EARTHING AND SCREENING     353

           is usually taken as 110 volts. If a resistance of 1000 ohms is used as a standard value then from
           equation (13.1) the threshold voltage E shock will be:-
                                                       0.116
                                        E shock = 1000 × √    volts                       (13.2)
                                                         t s
                 Where t s is the time duration of the shock in seconds. This voltage can be withstood by 99.5%
           of human bodies weighing 50 kg.


           13.1.2 Damage to Equipment

           Occasionally an electrical fault will occur inside a piece of equipment such as a switchboard or motor
           that causes a conductor to touch the casing or frame. In most power systems this type of fault would
           cause a much larger than normal current to flow in the conductors. This current would flow through
           the casing or frame and in so doing would usually cause serious damage to the conductors, their
           insulation and casing metalwork due to sparking or arcing. The damage will usually increase with
           time and can only be minimised by a careful design of the electrical protective relaying schemes that
           detect the fault current, see Chapters 11 and 12.


           13.1.3 Zero Reference Potential

           Most power systems comprise several different three-phase voltage levels, e.g. 11,000 V, 6600 V and
           440 V. They are isolated from one another by the use of transformers. Each isolated sub-section is
           invariably ‘earthed’ or ‘grounded’ at one or more points. (The term ‘earthed’ will be used hereinafter.)
           The purpose of this is to ensure that the voltage difference between any conductor and its casing
           cannot rise above a predetermined amount. The voltage difference can increase due to several causes.
                 Static charge builds up across the insulation and causes the conductor potential to rise. This is
           more of a problem with high voltage equipment because the dielectric properties of the insulation are
           more pure. The insulation resistance is extremely high and does not discharge the accumulated charge.
                 If a fault occurs between the primary and the secondary windings of a transformer, the lower
           voltage winding may experience a high voltage being impressed upon it.
                 If a three-phase sub-system is unearthed and a line-to-casing fault occurs, then the two ‘healthy’
                                                             √
           lines will have their voltage-to-casing raised by a factor of  3. Normally the insulation of machines
           and cables can withstand this increase for a long period of time without harm. It is good practice to
           specify that the insulation systems of transformers, motors, generators and cables should be able to
           withstand an overvoltage of this type continuously.


           13.2 SITE LOCATIONS
           The environment in which the power system is located will have an impact on how the methods of
           earthing equipment are applied. The environments can be broadly grouped as:-
           • Steel structures.
           • Land-based plants.
           • Concrete and brick-built structures.