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Module 1: Electrical Fundamentals
 Objective
 Define electricity
 Identify mechanisms for distributing electricity (how it
travels)
 Identify required actions to take following an electric
shock.

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What is Electricity?
 Electricity is a source of energy to power devices (e.g.,
lights, electrical drill, or a computer)
 If you compare electricity to water, voltage is the water
pressure and current is the rate of flow
 Just as with water, the higher the voltage (pressure) or
greater the current (flow rate), the more dangerous
electricity becomes

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Two Basic Types of Electrical Energy
 Alternating Current (AC)
 Power sources are generally supplied by generators
found at hydroelectric, coal fired, or nuclear power
plants
 AC energy is distributed by above or underground
power lines for end use in home, commercial, and
industrial applications
 Direct Current (DC)
 Power sources are generally supplied by batteries
 Batteries in cell phones, lap tops, flashlights,
Uninterruptable Power Supplies (UPS) or vehicles are
sources of direct current (DC)

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How does electricity travel?
 Consider a light switch circuit:
 There is a source, typically 230 volts alternating current
(VAC)
 There is a switch controlling the source, a light bulb, and
a return (typically at zero volts) or ground

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How does electricity travel?
 In the light switch, current will
only flow through the circuit if the
switch is closed, creating a place
for the energy to go
 This is created by a difference in
voltage between the source (230
VAC) and the return (0 Volts)
 If there isn’t a complete path in
the circuit, current will not flow
 Once the switch is closed current
flows and the lamp produces
energy in the form of light

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Electrical Shock
• Electric shock occurs when the human
body becomes a conductor, completing
the path for current to flow
• Basic electrical safety is that if a path is
not complete, current will not flow, and
shock will not occur
• Like water, electricity will take the path
of least resistance. Current will most
likely flow through a circuit instead of a
human body unless the body presents a
path of lower resistance.

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Electrical Shock
Open circuit with worker
grounded
Worker receiving electrical
shock from lighting circuit

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Effects of Shock
 Effects of electrical shock range from mild tingling to heart
failure, depending on the amount of current
 Current as low as 50 milliamps can cause heart fibrillation
 Heart fibrillation is where the ability of the heart to pump
in a regular rhythm is disrupted
 Given enough time in this state, it is usually fatal

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Effects of Shock
 Severity of a shock is determined by amount of current
and the path through the body
 If the current path is through the heart, there is a much
greater chance of death than if the current passes from
one finger to another
 At lower currents, respiratory paralysis can occur, also
potentially fatal

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Effects of Shock
 Direct effects include pain, paralysis, heart fibrillation, or
tissue burn
 Indirect effects include confusion, amnesia, headaches, or
breathing and heart irregularities
 Problems may last several days and progress into vision
abnormalities and swelling of affected areas
 Over a victim’s lifetime, long range effects may include
paralysis, speech/writing impairment, loss of taste, and
other disorders

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What To Do When A Person Is Shocked
If victim is still engaged with or attached to the circuit:
 De-energize the circuit, if possible
 Remove victim from the circuit using non-conductive
material (i.e., length of dry rope, dry broomstick, or
leather belt)
 Call 108
 Apply artificial respiration and CPR, if necessary
If victim is conscious, they still need medical treatment as
soon as possible.

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Arc Flash/Blast
 Arc Flash/Blast occurs when an energized source comes
in contact with a grounded source creating an unexpected
release of energy in the form of noise and pressure.
 Effects of Arc Flash/Blast - may cause severe burns, eye
and hearing damage

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Module 2: Engineering Controls
 Objective:
 Identify the purpose of various engineering controls
designed for electrical safety
 The preferred method to control electrical hazards is
to engineer controls into the design of equipment

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Engineering Safeguards
Engineered safeguards can be as simple as a light switch
cover or a door on the breaker panel.

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What If Engineering Safeguards Are Removed?
 A missing cover screw caused this cover
to fall onto the plug, which was not fully
inserted, & resulted in a short circuit and
damaged outlet.
 The outlet cover is metal. Metal is still
used in many areas. It is safe if the cover
is installed correctly.
 The plug would be safe if it was installed
correctly.
 Engineering controls require proper
installation to ensure safety. In this case,
improper installation caused the short.

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Internal Barriers
 Internal barriers on some equipment ensure workers are
not exposed to energized parts
 Barriers may be as simple as covers over terminal posts or
Plexiglas® panels
Plexiglas cover over energized
doors is an engineered control.

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Internal Barriers
Ground Fault Circuit Interrupters (GFCIs) are required under
the following conditions:
 Damp or wet location
 Within 6 feet of exterior door
 Within 6 feet of signs
 Outdoors
 Rooftops
 If a GFCI outlet is not available, portable GFCIs are an
alternative.

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What is an Administrative Control?
 Administrative controls relate to organization and
management, procedures, record keeping, assessment,
and reporting necessary to ensure safe operation of a
facility
 Examples:
 Work planning/control documents
 Work-related training and certifications
 Warning signs, labels, and tags

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National Fire Protection Association (NFPA)
70E Requirements
 NFPA 70E (Electrical Safety in the Workplace) identifies
requirements to maintain a safe electrical workplace
 NFPA 70E has two categories for electrical hazards:
1. Shock hazards
2. Arc flash hazards
 Unqualified personnel must be escorted by a qualified
person to enter a shock or arc flash boundary
 Qualified person must ensure unqualified person has
required PPE & understands hazards/required controls
 Qualification requires employees to have knowledge about
the work and equipment they will be working on

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Excavation/Penetration Permits
 Hidden hazards are sources of energy that are not visibly
apparent, such as underground electrical conduit or wiring
inside walls
 There are specific requirements for excavation and drilling
into walls
 Obtain Excavation or Penetration Permit per FMOC
ES&H Specification 01065 requirements

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Electrical Lockout/Tagout (LOTO)
 The most important administrative control is Lockout/Tagout
 If you see a lock on an electrical circuit, do not attempt to
operate the circuit.
 To gain access to a locked & tagged out circuit, contact the
person named on the tag. Do not remove the tag or restore
the circuit without approval. If and when possible, a qualified
worker will restore the circuit in accordance with the LOTO
procedure.
 Electrical locking devices may be installed on a cord, switch,
breaker, or disconnect device: look before you operate the
equipment.
 Be sure to follow your company’s
LOTO program.

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Pre-Work Briefings
 A pre-work briefing is the best way to identify hazards,
answer questions, and plan work.
 They improve productivity, reduce accidents/injuries, and
improve communications between all levels of the
organization
 affects more people, and can have more serious
consequences if safe procedures are not followed.

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Module 4 – Hazard Recognition & Avoidance
 Objective
 Identify hazards associated with electrical systems and
equipment
 Discuss electrical accident prevention through
increased awareness of surrounding conditions and
Sandia requirements
 Accident prevention is a deliberate, planned series of
events that includes training, awareness, design
considerations, procedures, and management support
 NFPA70E requires electrical safety program to instill
safety principles in employees. Safety, particularly
electrical safety, is a mind set. Since electricity is part of
everyday life, it is easy to overlook potential hazards.

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Overhead Hazards
 Specific requirements for working in the vicinity of
overhead power lines:
 Transit: Equipment not performing its primary function
(i.e., traveling under power lines) may not come within
4’ of energized overhead lines.
 Standoff Distance: Operating equipment may not
approach energized power lines closer than 10’. This
distance increases if the voltage in the lines is greater
than 50,000 volts.
 Trained Operators: Anyone working near energized
power lines must be trained on the specific hazards
associated with working on those lines.

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Overhead Hazards
 In 2006 several accidents across the U.S. were caused by
inadvertent contact with overhead power lines.
 The Department of Labor reports that more than 100
workers are killed every year due to contact with overhead
power lines.

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Missing Ground Pin
The ground pin is missing in this picture.
You might say no problem – the plug still
fits in the outlet. Is this plug safe?
With no engineered ground, you and the
tool could easily become the path to
ground for current.
If the tool experienced an internal short
circuit or made contact with a hidden,
energized wire, the metallic housing and
anyone touching it would become
energized.
In a case like this, a fatal shock could be
delivered.

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Burned Insulation
In this picture, a section of insulation is burned and
missing. If you were using this in your office, and the
exposed portions contacted the metal chair you are sitting
on, you would probably receive a shock.

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Shorted Nightlight
When the conductive knife contacted
the energized blades of the night light,
the knife shorted across the energized
blades, creating a short circuit.
Tired of looking at a night light, and believing the easiest way
to remove it from the wall was to pry it loose with a butter
knife, a woman quickly found out that the butter knife was not
the right tool to use. The results are evident.
The woman using the knife was okay. However, this short
circuit could have been avoided had she planned the job and
applied safe work practices.

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Integrated Safety Management System (ISMS)
Appling these ISMS principles to all the work that you do will
help create a safe working environment for you and the
people you work with and around:
 Plan Work
 Analyze Hazards
 Control Hazards
 Perform Work
 Feedback and Improve

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Module 4 –SUMMARY
There are four facts to remember about electricity:
1. Water and electricity do not mix.
2. Inspect all equipment prior to use and do not use
damaged equipment.
3. Employ ISMS principles: Plan work; analyze hazards;
control hazards (with PPE, correct tools etc.); perform
work; and feedback & improve.
4. Use common sense - ask questions if you do not
understand, and, if not satisfied with the answer, shut
down unsafe work practices.

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Remember . . . Be Careful Out There!
~ The End ~

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