4AE3 U3 C1 Obj 2.pdf

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Objective 2
Describe the role and duties of a Power Engineer

Power Engineers are skilled and knowledgeable workers who operate and maintain
power plant equipment, including boilers. Because of their knowledge and abilities,
Power Engineers are ideal candidates for operating sophisticated and potentially
dangerous processes and process equipment. In recognition of the need for
competent operators, every Canadian jurisdiction has enacted legislation mandating
the role of the Power Engineer within industry.
On-the-job, the activities of Power Engineers address the entire spectrum of heat
generation and heat utilization processes. To make these systems function safely
and economically, Power Engineers must understand equipment operation, process
design requirements, and design limitations. It is usually not necessary to know all
design aspects. Rather, Power Engineers must be able to comprehend and
interpret design specifications, and apply this information to the operation and
maintenance of sophisticated and complex controls, equipment and processes.
In large plants, Power Engineers may be supervisors who direct others to safely
and efficiently operate a shift. The supervised Power Engineers may be operating:
• steam generators or boilers
• Industrial refrigeration and air compression plants
• boiler water, potable water and wastewater treatment facilities
• turbines, diesel engines, generators, switchgear, pumps and other equipment
that utilizes, develops or distributes energy.

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Some of this equipment is illustrated in Figure 6.
Figure 6 – Typical Equipment Operated by Power Engineers
Control panels for emergency power

A An emergency power diesel generator

A steam powered electric generator

In smaller plants, Power Engineers
• operate and maintain equipment
• maintain inventory and order supplies
• prepare specifications and contracts for purchasing consumables and new
equipment.
Generally speaking, in smaller plants, Power Engineers assume total responsibility for
the safe and efficient functioning of the plant. There may be no other staff to fulfill these
A High pressure boiler feedwater pump BFWP

roles.

A water demineralizer

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POWER ENGINEERS: ENERGY CONVERSION EXPERTS
Power Engineers are experts at energy conversion. An energy conversion expert is
someone with a broad range of knowledge and skills, who can operate complicated
equipment and processes to convert energy in its many forms, and perform these
conversions efficiently, safely, and with minimal environmental impact. As Power
Engineers advance in their studies and levels of certification, they become
increasingly knowledgeable and adept at the efficient, safe, and environmentally
responsible conversion of energy. Because of this, Power Engineers advance to take
on increasingly more responsible roles.

Efficient Energy Conversion
To convert energy efficiently, most of the energy entering a process must leave the
process, though in a converted form.
For example, consider a thermal electric generating station. Using boilers, Power
Engineers take the chemical energy stored in fuel and convert it to heat energy.
To do this efficiently, Power Engineers monitor and control burners, and maintain
proper combustion conditions.
The heat energy released by the burners is converted to potential energy (steam
pressure) by a boiler (a specialized heat exchanger). To do this efficiently, the Power
Engineer must know how to keep the heat transfer surfaces of the boiler clean so
that maximum heat transfer occurs. The Power Engineer must also be able to
recognize when boiler heat transfer surfaces are becoming dirty and what to do to
make them clean.
The Power Engineer then converts the potential energy of the steam into
mechanical energy, using a steam turbine. The Power Engineer must know how
to optimize the efficiency of this energy conversion, by considering things like
turbine rotor blade clearances and turbine back pressure.
Finally, the Power Engineer guides the conversion of the steam turbine’s mechanical
energy into electrical energy.
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A 500 MW thermal generating station may burn around 300 000 kg of lignite coal
per hour. At $40/tonne, the production cost for fuel is $12,000 per hour. This is
around 2.4¢/kWh, just to purchase the coal. An overall plant efficiency increase of
only 1% results in a savings of $120 per hour, or $1 million per year!
Not all plants are as sophisticated as thermal generating plants. However, Power
Engineers all study the same energy conversion principles that apply in any energy
plant, small or large. Through efficient operation, Power Engineers increase the
plant profitability, by reducing the overall plant energy, manufacturing, and
production costs.

Safe Energy Conversion
The equipment described above converts several million Joules of energy every
second! The mishandling of such large amounts of energy poses immediate danger.
Power Engineers develop the skills to safely operate very sophisticated and
potentially dangerous equipment, including:
• high-pressure boilers

• steam turbines

• pressure vessels

• gas turbines

• pressure piping systems

• high-voltage electric generators

• industrial refrigeration plants

• high-voltage switchgear

• air compressors
Power Engineers recognize unsafe conditions, and intervene appropriately to ensure
the safety of plant personnel and the public. In doing so, they protect plant equipment,
protect the investment of their owners, and reduce corporate insurance costs.

Environmentally Responsible Energy Conversion
The primary result of efficient energy conversion is a reduction i n energy
consumption. The secondary result is the accrual of environmental benefits
associated with decreased fuel consumption, including:
• Reduced upstream fuel processing activities, with their own environmental impacts
• Reduced fuel delivery activities and resulting emissions
• Reduced consumption of treatment chemicals
• Reduced stack emissions, resulting in less acid rain and climate change impact.
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Consider the thermal generating station once again. A 500 MW thermal station
operating at full capacity may burn around 300 000 kg of lignite coal per hour. Over
the same hour, this plant may produce 785 000 kg of CO2 emissions. An overall
plant efficiency increase of only 1% results in a CO2 emission reduction of 7850 kg
per hour, or 6.8 million kg of CO2 per year! The percent reduction applies to the
emissions of acid-rain forming compounds, carbon monoxide, heavy metals and
mercury as well.
Operating a power plant of any size involves
• being aware of waste streams
• reducing waste stream quantities
• treating waste streams to reduce impact on the environment
Power Engineers develop expertise in all these areas.

POWER ENGINEERS: MAINTENANCE EXPERTS
In addition to being energy conversion experts, Power Engineers are also skilled at
In addition to being energy conversion experts, Power engineers are also skilled
in maintaining power plant equipment. In some Canadian jurisdictions, Power
Engineers of various classifications can legally maintain and repair electrical
equipment, oil burners, and gas burners, in the plants where they are employed.
Some jurisdictions permit Power Engineers to certify as Industrial Mechanics or
Millwrights. In other jurisdictions, Power Engineers are focused almost entirely on
safe and efficient operation.

In jurisdictions where Power Engineers are permitted to perform mechanical repairs
and maintenance, extra “maintenance shift” rotations are scheduled. Power
Engineers take turns repairing or replacing all manner of equipment, either by
themselves or alongside licensed tradespeople.

In jurisdictions or plants where Power Engineers are primarily operators, they
still need to understand equipment and process design parameters. This is
necessary to recognize when processes and process equipment are operating
incorrectly. They also need to know suitable repair methods, despite not being
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permitted or able to perform the actual repair. For example, Power Engineers that
work as boiler inspectors may be poor welders. However, they know and can
identify the characteristics of good welds, and can describe proper, code-compliant
procedures used in the weld repairs of boilers.

Regardless of where they work, Power Engineers diagnose process abnormalities,
identify faulty equipment, troubleshoot causes of equipment failure, and direct
tradespeople to suitably repair and maintain equipment. Power Engineers issue work
orders covering the repair and maintenance of equipment by tradespeople. Power
Engineers can also coordinate the timing and planning of repairs and maintenance,
and facilitate these activities by preparing equipment for servicing. Power Engineers
on shift also have the authority to stop unsafe work.
Side Track

For more information about the duties of Power Engineers, look up
Occupational Classification 9241 on the Government of Canada website.

HISTORICAL DEVELOPMENT OF POWER ENGINEERING
It is difficult to establish the date when certification of Power Engineers first began.
Long before the invention of the steam engine, manual firing of furnaces was under
legal scrutiny. A royal proclamation by Edward I of England in 1306 prohibited the
“use of sea coals in furnaces,” and established a commission which could relax the
rules in the case of careful firemen, or fine the more careless. In Germany,
because of pollution problems, metal plants were scrupulously monitored, and
sometimes denied the use of coal as early as 1350.
The steam engine, invented early in the nineteenth century, gave mankind the first source
of steady and reliable mechanical power. It was originally used to remove water from mines
and thus increase mine output. For many years, it was the practice for the engines to be
put together on site. The mechanics who built engines were loaned by the builder for
commissioning and start up, and often remained to operate the entire power plant. Frequently
they stayed with the new owner.
Owners hired unskilled helpers, who started out doing manual labor, often on the coal
pile. Through a system that they called “progression,” these workers were promoted to
jobs with gradually increasing levels of skill as they acquired experience. As new plants
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were built and labor became more mobile, former employers “certified” the state of
progression of a person moving to a new plant.
In the trend toward greater efficiency, boilers were designed to operate at higher pressure.
This led to serious accidents occurring due to the actions of unqualified personnel. It was
natural for insurance underwriters and governments to become involved, and to take
responsibility for the certification of both operators and equipment.
In recent years there has been a dramatic increase in efficiency of modern plants. Close
control of the steam generation process and enforcement of environmental regulations
has enlarged the responsibilities of Power Engineers, demanding more knowledge and
providing greater opportunity to use their talent. For Power Engineers who wish to achieve
job satisfaction in this expanding technology, the learning process never ends.

NATURE OF THE WORK
Across Canada, and many parts of the United States, the Power Engineering
profession is regulated by law. The government of the state, province, territorial or
civic jurisdiction may have laws with wording similar to the following:
The holder of a Certificate of Competency, the classification of which authorizes
him/her to act as an engineer, may sketch, construct, install, operate, repair, and give
advice on all things pertaining to any power plant in which that person is employed.

The novice engineer is most likely to be involved in equipment operation and repair,
until enough knowledge and experience has been gained to perform other functions
permitted by local law.
In very small plants, much of the work may be manually performed by the Power
Engineer:
• Operating valves and pumps
• Observing and recording levels, temperatures, flows and pressures
• Checking combustion conditions
• Starting electric motors and equipment
• Regenerating water softeners
In larger plants, automatic control systems can perform all of these tasks. Central
control rooms, like that shown in Figure 7, enable relatively few engineers to operate
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automated systems that, if operated manually, would require many engineers.
The engineer’s function is that of an interpreter. Displayed on the control room
monitors and panel mounted instruments is the information to safely control
boilers, generators, industrial processes, and air conditioning equipment. On the
basis of that information, changes are made automatically, or with manual operator
intervention. The Power Engineer continually monitors and analyzes trends, and
anticipates adverse conditions. By promptly interacting with graphical user interfaces
and other electrical controls, the control room operator commands the plant to
precede with the desired “steady state” operations.

The power industry has long employed automatic devices for the control of burner
systems, feedwater systems and related equipment. Each new power plant employs
increasing levels of automation:
• increased mechanization
• more reliance on automatic equipment
• real-time process monitoring

This reality does not change the

Figure 7 – Central Control Room

need for Power Engineers. There
are situations when equipment
must be operated manually, and
the controls used primarily to
inform operator decisions (such
as when warming a boiler and
placing it in parallel operation with
other boilers). Plants still require
the presence of expert operators that know how processes and equipment should
operate, when controls and instruments are being repaired, maintained, reprogrammed or replaced. Power Engineers have adapted to increased automation
by increasing in their understanding of control instrumentation.

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Working Conditions
Power Engineers work year-round, without seasonal lay-offs, in plants that rarely
shut down. Power Engineers typically work eight or twelve hours per day, in rotating
shifts. They work week days, weekends, and holidays. Shifts are arranged so that
at some point, several days off are grouped together in a type of “weekend”.
At one time, it was common practice to operate three eight-hour shifts, starting at 8
AM, 4 PM, and midnight, with four teams assigned to these three shifts. More
common now are 12-hour shift rotations. One type of 12-hour shift schedule is
shown in Figure 8.
Figure 8 – Typical 12-Hour Shift Pattern

Week 1
Week 2
Week 3
Week 4

SUN
D N
D B
B A
A C
C D

MON
D N
A C
C D
D B
B A

TUE
D N
A C
C D
D B
B A

WED
D N
A C
C D
D B
B A

THUR
D N
B C
A D
C B
D A

FRI
D
B
A
C
D

SAT
N D N
A B A
C A C
D C D
B D B

Plants with 12-hour shifts operate with four or five teams. Figure 7 shows a four-team
schedule, with each shift assigned a letter. Follow Team A. Their shift rotation begins
on a Monday morning, and lasts three day shifts. Then, they have one full day off.
Team A returns on Friday for three night shifts that finish on Monday morning.
Then, they are off until Thursday morning day shift. After four day shifts, ending
Sunday evening, Team A has seven days off. They return the following Monday for
a set of four night shifts. The schedule repeats every 28 days.
With this schedule, each team puts in 168 hours over 28 days. The standard “40 hour”
work week schedule is 160 hours over 28 days. Therefore, in this rotation, each
Power Engineer logs eight hours of overtime each 28 day cycle. Overtime may be
paid out at overtime rate, or “banked” for use as time off at straight rate, depending
on the plant’s employment agreements.
Other shift scenarios include “week in” and “week out” camp style deployment. This
is common in locations where the Power Engineers reside a great distance from the
plant, and are flown to or from a work encampment. Some 12-hour shifts have only
two or three shifts in a row, and fewer days off between sets.
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To help promote accident-free performance, most working areas are kept clean and
well-lit. Central control rooms are climate-controlled year-round. However, the plant
environment is likely dirty, dusty, smoky, and noisy. Frequently, Power Engineers
work in temperature extremes, confined spaces, awkward positions, and at heights,
while they inspect, adjust, or repair equipment.
Because work must be performed in close proximity to boilers, rotating equipment,
electrical equipment, piping, and plant processes, Power Engineers must guard
against burns and other injuries that may occur.

Methods and Procedures
When operating, testing, maintaining, or repairing equipment, Power Engineers
must strictly adhere to the methods and practices set out in site-specific policies and
procedure manuals. These manuals are developed in accordance with equipment
manufacturer’s instructions and the results of job hazard analyses. The procedure
manuals

also

incorporate

efficiency

considerations

and

environmental

requirements.

Power Engineers are expected to obey and participate in setting up policies and
procedures, and to mentor junior employees in developing sound practices and good
habits.

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