@article{Baranov_2018, title={POWER DESCRIPTIONS OF A STORM CLOUD OF TROPOSPHERE OF EARTH: FEATURES OF THEIR CALCULATION AND APPLIED UTILIZATION}, url={http://eie.khpi.edu.ua/article/view/2074-272X.2018.3.05}, DOI={10.20998/2074-272X.2018.3.05}, abstractNote={<strong><em>Purpose.</em></strong><em> Implementation of calculation estimation of such basic power descriptions of the system is a «storm cloud - earth», as total charge of q</em><sub>Σ</sub><em>, electric potential of </em><em>φ<sub>r</sub>, electric energy of W</em><sub>0</sub><em> and amplitude-temporal parameters (ATP) of pulse current i<sub>L</sub></em>(<em>t</em>)<em> in the channel of a long air spark discharge of cloud on earth.</em><em> <strong>Methodology.</strong> Electrophysics bases of technique of high voltages and large currents, theoretical bases of the electrical engineering, theoretical electrophysics, theory of the electromagnetic field and technique of the strong electric and magnetic fields. <strong>Results.</strong> The results of calculation estimation of basic power descriptions are resulted in the overhigh voltage electrophysics calculation system a «storm cloud – earth». To such descriptions of a storm cloud behave: total electric charge of q</em><sub>Σ</sub><em>, concentrated in a storm cloud of spherical form of the set volume with the </em><em>shallow dispersible negatively charged including as particulate dielectric matters the set by an middle closeness; electric potential of φ<sub>r</sub> is in the spherical volume of a storm cloud of the set size; electric energy of W</em><sub>0</sub><em>, accumulated in the spherical volume of a storm cloud of the set radius of </em><em>R</em><sub>0</sub><em>; PTP (amplitude of </em><em>I<sub>mL</sub> and duration of τ<sub>p</sub> at level 0.5I<sub>mL</sub>) of aperiodic impulse of current i<sub>L</sub></em>(<em>t</em>)<em> of linear lightning in the plasma channel of a long air spark digit of a storm cloud on earth. The ground of possibility of the use is given in close practical calculations in place of the real storm cloud of the simplified calculation model of a storm cloud, containing the spherical volume of </em><em>V</em><sub>0</sub><em> by the radius of </em><em>R</em><sub>0</sub><em> is shown that at </em><em>R</em><sub>0</sub><em>≈985 m and accordingly V</em><sub>0</sub><em>≈4∙10<sup>9</sup> m<sup>3</sup> in the examined model of a storm cloud his indicated power descriptions arrive at the followings numeral values: charge of q</em><sub>Σ</sub><em>≈−55.6 C, potential on the outward surface of cloud of φ<sub>R</sub>≈−506 MV, electric energy of W</em><sub>0</sub><em>≈14.1 GJ in a cloud and amplitude of aperiodic impulse of current of I<sub>mL</sub></em>≈−<em>262.1 кА at duration of his flowing </em><em>τ<sub>p</sub>≈142.4 μs in the plasma channel of a long air spark digit of cloud on earth. This calculation information well correlates with the known experimental information, characteristic for the short shots of lightning in surface objects. The receive results will be instrumental in possibility of prognostication of a sticky storm wicket specialists at presence of only minimum initial information about a storm cloud in earthly troposphere. <strong>Originality.</strong> First at the analysis of a storm situation in troposphere of Earth offered approach, related to bringing the real storm cloud over the volume of V</em><sub>0</sub><em> to an equivalent on volume spherical storm cloud by the radius of </em><em>R</em><sub>0</sub><em>, for which will apply the </em><em>physical and mathematical vehicle of analysis of flowings in him electrophysics processes developed an author. <strong>Practical value.</strong> Application of the in practice calculation findings will allow to deepen scientific and technical knowledge in area of nature of atmospheric electricity, will be instrumental in further development of physics of linear lightning and successful decision of global problem of protecting from lightning of surface objects and auxiliary them personnel. </em>}, number={3}, journal={Electrical Engineering & Electromechanics}, author={Baranov, M. I.}, year={2018}, month={Jun.}, pages={37–42} }