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straight i over denominator 2 πr end fraction equals 477.7 straight V"/>

      Vt = V (r0 )V (r)= 1114.6 V

      From Eq. 1.16, the body current with RB = 1 kΩ, and RBG = 1.5ρ = 300 Ω, is:

iB equals fraction numerator straight v subscript th over denominator straight R subscript straight B plus straight R subscript BG end fraction equals space 857.4 space mA

      1.10 Identification of Extraneous-Conductive-Parts

      The term earth potential is generally assumed to be zero volts and introduced by the general mass of the earth into the installation. This definition implies that such conductive parts would originate outside the building and be in contact with the ground. If this can be verified by visual inspection, the part in question should be bonded as close as practicable to their point of entry within the building. It is important to clarify that for bonding purposes, the point of connection of pipework should take place along the section of the pipe from the meter into the building, which is owned by the user, and not on the section that comes in from the road into the meter. This prevents corrosion issues to the service pipework.

      If it is not possible to verify by visual inspection alone that a conductive part is an EXCP, a measurement of the resistance REX between the conductive part in question and the main ground busbar should be performed. If the measured resistance REX satisfies Eq. 1.18, based on the circuit of Figure 1.16, the conductive part in question is not to be considered an EXCP.

      Vth is the nominal voltage to ground of the installation (in V); RB is the standard value of body resistance of 1 kΩ; IBM (A) is the maximum value of body current that is deemed acceptable to the designer. Threshold values for IBM may be 0.5 mA (i.e., the threshold of perception), 10 mA (the threshold of let-go), or 30 mA.

      However, the designer should assess if the measured resistance to the ground of the concerned conductive part may change (i.e., decrease) throughout the lifetime of the installation.

      If, for example, the chosen threshold of safe current is 30 mA with vth = 230 V, and the measured resistance between a conductive part not forming part of the electrical installation (a presumed EXCP) and the ground is greater than 6.67 kΩ, then no connection to the main ground terminal of the metal part in question would be required.

      1.11 Measuring Touch Voltages

      For touch voltage measurements a current injection method may be used (Figure 1.18).

      An alternating voltage of approximately the system frequency is applied between the facility ground electrode and an auxiliary ground electrode, located far enough to guarantee separate zones of influence (e.g., 4 or 5 times the maximum dimension of the facility ground electrode). A test current im is injected into the facility grounding system, which causes a measurable ground potential rise.

      The test current should be so high that the measured touch voltage, referred to as the test current, is greater than possible disturbance voltages; according to EN 50522, this may be ensured for test currents of at least 50 A. Always according to EN 50522, the measuring electrodes for the simulation of the feet, connected in parallel, must have a total area of 400 cm2, lie on the ground with a minimum total force of 500 N, and placed at a distance of 1 m from the equipment of the installation, or from an EXCP. During the test, the auxiliary ground electrode may assume a dangerous ground potential rise, and therefore should be guarded.

      The tip-electrode for the simulation of the hand touching the equipment, or an EXCP, must be capable of penetrating a paint coating (not insulation).

      The reading of the voltmeter, which is referred to as the test current, must then be scaled up by multiplying it by the ratio of the effective ground-fault current provided by the utility to the test current.

      The touch voltage measurement should be performed in the substation, as a sampling test, keeping in mind that higher magnitudes for the touch voltages may be found around the edge of the ground grid.

      References

      1 1 Moreno, B., and López, A.J.(2008). The effect of renewable energy on employment. The case of Asturias (Spain). Renewable and Sustainable Energy Reviews 12 (3): 732–751.

      2 2 Bulavskaya, T., and Reynès, F.(2018). Job creation and economic impact of renewable energy in the Netherlands. Renewable Energy 119: 528–538. doi:9.

      3 3 Sooriyaarachchi, T.M., Tsai, I.-T., El Khatib, S., Farid, A.M., and Mezher, T.(2015). Job creation potentials and skill requirements in, PV, CSP, wind, water-to-energy and energy efficiency value chains. Renewable and Sustainable Energy Reviews 52: 653–668.

      4 4 Gammon, T., Lee, W., and Intwari, I.(2019). Reframing our view of workplace ‘electrical’ injuries. IEEE Transactions on Industry Applications 55 (4): 4370–4376.

      5 5 Crow, D.R., Liggett, D.P., and Scott, M.A.(2017). Changing the electrical safety culture. 2017 IEEE IAS Electrical Safety Workshop (ESW), 1–7.

      6 6 Neitzel, D.K.(2016). Electrical safety by design and maintenance. 2016 IEEE Pulp, Paper Forest Industries Conference (PPFIC), 6–13.

      7 7 Mathe, L., Sera, D., Spataru, S.V., Kopacz, C., Blaabjerg, F., and Kerekes,

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