Chapter 25: Baiianced And Unbaxiancbd Polyphase Systema

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Source Metadata

Field	Value
Source	Theory and Calculation of Alternating Current Phenomena
Year	1897
Section ID	`theory-calculation-alternating-current-phenomena-1897-chapter-25`
Location	lines 25605-26027
Status	candidate
Word Count	1558
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Opening Source Excerpt

CHAPTER XXV. BAIiANCED AND UNBAXiANCBD POLYPHASE SYSTEMa 239. If an alternating E.M.F. : ^ = ^ V2 sin j8, produces a current : /• = /V2sin()8-^), where w is the angle of lag, the power is : / = ^/ = 2 Elsm )8 sin 03 - u») = -£'/(cos w — sin (2 /3 — w)), and the average value of power : 7^= EI cos w. Substituting this, the instantaneous value of power is found as : \^ cos w J Hence the power, or the flow of energy, in an ordinary single-phase alternating-current circuit is fluctuating, and varies with twice the frequency of E.M.F. and current, unlike the power of a continuous-current circuit, which is constant : p -= €t. If the angle of lag w = it is : / =

Source-Located Theme Snippets

Alternating current

... r is : / = ^/ = 2 Elsm )8 sin 03 - u») = -£'/(cos w — sin (2 /3 — w)), and the average value of power : 7^= EI cos w. Substituting this, the instantaneous value of power is found as : \^ cos w J Hence the power, or the flow of energy, in an ordinary single-phase alternating-current circuit is fluctuating, and varies with twice the frequency of E.M.F. and current, unlike the power of a continuous-current circuit, which is constant : p -= €t. If the angle of lag w = it is : / = /^ (1 - sin 2 )3) ; hence the flow of power varies between zero and ...

Complex quantities

CHAPTER XXV. BAIiANCED AND UNBAXiANCBD POLYPHASE SYSTEMa 239. If an alternating E.M.F. : ^ = ^ V2 sin j8, produces a current : /• = /V2sin()8-^), where w is the angle of lag, the power is : / = ^/ = 2 Elsm )8 sin 03 - u») = -£'/(cos w — sin (2 /3 — w)), and the average value of power : 7^= EI cos w. Substituting this, the instantaneous value of power is found as : ...

Waves / transmission lines

... of energy or the effective power of the circuit. 1240} BALANCED POLYPHASE SYSTEMS, 857 If the current lags or leads the E.M.F. by angle a> the power varies between p(\--±J\ and /Yl+-l_V y cos w y y cos w j that is, becomes negative for a certain part of each half- wave. That is, for a time during each half-wave, energy flows back into the generator, while during the other part of the half-wave the generator sends out energy, and the difference between both is the effective power of the circuit. If ci = 90°, it is : / = EIcos2p\ that is ...

Dielectricity / capacity

... ly, as in the single-phase sys- tem ; and the ratio of the minimum value to the maximum value of power is called the balance factor of ttie system. 358 ALTERNATIXG-CURRENT PHENOMENA. [§§241,242 Hence in a single-phase system on non-inductive circuit, that is, at no-phase displacement, the balance factor is zero ; and it is negative in a single-phase system with lagging or leading current, and becomes = — 1, if the phase displace- ment is 90° — that is, the circuit is wattless. 241. Obviously, in a polyphase systeiji the balance of the system is a funct ...

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Modern Engineering Reading Prompts

Alternating current: Compare Steinmetz’s AC language with modern sinusoidal steady-state analysis, RMS quantities, phase, and phasor notation.
Complex quantities: Track how Steinmetz preserves geometric rotation and quadrature while translating the same operation into symbolic form.
Waves / transmission lines: Map Steinmetz’s wave and line language onto modern distributed constants, propagation velocity, standing waves, and reflections.
Dielectricity / capacity: Check whether the passage treats capacity, condensers, displacement, or dielectric stress as field storage rather than only circuit algebra.
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Dielectricity / capacity: A Wheeler-style reading may emphasize dielectric compression, field stress, and stored potential, but this page treats that as interpretation unless Steinmetz explicitly says it.
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