1. ELECTRICAL SAFETY AWARNESS TRAINING
Training Program
Updated 5/5/04

2. Electrical Fires in the USA
Daily, fires occur due to electrical problems: defective electrical device, circuit overloading, circuit overheating, explosions ignited by electrical spark, etc.
Electricity is one of the most common causes of fire in the USA. Each year there are approximately:
1.6 million fires (all causes) reported,
causing 3,600 fire deaths,
18,000 fire related injuries,
$10.7 billion in property damage.
Source: National Fire Protection Association, 2007

3. Grounding What is Grounding?
“Grounding” a tool or electrical system means intentionally creating a low-resistance path that connects to the earth. This prevents the buildup of voltages that could cause an electrical accident.
Grounding is normally a secondary protective measure to
protect against electric shock. It will substantially reduce the
risk of injury or death in case of shock, especially when used
in combination with other electrical safety measures.
An equipment ground helps protect the equipment operator.
It furnishes a second path for the current to pass through
from the tool or machine to the ground. This additional
ground safeguards the operator if a malfunction causes the
tool’s metal frame to become energized. The resulting flow
of current may activate the circuit protection devices.

4. Protection Overcurrent Protection
Fuses and circuit breakers open/break the circuit automatically when too much current flows through them.
This is designed to protect the wiring/equipment from overheating and possible damage – NOT THE USER
GFCI (Ground Fault Circuit Interrupter)
Used in wet and other high-risk areas.
Stops the flow of electricity when there is
a difference between current leaving and
returning from the outlet.
Should be tested monthly
Push test button and then the reset button
The basic idea of an over current (think of overcurrent as current out of control) protection device is to create a weak link in the system that will stop the flow of electricity before the overcurrent can cause any other damage.
Overcurrent protection devices should always be placed on the hot leg and sized appropriately. Improper sizing can cause wiring or equipment to be damaged before the protection device has a chance to do its job.
These devices may not and are not intended to protect people; they protect equipment.

5. Power Extension Cords and Power Strips
Extension Cords & Power Strips are for TEMPORARY use only!
They may not be run through doorways, ceilings or windows
Power Strips (Transient Voltage Surge Suppressors)
FOR ELECTRONICS ONLY (Computer Equipment etc.)
NOT FOR APPLIANCES (Refrigerator, Microwave Toaster, Coffee Pot, Water Cooler etc.)
Do not overload
The number of outlets on the power
strip does not indicate how many
devices can be connected
Power extension cords and power strips (also known as power taps) are a means to deliver electricity from a power source to a tool or device located where the power source is not.
Sometimes the use of such power delivery devices presents overloading factors.
The possible consequences of using a power strip should be considered beforehand.
Some concerns include
Damaged or faulty devices posing fire and shock hazards
Tripping hazards
Rules to follow:
Extension cords are authorized only for temporary use (to do the job at hand, not to remain as a power source for an extended amount of time (days, weeks).
Extension cords may not be run through doorways, windows, ceilings, etc. whereby they may be damaged and/or pose tripping hazard
Extension cords may not be smaller in diameter then the tool power cords to which they are connected
Power strips are authorized only for temporary use, if they are to be used as extension cords
Power strips designated as TVSS may be used for longer periods of time for electronic devices only (computers and components, adding machines, clocks, radios) but should not be overloaded or doubled-up
Power strips and extension cords may not be used for appliances (refrigerators, microwaves, coffee pots, portable heaters)
All devices and cords must be UL or comparably approved and in good working condition without any signs of damage 12

6. Properly Used Power Strip
EXAMPLES OF A PROPERLY
USED POWER STRIP
STRIP IS NOT OVERLOADED
ONLY COMPUTER (ELECTRICAL) EQUIPMENT IS ATTACHED TO STRIP
CORDS ARE KEPT NEAT
NO EXTENSION CORDS ARE ATTACHED TO POWER STRIP
POWER STRIP IS ATTACHED DIRECTLY TO WALL OUTLET-NO EXTENSION CORD IS USED

7. Improperly Used Power Strip
EXAMPLES OF AN IMPROPERLY
USED POWER STRIP
POWER STRIP IS OVERLOADED DUE TO MINI-FRIDGE, MICROWAVE, AND TWO-POT COFFEE MAKER ALL ON ONE POWER STRIP
APPLIANCES ARE CONNECTED TO A POWER STRIP (THEY SHOULD BE CONNECTED DIRECTLY INTO A WALL OUTLET)
POWER STRIP IS NOT CONNECTED DIRECTLY TO THE WALL OUTLET - AN EXTENSION CORD IS USED
EXTENSION
CORD IS USED
WITH POWER
STRIP

8. Damaged and Unapproved Devices
Not Permitted:
Cord plug with ground prong missing
Damaged TVSS rated power strip
Adapter enables circuit overload

9. Damaged and Unapproved Devices
Not Permitted:
Lamp extension cord, also damaged
Power taps
Adapter to change 3-prong plug
to 2-prong eliminating ground

10. Container Bonding and Grounding (Static Electricity)
Bonding Cable
Grounding Cable
Grounding Bus
or Electrode
Proper grounding and bonding is used to address the dangers of static electricity.
In order for grounding to protect, all surfaces must be bonded together and grounded to earth.
Static electricity is thereby released to earth as it is generated, preventing the accumulation of dangerous charges that may ignite flammable / hazardous substances. 7

11. Responsibilities
Entire system must be properly bonded and grounded to the earth
Facilities
Responsible for the system up to the wall outlet (all wiring and outlets)
User
Responsible for the condition of plug and cord of equipment
Inspect equipment to ensure plugs and cords are not damaged.
Do not break off third prong or use adaptors
No Prong = Not Grounded

12. Electrical Safety Incidents
The following is an example of :
Electrocution Due to Improper Use of Common Equipment

13. Background
Dr. X was conducting an experiment related to plant growth.  He needed to expose the plants to light for specific time-periods each day.   Accordingly, he had a portable fluorescent lighting rack constructed and mounted on a wooden frame.  He also obtained an electric timer to automatically turn the lights on and off. The light fixture was plugged into the timer, which was plugged into the wall outlet.  However, since the timer only accepted a two prong plug, an adapter was used to allow the three prong plug of the lighting rack to be used with the two prong outlet of the timer.

14. The Incident
Dr. X adjusted the timer so that the lights would be on and plugged the timer into a standard 3-prong wall outlet.  Then another person in the lab noticed Dr. X grasping the lighting rack and appearing to be rigid.  A third person grasped Dr. X by the shoulders and pulled him away from the lighting rack.  CPR was performed on him until EMS arrived.  Dr. X was transported to a hospital where he was pronounced dead.

15. The Investigation The investigation revealed the following details:
A potential difference of 397 volts was measured between the metal fluorescent light fixture and the adjacent stainless steel sink.  (There should not have been any potential difference).    
Both the fixture and the wall outlet were found to be wired correctly.
The light fixture was rated for 800 mA, but the lamps used were 1500 mA.
The transformer in the ballast was found to have short circuited to the case.

16. What Probably Happened
Use of bulbs drawing more current than approved for the fixture caused overheating of the ballast resulting in melting of insulation around the transformer coil.  This allowed an energized transformer wire to touch the metal cover of the ballast which in turn energized the metal fluorescent fixture.  The lights probably continued to function since they were wired correctly. When Dr. X grasped the fixture, some part of him probably brushed against the nearby metal sink.  This completed a circuit to ground through Dr. X, electrocuting him.

17. Preventing this Fatality
As with many very serious accidents, a number of factors were involved, any
one of which could have prevented this fatality.
If overrated lamps had not been used, the ballast would probably not have overheated and failed.
If the ground wire connection between the light fixture and the plug not been interrupted by the "cheater" adapter and the two-prong timer, the fixture would have safely shorted to ground tripping the circuit breaker when the equipment was plugged in before Dr. X touched it.
Had the standard outlet near the sink been Ground Fault Circuit Interrupter (GFCI) protected (as it should have been because it was near a sink), the GFCI would have tripped at the first flow of current through Dr. X immediately cutting off power to the fluorescent fixture and saving his life.
These electrical safety violations cost Dr. X his life.  If any one of them had been
corrected before the incident, Dr. X would still be researching plant growth.

18. Don’t Let This Happen in Your Lab!
1)Follow manufacturer's recommendations for use of  electrical
equipment.  Do not use electrical equipment for a task it is not designed
for.
2) Generally, equipment used in research should have a 3 prong plug or
be double insulated. Equipment with neither of these features are less
safe but may meet electrical codes.  A 3 prong plug must always go into
a 3 prong outlet.  Do not use a "cheater" plug or pull out the 3rd prong.
3) Do not use multiple cube taps in a standard outlet.  If you must plug
more than two pieces of low demand equipment into a standard outlet,
use a fused power strip that will trip if too much power is used.
4) Make sure that any outlet near a sink or other water source is Ground
Fault Circuit Interrupter (GFCI) protected.  If you have a GFCI,
periodically test it by plugging something into it and pushing the "test“
button.  The equipment should turn off and then turn it back on.

19. …continued
5) If you see a person being electrocuted, DO NOT TOUCH HIM!  The
electricity can go though you too.  If possible, remove the power (pull
plug or trip circuit breaker), or use a non-conductive item (e.g. wooden
broom handle) to pry him away from the contact.
6) Above all, do not disable any electrical safety feature expecting that
another safety feature will protect you.  In the incident described above,
if proper lamps were used, the ballast could still have been defective
from other causes.  Also, GFCIs can be defective.  That is why they
should be periodically tested.
7)  Check that power cords are in good condition.
8) Do not use extension cords as a substitute for permanent wiring.

20. Electrical Work
Electrical work is only to be performed by qualified individuals
Contact Facilities X4588 for ALL electrical work
Do not attempt to fix on your own
Attempting to repair equipment
yourself may create a hazard
This information is only provided to familiarize the reader with some basic concepts so he/she may better understand.
EEW pertains to qualified electrical workers.
They must attend additional and more extensive training than provided in this section.
This does not apply to anyone attending the New Employee Orientation Training. 13

21. Conclusion Know and follow safe work rules and practices
NO EXTENSION CORDS AS PERMANENT WIRING
POWER STRIPS ARE FOR ELECTRONICS ONLY
Report all unsafe conditions to Facilities X4588 or EHS X4078
Do not take shortcuts and risk the safety of yourself or others.
Know and follow safe work practices and procedures, and if you are unsure…ASK!!
Use only appropriate tools and equipment for the work to be done.
Inspect all tools and equipment prior to and during work activity.
The label UL Approved only means the device left the factory meeting certain criteria.
During the time that you may use the device, it may become damaged, therefore exposing yourself and others to hazards.
Remember: stray electric current caused by damage to a device can shock, seriously injure or kill.
Report any and all unsafe conditions:
Receiving an electric shock
Sparks
Overheating or smoking equipment;
Corroded/damaged outlets, switches and junction boxes;
Damaged extension cords and equipment power cords that are in use;
Exposed wiring, broken plugs, outlets, missing box cover or faceplates;
Outlets in damp areas not equipped with GFCI.
Stay productive and safe - follow the rules.