Electrical Shock Hazard
If electrical systems are not properly wired to remove dangerous voltage, persons can be subjected to electric shock, which can result in injury or death.People become injured and death occurs when voltage pushes electrons through the human body, particularly through the heart. An electrical shock from as little as 50V alternating current for as little as one second can disrupt the hearts rhythm resulting in death in a matter of minutes from ventricular fibrillation.
What determines the severity of electric shock?
The severity of an electric shock is dependent on the current flowing through the body, which is impacted by the electromotive force (E) measured in volts and the contact resistance (R) measured in ohms, using the formula is I = E/R.
Electric Shock
Values
- Electrical Sensation. Tingle sensation occurs at about 0.25 to 0.5 mA for an adult female and between 0.50 and 1 mA for an adult male.
- Uncomfortable Sensation. Current over 1 - 2 mA is very uncomfortable to both sexes.
- Maximum Let-Go Level. The maximum Let Go Threshold level for a female is approximately - 9 mA and for a male it is about - 15 mA.
The "Let Go" Threshold is the
current level where we lose control of our muscles and the electricity causes
muscles to contract until the current is removed.
According to the IEEE Std. 80, the maximum
safe shock duration can be determined by the formula Seconds = 0.116/(E/R), where
R (resistance of person) is assumed to be 1000 ohms.
For a 120V circuit the maximum shock duration
= 0.116/(120V/1000) = 1 Second
For a 277V circuit the maximum shock duration = 0.116/(277V/1000) = 0.43 Second
For a 277V circuit the maximum shock duration = 0.116/(277V/1000) = 0.43 Second
To protect against electric shock from
dangerous voltages on metal parts of electrical equipment from a ground-fault
must be quickly removed by opening the circuit’s overcurrent protection device.
The time it takes for an overcurrent protection device to open and clear a ground-fault
and remove dangerous voltage is inversely proportional to the magnitude of the
fault current. This means that the higher the ground-fault current, the less time
it will take for the overcurrent device to open and clear the fault.
An inverse time circuit breaker or fuse
most likely will prevent serious electric shock if the ground-fault current is
at least six times the rating of the overcurrent protection device. For a 20A
circuit, the ground-fault current should be at least 120A.
As is apparent, the impedance of the fault
current path plays a critical and vital role in removing dangerous voltages from
metal parts by facilitating the opening of the branch-circuit overcurrent protection
device to prevent electric shock or electrocution.
Source By Mike Holt
http://www.mikeholt.com/mojonewsarchive/ET-HTML/HTML/EletricalShockHazard