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1 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
200 Finch Avenue West Unit 215, Toronto, Canada
Pipeline hydraulic Design
Pump Design and Operation
Piping Materials
Piping Stress Analysis
Fittings and Flanges and Valves
Piping Diagrams
Heat Exchanger Design
Heat Exchanger Network Design
Fractionation Distillation Process
Packed Columns Design and Operation
Industrial Furnaces Design and Operation
Cooling Tower Design and Operation
Flare Systems Design and Operation
Pressure Relief Valves
Petroleum Refinery Engineering I
Petroleum Refinery Engineering II
Introduction to Process Control
Process Control in Process Plants
PIPING
OIL AND GAS INDUSTRY
2 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Wastewater Treatment Processes
Advanced Wastewater Treatment
Environmental Chemistry
Chemical Kinetics
Chemical Reactor Design and Operation
Advanced Chemical Reactor Design
Mass Transfer
Advanced Mass Transfer
Heat Transfer
Heat Transfer Mathematical Modeling
Thermodynamics
Chemical Process Principles
Fluid Mechanics
Advanced Topics in Fluid Mechanics
ENVIRONMENT
CHEMICAL PROCESSING
3 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Pipeline hydraulic
Design
You will learn
Basic terms and basic units in
fluid mechanics, unit
conversions, fluid flows and
the classifications, velocity,
flow rate, head loss and
pressure drop calculations,
hydraulic pressure gradient,
gas and liquid pipeline
hydraulic design, parallel
piping, series piping, injection
and delivery in pipelines, and
pipe loops design.
Duration
21 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
discipline, consulting and
engineering staff, and graduate
students.
Course Content
Units and conversions
Fluid flow and
classifications
Flow regimes and
Reynolds number
Velocity, head loss
calculations
Fluid Flow equations
Gas and liquid pipeline
hydraulic design
Injections and delivery in
pipelines
Pipe loops design
Parallel and series
pipelines
Piping Materials
You will learn
Piping material engineering
activities and piping material
engineer duties and
responsibilities, piping
components and their material of
construction, pipe manufacturing
methods and pipe sizes and
schedules, piping standards, types
of pipe ends and pipe
connections.
Duration
12 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering discipline, consulting
and engineering staff,
manufacturing engineers and
technologists, and graduate
students.
Course Content
Piping material duties and
responsibilities
Introduction to piping
components
Material of construction
Piping Classes
Pipe material selection
Pipe sizes
Pipe schedules
Piping standards
Pipe manufacturing
Pipe ends
Pipe connections
Fittings and Flanges
and Valves
You will learn
Introduction, material of
construction, selection and
application of piping components
including fittings, flanges and
valves and their types
Duration
12 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering discipline, piping
engineers and technologists,
manufacturing engineers and
technologies, and graduate
students.
Course Content
Introduction to fittings
Classifications of fittings
Fittings selection
Fittings applications
Introduction to flanges
Flanges Applications
Flanges Ratings
Flanges Facing
Material of Construction
Bolts
Gaskets
Introduction to Valves
Valve components
Principal functions
Valve types
Valves applications
Valve selection
Pip
ing
Co
urs
es
4 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Piping Stress
Analysis
You will learn
Piping stress classifications,
analysis of piping systems,
flexibility analysis and its
codes and standards, Piping
Supports design and
calculations, thermal
expansion loop design and
calculation
Duration
18 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, piping
engineers and technicians, and
graduate students.
Course Content
Strength of materials
Introduction to stress
analysis
Stress and strain
calculations
Stress analysis in
pipelines
Codes and standards
Flexibility analysis in
pipelines
Thermal loop expansion
design
Expansion joint design
Pipe span calculation
Pipe supports
Support selection and
design
Pump Design and
Operation
You will learn
Piping material engineering
activities and piping material
engineer duties and
responsibilities, piping
components and their material of
construction, pipe manufacturing
methods and pipe sizes and
schedules, piping standards, types
of pipe ends and pipe
connections.
Duration
15 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
manufacturing engineers and
technicians, and graduate
students.
Course Content
Piping material duties and
responsibilities
Introduction to piping
components
Material of construction
Piping Classes
Pipe material selection
Pipe sizes
Pipe schedules
Piping standards
Pipe manufacturing
Pipe ends
Pipe connections
Piping Diagrams
You will learn
Process Flow Diagram, Piping
and Instrumentation Diagram
(P&ID), Plot plans, Elevation
drawings, Equipment drawings,
and Pipe Isometrics and standard
symbols
Duration
12 hours
Who Should Attend
The course provides substantial
technical detail on piping
drawings and it is designed for
technical personnel, all
engineering disciplines, piping
engineers and technologists,
manufacturing engineers and
technicians, process engineers
and technicians, and graduate
students.
Course Content
Block Flow Diagram
Process Flow Diagram
Process Symbols
Piping and Instrumentation
Diagram
Plot Plans
Elevation Drawings
Equipment Drawings
Plant Layouts
Nozzle Arrangements Piping Isometrics
Pip
ing
Co
urs
es
5 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Heat Exchanger
Design
You will learn
Introduction to head transfer
and heat transfer phenomena,
heat transfer coefficient
calculations, Heat Exchangers
Types, Thermal and
Mechanical Design and
Operation of Various types of
Heat Exchangers
Duration
30 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, Process and
Mechanical engineers,
manufacturing engineers and
technicians, and graduate
students.
Course Content
Introduction to heat
transfer
Types of heat transfer
equipment
Heat Transfer Coefficient
Heat Transfer Surface
Area
Mean Temperature
Mechanical Design
Design and Operation of
double-pipe and shell and
tube heat exchangers
Design and Operation of
Condensers and Reboilers
Design and Operation of
Plate and Frame heat
Exchangers
Pressure drop calculations
in heat exchangers
Heat Exchanger
Network Design
You will learn
Introduction to heat recovery
systems and basic terminology,
energy targets, heat recovery
pinch, stream splitting, multiple
utilities, threshold problems,
optimization of heat exchanger
networks, Retrofit, Data
Extraction
Duration
18 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
thermal engineers and
technologists, and graduate
students.
Course Content
Introduction to Thermo-Fluid
systems
Introduction to heat recovery
systems Setting energy target
Heat Recovery
Pinch Point
Stream Splitting
Multiple Utilities
Threshold Problems
Optimization of Heat
Exchanger Network
Retrofit objectives and design
methods
Data Extraction
Fractionation
Distillation
You will learn
Introduction to separation
processes, the importance of
distillation process in oil and gas
industry, the basic theory of
distillation, McCabe-Thiele
method, Ponchon-Savarit method,
multicomponent distillation,
mechanical design of distillation
column, components of tray
columns.
Duration
33 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
manufacturing engineers and
technologies, Process engineers
and technicians, and graduate
students.
Course Content
Introduction to Separation
processes
Introduction to Distillation
Process
Types of Distillation
Processes
Components of Tray
Columns
McCabe-Thiele
Ponchon-Savarit
Multicomponent distillation
calculations
Mechanical Design of Tray
Columns
Oil a
nd
Ga
s C
ou
rse
s
6 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Packed Columns
Design and
Operation
You will learn
Importance of packed columns
in oil and gas industry,
packing types, Packing
support, packing selection and
performance, design capacity
and pressure drop, mass and
heat transfer in packed towers,
diameter and length of packed
towers
Duration
18 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, process
engineers and technicians, and
graduate students.
Course Content
Introduction to packed
Towers
Packed towers
components
Packing types
Design capacity and
pressure drop
Mass and heat transfer in
packed towers
Mass transfer with
reaction
Mechanical design of
packed towers
Industrial Furnaces
Design and
Operation
You will learn
Introduction to combustion
processes, introduction to
convection and radiation heat
transfer, industrial heating
processes, batch and continuous
furnaces, operation and control of
industrial furnaces.
Duration
18 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
manufacturing engineers and
technicians, and graduate
students.
Course Content
Convection and Radiation
heat transfer
Combustion process
Flames and burners for
furnaces
Fuel handling systems
Furnace design methods
Batch furnaces
Continuous furnaces
Cooling Tower
Design and
Operation
You will learn
Importance of cooling towers,
humidification, cooling towers
types, cooling tower components,
cooling tower design, cooling
tower operation and control
Duration
18 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
manufacturing engineers and
technicians, and graduate
students.
Course Content
Humidification process
Humidity chart
Convection heat transfer
Types of cooling towers
Cooling towers components
Cooling tower design
Cooling tower operation and
control
Oil a
nd
Ga
s C
ou
rse
s
7 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Flare Systems
Design and
Operation
You will learn
The function of flares, how
flares work, different types of
flare systems, different types
of flare stacks, flares and
processes, operating
parameters, flares operation,
and troubleshooting
Duration
9 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, process
engineers and technicians, and
graduate students.
Course Content
The function of flares
Types of flare systems
Types of flare stacks
Flare representation and
data
Flares and processes
Operating parameters
Operation
troubleshooting
Pressure Relief
Valves
You will learn
Types of pressure relieving
devices, types of valves and relief
systems, materials of
construction, relief mechanism,
pressure setting and design basis,
selection and application, sizing
PSV.
Duration
9 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
and graduate students.
Course Content
Types of pressure-relieving
devices
Types of valves/relief devices
Materials of construction
Relief mechanisms
Design basis
Relieving capacity
Selection and application
Sizing valves for pressure
relief
Orifice area calculation
Petroleum Refinery
Engineering I
You will learn
Petroleum crude oil feedstock and
products, overview of petroleum
refinery processes,
characterization of crude oil and
petroleum products, atmospheric
distillation and vacuum
distillation, desalting process of
crude oil
Duration
30 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
manufacturing engineers and
technicians, process engineers
and technicians, and graduate
students.
Course Content
Overview of petroleum
refinery processes
Petroleum refinery feedstocks
Petroleum refinery products
Crude oil and products
characterization
Crude oil desalting
Atmospheric distillation
Vacuum distillation
Oil a
nd
Ga
s C
ou
rse
s
8 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Petroleum
Refinery
Engineering II
You will learn
Thermal and catalytic cracking
reactions in petroleum
refineries, coking and thermal
processes, catalytic cracking
unit, catalytic hydrocracking,
catalytic reforming, alkylation
and polymerization, hydrogen
production, lubricating oil.
Duration
30hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, manufacturing
engineers and technicians,
process engineers and
technicians, and graduate
students.
Course Content
Coking and Thermal
cracking
Catalytic cracking
process
Catalytic hydrocracking
Catalytic hydrotreating
Catalytic reforming
Isomerisation
Alkylation
Polymerization
Lubricating oil
Hydrogen production
Introduction to
Process Control
You will learn
Introduction and fundamentals of
process control, basic techniques
of closed-loop control, stability,
Root-locus methods, controller
tuning and process identification,
and control valves
Duration
36 hours
Who Should Attend
The course provides substantial
technical detail on process control
and it is designed for technical
personnel, all engineering
disciplines, control engineers and
technicians, process engineers
and technicians, and graduate
students.
Course Content
The laplace transform
Linear open loop systems
Linear closed loop systems
Frequency response
Controller tuning and
process identification
Control valves
Feedback control
Stability analysis of
feedback systems
Feedforward and ratio
control
Process Control in
Process Plants
You will learn
Develop effective control
structures for chemical and
petroleum plants. Process control
on individual unit operations.
You will learn how to design a
control system that provides basic
regulatory control of the process.
Duration
21 hours
Who Should Attend
The course provides substantial
technical detail on process control
and it is designed for technical
personnel, all engineering
disciplines, control engineers and
technicians, process engineers
and technicians, and graduate
students.
Course Content
Process Control Basics
Review
Plantwide control
fundamentals
Plantwide control design
procedure
Reactors control
Heat Exchangers control
Distillation column control
Other units control
Process units control cases
Oil a
nd
Ga
s C
ou
rse
s
9 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Chemical Kinetics
You will learn
Experimental and theoretical
aspect of chemical reaction
kinetics, reaction orders, rate
laws for different reaction
orders, reversible reaction,
multiple reactions, reaction
mechanism, deriving rate laws
Duration
15 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, process
engineers and technicians,
chemists and pharmacists, and
graduate students.
Course Content
Introduction to chemical
reaction
Stoichiometry
Kinetics and kinetic
expressions
Kinetics of homogeneous
reactions
Rate laws
Deriving rate orders
Non-elementary reaction
kinetics
Catalysis
Multiple reaction kinetics
Kinetics of heterogeneous
reactions
Interpretation of kinetic
data
Chemical Reactor
Design and
Operation
You will learn
Importance of chemical reactors
in oil and gas industry, types of
reactors in oil and gas industry,
homogeneous reactions, batch
reactors design and operation,
continuous flow reactors design
and operation, multiple reactions
in chemical reactors
Duration
30 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
manufacturing engineers and
technicians, process engineers
and technicians, polymer
scientists, and graduate students.
Course Content
Introduction to chemical
reaction
Types of chemical reactors
Batch reactor design and
operation
Plug flow reactor design and
operation
Completely mixed reactor
design and operation
Chemical reactors
components
Thermal considerations in
chemical reactors
Advanced Chemical
Reactor Design
You will learn
Advanced topics in chemical
reactors, nonideal reactors, design
of catalytic reactors, heat and
mass transfer in catalytic reactors,
multiphase reactor design, fixed
bed and fluidized bed reactor
design
Duration
27 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
manufacturing engineers and
technicians, process engineers
and technicians, and graduate
students.
Course Content
Non-ideal flow
Heterogeneous reactions
Fluid-fluid reactions
Heat and mass transfer in
chemical reactors
Steady-state non-isothermal
reactor design
Unsteady-state non-
isothermal reactor design
Distribution of residence
times for chemical reactors
Fixed bed reactor design
Fluidized bed reactor design
Ch
em
ica
l Pro
ce
ss
es
Co
urs
es
10 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Mass Transfer
You will learn
Introduction to mass transfer
and separation processes, mass
transfer coefficient, interphase
ass transfer, application of
mass transfer in step-wise and
continuous processes, mass
transfer modeling
Duration
27 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, process
engineers and technicians,
chemists, pharmacists,
polymer technicians,
undergraduate and graduate
students.
Course Content
Molecular diffusion and
transport
Binary mixture system
Fick’s law of diffusion
Mass Transfer Coefficient
Interphase mass transfer
Gas-Liquid mass transfer
model
Absorption and stripping
operation principles
Analogy of heat and mass
transfer
Mass transfer modeling
Application of mass
transfer
Advanced Mass
Transfer
You will learn
Advanced topics in mass transfer
including the mass transfer
coefficient calculation, mass
transfer modeling, unsteady state
mass transfer, turbulent mass
transfer, combined heat and mass
transfer, diffusion in dilute and
concentrated solutions,
multicomponent diffusion
Duration
21 hours
Who Should Attend
The course provides advanced
topics and it is designed for
graduate students in chemical and
biochemical engineering,
chemistry, and people have prior
knowledge of mass transfer.
Course Content
Models for Diffusion
Diffusion in dilute Solutions
Diffusion in concentrated
solutions
Dispersion
Diffusion coefficient in
binary and multicomponent
systems
Simultaneous heat and mass
transfer
Mass transfer modeling
Unsteady state mass transfer
Turbulent mass transfer
Mass transfer in catalytic
reactors
Heat Transfer
You will learn
Introduction to heat transfer,
types of heat transfer, one-
dimensional and multi-
dimensional heat transfer,
unsteady state heat transfer,
introduction to convection heat
transfer, heat transfer coefficient,
condensation and boiling heat
transfer, radiation heat transfer
Duration
30 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
manufacturing engineers and
technicians, process engineers
and technicians, and
undergraduate and graduate
students.
Course Content
Introduction to heat transfer
Introduction to conduction
heat transfer
One-dimensional and
multidimensional heat
transfer
Unsteady state heat transfer
Convection heat transfer
Heat transfer coefficient
Condensation and Boiling
heat transfer
Radiation heat transfer
Ch
em
ica
l Pro
ce
ss
es
Co
urs
es
11 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Heat Transfer
Mathematical
Modeling
You will learn
Advanced topics in conduction
heat transfer, different heat
conduction formulations,
lumped formulation, integral
formulation differential
formulation, initial and
boundary conditions,
superposition, Bessel function,
fourier functions, orthogonal
functions
Duration
21 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for graduate
students in mechanical,
chemical, and thermal
engineering and people have
background in heat transfer
Course Content
Heat Transfer Modeling
Boundary conditions
Lumped formulation
Integral formulation
Differential formulation
Initial and boundary
conditions
Superposition
Bessel function
Fourier series
Orthogonal function
Partial differential
equations in heat transfer
equations
Thermodynamics
You will learn
Basic terms in thermodynamics,
heat and work, first and second
law of thermodynamics, enthalpy,
entropy, phase equilibrium,
chemical equilibrium,
thermodynamic cycles
Duration
36 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
mechanical and chemical
engineers, and graduate students.
Course Content
Basic Terms
First law of thermodynamics
Second law of
thermodynamics
Work and Heat
Enthalpy
Entropy
Properties of a pure substance
Irreversibility and availability
Power and refrigeration
Gas mixtures
Phase equilibrium
Chemical equilibrium
Equations of state
Mass and Energy
Balance
You will learn
Chemical engineers roles and
responsibilities, chemical
processes and introductory
concepts, material balance
without and with reactions, ideal
and real gases, energy balance,
heats of solution and mixing,
energy balances on nonreactive
and reactive processes
Duration
35 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines, chemical
processes engineers and
technicians, and undergraduate
graduate students.
Course Content
Units and dimensions
Conversion of units
Mass and volume
Flow rate
Chemical composition
Temperature and pressure
Material balance
Recycle and bypass
Ideal and real gases
Energy balance on
nonreactive processes
Energy balance on reactive
processes
Combined material and
energy balance
Ch
em
ica
l Pro
ce
ss
es
Co
urs
es
12 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Fluid Mechanics
You will learn
The basic terms in fluid
mechanics, fluid flow
classifications, laminar and
turbulent flow, Bernoulli
equation, Navier-Stokes
equation, velocity profile
calculation, dimensional
analysis, boundary layer
theory, and fluid flow in pipes
Duration
30 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, mechanical,
civil and process engineers and
technicians, and undergraduate
students.
Course Content
Introduction
Balance equation and the
mass balance
Bernoulli’s equation
Fluid friction
Momentum balance
Laminar and Turbulent
flows
Fluid flow in pipes
Pumps, compressors, and
turbines,
Flow through porous
media
Non-newtonian fluid flow
Turbulence
Mixing
Dimensional analysis
Advanced Topics in
Fluid Mechanics
You will learn
Advanced terms in fluid
mechanics, turbulence, vorticity,
analysis of a differential fluid
element in laminar flow,
differential equations of fluid
flow, inviscid fluid flow, viscous
flow, boundary layer theory,
multiphase flow, fluidization
Duration
30 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel,
Mechanical, Process and Civil
engineers, consulting and
engineering staff, and graduate
students.
Course Content
Fluid Statics
Conservation of Mass
Control-Volume Approach
Analysis of a differential
fluid element in laminar flow
Differential equations of fluid
flow
Solving differential equations
Inviscid fluid flow
Viscid fluid flow
Dimensional analysis
Boundary Layer Theory
Turbulent flow
Multiphase flow
Fluidization
Ch
em
ica
l Pro
ce
ss
es
Co
urs
es
13 200 Finch Avenue West, Toronto, ON Unit 215 www.nycollege.ca
Wastewater
Treatment
Processes
You will learn
Basic concepts in water and
wastewater treatment, physical
operations such as
sedimentation, flocculation,
floatation and filtration,
chemical processes such as
ozonation, chlorination, and
biological processes such as
aerobic and anaerobic
processes
Duration
36 hours
Who Should Attend
The course provides
substantial technical detail and
it is designed for technical
personnel, all engineering
disciplines, consulting and
engineering staff, water and
wastewater treatment plants
engineers and technicians,
civil and chemical engineers.
Course Content
Basic terms in water and
wastewater treatment
Characterization of
wastewater
Municipal and industrial
wastewater properties
Sedimentation
Flocculation
Coagulation
Floatation
Activated sludge process
Nitrogen and
phosphorous removal
Ozontion and chlorination
Advanced
Wastewater
Treatment
You will learn
Advanced topics in water and
wastewater processes, advanced
biological processes including
aerobic and anaerobic processes,
wastewater microbiology,
advanced chemical processes
Duration
30 hours
Who Should Attend
The course provides substantial
technical detail and it is designed
for technical personnel, all
engineering disciplines,
consulting and engineering staff,
water and wastewater treatment
plants engineers and technicians,
civil and chemical engineers.
Course Content
Wastewater microbiology
Activated sludge process
Advanced aerobic processes
Advanced anaerobic
processes
Biological nitrogen and
phosphorous removal
Biological wastewater
treatment modeling
Advanced chemical processes
UV process
Ozonation process
Chlorination process
Environmental
Chemistry
You will learn
Basic concepts in chemistry,
organic chemistry, physical
chemistry, and analytical
chemistry, introduction to
atmospheric chemistry,
greenhouse effects, ozone hole,
renewable and nuclear energy,
global warming, chemistry of
water, water analysis, heavy
metals in waste and soil
Duration
15 hours
Who Should Attend
The course provides substantial
technical detail on piping
drawings and it is designed for
technical personnel, all
engineering disciplines, piping
engineers and technologists,
manufacturing engineers and
technicians, process engineers
and technicians, and graduate
students.
Course Content
Basic concepts in chemistry
Basic concepts in analytical
chemistry
Water chemistry
Water and wastewater
analysis
Atmospheric chemistry
Greenhouse effects and ozone
hole
Soil chemistry
Solid waste characterization
En
viro
nm
en
t Co
urs
es