Electric shock
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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]
Overview
An electric shock can occur upon contact of a human's body with any source of voltage high enough to cause sufficient current flow through the muscles or hair. The minimum current a human can feel is thought to be about 1 milliampere (mA). The current may cause tissue damage or fibrillation if it is sufficiently high. A fatal electric shock is referred to as electrocution.
Shock effects
Psychological
The perception of electric shock can be different depending on the voltage, duration, current, path taken, frequency, etc. Current entering the hand has a threshold of perception of about 5 to 10 mA (milliampere) for DC and about 1 to 10 mA for AC at 60 Hz. Shock perception declines with increasing frequency, ultimately disappearing at frequencies above 15-20 kHz.
Burns
Tissue heating due to resistance can cause extensive and deep burns. Voltage levels of (> 500 to 1000 V) shocks tend to cause internal burns due to the large energy (which is proportional to the duration multiplied by the square of the voltage) available from the source. Damage due to current is through tissue heating. In some cases 16 volts might be fatal to a human being when the electricity passes through organs such as the heart.
Ventricular fibrillation
A low-voltage (110 to 220 V), 50 or 60-Hz AC current travelling through the chest for a fraction of a second may induce ventricular fibrillation at currents as low as 60mA. With DC, 300 to 500 mA is required. If the current has a direct pathway to the heart (e.g., via a cardiac catheter or other kind of electrode), a much lower current of less than 1 mA, (AC or DC) can cause fibrillation. Fibrillations are usually lethal because all the heart muscle cells move independently. Above 200mA, muscle contractions are so strong that the heart muscles cannot move at all.
Neurological effects
Current can cause interference with nervous control, especially over the heart and lungs. Repeated or severe electric shock which does not lead to death has been shown to cause neuropathy.
When the current path is through the head, it appears that, with sufficient current, loss of consciousness almost always occurs swiftly. (This is borne out by some limited self-experimentation by early designers of the electric chair and by research from the field of animal husbandry, where electric stunning has been extensively studied) [2].
Arc-flash hazards
Over 80% of all injuries and fatalities caused by electrical incidents are not caused by electric shock, but by the intense heat, light, and pressure wave (blast) caused by electrical faults. The arc-flash in an electrical fault produces the same type of light radiation from which electric welders protect themselves using face shields with dark glass, heavy leather gloves, and full-coverage clothing. The heat produced may cause severe burns, especially on unprotected flesh. The blast produced by vaporizing metallic components can break bones and irreparably damage internal organs. The degree of hazard present at a particular location can be determined by a detailed analysis of the electrical system, and appropriate protection worn if the electrical work must be performed with the electricity on.
Issues affecting lethality
Other issues affecting lethality are frequency, which is an issue in causing cardiac arrest or muscular spasms, and pathway - if the current passes through the chest or head there is an increased chance of death. From a mains circuit the damage is more likely to be internal, leading to cardiac arrest.
The comparison between the dangers of alternating current and direct current has been a subject of debate ever since the War of Currents in the 1880s. DC tends to cause continuous muscular contractions that make the victim hold on to a live conductor, thereby increasing the risk of deep tissue burns. On the other hand, mains-frequency AC tends to interfere more with the heart's electrical pacemaker, leading to an increased risk of fibrillation. AC at higher frequencies holds a different mixture of hazards, such as RF burns and the possibility of tissue damage with no immediate sensation of pain. Generally, higher frequency AC current tends to run along the skin rather than penetrating and touching vital organs such as the heart. While there will be severe burn damage at higher voltages, it is normally not fatal.
It is sometimes suggested that human lethality is most common with alternating current at 100-250 volts, however death has occurred from supplies as low as 32 volts and supplies at over 250 volts frequently cause fatalities.
Electrical discharge from lightning tends to travel over the surface of the body causing burns and may cause respiratory arrest.
Lethality of a shock
The voltage necessary for electrocution depends on the current flowing through the body and the duration of the current flow. Using Ohm's law, Voltage = Current x Resistance, we see that the current drawn depends on the resistance of the body. The resistance of our skin varies from person to person and fluctuates between different times of day. In general, dry skin isn't a very good conductor having a resistance of around 10,000 Ω, while skin dampened by tap water or sweat has a resistance of around 1,000 Ω.
The capability of a conducting material to carry a current depends on its cross section, which is why males typically have a higher lethal current than females (10 amperes vs 9 amperes) due to a larger amount of tissue. However, death can occur from currents as low as 0.1 to 0.3 amps.
Using Ohm's law, we may derive the voltages lethal to the human body. This is given in the following table: [1]
Electric current (amperes) | Voltage at 10,000 ohms | Voltage at 1,000 ohms | Maximum power (watts) | Physiological effect |
0.001 A | 10 V | 1 V | 0.01 W | Threshold of feeling an electric shock, pain |
0.005 A | 50 V | 5 V | 0.25 W | Maximum current which would be harmless |
0.01-0.02 A | 100-200 V | 10-20 V | 1-4 W | Sustained muscular contraction. "Cannot let go" current. |
0.050 A | 500 V | 50 V | 25 W | Ventricular interference, respiratory difficulty |
0.1-0.3 A | 1000-3000 V | 100-300 V | 100-900 W | Ventricular fibrillation. Can be fatal. |
6 A | 60,000 V | 6,000 V | 400,000 W | Sustained ventricular contraction followed by normal heart rhythm.
These are the operation parameters for a Defibrillator. Temporary respiratory paralysis and possibly burns. |
Point of entry
- Macroshock: Current flowing across intact skin and through the body. Current traveling from arm to arm, or between an arm and a foot, is likely to traverse the heart, and so is much more dangerous than current traveling between a leg and the ground.
- Microshock: Direct current path to the heart tissue
Avoiding danger of shock
It is strongly recommended that people should not work on exposed live conductors if at all possible. If this is not possible then insulated gloves and tools should be used. If both hands make contact with surfaces or objects at different voltages, current can flow through the body from one hand to the other. This can lead the current to pass through the heart. Similarly, if the current passes from one hand to the feet, significant current will probably pass through the heart. An alternative to using insulated tools is to isolate the operator from ground, so that there is no conductive path from the live conductor, through the operator's body, to ground. This method is used for working on live high-voltage overhead power lines. [2]
It is possible to have a voltage potential between neutral wires and ground in the event of an improperly wired (disconnected) neutral, or if it is part of certain obsolete (and now illegal) switch circuits. The electrical appliance or lighting may provide some voltage drop, but not nearly enough to avoid a shock. "Live" neutral wires should be treated with the same respect as live wires. Also, the neutral wire must be insulated to the same degree as the live wire to avoid a short circuit.
Electrical codes in many parts of the world call for installing a residual-current device (RCD or GFCI, earth fault circuit interrupter) on electrical circuits thought to pose a particular hazard to reduce the risk of electrocution. In the USA, for example, a new or remodeled residential dwelling must have them installed in all kitchens, bathrooms, laundry rooms, garages, and any other room with an unfinished concrete floor such as a workshop. These devices work by detecting an imbalance between the live and neutral wires. In other words, if more current is passing through the live wire than is returning though its neutral wire, it assumes something is wrong and breaks the circuit in a fraction of a second. There is some concern that it might not be fast enough for infants and small children in rare instances.
The plumbing system in a home or other building has traditionally used metal pipes and thus been connected to ground through the pipes. This is no longer always true because of the extensive use of plastic PVC piping in recent years, but a plastic system cannot be relied upon for safety purposes. Contrary to popular belief, pure water is not a good conductor of electricity. However, most water is not pure and contains enough dissolved particles (salts) to greatly enhance its conductivity. When the human skin becomes wet, it allows much more current to flow than the dry human body would. Thus, being in the bath or shower will not only ground oneself to return path of the power mains, but lower the body's resistance as well. Under these circumstances, touching any metal switch or appliance that is connected to the power mains could result in electrocution. While such an appliance is not supposed to be live on its outer metal switch or frame, it may have become so if a defective live bare wire is accidentally touching it (either directly or indirectly via internal metal parts). It is for this reason that mains electrical sockets are prohibited in bathrooms in the UK. However, widespread use of plastic cases for everyday appliances (which won't conduct electricity), grounding of these appliances, and mandatory installation of Residual Current Devices (R.C.D.s) have greatly reduced this type of electrocution over the past few decades.
A properly earthed appliance eliminates the electric shock potential by causing a short circuit if any portion of the metal frame (chassis) is accidentally touching the live wire. This will cause the circuit breaker to turn off or the fuse to blow resulting in a power outage in that area of the home or building. Often there will be a large "bang" and possibly smoke which could easily scare anyone nearby. However, this is still much safer than risking electric shock, as the chance of an out-of-control fire is remote. Many people in this situation have nevertheless called the fire department as a precaution.
Where live circuits must be frequently worked on (e.g. television repair), an isolation transformer is used. Unlike ordinary transformers which raise or lower voltage, the coil windings of an isolation transformer are at a 1:1 ratio which keeps the voltage unchanged. The purpose is to isolate the neutral wire so that it has no connection to ground. Thus, if a technician accidentally touched the live chassis and earth at the same time, nothing would happen.
Neither earth fault circuit interrupters (RCD/GFCI) nor isolation transformers can prevent electrocution between the live and neutral wires. This is the same path used by functional electrical appliances, so protection is not possible. However, most accidental electrocutions, especially those not involving electrical work and repair, are via earth -- not the neutral wire.
First Aid
In helping a victim of an electric shock, the first thing you must do is disconnect the power supply, if it is safe to do and will not take long to find; touching the power source may put you in danger. If the victim is in contact with something portable such as a hair dryer, attempt to move it away using a non-conductive object such as a wooden broom. Time is precious and knocking the victim from the source can prove an effective way to speed the process. Do not attempt to touch the affected person until they are free and clear of the supplied power. Don’t even touch the victim until you are sure the power supply is turned off. Be especially careful in wet areas, such as bathrooms, since most water will conduct electricity and electrocuting yourself is also possible.
People "hung up" in a live current flow may think they are calling out for help but most likely no sound will be heard from them. When the muscles contract under household current, the person affected will appear in lock-up state, unable to move or react to you. When using a wooden object, swiftly knock the person free without severely trying to injure them, but strong enough to free, and land them clear of the source. The source may also be lifted or removed, if possible, with the same wooden item. This is not recommended on voltages that exceed 500v. Most electrocutions happen from house current at home. Do not attempt without rubber or some form of insulated sole shoes; bare or socked feet will allow the current to flow to ground through your body as well.
First aid instructions
- Check if you are alone. If there are other people around, instruct them to call an ambulance right away.
- Check for a response and breathing. If the area is safe for you to be in, and you have removed the object or have cut off its power supply, yell to the person to see if they are conscious. At this stage, do not touch the victim. Check once again to see if the area is safe. If you are satisfied that it is safe, start resuscitating the victim. If you have no first aid knowledge, skip to the next step if someone has not already done it for you.
- Call emergency services for an ambulance.
- If the breathing and pulse are steady, attend to injuries. Cool the burns and cover with dressings that won’t stick. Never put ointments or oils onto burns. If the victim has fallen from a height, only move them if there is chance of further danger (such as falling objects). Try not to move them unnecessarily in case of spinal injuries or causing them excess pain, unless you are satisfied that moving them is necessary to prevent further dangers.
- Talk calmly and reassuringly to the conscious victim until the ambulance arrives.
Electrocution statistics
There were 550 electrocutions in the US in 1993, which translates to 2.1 deaths per million inhabitants. At that time, the incidence of electrocutions was decreasing. [3]
Deliberate uses
Electric shock as medical treatment
Electric shock can also be used as a medical therapy, under carefully engineered conditions:
- In a psychiatric therapy for mental illness, called in modern usage Electroconvulsive therapy or ECT; previously referred to as electroshock therapy or EST. The objective of the therapy is the seizure induced, not the shock or the physical convulsions. There is no sensation of shock because the patient is anesthetized. The therapy was originally conceived of after it was observed that depressed patients who also suffered from epilepsy experienced some remission after a spontaneous seizure. The first attempts at deliberately inducing seizure as therapy used not electricity but chemicals; however electricity provided finer control for delivering the minimum stimulus needed. Ideally some other method of inducing seizure would be used, as the electricity may be associated with some of the negative side effects of ECT including amnesia.
- As a treatment for fibrillation or irregular heart rhythms: see defibrillator and cardioversion.
- As a method of pain relief: see Transcutaneous Electrical Nerve Stimulator (more commonly referred to as a TENS unit).
- As an aversive punishment for conditioning of mentally handicapped patients with severe behavioral issues. This method is highly controversial and is employed at only one institution in the United States, the Judge Rotenberg Institute. The institute also uses electric shock punishments on non-handicapped children with behavioral problems. Whether this constitutes legitimate medical treatment versus abusive discipline is the subject of ongoing litigation.
Torture
Electric shocks have been used as a method of torture, since the received voltage and amperage can be controlled with precision and used to cause pain while avoiding obvious evidence on the victim's body. Such torture usually uses electrodes attached to parts of the victim's body. The genitalia are amongst the most painful, and at the same time humiliating. Nipples and the tongue are also frequent sites. Another frequent method of electrical torture is stunning with an electroshock gun such as a cattle prod or a taser (provided a sufficiently high voltage and non-lethal current is used in the former case).
The Nazis are known to have used electrical torture during World War II. An extensive fictional depiction of such torture is included in the 1966 book The Secret of Santa Vittoria by Robert Crichton. During the Vietnam War, electric shock torture is said to have been used by both sides. A scene of electrical torture in the American Deep South is included in the 1980 Robert Redford film Brubaker. Amnesty International published an official statement that Russian military forces in Chechnya tortured local women with electric shocks by connecting electric wires to their bra straps [4]. An example in popular modern culture is the electric torture of Riggs in Lethal Weapon.
Advocates for the mentally ill and some psychiatrists such as Thomas Szasz have asserted that electroconvulsive therapy is torture when used without bona fide medical benefit against recalcitrant or non-responsive patients. See above for ECT as medical therapy. These same arguments and oppositions apply to the use of extremely painful shocks as punishment for behavior modification, a practice that is openly used only at the Judge Rotenberg Institute.
Capital punishment
Electric shock delivered by an electric chair is sometimes used as a means of capital punishment, although its use has become rare in recent times. Although the chair was at one time considered a more humane and modern execution method than hanging, shooting, or decapitation, it is now being replaced for the same reasons by lethal injection. Modern reportage has revealed that it sometimes takes several shocks to be effective, and that the condemned person may actually catch fire before the process is complete.
Throughout the world, execution via electric shock has widely been regarded as inhumane. Other than the United States, only the Philippines used this method for a few years. It remains a legal means of execution in some states of the USA.[5] It is reportedly one of the most grisly forms of modern execution to witness, with smoke or actual flame visible, coming from the prisoner's garments or cap.
Notes
- ↑ "Dangers of electricity". Arizona State University. Retrieved 2007-06-14.
- ↑ Philippe Morel, "Line Maintenance Reaches New Heights", Transmission & Distribution World, Aug 1, 1999, accessed 2007-06-22
- ↑ Folliot, Dominigue (1998). "Electricity: Physiological Effects". Encyclopaedia of Occupational Health and Safety, Fourth Edition. Retrieved 2006-09-04.
- ↑ Russian Federation Preliminary briefing to the UN Committee against Torture 1 April 2006, statement by Amnesty International
- ↑ http://www.deathpenaltyinfo.org/state/
See also
External links
- National Institute for Occupation Safety & Health: Worker Deaths by Electrocution a CDC study.
- Physiological effects of electricity
- Shock current path
- Electrical injury (Merck Manual)
- Electric Shock Hazards (Hyperphysics)
- Question: Why Does Mixing Water and Electricity Cause Electric Shock?
- Electric Shock - a more technical perspective
- Construction Safety Association of Ontario: Electrocution ... article with case studies
- Protection against electric shocks - Physiological effects and protection rules
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bg:Токов удар de:Stromunfall it:Folgorazione he:התחשמלות nl:Elektrocutie fi:Sähköisku