Water and Wastewater Analysis Lecture 5 PDF

Summary

This lecture covers water and wastewater analysis, focusing on methods of analysis, water quality parameters, and sampling techniques. It details grab sampling, composite sampling, and different chemical analysis methods including gravimetric and volumetric analysis, and explains standard solutions and indicators used in these techniques. The lecture also introduces related concepts like molarity and normality.

Full Transcript

WATER AND
WASTEWATER ANALYSIS
ENVIRONMENTAL CHEMISTRY
LECTURE 5
Water and Wastewater Analysis in
Chemistry

Water and wastewater analysis is a crucial aspect of
environmental chemistry and public health. It
involves determining the physical, chemical, and
biological characteristics of water samples to
ensure their safety for consumption, discharge into
the environment, or reuse in various applications.
Methods of Analysis

Standard Methods of Water and Wastewater Analysis
published by the American Public Health
Association in collaboration with the American Water Works
Association and the Water Environment Federation.

Expression of Results

For water and wastewater – mg/L or ppm
For sludges, soil and semisolid samples – ppm
Water Quality Parameters

❑ Turbidity
❑ pH
❑ Dissolved oxygen
❑ Biological oxygen demand (BOD)
❑ Chemical oxygen demand (COD)
❑ Nutrients (e.g., nitrogen, phosphorus)
❑ Heavy metals
Water Sampling Techniques
1. Grab samples
Those taken instantaneously and analyzed separately
Most samples in environmental engineering practice is grab
sampling
Problem of frequency of sampling – may vary from one to hundreds
per day

Application:

- For deep well water that has been in service for some time – single
grab sample is representative
- Large river that changes its quality slowly – once daily grab sample
- Industrial waste that changes quality daily – grab sampling every 10
or 15 minutes that could be pooled into 2-, 4-, 8-, 12-, or 24-h
composites
Water Sampling Techniques

2. Composite Samples

Used for evaluating the efficiency of wastewater treatment
facilities where average results are adequate
Samples are collected at regular interval usually every 1 or 2
hours pooled into 24 hours
Application:
- Wastewater treatment plants – 8 am to 4 pm measure the
strength of daytime waste; samples
collected prior to 8 am measures treatment for weak waste
METHODS OF CHEMICAL ANALYSIS TO
QUANTIFY A SAMPLE
A. Gravimetric Analysis
Analysis by weight where the final results are obtained by
means of analytical balance
Application: determination of total solids, suspended solids,
fixed and volatile solids
Time consuming
Constant weight of containers that hold precipitate or residue,
e.g. crucible or dish
Thoroughly cleaned and heat-treated to the same actual
temperature to be used
Cooled in the dessicator
METHODS OF CHEMICAL ANALYSIS TO
QUANTIFY A SAMPLE
B. Volumetric Analysis (Titrimetry)

Depends upon the measurement of liquid reagent volumes of standard
solutions needed to complete a particular reaction in samples

Volumetric analysis involves the measurement of the volume of a
solution of known concentration (the titrant) that is required to react
completely with the substance being analyzed (the analyte). The
endpoint of the reaction is usually indicated by a color change (using
an indicator) or by reaching a certain pH. This method is commonly
used for acid-base titrations, redox titrations, and complexometric
titrations.
 Equivalent weight of a compound is the weight of that compound which contains one-gram
atom of available hydrogen or its chemical equivalent

Molarity – 1 molar solution (1 M) contains 1 gram molecular weight of chemical per liter of solution.

A mole is one gram molecular weight of a substance

The molecular weight of a common table salt is 58.44, thus 58.44g of NaCl is 1 mole of
NaCl.
2M solution of HCl (hydrochloric acid) would contain two gram molecular weights, 2 x
(1+35.5) or 72.9 g HCl in 1 liter of water
A molar solution of NaOH contains 58.44 grams of pure salt dissolved in a total solution
of 1 liter.
Molality – weight to weight relationship rather than weight-to-volume
relationship. A m solution consists of1 mole of substance dissolved in 1000
g of solvent, e.g. 1 liter of water

Normal solution – a solution that contains one equivalent weight of a
substance per liter of solution.

A 1 N solution contains one gram-equivalent weight of particular acid,
base or salt per liter of water.
To prepare 1 liter of normal solution of acid or base:

Amount of compound to furnish ion to yield 1.008 g of H+ or 17.007 g of
OH-
Enough distilled water to make 1 liter
Normality of solution is its relation to normal solution, N
Half-normal solution is 0.5 N or N/2
Normality expresses equivalency in reactions.

For example 1N (normal) solution of sodium hydroxide will exactly neutralize 1 N
solution of sulfuric acid.
The valence of sodium is +1 and the sulfate is –2.

Formula:

N/50 or 0.02N NaOH solution consists of 0.8 g (40/50 or 0.02x40) NaOH in 1 liter of
water.
Problem 1: If 40 ml of 0.02 N NaOH is equivalent to
30 ml of CaCO , what is the normality of the CaCO
3 3

solution?
Problem 2: If 50 ml of 0.1 N HCl is equivalent to
25 ml of NaOH solution, what is the normality of
the NaOH solution?
C. Standard Solution

Standard solution – a solution whose strength or reacting value per unit volume is known.
Facilities needed for conducting volumetric analysis:

1. Equipment to measure the sample accurately, e.g. analytical balance, volumetric glassware
such as pipet
2. Standard solution
3. Indicator to show stoichiometric end point
4. Calibrated buret to measure volume of standard solution

Standard solutions use solutions which are equivalent to one another in strength, i.e.
1.0 ml of reagent A with react exactly with 1.0 ml of reagent B

1 g of hydrogen atomic weight or 1.008 g of hydrogen ion reacts with 1 g ionic weight
or 17.007 g of hydroxyl ion.
Indicators
Indicators serve as signal the reaching of the completed reaction
Types of indicators: electrometric, acid-base, precipitation,
adsorption, oxidation – reduction
Water Sampling Techniques

Flow-Through Sampling

Flow-through sampling is a method where water or another
liquid is continuously passed through a system that allows for
real-time sampling and analysis. This technique is often used in
environmental monitoring, where continuous data collection is
needed, such as in rivers, lakes, or industrial discharges. Flow-
through systems can include sensors and other devices to
measure parameters like pH, temperature, dissolved oxygen,
or specific contaminants.
Water Sampling Techniques
Sampling Equipment
1. Samplers:

Automatic Samplers: These devices are used for collecting samples at
predetermined intervals or in response to specific triggers (e.g., changes in
water quality). They can be programmed to collect samples at specific times
or flow volumes, making them ideal for long-term monitoring projects.

Grab Samplers: These are manual devices used to collect a single sample at
a specific point in time. Grab samplers are typically used when an immediate
snapshot of water quality is needed. They can be as simple as a container on
a pole or a more complex device that can be lowered to a specific depth.
Water Sampling Techniques

2. Bottles:

Glass Bottles: Often used for collecting samples where chemical
reactions with the container are a concern, such as in trace metal
analysis. Glass is inert and doesn’t leach chemicals that could
contaminate the sample.

Plastic Bottles: Typically made of polyethylene or polypropylene, these
are used for general sampling purposes. They are lightweight, durable,
and less prone to breakage compared to glass. However, they may not
be suitable for sampling certain chemicals that can interact with the
plastic.
Water Sampling Techniques

3. Preservatives:

Chemical Preservatives: These are added to samples immediately after
collection to prevent changes in the composition of the sample before
analysis. For example, nitric acid is often added to water samples
intended for metal analysis to preserve the metal ions in solution.

Refrigeration: Some samples need to be kept cool to prevent biological
activity that could alter the sample's composition. For example, samples
for nutrient analysis are often refrigerated or placed on ice until they can
be analyzed.
Equipment and Techniques
Spectrophotometry

a. UV-Vis spectrophotometer
Equipment and Techniques

Spectrophotometry

b. Atomic absorption spectrophotometer
Atomic absorption spectrometry (AAS) detects
elements in either liquid or solid samples through
the application of characteristic wavelengths of
electromagnetic radiation from a light source.
Individual elements will absorb wavelengths
differently, and these absorbances are measured
against standards.
Equipment and Techniques

Chromatography

Liquid chromatography (LC)
Gas chromatography (GC)
Mass spectrometry (MS)
Equipment and Techniques
Titration
a. Acid-base titration
b. Redox titration
c. Conductivity titration