Industrial Electronics video assignment : Electromechanical Relay

Electric Shock

     Electricity is essential to modem life, both at home and on the job. Some employees work with electricity directly, as is the case with engineers, electricians, electronic technicians, and power line workers. Others, such as office workers and sales-people, work with it indirectly. As a source of power, electricity is accepted without much thought to the hazards encountered. Perhaps because it has become such a familiar part of our surroundings, it often is not treated with the respect it deserves. Electric shock occurs when a person’s body becomes part of electric circuit. The current must enter the body at one point and leave at another. Electric shock normally occurs in one of three ways : Individuals-while in contact with the ground- must come in contact with both wires of the electric circuit, one wire of an energized circuit and the ground, or a metallic part that has become "hot" by contact with an energized conductor. The three electrical factors involved in an electric shock are resistance, voltage, and current.

Figure 1. Electric shock danger sign

The lower body resistance, the greater the potential electric shock hazard. Body resistance can be divided into external ( skin resistance) and internal ( body tissues and blood stream resistance). Resistance to the flow of electricity is measured in ohms and varies widely. It is determined by three factors: the nature of the substance itself, the length and cross-sectional area (size) of the substance, and the temperature of the substance.Some substances, such as metals, offer very little resistance to the flow of electric current and are called conductors. Other substances, such as bakelite, porcelain, pottery, and dry wood, offer such a high resistance that they can be used to prevent the flow of electric current and are called insulators. Dry wood has a high resistance, but when saturated with water its resistance drops to the point where it will readily conduct electricity. The same thing is true of human skin. When it is dry, skin has a fairly high resistance to electric current; but when it is moist, there is a radical drop in resistance. Pure water is a poor conductor, but small amounts of impurities, such as salt and acid (both of which are contained in perspiration), make it a ready conductor. When water is present either in the environment or on the skin, anyone working with electricity should exercise even more caution than they normally would. However, in a small number of instances, the consequence is death from cardiac arrest, or from ventricular fibrillation (where the heart muscle beats in a spasmodic and irregular fashion) or from respiratory arrest. The magnitude of the current is the applied voltage divided by the impedance of the body. 

The overall circuit impedance will comprise the body of the casualty and the other components in the shock circuit, including that of the power source and the interconnecting cables. For this reason, the voltage applied to the body, which is commonly known as the touch voltage, will often be lower than the source voltage. The impendance of the body is determined by the magnitude of the touch voltage ( there being an inverse relationship between impedance and voltage) and other factors, such as the wetness of the skin, cross-sectional area of contact with the conductors, and whether or not the skin is broken or penetrated by the conductors.

Sources :

http://www.technick.net/public/code/cp_dpage.php?aiocp_dp=guide_electric_hazards

http://electrical-engineering-portal.com/do-you-understand-what-is-electric-shock

Petruzella, Frank. (1995). Industrial Electronics. Mc Graw Hill.1-2