piping - toronto engineering courses & technology … · fractionation distillation process...

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


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


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




engineering discipline, piping

engineers and technologists,


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


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




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




engineering disciplines,

consulting and engineering staff,


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


technical detail on piping

drawings and it is designed for

technical personnel, all

engineering disciplines, piping



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


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





engineering staff, Process and

Mechanical engineers,



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


Condensers and Reboilers


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






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






technologies, Process engineers


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


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





engineering staff, process


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








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








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


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







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






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








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


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




disciplines, manufacturing

engineers and technicians,

process engineers and


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


technical detail on process control

and it is designed for technical


disciplines, control engineers and



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


technical detail on process control

and it is designed for technical


disciplines, control engineers and



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


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







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








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








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


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







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







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


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


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






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




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


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





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



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


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





engineering staff, water and

wastewater treatment plants


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






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


technical detail on piping

drawings and it is designed for

technical personnel, all

engineering disciplines, piping





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

piping - toronto engineering courses & technology … · fractionation distillation process...

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