Source: http://www-spires.fnal.gov/spires/find/books/www?keyword=Electric+Power+-+Distribution
Timestamp: 2019-04-18 10:18:50+00:00

Document:
Author(s): Central Station Engineers of the Westinghouse Electric Corp.
Publisher: Westinghouse Electric Corporation: East Pittsburgh, Penn.
Corp. Author: Central Station Engineers of the Westinghouse Electric Corp.
Keywords: Electric Power - Distribution.
Production and Diagnosis of Dense Cool Alkali Plasmas -- Shock Waves and Thermodynamics of Strongly Compressed Plasmas -- Strongly-Coupled Plasma Diagnostics and Experimental Determination of DC Electrical Conductivity -- III.
-- §21. Reflectors in the Shape of a Surface of Rotation -- § 22. The Spectral Composition of the Radiation -- § 23. The Transition to a Resonator with Plane Mirrors -- § 24. An Optical Resonator with Lenses -- Conclusions -- VII.
Means of Rapid Q-Switching -- § 41. Equations for Light Energy in a Resonator with Modulated Q -- § 42. Shape of the Intensity Peak -- § 43. Effect of a Finite Q-Switching Rate and Pump Nonuniformity on the Shape of the Peak -- § 44.
electro-magneto-gasdynamies -- References -- III. Electromagnetic Equations in Plasma Dynamics -- 1. Introduction -- 2. Maxwell’s equations -- 3. Equation of conservation of electrical charge -- 4. Equation of electrical current -- 5.
Vector and scalar potentials -- 6. Boundary conditions -- 7. Units in electromagnetic theory -- References -- IV. Magnetogasdynamics and Electromagnetogasdynamics -- 1. Introduction -- 2. Magnetogasdynamic approximations -- 3.
for special cases -- References -- VI. Magnetohydrodynamics -- 1. Introduction -- 2. Laminar flow between parallel plates -- 3. Laminar flow in a pipe under external magnetic field -- 4. Laminar flow near a stagnation point -- 5.
Inviscid flow past a magnetized sphere -- 6. Boundary layer flow of a fluid of very small electrical conductivity -- 7. Boundary layer flow of fluid of large or infinite electrical conductivity -- 8. Unsteady motion of a plate.
Rayleigh’s problem -- 9. The temperature distribution in magnetohydrodynamics -- References -- VII. Stability of Magnetogasdynamic Flows -- 1. Introduction -- 2. Stability equations for parallel flow in magnetohydrodynamics -- 3.
Stability of laminar flow between parallel planes in the presence of a coplanar magnetic field -- 4. Stability of laminar flow between parallel planes under a transverse magnetic field -- 5. Stability of boundary layer flow -- 6.
Magnetohydrodynamics -- 1. Introduction -- 2. Double and triple correlation in isotropic turbulence -- 3. Generalized von Kármán-Howarth equation -- 4. Equations in terms of vector potential -- 5. The dissipation of energy -- 6.
inviscid and non-heat-conducting fluid of finite electrical conductivity -- 6. Shock wave structure in a fluid of infinite electrical conductivity -- 7. Shock wave structure in a plasma -- 8. Unsteady flow of an ideal plasma -- 9.
Characteristics of the fundamental equations of one-dimensional unsteady flow of magnetogasdynamics -- 10. Steady flow through a nozzle -- 11. Approximate one-dimensional flow in a transverse electromagnetic field -- 12.
waves -- 6. Electromagnetogasdynamic waves -- References -- XI. Shock Wave Propagation in Magnetogasdynamics -- 1. Introduction -- 2. Oblique shock in magnetogasdynamics -- 3. Oblique shock wave structure in magnetogasdynamics -- 4.

References: §21
 § 22
 § 23
 § 24
 § 41
 § 42
 § 43
 § 44