Download Arc Flash Mitigation

Bluebonnet Electric Cooperative
Arc Flash Hazard Mitigation
Thomas Ellis, PE
Manager of Engineering
Serves 81,000 meters across
11,000 miles of power lines within
14 Central Texas Counties
What is Arc Flash
Arc Flash is a massive energy discharge
 Similar to the arc obtained during
electrical welding
 Initiated by creation of a conducting path
or breakdown in insulation
 Sustained by the establishment of a highlyconductive plasma
 Arc fault current is often lower than
available bolted fault current

Arc Flash Energy
System Voltage
 Fault current
magnitude
 Duration of Fault
 Enclosures magnify
blast and energy
transmitted

◦ 2-12 times greater
energy
Incident Energy
Incident
Energy
measured
at the arc
potential
to the
employees
face and/or
torso
cal/cm^2
Incident Energy
Incident Energy
(cal/cm²)
1.2
Degree Burn
2nd degree burn to bare skin
4
Ignite a cotton shirt
8
3rd degree burn to bare skin
Shows the damage that incident energy can impart.
Arc Flash Effects

Extreme heat, pressure
waves, and sound
waves
◦ 35,000 degrees
Fahrenheit
◦ Molten Metal, Shrapnel,
and Vapor
◦ Expansion rate 40,000-1
◦ Intense light




Burns
Punctures
Concussion
Capable of causing
severe/fatal injuries
Arc Flash Hazards

Personnel have exposure to electric arcs:
◦ When working on or near exposed energized
electrical conductors or circuit parts.
◦ When interacting with electrical equipment
where an electric arc could occur.
◦ Under normal conditions, equipment that is
installed and maintained is not likely to pose
an arc flash hazard if an personnel are not
interacting with the equipment.
Racking Breaker
National Electric Safety Code
(NESC) - 2007
2007 code published August 1, 2006
 410.A.3

◦ “Effective as of January 1, 2009, the employer
shall ensure that an assessment is
performed to determine potential exposure
to an electric arc for employees who work on
or near energized lines, parts, or equipment.”
 Potential exposure greater than 2 cal/cm^2
 410-1, 410-2
 ATPV less than anticipated arc energy, <1000V
 arc hazard analysis
National Electric Safety Code
(NESC) - 2012
2012 code published August 1, 2011
 410-A3

◦ Perform a detailed arc hazard analysis
◦ Alternative – use clothing system tables
 410-1- independent of fault current
 50V - 1000V
 410-2
 1.1kV – 46kV
 410-3
 46.1kV – 800kV
Arc Flash Hazards
BBEC identified arc hazards over 2
cal/cm².
 Proactive approach to limit employee arc
exposure thru:

◦ Engineering controls
◦ Work rules
◦ Personal Protective Equipment
Objectives

Reduce potential for personnel injury due
to arc flash incidents
 Electrically safe?
◦ Identify hazards
◦ Provide guidance for performing required
duties on or near energized lines and
equipment
◦ Determine the best possible PPE

To comply with NESC-2007/NESC-2012
Arc Flash Analysis

What is Arc Flash Analysis?
◦ A study to determine the anticipated level of
incident energy personnel would be exposed to
 Conducted for the purpose of:
 Injury prevention
 Determination of the following:
 Safe work practices
 Arc flash protection boundary
 Effective arc rating of clothing systems
 Appropriate levels of PPE
 Training for personnel on hazards of arc flash
 Appropriate tools
 NFPA 70E, IEEE 1584
Arc Flash Calculation Variables



Voltage
Fault current in Amps
Duration of Fault in Seconds or Cycles
◦ Protective device clearing time


Arc Gap Length
Working Distance to Employee
◦ Arc to employee-assumptions vary depending on
task

Open Air versus Enclosed Space (“Arc in a
Box”
Arc Flash Analysis

Arc Flash Boundary
◦ Personnel inside the arc flash boundary are
required to wear the standard work uniform
when:




Performing work
Assisting in work
Observing work
(1.2 cal/cm^2)
Arc Flash Analysis

System normal
operating mode
◦ Non-Reclose
◦ Abnormal operating
mode requires
additional caution
 Proper documentation
of changes
 Reliable update process
Arc Flash Analysis
Proper equipment
operation
 Coordination study

◦ Proper equipment
◦ One shot

Adherence to
maintenance plan
Identified Work
Inside a substation between the transformer
low side and the outgoing primary feeders.
 On energized conductors or circuit parts over
600 volts.
 On energized conductors or circuit parts under
600 volts.
 To connect and disconnect meters.

Inside Substation

Boundary – inside the fence
◦ No rubber gloving
 Incident energy values may be excessive, the standard work
uniform will not provide effective AR protection during
rubber gloving procedures.
 Employees shall use a 15’ switch stick or a telescoping station
stick to maintain a minimum of 8’ from the potential arcing
source If under extreme conditions, an 8’ working distance
cannot be maintained, a hot stick barrier (safety shield meeting
ASTM F2522 – 05 standards) and an arc rated face shield shall
be worn to provide extra protection against arc flash impacts

.
Energized equipment over 600V



Boundary – 15’
Non-reclose
Rubber gloving


15” working distance
Hot sticks

OH
 8’ stick,
 6’ working distance

URD
 6’ stick
 4’ working distance
Energized equipment under 600V
Boundary – 15’
 Three Phase Enclosures

◦ Diagnostics only
 8’ hotstick
 8” probe

Single Phase Enclosures
◦ 15” working distance
Meters
Boundary – 15’
 Self contained

◦ Meter pullers
◦ Diagnostics
 8” probes
Hazard Identification and Risk
Assessment
Evaluate jobsite
 Identify hazard
 Risk reduction

◦ Engineering controls
◦ Work practices
◦ PPE
Safe Work Practices

Equipment Operation
◦ Unknown conditions

Switching and Tagging
◦ Verify/Authorize orders

Non-Reclose (HLTG)
◦ Normal mode

Cover-up
◦ Properly rated & applied

URD
◦ 4 feet minimum
Remote Switching

When applicable,
SCADA operations
shall be used to
remotely operate
switches. Remote
operation of switches
will reduce, if not
eliminate, employee
related arc flash
hazards.
Standard Work Uniform
8.7 cal/cm^2
 Shirt 8.7 cal/cm^2
 Pants 20 cal/cm^2
 Additional items

◦
◦
◦
◦
◦
Coveralls 20 cal/cm^2
Face shield 12 cal/cm^2
Balaclava 47.9 cal/cm^2
Hood 40 cal/cm^2
Ear Arc Plug
Responsibilities

Management
◦ Responsible for initiating, overseeing, reviewing
and updating a hazard recognition program to
identify arc hazards and controls.
◦ Responsible for communicating and training
employees on identified arc hazards.
◦ Responsible for implementing and enforcing the
arc hazard implementation plan and for regularly
reviewing and updating the program an necessary
to ensure all arc hazards have been effectively
identified and abated.
◦ Responsible for budgeting necessary funds to
ensure compliance.
Responsibilites

Supervisors, Foreman and Lead Technicians
◦ Identifying arc hazards and working with management
to develop processes and or procedures to minimize
and/or eliminate the hazards.
◦ Ensuring employees have received necessary arc
hazard training.
◦ Ensuring only qualified employees work on or near
equipment with potential arc hazards.
◦ Enforcing the arc hazard implementation plan
requirements including work rules and PPE.
Responsibilities

Employees
◦ Identifying arc hazards and working with
management to develop processes and or
procedures to minimize and/or eliminate the
hazards.
◦ Following work rules and wearing the
appropriate FR clothing and other PPE as
required.
Training

Employees will receive arc flash training
initially and every 3 years. Training will
include but not be limited to:
◦ – Electric arc hazards
◦ – Identified work practices with arc hazards.
◦ – Engineering controls to minimize arc
exposure
◦ – Work rules required to minimize arc
exposure.
◦ – PPE use, care and maintenance
Safety Rules
The arc flash implementation plan does
not eliminate any existing safety rules or
procedures.
 All employees are required to follow
established safety rules when working on
or near energized lines and equipment.
 All other work must be evaluated for arc
hazards before the start of work.
