows by trunk sewers to the wastewater
treatment plant.

Sometimes it is impossible or impractical to
install gravity sewers, so the waste has to be
pumped by pumping stations through force
mains or pressurized pipes.

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Wastewater Treatment
Water reuse provide a more
sustainable approach to
meeting the demand for
water in many growing
communities.

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Wastewater Treatment

The shift toward reused and recycled drinking
water is occurring in many water-scarce areas
throughout the world.

The advantages to recycling water include:

Lower costs
Reliable water source
Fewer impacts from excessive water withdraw
to ecosystems
Less costly infrastructure investments needed
compared to building large reservoirs or
conveyance systems

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 End of Lecture 3
Water Quality Impacts

Study Well :)

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