Electricity accident

As electric injuries , electrical accident, also electric shock or electrocution a is injury by the action of the electric current refers to humans or animals. The extent of the damage is determined by several factors. The most common consequences of electrical accidents are chemical and thermal effects ( burns ), neurological effects, muscle irritation (e.g. muscle spasms , tetanic muscle contractions ) or muscle paralysis . The latter, in turn, can lead to life-threatening cardiac arrhythmias such as ventricular fibrillation as well as cardiac and circulatory arrest or respiratory paralysis with fatal outcome. Not to be underestimated are accidents caused indirectly, such as falls with considerable consequences. The following are decisive for the effects of an electrical accident:

• the current strength per area (current density), which is set due to the circumstances described below in the article (especially voltage and resistance),
• the type of current - alternating current or direct current ,
• the frequency (only available with pulsating direct current or alternating current)
• the state of health or age
• the presence or absence of medical implants
• the current path through the body (e.g. hand - hand; hand - foot, left, right)
• the duration of the electric current
• the size of the contact surfaces (for contact without voltage flashover)
• the conductivity at the contact point (for contact without voltage flashover)
• the step voltage (during thunderstorms or grounded power systems)

Warning sign W012 according to ISO 7010 : Warning of electrical voltage

Basics

A closed circuit is always required for electrical current to flow . At low voltage, direct contact with both poles of the voltage source is required. If a consumer (such as an electric motor) is only connected to one wire and thus only to a single electrical pole, the circuit is not closed and the consumer does not work because no current can flow.

If a person touches both lines of a voltage source at the same time, the circuit closes, causing current to flow through the person concerned. In the special case of an IT system , a single line can be touched without current flowing. Much more often, however, a conductor is earthed in power grids , which means that even in the low-voltage range, contact with a single conductor, depending on the earthing conditions, can lead to electric shock. Depending on the respective earthing system of the household electricity (such as the TT system or TN system ), the neutral conductor and the protective conductor may be touched safely if correctly installed , but not the external conductors (phase) carrying voltage to earth. If, however, there is only contact with the phase, i.e. without the protective conductor or neutral conductor involved, either a dangerous current flows through the human body via the earth or earthed objects or, if the location is isolated, a lower current flows, which can also be dangerous , about the body.

This type describes the most common electrical accidents in the true sense of the word. The current flows over the body surface through the intact skin. Since the skin resistance makes up the largest part of the body resistance , much lower currents flow with the same applied voltage than with a so-called micro shock.

The average child can let go of the power source between 3 and 5 milliamps, the average adult between 6 and 9 milliamps, with 6 milliamps for women and 9 milliamps for men. In the skeletal muscles, contractions are triggered by low-frequency alternating current from a strength of 10 milliamperes , sometimes even from 8 milliamperes (the so-called release threshold , dangerous area AC3 begins), which, due to the stronger development of the flexors, lead to a " Holding on ”to the live parts and thus lead to a longer exposure time. Even this strength of current can be fatal for children. Cardiac arrhythmias are already possible with currents of 25 milliamps. From 30–50 milliamperes, a contracture , that is, tension of the respiratory muscles and the diaphragm , can occur in the thoracic area and thus a respiratory arrest for the duration of the current flow. This can also happen if the flow of current affects the breathing center in the brain stem (e.g. typically in a lightning accident with head perfusion).
Alternating current at 50 Hz can, depending on the area of ​​activity, lead to ventricular fibrillation at a current strength of approx. 50 mA and more and if it is used for more than one second. The current path is decisive here: if current flows in the chest-back or chest-left hand area, ventricular fibrillation is already possible at 27 mA. If the hand flows towards the foot, ventricular fibrillation can be expected from 40 mA.

High frequencies from around 100 kHz only lead to lower frequencies ; those from around 300 kHz no longer lead to nerve stimulation , since the ionic conduction prevailing in them is unable to follow the rapid polarity changes. The thermal damage, which is dependent on the voltage-current strength relationship, can nevertheless occur and is desirable in HF surgery in order to stop bleeding.

Although the effects of an electrical accident, as mentioned, depend on the current strength per body area and the duration of exposure, the voltage is mostly used as an indication of possible dangers, mainly due to Ohm's law . In addition, even when approaching non-insulated lines without contact, high voltage can lead to voltage flashover with the formation of arcs or, if there is insufficient or damaged insulation in power cables, to voltage breakdown. Thus, the information about the level of the voltage also serves to maintain the required safety distances to overhead lines at high voltage , which increase with increasing voltage.

The concrete value of the electric current flowing through the body results from the voltage and the body resistance (in the case of alternating voltage also the frequency) that the human or animal body forms. This is not constant and depends on various parameters. In practice, the sources of danger are mostly voltage sources . The higher the voltage (and frequency) or the lower the resistance, the more current flows through the body. Therefore, the level of the electrical voltage is usually used as a criterion for the classification of the danger, since the body resistance moves in certain known ranges.

According to the Association of Electrical, Electronic and Information Technologies , the maximum contact voltage in Germany must not exceed 50 V AC or 120 V DC. According to the Austrian Association for Electrical Engineering , the maximum contact voltage in Austria must not exceed 65 V AC or 120 V DC.

For the total body resistance, the transition resistance ( electrical resistance ) at the point of entry of the current in the skin, the skin itself, the body resistance (the resistance that the individual body tissues oppose for themselves and in their entirety to the flow of current) and the transition resistance at the point of exit are decisive. The latter is often largely determined by the nature of the standing area (floor conditions) and the shoes worn.

The guideline value for the skin resistance is very variable and depends on the current path as well as the condition, this is in the range from below 100 Ω to well over 1000 Ω. The body resistance as well as that of the muscles is around 1000 Ω. For an adult and a current path from the right hand to the left or right foot, for example, values ​​between 500 Ω and 3 kΩ are measured. This value can be lower if the skin is touched over a large area, if the skin is thin (for example, in babies) and if the distance is shorter. Especially damp or wet skin (for example from soapy water or sweat ) causes a massive drop in skin resistance. If the total body resistance is measured with a multimeter and with a low measuring voltage, very high values, often over 1 MΩ, are displayed. However, this is strongly dependent on the applied voltage, frequency and humidity and can therefore be regarded as a varistor . Contact with high voltages causes a breakdown through the skin, so that only the body resistance applies. In addition, a higher resistance of the skin as well as a longer contact time in accordance with the law of electricity heat cause burns of the skin of varying severity. In the relevant literature, a body resistance of 1 kΩ to 2.4 kΩ is assumed. In the defibrillator , which is used to preserve life , the voltage is up to 750 volts and is applied between 1 and 20 ms. The contact resistance from the electrodes to the body is intentionally made particularly small. With an assumed average body resistance of 500 Ω, the current strength then reaches up to about 1.5 A.

Exposure time

Electric shocks cause damage, which depends on their duration. For example, electrostatic discharges (voltages up to over 15 kilovolts) generally only lead to shock reactions or secondary accidents, despite their high current strength of a few amperes, as their discharge duration is only less than a microsecond. With the electric fence energizer (impulses of a few kilovolts) this is used to keep animals away without harming them. Muscle contractions already occur in both cases, but these do not yet lead to dramatic, uncoordinated movements. However, shock reactions can lead to secondary accidents.

If the exposure time exceeds about 100 milliseconds, the limit current strength for ventricular fibrillation (risk of death), which is almost 500 mA from 20 ms to then , drops sharply until it is approximately 40 mA from about 1 s exposure time. Accordingly, the residual current circuit breakers used to avoid electric shocks trigger within 100 ms at a residual current of 30 mA. In the case of larger fault currents, the tripping time is shorter and is a minimum of around 20 ms - a value that offers protection even if someone connected to the earth touches a conductor carrying mains voltage. Residual current circuit breakers only offer protection against leakage currents to earth.

frequency

Burns from electrical accidents

In Germany between 36 and 100 people die each year (observation period 2000–2015) as a result of electrical accidents, around 90% of which are caused by low voltage and 10% by high voltage . About 30% of high and 3% of low voltage accidents result in death.

The Institute for Research into Electrical Accidents (BG ETF) at the Employer's Liability Insurance Association for Energy, Textile, and Electro Media Products ( BG ETEM ) in Cologne has been collecting statistical data on electrical accidents in Germany for decades, which, due to the large amount of data, also allows statements to be made about the frequency of death.

Current path	Total accidents	of which fatal	rel. distribution		Lethality
			all in all	fatal
Hand-hand	2891	82	77.3%	48.5%	2.84%
Hand foot	349	19th	9.2%	11.2%	5.44%
Hand-feet, hands-foot	294	18th	7.7%	10.7%	6.12%
Hands feet	106	20th	2.8%	11.8%	18.67%
shortened current paths upper body (like hand-chest, or chest-back)	108	30th	3.0%	17.8%	27.78%
all in all	3748	169	100%	100%	4.51%

The basis for the evaluation were the accidents at work due to electrical current reported at the Institute for Research on Electrical Accidents of the BGFE (from 2008: BG ETF) in the years 1969 to 1996. The data in the table only includes power accidents in the low voltage range from 130 volts to 400 volts with 50 Hertz alternating voltage, for which a minimum flow time of 300 milliseconds can be assumed.

A research group led by J. Jacobson determined the probabilities of the occurrence of ventricular fibrillation from animal experiments with pigs . The aim was to determine comparison factors in order to be able to transfer the measured data to humans. The following test conditions were passed:

• Alternating current at 50 Hertz
• Duration of action 75% of the heart pulse period
• Longitudinal flow (right ear to left knee fold)
• Body mass of pigs 15 kg to 25 kg

Flicker probability	1 %	5%	50%	95%
Current rms value in A	0.63	0.79	1.50	2.80

A correction factor of 2.8 was determined to transfer these current values ​​to the conditions in humans (right arm to left foot). This means that the effective values for the current in the table must be multiplied by 2.8. Conservatively (with a safety factor), this correction factor is only assumed to be 1.5.

In Switzerland , electric shock on overhead lines is the most common non-natural cause of death for storks, eagle owls and other large birds .

Sources of danger

Source of danger: defective power cord: the jacket is damaged, so the protective insulation is no longer provided

Common causes of electric shock are:

• defective electrical devices or electrical lines and human errors in handling them (e.g. carelessness or negligence )
• Suspended live overland and overhead lines due to damage to the mast from storms and storms
• Touching overland and overhead lines (with objects) (e.g. with kites )
• Approaching high-voltage lines (can already lead to (life-threatening) voltage flashover)
• Failure to comply with safety distances
• Contact with live flooded areas
• lightning strike
• Unprofessional intervention in the existing electrical installation
• Fires in high voltage systems (including electric railways) that are fought with unsuitable extinguishing agents
• Accidents on electrically operated systems or devices
• Incorrect agreements about the activation of systems and lines
• Leakage current due to missing grounding or missing short-circuiting of a disconnected line
• Contact with a stun gun (Taser, the level of danger being disputed )
• Allegedly voltage-free components due to the mains isolator

Special organ damage

The consequences of the electrical accident are also dependent on the electrical conductivity of the individual tissues or organs, which increases with the level of the electrolyte content.

The lower the electrical resistance, the more current flows through the affected region. Thus, the different electrical resistances of the individual tissues in the human body are largely responsible for the path that the majority of the electrical current takes. The nerve tissue and blood show the lowest resistance , followed by blood vessels , mucous membranes and muscle tissue . Skin, tendons, fatty tissue and bones, which have a significantly higher electrical resistance, follow in ascending order. Accordingly, with direct current and low-frequency currents, nerve tissue, as well as bleeding tissue or tissue and muscle tissue with good blood flow, are most likely to have the most current flowing through them. Nevertheless, a higher resistance such as skin is only conditionally better protection, because as soon as electricity flows through it, electrical energy is converted into heat, which causes burns and tissue is destroyed. Smaller parts of the body such as fingers and hands or small surfaces can also be irreversibly destroyed more quickly if the current is not diverted enough.

However, the extent and severity of the consequences of an electrical accident cannot be deduced from the damage to the body surface (such as the skin) alone.

Especially in accidents with high voltage currents, peripheral nerves are often damaged, in some cases even delayed. Since the flow of current through the hands and arms usually occurs in the low-voltage range, mainly the median , ulnar and radial nerves are affected by damage, with remission often occurring.

The following table provides an overview of the possible consequences of an electrical accident, depending on the influencing factors described , which can, but do not have to, occur both simultaneously and with a time delay, individually or in combination with different probability:

body part (s) through which electricity flows or affected	u. a. possible symptom (s)
Body cells , tissues , organs (general)	Cell destruction, with the formation of toxic protein decomposition products that can lead to kidney damage and symptoms of poisoning, acidosis , overheating, damage or lysis or increased permeability of the plasma membrane , (functional) disorders, damage to destruction of various tissues and organs ( lesions , necrosis ), changes in the Membrane potential , depolarization , liquefaction of the tissue, changes in metabolism, (internal) bleeding , shock, ( multiple ) organ failure, coagulation, denaturation , dehydration , hypoxia , carbonization, electrolyte disturbance , hyperkalaemia , hypocalcemia , ion shift, disturbance of stimulus generation and conduction
Skin , muscles, but also all other tissues	light to severe (external and internal) burn injuries (grade 1-4, burn disease), among other things at the entry and exit points of the current (current marks ), but also severe muscle destruction (myolysis) or destruction of other tissues through internal burns ("boilings", Soft tissue injuries), with prolonged exposure including entire organs or the entire body, blistering , reddening of the skin, (burn) wounds , discoloration
Transitional epithelial tissue , Mucous membrane	Aphthae , erosions , ulcers
Muscles (general, all types)	Paralysis or spasms of the skeletal muscles (simple / phasic and tetanic muscle contractions , muscle spasms ), which can cause muscle tears , tendon tears , dislocations and broken bones , as well as of the heart and respiratory muscles , myoglobinemia, compartment syndrome , weak to severe muscle pain , but also rhabdomyolysis , Muscular atrophy , myoclonia
heart	Cardiac arrhythmias (can also longer delay hours after the accident occurring) such as ventricular fibrillation , atrial flutter and atrial fibrillation , premature beats , but also heart attack symptoms, bradycardia , hypertension , (sinus) tachycardia (this increase in blood pressure), ventricular flutter , (polymorphic) ventricular tachycardia , torsades de pointes , electromechanical dissociation , hypotension, AV block (Wenckebach period), temporary or permanent asystole ( cardiac arrest ) as well as (permanent) cardiac muscle damage (myocardial damage) up to (beginning) heart failure (acute or delayed), in individual cases ischemia with CK - rise and pericardial effusion , even troponin -increase, leg blocks (intraventricular spread disorder), syncope , coronary vasospasm (coronary vasospasm), intracoronary thrombus, bradycardia , heart attack and heart wall aneurysm
peripheral nerves	Paresthesia (including of the nerve trunk), sensory disorders , reversible and irreversible loss or paralysis ( paralysis ) of sensory, motor and reflex functions, paresis, disorders of the autonomic nervous system, pain
Spinal cord	more or less complete paraplegic syndrome , but also possibly amyotrophic lateral sclerosis , spinal trauma, spastic paresis, progressive deficits due to adhesive arachnoiditis, muscle atrophy
brain	Unconsciousness ( coma ), impaired consciousness ( clouding of consciousness ), vigilance disorder , restlessness , memory disorders , thought disorder , seizures such as tonic clonic convulsions , pareses , dys- paresthesia , cerebral edema (resulting, for example: increase in intracranial pressure ), confusion , dizziness , headache, nausea , Amnesia , aphasia , vegetative dystonia , opisthotonus , root syndrome or, in the case of (too) high exposure to heat, permanent damage such as a cerebral lesion (e.g. hemiplegia , paraplegia, tetraparesis , Parkinson’s syndrome or epilepsy / epileptiform seizure), disorders of respiratory regulation , Paralysis or death from central paralysis of the respiratory center ( apnea ), cranial nerve failure , acute brain death , ashing and boiling of the tissue, cerebral necrosis, cerebral venous thrombi, cerebral haemorrhages (such as around the 3rd ventricle , on the floor of the 4th ventricle and on the Cortical marrow boundary), extrapyramidal dysfunction , cerebral dysfunction, neurological focus symptoms (dur ch scarring), (severe) neurological failures resulting in cyanosis , hyperhidrosis , hypertension , tremor , changes in brain metabolism, permanent damage, cerebellar atrophy
Meninges	by thermal action: development of aseptic meningitis , arachnoiditis
Skullcap	by heating the tissue and a sharp increase in pressure: detonation
blood	Gas formation through electrolysis of the blood, increased LDH values
Blood vessels	Spasms , thromboses , aneurysms , vascular ruptures, vascular necrosis (of the intima and media), hemorrhages , embolism ( fat embolism ), in coronary arteries coronary spasms with myocardial ischemia ("angina pectoris electrica"), in higher temperatures coagulation with thrombus formation, venous hyperemia ,
Area thorax and lungs	Direct damage to the lungs, pneumothorax , respiratory insufficiency ( dyspnea ) due to tetany of the diaphragm, intercostal and auxiliary respiratory muscles up to respiratory arrest , peripheral respiratory paralysis, hypoventilation, dysfunction of the chest wall, exudative pleural effusion
Regions above or near the collarbones or area of ​​the eyes	Cataract (cataracta electrica, also delayed), Kornealäsion, retinopathy (with edema ), Retinaläsion, papilledema , scotoma , Photokeratitis , damage to the optic nerve , optic neuropathy, visual disturbances, pigmentary changes, wide and fixed pupil (autonomic dysfunction), macular edema , retinal detachment , uveitis , ocular thrombosis, temporary or permanent blindness , chorioretinal atrophy , papilledema, hemorrhage , Makulaläsion
Hearing and balance system	Inner ear damage , tympanic membrane perforation, burns (of the skin of the ear canal), transitory facial paralysis , lesions, dizziness , rupture of the Reissner membrane, bleeding with subsequent formation of a hematoma , fractures of the temporal bone , damage to the auditory balance nerve , hearing impairment ( tinnitus )
Abdomen area Esophagus, stomach, intestines	Necrosis, damage to the intra-abdominal hollow organs ( perforation ), nausea , vomiting , paralytic ileus , intestinal motility
Kidneys	acute tubular necrosis, kidney failure (e.g. due to myoglobinuria , hemoglobinuria , protein toxins, renal " crush syndrome ", or in the event of parenchymal damage), hypovolemia
Indirect effect: e.g. B. Bang or pressure wave (z. B. during a thunderstorm) can u. a. Internal bleeding , sudden hearing loss and tinnitus , bright electric arcs can damage the retina , and there is also a risk of secondary accidents such as B. A fall caused by shock, which can lead to head trauma if the head hits hard objects Long-term consequences: physical consequential damage such as peripheral nerve lesions that can occur up to 3 years after the accident, as well as sensitivity disorders and (poly) neuropathies (in the event of lightning strikes), but also psychological such as sleep disorders, post-traumatic stressful situations, depression, psychoses, anxiety attacks, but also motor neuron diseases (motor system degeneration), tonic spinal cord seizures, extrapyrimidal movement disorders, atrophy of the lateral and spinal cords

activities

Measures at the scene of the accident

In general, the scheme of the rescue chain for first aid must also be observed here and it is essential to pay attention to self-protection when providing assistance and to warn outsiders so that no live parts are touched or there is a sufficient safety distance in the event of high voltage (set up barriers). In addition, flooded areas represent a further danger - this should be taken into account by both the house residents and the emergency services on site. Among other things, it is important to:

High voltage area

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Motive: Warning sign on which the safety distance is clearly visible (not just a sign "Caution high voltage") such as this one (also for items overhead line ).

If you want to help, the instructions explain how it works.

In contrast to the low voltage which requires direct contact with the involved power lines for the current flow, are in non-insulated high-voltage system components such as power lines or overhead lines in the contactless approach flashovers with the formation of life-threatening arcs possible. Due to the high instantaneous power, the electric arc leads, in addition to the strong lighting effect and loud bang, to sudden evaporation of metallic contact material, which can lead to fires in the vicinity and burns on unprotected skin. Also at the insulation damaged high voltage cables are dangerous because voltage breakdowns can occur. For this reason, appropriate fire-resistant protective clothing with face protection such as a visor must be worn when working in the potential area of ​​impact of an electric arc .

U n to ...	Distance for electrotechnical
	instructed persons	Lay people
1 kV	0.5 m	1 m
30 kV	1.5 m	3 m
110 kV	2 m	3 m
220 kV	3 m	4 m
380 kV	4 m	5 m
500 kV		8 m
750 kV		11 m
1000 kV		14 m

To rescue the system, first ensure that it is de- energized . Systems and devices must first be disconnected from the power supply and then additionally grounded using a grounding rod or short -circuited using a short -circuiter in order to divert partial voltages and to prevent switched-off lines from remaining live, for example through inductive or capacitive coupling of neighboring operating wires. It should be noted that some energy technology systems with automatic restart are automatically reactivated after a short interruption due to the accident. The five safety rules must be followed in this order .

In the case of systems whose absence of voltage is not certain, a safety distance dependent on the voltage level, which increases with increasing voltage, must be observed. In addition, environmental factors such as weather conditions or ionization of air must be taken into account. Usual safety distances for people, which are observed by fire brigades, are given in the adjacent table.

There are separate safety distances for extinguishing any fires in live systems, which must be observed in systems that are live or not yet short-circuited. They also depend on the voltage, but also on the extinguishing agent used . If water is used, the above distances apply to a spray jet , to a full jet the distance increases to 6 meters at up to 110 kV, 7 meters at up to 220 kV and 8 meters at up to 400 kV.

Another source of danger for the rescuers is the step voltage that occurs when a live conductor touches the ground and current flows into the ground.

Low voltage area

Measures at the accident site in the event of low-voltage accidents

For rescue, exposed, live cables should be removed from the injured person with the help of dry and clean, non-conductive objects (e.g. long and thick broomstick made of plastic ), if necessary, bring the injured person out of the accident area using sufficiently electrically insulating aids such as safety gloves for electricians move away.

Even in the low-voltage area, the necessary safety distances must be observed when extinguishing work under voltage: The distance is one meter for a spray jet and five meters for a full jet. When extinguishing with portable fire extinguishers , a distance of one meter must be kept for a spray jet and only three meters for a full jet. ^[71]

In the case of unconscious patients, after the power supply has been switched off and (depending on the country-specific safety regulations ) any additional short-circuiting of the system, ensuring breathing and cardiovascular function has priority. If necessary, immediate cardiopulmonary resuscitation should be initiated. Trained rescue personnel defibrillate ventricular fibrillation . If available, a publicly accessible lay defibrillator is used.

In the case of responsive patients, burn injuries are only to be cooled initially, while maintaining normothermia, and covered with a low-germ, non-fluff wound pad. If water is used to cool any burns, it should therefore have room temperature, but under no circumstances a temperature below 15 ° C or even be ice-shaped, as this can lead to hypothermia on the one hand and, paradoxically, tissue damage on the other. The patient should not be left unattended, even if they are completely well, until heart damage has been ruled out. A 12-channel electrocardiogram is always required for this . Therefore, the alerted ambulance service usually transports them to the emergency room of a hospital. If changes in the electrocardiogram are detectable, a high-voltage accident has occurred or special risk factors exist, an observation with ECG monitoring is carried out for several hours.

The further measures depend on the severity of the burns. The thermal effect of the electric current leads to fluid loss in the body. Likewise, the charring of the affected tissue ( necrosis ) can lead to the development of toxins. There is a risk of sepsis resulting in death from bacterial infection of the damaged organs. In order to reduce damage to the kidneys, it is necessary to compensate for the loss of fluid with intravenous volume administration , for example sodium chloride infusion solution .

Diagnostics and monitoring

anamnese

The following points should be clarified:

• physical complaints at the time of the event or during the course?
• Chest pain, palpitations, shortness of breath?
• Loss of consciousness, gaps in memory, abnormal sensations, dizziness?
• Concomitant injuries (indirect consequences)?

Investigations

• Physical examination with a basic examination of the heart, lungs, abdominal area, in particular search for current brands
• Laboratory: complete blood count : determination of kidney and liver values (e.g. creatinine , GOT , GGT , GPT , AP , cholinesterase ), urea , hemoglobin , hematocrit , leukocytes , platelets , Quick value , muscle and heart enzymes ( troponin , Creatine kinase ), CK , CK-MB , myoglobin , haptoglobin , electrolytes , AST , alanine aminotransferase , bilirubin , albumin , amylase and lipase , lactate , LDH , aldolase , in the case of burns additional blood gases including carboxyhemoglobin and coagulation values ​​( aPTT , fibrinogen , III )
• Urine examination : myoglobin in urine ?, determination of the hourly diuresis, coloring
• 12-lead ECG
• Monitoring of renal excretion
• MRI for diagnosis of damage to muscles and tissues
• Measurement of the nerve conduction velocity to determine possible nerve damage
• Angiography e.g. E.g. in the case of disorders of the blood circulation

Monitoring High-voltage accidents are always subject to inpatient intensive care monitoring . In most cases, there are also relevant accompanying injuries such as burns. In the event of low-voltage accidents, monitor monitoring is required if the casualty was temporarily unconscious , arrhythmias were observed at the scene of the accident or during transport, or a suspicious 12-lead ECG is present. In- patient monitoring is only necessary if the medical history , physical examination or laboratory diagnostics reveal abnormal changes, a voltage above 500 V was the cause or there are serious underlying diseases of the cardiovascular system.

historical event

Illustration of a tragic electrical accident involving a line fitter in New York City in October 1889

The first electrical accident documented in writing is seen in the BGV as an event on November 4, 1879 in the Reichstag building in Berlin, in which an employee who wanted to demonstrate the function of the lamps to a group of people who were present got into the electrical circuit. He touched the two live contacts in the lamp base and fell to the floor. One of the people present made the suggestion to divert the harmful current, which should still be in the casualty, into the earth. To do this, the casualty was carried into the garden and his hands put into the earth. The "healing method" used at that time in the acute situation can be explained by the general lack of understanding of the context and does not represent a suitable reaction.

See also

• Protection class (electrical engineering)
• Five safety rules
• Residual current protective device

literature

• Gottfried Biegelmeier, Dieter Kieback, Gerhard Kiefer, Karl-Heinz Krefter: Protection in electrical systems. Volume 1: Dangers from Electric Current (=  VDE series of publications . Volume 80 ). 2nd Edition. VDE Verlag, Berlin / Offenbach 2003, ISBN 3-8007-2603-3 . 
• Gottfried Biegelmeier: Effects of the electric current on humans and farm animals. Electropathology textbook . VDE-Verlag, Berlin 1986, ISBN 3-8007-1452-3 . 
• Werner Hörmann, Bernd Schröder: Protection against electric shock in low-voltage systems - Commentary on DIN VDE 0100-410 (VDE 0100-410): 2007-06 (=  VDE series of publications . Volume 140 ). VDE-Verlag, Berlin, ISBN 978-3-8007-3190-9 . 
• Siegfried Altmann : An analysis of the "electrical accidents in the former GDR and today". VDE-Fachbericht 43. VDE-Verlag, Berlin / Offenbach 1993, pp. 5–17.
• Siegfried Altmann: Investigations into fatal electrical accidents in the home and leisure area as well as in trade in the new federal states. VDE-Fachbericht 53. VDE-Verlag, Berlin / Offenbach 1998, pp. 115–135.

Norms

• DIN IEC / TS 60479-1 ( VDE V 0140-479-1): 2007-05 Effects of electric current on people and farm animals - Part 1: General aspects
• DIN V VDE V 0140-479-4 (VDE V 0140-479-4): 2005-10 Effects of electric current on people and farm animals - Part 1: Effects of lightning strikes on people and animals
• DIN EN 61140 (VDE 0140-1): 2007-03 Protection against electric shock - common requirements for systems and equipment
• DIN VDE 0100-410: 2007-06; Erection of low-voltage systems - Part 4-41: Protective measures; Protection against electric shock
• DIN VDE 0100-540: 2012-06; Erection of low-voltage systems - Part 5-54: Selection and erection of electrical equipment - Earthing systems, protective conductors and protective equipotential bonding conductors

Web links

Commons : Electricity Accidents  - Collection of Pictures, Videos and Audio Files

Wikibooks: First Aid / Electric Shock  - Learning and Teaching Materials

Wiktionary: Electric shock  - explanations of meanings, word origins, synonyms, translations

• Electrical accident on the website of the Working Group for Emergency Medicine
• AGN Working Group for Emergency Medicine Emergency Graz: The electrical accident ( Memento from September 28, 2007 in the Internet Archive )
• Jens Jühling: Electrical accidents in Germany, (PDF; 230 kB) Berufsgenossenschaft Feinmechanik und Elektrotechnik, Cologne, lecture 2005 at the symposium "Mensch - Strom - Felder" on 10./11. November 2005 of the Research Center for Electropathology (FfE)
• ets.uni-duisburg-essen.de (PDF)
• Electropathological exhibition in the Technical Museum in Vienna

Footnotes

1. ↑ mainly in the case of electrical accidents in the low-voltage range up to around 400 V or 500 V (around 90% of electrical accidents). For accidents involving high voltage, see Influencing factors, voltage

Individual evidence

1. ↑ ^{a b c d} Jens Scholz, Bernd W. Böttiger, Volker Dörges, Volker Wenzel, Peter Sefrin : Emergency Medicine . Georg Thieme Verlag, 2012, ISBN 978-3-13-158983-5 ( limited preview in Google Book Search [accessed on May 30, 2016]). 
2. ^ Bogdan Adamczyk: Foundations of Electromagnetic Compatibility: with Practical Applications . John Wiley & Sons, 2017, ISBN 978-1-119-12079-7 ( google.at [accessed September 22, 2018]). 
3. ^ Stefan Jellinek: Electropathology . Рипол Классик, 1903, ISBN 978-5-88178-805-6 ( limited preview in Google Book Search [accessed August 5, 2016]). 
4. ^ Alfred X. Trautwein, Uwe Kreibig, Jürgen Hüttermann: Physics for physicians, biologists, pharmacists . Walter de Gruyter GmbH & Co KG, 2014, ISBN 978-3-11-037328-8 ( limited preview in the Google book search [accessed on September 12, 2016]). 
5. ↑ Electrical accident, electrical safety. (PDF) pp. 7-8 , accessed on September 12, 2016 . 
6. ^ H. Cottier: Pathogenesis: A handbook for medical training . Springer-Verlag, 2013, ISBN 978-3-642-67213-2 ( limited preview in the Google book search [accessed August 29, 2016]). 
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9. ^ Norbert Leitgeb: Safety of Electromedical Devices: Law - Risks - Opportunities . Springer Science & Business Media, 2010, ISBN 978-3-211-99683-6 ( limited preview in Google Book Search [accessed July 5, 2016]). 
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13. ^ Austrian Red Cross: Red Cross Carinthia: Electric shock. In: roteskreuz.at. Retrieved August 1, 2016 . 
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22. ↑ Gottfried Biegelmeier, Dieter Kieback, Gerhard Kiefer, Karl-Heinz Krefter: Protection in electrical systems, dangers from electrical current. 2003, p. 15 (curve c1 in Figure 1.2 according to IEC publication 60479-1)
23. ↑ ^{a b} Hamid Abdolvahab-Emminger: Physikum exact: the entire examination knowledge for the 1. ÄP; 199 tables; [ideal for the new AO] . Georg Thieme Verlag, 2005, ISBN 978-3-13-107034-0 ( limited preview in Google Book Search [accessed July 8, 2016]). 
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27. ↑ Electrical accident, electrical safety. (PDF) Retrieved July 29, 2016 . 
28. ↑ Tobias Mühlenbruch (Sonnentaler / La main à la pâte): Dangers of electricity. In: sonnentaler.net. Retrieved July 8, 2016 . 
29. ↑ Values ​​for direct current. (PDF) Hopital principal de dakar, accessed on August 29, 2016 . 
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33. ↑ Gottfried Biegelmeier, Dieter Kieback, Gerhard Kiefer, Karl-Heinz Krefter: Protection in electrical systems, dangers from electrical current. 2003, p. 192;
    Note: The ascending part of the T wave indicates the so-called vulnerable phase of the heart's action. Here parts of the heart muscle (myocardium) cannot yet be influenced (refractory), while others are already excitable again. If a current surge occurs in this phase, ventricular fibrillation can occur and the heart may fail to pump completely.
34. ↑ A. Lange: Physical Medicine . Springer-Verlag, 2013, ISBN 978-3-642-55837-5 ( limited preview in Google Book Search [accessed August 31, 2016]). 
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40. ↑ DIN VDE 0100-705: 2007-10 section 705.414
41. ↑ ^{a b} DIN VDE 0100-410: 2007 section 701.55
42. ↑ DIN VDE 0100-710_2012-10 section 710.414; for certain applications according to DIN EN 60601-1: 2013-12 (VDE 0750-1: 2013-12) or DIN 57753-1: 1983-02 also significantly less
43. ↑ EU Directive 2009/48 / EC Section IV Paragraph 1 and 2
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45. ^ Heinz G. Engelhardt: Accident medicine: a guide for clinic and practice . Walter de Gruyter, 1998, ISBN 978-3-11-015096-4 ( limited preview in Google Book Search [accessed December 11, 2016]). 
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50. ^ VDE Committee on Safety and Accident Research (SUF): Statistics on electricity accidents in Germany Deaths from electricity in Germany (source: Federal Statistical Office, DESTATIS, statistics on causes of death, from 1990 including new federal states); accessed on August 31, 2018
51. ↑ Institute for Research into Electrical Accidents; Jens Jühling: Electrical accidents in Germany. (PDF), p. 21, accessed on August 31, 2018.
52. ^ Dieter Kieback: Electricity accidents, ventricular fibrillation and lethality. (PDF; 1,4 & nb-07-26sp; MB) BG Elektro Textil Feinmechanik, 2009, p. 27 , accessed in 2018 . 
53. ↑ J. Jacobson, S. Buntenkötter: Contribution to the transferability of the risk from electrical currents from the model animal pigs to humans. In: German veterinary weekly. 81, No. 9, 1974, pp. 214-220.
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65. ↑ H. Berlet, H. Noetzel, G. Quadbeck, W. Schlote, HP Schmitt: Pathology of the nervous system II: developmental disorders, chemical and physical causes of illness . Springer-Verlag, 2013, ISBN 978-3-642-51154-7 ( limited preview in the Google book search [accessed June 20, 2016]). 
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73. ↑ Linus Geisler: Internal medicine: textbook for nursing professions . W. Kohlhammer Verlag, 2006, ISBN 978-3-17-018768-9 ( limited preview in Google Book Search [accessed September 3, 2016]). 
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79. ↑ Sönke Müller: Memorix emergency medicine . Georg Thieme Verlag, 2011, ISBN 978-3-13-157829-7 ( limited preview in the Google Book Search [accessed on May 23, 2016]). 
80. ↑ Hans-Georg Gieretz: Assessment in cardiology . ecomed-Storck GmbH, 2010, ISBN 978-3-609-16425-0 ( limited preview in Google book search [accessed on May 23, 2016]). 
81. ↑ Jürgen Barmeyer: The cardiological report: Instructions for differentiated assessment of cardiovascular diseases . Georg Thieme Verlag, 2009, ISBN 978-3-13-154932-7 ( limited preview in Google Book Search [accessed May 30, 2016]). 
82. ↑ Rainer Klinge: The electrocardiogram: guidelines for training and practice . Georg Thieme Verlag, 2015, ISBN 978-3-13-201310-0 ( limited preview in the Google book search [accessed on August 5, 2016]). 
83. ↑ Berndt Luederitz: Cardiac arrhythmias: diagnosis and therapy . Springer-Verlag, 2013, ISBN 978-3-662-07755-9 ( limited preview in Google Book Search [accessed September 1, 2016]). 
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87. ↑ Michael Bär: Neurology compact: for clinic and practice; 247 tables . Georg Thieme Verlag, 2009, ISBN 978-3-13-117195-5 ( limited preview in Google book search [accessed December 15, 2016]). 
88. ↑ Werner Hacke: Neurology . Springer-Verlag, 2016, ISBN 978-3-662-46892-0 ( limited preview in Google Book Search [accessed February 8, 2017]). 
89. ↑ Medical therapy 2005/2006 . Springer-Verlag, 2006, ISBN 978-3-540-27385-1 ( limited preview in Google Book Search [accessed September 1, 2016]). 
90. ↑ Deutscher Ärzteverlag GmbH, editorial office of Deutsches Ärzteblatt: Deutsches Ärzteblatt: Blitzunfall - Energy transmission mechanisms and medical consequences. In: aerzteblatt.de. Retrieved September 30, 2016 . 
91. ↑ Jennifer Linn, Martin Wiesmann, Hartmut Brückmann: Atlas Clinical Neuroradiology of the Brain . Springer-Verlag, 2011, ISBN 978-3-540-89569-5 ( limited preview in the Google book search [accessed June 20, 2016]). 
92. ↑ Physikalisch-Medicinische Societät zu Erlangen: Meeting reports . January 1, 1942 ( limited preview in Google Book Search [accessed August 6, 2016]). 
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94. ^ Heinrich Mattle, Marco Mumenthaler: Neurology . Georg Thieme Verlag, 2012, ISBN 978-3-13-157773-3 ( limited preview in Google Book Search [accessed on May 11, 2016]). 
95. ↑ Christoph Georg Wölfl, Christoph Wölfl: Accident rescue: tactics, technology and rescue equipment; with 32 tables . Schattauer Verlag, 2010, ISBN 978-3-7945-2684-0 ( limited preview in Google Book Search [accessed on May 11, 2016]). 
96. ^ A. Laggner, Thomas Hamp, C. Sitzwohl, David Weidenauer: Textbook Tertial Emergency and Intensive Care Medicine . Springer-Verlag, 2012, ISBN 978-3-7091-1012-6 ( limited preview in Google Book Search [accessed on May 13, 2016]). 
97. ↑ M. Eder, P. Gedigk: Textbook of General Pathology and Pathological Anatomy . Springer-Verlag, 2013, ISBN 978-3-642-96760-3 ( limited preview in Google Book Search [accessed June 10, 2016]). 
98. ↑ DP Todeschini, EDM Maito, A. Maldotti, ALM Moreira, FB Capaverde: Brain death caused by electric shock and organ donation in children . In: Transplantation Proceedings . tape 39 , no. 2 , March 1, 2007, ISSN  0041-1345 , p. 399-400 , doi : 10.1016 / j.transproceed.2007.01.033 , PMID 17362740 . 
99. ↑ Bodo Gorgaß, Friedrich W. Ahnefeld, Rolando Rossi: Paramedic and paramedic . Springer-Verlag, 2013, ISBN 978-3-662-09764-9 ( limited preview in Google Book Search [accessed July 5, 2016]). 
100. ↑ Norbert Boos: Neurotraumatology . Georg Thieme Verlag, 2005, ISBN 978-3-13-136921-5 ( limited preview in the Google book search [accessed December 15, 2016]). 
101. ↑ Werner Paulus, Michael J. Schröder: Pathology: Neuropathology . Springer-Verlag, 2011, ISBN 978-3-642-02324-8 ( limited preview in Google Book Search [accessed on August 5, 2016]). 
102. ↑ Susanne Asenbaum: Clinical Neurology II: The most important neurological diseases for human and dental medicine . Facultas, 2007, ISBN 978-3-7089-0080-3 ( limited preview in Google Book Search [accessed August 31, 2016]). 
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104. ↑ Hans-Christian Hansen: Disturbances of consciousness and encephalopathies: diagnosis, therapy, prognosis . Springer-Verlag, 2013, ISBN 978-3-642-36915-5 ( limited preview in Google Book Search [accessed December 11, 2016]). 
105. ↑ Jens Litmathe: Neurological emergencies: Preclinical and intra-clinical acute care . Springer-Verlag, 2016, ISBN 978-3-662-49775-3 ( limited preview in Google Book Search [accessed December 15, 2016]). 
106. ↑ Karl Friedrich Masuhr, Florian Masuhr, Marianne Neumann: Dual series of neurology . Thieme, 2013, ISBN 978-3-13-151697-8 ( limited preview in Google Book Search [accessed June 2, 2016]). 
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108. ^ Klaus Ellinger: course book emergency medicine: based on the nationwide curriculum additional designation emergency medicine: with 138 tables . Deutscher Ärzteverlag, 2011, ISBN 978-3-7691-0613-8 ( limited preview in Google Book Search [accessed June 4, 2016]). 
109. ↑ Hans A. Kühn: Internal Medicine. A textbook for medical students and doctors: Part 2: Digestive organs · Kidneys · Urinary tract · Endocrinology · Metabolism · Immunopathology · Physical influences · Poisoning · Vegetative disorders . Springer-Verlag, 2013, ISBN 978-3-642-65282-0 ( limited preview in the Google book search [accessed August 29, 2016]). 
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112. ↑ The unnatural death - heat, cold, electricity, lightning. (PDF) p. 38 , accessed on September 30, 2016 . 
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115. ↑ Frimmel Marcel: Clinical emergencies at hand: acute internal situations at a glance . Schattauer Verlag, 2016, ISBN 978-3-7945-3187-5 ( limited preview in Google Book Search [accessed February 8, 2017]). 
116. ↑ Heinz-Walter Delank, Walter Gehlen: Neurology: in collaboration with Catherine Eger, Tobias Müller, Stephan Zierz . Georg Thieme Verlag, 2010, ISBN 978-3-13-160002-8 ( limited preview in Google Book Search [accessed February 8, 2017]). 
117. ↑ VDE Committee on Safety and Accident Research (SUF): Correct behavior in flooded rooms VDE information sheet - Dangers from electricity in the event of flooding, heavy rain, flooding; accessed on August 31, 2018
118. ↑ Hans Kemper: dangers d. Insert. - Electricity (fire brigade expertise) . ecomed-Storck GmbH, 2015, ISBN 978-3-609-69792-5 ( limited preview in Google book search [accessed on May 27, 2016]). 
119. ↑ Operating manual. (PDF) p. 9 , accessed on September 21, 2016 . 
120. ↑ Operating Instructions . (PDF) p. 16 , accessed on September 21, 2016 . 
121. ↑ Guideline for protective measures on PBXs against interference from networks of electrical power transmission and distribution as well as AC railways. (PDF) Retrieved May 31, 2016 . 
122. ↑ Assistance in the track area. (PDF) (No longer available online.) Archived from the original on April 27, 2016 ; accessed on May 31, 2016 . Info: The archive link was inserted automatically and has not yet been checked. Please check the original and archive link according to the instructions and then remove this notice. @1@ 2Template: Webachiv / IABot / www.deutschebahn.com 
123. ↑ Danger from electrical current. (PDF) (No longer available online.) Formerly in the original ; accessed on February 21, 2014 .  ( Page no longer available , search in web archives )  Info: The link was automatically marked as defective. Please check the link according to the instructions and then remove this notice.@1@ 2Template: Toter Link / www.feuerwehr-nehren.de    
124. ↑ Fire fighting. (PDF) Retrieved May 31, 2016 . 
125. ↑ Gernot Marx, Elke Muhl, Kai Zacharowski, Stefan Zeuzem: The intensive medicine . Springer-Verlag, 2014, ISBN 978-3-642-54953-3 ( limited preview in the Google book search [accessed December 15, 2016]). 
126. ↑ Peter Knuth: Emergencies according to key symptoms: with 29 tables . Deutscher Ärzteverlag, 2005, ISBN 978-3-7691-0424-0 ( limited preview in Google book search [accessed February 8, 2017]). 
127. ^ Irene Schmid: Ambulanzmanual Pädiatrie from AZ . Springer-Verlag, 2014, ISBN 978-3-642-41893-8 ( limited preview in Google Book Search [accessed June 20, 2016]). 
128. ↑ Jörg Christian Brokmann, Rolf Rossaint: Repetitorium Emergency Medicine: To prepare for the "Emergency Medicine" exam . Springer-Verlag, 2011, ISBN 978-3-642-04960-6 ( limited preview in Google Book Search [accessed on August 29, 2016]). 
129. ^ Volker Diehl: Medical therapy in clinic and practice . Springer-Verlag, 2013, ISBN 978-3-662-12451-2 ( limited preview in Google Book Search [accessed February 8, 2017]). 
130. ↑ Klose: ECG monitoring in electrical accidents. In: The anesthesiologist. 48, Springer 1999, pp. 657-658. doi: 10.1007 / s001010050767
131. ↑ Thomas H. Schneider, Benno Wolcke, Roman Böhmer: Pocket Atlas Emergency & Rescue Medicine: Compendium for the emergency doctor . 4th edition. Springer, 2010, p. 454.
132. ^ Journal of Applied Electricity. 1879.
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